“ETHNOBOTANICAL AND BIODIVERSITY STUDIES OF COMMON TREES AND SHRUBS ALONG WITH NEXUS BETWEEN CLIMATE CHANGE AND GENE DIVERSITY
OF Juniperus excelsa IN ZARGHOON ECOSYSTEM, BALOCHISTAN (PAKISTAN)”
A thesis submitted to University of Balochistan, Quetta in the
fulfillment of the requirements for the degree of Doctor of Philosophy
Submitted By
ZAHOOR AHMAD BAZAI
DEPARTMENT OF BOTANY UNIVERISTY OF BALOCHISTAN, QUETTA
PAKISTAN (2012)
“ETHNOBOTANICAL AND BIODIVERSITY STUDIES OF COMMON TREES AND SHRUBS ALONG WITH NEXUS BETWEEN CLIMATE CHANGE AND GENE DIVERSITY
OF Juniperus excelsa IN ZARGHOON ECOSYSTEM, BALOCHISTAN (PAKISTAN)”
A thesis submitted to University of Balochistan, Quetta in the
fulfillment of the requirements for the degree of Doctor of Philosophy
Submitted By
ZAHOOR AHMAD BAZAI
DEPARTMENT OF BOTANY UNIVERISTY OF BALOCHISTAN, QUETTA
PAKISTAN (2012)
Dedicated
To
THOSE WHO CARE FOR EARTH,
THE EARTH ONCE OUR MOTHER, NOW OUR CHILD
IT NEEDS TO BE NOURISHED AND TAKE CARE
DECLARATIONIherebydeclarethattheworkpresentedinthisthesisismyown
effortexceptwhereotheracknowledgedandthatthethesisismy
own composition. No part of the thesis has previously been
presentedforanyotherdegree.
Zahoor Ahmad Bazai Ph.D. Scholar
CERTIFICATE
It is hereby, certified that this thesis entitled “Ethnobotanical and
Biodiversity Studies of Common Trees and Shrubs Added by the
Nexus Between Climate Change and Gene Diversity of Juniperus
excelsa in Zarghoon Ecosystem, Balochistan (Pakistan)” based on
the results of experiments carried out by Mr. Zahoor Ahmad Bazai.
We, the supervisor and co-supervisors are fully satisfied with his
research work, which was completed under our supervision and
guidance. Mr. Zahoor Ahmad Bazai has completed thesis write up.
It is recommended that thesis should be sent to external for
evaluation.
Supervisor:
Prof. Dr. Rasool Bakhsh Tareen
s
CERTIFICATE
This iscertifying thatMr.ZahoorAhmadBazai,Ph.D.scholarconducted
researchstudiesunderthesupervisionofProf.Dr.RasoolBakhshTareen
onthetopicentitled“Ethnobotanical and Biodiversity Studies of Common
Trees and Shrubs Added by the Nexus between Climate Change and Gene
Diversity of Juniperus excelsa in Zarghoon Ecosystem, Balochistan
(Pakistan)”
He carried out his Ph.D. work in Department of Botany, University of
Balochistan,Quetta,Pakistan. Theworkpresentedby thescholar in the
thesis isanoriginalworkofgreat scientificknowledge. In future,other
workswillalsobenefitby themethodology,reviewof literatures,results
andreferencespresentedinthethesis.
I do recommended and forward Ph.D. thesis to the Board of
advancedStudiesandResearch(BASR)foritsonwardtransmissiontothe
externalexaminersforitsevaluation.
Chairperson_____________
Department of Botany
University of Balochistan, Quetta, Pakistan Dean _________________________ Faculty of Life Science University of Balochistan, Quetta, Pakistan
LIST OF FIGURES
Contents Page #
Fig. 1. Map of the Zarghoon Juniper Forest Research Area (▲) with five clusters Killi Tor Shor (KTS), Medadzai (M), Gunda (G), Sarobai (S) and Killi Shaban (KS) 20km NE of Quetta City
12
Fig. 2. Pie Chart Showing Percentage of Different Uses of Juniper Tree’s Wood by the Community
36
Fig. 3. Livestock population in Zarghoon Ecosytem owned by local
communities
37
Fig. 4. Average Income sources of the community in percentage 38 Fig. 5. Bar Chart showing Percentage of Men/Women with respect to ethnobotanical Knowledge/ Ignorance”
39
Fig. 6. Bar Chart showing %age of Different Routes of Administration 40 Fig. 7. Bar Chart representing percentages of different modes of plants 41
Fig. 8. Average Diameter at Breast Height (inches) of Juniperus excelsa 47 Fig. 9. Ratio of Sex distribution of Juniper in 5 clusters of the study area. 48 Fig. 10. Mean New Regeneration Ground Cover %age 49 Fig. 11. Mean old Regeneration Ground Cover %age 50 Fig. 12. Rate of Deforestation in five localities 51 Fig. 13. Mean percentage values of Clay; Silt; Water holding capacity; and Sand
55
Fig. 14. Lanes representing the DNA isolation with agarose gel (1%) of Juniperus excelsa.in gel electrophoresis
58
Fig. 15. The DNA isolation but not intact form due to presence of secondary metabolites etc. before protocol modified
58
Fig 16. The DNA isolation with intact DNA shown after protocol modified
59
Fig 17. Intact DNA in lanes representing the DNA isolation with agarose gel (1%) of Juniperus excelsa.in as fingerprints
59
LIST OF TABLES
Contents Page #
Table 1. Quantity of Buffer extraction used for PCR amplification 28 Table 2. Time, activity and temperature of Genomic DNA initiated in PCR amplifier
29
Table 3. Priority of local community using plant species as fuel wood in Zarghoon Juniper forest
36
Table 4. Ecological Characteristics of five clusters in Zarghoon Forest
46
Table 5. Soil Physicochemical Characteristics of 5 Locations at Zarghoon Juniper Forest
54
Table 6. List of location, altitude, collection date, and University of Balochistan Botany Herbarium (UoBBH) voucher number of Juniperus excelsa
57
Table 7: No. of Polymorphic Bands (P.B.) per locus from J. excelsa populations of Zarghoon
60
Table 8. Genetic diversity of populations of Juniperus excelsa in Zarghoon
61
Table 9. Mean soil Physicochemical Characteristics of 5 Locations at Zarghoon Juniper Forest
62
Table 10. Climatic characteristics of different distribution area of Juniperus excelsa populations in Zarghoon region (average values of 1980 - 2010)
62
Table 11. Correlation coefficients between genetic diversity and environmental variables for J. excelsa populations in Zarghoon
63
APPENDICES Contents
Appendix-A. Village level Questionnaire appendix Appendix-B. Ethnototany Questionnaire Appendix-C. SPSS calculations Appendix-D. Acceptance letter of first research manuscript by Ph.D. dissertation Appendix-E. Copy of 2nd research manuscript published by Ph.D. dissertation
1
ACKNOWLEDGEMENT I
ABSTRACT II
CHAPTER1 5
1. INTRODUCTION 5
1.1. GEO-CLIMATE OF ZARGHOON REGION: 11
1.2. PARTICIPATORY RAPID/RURAL APPRAISAL (PRA) TYPE PARTICIPATORY APPRAISAL OF NATURAL RESOURCES (PANR): 13
CHAPTER 2 16
2. LITERATURE REVIEW 16
AIMS AND OBJECTIVES 23
CHAPTER 3 24
3. MATERIALS AND METHODS 24
3.1. QUESTIONNAIRES: 24
3.2. THE PARTICIPATORY RAPID/RURAL APPRAISAL (PRA)-TYPE, PARTICIPATORY APPRAISAL OF NATURAL RESOURCES (PANR): 24
3.3. PRA TOOLS APPLIED: 24
3.4. PLANTS UTILIZATIONS: 25
3.5. ECOLOGICAL ASPECTS: 25
3.6. LOCATION: 25
3.7. VEGETATION STUDY: 26
3.8. SOIL ANALYSIS 26
2
3.9. STATISTICAL ANALYSIS 27
3.10. GENE DIVERSITY: 27
CHAPTER 4 30
4. RESULTS AND DISCUSSIONS 30
4.1. ETHNOBOTANICAL ASPECTS: 30
4.1.1. DISCUSSIONS ETHNOBOTANY: 44
4.2. CONSERVATION ASPECT OF JUNIPER FOREST IN ZARGHOON: 46
4.2.1. Discussions Conservations Aspects: 52
4.3. SOIL ANALYSIS: 53
4.3.1. DISCUSSION SOIL: 56
4.4. GENETIC DIVERSITY: 57
4.4.1. DISCUSSIONS GENE DIVERSITY: 63
CHAPTER 5 66
CONCLUSIONS AND RECOMMENDATIONS 66
CHAPTER6 72
REFERENCES: 72
APPENDICES 89
3
Acknowledgement
My deepest gratitude to the “Almighty Allah”, the most merciful, the creator and the
provider, because all it was possible only by his mercy, kindness and providence.
I am extremely grateful to my earnest Supervisor Prof. Dr. Rasool Bakhsh
Tareen, Dean Life Sciences/Research University of Balochistan, for providing me
amenities, and support during my research work.
I am gratified to my co-supervisors Dr. Atta Muhammad Sarangzai & Dr.
Muhammad Younas Khan Barozai of Botany Department, University of Balochistan,
for the provision of appropriate guidance and facilitation.
I pay my special gratitude to Higher Education Commission (HEC), Pakistan
for awarding me the Ph.D. Indigenous Fellowship Batch-IV. The HEC’s financial support
for this Ph.D. research helped me considerably and improved my work.
I thank Prof. Dr. Abdul Kabeer Khan Achakzai, Chairman Department of
Botany, University of Balochistan, for his sincere guidance and cooperation in reviewing
this dissertation and helping out in writing publications.
I am thankful to Prof. Dr. Masoom Yasinzai for the provision of his lab to
perform my research. I am particularly thankful to Mr. Yasser. M. S. A. Al-Kahraman,
from Department of Biochemistry, for his assistance and support to my lab work.
Last but not the least; I am very thankful to Mr. Shai Mazar Baloch for his
facilitation in perusal of documentations administratively.
Every effort has been made to eliminate any error during the preparation of this
dissertation, yet as in case of any human enterprise, mistake does happen.
4
Abstract The Biodiversity assessment using ethnobotanical and ecological inspection complemented by genetic variation investigation of tree Juniperus excela was undertaken in Zarghoon Juniper Forest during the years 2009-11. In contemporary study the illustrious data assortment procedure entitled Participatory Rural Appraisal (PRA)-Type Participatory Assessment of Natural Resources (PANR) was applied. PRA tools social map, transit walk, structured, semi structured interviews and pie diagrams were used. PRA was piloted in five villages as central habitat of five constellations embraced of total 17 villages in Zarghoon Juniper ecosystem.Meetings with local communities both male and female separately were conducted and PRA tool carried out using charts and markers. Ethnobotanical assessment revealed that 60%, 35% and 5% medicines were used orally, topically and boiled to inhale, respectively. Correspondingly, in case of parts of plants usage 57, 26, 10 and 7% leaves, seeds, flower and roots were used, respectively. The socio-economic condition of the area indicated local community was deficient of basic amenities of life. The dependency on natural resources was high and unplanned land fragmentation occurred as the major source of income (90%) was from agriculture and livestock rearing and only 10% income by trade, services and labor. Rate of deforestation assessed by counting cut stumps, ranged from 6.69 to 4.70/acre. Average Diameter at Breast Height (DBH) in inches above ground at 4.5 measured and that ranged from highest 37.13 to lowest as 29.40. Goat made the dominant livestock population of 75%, sheep 23% and donkey 2%. Sex ratio of J. excelsa showed predominance of male with a mean value of 103±23ha-¹ (58%), followed by female 64±51 ha-¹ (36%) while bisexual were very rare (6%).Anthropogenic pressure like lopping for timber 28%, fuel wood 56%, debarking 11% and fencing 5% of Juniper tree equally treacherous at all populations. Leaf samples of the key species J. excelsa were collected for DNA isolation as no genetic analysis was ever carried out in this area. Owing to the existence of impurities of high magnitude of secondary metabolites, a novel protocol was generated to isolate pure DNA essentially for tree J. excelsa, which exhibited rich genetic resources and diversity. Six microsatellite primers were inspected and four showed considerable polymorphic amplifications. The percentage of polymorphic bands of populations was great with a variation of 8.8% as of maximum (61.8%) at Killi Shaban and minimum (53%) at Gunda. The polymorphism decreased with decrease in cover. The genetic diversity among populations also varied greatly, from 0.1012 - 0.2012 and their order in five villages were as Killi Shaban > Killi Tor Shore > Medadzai > Sarobai> Gunda. Results revealed a positive correlation between genetic diversity and annual mean precipitation, high and low temp and soil pH, and variance in these due to climate change might intimidate the genetic diversity and resources. The traditional healers are dwindling in number and traditional knowledge is threatened and might be exterminated in near future since younger generation is least interested in it. Therefore, it is preordained to preserve the indigenous knowledge. Geographical distance and density might have sound effects on genetic relationships, because genetic diversity improved even at short distance. Existing anthropogenic pressure on ecosystem can be curtailed by regulations implementations and financial assistance for sustainable resourse utilization to the unique Juniper ecosystem of Zarghoon.
5
CHAPTER1
1. Introduction
Balochistan is the largest province, representing 44% of the land cover of Pakistan
(Tareen et al.,2010). The Juniper forest ecosystem in province Balochistan is the second
largest in the world the first being in California. It is one of the oldest slow growing
Juniper trees of the world having trees as old as 700 to 900 years, but the urbanization
and population growth are amongst the root causes of deforestation (Marcoux, 2000).
Ecologically speaking, Juniper forest is not only a rare genetic resource, but it also one of
our national and biological heritage of Baluchistan and Pakistan. These forests also
considered as one of the world’s largest, oldest, extremely slow growing and drought
resistant tree species, therefore, often termed as "Living Forest Fossil" (Sheikh, 1985).
Juniperus excelsa is found from Turkey to Afghanistan, east, and south to Iran (Fisher &
Andrew, 1995) at elevations ranging from 1500 to 3000 m. It is also found in Pakistan,
where it is fairly common by forming open forests in Ziarat Baluchistan and inner dry
valleys of the Himalayas. However, the climate at these altitudes may be marginal for the
survival of Juniper, and even small increases in climatic stress could imperil the present
status of these woodlands (Andrew & Fisher, 1996).
Balochistan has one of the largest remaining tracks of pure Juniperus excelsa
forests in the world that has global significance Most of the Juniper forests have open
canopy. Juniper trees grow very slowly with poor natural regeneration. They cover
approximately141,000 hectares. The most extensive (100,000 hectares)and best known
examples are found in Ziarat and Zarghun range near Quetta(Atta et al., 2010). J. excelsa
tree is largely acknowledged for its small establishment potential under the closed canopy
of mature parent trees. Grazed and non-grazed forests express no difference in the
abundance of new and old regeneration (Frijis, 1992; Taketay & Bekele, 1995).
Junipers can tolerate poor soils and can survive at extremely low temperature in
comparison to other forest trees. In addition, they are highly resistant and they are the last
species that abandon areas in the process of deforestation (Pamay, 1955). Within this
6
wide distribution area the juniper trees display great variety in different soils and climatic
conditions. Particularly in Juniper forest zones with extreme climatic and soil
characteristics, shoot/root ratio is fundamental for biological success. Seedlings planted
in arid or semi-arid areas should have a well-developed root system for better absorption
of water lost from the soil in shoots and leaves (Hobbes, 1980).
Juniper forests always served as an important source of wood for construction,
cooking and fuel over ages but they are subjected to over exploitation, heavy grazing and
fires; while silivi-cultural practices or other management practices are lacking. Juniper is
the most prominent type of vegetation at or above 1600 m elevation (Chaudhary, 1997).
Balochistan is a forest deficit province of Pakistan characterized by mountain ranges and
deserts, arid and extreme climate and sparse and nomadic population but is endowed with
one of the biggest blocks of Juniper (Juniperus excelsa) Forests. The socio-economic
values of Juniper Forest to the local communities are due to meeting needs of fuel-wood
energy, grazing for livestock, constructional and other timber, fencing material, bark for
thatching of huts, medicinal plants for domestic use, shade for human and livestock and
privacy of huts. Their importance for marketable produce, watershed value, conservation
value, recreation and tourism is great.
In Pakistan the field of Ethnobotany is quite a virgin. Only a few papers have been
published. Today ethnobotany is widely accepted as a science of human interactions with
plants and its ecosystems. The fundamental structure of ethnobotanical research is to
examine the dynamic relationship between human population, cultural values and plants;
recognizing that plants permeate materially, and metaphorically many aspects of culture,
and that nature is by no means passive to human action but interacted with each other.
Thus ethnobotany is more than a study of plants useful to people, for it is devoted to
understanding the limitations and behavioral consequences of human population’s action
on their plant environment. (Shinwari & Khan, 1998)
Ethnobotany was described as “The study of direct interaction between human and
plant population, through its culture each human population classified plants, while
human behavior has direct impact on plant communities with which they interact, the
plants themselves also impose limitations on humans, these mixture interactions are the
focus of Ethnobotany” (Pei, 1995).
7
The emphasis of the restoration approaches on providing alternatives to reduce
pressure e.g. Gas, coal, fuel wood from outside, construction material made of iron,
barbed wire for fencing and bricks for lining of wells. Evolving grazing management
system, de-stocking, delaying spring raising and promoting on farm fodder production
are considered as essentials for the improvement of vegetation depleted overgrazing.
Adopt try planting of Juniper and alternative tree species, control of mistletoe,
encouraging planting outside forest and other forestry, range, watershed, wildlife and
socio-economic research topics have been identified (Rao, 1994).
In recent years, the interest in rare and narrow endemic species has turned to
urgency, as more and more species dwindle toward extinction. In addition, for this group
of species predicting the amount of genetic variability in plant species on the basis of
their distribution is often not reliable, since some endemic species exhibit equivalent or
higher levels of diversity compared to their more widely distributed congeners
(Gitzendanner & Soltis, 2000).
Conservation of forests is a significance constituent of environmental policies in
numerous countries. Genetic diversity is intact quantity of innate features in the genome
of a species or a population. Populations in different surroundings and species within
populations may have different genetic characteristics (Karimi et al., 2009).
Consequently, to study genetic interactions of species within populations and
amongst populations in dissimilar environment is the substance for administration of
flora. Biotechnology involvement to affluence in scrutinizing genetic mannerisms of an
individual species in different environmental conditions is prodigious. Seedlings planted
in arid or semi-arid areas should have a well-developed root system for better absorption
of water lost from the soil in shoots and leaves (Hermann, 1964; Baer, 1977).
Despite some researchers have questioned the relative importance of genetic
information, stating that ecological or demographic issues may be more pressing (Lande
1988;Schemske et al., 1994; Avise, 2008), molecular marker shave become part of a
repertoire of tools needed to assess the amount of genetic variation in populations of
endangered species and to address the ever-increasing loss of biodiversity. Microsatellite
DNA marker is a piece of DNA molecule that is associated with a certain trait of
organism. It can be of different types like morphological, chromosomal, genetic and
8
biochemical. A specific sequence of DNA bases (nucleotides) made up of mono, di, tri or
tetra tandem repeats also called STR= Single Tandem Repeat, SSR= Simple Sequence
Repeat, SSLP= Simple Sequence Length Polymorphism. Markers are highly
polymorphic, occur abundantly and distributed evenly throughout the genome, are
typically short (less than 100bp). In addition are used in application in personal
identification, population genetic analysis and easy to detect by PCR. Microsatellites are
“junk” DNA and majority of microsatellites are found in non-coding regions of the
genome. Microsatellites may provide a source of genetic variations (Mueller &
Wolfenbarger, 1999; Savelkoul et al., 1999).
Biodiversity has three components and genetic diversity is one of the portions of
biodiversity, and therefore is significant in conservation. Conservation of forests is
important content of biodiversity conservation (Kate & Larid, 1999). Threats to the
biodiversity particularly the medicinal plants have been an increasing concern to
conservationists as well as resource users. Uncontrolled trade of wild plants, destructive
harvesting technique s, and the destruction of the natural habitats of the plants are mainly
causing such threats. The nature, extent and impact of these factors vary and so do the
degrees of threat in different places and countries. Global trade for medicinal plants at an
annually increasing rate is a major threat to the sustainability of these resources and
eventually to the biodiversity. Apart from traditional medications, medicinal plant use has
increased and diversified steadily in the last few decades, not only in cookery and popular
and modern western medicine but also in different fields that are alien to medicine, such
as the cosmetics and dye industries. In Europe alone, about 2000 plant species are traded
commercially as medicinal or aromatic plants (Lange, 1998).
Over-Exploitation of the wild stock of medicinal plants is another common
phenomenon posing a serious threat to the medicinal plants. Traditionally, medicinal
herbs have been collected and used locally. People had a small quantity of dried
medicinal herbs in store, but collection as well as use reflected the local needs only. Due
to the extension of trade relations accompanying urbanization and technological
enhancement, medicinal plants have entered trade on a larger scale. Individuals, families
or groups started to subsist on the collection of wild herbs and on the medicinal plant
trade. Therefore, medicinal plants have become a commodity and obtained an isolated
9
value that is, in many cases, no longer connected to their original function. This
development has led to reckless utilization of many medicinal plants, motivated by the
benefits of a short-term profit to be gained by exploiting the resource while neglecting all
considerations of sustainability.
Genetic erosion and changes are also causing threats to the medicinal plant species
or plant properties. Other than the natural genetic process and erosion (mutation,
speciation and evolution), humans are also inducing genetic changes by mutation.
Induced genetic changes in medicinal plants through cultivation and the development of
varieties often are intended to intensify the concentration of certain compounds.
The changes and the subsequent adaptation to the newly created conditions - unlike
in nature - take place very quickly, often within a few years. The desired results are
achieved in the beginning, but the equilibrium of the plants is often disturbed. People can
use these plants to isolate the desired substances to treat symptoms, but in the long-term,
the healing power of these plants is questionable. Moreover, genetic erosion among wild
plants is very poorly documented (Annonynous-a, 1997). There would seem to be little
doubt from theoretical considerations (Holsinger & Gottlieb, 1991; Menges, 1991) that
many medicinal plant species that have been listed as threatened, and indeed others that
have not, must be suffering from genetic erosion now, or will do so in the near future.
There is no reliable estimate for the number of medicinal plants that are globally
threatened, but they are variously calculated as 4,160 or 10,000 (Vorhies, 2000).
Increasing human and livestock population in and around these forests and changes
in the livelihood patterns from pastoral to a mix of agro-pastoral steadily started
degradation in the ecosystem. These “Old Growth” forests has started yielding its area to
the human habitation and showing signs of deterioration in the form of soil erosion and
decreasing ground cover essential for maintenance of watershed values. Besides, the
livelihood source to the local communities, these forests also play an important role in
provision of recreation facilities to the inhabitants of the province and people from other
provinces. However, the most important aspect of these forests is from the biodiversity
point of view.
The Juniper forest ecosystem has already been identified as a critically threatened
ecosystem. Taking into consideration this situation, IUCN, Pakistan has put up efforts
10
since 1998 to draw the attention of government, Communities, Civil Society
Organizations (CSOs), Non-Governmental Organizations (NGOs), media and other
stakeholders to this aggravating situation. These efforts found good response not only at
the local community levels but also at the provincial and country levels. Studies found a
wide range of scope for biodiversity conservation in forests. Different most important
valleys were selected initially as sample clusters for overall ground situation and for
sustainable management of the natural resources of the selected valleys (Anonymous-b,
2008).
It is a thought-provoking undertaking for scholar of botany and forestry to
investigate not only the knowledge of plant world, but also apply the results of the study
to biodiversity conservation and community development. One of the objectives is to
guarantee that the local natural history becomes a living, written tradition in communities
where it has been communicated vocally for many years. It is an effort alongside time,
because indigenous knowledge of the environment is threatened in the face of
annihilation of natural areas and transformation of traditional cultures.
The current study gets hold of importance by the use of Participatory Rapid/Rural
Appraisal (PRA) type Participatory Appraisal of Natural Resources (PANR). PANR is
based on PRA type where the latter is a generic term covering interactive community
participation of a general kind, while the former is topical and stands for such
participation around natural resources. The labeling of PANR is to distinguish it from
PRA as to focus local communities with natural resource. It is a methodology for
interacting with villagers, understanding them and learning from them. It involves a set of
principles, a process of communication and a means of methods for seeking villagers
participation in putting forward their points of view about any issue enabling them do
their own analysis with a view to make use of such learning (Mukherjee, 1994).
The research conducted to investigate the cultural aspects, livelihood pattern and
people behavior towards plants by the use of different tools like questionnaires, social
map, semi structured interviews (SSI), focus group discussions (FGDs), Pie-diagram etc.
of famous data collection technique called participatory rural appraisal (PRA), and
PANR. The aim of the survey was to provide an insight of different aspects of medicinal
plants use and their socio economic influence on them.
11
To date, no studies like ethnobotanical, conservation and management, and Genetic
variation of Zarghoon Juniper Ecosystem has been done in this part of country. In
addition, this study is also exceptional after the use of Participatory Rural Appraisal
(PRA) type Participatory Appraisal of Natural Resources (PANR). This study is a
complete set of biodiversity study investigating all three components that is Species
Diversity, Ecosystem Diversity and Gene Diversity. Therefore, the distinction of the
current research is that it’s an amalgamation of dry lab and wet lab interventions with the
use of PRA-type PANR. In current study an optimal and distinctive method for the
extraction of genomic DNA was used for Juniperus excelsa at the Zarghoon Juniper
Ecosystem in Balochistan, Pakistan to study the genetic variation within the population
and among the populations of Juniperus excela.
1.1. Geo-Climate of Zarghoon region:
Zarghoon region is located 20 km to the southern part of Quetta valley lies
approximately between latitude 300 39΄ N and longitude 670 15΄ E. It covers an area of
about 354 square miles out of which 86 sq miles is piedmont 101 square miles is valley
floor and the rest is mountain high land(Hunting Survey Corporation, 1960). The locality
has tremendous variation from hill top to valley bottoms and gentle slopes with grasses
scattered trees. Babri Shela is the stream along which road separates from Quetta-Urak
road. The Kacha track runs through the ridge of Kotal Narai, the Boundary flanked by
Zarghoon Reserved Forest, and Urak. This forest drains on the other side into Kotal Narai
Stream. The Zarghoon Reserved and Guzara forests have significant pressure for fuel
wood from the unrestricted occupants of Urak. High mountain peaks in the area are
Tagha (11,334 feet), Sawan Ghara (11,174 feet), Buk (10,015 feet), Chunda (9,617 feet),
Loe Tabai (9,540 feet) and Chur (9,004 Feet). The name Zarghoon is derived from a
Pushto term, meaning flourishing.
12
QUETTA
ZARGHOON ▲
KS
G
M KTS
Fig 1. Map of the Zarghoon Juniper Forest Research Area (▲) with five clusters Killi Tor Shor (KTS), Medadzai (M), Gunda (G), Sarobai (S) and Killi Shaban (KS) 20km NE of Quetta City
S
13
1.2. Participatory Rapid/Rural Appraisal (PRA) type Participatory Appraisal of Natural Resources (PANR):
Participatory Rural Appraisal (PRA) is a methodology for interacting with villagers,
understanding them and learning from them. It involves a set of principles, a process of
communication and a menu of methods for seeking villagers’ participation in putting
forward their points of view about any issue and enabling. It initiates a participatory
process and sustains it. Its principles and the menu of methods help in organizing
participation. PRA is a means of collecting different kinds of data, identifying and
mobilizing intended groups and evoking their participation and also opening ways in
which intended groups can participate in decision-making, project design, and execution
and monitoring. PRA is sometimes known as Participatory Rapid Appraisal where
emphasis is on both ‘Participatory’ and ‘Rapid’. The labeling of PANR is to distinguish it
from PRA as to focus local communities with natural resource. It is a methodology for
interacting with villagers, understanding them and learning from them (Chambers, 1991).
Indigenous Knowledge and its Sources
Before discussing the methods it is important to identify the indigenous knowledge
sources which are available in rural areas. These sources are a rich repertoire of culture,
practices, beliefs and approaches for understanding and appreciating rural people.
Learning about rural knowledge base from different sources can be an important aspect
of a PRA exercise. Several methods can be combined in different ways in order to
analyze issues at hand and conduct an appraisal of the subject under consideration. Some
major methods have been described below along with illustrations taken from field
situations. In this study; the following PRA methods were applied:
Maps and Models
Participatory mapping is crucial to PRA and can be on different aspects of rural life
such as social issues, resource, health, wealth, literacy, census, livestock, economic
activity, social stratification, forms of livelihood etc. such maps can portray the image of
dwellings in a village, of farms and fields, water collections, forests, soils and of many
other aspects depending on the topic under consideration. In participatory mapping and
modeling, villagers prepare the map/model of their village with chalks, colors and other
materials either on ground or on paper.
14
It is a rich tool and is commonly used in PRA. It has enormous potential. Maps by
villagers provide a basis for knowing different aspects of a village. A village resource
map can also show different kinds of natural resources and micro environments. In a
resource map, the villagers draw the resource profile of the village depicting different
kinds of soils, rivers, ponds, trees, crops and micro environments.
Transect walk
Participatory transect walks systematically involve walking with the villagers
through an area and discussing about different aspects of land-use and agro-ecological
zones in the village observed during the walk. A transect walk is a useful method for
knowing rural ecological condition. A walk from one point of the village to another
enables the outsider to observe different aspects of rural ecology and to discuss with rural
people about soil condition, land-use patterns, crops, livestock, micro environment, agro-
ecological zones etc.
Seasonal Diagramming
Rural livelihoods are integrally connected with seasonality. Each season has its own
problems and the rural people have different strategies for their livelihoods. The seasons
bear heavily on the physical conditions which in turn influence their lives. Seasons bring
about differences in climatic conditions, in crops frown, in availability of water, food,
fuel and fodder which in turn influence the living conditions in rural areas. Seasonal
diagramming can lead to comparisons of related aspects of rural livelihoods such as
seasonal variations and their linkages with food, employment, work load, disease, etc.
Different aspects of rural life can be reflected through seasonal diagramming. A
method which reflects the seasonality, aspect of some other method such as a
questionnaire survey taken at two different points of a year. In the latter case, the
‘seasonality’ aspect can either be neutralized through ‘averaging’ or conclusions can be
drawn on the basis of a partial picture for one season.
Mobility Map
This shows the pattern of spatial mobility for different sections of a community with
respect to different activities. Patterns of group mobility of rural people can emerge from
individual maps. Mobility maps of rural people based on socio-economic aspects, gender,
age groups and other criteria can indicate the nature of work, wealth, interaction with
15
outside world and interaction within communities and with other communities in a
village. It shows the degree of mobility of rural groups and communities and importance
of different areas in terms of their different activities. It also indicates location-specific
activity profile.
Pie Diagram
Pie diagrams or pie charts indicate parts of a whole in proportional terms. It can
show the use of land, water, credit and patterns of income, consumption and expenditure,
sources of debt, medicines, kinds of trees etc. in lives of rural people. It shows that the
proportion of land used for agriculture differs from season to season depending on the
climate, availability of water and the nature of crops grown. Pie diagrams show the
importance of relative items in the lives of rural people. In this case, the proportion of
land used for agriculture also indicates the seasonal hardship of the farmer in terms of
livelihood.
Livelihood Analysis
One application of pie diagram can be for analyzing livelihood through the help of
pie-charts. This depicts the behavior and adjustment strategies of households with
different socio-economic characteristics. Each household has strategies to copy with
difficult situations which arise from time to time. Such analysis can account for the size
of the household, age and gender composition, wealth, assets, livestock, income and
expenditure patter, debt pattern, consumption pattern, seasonality, income by sources,
disease and social obligations.
16
CHAPTER 2
2. Literature Review
Hocking, (1958) wrote a series of papers in medicinal plants of Pakistan and
included some information on Balochistan. Ahmed (1956) listed 356 medicinal plants
found in Pakistan, with their vernacular names and medicinal uses. Noy-Meir (1973)
observed that unpredictable and highly variable amounts of precipitation in arid
ecosystems are limiting to primary plant productivity. However when water is available,
the productivity may be influenced or limited by other factors such as soil and air
temperature, herbivory, microflora activity and soil nutrient availability.
Zaman and Khan (1970) listed 100 drug plants of West Pakistan. Ikram and Hussain
(1978) presented a checklist of 171 medicinal plants, their part(s) used, local names.
Ettershank et al., (1978); West and Skujins (1978); Sharifi et al., (1990) suggested that
nitrogen is generally considered to be the second most important factor limiting growth in
warm desert ecosystem and play a major role in determining productivity under
conditions of adequate water supplies. Beadle and Tchan (1955) concluded that nitrogen
is most limiting factor of arid and semi-arid regions of the world. Other factors such as
phosphorus interact and confound the relation between available nitrogen status and
growth, because nitrogen, primary control over the fertility of the soil, biological
mechanism responsible for nitrogen fixation are controlled by available soil moisture and
it is strongly correlated with climate. Mooney et al., (1981); Egli and Schmid (1999)
observed the effect of leaf age on leaf nitrogen content with younger leaves having high
nitrogen contents than older ones.
Koniak and Everet (1982) found that species diversity tended to decrease from
grass-forb, shrub-tree, tree-shrub to tree dominated sites. Detecting no change in diversity
may be a result of seeds that persist for long periods of time in the seed bank.
Kartha (1985) assumed that the meristem have a significant place in domain of plant
tissue culture due to its role in clonal propagation as well as in the production of virus
free plants. Moreover it is less differentiated and genetically more stable which makes it
ideal system for germplasm preservation.
17
Lande (1988) have questioned the relative importance of genetic information,
stating that ecological or demographic issues may be more pressing molecular markers
have become part of a repertoire of tools needed to assess the amount of genetic variation
in populations of endangered species and to address the ever-increasing loss of
biodiversity.
Van der Valk and Peterson (1989) reviewed the possibility of exploiting seed banks
for management purposes (including restoration) and made three simple but important
points. First, if management is to be successful, the seeds of desired species must be
present in the seed bank. Second, undesirable species should be in low abundance and
third, the proper environmental conditions for successful germination and establishment
of desired species should be met.
Walser et al., (1990) observed that temperate zone woody plants have the ability to
acclimatize during the fall season and thus withstand extremely cold winter temperatures.
Smith and Smith (1989) concluded that aridity, cold temperature, short growing season,
long periods of drought and low nutrient supply favor shrubs. In certain environments
shrubs have many advantages. Shrubs invest less energy and nutrients in above ground
parts than trees. Their structural modifications improve light interception, heat
dissipation, and evaporation. The multi stemmed forms of shrubs influence interception
of moisture and stem flow, increasing or decreasing infiltration in to the soil, because
most shrubs can get their roots down quickly and form extensive root systems, they use
moisture deep in the soil. This feature gives them a competitive advantage over trees and
grasses Smith and Smith (1989). Ueckert (1985) suggested that many of the shrubs that
were valuable as fodder for livestock and for wildlife are almost eliminated in many areas
by continuous yearlong grazing by cattle, sheep and goat. Therefore, the shrubs are
suitable, because they produce more biomass than other plant groups such as annual and
perennial grasses during periods of environmental stress, the level of production may not
be sufficient to sustain a consistently high level of uses.
Martinez (1992) reported 50 plants used by the rural community of the Distrio
Federal, San Lorenzo Acoplic, Cuajimalpa, Mexico. Medicinal and food sources were
commonest uses.
18
Schemske et al., (1994) have questioned the relative importance of genetic
information, stating that ecological or demographic issues may be more pressing
molecular markers have become part of a repertoire of tools needed to assess the amount
of genetic variation in populations of endangered species and to address the ever-
increasing loss of biodiversity.
Al-Jaloud et al., (1994) mentioned that the phosphorus content of plant tissue
declines with increasing maturity, and the rate and extent of decline varies with species.
Davis et al., (1995) obtained the information on traditional veterinary medicines and
practices from interviews with Pashton Nomades (Koochi) refugees (17 women and 18
men) from Afghanistan and in around Quetta in Pakistan in 1992. The main animal
diseases encountered and medicines to treat them were listed.
Mash (1995) reported 65 plants (including tree species) used by tribal and forest
dwellers in Madhya Pradesh. Thirty three species used as edible, 8 species as oil and oil
seed producing plants; 10 species for gums, resins; 6 species as dye plants; 10 species
used for cordage and basketry; and 8 species associated with socio-religious ceremonies.
Ravishankar (1995) discussed the ethnobotany of India with regard to the tribal
people’s knowledge of the edible, medicinal, fodder and agricultural value of forest
plants.
Flores and Vermont (1996) conducted an ethonobotanical survey among traditional
communities of the Yucatan peninsula region of Mexico and also in Guatemala and El
Salvador. Two hundred and seventy four species were listed as medicinal and only
exudates of 48 species were used to cure human affections.
Johnston and Colquhhoun (1996) carried out a preliminary assessment of the
utilization of forest plant species within an American community at Kurupukari, Guyana.
One hundred and twenty species of 46 plant families covering 264 different uses were
identified, 64 species for medicinal, 53 for ethnological, 43 edible, 20 for timber, 14 for
construction and species with miscellaneous uses.
Jovel et al., (1996) documented 60 plant species used for medicinal purposes among
the Mestizo people of Suni Mirano. Some cultural data on traditional healing and
ethiology were also collected.
19
Longuefosse and Nossin (1996) carried out ethnobotanical survey amongst the
population of Martinique. About 100 people (average age 69, 80% were women) were
interviewed and 261 plants were reported as medicinal plants to be used for particular
diseases.
Shinwari and Shah (1996) carried out an ethnobotanical survey of Kharan district of
Balochistan province. They reported 171 species of Angiosperm belonging to 130 genera
and 44 families. Among these 26 species had medicinal importance, 27 species as food
and house making purposes. Ten wild species as fodder while 44 common weeds of
various crops identified.
Boruah et al., (1997) reported four species of edible, fleshy fungi used by local
people of NE Index. Calvaria coiner, C.aura were collected from Nongpoh (Meghalaya)
while Lepidium procera & Termitomyces robustus were collected from Charaibahi areas.
Figueireds et al., (1997) worked on the ethnobotany of the community Calhas
Beach Jaguram Island, during which 42 adults were interviewed. They observed that old
islander had deeper knowledge of medicinal plants than younger.
Gupta et al., (1997) carried out a medico-ethnobotanical survey among the
inhabitants of Padera forest (Andra Pradesh, India). They reported 16 plants, which were
used in medicine.
Gurib et al., (1997) carried out a survey of the medicinal plants of Mauritius.
Healers and lay people who use medicinal plants were interviewed. Four hundred and
sixty one plants were identified and listed in alphabetically order of Latin name,
vernacular name, parts used, medicinal properties/diseases treated and chemical
constituents.
Pal and Jain (1998) carried out an ethnobotanical survey among the following ethnic
groups; Lodha, Munda, Oraon and Santal. They documented 343 tribal medicinal plants
(Latin name, common name, tribal name, morphology, flowering & fruiting periods and
distribution) and >2000 prescriptions, for prevention and treatments of ailments and
diseases of human and pets. They described the uses of plants as a source of narcotics,
hallucinogens, beverages, poisons, pesticides and in storage of grain.
20
Reddy et al., (1998) conducted an ethnobotanical survey on plants used for
veterinary purposes, during 1998-96 in Andhra Prasdesh, India. Both tribal and non-tribal
peoples were interviewed. Forty-eight medicinal plants were tabulated with Latin, family
and vernacular names, part(s) used, preparation/administration and medicinal uses.
Roodt (1998) reported the medicinal uses and nutritional value of the trees and
shrubs of the Okavango delta. The species included are all indigenous and were chosen
because of their abundance, unique appearance or economic, spiritual or medicinal
importance.
Singh and Pandy (1998) described 610 plant species from Rajastan, India as:
botanical and local names, plant morphology and habitat, distribution and tribal uses
(medicine, food, timber, fodder, firewood, tannin, dye, oil, fiber, alcohol, gum, resin and
religious uses). Information was also provided on plants mentioned in folk songs and
proverbs or used as landmarks or in musical instruments as well as those associated with
superstitious.
Adams (1999) explained that the most surprising aspect of his research has been the
divergences of morphologically near-identical taxa in their terpenoids and DNA
fingerprints. He showed that even species separated by minute morphological character
differences possess considerable terpenoid and DNA differences, which suggest that
evolution proceeds at different rates for different character sets
Khan (1999) reported 22 genera belonging to 15 families from Chindwara district
(M.P.) India. Many of the medicinal plants were most frequently used by the locals for
diseases such as bleeding piles, kidney stone, malaria, diarrhea and abscess.
Chambers et al., (1999) reviewed the reproductive ecology, seed dispersal, post-
dispersal seed mortality, seed dormancy, seed germination requirements, and seedling
establishment of pinyon and juniper species of the western US. Included were seed and
seedling fate diagrams that helpedto put seed bank dynamics into perspective. Further
research in this direction would significantly advance the knowledge base and modeling
capacity of the field of vegetation science.
Shinwari and Khan (1999) described the multiple dimensions of ethnobotany and its
present status in Pakistan.
21
Savelkoul et al., (1999) concluded AFLP a promising tool in providing a very large
number of polymorphic markers with a very fast and relative simple laboratory work
Mueller and P.H.M. (1999) Concluded AFLP is an effective tool and large no of
polymorphic bands can be easily obtained using this tool.
Hsiang and Huang (2000) used Random amplified polymorphic DNA (RAPD)
markers to assess differences among Juniper and Cedar cultivars.
Gitzendanner and Soltis (2000) predicted the amount of genetic variability in plant
species on the basis of their distribution is often not reliable, since some endemic species
exhibit equivalent or higher levels of diversity compared to their more widely distributed
congeners.
Osem et al., (2006) examined the effects of grazing on the similarity between
species in the seed bank versus established vegetation. Peak-standing biomass of annuals
was used as a measure of annual productivity. They concluded that at low levels of net
primary productivity (as measured by peak standing biomass) where soil water and
nutrients are limiting, the relationship between seed bank to standing vegetation
similarity is positive. At high levels of net primary productivity, where space and light
are limiting, the reverse is true. Above this range soil resource availability is no longer
the factor limiting plant density. It was hypothesized that grazing encouraged recruitment
from the seed bank 6 by diminishing vegetation cover and litter accumulation that could
constrain germination, seedling emergence, and plant survival.
Allen & Nowak (2008) found that seed bank density and species diversity did not
differ between high, medium, and low Pinus monophylla/Juniperus osteospermac over
treatments. This is in agreement with second year findings. Reasons for the disparity
between these studies are unclear. Site dissimilarity and temporal variation in seed crops
related to climatic conditions are possibilities.
Avise (2008) have questioned the relative importance of genetic information, stating
that ecological or demographic issues may be more pressing molecular markers have
become part of a repertoire of tools needed to assess the amount of genetic variation in
populations of endangered species and to address the ever-increasing loss of biodiversity.
22
Atta et al., (2010) reported Juniperus excelsa (DC.) M. Bieb. (Cupressaceae) is
long-lived tree that provides many benefitsto regional ecosystems and local economies of
surrounding communities. However, relatively little isknown about the insects, diseases
and other factors that affect the health and productivity of Juniperforests in Ziarat district
of Balochistan Province, Pakistan.
Derwich et al., (2010) reported medicinal value and effectiveness of Juniperus
specie against many bacteria. In this study, the essential oils of J. phoenicea collected
from Atlas median in the region of Boulmane (Morocco) were obtained by hydro-
distillation of the aerial parts and analysed by gas chromatography equipped with flame
ionisation detector (GC-FID) and gas chromatography coupled to a mass spectrometry
system (GC/MS) for their chemical composition. Their antibacterial activity was studied
in vitro on seven bacterial strains: Escherichia coli, Staphylococcus aureus, Staph.
intermedius, Klebsiella pneumonia, Pseudomonas aeruginosa, Bacillus subtilis and
Streptococcus mutans. Twenty tree compounds were identified in leaves oil representing
81.87% of the total oil composition.
Douaihy et al., (2011) reported high levels of genetic diversity at species and
population levels in the high-mountain Lebanese Juniperus excelsa populations.
Biodiversity assessment is an important first step to evaluate the health of an
ecosystem and develop management and conservation measures. This comprehensive
biodiversity study covers evaluation of diversity of species, ecosystem, and genes. Study
is performed in Zarghoon area of Balochistan, Pakistan. Participatory Rural Appraisal
(PRA) type approach is used to assess the socio-economic conditions in the study area
and to document the medicinal use of juniper ecosystem. Genetic variation of Juniperus
excela is evaluated using DNA technique. The novelty of this research stems from the
fact that it is the first attempt to perform genetic analysis in the study area. The issue of
presence of impurities in the DNA is addressed using a novel technique to isolate pure
DNA.
23
Aims and Objectives The aim of the study is to bring sustainable utilization of natural resource. The core
objectives of the proposed research work are as under:
Information collection with different stakeholders through Participatory Rural
Information (PRA) for identification and role of traditional believes in conservation,
economic, medicinal and traditional use of common trees and shrubs.
Collection and preservation of Common trees and shrubs for identification in need of
urgent conservation by using Ethno botanical knowledge and placing
recommendations.
Nutrient concentration in soil and rain water and physical parameters like stream
conductivity, dissolved oxygen percentage and temperature of different watershed
will be analyzed to observe the effect of deforestation.
The first ever attempt to analyze DNA in this area, DNA extraction, and use of
Polymerase Chain Reaction (PCR) amplifications and using microsatellites to assess
the genetic variability due to climate change between populations and within
population of (Key ecosystem species Juniperus excela).
Assessing impact of soil physical and chemical characteristics to observe its
correlation floristic diversity and genetic diversity.
Observing the impact of ecological factors and possibly the climate change depending
upon the obtainable flair on the genetic diversity and genetic relationship of the
traditional use of common trees and shrubs.
Overall, this research work will be helpful in understanding the ethnobotanical
information, first ever gene diversity in Zarghoon ecosystem and conservation problems
of the world’s unique ecosystem known and associated common trees and shrubs,
medicinal plants in Zarghoon. The current study will also invoke awareness concerning
the importance of all three aspects of biodiversity.
24
CHAPTER 3
3. Materials and Methods
3.1. Questionnaires:
Two categories of Opinion polls (Questionnaires, Appendices-A&B) were
established. (i) To assemble information relating to the information about the usage
plants of the area. (ii) To amass socio-economic facts and figures of the region.
Every single determination was made to articulate a comprehensive easy going, and
efficient questionnaires which were pre tested for the exploration. The motivation of
designing the Questionnaires was to discover the factual conceivable depiction of the
ethnobotanical study and socio-economic situations and livelihood configuration of
Zarghoon Juniper Eco system.
The first Questionnaire was completed through discussions and dialogues and the
second Questionnaire was filled by the researcher through conducting calisthenics (like
Social Map, Pie Chart) of PRA in community consultation. Meetings with local
communities both male and female separately were conducted and PRA tool carried out
using charts and markers.
3.2. The Participatory Rapid/Rural Appraisal (PRA)-type, Participatory Appraisal of Natural Resources (PANR):
The Participatory Rapid/Rural Appraisal (PRA)-type, Participatory Appraisal of
Natural Resources (PANR) was used for ethnobotanical study of Juniper Zarghoon
Forest.
3.3. PRA Tools Applied:
The contemporary study was heading to scrutinize the cultural traits, livelihood
arrangement and people behavior towards plants by means of different tools like
questionnaires, social map, semi structured interviews (SSI), focus group discussions
(FGDs) etc. of famous data gathering technique entitled participatory rural appraisal
(PRA), and PANR. The use of tools was initiated to assess insight of different aspects of
medicinal plants use and socio economic influence on them. The team of six members
25
comprised of both male and female. The notables were communicated to acquire the
access point. There are 17 villages in Zarghoon area and five constellations were
prepared each representing community members from 3 villages. PRA was conducted in
five villages named Killi Tor Shore, Medadzai, Ghunda, Sabozai and Killi Shaban each
as central place of five clusters comprised of total 17 villages in Zarghoon Juniper
ecosystem. Enthobotanical information was collected from various villages of the
Zarghoon, elders and key informants were met from whom enquired the information
about which the local people were accustomed with the traditional uses of wild plants for
ethnobotanical initiatives. Various native therapists were interviewed in this regard.
3.4. Plants Utilizations:
This ethnobotanical study was applied to prioritize the medicinal plants in need of
crucial conservation by using Ethno botanical knowledge and assigning
recommendations.
3.5. Ecological Aspects:
In Juniper forest surrounding five villages a total of 15 plots each of 2 acre at the
rate of 3 plots per forest locality were positioned indiscriminately. In each and every plot
the density of mature trees, the individual ground cover of new regeneration seedlings up
to the height of 5 inches and old regeneration saplings up to 5ft were measured, (DBH)
Diameter at breast height, and manmade deforestation of mature trees was documented.
Average ground cover percentages of Old and New Regeneration, sex ratio were
calculated for each location. Deforestation was calculated by counting the number of
stumps present in each plot.
3.6. Location:
Ten stands occupying comparatively undisturbed area of Zarghun Juniper
ecosystem were premeditated. Around the study area 10 stands were sampled using Point
Central Quarter method of (Cottam & Curtis, 1956) for juniper tree population while
Circular plot method (1.5 m radius) was used for sampling of the associated vegetation.
At each stands 15 points were taken at 30 meter intervals along transect in a stratified
26
random way over an area of at least 3 ha (Ogden & Powell, 1979). GPS was use to record
elevation, position of stands, and aspect while degree of slope was recorded by the help
of slope meter. Plot sampling quadrate Pol= number of stands in which species occur,
RF2 Mean relative frequency with standard deviation, FR3=Range of relative values
were calculated.
3.7. Vegetation Study:
After reconnaissance, regular field trips were organized throughout harvest season.
Plants specimens of common trees and shrubs were collected and their uses by the local
inhabitants were inquired. Later on, these specimens were identified as Identification of
plants was confirmed by Flora of Pakistan (Nasir & Ali, 1970-1979, 1980-1989; Ali &
Nasir, 1989-1992 and Ali & Qaiser, 1993-2009). Subsequently, deposited in the
Herbarium Botany Department, University of Balochistan, Quetta. Interviews of 120
informants including local inhabitants, and Pansaries (local herbalists)were conducted on
random bases. Questionnaires were implemented for interviews. The outcome of the
results were rechecked and compared with literature. Analysis of the data was carried out
and indigenous knowledge was documented.
The data were coded, categorized and fed in computer and analyzed using computer
software packages MS Excel and SPSS (Statistical Package for Social Science) 11.5
versions. Quantitative data were analyzed by simple statistical tools such as frequency,
mean, percentage, standard deviation and range and qualitative data information and
attitudes were analyzed by ordering, ranking with descriptive manner. The impacts of
various socio-economic factors such as education status, ethnicity, and land holding size,
number of livestock and source of income on the diversity of farm trees were analyzed by
using SPSS. The results are presented through text, Tables and Figures with interpretation
accordingly.
3.8. Soil Analysis
Three soil samples from each location of five habitats were collected at 0-25cm
depth and evaluated for their physical and chemical characters. Samples were dried,
sieved and soaked paste were prepared with distill water and filtered, filtrate were used.
27
pH of soil saturated paste was used by using glass electrode (pH 3305 Jenway). Soil
texture was calculated by hydrometer (Bouyoucos, 1962). NPK concentrations were
measured by using Hanna Quick pH/NPK Soil Test Kit.
3.9. Statistical Analysis
Result were expressed in means and standard error of means (Means ±SEM). Mean
value and standard deviation of elemental concentrations and other treatments were
subjected to analysis of variance (ANOVA). Level of significance was checked at 0.05
levels. Data was recorded in pre-designed performas for each plot independently and
subjected to statistical analysis ANOVA by using SPSS (Appendix-C).
3.10. Gene Diversity:
DNA Isolation Protocol
Fresh Leaf samples were used for DNA isolation by the modified PVP method
(Duffy, 2009) sowing to its appropriateness to Juniperous excelsa. 8g of leaf sample from
each tree were pulverized in liquid nitrogen and grinded using pestle and mortar. 8 ml of
CTAB was added then mixed with 20ml extraction buffer containing PVP and (300 m M
NaCl, 30 mM EDTA, 0.5% SDS, 250 mM Tris–HCl pH 8.0). 1.5ml eppendorf tubes
were filled with it and mixed by vortex and incubated for 1hour at 60°C.and centrifuged
at 12,000 rpm for 15 min at RT (room temperature).
The decantation of supernatant was carried out carefully and it was poured into new
eppendorf tube using micropipettes. add 700microliter(µl) of Phenol: Chloroform:
Isoamlealcohol (PCI:25:24:1, v/v/v) in each tube to precipitate DNA and mixed the
solution using vortex and centrifuge for 15min at 12000 rpm on -4°C. Repeated the PCI
precipitation once again. That turned the color of pellet from brown to white and
removed waste from DNA. Then took supernatant into empty tubes and added twice the
volume of sodium acetate and kept overnight at -20°C. Next day centrifuged the tubes for
10min at 12000rpm on-4°C. The pellet was then washed with 70% ethanol and air dried.
Later on added 30 µl deionized water in each tube and kept at -20°C.
28
Basic Modified Method of Gel Electrophoresis
The DNA was ready for gel electrophoresis. The TBE solution was prepared and
40ml of 0.5X TBE was taken in a conical flask of 50ml. 1% Agarose powder (0.4gm)
was added and heated in oven for 2min. Ethedium bromide (3µl) was added. DNA
concentration and purity was determined by running the samples on agarose gel and
nucleic acid concentration was calculated following (Sambrook et al., 1989), but
modified according to the nature of species used. The modifications included the change
of agarose percentage at 1% instead of 0.7%.
The amount of DNA used in previous methods revealed two problems high amount
of DNA loaded appeared to run fast and size appeared wrong whereas, DNA loaded in
small amount was not visible and bands were indistinct. Therefore, the amount of DNA
loaded on gel was changed and took around 5 (µl). The loading buffer gave color and
density to the sample, when added 1.5µl of Bromophenol blue (dye) to load into the wells
with ease. The dyes and DNA moved from positive to negative charge that allowed
monitoring the progress of the gel. Finally the accurate voltage was established to be 85-
100 V for 25 min. below or above the mentioned range of voltage and time gel
electrophoresis of this species of this meticulous region was not possible.
Gel was visualized under UV light in gel documentation and quality and quantity
was estimated. Polymerase Chain Reaction (PCR) amplification with given quantity,
Time, activity and temperature of Genomic DNA initiated in PCR amplifier done
(Tables. 1-2).
Table 1. Quantity of Buffer extraction used for PCR amplification.
S.No. Reagents Quantity Concentration
1 DNA (Sample) 1 L 50ng / L 2 PCR Buffer 2.5 L 10X 3 MgCl
2 2.5 L 25mM / L
4 dNTPs 2.5 L 2.5mM / L 5 Forward Primer 1 L (Each) 10 mM / L 6 Reverse Primer 1 L (Each) 10mM / L 7 Taq Polymerase 0.1 L 5U / L 8 Deionized Water 14.9 L NIL
29
Table 2. Time, activity and temperature of Genomic DNA initiated in PCR amplifier
S.No. Activity Time Temperature
1 Initial Denaturation 4 min 95°C 2 Denaturation 30 Sec 94°C 3 Annealing 45Sec 37°C 4 Extention 45Sec 72°C 5 Final Extention 10 min 72°C 6 Store ∞ 4°C
Nuclear simple Sequence Repeat markers (nSSR) markers Jc016, Jc031, Jc032,
Jc35, Jc37, and Jc166 (Michalczyk et al., 2006) were used to analyze polymorphism in J.
excelsa, these markers were formerly established for J. communis. Jc016 did not exhibit
any polymorphic bands for J. excelsa while the rest of four showed significant
polymorphism when adapted for J. excelsa.PCR products were genotyped with ABI
prism 3130xl genetic analyzer. Statistical analysis for calculation of observed and
expected number of alleles, alleles frequency, expected and observed heterozygosity,
expected and observed homozygosity, F- statistics, dendrogram based on Nei’s genetic
distances using UPGMA and Polymorphic Information Content (PIC) was carried out by
using software “POPGENE 3.31 & POWER STAT”.
30
CHAPTER 4
4. Results and Discussions
4.1. Ethnobotanical Aspects:
The use of Participatory Rapid/Rural Appraisal (PRA)-type, Participatory Appraisal
of Natural Resources (PANR) resulted given results of Juniper Zarghoon Forest. In
addition, two categories of questionnaires (Appendices-A&B) were also used.
The native community of the area belongs to the tribe Dommar, distributed into 2
sub tribes of Shabozai and Nethozai which are further alienated into five coteries of
Daywarzai, Nokerzai, Paozai, Barazai & Sirkosy and two clans of Daulatzai, & Sutrani
respectively. Each tribe is further divided into families or sub tribes like Barazai into four
families of Sammerzai, Dadu, Jangi & Barai, Naukarzai into four families of Pakarzai,
Shawazai, Ghaibizai & Dalian, Piozai into three families of Piozai, Mirzagai &
Sulernanzai, Daywarzai into seven families of Shobazai, Haibatzai, Umerzai, Akhterzai,
Sheikhan, Boragai, & Khaddar khail Sardar is head of the area, while each clan is
commanded by a Malik.Sheikhan, the secular frontrunners are also inherent in the area
and have certain rights in the forests and land resources.
The noticeable Sardars and Maliks of different sub tribes in the area are Malik Essa
& Sardar Tariq of Piozai tribe, Sardar Sawal Khan of Barazai trib, Malik Pakar, Malik
Haji Muhammad Akbar Khan & Malik Adam of Naukarzai tribe, Malik Sahib Khan of
Daywarzai tribe and Malik Doosmal of Daulatzai tribe.
About 55 years ago, a few families, belonging to Sooren Khel, Bandazai and Naseer
tribes migrated in and got settled in Zarghoon Garh. They purchased some land from
Dommar tribe. They procured some property from Dommar tribe. They are called
Kharootis. Although the Kharootis have properties in Zarghoon Ghah (Mountain) yet
have no rights in the forests and communal lands.
Origin:
During the 14th century, Dommar tribe was forced to migrate from Central Asia and
Afghanistan. They got settled in Zarghoon Garh. According to their history they fought
against Mughals and defeated them.
31
Population:
More than 20,000 people live in the Zarghoon area in 640 households distributed
over 17 Villages (Killis). Average household size is 15.6 with 5 as minimum while 60
maximum. Prominent villages are Killi Tor Shore, Killi Shaban, Killi Tariq Abad, Killi
Bridge, Killi Sarki Kach, Killi Kar Kana, Killi Loi Zawar, Kill Shahabzai, Killi Dillow,
Killi Soi Khan, Killi Sarobai, Killi Dalwani, Killi Kharotan, Killi Jilgah, Killi Sarkosy
and Killi Kala Ragha.
The community is semi nomadic in nature. During the heavy snow fall season, the
road becomes blocked disturbing the supply of food stuff. Food for livestock also grows
limited and survival turnout to be difficult. Maximum people thus migrate to warm places
in Hernai and Sibi along with their livestock. Migration, since a local tradition, is socially
accepted and is also good ecologically as the pressure on the upland pastures decreases,
which ensures accessibility of some food to the local wildlife species.
In the late spring the people arrive back along with their livestock and reach upper
pastures for grazing their livestock. Some families are perpetually established in the area
specifically those who have no or limited livestock. They do not migrate to other places
in winter.
Social amenities (Health, Electricity, Roads):
Zarghoon is linked with Quetta by a grime road. The road construction was started
in 1995 by the Pakistan Army as a consequence of an agreement between Army and local
communities. This road links 12 villages, out of 17 to the main road. According to the
agreement, 5500 acres of Guzara forest land has been handed over to the army in lieu of
the road facility. The contract does not confine the Pakistan Army to any definite use of
the road.
Although three primary school buildings exist in Killi Tor Shor. Killi Ullah and
Killi Sirki Kach, but none has a teacher to teach. A small number of families can manage
to pay for education for their children exterior the valley. The literacy rate is thus awfully
low, and reckons below 5% for males and 1% for females.
Health facilities are not available in the entire Zarghoon area. A dispensary building
is being constructed in Killi Tor Shor, nevertheless there is no dispenser or health
attendant to work yet. There is no lady health visitor obtainable in the valley to provide
32
basic support to expecting women. Because of poverty, and its inaccessibility, inadequate
number of people can afford to take their women to hospitals in Quetta.
Women Status:
In Zarghoon Garh women are not only responsible to take care to household
activities including child care but also require assisting their men in various agriculture
practices and livestock tending. Apparently Women have no say in family decisions and
have diminutive awareness concerning their environment. However, it is believed that
some of them have tremendous knowledge about various medicinal plants and their uses.
Religion, Traditions, Culture and Disputes:
The local communities of Zarghoon Range are Muslims. They wear Shalwar
Kamez, waist coat and Turban. More than 90% of local communities are Pashtoon.
Speaking Pushto while the rest belong to a Baloch tribe speaking Brahvi.
Marriages within own family is a routine except in cases where parents see an
attractive future for their sons/daughters. The bride's father takes a dowry in range of
Rs.30, 000 to Rs.200, 000 depending upon the financial status of the bridegroom's family.
A lunch is offered to the community members by the bridegroom's family. The
community has a joint family system.
The local community of Zaghoon Garh is very hospitable. According to their
traditions they provide protection to people, who have any family problem elsewhere and
wish to seek refuge in Zarghoon to escape any revenge, including murder.
There are no big tribal disputes in the area amongst the Dummar tribe as is the case
in other tribal areas of provinces Balochistan & Khyber Pakhtonkua (KPK). Occasional
or accidental disputes arise among the local community, mostly on rights and ownership
of land, livestock grazing areas and wood collection. Like other tribal areas in Pakistan,
the people of Zarghoon get their disputes settled in general meetings headed by the Chief
of the area, called Maliks and Sardars. These meetings are known as Jirgah in a tribal
Society. If the Jirgah fails to reach a decision for the dispute, the matter is then taken to
the civil courts. However, this is quite rare the people of Zarghoon are quite peaceful.
Ownership:
Almost each family of Dummar tribe own land within and around the Zarghoon
mountain range. The low lands are being owned individually or by families while rights
33
exist for all in the forests to graze their livestock and collect fuel wood. Based on the
information, collected from the local people, the following tribes have ownership and
rights in the area:
Daywrzar tribe own land at Valla.
Barzai tribe own land at Tore Shore.
Daulatzai tribe own land at Ghauri, Baranai, Karkarah, Nargasai, Shahmir, Chalak,
Howt, Tal, Maghzai.
Naukarzai tribe own land at Shaban, Sirki Katch.
Paiozai tribe own land at Tore Shore and Shakai.
Moreover, the entire tribe owns a communal agricultural land in 'Sarobi" which is
rain fed. Wheat is normally grown here. In addition to it, they also have rights in the areas
of Margat, Ozghar, Ghaibi Garh, Watch kan, Lound, Lakari, Sinzlai, Tarangah, Hassan
Khan, Maghzai and Bukh.
The communal lands in the foot hills of Zarghoon Garh have not yet been settled
and distributed among the individual community members. This is because of some
minor disputes on the ownership and, secondly, for no urgent need for land.
Existing Rights:
An area of 28,956 acres of Zarghoon was declared reserved in 1890 and 34,430
acres of Tor Shor notified in 1911 through an agreement with the local community.
However, the community was allowed to continue exercising their rights of grazing and
dry wood collection.
According to a rough estimate, Zarghoon range is spread to the north south for
about 50 Km. and to the east west for about 100 km. Local community have rights to
graze livestock in 1/3 of the area and collect dry wood and leaves for their use. The
Balochistan Forest Department is responsible for the protection of forests in Zarghoon
which is done through four forest guards who belong to local community. The forest
Guards are allowed, in addition to their salary; to also graze their livestock from May till
the snow fall season.
According to the provisions of the Balochistan Forest Act, tree cutting in reserved
forest of Zarghoon is not allowed, nonetheless due to several reasons, these rules and
34
regulations of the Forest Act are not being implemented properly. Green trees are still cut
down by the local communities to fulfill their cooking and heating needs. The forests are
not being protected properly. People still cut a large number of trees to meet their
domestic demands for fuel wood. Commercial logging is also going on.
There are a few forest patches which are quite unharmed and support decent forest
cover. These sites are known as Oblun, Rode, Narai, Shero Gaza, Lanai, Shakai, Girgai,
Shaban, Halq, Sui Khan, Baranai and Koch.
Livestock:
About 17,000 animals including goats, sheep, cows and donkeys are present in the
area. Local communities meet their demand of milk products from their livestock. They
keep donkeys and pack animals (for bringing fuel wood from forest and wheat from the
nearest town called Urak) and horse & camels as means of transportation. The local
community also raises poultry to meet domestic needs. They sell their livestock to
purchase the basic necessities for daily life. The prices range between Rs. 2,000-5,000
per sheep and Rs. 1,000-3,000 per goat. In addition to getting food and cash from
livestock, they also get wool from their sheep and goats. Average production of wool is
about 3 kilograms per sheep, which is sold in Quetta market for 25-30 per kilogram.
Range lands are communal property which is divided among various clans of the
area. For identification individual clan property geographical boundaries are used. There
is no restriction on livestock grazing in the Guzara forest. The nomads graze their
livestock during their migration in summer and winter on their way to Sibi and Quetta,
respectively. This puts extra burden on the range lands and forests of the area. However
in reserved forests grazing is not allowed from May until onset of show fall.
Average livestock mortality from various diseases is estimated at about 11% per
year. Common diseases of livestock in the area are throat soar, foot & mouth diseases,
worms and diarrhea. In addition to diseases, some animals are killed by predators, mainly
wolves, however, their exact number is not known.
The Zarghoon Juniper Forests
The Zarghoon and Tor Shor forests, with an area of 28,956 acres and 34430 acres,
correspondingly were acknowledged reserved between 1890 and 1911. In Zarghoon
reserved forest grazing is allowed over an area of 5,500 acres and in Tor Shor reserved
35
forests, it is allowed over 1/3rd of the total area from May till onset of snow fall. For
protection purposed the Forest department has prearranged 4 forest guards, who are
indigenous and are frequently blamed for being involved in the cutting of forests from
Reserved Forest, apparently for making money. Details on the biodiversity resources and
related issues are given in the following sections.
Uses of Juniper Tree’s Wood by the Community”
In all the five clusters Killi Tor Shor (KTS), Medadzai (M), Gunda (G), Sarobai (S)
and Killi Shaban (KS) information collected through PRA-type PANR on the Juniper
forest wood products consumption by the local communities by using different tools. The
data clearly indicate that community consumption of the wood products is way too much
than the regeneration capacity of the forest and the situation is further aggravated by the
smuggling of the juniper wood and natural and other anthropogenic changes in the
environment.
The data on forest wood products was collected by using PRA technique of Focal
Group discussion (FGDs) and a group of 20 persons from each village were selected and
a discussion was generated separately in each village on the consumption of wood. A
large proportion of community population i.e. 56% used forest wood for fuel, and it is
obtained in different forms for instance; by cutting the stems or branches. 28% for timber,
11 % of the local population uses the tree bark of the Juniper trees that make the trees
vulnerable to diseases and death ultimately. Another use of Juniper trees is for making
the fencing material around the cultivated area and 5% of population (farmers).
The data clearly shows the dependency of the poor community on the forest
resources which are overexploited by the communities as the poor and uneducated
communities of the area are unaware of the importance of the forest for their own
livelihood in future.
36
Fig 2. Pie Chart Showing "Percentage of Different Uses of Juniper Tree’s Wood by the Community”
PRA also revealed that in Juniper tract four plant species, Juniperus excelsa,
Caragna ambigua, Berberis balochistanica, Sophora mollis andSeriphidium
stenocephalumbelonging to four families are conventionally utilized as fuel wood by the
local inhabitants (Table 3.) Among these five plant species Juniper is used as most
abundantly utilized species during all four seasons of the year. The data of fuel wood
consumption collected from five clusters and each cluster shoed different data than other.
Table 3. Priority of local community using plant species as fuel wood in Zarghoon Juniper forest
S.No. Scientific Name Vernacular Name
Existence Tendency
1 Juniperus excelsa Obusht Abundance Top Priority 2 Caragna ambigua Makhai Abundance Second Priority 3 Berberis baluchistanica Zarlog Less abundance Second priority 4 Seriphidium stenocephalum Tarkha Abundance Along with
other wood 5 Sophora mollis Ghuzera Abundence Second priority
Grazing is one of the major factors in the area that is responsible for decrease in
regeneration %age. In the study local community is dependent on the forest for feeding
their livestock. According to PRA study made in the area the livestock are grazed on the
forest rangeland for about 7-8 months in a year. Individual number of sheep, goats, cattle
28%
56%
11% 5%
Timber Fuel wood Bark Fencing material
37
and donkeys is as in the pie chart below.Sheep make the dominant livestock population
of 23%, donkey and cattle 2% and goat population is 75%.
Livestock Population
Sheep, 23%
Goat, 75%
Donkey, 2%
Fig 3. Livestock population in Zarghoon Ecosystem owned by local communities
Socioeconomic Findings by Using Participatory Rural Appraisal(P.R.A.):
Results revealed during PRA and using village level questionnaire (Appendix-A)
revealed that more than 20000 people live in the Zarghoon area in around 2200
households comprised of 17 villages. People live in joint families in large compound and
each compound having in an average 4 households. The community is deprived of basic
requirements of life like, clean drinking water, gas for energy in winter, health facilities,
telephone, educational institutes etc. The community is totally dependent on the forest for
their different needs.
The community is mostly dependent on the medicinal plants and berries of juniper
for treatment of diseases as the allopathic medicines are mostly unavailable and poor
communities are not capable of taking patients to other cities for proper medical
treatment. The major source of income is agriculture but only few people are land owners
most of the farmers are tenants. In an average 50%, 33%, 11% and 6% people have
38
livelihood of agriculture, livestock, services and trade respectively.
Fig 4. Average Income sources of the community in percentage
The information collected PRA indicates that the community consumption of the
wood products is way too much than the regeneration capacity of the forest and the
situation is further aggravated by the smuggling of the juniper wood and natural and other
anthropogenic changes in the environment.
It is estimated through PRA studies that approximately 15000-18000 trees are used
annually by the community; the amount of wood used per day is appx. 7000 kg. This
figure will increase in future with the unchecked population growth in the area and
increase in illegal log business. A large proportion of community used forest wood for
fuel, by cutting the stems or branches. Many use the tree bark of the Juniper trees that
make the trees vulnerable to diseases and death ultimately. Another use of Juniper trees is
for making the fencing material around the cultivated area and poles.
Gender Centered Ethnobotanical Knowledge:
The women have a major role in preserving the ethnobotanical knowledge about the
local herbs and their usefulness, which is useful knowledge and a cultural and historical
heritage (Fig. 5). But the alarming issue is that the local communities of the area consider
the plant resources as limitless and they use the plants beyond their natural regeneration
capacity. The communities are illiterate large in numbers and have no knowledge about
50%33%
6% 11%
Agriculture livestock Services Trade
39
the importance of conserving the plant species by growing them domestically or
commercially.
The community used the medicinal plants for treating some common illnesses like
cough, cold, stomachache, pains etc in contrast some serious diseases like asthma , High
Blood Pressure, Diabetes are also treated using the medicinal plants from the valley. The
medicines were mostly known by old women of the family as they are held responsible
for taking care of men and young ones. Overall 60% women while only 40% men had
some ethno botanical knowledge.
Fig. 5. Bar Chart showing Percentage of Men/Women with respect to ethnobotanical Knowledge/ Ignorance
Mode of Administration of Different medicinal Preparations:
The medicinal preparations (Fig. 6) are used variously by the community. They
have this knowledge from their forefathers and use it in the same way. Mostly the plants
preparations are five categories, like juice extracted from fresh plant parts (26%), Plants
part applied as paste (38%), Powder from fresh or dried plants parts (18%), Fresh parts
(7%) and decoction (11%). The external applications of plants parts mostly for wound,
0%
20%
40%
60%
80%
100%
%ag
e of
eth
nob
otan
ical
kn
owle
dge
vs
ign
oran
ce
Ignorant
40
skin diseases and snake bites, whereas internal application is inhalation and drinking
juice.
0%
5%
10%
15%
20%
25%
30%
35%
40%
%ag
e of
dif
fere
nt m
odes
of
plan
t u
ses
PasteJuice
Powder
Topical
Decoction
Fig. 6. Bar Chart showing %age of Different Routes of Administration
Livelihood Pattern of Local Community:
The village level questionnaire (Appendix-A) shows that the community is
deprived of basic requirements of life like, clean drinking water, gas for energy in winter,
health facilities, telephone, educational institutes etc. The community is totally dependent
on the forest for their different needs.
The community is mostly dependent on the medicinal plants and berries of juniper
for treatment of diseases as the allopathic medicines are mostly unavailable and poor
communities are not capable of taking patients to other cities for proper medical
treatment. The major source of income is agriculture but only few people are land owners
most of the farmers are tenants. In an average 50, 33, 11 and 6% people have livelihood
of agriculture, livestock, services and trade respectively.
The information collected PRA indicates that the community consumption of the
wood products is way too much than the regeneration capacity of the forest and the
41
situation is further aggravated by the smuggling of the juniper wood and natural and other
anthropogenic changes in the environment.
It is estimated through PRA studies that approximately 15,000-18,000 trees are used
annually by the community; the amount of wood used per day is appx. 7,000 kg. This
figure will increase in future with the unchecked population growth in the area and
increase in illegal log business. A large proportion of community used forest wood for
fuel, by cutting the stems or branches. Many use the tree bark of the Juniper trees that
make the trees vulnerable to diseases and death ultimately. Another use of Juniper trees is
for making the fencing material around the cultivated area and poles.
This livelihood pattern survey was lucrative to probe about why younger generation
lacks interest in indigenous knowledge of using medicinal plants to heal diseases. The
root cause of their lack of interest is their tendency to migrate to cities for lucrative jobs.
Therefore, wealth of indigenous knowledge is declining in this area.
Some medicinal plants used by local inhabitants for treatment of different diseases:
The area is rich with medicinal plants and out of which many shrubs and trees were
identified and discussed in this study. These plants fit in 20 genera and 13 families that
are used by aboriginal people via indigenous knowledge they acquire for the treatment of
many diseases. Information regarding different uses of plants collected through
ethnobotanical questionnaire (Appendix-B).
Fig. 7. Bar Chart representing percentages of different modes of plants
0%
10%
20%
30%
40%
50%
60%
%ag
e of
dif
fere
nt m
odes
of
plan
t us
es
LeavesSeeds
Flowerroots
42
In case of parts of plants usage 57%, 26%, 10% and 7% leaves, seeds, flower and
roots are used respectively. Local community using leaves more than any other part of
the plants. When they were inquired about why leaves in excess are used as medicine.
People replied, since it’s easy to access and huge amount availability compare to other
parts. Leaves can be used alone or can be mixed with twigs, stems, and buds. The seeds
of many plants used as medicine may be contained within a fruit or are sometimes used
on their own. Juniper berries look like fruits but they are actually seeds surrounded by
beautiful woody cones. The fleshy or woody roots are used for medicinal purposes. Roots
may be solid, fibrous or fleshy and used by local people as medicines using their
indigenous knowledge. It is inevitable to preserve the indigenous knowledge for
sustainable utilization of natural resources.
In Zarghoon Ecosystem besides Juniperus excelsa, Pistacia atlantica subsp
cabulica, Fraxinus xanthoxyloides are another two prominent trees.
Juniperus excela:
The family Cupressaceae entailing of 55 species of genus Juniperus, occurring all
over the northern hemisphere of the world except Juniperus procera, which grows
naturally in the southern hemisphere. In province Balochistan, J. excelsa has natural
stands distributed between 20°9'N and 30°37'N and between 7°1'E,as well as in some
isolated dry valleys. There are three spatially segregated pockets of Juniper forests,
namely Zarghoon, Ziarat and Harboi (in districts Quetta, Ziarat, Harnai and Kalat
respectively).
J. excelsa forests sprawled in Balochistan has approximately 141,000 hectares (ha), the
major portion i.e. 86,000 ha is found in Ziarat and Loralai districts. J. excelsa trees
typically grow as pure stands, and form characteristically open and multistoried forests
between elevations of 2000 to 3000 m (Sheikh, 1985).
Juniper forest is evergreen or populated by conifers, which is a widespread low-
density forest. This species is small tree and has a small leaf that has small spectral
reflectance on multispectral band. High spatial resolution satellite imagery has capability
to estimate tree density as one parameter for forest inventories. Juniper tree is largely
acknowledged for its small establishment potential under the closed canopy of mature
parent trees. Grazed and non-grazed forests express no difference in the abundance of
43
new and old regeneration (Taketay & Bekele, 1995; Frijis, 1992).Junipers can tolerate
poor soils and can survive at extremely high and low temperatures in comparison to other
forest trees. In addition, they are highly resistant and they are the last species that
abandon areas in the process of deforestation (Pamay, 1955).
Fraxinus xanthoxyloides:
The commonly known as wild ash or Quetta Ash the Fraxinus xanthoxyloides is,
belongs to family Oleaceae and locally called as Shang. A small deciduous tree 3-
7.5mtall, native to the sub-continent, including Pakistan, Afghanistan and India. In
Pakistan it is widely found in Gilgit Agency, Chitral, Dir, Swat, Hazara, Kurrum, and
Balochistan. It prefers arid and semi- arid conditions, cool temperate, Mediterranean
climate with a temperature range of -20 to 35 Cº, and elevations between 1000 and
2500m, (Sheikh, 1993). Ash plant produce compound leaves with toothed leaflets that
turn yellow color in autumn. The dull green leaves are 8-15 inches long and consist of 5-
9 oval or lance-shaped leaflets. Plant is wind pollinated and characterized by apetalous
flowers. It grows from seed as well as by vegetative means. The growth rate is very slow,
but the tree is considered valuable for forestation projects and water shed management.
Wood is hard; branches are often cut and used for burning. The leaves can be used for
fodder for sheep and goats.
Pistacia atlantica subsp cabulica:
Pistacia atlantica subsp cabulicais locally known as Shinea or wild Pistachio and
is native to the Mediterranean rangelands of Balochistan. It belongs to the family
Anacardiaceae, and grows to elevations of 2500 – 3000m in areas with annual rain fall of
150-300mm. Pistacia atlantica subsp cabulica, is found in dry temperate regions of
Pakistan. It occasionally grows on exposed rocky slopes. It is important soil stabilizer and
tannin rich specie. Galls produced on the stems and leaf petioles yield gums which are
locally used as medicines, seeds of this species are edible in different parts of
Balochistan. Over the past few years, population of this plant is gradually decreasing.
It has the capability to grow in dry and harsh climates and can withstand
temperatures below 0 Cº. The growth rate of this species is very slow; seedling grows at a
44
rate of 8cm / year. Their main uses are fruit, fodder, and fuel. In some areas the trees are
lopped to provide fodder for sheep and goats. The Balochistan Forest Department has
made sporadic efforts to establish stands of shinae through nursery- grown seedlings and
direct seeding in national parks.
As growing period starts (early March) of Pistacia atlantica subsp cabulica,
therefore early initiation of foliage occurs. Very few male plants as compared to female
plants probably of the ratio 1:2 or more found in experimental sites. It was found at the
stage of maturity around 50% seeds are hollow.
Interviews of 120 informants including local inhabitants, herbalists and Pansaries
(Local Herbalist) were conducted on random bases. Questionnaires were adopted for
interviews. The outcome of the results were rechecked and compared with literature.
Analysis of the data was carried out and indigenous knowledge was documented.
The overall flora of Zarghun Juniper Ecosystem has been identified and classified
into 39 families, 129 genera and 168 species, belonging to gymnosperms (4),
angiosperms (164). Among the angiosperms 42 species, 36 genera and 8 families belong
to monocotyledons, whereas 122 species, 106 genera and 34 families belong to
dicotyledons. The floristic composition was in accordance with (Asif, 1999).
4.1.1. Discussions Ethnobotany:
Pakistan has exceptional biodiversity, encompassing 9 ecological zones with around
6000 plant species out of which 400-600 are considered medicinally important
(Hamayaun et al., 2005). Despite having wide variety of medicinal plants Pakistan still
imports fair amount for its industry thus have great potential.
In Zarghoon area any diseases are treated by using plants and women possess
ethnobotanical knowledge passed from generation to generation. Earlier ethnobotanical
and medicinal plants utilization studies in Pakistan and Balochistan are having rarely
compatibility with current study. The current study shows that roots and sap of Berberis
baluchistanicais used for internal injury and joint pain, which is in accordance with
mentioned by (Inam et al.,2000; Shah and Khan, 2006; Hussain et al.,2008 and Abbasi et
45
al.,2009). Seeds and leaves of Peganum harmalaare good for stomach and leg problem in
Zarghoon, similarly same plant is useful for asthma, bones crakes (Shah et al., 2006).
Indigenous knowledge about Ziziphora clinopodioides in Zarghoon is that it is used
for motion and vomiting and analogous utilization is reported by (Ali & Qaiser, 2009).
Seeds of Plantago major are cooked with sugar and butter and fed to infants to control
appetite, to control phlegm, cough. Seed tonic useful remedy for dysentery, also useful
for chest congestion and cough, while (Abbassi et al., 2005) reported the same plant is
used against cough, asthma and phlegm.
Ethnobotany is the first understanding the early man had developed in sight of
stipulation, institution, surveillance and research. Archaeological or Paloeobotanical
suggestions about assemblage, expenditure and cultivation of any plant products by early
man for food, house building etc. and references to herbal medicines in ancient scriptures
suggest a very long history of ethnobotany (Hussain and Waqar, 1995).
People in this area are using plants as medicines historically over centuries, even
though their use is being supplanted by the allopathic medicine, yet they are not elapsed
entirely. Local communities have strong believe that the indigenous medical knowledge
appears to have some compensation over the allopathic medical knowledge as stated by
Hakims and other local peoples.
Free from side effects
Easily available in the far off places
Cheaper than allopathic medicines
Tried and tested knowledge
It has been found that copious numbers of pants are used by the local people as
medicine. They use various parts of the plants-stem, bark gum, leaves, fruits, seeds,
flowers etc. for medicinal purpose nevertheless the approach of application fluctuates
bestowing to the civilizations of different villages. Discoveries on Medicinal customs of
plants illustrated that one plant is used for a number of diseases in dissimilar traditions.
46
4.2. Conservation aspect of Juniper Forest in Zarghoon:
Ecological Aspects:
The range of altitude of Juniperus excelsa at Zarghoon and the associated vegetation
to grow is between 2100 to 3,100 m on ridge tops, and moderate (20º) to steep (29º)
slopes and forms pure, open and dense vegetation without any stratification. The
associated flora were also listed and classified on the basis of mean relative frequency
level. Main locations, aspect, slope, and canopy of each stand of the study area are given
in the (Table 4).
Table 4. Ecological Characteristics of five clusters in Zarghoon Forest
Site
Name
Field
Code
Slope
(0)
Aspect Canopy
Killi Tor
Shore
KTS 28 North Open
Medadzai M 24 North Open
Gunda G 24 North East Open
Sarobai S 20 South West Open
Killi
Shaban
KS 29 South West Open
The status Zarghoon Juniper forest was measured calculating different parameters
like Diameter at Breast Height (DBH), old regeneration status, new regeneration status,
deforestation, and sex distribution. The calculations and SPSS application analysis are as
(Appendix-C).
Mean Diameter at Breast Height (DBH) in Inches
Average Diameter at Breast Height (DBH) of the Juniperus excelsa trees in three
plots at each of the five locations Killi Tor Shor (KTS), Medadzai (M), Gunda (G),
Sarobai (S) and Killi Shaban (KS) measured at 4.5 feet (1.37m) above the forest floor.
The DBH measurement helped in assessing the growth, volume, yield and forest
potential. The mean DBH calculated is shown in (Fig. 8).Analysis of Variance was
47
applied on the obtained data to check if there is a difference in the DBH of trees in five
locations.
Fig. 8.Average Diameter at Breast Height(inches) of Juniperus excelsa
Average DBH of Juniperus excela in inches measured at five locations were from
highest to lowest as 37.13, 36.86, 32.40, 31.96, and 29.40 at KS, S, KTS, G, and M
respectively. The ANOVA results show that at 5% significance level, there is a
significant difference in means DBH in trees of five locations. The Levene test was
applied to check the homogeneity of variances (assumption of ANOVA). It was found
that data comes from homogenous population.
The ANOVA result shows that at 5% significance level, there is a significant
difference in means DBH in trees of five locations. The Tukey’s post-hoc test is used to
compare the mean DBH in trees of one village to another. The mean DBH of Medadzai
was found significant from Sarobai and Killi Shahban whereas no significant differences
were found between the mean DBH of other locations. We can say that the mean DBH of
Medadzai was significantly lower than those of Sarobai and Killi Shahban.
Sex distribution:
0
5
10
15
20
25
30
35
40
Killi Tor Shore (KTS) Medadzai (M) Gunda (G) Sarobai (S) Killi Shaban (KS)
Mean DBH (Inches) of Juniperous excelsa
48
The relative richness of male, female and bisexual of Juniperus excelsa calculated
and found different from each other in different clusters. It varied like in some clusters
the female dominated, but male in majority as well overall with a 58% as a whole with
the value 103±23. In addition, the mean density of female calculated was 64±51 or 36%
in the area. Bisexual individuals were infrequent, establishing about 6% of the total
samples. The dominance of male is conspicuous but the male and female ratio were less
significantly different from 1(Chi square =0.39 N.S). The sex distribution ratio revealed
very valuable conclusion from conservation point of view. The difference in ratio of male
and female juniper stands as less possibility of more stable regeneration process in
Juniper ecosystem.
Fig. 9.Ratio of Sex distribution of juniper in 5 clusters of the study area.
New Regeneration:
Average of total ground cover percentage by new regeneration (up to the height of 5
inches) for the three plots of each of the five locations calculated. The data is presented in
(Fig. 10).
58%36%
6%
Female Male Bi-Sexual
49
Fig. 10. Mean New Regeneration Ground Cover %age.
Average new regeneration ground cover %age measured at five locations were from
highest to lowest as 4.07, 4.03, 3.49, 3.58, 2.86 at KTS, KS, S, G, and M respectively.
The ANOVA results show that at 5% significance level, there is a significant difference
in means new regeneration ground cover %age of five locations.
The Levene test was applied to check the homogeneity of variances (assumption of
ANOVA). It was found that data comes from homogenous population. The ANOVA
result shows that at 5% significance level, there is a significant difference in means new
regeneration ground cover %age of five locations.
The Tukey’s post-hoc test is used to compare the mean new regeneration ground
cover %age of one village to another. The mean new regeneration ground cover %age of
Medadzai was found significant from Killi Tor Shore and Killi Shahban, whereas no
significant differences were found between the mean new regeneration ground cover
%age of other locations. We can say that the mean DBH of Medadzai was significantly
lower than those of Killi Tor Shore and Killi Shahban.
Old Regeneration:
Old Regeneration saplings up to height of 5 feet Ground Cover % was measured for
trees in three plots at each location and the mean is represented in figure 3. The data was
00.5
11.5
22.5
33.5
44.5
Killi Tor Shore(KTS)
Medadzai (M) Gunda (G) Sarobai (S) Killi Shaban(KS)
Mean New Regenenration Ground Cover %
50
checked for difference in average old regeneration at five villages. The data was checked
at 95% level of confidence.
Fig.11. Mean old Regeneration Ground Cover %age.
There was statistically insignificant difference in old regeneration% of trees at the
five locations. Moreover there was found no interaction between the Old regeneration %
and the locality. The mean old regeneration ground cover % calculated from highest to
lowest was 4.75 at Killi Tor Shores, 3.74 at Sarobai, 3.48 at Killi Shaban, 3.43 at
Ghunda, and 3.36 at Medadzai. The ANOVA results show that at 5% significance level,
there is a significant difference in means old regeneration ground cover %age of five
locations. The Levene test was applied to check the homogeneity of variances
(assumption of ANOVA). It was found that data comes from homogenous population.
The ANOVA result shows that at 5% significance level, there is a significant
difference in means old regeneration ground cover %age of five locations. The Tukey’s
post-hoc test is used to compare the mean old regeneration ground cover %age of one
village to another. The mean old regeneration ground cover %age of Medadzai was found
significant from Killi Tor Shore and Killi Shahban whereas no significant differences
were found between the mean old regeneration ground cover %age of other locations. We
00.5
11.5
22.5
33.5
44.5
5
Killi Tor Shore(KTS)
Medadzai (M) Ghunda (G) Sarobai (S) Killi Shaban (KS)
Mean Old Regeneration Ground Cover %
51
can say that the mean DBH of Medadzai was significantly lower than those of Killi Tor
Shore and Sarobai.
Deforestation:
The data was collected for deforestation status in the three plots for each of the
five locations by counting the number of fresh cut stumps present in each plot.
According to the results obtained the mean deforestation status of the five selected
locations was mean number of cut stumps as 6.69 at Killi Shaban, 5.95 at Killi Tor Shore,
5.66 at Ghunda, 4.81 at Sarobai, and 4.70 at Medadzai. There was statistically
insignificant difference in deforestation at the five locations. Moreover there was found
no interaction between the deforestation and the locality. The ANOVA results show that
at 5% significance level, there is a significant difference in deforestation of five locations.
The Levene test was applied to check the homogeneity of variances (assumption of
ANOVA). It was found that data comes from homogenous population.
Fig.12. Rate of Deforestation in five localities
The ANOVA result shows that at 5% significance level, there is a significant
difference in means deforestation of five locations. The Tukey’s post-hoc test is used to
compare the deforestation of one village to another. The deforestation of Medadzai was
found significant from Killi Tor Shore and Killi Shahban whereas no significant
differences were found between the deforestation of other locations. We can say that the
012345678
Killi Tor Shore(KTS)
Medadzai (M) Ghunda (G) Sarobai (S) Killi Shaban(KS)
Mean Deforestation %
52
deforestation of Medadzai was significantly lower than those of Killi Shaban and Killi
Tor Shore.
4.2.1. Discussions Conservations Aspects:
Forest trees regenerate in their natural habitats. However, natural regeneration of
tree species occurs in suitable environmental conditions for germination, seed production,
and growth (Margolis & Brand, 1990). Regeneration of Junipers was seemingly very
poor which is in line with the findings of (Hajar et al., 1991). Authors in (Gardner &
Fisher, 1994) suggested climatic change as a possible reason for the poor regeneration of
Juniperus excelsa. Natural regeneration may be affected by the difficult seed germination
due to drought, increasing recreation activity through forests and over-grazing these
findings are in accordance with (Herzog, 1998) who reported that the Juniper seedlings
can survive 150 mm rainfall a year, but they cannot survive a ”drought” lasting longer
than 2-3 weeks.
The Zarghoon Juniper ecosystem is very disturb due to anthropogenic pressure such
as deforestation, over exploitation, up-rooting of plants for medicinal purposes,
imprudent land fragmentation for agriculture, livestock rearing, road construction, fuel
wood consumption and settlements. The Juniper ecosystem, if depleted or destroyed, it is
difficult to restore, regenerate and impossible to recreate with all its components because
germination in these forests (Juniper) is nominal due to nonviable embryo. The same way
all the associated species with these trees will be on the stage of destruction. The local
people save the rooms from water drops in long snowfall, by using bark of Juniper trees.
Bark and even cambium is removed for thatching of huts and rooms. The removing of
cambium results in the death while the removal of bark exposes the trees to vagaries of
extreme climatic conditions, obviously affecting their health and growth. The protection
of the Juniper forest is inevitable to local economy and human environment. This
provides services like housing, energy, agriculture, forestry, livestock rearing, nature
conservation and tourism. The vegetation growing in catchment areas are important for
watershed management, water and soil conservation but overexploitation of these
vegetation by local inhabitants for fencing, timber, materials, thatching of bark for huts,
53
medicinal plants(Beg & Repp, 1966; Singh & Kumar, 1981;Siddiqui, 1998; Abbasi,
2001; Khan, 2001).
Human disturbance, grazing pressure and climatic change are the factors that could
lead to poor regeneration of Juniper was also reported by (Gardner & Fisher, 1994). The
regeneration of natural forests is possible by reforestation of the gaps in these forests with
endemic species. These suggestions concurs with (Bishaw, 2001) thought that
conservation of the natural forests need proper attention and research in these forests
should focus in improving natural regeneration of the various species and conservation of
bio-diversity. Juniper seedlings grow very slowly, a few centimeters a year only same
was reported by (Herzog, 1998).
Population growth and poverty are main causes of the deforestation in Juniper
ecosystem of Zarghoon. Juniper trees are the main source of fuel for the local community
and demand for wood greatly exceeds that which the forest resources can sustainably
supply, these findings are in accord with (Amente, 2005; Thomas & Bekele, 2003).
Juniper forests are small and fragmented in its natural habitat due to anthropogenic
pressure mainly logging (Aboulfatih et al.,1998).
4.3. Soil Analysis:
Three soil samples from each location of five habitats were collected at (0-25cm)
depth and evaluated for their physical and chemical characters. Different elements play
vital role in plant growth as they are absorbed from soil. Soil Physicochemical
Characteristics of 5 Locations at Zarghoon Juniper Forest (Table.5). Soil has important
chemical physiological and biological properties and it varies from place to place,
depending upon the parent rock materials, climate topography, age and biological factors.
Soil texture is important because it determine water intake rates.
Physical Characters
The results of physical analysis showed that pH values of soil vary from 7.4 - 8.1.
High pH (8.1) was found from the soil of Killi Shaban, medium (7.6) from Medadzai and
almost neutral (7.3) from Sarobai. The quantity of organic matter was not very high in the
five study areas. On the basis of organic matter content, soils are characterized as mineral
54
or organic. Mineral soils forms cultivated land and may contain high percent organic
matter but here soil is sustaining natural forest. Organic soils are naturally rich in organic
matter principally for climatic reasons. It is precisely for this reason that they are not vital
cropping soils. Anthropogenic influence and course soil decreases soil organic matter
contents and can be increased or even maintained at good levels requires a sustained
effort that includes returning organic materials to soils by less erosion and no land
fragmentation. Lesser the organic matter less will be the regeneration.
The highest and lowest percentages of OM 2.432 and 1.312 at Killi Tor Shor and
Medadzai respectively with a difference between the maximum OM and minimum
noticed were 1.11. The organic matter contents of Medadzai and Sarobai was almost the
same i.e. 1.312 and 1.353 respectively. When plant residues are returned to the soil,
various or compounds undergo decomposition. Decomposition is a biological process
that includes the physical breakdown and biochemical transformation of complex organic
molecules of dead material into simpler organic and inorganic molecules (Juma, 1998).
Overgrazing destroys the most palatable and useful species in the plant mixture and
reduces the density of the plant cover, thereby increasing the erosion hazard and reducing
the nutritive value and the carrying capacity of the land.
Table 5. Soil Physicochemical Characteristics of 5 Locations at Zarghoon Juniper Forest.
Physical Chemical
pH Organic Mattr%
W.H.C %
Sand Silt Clay Texture class
N mg/kg
K. mg/kg
P mg/kg
KilliTor Shor 7.8 2.432 22.40 45 18 9 Sandy Loam 33 172 2.92
Medadzai 7.3 1.312 19.04 55 15 8 Sandy Loam 43 203 5.18
Ghunda 8.0 2.429 21.23 53 16 7 Sandy Loam 396 207 2.46
Sarobai 7.6 1.353 23.21 51 18 7 Sandy Loam 29 81 3.5
Killi Shaban 8.1 2.683 24.87 59 19 9 Sandy Loam 38 129 5.4
Mean of Physicochemical Characteristics
7.76 2.041 22.15 52.6 17.2 8 _ 107.8 158.4 3.89
55
The soil type of the area was Sandy-loam that predominant soil type analyzed. The
mean of fractions of the sand in five clusters of the study area was (52.6%), followed by
silt (17.2%), clay (8%) whereas water holding capacity indicated (22.15%) of the total
samples across the study area. Soil texture has great effect on the water content, soil
fertility, soil erosion, soil temperature and water holding capacity. The soil analyses of J.
excelsa stands presented here showed that loamy sand was the predominant soil. Sand
fraction represents the main part of the soil sampled analyses (Fig. 13).
The findings were supported by the results of Hussain & Rizvi, (1974). A poor
correlation was recorded only between soil texture values; Sand (r= 46; p<0.01) and Clay
(r= 57; p<0.01) indicating that density of Juniper trees/seedlings are greatly dependent
upon the soil containing sand, clay and calcium carbonate probably due to some animal
grazing, human disturbances, climate change particularlyprevailing drought conditions in
the past few years.
Fig. 13.Mean percentage valuesof Clay; Silt; Water holding capacity; and Sand.
Chemical Characteristics:
The amount of potassium concentration in soil was recorded from all five studied
sites. Highest amount (207mg/kg) was found in soil of Gunda, medium amount
(129mg/kg) from killi Shaban and lesser amount (81mg/kg) from Sarobai. Potassium is
required in large amount in plants and this cation is involved in maintenance of ionic
balance in cells. It also serves as a catalytic role. The critical concentration of potassium
is (60mg/kg) as reported by Hanlon et al.,(1990).
17%
53%8%
22%
Silt Sand Clay W.H.C.
56
Phosphorus was estimated from the soils of all five sites. High amount (5.4mg/kg)
was analyzed from killi Shaban, Medium amount (3.5mg/kg) was found from Sabozai
and slightly less (2.46mg/kg) was estimated from Gunda soil. The lowest amount of
Phosphorus in the soil might be due to the deficiency of water and that is water stress and
drought period the area passed by. The Highest amount of available K was 207 recorded
at Gunda while the lowest was at Sarobai i.e. 81.
4.3.1. Discussion Soil:
Soil conditions are important because it influences the growth characteristics of
plant and indirectly affects their nutritive value. Site also affects the chemical content of
plants and plant parts. Variation in cation uptake selectively occurs between taxa of
different ecological habitats (Marschner, 1995). The soil properties as well as the
genotype of any plant differentiate the concentration and quantity of different plant
materials(Ernst, 1995; Őzcan & Bayçu, 2005). The variation among plants in their
abilities to absorb different elements is not always constant and is affected by changing
conditions of soil, climate and by the stages of plant growth (Kabata-Pendias & Pendias,
1986; Őzcan & Bayçu, 2005). Where an element is easily soluble, plants may take up
very large amount of minerals if water is available. Nutrient which are non-functional in
plants are linked to moisture availability.
Any form of human intervention influences the activity of soil organisms (Curry &
Good, 1992) and thus the equilibrium of the system. Management practices that alter the
living and nutrient conditions of soil organisms, such as repetitive tillage or burning of
vegetation, result in a degradation of their microenvironments. In turn, this results in a
reduction of soil biota, both in biomass and diversity. Where there are no longer
organisms to decompose soil organic matter and bind soil particles, the soil structure is
damaged easily by rain, wind and sun. This can lead to rainwater runoff and soil erosion,
removing the potential food for organisms, i.e. the organic matter of the topsoil.
Therefore, soil biota is the most important property of the soil, and “when devoid of its
biota, the uppermost layer of earth ceaes to be soil” (Lal, 1991).
57
4.4. Genetic Diversity:
In Zarghoon Juniper forest leaf samples of total 25 trees as per five samples from
growth vicinities named Killi Tor Shore, Medadzai, Gunda, Sarobai and Killi Shaban
were collected for DNA isolation.
Table 6.List of location, altitude, collection date, and University of Balochistan Botany Herbarium (UoBBH) voucher number of Juniperus excelsa.
SPECIES LOCATION # of Samples
Alti (m)
COLLECTION DATE
VOUCHER #
J. excelsa Killi Tor Shor
5 2500 20-07-10 UoBBH201 to 205
J. excelsa Medadzai 5 2400 27-07-10 UoBBH206 to 210
J. excelsa Gunda 5 2300 04-08-10 UoBBH211 to 215
J. excelsa Sarobai 5 2570 11-08-10 UoBBH216 to 220
J. excelsa Killi Shaban 5 3100 18-08-10 UoBBH221 to 225
Fresh Leaf samples were used for DNA isolation by the modified PVP method
(Duffy, 2009) sowing to its appropriateness to Juniperus excelsa. The DNA after
extraction was ready for gel electrophoresis.
The amount of DNA used in previous methods revealed two problems high amount
of DNA loaded appeared to run fast and size appeared wrong whereas, DNA loaded in
small amount was not visible and bands were indistinct. Therefore, the amount of DNA
loaded on gel was changed and took around 5 (µl). The loading buffer gave color and
density to the sample, when added 1.5µl of Bromophenol blue (dye) to load into the wells
with ease. The accurate voltage was established to be 85-100 V for 25 min. below or
above the mentioned range of voltage and time gel electrophoresis of this species of this
meticulous region was not possible. The fingerprints showing DNA in deteriorated form
and intact both forms when run on Gel electrophoresis with agarose gel (1%) of
Juniperus excelsain (Fig. 17-20).
58
Fig. 14. Lanes representing the DNA isolation with agarose gel (1%) of Juniperus excelsa.in gel electrophoresis.
Fig. 15. The DNA isolation but not intact form due to presence of secondary metabolites etc. before protocol modified.
59
Fig 16. The DNA isolation with intact DNA shown after protocol modified.
Fig 17. Intact DNA in lanes representing the DNA isolation with agarose gel (1%) of Juniperus excelsa in as fingerprints
Gel was visualized under UV light in gel documentation and quality and quantity
was estimated. Polymerase Chain Reaction (PCR) amplification with given quantity,
Time, activity and temperature of Genomic DNA initiated in PCR amplifier done
(Tables. 1-2).
60
PCR products were genotyped with ABI prism 3130xl genetic analyzer. Statistical
analysis for calculation of observed and expected number of alleles, alleles frequency,
expected and observed heterozygosity, expected and observed homozygosity, F-
statistics, dendrogram based on Nei’s genetic distances using UPGMA and Polymorphic
Information Content (PIC) was carried out by using software “POPGENE 3.31 &
POWER STAT”.
Table 7: No. of Polymorphic Bands (P.B.) per locus from J. excelsa populations of Zarghoon
Populations (sites) Locus No. of Samples No. of Bands No. of P.B. Killi Shaban 5 68 42 Jc031 7 Jc032 11 Jc035 7 Jc037 13 Jc166 4 Killi Tor Shor 5 69 38 Jc031 10 Jc032 9 Jc035 5 Jc037 11 Jc166 3 Medadzai 5 56 32 Jc031 4 Jc032 8 Jc035 5 Jc037 12 Jc166 3 Sarobai 5 52 28 Jc031 7 Jc032 5 Jc035 9 Jc037 5 Jc166 2 Gunda 5 49 26 Jc031 9 Jc032 3 Jc035 5 Jc037 7 Jc166 2
Six different microsatellite loci primers initially recognized for J. communis were
inspected for J. excela and four out of six primers revealed polymorphism at variable
61
proportions. The maximum number of polymorphic bands i.e., 13 in any J. excela
population was recorded at the locus Jc037. There was distinct size range in polymorphic
bands which could be easily detected. The Primer for allele Jc166 amplified relatively
fewer polymorphic bands for any given population and the amplification products range
was 2-3. The amplification products for the locus Jc032 showed moderate to good
polymorphism and it ranged between 3-11 bands for any population. Primers for loci
Jc031 and Jc35 showed moderate level of amplification of polymorphic bands with a
range of 4-10 and 5-9 respectively.
Table 8. Genetic diversity of populations of Juniperus excelsa in Zarghoon Populations
(sites) No. of sample
No. of total
bands
No of polymorphic
bands
% of polymorphic
bands
Gene diversity (He)
Killi Shaban 5 68 42 61.8 0.2012 (±0.0178) Killi Tor Shor 5 69 38 55 0.1971 (±0.0122)
Medadzai 5 56 32 57.1 0.1543 (±0.0145)
Sarobai 5 52 28 53.8 0.1422 (±0.0156)
Gunda 5 49 26 53 0.1012(±0.0100)
Total 25 298 150 280.7 0.796 Mean 5 59.6 30 56.14 0.1592
The level of genetic diversity in wild populations of J. excels obtained in this study
(polymorphism = 56.14%, He = 0.1592) is close to the average values for widespread
distributed species (polymorphism =58.9%, He = 0.202) (Hamrick and Godt, 1989). It is
a little less than populations of J. excels collected only from Killi Shaban. Comparatively,
J. excels had rich genetic resources and diversity. The percentage of polymorphic bands
of populations was great with a variation of 8.8% as of maximum (61.8%) at Killi Shaban
and minimum (53%) at Gunda. The polymorphism decreased with decrease in cover. The
genetic diversity among populations also varied greatly, from 0.1012 - 0.2012 and their
order was Killi Shaban > Killi Tor Shore > Medadzai >Sabozai> Gunda.
Genetic diversity is intact quantity of innate features in the genome of a species or a
population. Populations in different surroundings and species within populations may
have different genetic characteristics
62
Table 9. Mean Soil Physicochemical Characteristics of 5 Locations at Zarghoon Juniper Forest.
Physical Chemical
pH Organic Mattr%
W.H.C %
Sand Silt Clay Texture class
N mg/kg
K. mg/kg
P mg/kg
Mean of Physicochemical Characteristics
7.76 0.3818 26.95 36.2 27.8 36 _ 107.8 158.4 3.89
The mean percentage of organic matter at different soil compositions was 0.3818, while
pH of the most of the soil was slightly alkaline with a mean of 7.76. Nitrogen contents of
the soil showed a mean value of 107.8mg/kg which may be due to surface runoff from
the orchards applied with Nitrogenous fertilizers. Potassium mean value was 158.4 mg/kg
which is sufficient for growth of plants while Phosphorus was way too small in quantity
and this important element needs to be applied artificially to the soil for better growth of
most of the plant mean P value was 3.89 mg/kg as shown in the table above.
Table 10.Climatic characteristics of different distribution area of Juniperus excelsa populations in Zarghoon region (average values of 1980 - 2010) Mean Tempt
Mean Relative Humidity (%)
Mean Lowest Temperature Co
Mean highest TemperatureCo
Mean Precipitation(mm)
10 20 -10 22 290
Different regional climatic parameters were also imperative and presented significant
impact on the genetic diversity of J. excelsa trees. Changes in these parameters due to
climate change may have radical effects on the genetic diversity of J. excelsa
populations. The mean humidity was 20% over the duration of study period which is
characteristic of arid to semi-arid climate of Balochistan. The variance between mean
maximum and minimum temperatures was 32Co and ranged between -10 to 22 Co. The
mean annual temperatures of any area are vital regarding the configuration of vegetation
and ecosystem and a slight change in mean temperatures due to climate change has the
potential of changing the intact conformation of vegetation of this area as all the species
are very temperature sensitive. The importance of mean precipitation for vegetation of
this area cannot be denied. Mean precipitation was 290 mm and further decrease in
63
precipitation might result in mass extinction of many species and genetic diversity as
adaptation is a slow procedure while climate change brings about unexpected changes.
Table 11.Correlation coefficients between genetic diversity and environmental variables for J. excelsa populations in Zarghoon.
GD Amh Amp Amht Amlt N P K pH O.M. % P.B. -0.302 0.843* 0.973* 0.714* -0.214 -0.112 -0.145 0.975* 0.125 GD -0.634 0.673 0.674* 0.636 -0.123 0.211 0.451 0.764* -0.321
GD=Genetic diversity, Amt=Annual mean temperature, Amh=Annual mean humidity, Amp=Annual mean Precipitation Amht=Annual mean highest temperature, Amlt=Annual mean lowest temperature, %age Polymorphic Band
The polymorphism was significantly correlated with annual mean precipitation (r =
0.843) and Soil pH (r = 0.975). The gene diversity was significantly correlated with soil
pH (r= 0.764) and near significantly correlated with annual mean precipitation (r =
0.673).The polymorphism was significantly correlated with annual mean high temp as (r
= 0.973) and annual mean low temp (r = 0.0.714). The gene diversity was significantly
correlated with annual mean high temp (r= 0.674) and near significantly correlated with
annual mean low temp (r = 0.636). This suggests that annual mean precipitation, high and
low temp and soil pH were important factors affecting genetic diversity of populations of
J. excelsa
4.4.1. Discussions Gene Diversity:
Genetic diversity is intact quantity of innate features in the genome of a species or a
population. Populations in different surroundings and species within populations may
have different genetic characteristics (Kim et al., 1997; Karimiet al., 2009).
Consequently, to study genetic interactions of species within populations and
amongst populations in dissimilar environment is the substance for administration of
flora. Biotechnology involvement to affluence in scrutinizing genetic mannerisms of an
individual species in different environmental conditions is prodigious. Juniper forests
with extreme climatic and soil characteristics, shoot/root ratio is fundamental to
biological success. Seedlings planted in arid or semi-arid areas should have a well-
developed root system for better absorption of water lost from the soil in shoots and
leaves (Hermann, 1964; Hobbes, 1964; Baer, 1977).
64
Junipers can endure deprived soils and persist at exceedingly high and low
temperatures in contrast to other forest trees. In addition, they are extremely resilient and
they are the latest species that abandon areas in the course of deforestation (Pamay,
1955).
Afforestation revisions on juniper documented that seedlings with low shoot/root
fresh or dry weight provided healthier results, chiefly in scorched areas (Yahyaolu &
Genc, 2007; Gultakin, 2007). Biodiversity has three components and genetic diversity is
one of the portions of biodiversity, and therefore is significant in conservation.
Conservation of forests is important content of biodiversity conservation (Kate & Laired,
1999). The objective of this study was to test the hypothesis that populations in different
environments have different genetic diversity and to elucidate the genetic relationships
between populations of J. excelsa. It embraces high magnitudes of polysaccharides, and
secondary metabolites such as phenols alkaloids that inhibit DNA isolation. These
compounds directly or indirectly obstruct with the enzymatic reactions. J. excela did not
endorse intact and high yield of DNA from one isolation protocol. Therefore, numerous
protocols for DNA extraction were applied to many plant species. Microsatellite DNA
marker is a piece of DNA molecule that is associated with a certain trait of organism. It
can be of different types like morphological, chromosomal, genetic and biochemical.
A specific sequence of DNA bases (nucleotides) made up of mono, di, tri or tetra
tandem repeats also called STR= Single Tandem Repeat, SSR= Simple Sequence Repeat,
SSLP= Simple Sequence Length Polymorphism. Markers are highly polymorphic, occur
abundantly and distributed evenly throughout the genome, are typically short (less than
100bp). In addition are used in application in personal identification, population genetic
analysis and easy to detect by PCR. Microsatellites are “junk” DNA and majority of
microsatellites are found in non-coding regions of the genome. Microsatellites may
provide a source of genetic variations.
At a given microsatellite, different individuals can have different numbers of
repeats. Changes in the number of repeats result from mutation. Microsatellites mutate
very rapidly (100 -10,000 times faster than normal base pair substitutions), so there is lots
of variation between individuals (Caskey et al., 1992; Glowatzki-Mulliset al., 1995;
65
Garcia-Moreno et al.,1996). Inter-annual variability in climate is a normal occurrence,
even in the absence of long-term climatic changes. Most species tolerate such short-term
variability through phenotypic plasticity. However, beyond the point at which individuals
(and therefore species) are able to tolerate changes in climate, distributional and
evolutionary changes are inevitable (Lynch & Lande, 1993). The accumulating evidence
of plant migrations indicates that this point has already been passed for many species.
The preservation of high level of genetic diversity in J. excels is in accord with
findings of high genetic diversity in Eastern Mediterranean species and populations that
did not suffer from severe demographic and genetic bottlenecks (Fady-Welterlen, 2005).
The extraordinary within-population diversitymight also be elucidated by a latest
derivation of the shattering joined with a great original degree of diversity, as was
suggested for Cedrus spp. (Bou Dagher-Kharratet al., 2007). In addition, some life-
history behaviors of Juniper species such as out crossing, wind pollination, conceivable
long-distance seed dispersal, elongated duration of life and a widespread scattered
population have possibly encouraged and preserved extraordinary genetic diversity
(Hamrick et al., 1992;Austerlitz et al., 2000).
66
CHAPTER 5
Conclusions and Recommendations
Management-related issues, such as lack of incentives, give the impression to be
amongst the most. important constrictions for the maintenance of juniper forest. Abiotic
and biotic factors and the undesirable. magnitudes of deforestation and clear-cutting has
resulted in to forest decline and to a general loss of. diversity both genetic and at the
species level. DNA markers were developed. in recent years for the detection of genetic
diversity amongst and within the juniper populations. The consumption of these markers
permitted the gathering of significant evidence. about the individual and dissemination of
the genetic resources of this. species in relation to the changing local climate, which is
one of the core factors determining diversity in forest tree species. A molecular pattern of
diversity represents important. preliminary information and a good basis for planning
conservation strategies. However, programs of conservation of genetic resources cannot
be proficiently comprehended. devoid of the accessibility of documentation on adaptive
behaviors, which might. exhibit a diverse geographic configuration than molecular
markers.
Highly polymorphic. molecular markers and microsatellites are very useful for
providing information about. the reproductive arrangements and the effects of population
inbreeding on the level of diversity. Studies aimed at analyzing the organization of the
diversity within populations. of juniper are evolving. Ethnobotanical endeavors can help
ascertain management disagreements, circumstances where proportions of harvest plants
exceed. rates of re-growth. The fact that ethnobotany is or should be a combined
endeavor. amid individuals in indigenous communities, counting numerous professionals,
and technologists. means that a commencement can be accomplished to determine
elucidations to .conservation and development concerns, even as evidence on plant
usages is being collected.
Traditionally, native communities worldwide are tremendously well-informed
about native plant. and other natural assets. Continuously upon which they are so
instantaneously and .intimately reliant. Regrettably, considerable volume of this fortune
of knowledge is .becoming last as traditional culture gnarled. Ethnobotanists can perform
67
effective role in. retrieving diminishing information and recurring it to resident
communities. In this approach native ethnobotanical knowledge. can be conserved as part
of living cultural-ecological systems helping to sustain an .intellect of vanity in local
cultural knowledge and practice, and fortifying links between. communities and the
environment, so indispensable. for conservation.
Imprudent land development, over exploitation, natural ailments and absence or
scantiness of natural renaissance. intimidates the endurance of the Juniper forests. The
forests meet the traditional hassles. for fuel-wood, grazing, timber, thatching and fencing
material but can no longer withstand. the amplified dimensions of elimination and over
use.
Cultivation or orchard expansion is good for the economy of local community but
to organize it by dissipating the Juniper. forests and paling them by continuous lopping of
Juniper trees is injudicious. There are. not many stable surface water sources in the
Juniper tract but widespread orchard .cultivation has been undertaken on extensive areas
by developing water. The mistreatment of ground. water could overdo recharge rates by
treacherously high levels in certain areas. The expansion of horticultural and other
irrigated cropping enterprises in the Juniper tract .at Zarghoon forest might pose a great
peril to the sustainability of the orchards if ground .water use is not efficient and if the
vegetation in the watersheds is not improved.
There has been 3-4% annual growth in the .human population near the Juniper
tract. A huge migratory population has established at .the orchard gorges and fuel-wood
for heating in winter is indispensable for their livelihood. There has also been expansion
in housing as a consequence of upsurge in population .as well as due to cognizance to
have better house but this activity has disbursed outsized .magnitudes of Juniper timber.
Over grazing has turned out to be a constant .object of overall degradation in the
density and composition of vegetation in the .Juniper tract. The prevailing shrub
communities were naturally selected to .endure barrenness; they are fibrous, musky and
generally unpalatable and had .weathered deprivation of the grazing animals. Some
communities are degraded .because of the devastation of some floristic constituent. The
gradual opening of the .vegetative cover has led to several retrogressive phases including
decline of water .withholding. This, however, accompanied with exhaustion of organic
68
material and available nitrogen. The denuded areas are often colonized by nitrogen fixing
plants e.g. Sophora, Astragalus, Caragana etc. Although the plants have considerable
water and soil .conservation value, the more nutritive palatable forms have been eaten
out, and the .remaining ones are both spinose, unpalatable and some moderately toxic to
stock.
90% of Juniper seeds are not viable. There is also a very low proportion of germination
of viable seed, i.e. less than 1% in the best conditions. Then the seedlings are trodden by
livestock and .the poles are cut for fencing, fixing along graves and for other uses. As a
result, the .number of sprouts, plantlets and ends surviving in the forests make a very low
percentage in the composition of the forests. This suggest the Juniper forest ecosystem is
not vigorous. and may not persist long to assist the local, national and international needs.
To recover exponentiation of Juniper by seeds, it would, therefore, be advisable
that, in .addition to protection against trampling, the ecological conditions for
germination. in the open spaces be upgraded. Strictly managed rotational grazing will
provide .favorable conditions for germination.
There is also inordinate probability of encouraging vegetative progression by
natural .layering. Lower branches of the old trees which touch the soil or are buried
underneath, often, show formation of roots. Thus, while still being nourished by parent
tree in .the most critical time of establishment, daughter trees grow up around the old
trees .especially after the mother tree has been cut. Samples of natural populations are
most .suitable for in situ gene conservation. Taking benefit of surviving nature protection
areas, the assortment and conservation of extraordinary gene reserve forests are
comparatively economical. Regeneration ought to take place by natural procedures.
Regeneration with non-local seed or genetically improved material should not take place.
It can .be anticipated that in the long run the gene and genotype frequencies will modify
in .response to selection pressure climate change. In order to eliminate the undesirable
effects of inbreeding and random drift, each in situ conservation unit must be rather large.
In relation to the total forest area or the area of .national parks, the area of gene reserves
is modest.
Conclusions:
69
Forest cover is becoming more and more open, soil erosion and water runoff are
.accelerating, soil productivity is decreasing, forests are unable to meet local needs, and
the .conservation, recreation, scientific and educational values are being lost. Thus,
sustainable .development in the area might be retarded permanently after the forests are
cleared and .existing water reserves are shattered. The re-creation of the ecosystem is
either not .conceivable or is very expensive even if that be a man-made secondary
ecosystem.
There is a .tremendous need of recognition of forested areas confronting threats.
Juniper forests are .under great pressure and communities are to be helped in forest
conservation and .sustainable exploitation. Government intercession for assistance is
necessary as these .must not be neglected simply for the purpose that these forests are not
influenced by government.
Recommendations:
Genes of Juniperus excelsa trees cannot be packaged and stored in cupboards or
just in the form of .words in a book. They must be kept alive in the form of living trees
their seeds, fruits, .gametes and provided a habitat in which they can thrive and keep
evolving in the .natural conditions.
There is a requirement for a transformation in the attitude of government
functionaries as .well as communities concerning the ownership and utilization of the
Juniper forests. The forests are not only nations but also for the local communities and
are to be managed .for them to yield them greater benefits on sustained basis irrespective
of the present legal .status of forests. The communities are to be made aware of this
change in the attitude .of government, functionaries for enlisting their co-operation.
This is important the .objectives of management are well defined and higher priority is
given to the insubstantial .benefits such as watershed, recreation and conservation values
as the management of .forests for these objectives will supply them essential
commodities and services .such as water for orchards and agricultural crops as well as
employment and .business due to increasing tourism. However, local basic need such as
basic needs such .as fuel wood for energy can be met from the forests which have dry and
fallen wood. The .forests, where dry wood is no longer available, should be closed to
70
wood collection .and removal. Letting people take away fire-effected trees encourage
them to burn more green trees.
The results of the .contemporary trial specified that the combination of CTAB and
PVP in modified expanses .facilitated fabricating high excellence and harvest DNA from
Juniperus excelsa of Zarghoon Juniper ecosystem. Since it is an original study to evaluate
genetic inconsistency in virgin .research land (Zarghoon) and the DNA extraction method
used is very lucrative for .supplementary research. Cultivating renaissance of Juniperus
excelsa trees in Zarghoon. Nevertheless, it can be concluded that the Juniper forest is
facing a major threat of .dilapidation due to high rate of deforestation and rationally low
rate of regeneration. The .unparalleled Zarghoon Juniper forest is in dire need of research
particularly in disciplines like biotechnology, molecular biology and pharmacology and
also for conservation and planning best management practices for sustainable
consumption of .forest assets. The annual mean precipitation, temp and soil pH are
important factors .affecting genetic diversity. J. excelsa distributed in semi-arid. The
geographical distance .might have some effects on genetic relationships, because even at
short distance of .nearest populations G diversity is more if more dense. The five
populations were .different in genetic resources and diversity with some specials features,
and therefore, they all need special conservation as given below.
In terms of .gene conservation the conclusion is that neutral marker gene diversity
can be preserved .anywhere. The diversity of adaptive traits needs to be preserved in
several ecologically .different areas. Thus, the genetic configuration of Juniper stands at
the Zarghoon Forest at Balochistan, are unique. In order to sample most of the large
within-population .genetic diversity, a large number of trees per population is needed.
The goal is to .maintain the adaptive potential of the population over several generations
by carrying over .most of the alleles in all polymorphic loci. This is more challenging
than sustaining the .modifications of metric traits among individuals at its unique level. If
the scheme is based .on marker genes alone, a substantial share of variation in adaptive
characters is lost.
Rare alleles and .exceptional morphological variants are sometimes declared as
the foremost objective of .gene conservation. They are stimulating as research substances
71
and instances of genetic diversity, but they do not fit in to the conventional purposes of
gene conservation.
In-situ and ex-situ .conservation of the genetic diversity of Juniper forest.
Find solutions .through investigation concerning problem of natural regeneration
of forest.
Endorse natural .regeneration and vegetative multiplication of the Juniper.
Proper management and .funding is required to protect the forest against flash
floods.
Plantation of the juniper .forest must be promoted on national/local levels
Conduct delinquent oriented .research in forestry, range, watershed and wildlife.
Establishment and training of .forestry staff.
Establish a Juniper national .park/World heritage site.
Spatial planning of Zarghoon .forest and villages.
Scrutinize revenue generation .undertakings and stimulate them.
Separate the conservation of the .genetic diversity of natural populations from the
maintenance of adequate genetic .variation in breeding populations.
incentives must be provided by the .Government in support of gene conservation
as part of the routine silvicultural practice
A national approach or program for the .conservation of forest genetic resources
Present findings revealed that existing .extraordinary anthropogenic pressure on
ecosystem can be abridged by regulations, .implementations and financial assistance for
sustainable recourse utilization to the unique .juniper ecosystem of Zarghoon.
A national gene conservation program is .inevitable and all native juniper species of
Balochistan should gradually be included in .national gene conservation programs, as
well as the introduced species that have at least .potential value as forest trees. Junipers
have been on the Earth for hundreds of millions of years. There is a lot we can do to
make sure that future generations inherit this .genetic wealth.
72
CHAPTER6
REFERENCES:
Abbasi, A.M., G. Dastagir, F. Hussain and P. Sanaullah. 2005. Ethnobotany and
marketing of crude drug plants in district Haripur, Pakistan. Pak. J.Plant.
Sci.,11(2): 103-114.
Abbasi, A.M., M.A. Khan, M. Ahmad, M. Zafar, H. Khan, N. Muhammad and S.
Sultana, 2009. Medicinal plants used for the treatment of Jaundice and hepatitis
Basedon socioeconomic documentation.African Journal of Biotechnology 8:
1643-1650.
Abbasi, I.K. 2001.Workshop report on Partnership for conservation anddevelopment.
Agha Khan and WWF- Pakistan, Gilgit, Pakistan, pp. 4-13.
Aboulfatih, H.A.,U. Emara and A. Hashish. 1989. The influences of grazing on
vegetation and soil of Asirhighland Arab. Gulf J. of Sci. Res, 7b(1): pp. 69-78.
Adams, R.P. 1999. Systematics of multi-seeded eastern hemisphere Juniperus based on
leaf essential oils and RAPD DNA fingerprinting. Biochem. Syst. Ecol. 27: 709-
725.
Adams, R.P. 2000a. Systematics of the one seeded Juniperus of the eastern hemisphere
based on leaf essential oils and random amplified polymorphic DNAs (RAPDs).
Biochem. Syst. Ecol. 28: 529-543.
Adams, R.P. 2000b. The serrate leaf margined Juniperus (Section Sabina) of the western
73
hemisphere: systematics and evolution based on leaf essential oils and Random
Amplified Polymorphic DNAs (RAPDs).Biochem. Syst. Ecol. 28: 975-989.
Adams, R.P. 2000c. Systematics of Juniperus section,Juniperus based on leaf essential
oils and random amplified polymorphic DNAs (RAPDs). Biochem. Syst. Ecol.
28: 515-528.
Adams, R.P. and R.N. Pandey2003. Analysis of Juniperus communis and its varieties
based on DNA fingerprinting. Biochem. Syst. Ecol. 31: 1271-1278.
Adams, R.P., M.S.G. Elizondo, M.G. Elizondo and E. Slinkman.2006. DNA
Fingerprinting and terpenoid analysis of Juniperus blancoi var. huehuentensis
(Cupressaceae), anew subalpine variety from Durango, Mexico.Biochem.Syst.
Ecol. 34: 205-211.
Adams, R.P. and A.E. Schwarzbach.2006. A new variety of Juniperus sabina from
Mongolia: J. sabina var. mongolensis. Phytologia 88: 179-185.
Ahmad, V.S. 1956 a note on the plants of medicinal value found in Pakistan. Medicinal
plant branch, Pakistan forest research institute Abbottabad, Pakistan.
Ali, H. and M. Qaiser. 1993-2009. The Ethnobotany of Chitral valley, Pakistan, with
particular reference to medicinal plants. Pakistan Journal of Botany 41: 2009-
2041.
Ali, S.I. & Y.J. Nasir (Ed.) 1989-1992. Flora of Pakistan. No. 191-193. Karachi and
Islamabad.
Ali, S.I. and M. Qaiser. (Ed.). 1993-2009. Flora of Pakistan.No. 194-17. Islamabad and
Karachi.
74
Al-Jaloud, A.A., S.A. Chaudhary.,I.I. Bashour., S. Qureshi and Alshaghitti, A. 1994.
Nutrient evaluation of some arid range plants in Saudi Arabia. Journal of Arid
environments, 28:299-311.
Allen, E.A. and R.S. Nowak. 2008. Effect of pinyon-juniper tree cover on the soil seed
bank. Rangeland Ecology and Management. 2008. 61(1):63-73.
Amente, G., 2005. Rehabilitation and sustainable use of degraded community forests in
the Bale Mountains of Ethiopia. Inaugural dissertation, Faculty of Forest and
Environmental Sciences, Albert-Ludwigs University, Freiburg in Breisgau,
Germany.
Andrew S.G., and Fisher, M. 1996. The distribution and status of the montane juniper
woodlands of Oman. J. Biogeogra., 23: 791-803.
Anonymous (a), 1997. Centers of plant diversity: a guide and strategy for their
conservation. IUCN Publications Unit, Cambridge, by WWF & IUCN. UK.
Anonymous(b), 2008. PakistanEcoConsult (Pvt) Limited,Balochistan,
Pakistan.Assessment Study for Juniper Project, IUCN Balochistan.p:8
Asif, M. 1999.“Floral Diversity and Economic Importance of Zarghoon Juniper
Ecosystem” Dissertation, University of Balochistan, Quetta, Pakistan.
Atta, M.S., K. Nasrullah, W. Muhammad, and K. Asmatullah. 2010. New spread of dwarf
mistletoe (Arceuthobium oxycedri) in juniper forests, Ziarat,Balochistan,Pakistan,
Pak. J. Bot., 42(6): pp. 3709-3714.
Atta, M.S., M. Ahmed, A. Ahmed, L. Tareen and S.U. Jan. 2012. The Ecology and Dynamicsof Juniperus excelsa Forest in Balochistan-Pakistan. Pak. J. Bot., 44(5): pp. 1617-1625.
75
Austerlitz F, Mariette S, Machon N, Gouyon P-H, Godelle B. 2000.Effects of
colonization processes on genetic diversity: differences between annual plants and
tree species. Genetics 154:1309–1321.
Avise, J.C., 2008. Markerymolekularne w genetycekonserwatorskiej. In: Avise J.A.,
Markerymolekularne, historianaturalnaiewolucja” .Wydawnictwo
UniwersytetuWarszawskiego, Warszawa, 463-515.
Badeau, V., J.L.Dupouey, C. Cluzeau, and J. Drapier. 2005. Aires potentielles de
répartition desessences forestières d’ici 2100. Forêt Entreprise, 162:25–29.
Baer N., F. Ronco, and C.W. Barney. 1977. Effects of watering, shading,and size of stock
on survival of planted lodgepole pine. USDA ForestServ., Rocky Mt., Forest and
Range Exp. Sta., Fort Collins, Colorado, Res. Note RM-347, p. 4.
Beadle, N.C.W. and Y.T. Tchan.1955. Nitrogen economy in semi- arid plant
communities. I. The environment and general considerations. Linn.Soc. N. S.
W. Proc. 80: pp. 62-70.
Beg, A.R. and G.I. Repp. 1966. Preliminary ecological observation in the Juniper forest
of Ziarat Silvi Conference. pp. 245–253.
Bishaw, B. 2001. Deforestation and land degradation on the Ethiopian highlands: A
strategy for physical recovery, in Abstracts of international conference on
contemporary development Issues in Ethiopia.16–18.
Bou Dagher-Kharrat, M.S. Mariette, F. Lefe`vre, B. Fady, G. Grenier-deMarch, C.
Plomion, A. Savoure. 2007. Geographical diversityand genetic relationships
among Cedrus species estimated byAFLP. Tree Genetics & Genomes 3: pp. 275–
285.
76
Boruah, P., Kalita, P., Bordoloi, D. Gogoi, P. And Adhikary, R.K. 1997. Some Fleshy
Fungi of Ethnobotanic use from N.E. India. Advance in Forestry Research in
Indis. 16: 165-171.
Bouyoucos, G.J. 1962. Hydrometer method improved for making particle size of soils.
Agron. J. 54:464 – 465.
Caskey, C.T., A. Pizzuti, Y. Fu, R. G. Fenwick Jr., and D. L. Nelson.1992. Triplet
repeat mutations in human disease. Science (Wash. DC) 256:784–789.
Chambers, J.C., S.B. Vander Wall and E.W. Schupp. 1999. Seed and seedling ecology
of pinion and juniper species in the pygmy woodlands of western North America.
The Botanical Review.65:1-38.
Chamber, R. 1991. Shortcut and Participatory Methods for Gaining Social Information
for projects in Cemea, Micheal M (ed.), Putting People First, Sociological
Variables in Rural Development, Published for the World Bank, Oxford
University Press, p. 36.
Chaudhary, S.A., 1997. Flora of the Kingdom of Saudi Arabia, volume one.
National Agriculture and Water Research Centre, Ministry of Agriculture, Saudi
Arabia, p. 691.
Cottam, G. and J.T. Curtis. 1956. The use of distance measures in Phytosociological
Sampling.Ecology, 37(3): 451-460.
Curry, J.P. & Good, J.A. 1992. Soil faunal degradation and restoration.Adv. Soil Sci.,
17: 171-215.
Dastagir, G. 2001. Medicinal plants of Mai Dhani Hill, Muzafarabad, Azad Jammu and
77
Kashmir.HamdardMedicus, Vol. XLIV:29pp.
Davis, D.K., Qureshi, K. Sherman, D., Sollod, A. and Stem, C. 1995. Ethnoveterinary
Medicine in Afghanistan. An Overview of Indigenous Animals Healthcare among
PashtoonKoochi Nomads.J.Arid. Envirn. 1995.31; pp. 4:483-500.
Derwich, E.Z.,S. Benziane and A. Boukir. 2010. Chemical Composition of LeafEssential
Oil of Juniperus phoenicea and Evaluation of its Antibacterial Activity.
International journal of agriculture and biology. 1560–8530:199-204
Douaihy B, Vendramin GG, Boratyn´ ski A, Machon N, BouDagher-Kharrat M. 2011.
High genetic diversity with moderate differentiation in Juniperusexcelsa from
Lebanon and the eastern Mediterranean region. AoB PLANTS 2011
plr003doi:10.1093/aobpla/plr003
Duffy K.J., G. Scopece, S. Cozzolino,M.F. Fay,R.J. Smith, and Stout J.C. 2009.
Ecology and genetic diversity of the dense-flowered orchid, Neotineamaculata, at
the centre and edge of its range. Ann. Bot. 104:507–516.
Egli, P., and B. Schimid.1999. Relationship between leaf nitrogen and limitations of
photosynthesis in canopies of Solidago altissima.Acta Oecologia.20(5): 559-570.
Ettershank, G., J.A. Ettershank, J.A.Bryant, M. Whitford, 1978. Effects of nitrogen
fertilization on primary production in a Chihuahuas Desert ecosystem.
Journal of Arid Envirnoments.1:135-139.
Ernst, W.H.O. 1995. Sampling of plant material for chemical analysis. Sci. Total
environment, 176(1-3): 15-24.
Everett, R.L. 1986. Understory seed rain in harvested pinyon-juniper woodlands. Great
Basin Naturalist. 46:706-710.
78
Fady-Welterlen B. 2005. Is there really more biodiversity inMediterranean forest
ecosystems. Taxon 54: 905–910.
Figueiredo,G.M. Leitao. HF, Filho and Begossi, A. 1997. Atlantic Forest Coastal
Communities: II. Diversity of Plant uses at Sepetiba Bay (SE Brazil)Human
ecology, New York. 1997.
Fisher, M. and S.G. Andrew. 1995. The status and ecology of a Juniperusexcelsa subsp.
polycarpos woodland in the northern mountains of Oman. Vegetation, 119: 33-51.
Flores, J.S. and R.R. Vermont. 1996. The secretion of Exudated of Plants Used in Mayan
traditional Medicine. J.Herbs Species and Medicinal Plants. 4;1:53-59.
Frijis, I. 1992. Forests and forest trees of northeast tropical Africa. HMSO, Kew
Bulletin additional series XV, London.
Garcia–Moreno, J., M.D. Matocq, M.S. Roy, E.Geffen, and R.K. Wayne. 1996.
Relationships and genetic purity of the endangered Mexican wolf based on
analysis of microsatellite loci.Conserv. Biol. 10:376–389.
Gardner A. S. and M. Fisher. 1994. How the forest lost its trees: Just So storytelling
AboutJuniperusexcelsain Arabia. Short communication, Journal of Arid
Environments 26: 299-301.
Gitzendanner.M.A., P.S. Soltis. 2000. Pattern of genetic variation in rare and
widespread plant congeners”. Am. J. Bot. 87(6): pp. 783-792.
Glowatzki-Mullis, M.L., C. Gaillard, G. Wigger, and R. Fries. 1995. Microsatellite
based parentage control in cattle. Anim. Genet. 26:7–12.
79
Gupta, V.C. S.J. Hussain, S. imam. 1997. Medico-ethnobotanical Survey at Paderu Forest
ofAraku Valley, Andra Pradesh, India. Fittoterapia, 68;1: 45-48.
Gurib, Fakim, A. Gueho, J. Sewraj, and M. Bissoondoyal. 1997. The Medicinal Plants of
Mauritius partI. Inter. J.Pharmacognosy.35;4:237-254.
Hajar A.S., A.A. Faragalla and K.M. Al-Ghamdi. 1991. Impact of biological stress
onJuniperusexcelsaM. Bieb.in south-western Saudi Arabia: insect Stress. Journal
of Arid Environment 21: 327-330.
Hamayaun M., M.A. Khan. And T. Hayat. 2005. Ethnobotanical profile of Utror and
Gabral valleys, district Swat, Pakistan. Ethnobotany leaflets. 10: 40-45.
Hamrick, J.L.M.J.W. Godt,S.L. Sherman-Broyles. 1992. Factors influencinglevels of
genetic diversity in woody plant species. NewForests 6: 95–124.
Hanlon, E.A., G. Kidder, and B.L. Mc-Neal, 1990. Soil, Container Media and Water
Testing: Interpretations and IFAS Standardized Fertilization Recommendations.
Circular 817.Florida Cooperative Extension Service, Institute of Food and
Agricultural Science, University of Florida, Gainesville, FL.
Hermann, R.K. 1964. Importance of top-root ratios for survival of Douglas-fir seedlings.
Tree Planters, Notes 64: 7-11.
Herzog M. 1998. Shrubland Management in Tribal Islamic Yemen. Social Forestry as
Development of a Local and Sustainable (Sylvi-)Culture: An Essay in Practical
Philosophy. A report of a study work in forestry development financed by the
Swiss Development Cooperation. Haldenweg 32, 4310 Rheinfelden. Switzerland.
Hobbes, S.D., R.H. Byars,D.C. Henneman, C.R. Freost. 1980. First Year Performance of
containerized Douglas-fir Seedlings on Droughty sites in Southwestern Oregon.
80
Oregon State Univ., Forest Res. Lab., Corvallis, Res. Pap.42, Oregon, USA.
Hocking, G.M. 1958. Pakistan medicinal plants, I. Qualities PlantaumEt Material
Vegetables,5:145-153.
Holsinger, K. E. and L.D. Gottlieb. 1991. Conservation of rare and endangered plants:
principles and prospects. In Genetics and conservation of rare plants” (eds. D. A.
Falk and K).
Hsiang, T. and J. Huang.2000. The use of RAPD markers to distinguish among Juniper
and Cedar cultivars. Can. J. Bot. 78: 655-659.
Hunting Survey Corporation.1960. Reconnaissance Geology of part ofWest Pakistan:
A Colombo Plan cooperation Project, Toronto,Canada.
Hussain, M. and S.Waqar. 1995. An Ethnobotanical Survey of Charsada, NWFP,
Pakistan.
Hussain, K., A.Shahzad and S.Z. Hussnain.2008. An Ethnobotanical Survey of
important wild medicinal plants of Hattar District Harripur,
Pakistan.Ethnobotanical Leaflet 12: 29-35.
Ikram, M. and S.F. Hussain. 1978. Compendium of Medicinal Plants. PCSIR, Lab.,
Peshawar.
Inam, B., K. Sultana, R.A. Qureshi and S.A. Malik. 2000. Checklist of plants of
Bhogarmong, Siranvally, N.W.F.P., Pakistan. Ham. Med., 43(4): 62-75.
Johnston, M. Colquhoum, A. 1996. Preliminary Ethnobotanical Survey of Kurupukarrian
American Settlement of Central Guyana.Economic Botany. 50;2:182-194.
81
Jovel, E.M. Cabanillas, J. Towers, GHN. 1996. An Ethnobotanical Study of the
traditional Medicine of the Mestizo People of SuniMirano, Loreto, Peru. J. of
Ethnopharmacology. 53;3:149-156.
Juma, N.G. 1998. The pedosphere and its dynamics: a systems approach to soil science.
Volume 1.Edmonton, Canada, Quality Color Press Inc. 315 pp.
Kabata-Pendias, A., and H. Pendias. 1986. Trace elements in Soil and Plants. CRC
Press, Inc. BocaRaton, Florida.
Karimi H.R., S. Kafkas, Z. Zamani,A. Ebadi. 2009. Genetic relationships among
Pistacia species using AFLP markers. Plant Syst. Evol. 279:21–28.
Kartha, K.K. 1985-86. “Annual Report, Plant Biotechnology Institute, National Research
Council, Canada. P. 26.
Kate, K.T. and S.A. Laird.1999.The commercial use of biodiversity. Earthscan
Publications Ltd., London.
Khan, A.A. 1999. Some Common Ethnobotanical Uses of Plants Among the Gonds of
Chhindwara District, (M.P.), India.HamdardMedicus, Vol. XLII:80-83.
Khan, S. 2001. Report on Evaluation of Fuel Efficient Stoves provided to three project
sites of WWF- P Northern areas, Pakistan. Printed at WWF- Pakistan, Peshawar,
pp.7-9.
Kim, C.S., C.H. Lee, J.S. Shinl, Y.S. Chungi and N.I. Hyung. 1997. A simple and rapid
method for isolation of high quality genomic DNA from fruit trees and conifers
82
using PVP”1997, Oxford University Press Nucleic Acids Research.Vol.25, No. 5
1085–1086.
Koniak, S. and R.L. Everett. 1982. Seed reserves in soils of successional stages of
pinyon woodlands. American Midland Naturalist. 108:295-303.
Lal, R. 1991. Soil conservation and biodiversity.In D.L. Hawksworth, ed. The
biodiversity of microorganisms and invertebrates: its role in sustainable
agriculture, pp. 89-103. Wallingford, UK, CAB International.
Lande, R. 1988. Genetics and demography in biological conservation. Science 241:
1455-1460.
Longuefosse, JL. Nossin, E. 1996. Medical Ethnobotany Survey in Martinique. J. of
Ethnopharmaecology. 53;3:117-142.
Lynch, M., and R. Lande. 1993. Evolution and extinction in response to environmental
change, pp. 234-250. In P. Kareiva, J. Kingsolver, and R. Huey (eds.) Biotic
Interactions and Global Change.Sinauer Assocs., Inc. Sunderland, MA.
Malcolm, J.R., Markham, A., Neilson, R.P. & Garaci, M. 2002. Estimated migration
rates under scenarios of global climate change. Journal of Biogeography, 29:
835–849.
Marcoux.A. 2000.Population and deforestation.S D Dimensions. Sustainable
Development Department, Food and Agriculture Organization of the United
Nations (FAO).
Margolis H.A. and D.G. Brand. 1990. An eco-physiological basis for understanding
83
Plantation establishment; Review/Syntheses.Canadian Journal of Forest
Research 20: pp. 375-390.
Marschner, H. 1995. Mineral nutrition of Higher Plants, 2nd ed. Academic Press,
London.
Martinez, Z. 1992. Useful Plants of sanlorenzoAcopilco, Distrito Federal. Ciencia
Forestal.Publ. 1994. 17;71:123-146.
Mash, S.K.1995. An Account of Ethnobotanical Observations made in Jabalpur Forest
Division (M.P.).VanikiSandesesh. 19;3:14-19;6ref.
Menges, E. S. 1991. The application of minimum viable population theory to plants.In
Genetics and conservation of rare plants. (ed. D. A. Falk and K. E.
Holsinger).Oxford University Press, New York and Oxford.pp. 45- 61.
Michalczyk IM, Sebastiani F, Buonamici A, Cremer E, Mengel C, Ziegenhagen B,
Vendramin GG. 2006.Characterization of highly polymorphic nuclear
microsatellite loci in Juniperus communis L. Molecular Ecology Notes;6:346-348.
Mooney, H. A., C. Field, S.L. Gulmon, F.A. Bazzaz.1981.Photosynthetic capacity in
relation to leaf position in deserts versus old field annuals. Oecologia.50, 109-112
Mukherjee, N. 1994.Participatory Rural Appraisal Methodology and Applications.
2rd edition, Ashok Kumar Concept Publishing Company, New Delhi India, p. 30.
Mueller,G.U., L.L. Wolfenbarger 1999. AFLP genotyping and fingerprinting, TREE
14 389–394.
Nasir, E. and S.I. Ali. (Eds.). 1970-1979.Flora of West Pakistan. No. 1-131. Islamabad,
Karachi.
84
Nasir, E. & S.I. Ali. (Eds.). 1980-1989.Flora of Pakistan. No. 132-190. Islamabad,
Karachi.
Noy-Meir, I.1973. Desert ecosystems: environment and producers. In: Johnston, R.
F.,ed. Annual review of ecology and systematic. Palo Alto, Ca: Annual Review,
Inc.4:25-52.
Ogden, J. and J.A. Powell. 1979. A quantitative description of the forest vegetation on an
altitudinal gradient in mount field National Park. Tasmania and discussion of its
history and dynamics. Aust. J. Ecol. 4:293-325.
Oostermeijer, J.G.B., B. De Knegt. 2004. Genetic population structure of the wind-
pollinated, dioecious shrub Juniperus communis in fragmented Dutch heathlands.
PlantSpecies Biology 2004, 19:175-184.
Osem, Y., A. Perevolotsky and J. Kigel. 2006. Similarity between seed bank and
vegetation in a semi-arid annual plant community: the role of productivity and
grazing. Journal of Vegetation Science. 17:29-36.
Özcan, T., and G. Bayçu.2005. Some elemental concentrations in the acorns of
Turkish QuercusL.(Fagaceae) taxa. Pak.J. Bot. 37(2):361-371.
Pal, D.C., S.K..Jain. 1998. Materia medica, Vegetable; Medicinal plants; India Book
(ISBN 8185421307 ), Naya Prokash (Calcutta).
Pamay, B. 1955.Türkiyeardıçtürleriveyayılı_ları. _Ü OrmanFakültesiDergisi 1: 91-12.
Pei, S. 1995. Ethnobotany and Sustainable use of Plant Resources in the HKM
Mountain Region, Planing workshop on Ethnobotany and its application to
conservation and community development in the Hindu Kush Himalayan (HKH)
85
Region. Nepal.
Qureshi, R., A. Waheed, M. Arshad and T. Umbreen. 2009. Medico-ethnobotanical
inventory of Tehsil Chakwal, Pakistan. Pak J. Bot., 41(2): 529-538.
Rao, A.L. 1994. The Juniper Forests in Balochistan, Pakistan. IUCN, World
Conservation Union, Draft, Report. p. 3.
Ravishankar, T. 1995. Tribal People and Their Knowledge of Plant genetics resources.
International Seminar on management of MFP, 13-15. J. of Non-Timber Forest
Products. 2;1-2:100-103.
Reddy, R.V. Lakshami, N.V.M.Raju, RRV and R.R. Vekataraju. 1998. Folk Veterinary
Medicinal Plants in Cuddapah Hills of Andhra Pradesh, India.FItoterapia
69;4:322-328.
Rehfeldt, G.R., Tchebakova, N.M., Parfenova, Y.I., Wykoff, W.R., Kuzmina, N.A. &
Milyutin, L.I. 2002. Intraspecific responses to climate change in Pinus sylvestris.
Global Change Biology, 8: 912–929.
Roodt, V.1998.trees and Shrubs of the Okavango Delta Medicinal Uses and Nutritional
values. 213pp. Shell Field Guide Series: Part I.
Sambrook J, E.F. Fritsch, T. Maniatis. 1989. Molecular cloning: Alaboratory manual.
Cold Spring Harbor Laboratory Press, Cold Spring Harbor, New York, USA.
Savelkoul, P.H.M., H.J.M. Aarts, J. de Haas, L. Dijkshoorn, B. Duim,M. Otsen, J.L.W.
Rademaker, L. Schouls, J.A. Lenstra. 1999. Amplified-Fragment Lenght
Polymorphism analysis: the state of an art J. of Clin. Microbiol, 37 3083–3091.
Schemske.D.W., B.C.Husband, M.H Ruckelshaus, C.Goodwiuie., I.M. Pparkes.,
86
J.G.Bishop. 1994. Evaluating approaches to the conservation of rare and
endangered plants. Ecology 75: 584-606
Shah, G.M. and M.A. Khan. 2006. Common medicinal recipies of Siran valley, Mansera,
Pakistan, Ethnobotany leaflets, 10: 63-71.
Shah, S.R.U., G. Hassan, A. Rehman and I. Imtiaz. 2006. Ethnobotanical studies of the
flora of Musakhail and Barkan in Balochistan, Pakistan. Pakistan Journal of
Weed Science Research 12: 199-211.
Sharifi, M. R., E.T. Nilsen, and P.W. Rondel.1990. Biomass and net primary
production of Prosopis glandulosa, (Fabaceae) in the Sonora desert of California.
American Journal of Botany, 69: 760-767.
Sheikh, I.S. 1985. Afforestation in Juniper forests of Balochistan.Pakistan Forest
Institute, Peshawar, Pakistan.
Sheikh, M.I.1993.Trees of Pakistan. Winrock International Institute for
Agricultural development.
Shinwari, M.I. and M. A. Khan. 1998. Ethnobotany of Marghalla Hills, National Park
of Islamabad” Department of Biological Sciences, Q. U. Islamabad, Pakistan.p. 9.
Shinwari, M.F. and Khan, M.A. 1999. Multiple Dimensions of Ethnobotany and its
present status in Pakistan. HamdardMedicus Vol. XLII: 5-10.
Shinwari, Z.K. and Shah, M. 1996. The Ethnobotany of the KharanDistt.Balochistan.
Pro.First Training Workshopp.Ethnob. Appl. Consserv.:124-132.
Siddiqui, KM. 1998. Properties and Uses of Pakistani Timber, Forest Products
Research Division, Pakistan Forest Institute Peshawar. pp. 3-5.
87
Singh.And K. Agia. 1981.A contribution to the ethnobotany of Sub Hamalian Region
of Eastern Uther Perdash. India, pp. 237-246.
Singh, V. and Pandey, RP. 1998. Ethnobotany of Rajastan, India. XXI, 367pp.
Smith, L. R., and T.M. Smith. 1989.Fundamental of ecology. 4th edition. Wesely
Longman (New York).
Taketay, D. and T. Bekele. 1995. Floristic composition of wof-washa natural forest,
central ethiopia: Implications for the conservation of biodiversity. Feddes report,
Berlin Germany, Tech. Rep. 106-1-2.
Tareen, R.B., Tahira B., Khan M.A., Ahmad M., and Zafar M. 2010. Indigenous
Knowledge of Folk Medicine bt the Women of Kalat and Khuzdar Regions of
Balochistan, Pak. J. Bot., 42(3): 1465-1485.
Thomas and M. Bekele.2003.Role of planted forests and trees outside forests in
sustainable forest management: Republic of ethiopia country case study, FAO,
vol.(1):1.p. 1.
Ueckert, D.N. 1985. Use of shrubs for rangeland re-vegetation.In:Proceedings of the
International Ranchers Roundup. Laredo, Texas. Texas Agricultural Extension.
Van-Der, I.,M. Merwe,M.O.Winfield,G.M. Arnold andJ.S. Parker. 2000. Spatial and
temporal aspects of the genetic structure of Juniperus communis populations.
Molecular Ecology, 9:379-386.
Van der Valk, A.G. and R.L. Peterson. 1989. Seed banks and the management and
restoration of natural vegetation. In Ecology of Soil Seed Banks. M.A. Leck, V.T.
Parker, and R.L. Simpson (eds.). Academic Press, San Diego, CA.
88
Vorhies, F. 2000.The global dimension of threatened medicinal plants from a
conservation point of view. In Medicinal utilization of wild species: challenge for
man and nature in the new millennium” (eds. S. Honnef and R. Melisch). WWF
Germany/ TRAFFIC Europe-Germany. Hannover pp 26-29.
Walser, R.H., D.J. Weber, E.D. McArthur, and S.C. Sanderson.1990. Salinity and
moisture stress in relation to die off of Wild land Shrubs. In: Proceeding-
Symposium on Cheat grass Invasion, Shrub Die-Off, and Other Aspects of Shrub
Biology and Management. Las Vegas, NV, April 5-7 1989.
West, N., and Skujins, J. 1978. Nitrogen in Desert Ecosystem. Hutchinson & Ross,
Stroudsburg, Pennsylvania.
Zaman, M.B. and M.S. Khan. 1970. Hundreed drug plants of West Pakistan. Medicinal
Plants Branch, Pakistan Forest Institute, Peshawar. Pp. 1-105.
89
APPENDICES
Appendix-A Village level Questionnerier
1
VillagelevelquestionnaireforZarghoonForest
Name of the District: Total no of respondents: Name of the Union Council (u/c): Male Name of enumerator: Female Name of the Village: Date; 1. Pattern of the village; (compact/ scattered): 2. Type of house (pacca/semi pacca/ katcha /other): 3. Total no of compound in the village;(more then Ten HH/less then Ten HH): 4. Population size in the village. 5. Main tribes in the village. 6. Major languages spoken in the village. 7. Accessibility pattern: Metal road /shingle road/dirt road) 8. Distance of the village (k ms): (from district town /from main highway /from nearest
village. 9. Basic facilities existing in the village:(School-Boys, Girls/BHU/Water supply/
Electricity/Others) 10. Type of leadership dominant in the village :(Tribal Chief/Religious leader/Village
elders) 11. Common meeting place:(Mosque/ Hujra / Otaq /School / Bazzar / Other) 12. Main decision makers in the family:
[Head of the family /elderly women- (family decisions, financial matters & Child schooling, Children marriages etc.)-Collective approach]
Appendix-A Village level Questionnerier
2
13. Migration pattern exists in the village:(seasonal/for livelihoods/due to droughts/due to
political reasons) 14. Is agriculture the primary means of subsistence? 15. What are major crops grown and their yields? 16. Is pesticide spray done to control pests and diseases? 17. What are the major constraints to productivity? 18. What is the source of water used by the community for various enterprises like crops,
horticulture, domestic, livestock etc.? 19. What are the limitations and problems associated with water availability and use
system in the area? 20. What is the method used for irrigating different crops? 21. Are the users aware of undesired depletion of water table in various areas of the
province? 22. If yes, whet is the source of their information? 23. What sort of businesses is established in the village? 24. Who are the buyers? (Villagers, distributors, take to city, others) 25. Are women involved in income generation activities? 26. Who does most of the household activities? 27. Have the women ever involved in a common action? If yes, which type of collective
work have you been involved?
28. What were the most important plants and wild life species present 15 to 50 years ago? (local name)
29. What medicinal plants are available? 30. Do they use locally and sell also? 31. What are their preferences in case of using medicinal plants in comparision to
allopathic?
Appendix-A Village level Questionnerier
3
32. What kind of health facility is available in the village? Also whether the available health facility is functional or not and equipped with staff, medicines, distance of facility from the community, other facilities.
33. What kind of traditional health practitioners exist in the village? Are they functional?
Which Govt/non-governmental agency were they trained by? And where did they receive training? ( in village, at district, U/C, divisional or provincial level)
34. How many girls, boys and women were vaccinated during the past one year in the village
35. What are the problems being faced by the people due to watershed degradation? [Decline of water table flash floods and their damage to crops, Soil erosion, scarcity of fuel wood and forage status of springs in the village flowing but discharge decreased)
36. What is the source of fuel for domestic purpose?
a) LGP b) Kerosene Oil c) Fuel wood purchased d) Cow dung e) Existing Forest
Appendix-B EthnobotanyQuestionnerier
1
Questionniere Ethnobotanical data Collection
1. Local/Vernacular Name
__________________________________________________
2. Botanical/Scientific Name
__________________________________________________
3. Locality
__________________________________________________
4. Elevation
__________________________________________________
5. Soil Type/Condition
__________________________________________________
6. Date of Collection
__________________________________________________
Appendix-B EthnobotanyQuestionnerier
2
7. Name of Interviewee
__________________________________________________
8. Parts Used
__________________________________________________
9. Purpose of Use
__________________________________________________
10. Method of Medicine Preparation
__________________________________________________
Appendix-C SPSS calculations
1
Diameter at Breast Height (DBH) in inches at 4.5 feet above ground level:
Descriptives
Diameter at Breast Height
N Mean Std. Deviation Std. Error
95% Confidence Interval for Mean
Minimum Maximum Lower Bound Upper Bound
Killi Tor Shore 3 32.4 2.8 1.6 25.4 39.3 29.6 35.2
Medadzai 3 29.4 2.5 1.4 23.1 35.6 27.3 32.2
Ghunda 3 31.9 2.3 1.3 26.2 37.6 29.6 34.2
Kala Ragha 3 36.8 1.6 0.9 32.8 40.9 35.1 38.3
Killi Shaban 3 37.1 2.9 1.7 29.7 44.5 34.4 40.3
Total 15 33.5 3.7 0.9 31.4 35.6 27.3 40.3
This table show the averages DBH for five locations along with their standard deviations. The 95% confidence intervals are also produced.
Test of Homogeneity of Variances
Diameter at Breast Height
Levene Statistic df1 df2 Sig.
.238 4 10 .911
This table displays that the Levene test was applied to check the homogeneity of variances (assumption of ANOVA). It was found that data comes from homogenous population.
ANOVA
Diameter at Breast Height
Sum of Squares Df Mean Square F Sig.
Between Groups 134.6 4 33.6 5.4 .014
Within Groups 62.0 10 6.2
Total 196.6 14
The ANOVA results shows that at 5% significance level, there is a significant difference in means DBH in trees of five locations.
Appendix-C SPSS calculations
2
Diameter at Breast Height
Area N
Subset for alpha = 0.05
1 2
Tukey HSDa Medadzai 3 29.4
Ghunda 3 31.9 31.9 Killi Tor Shore 3 32.4 32.4
Kala Ragha 3 36.8 Killi Shaban 3 37.1
Sig. .59 .15
Means for groups in homogeneous subsets are displayed.
a. Uses Harmonic Mean Sample Size = 3.000. The Tukey’s post-hoc test is used to compare the mean DBH in trees of one village to another. The mean DBH of Medadzai was found significant from Kala Ragha and Killi Shahban whereas no significant differences were found between the mean DBH of other locations. We can say that the mean DBH of Medadzai was significantly lower than those of Kala Ragha and Killi Shahban.
Descriptives
New Regeneration
N Mean Std. Deviation Std. Error
95% Confidence Interval for Mean
Minimum Maximum Lower Bound Upper Bound
Killi Tor Shore 3 4.0 1.6 0.9 -.04 8.1 2.23 5.44
Medadzai 3 2.6 1.6 0.9 -1.3 6.6 1.29 4.44
Ghunda 3 3.5 1.3 0.7 .27 6.8 2.32 4.97
Kala Ragha 3 3.5 1.1 0.6 .84 6.3 2.32 4.34
Killi Shaban 3 4.0 0.7 0.4 2.2 5.7 3.30 4.70
Total 15 3.5 1.2 0.3 2.9 4.2 1.29 5.44
Test of Homogeneity of Variances
New Regeneration
Levene Statistic df1 df2 Sig.
.742 4 10 .585
ANOVA
New Regeneration
Sum of Squares df Mean Square F Sig.
Between Groups 3.7 4 .944 .535 .713
Within Groups 17.6 10 1.763
Total 21.4 14
Appendix-C SPSS calculations
3
Descriptives
Old Regeneration
N Mean Std. Deviation Std. Error
95% Confidence Interval for Mean
Minimum Maximum Lower Bound Upper Bound
Killi Tor Shore 3 4.7 0.8 0.4 2.6 6.8 4.02 5.70
Medadzai 3 3.3 0.9 0.5 0.8 5.8 2.34 4.32
Ghunda 3 3.4 1.0 0.6 0.8 6.0 2.44 4.55
Kala Ragha 3 3.7 0.5 0.3 2.2 5.1 3.07 4.09
Killi Shaban 3 3.4 0.0 0.0 3.3 3.6 3.44 3.55
Total 15 3.7 0.8 0.2 3.2 4.2 2.34 5.70
Test of Homogeneity of Variances
Old Regeneration
Levene Statistic df1 df2 Sig.
1.538 4 10 .264
ANOVA
Old Regeneration
Sum of Squares df Mean Square F Sig.
Between Groups 4.009 4 1.002 1.572 .256
Within Groups 6.375 10 .638
Total 10.384 14
Appendix-C SPSS calculations
4
Descriptives
Deforestation percentage
N Mean Std. Deviation Std. Error
95% Confidence Interval for Mean
Minimum Maximum Lower Bound Upper Bound
Killi Tor Shore 3 5.9 1.9 1.1 1.1 10.8 3.78 7.55
Medadzai 3 4.7 1.5 0.9 .7 8.6 3.34 6.44
Ghunda 3 5.6 1.8 1.0 1.1 10.2 3.89 7.55
Kala Ragha 3 4.8 1.0 0.6 2.0 7.5 3.55 5.45
Killi Shaban 3 6.6 2.1 1.2 1.2 12.1 4.66 8.99
Total 15 5.5 1.6 .43 4.6 6.4 3.34 8.99
Test of Homogeneity of Variances
Deforestation percentage
Levene Statistic df1 df2 Sig.
.312 4 10 .863
ANOVA
Deforestation percentage
Sum of Squares Df Mean Square F Sig.
Between Groups 8.2 4 2.0 0.6 0.6
Within Groups 31.2 10 3.1
Total 39.4 14
FYTON ISSN 0031 9457 (2013) 82: 69-74
Application of the Participatory Rural Appraisal (PRA) to assess the ethnobotany and forest conservation status of the Zarghoon Juniper Ecosystem, Balochistan, PakistanUso del enfoque de valuación rural participativa (PRA) para evaluar el estado de conservación del bosque y etnobotánica del Ecosistema de Junípero Zarghoon, Balochistan, Pakistan
Bazai ZA1, RB Tareen1, AKK Achakzai1, H Batool2
Resumen. El enfoque de recolección de datos llamado Valuación Rural con Participantes (PRA) se utilizó en cinco villas: Killi Tor Shore; Medadzai; Ghunda; Kala Ragha y Killi Shaban. En cada villa se muestrearon hasta cinco grupos, comprendiendo un total de 17 villas en el ecosistema de junípero de Zarghoon. Esta área es rica tanto histórica como culturalmente por el uso de plantas medicinales, principalmente por mujeres (60%). En este estudio, 26 especies de plantas medicinales pertenecieron a 20 géneros y 13 familias. Estas son utilizadas por aborígenes a través del conocimiento indígena que ellos tienen para el tratamiento de varias enfermedades. Cerca de 60, 35 y 5% de las medicinas son preparadas para su uso oral, como tópico y hervidas para inhalar, respectivamente. La distribución por-centual de las partes vegetales usadas con este propósito es de 57, 26, 10 y 7% para hojas, semillas, flores y raíces, respectivamente. Es im-portante mantener el conocimiento indígena que tiene la gente para usar la vegetación como medicinas para una utilización sustentable de los recursos naturales renovables. Las herramientas utilizadas en el programa PARA incluyeron el uso de mapas sociales, sendas efec-tuadas por caminatas, entrevistas estructuradas y semi-estructuradas, y diagramas circulares. Las condiciones socio-económicas revelaron cerca de 20000 personas habitando 400 viviendas distribuidas en 17 villas, y su subsistencia dependió del bosque. A la comunidad le faltan cosas básicas para vivir. Las fuentes principales de ingreso económico (90%) son la agricultura y la cría de ganado, y solo un 10% proviene de intercambios, servicios y trabajo. La alta presión antrópica actual sobre el ecosistema puede ser reducida por regulaciones, implemen-tación de servicios y asistencia financiera. Esto debería contribuir a una utilización sustentable de los recursos en el único ecosistema de junípero de Zarghoon.
Palabras clave: Ecosistema de junípero; Zarghoon; PRA; Etno-botánica; Plantas medicinales; Biodiversidad.
Abstract. The data collection approach called Participatory Rural Appraisal (PRA) was used in five villages: Killi Tor Shore; Medadzai; Ghunda; Kala Ragha, and Killi Shaban. Up to five groups were sampled in each village, comprising a total of 17 villages within the Zarghoon Juniper ecosystem. This area is rich both historically and culturally for using medicinal plants, mostly by women (60%). In this study, 26 species of medicinal plants fit in 20 genera and 13 families. They are used by aboriginal people via the indigenous knowledge they have for the treatment of many diseases. About 60, 35, and 5% of the medicines are prepared to be used orally, topically and boiled to inhale, respectively. Percentage distribution of plant parts used with purpose is 57, 26, 10 and 7% for leaves, seeds, flowers and roots, respectively. It is important to preserve the indigenous knowledge that people have for using vegetation as medicines for a sustainable utilization of the renewable natural resources. The PRA tools used consisted of social maps, transit walks, structured and semi-struc-tured interviews, and pie diagrams. The socio-economic conditions revealed around 20000 people living in 400 households distributed in 17 villages, and livelihood depended on the forest. The community lacks basic amenities of life. The major sources of income (90%) are agriculture and livestock raising, and only 10% comes from trade, services and labor. The current high anthropogenic pressure on the ecosystem can be reduced by regulation, service implementations and financial assistance. This should contribute to sustainable resource utilization in the unique juniper ecosystem of Zarghoon.
Keywords: Juniper ecosystem; Zarghoon; PRA; Ethnobotany; Medicinal plants; Biodiversity.
1 Department of Botany, University of Balochistan, Quetta-Pakistan.2 Department of Botany, Sardar Bahadur Khan Women University Quetta-Pakistan.Address Correspondence to: Dr. A.K.K. Achakzai, Department of Botany, University of Balochistan, Quetta-Pakistan. e-mail: [email protected] Recibido / Received 9.IV.2012. Aceptado / Accepted 15.IX.2012.
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Bazai ZA et al., FYTON 82 (2013)
Table 1. A detailed taxonomic description of medicinal plant species used in the study area in terms of their parts and folk medicinal uses.Tabla 1. Descripción taxonómica detallada de especies de plantas medicinales utilizadas en el área de estudio en términos de sus partes y usos medicinales tradicionales.
S. No.
Botanical Name *Vernacular Name
Family Part Used Folk Medicinal Uses
1 Achillea santolina (L.)
Brinjas Asteraceae Leaves Plant extract is given to children to treat stomach ache and in-digestion. Also used as blood purifier and refrigerent. It is used to treat diabetes and also as a cooling medicine to reduce heart shocks.
2 Achillea wilhelmsii Boh-e-madran Asteraceae Whole plant Whole plant is soaked in water or boiled to obtain the extract, and it is used to treat stomachache, diabetes, gastric troubles, fat-ness, and used as a blood purifier.
3 Artemisia maritime (L.)
Tarkha Asteraceae Whole plant Plant extract is used as a blood purifier and heart tonic. Also useful for treating pain in joints, fever, and, stomach ache/indi-gestion.
4 Berberis baluchistanica Ahrendt
Zarlog Berberidaceae Roots and sap Roots are boiled to make decoction, which is used to heal inter-nal injuries in man and cattle. Also for the relief of joint pain.
5 B. callobotrys Khar Zaaulg Berberidaceae Leaves and sap Plants are used to treat jaundice. Leaf extracts are used as a blood purifier and for the treatment of acne.
6 Bunium persicum Tora Zirak Plantagina-ceae
Leaves and sap Fruits are aromatic and used as spice.
7 Centaurea phyl-locephala, Boiss.
Talkha Asteraceae Leaves It is used to treat stomach ache, swelling up of body, and wounds in cattle.
8 Ephedra foliate, Boiss and Kotschy
Oman Ephedraceae Whole plant It’s a source of ephedrine, a well known alkaloid. It is used to treat heart diseases, high fever and asthma. Seeds are used as a cooling medicine. Stem is used to heal the wound of ear piercing.
9 E. intermedia, Sch-renk and Meyer
Oman Ephedraceae Whole plant The plant is used for the extraction of ephedrine. Used for asth-ma and cough, and to heal wounds.
10 Ferula oopoda Hing Apiaceae Seeds, leaves and sap
Boiled seeds and decoction for infant cough, and stems to kill intestinal worms. Sap locally called Ingapatric is used for tooth-ache.
11 Juniperus excelsa Boiss
Obusht Cupressaceae Seeds and leaves
Oil is obtained from berries (fruit), which is carminative, diuretic and stimulant.
12 Lepidium repens, Boiss
Garbust Bashka Brassicaceae Leaves It is used to treat skin infections. Leaves are cooked and eaten to warm the body.
13 Malva neglecta Khatmi Malvaceae Whole plant It is useful to treat cough; roots are used as a cooling medicine; leaves are cooked and eaten to treat gynecological disorders, and boiled leaves are applied to the body for treating sterility.
14 Mentha longifolia Vialani Lamiaceae Leaves and roots
Leaves are used to treat gastric troubles, diarrhea. Juice of leaves is mixed with raw apple juice to treat motion and vomiting.
15 Nepeta practervisa Simsok Lamiaceae Leaves For treatment of flu, cough. Leaves are used to make tea which is useful to warm the body.
16 Peganum harmala Kisankoor/spanda Zygophyl-laceae
Leaves and seeds
Seeds are used to treat indigestion, stomach ache. Used to treat diabetes, joints ailments and measles. Seeds are mixed in bathing water to treat pain.
17 Perovskia abrotanoi-des Karel
Gowaridaranai Lamiaceae Leaves, flower and seeds
Flower and leaves are used for the treatment of typhoid and headache. Whole plant is ground and soaked for vomiting.
18 Pistacia atlantica ssp., Stocks Pistacia cabulica Stocks.
Sharawan Anacardiaceae Leaves, fruits and gum
Leaf extracts are used to treat indigestion. Oil is obtained by grinding the seeds, and the oil is used for cooking. It warms the body and treat cough when applied on to the skin. Oil is used for many other purposes.
19 Plantago lanceolata Ispaghol/ Phidori Plantagina-ceae
Seeds Seeds are useful in constipation, purgative and to control fatness. Leaves are applied to wounds.
20 Plantago major (L.) Bar-e-tang Plantagina-ceae
Seeds Seeds are cooked with sugar and butter, and fed to infants to control appetite. Also used to control phlegm, cough. Seed tonic useful for dysentery, chest congestion and cough.
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Participatory Rural Appraisal to assess a Juniper Ecosystem in Pakistan
21 Salvia cabulica Metetay Lamiaceae Leaves It is used to treat stomachache and indigestion.
22 Salvia glutinosa (L.) Gul-e-Kakar Lamiaceae Leaves and flowers
Used to treat Jaundice and as refrigerant.
23 Whole plant Tora mouri Lamiaceae Whole plant Plant is ground and the oil is added to cure typhoid fever. Decoc-tion is used for cough.
24 Viola kunawarensis Royle
Gul-e-Banafsha Violaceae Leaves and sap Useful to treat pain and swelling of liver. Also to treat stomach-ache.
25 Ziziphora clinopodioides Lam
Spina mourai Laminaceae Whole plant Whole plant is soaked in water, and decoction is given to chil-dren to reduce their thirst. Good for motion and gastric prob-lems.
26 Z. tenuior (L.) Mourai Laminaceae Seeds Seeds are used to cure dysentery.
* Vernacular name is in Pashto, Pushto or Pakh
and leaves of Peganum harmala are good for stomach and leg problems, and measles in Zarghoon. This plant is also useful for asthma and bone fractures (Shah et al., 2006). The indig-enous knowledge about Ziziphora clinopodioides in Zarghoon is that it is used for motion and vomiting; an analogous utiliza-tion was reported by Ali & Qaiser (2009). Seeds of Plantago major are cooked with sugar and butter, and fed to infants to control appetite, phlegm and cough. Tonic made from seeds is useful for dysentery, chest congestion and cough. Abbassi et al. (2005) also reported that P. major is used to control cough, asthma and phlegm.
Conclusions and recommendations. The previous discus-sion clearly indicates that local people are intensively depen-dent on the Juniper ecosystem either for fuel wood or medici-nal plants. However, its utilization is not sustainable because natural resources of the area are heavily exploited. The juniper forest is under a major threat of degradation due to the (1) high rate of deforestation, and (2) comparatively low rate of regeneration.
The study area encompasses a rich biodiversity that includes a large variety of medicinal and other useful plants. Growing medicinal plants both in situ and in vitro is inevitable for the development and conservation of the area. Extensive research must be carried out in the fields of pharmacology, biotech-nology and biochemistry. If it continues, the tremendous de-crease in the transmission of knowledge from local Herbalists to local people can reduce the knowledge of aboriginal people about their natural resources. The community should be aware of the importance of the (1) forest, (2) medicinal plants, and (3) current vulnerability of the forest due to the community activities. The community should be trained about the sus-tainable use of products other than those provided by the tree forest, particularly medicinal plants and their commercializa-tion, which might contribute to raise their economy.
REFERENCESAbbasi, A.M., G. Dastagir, F. Hussain & P. Sanaullah (2005). Eth-
nobotany and marketing of crude drug plants in district Haripur, Pakistan. Pakistan Journal of Plant Science 11: 103-114.
Abbasi, A.M., M.A. Khan, M. Ahmad, M. Zafar, H. Khan, N. Mu-hammad & S. Sultana (2009). Medicinal plants used for the treatment of Jaundice and hepititus based on socioeconomic documentation. African Journal of Biotechnology 8: 1643-1650.
Achakzai, A.K.K. & Z.A. Bazai (2006). Phytoaccumulation of Heavy Metals in Spinach (Spinacia oleracea L.) Irrigated with Wastewater of Quetta City. Journal of Chemical Society of Pakistan 28: 473-477.
Ahmed, M., E.E. Nagi & E.L.M. Wang (1990). Present state of juniper in Rodhmallazi Forest of Balochistan, Pakistan. Pakistan Journal of Forestry 40: 227-236.
Ali, H. & M. Qaiser (2009). The Ethnobotany of Chitral valley, Pakistan, with particular reference to medicinal plants. Pakistan Journal of Botany 41: 2009-2041.
Ali, S.I. & Y.J. Nasir (Eds.). (1989-1992). Flora of Pakistan. No. 191-193. Karachi and Islamabad.
Ali, S.I. & M. Qaiser. (Eds.). 1993-2009. Flora of Pakistan. No. 194-17. Islamabad, Karachi.
Hamayaun M., M.A. Khan & T. Hayat (2005). Ethnobotanical pro-file of Utror and Gabral valleys, district Swat, Pakistan. Ethno-botany leaflets 10: 40-45.
Hunting Survey Corporation.(1960). Reconnaissance Geol-ogy of part of West Pakistan: A Colombo Plan Cooperation Project,Toronto, Canada.
Hussain, K., A.Shahzad & S.Z. Hussnain (2008). An Ethnobotani-cal Survey of important wild medicinal plants of Hattar District Harripur, Pakistan. Ethnobotanical Leaflet 12: 29-35.
Inam, B., K. Sultana, R.A. Qureshi & S.A. Malik (2000). Checklist of plants of Bhogarmong, Siran vally, N.W.F.P., Pakistan. Ham-dard Medicus 43: 62-75.
Leporatti, M.L. & E. Lattanzi.(1994). Traditional Phytotherapy on coastal areas of Makran (Southern Pakistan). Fitoterpia 65: 158-161.
74
FYTON ISSN 0031 9457 (2013) 82: 69-74
Bazai ZA et al., FYTON 82 (2013)
Malik, S., M. Shah & Q. Marwat (1990). Ethnobotanical Evalua-tion of Valuable Plants of Balochistan, Pakistan. Project No. 123, Pakistan Science Foundation.
Marcoux. A. (2000). “Population and deforestation”. SD Dimen-sions. Sustainable Development Department, Food and Agricul-ture Organization of the United Nations (FAO).
Mukherjee, N. (1994). Participatory Rural Appraisal Methodology and Applications. 2nd edition, Ashok Kumar Concept Publishing Company, New Delhi India, 30 p.
Nasir, E. & S.I. Ali. (Eds.). 1970-1979. Flora of West Pakistan. No. 1-131. Islamabad, Karachi.
Nasir, E. & S.I. Ali. (Eds.). 1980-1989. Flora of Pakistan. No. 132-190. Islamabad, Karachi.
Shah, S.R.U., G. Hassan, A. Rehman & I. Imtiaz (2006). Ethno-botanical studies of the flora of Musakhail and Barkan in Balo-chistan, Pakistan. Pakistan Journal of Weed Science Research 12: 199-211.
Shah, G.M. & M.A. Khan (2006). Common medicinal recipies of Siran valley, Mansera, Pakistan. Ethnobotany Leaflets 10: 63-71.
Shinwari, Z.K. & S. Malik (1989). Plant Wealth of Dera Bugti area. Progressive Farming 9: 39-42.
Tareen, R.B., K. Mohammad & M.I. Zaidi (2002a). Plant Commu-nities, species diversity, medicinal plants and soil relationship of water courses in Shireen valley, Juniper ecosystem, Ziarat Balo-chistan. Research Journal University of Balochistan 1: 41-47.
Tareen, R.B., M.I. Zaidi, M.A.K. Malghani, Q.A. Ali & M. Asif. (2002b). Ethnobotanical studies of medicinal and aromatic plants of Juniper ecosystem, Ziarat Balochistan. Research Journal Uni-versity of Balochistan 1: 17-23.
International Journal of Basic & Applied Sciences IJBAS-IJENS Vol:12 No:05 38
128105-6363- IJBAS-IJENS @ October 2012 IJENS I J E N S
Abstract— This research was carried out through field survey
in surrounding forest localities of five villages named Killi Tor
Shore (K.T.S.), Medadzai (M), Ghunda (G), Sarobai (S) and Killi
Shaban (K.S.) in study area Zarghoon Juniper ecosystem.
Different physical characteristics of Juniperus excels trees were
recorded. Rate of deforestation was maximum at (K.S.) with 6.69,
and minimum at (M) with 4.70, along with 5.95, 5.66 and 4.81 at
(K.T.S.), (G) and (S.) respectively. Average Diameter at Breast
Height (DBH) in inches measured at five locations were from
highest to lowest as 37.13 at KS, 36.86 at S, 32.40 at KTS, 31.96 at
G, and 29.40 at M respectively. Sheep made the dominant
livestock population of 23%, donkey 2% and goat population was
75%. The community prefers to keep goats because the sheep
feed on soft grasses which were not easily available in these areas.
There was statistically insignificant variance in the average
(DBH) in all five selected locations due to same atmospheric
conditions. Old and New Regeneration ground cover percentage
was less due to the high anthropogenic pressure on forest for
different uses like lopping for Timber 28%, fuel wood 56%,
debarking 11% and fencing 5% of juniper tree the situation was
equally treacherous. Based on findings it was suggested that
existing high anthropogenic pressure on ecosystem can be
abridged by regulations implementations and financial assistance
for sustainable recourse utilization to the unique juniper
ecosystem of Zarghoon.
Index Term— Anthropogenic, Regeneration, Diameter at
Breast Height (DBH), Deforestation, Conservation
I. INTRODUCTION
Juniper forests always served as an important source of wood
for construction, cooking and fuel over ages but they are
subjected to over exploitation, heavy grazing and fires; while
Zahoor Ahmed Rasool Bakhsh Tareen and Muhammad Younas Khan
Barozai are with the department of botany at the university of Balochistan,
Quetta (87300) Pakistan.
Huma Batool is with the department of botany at the Sardar Bahadur Khan
Women University Quetta (87300) Pakistan.
ACKNOWLEDGMENT
The Financial support by Higher Education Commission (HEC), Pakistan
is highly acknowledged.
silivi-cultural practices or other management practices are
lacking. Juniper is the most prominent type of vegetation at or
above 1600 m elevation [1].
Junipers can tolerate poor soils and can survive at extremely
high and low temperatures in comparison to other forest trees.
In addition, they are highly resistant and they are the last
species that abandon areas in the process of deforestation [2].
The natural distribution of this species varies between 300-
3500m latitudes uprightly [3] [4] [5]. Within this wide
distribution area the juniper trees display great variety in
different soils and climatic conditions.
Particularly in juniper forest zones with extreme climatic
and soil characteristics, shoot/root ratio is fundamental for
biological success. Seedlings planted in arid or semi-arid areas
should have a well-developed root system for better
absorption of water lost from the soil in shoots and leaves [6]
[7] [8]. Afforestation studies on juniper recognized that
seedlings with low shoot/root fresh or dry weight provided
better results, principally in arid areas [9] [10]. In areas where
summer temperatures are high, seedlings with a long root
system are able to reach deeper soil layers comprising
adequate moisture [7].
Population growth and urbanization are amid the foundation
sources of deforestation [11] [12]. British environmentalist
Norman Myers reported, 5% of deforestation is due to cattle
ranching, 19% due to over-heavy logging, 22% due to the
growing sector of palm oil plantations, and 54% due to slash
and- burn farming [13].
Grazed and non-grazed forests express no difference in the
abundance of new and old regeneration [14]. Juniperus tree is
largely acknowledged for its small establishment potential
under the closed canopy of mature parent trees [14] [15]. Its
regeneration is adapted to forest clearing, gaps and forest
edges where there is bright sunlight. Extensive re-growth is
found in intensively logged over forest areas with open
canopies. In the present study the old and new regeneration %
age of the forest ground cover was measured in plots at five
selected villages. The deforestation caused by human activities
was measured by counting the number of fresh cut stumps in
15 plots selected randomly, to measure the future existence
chances of this forest.
Study of Anthropogenic Pressure on
Regeneration and Deforestation to Assess the
Forest Conservation Status at the Zarghoon
Juniper Ecosystem in Balochistan, Pakistan
Zahoor Ahmad Bazai, Rasool Bakhsh Tareen, Huma Batool and Muhammad Younas Khan Barozai
International Journal of Basic & Applied Sciences IJBAS-IJENS Vol:12 No:05 39
128105-6363- IJBAS-IJENS @ October 2012 IJENS I J E N S
II. GEO-CLIMATE OF ZARGHOON REGION
Zarghoon region is located to the southern part of Quetta
valley lies approximately between latitude 30° N and
longitude 67° E. It shields an area of about 354 sq. miles out
of which 86 sq. miles is piedmont 101 sq. miles is valley floor
and the rest is mountain high land. The locality has
tremendous variation from hill top to valley bottoms and
gentle slopes with grasses scattered trees. Rain and snow fall
is dominated in winter; the mean maximum temperature in
summer is 25°C and means minimum temperature in winter is
˗15°C.
A. Material and Methods
In Juniper forest neighboring five villages a total of 15 plots
each of 2 acres at the rate of 3 plots per forest vicinity were
positioned randomly. In each and every plot the density of
mature trees, the individual ground cover of new regeneration
seedlings up to the height of 5 inches and old regeneration
saplings up to 5ft were measured, Diameter at breast height
(DBH), and manmade deforestation of mature trees
documented.
Average ground cover percentages of Old and New
Regeneration were calculated for each location. Deforestation
was calculated by calculating the number of stumps present in
each plot. Data was recorded in pre-designed Performa’s for
each plot separately and subjected to statistical analysis
ANOVA by using SPSS.
Participatory Rural Appraisal PRA techniques for instance,
Semi Structured Interviews (SSI), Focused Group Discussions
(FGD), transact walk, etc. were used to determine the
community’s dependence on the Juniper forest and the profits
they acquire from the forest. The data on livelihood conditions
of the community especially cattle rearing etc. were also
collected using PRA.
III. RESULTS AND DISCUSSION
A. Diameter at Breast Height (DBH)
Average Diameter at breast height of the trees in three plots
at each location was measured. The mean DBH calculated is
shown in Fig. 1. Analysis of Variance was applied on the
obtained data to check if there is a difference in the DBH of
trees in the five locations.
Fig. 1. Average Diameter at Breast Height (DBH) in inches
Average DBH in inches measured at five locations were
from highest to lowest as 37.13 at KS, 36.86 at S, 32.40 at
KTS, 31.96 at G, and 29.40 at M. The ANOVA results show
that at 5% significance level, there was a significant difference
in means DBH in trees of five locations. The Levene test was
applied to check the homogeneity of variances (assumption of
ANOVA). According to the statistical analysis it was
concluded the tree population was homogenous. The ANOVA
result at 5% significance level demonstrated a substantial
difference in mean DBH of trees of five locations.
The Tukey’s post-hoc test was used to compare the mean
DBH in trees of one village to another. The mean DBH of
Medadzai was found to be significant from Sarobai and Killi
Shahban whereas, no significant differences were found
between the mean DBH of other locations. The mean DBH of
Medadzai was considerably lower than those of Sarobai and
Killi Shahban.
B. New Regeneration
Average of Total ground cover percentage by new
regeneration (up to the height of 5 inches) for the three plots
of each location was calculated. The data is presented in Fig.
2.
Fig. 2. Mean New Regeneration Ground Cover %age.
Average new regeneration ground cover %age measured at
five locations were from highest to lowest as 4.07 at KTS,
4.03 at KS, 3.49 at Sarobai, 3.58 at G, and 2.86 at M. The
ANOVA results illustrate that at 5% significance level, there
was a noteworthy difference in mean new regeneration ground
cover %age of five locations. The Levene test was applied to
check the homogeneity of variances (assumption of ANOVA).
It was found that data comes from homogenous population.
The ANOVA result exhibited that at 5% significance level,
there wass a significant difference in means new regeneration
ground cover %age of five locations.
The Tukey’s post-hoc test was used to compare the mean
new regeneration ground cover %age of one village to
another. The mean new regeneration ground cover %age of
Medadzai was found significant from Killi Tor Shore and Killi
Shahban whereas, no significant modifications were found
between the mean new regeneration ground cover %age of
other locations. We can say that the mean DBH of Medadzai
was significantly lower than those of Killi Tor Shore and Killi
Shahban.
C. Old Regeneration
An old Regeneration sapling up to height of 5 feet Ground
Cover %age was measured for trees in three plots at each
location and the mean is represented in Fig. 3. The data was
checked for difference in average old regeneration at five
villages. The data was checked at 95% level of confidence.
There was statistically insignificant difference in old
regeneration % of trees at the five locations. Moreover there
International Journal of Basic & Applied Sciences IJBAS-IJENS Vol:12 No:05 40
128105-6363- IJBAS-IJENS @ October 2012 IJENS I J E N S
was no interaction between the Old regeneration % and the
locality. The mean old regeneration ground cover % calculated
from highest to lowest was 4.75 at Killi Tor Shores, 3.74 at
Sarobai, 3.48 at Killi Shaban, 3.43 at Ghunda, and 3.36 at
Medadzai.
Fig. 3. Mean old Regeneration Ground Cover %age.
The ANOVA results confirm that at 5% significance level,
there was a significant difference in means old regeneration
ground cover %age of five locations. The Levene test was
applied to check the homogeneity of variances (assumption of
ANOVA). It was found that data comes from homogenous
population. The ANOVA result shows that at 5% significance
level, there was a significant difference in means old
regeneration ground cover %age of five locations.
The Tukey’s post-hoc test was used to compare the mean
old regeneration ground cover %age of one village to another.
The mean old regeneration ground cover %age of Medadzai
was found significant from Killi Tor Shore and Killi Shahban
whereas no significant differences were found between the
mean old regeneration ground cover %ages of other locations.
We can say that the mean DBH of Medadzai was significantly
lower than those of Killi Tor Shore and Sarobai.
D. Deforestation
The data was collected for deforestation status in the three
plots for each of the five locations by counting the number of
fresh cut stumps present in each plot.
According to the outcomes obtained the mean deforestation
status of the five selected locations was mean number of cut
stumps as 6.69 at Killi Shaban, 5.95 at Killi Tor Shore, 5.66 at
Ghunda, 4.81 at Sarobai, and 4.70 at Medadzai. There was
statistically insignificant difference in deforestation at the five
locations. Moreover there was no interaction between the
deforestation and the locality. The ANOVA results express
that at 5% significance level, there was a significant difference
in deforestation of five locations. The Levene test was applied
to check the homogeneity of variances (assumption of
ANOVA). It was found that data comes from homogenous
population. The ANOVA result shows that at 5% significance
level, there was a significant difference in means deforestation
of five locations.
Fig. 4. Rate of Deforestation in five localities
The Tukey’s post-hoc test was used to compare the
deforestation of one village to another. The deforestation of
Medadzai was found significant from Killi Tor Shore and Killi
Shahban whereas no significant differences were found
between the deforestation of other locations. Deforestation at
Medadzai was significantly lower than those of Killi Shaban
and Killi Tor Shore.
IV. USES OF JUNIPER TREE’S WOOD BY THE
COMMUNITY
In all the five village data was also composed on the Juniper
forest wood products consumption by the local communities.
The data clearly directed that community consumption of the
wood products was way too plentiful than the regeneration
aptitude of the forest and the situation was further aggravated
by the smuggling of the juniper wood and natural and other
anthropogenic changes in the environment.
The data on forest wood products was collected by using
PRA technique of Focal Group discussion (FGDs) and a group
of 20 persons from each village were selected and a discussion
was generated separately in each village on the consumption
of wood. A large proportion of community population i.e.,
56% used forest wood for fuel, and it was obtained in different
forms for instance; by cutting the stems or branches. 28% for
timber, 11% of the local population uses the tree bark of the
Juniper trees that make the trees vulnerable to diseases and
death ultimately. Another use of Juniper trees was for making
the fencing material around the cultivated area and 5% of
population (farmers).
The data clearly shows the dependency of the deprived
community on the forest resources which were wrecked by the
communities as the underprivileged and uninformed
communities of the area were ignorant of the importance of
the forest for their own livelihood in future.
Grazing was one of the major factors in the area liable for
decline in regeneration %age. It was absolute that local
community was dependent on the forest for feeding their
livestock. According to PRA study made in the area the
livestock were grazed on the forest rangeland for about 7-8
months in a year. Individual number of sheep, goats, cattle and
donkeys was as in the pie chart below. Sheep made the
dominant livestock population of 23%, donkey and cattle 2%
and goat population was 75%.
International Journal of Basic & Applied Sciences IJBAS-IJENS Vol:12 No:05 41
128105-6363- IJBAS-IJENS @ October 2012 IJENS I J E N S
Fig. 5. Pie Chart Showing Percentage of Different Uses of Juniper Tree’s
Wood by the Community
Fig. 6. Livestock population
V. DISCUSSION
Forest trees regenerate in their natural habitats. However,
natural regeneration of tree species occurs in suitable
environmental conditions for germination, seed production,
and growth [16]. Regeneration of Junipers was seemingly very
poor which is in line with the findings of [17]. Authors in [18]
suggested climatic change as a possible reason for the poor
regeneration of Juniperus excelsa. Natural regeneration may
be affected by the difficult seed germination due to drought,
increasing recreation activity through forests and over-grazing
these findings are in accordance with [19] who reported that
the Juniper seedlings can survive 150 mm rainfall a year, but
they cannot survive a ”drought” lasting longer than 2-3 weeks.
Human disturbance, grazing pressure and climatic change
are the factors that could lead to poor regeneration of
Juniperus as also reported by [18]. The regeneration of natural
forests is possible by reforestation of the gaps in these forests
with endemic species. These suggestions concurs with [20]’s
thought that conservation of the natural forests need proper
attention and research in these forests should focus in
improving natural regeneration of the various species and
conservation of bio-diversity. Juniper seedlings grow very
slowly, a few centimeters a year only same was reported by
[19].
Population growth and poverty are main causes of the
deforestation in the study area as also asserted by [21]. Juniper
trees are the main source of fuel for the local community and
demand for wood greatly exceeds that which the forest
resources can sustainably supply, these findings are in accord
with [21] [22] [23]. Juniper forests are small and fragmented
in its natural habitat due to anthropogenic pressure (mainly
logging) in accord to [24].
VI. CONCLUSION
The results of the present trial specified that improving regeneration of Juniperus excelsa trees in Zarghoon Juniper
forest is possible through protection of natural forest from
anthropogenic disturbance. However, it can be concluded that
the Juniper forest is under major threat of dilapidation due to
high rate of deforestation and reasonably low rate of
regeneration. Grazing and anthropogenic deforestation are
only some of the important factors, there are many other
natural factors like diseases and changing environment. The
matchless Zarghoon juniper forest is in dire need of research
for conservation and planning best management practices for
sustainable consumption of forest resources.
REFERENCES
[1] S. Chaudhary, “Flora of the kingdom of saudi arabia,” National
Agriculture and Water Research Centre, Ministry of Agriculture, Saudi
Arabia, Tech. Rep., 1997.
[2] B. Pamay, “Turkiye ardic turleri ve yayililari,” U Orman Fakultesi
Dergisi, Tech. Rep., 1955.
[3] G. Elicin, “Turkiye doal ardic (juniperus l.) taksonlarinin yayililari ile
onemli morfolojik ve anatomik ozellikleri uzerine araitirmalar.”
stanbul,Turkey, Tech. Rep., 1977.
[4] H. Kayacik, “Orman ve park aaclari ozel sistematii,” U Orman Fakultesi
Yayinlari, Tech. Rep., 1980.
[5] S. Al-Shamrary, “Methods of protecting soil from drifting in al-sarah
region in the southwestern saudi arabia,” in Desert Studies in Saudi
Arabia. The Desert Studies Centre, King Saud University, Riyadh, Saudi
Arabia, 2-4 Oct. 1994, pp. 248–312.
[6] R. Hermann, “Importance of top-root ratios for survival of douglas-fir
seedlings,” Tree Planters Notes, vol. 64, pp. 7–11, 1964.
[7] R. F. B. C. Baer, N., “Effects of watering, shading, and size of stock on
survival of planted lodgepole pine,” USDA Forest Serv., Rocky Mt.,
Forest and Range Exp. Sta., Fort Collins, Colorado, Tech. Rep., 1977.
[8] B. R. H. D. Hobbs, S.D. and C. Freost, “First year performance of -0
containerized douglas-fir seedlings on droughty sites in southwestern
oregon,” Oregon State Univ., Forest Res. Lab., Corvallis, Res. Pap., vol.
42, 1980.
[9] Z. Yahyaolu and M. Genc, “Fidan standardizasyonu, standart fidan
yetitirmenin biyolojik ve teknik esaslari,” SDU Orman Fakultesi Yayini,
Isparta, Turkey., Tech. Rep., 2007.
[10] H. Gultekin, “Turkiye ardic (juniperus l.) turlerinin ekolojisi ve
silvikultur teknikleri. orman muhendisleri odasi yayini,” Ankara,
Turkey, Tech. Rep., 2007.
[11] A. Marcoux, “Population and deforestation,” Sustainable Development
Department, Food and Agriculture Organization of the United Nations
(FAO), Tech. Rep., 2000.
[12] M. Ehrhardt, “Demographics, democracy, development, disparity and
deforestation: A crossnational assessment of the social causes of
deforestation,” in Annual meeting of the American Sociological
Association, Atlanta, GA, Aug 2003.
[13] J. Hance, “Tropical deforestation is one of the worst crises since we
came out of our caves,” in A Place Out of Time: Tropical Rainforests
and the Perils They Face, 2008.
[14] D. Taketay and T. Bekele, “Floristic composition of wof-washa natural
forest, central ethiopia: Implications for the conservation of
biodiversity,” Feddes report, Berlin Germany, Tech. Rep. 106-1-2, 1995.
[15] Friis, Forests and forest trees of northeast tropical Africa. London: Kew
bulletien additional series, 1992.
[16] H. A. Margolis and D. G. Brand, “An ecophysiological basis for
understanding plantation establishment,” Canadian Journal of Forest
Research, vol. 20, pp. 375–390., 1990.
[17] F. A. A. Hajar, A. S. and K. M. Al-Ghamdi, “Impact of biological stress
on juniperus excelsa m. bieb. in south-western saudi arabia: insect
stress,” Journal of Arid Environment, vol. 2 , pp. 27–330., 1991.
[18] A. S. Gardner and M. Fisher, “How the forest lost its trees: Just so
storytelling about juniperus excelsa in arabia,” Journal of Arid
Environments, vol. 26, pp. 299–301, 1994.
[19] M. Herzog, “Shrubland management in tribal islamic yemen. Social
forestry as development of a local and sustainable (sylvi-)culture: An
International Journal of Basic & Applied Sciences IJBAS-IJENS Vol:12 No:05 42
128105-6363- IJBAS-IJENS @ October 2012 IJENS I J E N S
essay in practical philosophy,” Swiss Development Cooperation, Tech.
Rep., 1998.
[20] B. Bishaw, “Deforestation and land degradation on the Ethiopian
highlands: A strategy for physical recovery,” in Abstracts of
international conference on contemporary development Issues in
Ethiopia, Aug 2001, pp. 16–18.
[21] G. Amente, “Rehabilitation and sustainable use of degraded community
forests in the bale mountains of ethiopia,” Ph.D. dissertation, Faculty of
Forest and Environmental Sciences, Albert-Ludwigs University,
Freiburg in Breisgau, Germany, 2005.
[22] I. Thomas and M. Bekele, “Role of planted forests and trees outside
forests in sustainable forest management: Republic of ethiopia country
case study,” FAO, vol. , no. , p. , 200 .
[23] Z. Bradstock, A. and J. Sultan, “From grassroots to government: Farm-
africa’s experiences influencing policy in sub- saharan africa,” London:
FARM-Africa andthe Overseas Development Institute, Policy and
research series, 2007.
[24] A. E. Aboulfatih, H. and A. Hashish, “The influences of grazing on
vegetation and soil of asir highland,” Arab. Gulf J. of Sci. Res., vol. 7b,
no. 1, pp. 69–78, 1989.