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REFERENCES
REFERENCES
Abd-Alla, M.H. (1994). Solubilization of rock phosphates by Rhizobium and
Bradyrhizobium. Folia Microbiologica., 39(1): 53-56.
Abd-Alla, M. H. and Omar, S.A. (2001). Survival of Rhizobia / Bradyrhizobia and
a rock-phosphate solubilizing fungus Aspergillus niger on various
carriers from some agro-industrial wastes and their effects on nodulation
and growth of faba bean and soybean. Journal of Plant Nutrition., 24(2):
261-272.
Abou-Shanab, R.A., Ghozlan, H., Ghanem, K. and Moawad, H. (2005).
Behavior of bacterial populations isolated from rhizosphere of Diplachne
fusca dominant in industrial sites. World Journal of Microbiology and
Biotechnology., 21: 1095-1101.
Achal, V., Savant, V. V. and Reddy, M. S. (2007). Phosphate solubilization by a
wild type strain and UV- induced mutants of Aspergillus tubingensis. Soil
Biology and Biochemistry., 39: 695-699.
Acosta-Martinez, V. and Tabatabai, M. A. (2000). Enzyme activities in a limed
agricultural soil. Biology and Fertility of Soils., 31: 85-91.
Adriano-Anaya, M.L., Salvador-Figueroa, M., Ocampo, J.A. and Garcia-
Romera, I. (2006). Hydrolytic enzyme activities in maize (Zea mays) and
sorghum (Sorghum bicolor) roots inoculated with Gluconacetobacter
diazotrophicus and Glomus intraradices. Soil Biology and Biochemistry.,
38: 879-886.
Agasimani, C.A., Ravishankar, G., Radder, G.D and Sreenivasa, M.N. (1995).
Influence of phosphate solubilizing microorganisms and sources of
202
phosphate on growth and yield of groundnut. Proceedings of National
Symposium, Frontiers in Applied Environmental Microbiology, pp. 161-
163, SES, CUSAT, Cochin.
Ahmad, F and Ahmad, I. (2004). Plant growth promoting activities and tolerance
traits among Azotobacter choroococcum strains associated with
sugarcane rhizosphere. Asian Journal of Microbiology, Biotechnology
and Environmental Sciences., 6(2): 231-236.
Alexander, M. (1978). Introduction to Soil Microbiology. Wiley Eastern Limited,
New Delhi, India. ISBN 0-85226-013-X.
Algawadi, A.R. and Gaur, A.C. (1988). Assosiative effect of Rhizobium and
phosphate solubilizing bacteria on the yield and nutrient uptake of
chickpea. Plant and Soil., 105: 241-246.
Alikhani, H.A., Saleh-Rastin, N. and Antoun, H. (2006). Phosphate solubilizing
activity of rhizobia native to Iranian soils. Plant and Soil., 287: 35-41.
Altomare, C., Norvell, W.A., Bjorkman, T. and Harman, G.E. (1999).
Solubilization of phosphates and micronutrients by the plant-growth-
promoting and biocontrol fungus Trichoderma harzianum Rifai 1295-22.
Applied and Environmental Microbiology., 65(7): 2926-2933.
Anandham, R., Choi, K.W., Gandhi, P.I., Yim, W.J., Park, S.J., Kim, K.A.,
Madhaiyan, M. and Sa, T.M. (2007). Evaluation of shelf life and rock
phosphate solubilization of Burkholderia sp. in nutrient-amended clay,
rice bran and rock phosphate-based granular formation. World Journal
of Microbiology and Biotechnology., 23: 1121-1129.
References 203
Anu and Kundu, B.S. (2005). Development and characterization of lacZ marked
strains of phosphate solubilizing bacteria. Indian Journal of
Microbiology., 45(4): 261-263.
Aparna, V. (2007). Efficacy of phosphate solubilizing bacteria isolated from
vertisols on growth and yield parameters of sorghum. Research Journal
of Microbiology., 2(7): 550-559.
Arangarasan, V., Palaniappan, S.P. and Chelliah, S. (1998). Inoculation effect of
diazotrophs and phosphobacteria on rice. Indian Journal of Microbiology.,
38: 111-112.
Armstrong, D.L. (1988)*. Role of phosphorus in plants. In Better Crops with
Plant Food. Ed. Armstrong, D.L. Potash and Phosphate Institute,
Atlanta, U.S.A., pp. 4-5.
Arnou, D.I. (1953) *. Soil and fertilizer phosphorus in crop nutrition (IV). Ed. WH
Pierre. Noramn, A.G. Acad. Press NY.
Arunachalam, K. Arunachalam, A. and Melkania, N.P. (1999). Influence of soil
properties on microbial populations, activity and biomass in humid
subtropical mountainous ecosystems of India. Biology and Fertility of
Soils., 30: 217-223.
Azcon, R., Azcon-Aguilar, C., Barea, J.M. (1978). Effects of plant hormones
present in bacterial cultures on the formation and responses to VA
enodomycorrhiza. New Phytology., 80: 359-364.
Azcon-Aguilar, C., Gianinazzi-Pearson, V., Fardeau, J.C., and Gianinazzi, S.
(1986). Effect of vesicular-arbuscular mycorrhizal fungi and phosphate-
solubilizing bacteria on growth and nutrition of soybean in a neutral-
204
calcareous soil amended with32
P -45
Ca-tricalcium phosphate. Plant and
Soil., 96: 3-15.
Babana, A.H. and Antoun, H. (2006). Effect of Tilemsi phosphate rock
solubilizing microorganisms on phosphorus uptake and yield of field
grown wheat (Triticum aestivum L.) in Mali. Plant and Soil., 287: 51-58.
Babenko, Y.S., Tyrygina, G.I., Grigoryev, E.F., Dolgikh, L.M. and Borisova, T.I.
(1984). Biological activity physiologo-biochemical properties of bacteria
dissolving phosphates. Microbiologiya., 53: 533-539.
Babu-Khan, S., Yeo, T.C., Martin, W.L., Duron, M.R., Rogers, R.D. and
Goldstein, A.H. (1995). Cloning of a mineral phosphate gene from
Pseudomonas cepacia. Applied and Environmental Microbiology.,
61(3): 972-978.
Bagyaraj, D.J., and Varma, A. (1995). Mineral phosphate solubilization:
agronomic implications, mechanisms and molecular genetics. Advanced
Microbial Ecology., 14: 119-142.
Banik, S. and Dey, B.K. (1982). Available phosphate content of an alluvial soil
as influenced by inoculation of some isolated phosphate solubilizing
microorganisms. Plant and Soil., 69: 353-364.
Barea, J. M., Navarro, E. and Montoya, E. (1976). Production of plant growth
regulators by rhizosphere phosphate-solubilizing bacteria. Journal of
Applied Bacteriology., 40: 129-134.
Barea, J.M., Pozo, M.J., Azcon, R. and Azcon-Aguilar, C. (2005). Microbial co-
operation in the rhizosphere. Journal of Experimental Botany., 56(417):
1761-1778.
References 205
Barea, J.M., Toro, M., Orozoco, M.O., Campos, E. and Azcon, R. (2002). The
application of isotopic (32
P and 15
N) dilution technique to evaluate the
interactive effect of phosphate solubilizing rhizobacteria, mycorrhizal
fungi and Rhizobium to improve the agronomic efficiency of rock
phosphate for legume crops. Nutrient Cycling in Agroecosystems., 63:
35-42.
Barik, S.K. and Purushothaman, C.S. (1998). Phosphatase activity of two
strains of bacteria on orthophosphate enrichment. Proceedings,
National Symposium Frontiers in Applied Environmental Microbiology,
pp. 165-170, SES, CUSAT, Cochin.
Bar-Yosef, B., Rogers, R.D., Wolfram, J.H. and Richman, E. (1999).
Pseudomonas cepacia- mediated rock phosphate solubilization in
kaolinite and montmorillonite suspensions. Soil Science Society of
America Journal., 63: 1703-1708.
Bashan, Y. (1998). Inoculants of plant growth promoting bacteria for use in
agriculture. Biotechnology Advances., 16: 729-770.
Baya, A.M., Boethling, S. and Ramos-Cormenzana, A. (1981). Vitamin
production in relation to phosphate solubilization by soil bacteria. Soil
Biology and Biochemistry., 13: 527-531.
Belimov, A.A., Kojemiakov, A.P. and Chuvarliyeva, C.V. (1995). Interaction
between barley mixed cultures of nitrogen fixing and phosphate
solubilizing bacteria. Plant and Soil., 173: 29-37.
Belyaeva, O.N., Haynes, R.J. and Birukova, O.A. (2005). Barley yield and soil
microbial and enzyme activities as affected by contamination of two
soils with lead, zinc or copper. Biology and Fertility of Soils., 41: 85-94.
206
Bray, R.H., Kurtz, L.T., (1945). Determination of total organic and available
forms of phosphorus in soils. Soil Science., 32: 266-272.
Busman, L., Lamb, J., Randall, G., Rehm, G. and Schmitt, M. (2002)*. The
nature of phosphorus in soils. University of Minnesota Extension
Service.
Cabello, M., Irrazabal, G., Bucsinszky, A.M., Saparrat, M. and Schalamuk, S.
(2005). Effect of an arbuscular mycorrhizal fungus, Glomus mosseae,
and a rock-phosphate-solubilizing fungus, Penicillium thomii, on Mentha
piperita growth in a soilless medium. Journal of Basic Microbiology.,
45(3): 182-189.
Calvaruso, C., Turpault, M., Leclerc, E. and Frey-Klett, P. (2007). Impact of
ectomycorrhizosphere on the functional diversity of soil bacterial and
fungal communities from a forest stand in relation to nutrient
mobilization processes. Microbial Ecology., 54: 567-577.
Canbolat, M.Y., Bilen, S., Cakmaker, R., Sahin, F.and Aydm, A. (2006). Effect
of plant growth-promoting bacteria and soil compaction on barley
seedling growth, nutrient uptake, soil properties an rhizophere
microflora. Biology and Fertility of Soils., 42: 350-357.
Casida, L.E. (1977). Microbial metabolic activity in soil as measured by
dehydrogenase determinations. Applied and Environmental Microbiology.,
34(6): 630-636.
Cattelan, A.J., Hartel, P.G. and Fuhrmann., J.J. (1999). Screening for plant
growth promoting rhizobacteria to promote early soyabean growth. Soil
Science Society of America Journal., 63: 1670-1680.
References 207
Cavalcante, V.A. and Dobereiner J. (1988). A new acid tolerant nitrogen fixing
bacterium associated with sugar cane. Plant and Soil., 108, 23-31.
Chabot, R., Antoun, H. and Cescas, M.P. (1996). Growth promotion of maize
and lettuce by phosphate solubilizing Rhizobium leguminosarum biovar.
phaseoli. Plant and Soil., 184: 311-321.
Chabot, R., Beauchamp, C.J., Kloepper, J.W. and Antoun, H. (1998). Effect of
phosphorus on root colonization and growth promotion of maize by
bioluminescent mutants of phosphate solubilizing Rhizobium
leguminosarum biovar phaseoli. Soil Biology and Biochemistry., 30(12):
1615-1618.
Chatli, A.S., Beri, V. and Sidhu, B.S. (2008). Isolation and characterization of
phosphate solubilizing microorganisms from the cold desert habitat of
Salix alba Linn. in trans Himalayan region of Himachal Pradesh. Indian
Journal of Microbiology., 48: 267-273.
Chen, Y.P., Rekha, P.D., Arun, A.B., Shen, F.T., Lai, W.A. and Young, C.C.
(2006). Phosphate solubilizing bacteria from subtropical soil and their
tricalcium phosphate solubilizing abilities. Applied Soil Ecology., 34:
33-41.
Chen, Z., Ma, S. and Liu, L. (2008). Studies on phosphorus solubilizing activity
of a strain of phosphobacteria isolated from chestnut type soil in China.
Bioresource Technology., 99: 6702-6707.
Chiarini, L., Bevivino, A., Tabacchioni, S. and Dalmastri, C. (1998). Inoculation
of Burkholderia cepacia, Pseudomonas fluorescens and Enterobacter
sp. on Sorghum bicolor: Root colonization and plant growth promotion
of dual strain inocula. Soil Biology and Biochemistry., 30(1): 81-87.
208
Chuang, C.C., Kuo, Y.L., Chao, C.C. and Chao, W.L. (2007). Solubilization of
inorganic phosphates and plant growth promotion by Aspergillus niger.
Biology and Fertility of Soils., 43(5): 575-584. DOI 10. 1007/s00374-
006-0140-3.
Chung, H., Park, M., Madhaiyan, M., Seshadri, S., Song, J., Cho, H. and Sa, T.
(2005). Isolation and characterization of phosphate solubilizing bacteria
from the rhizosphere of crop plants of Korea. Soil Biology and
Biochemistry., 37: 1970-1974.
Coenye, T. and Vandamme, P. (2003). Diversity and significance of
Burkholderia species occupying diverse ecological niches.
Environmental Microbiology., 5(9): 719-729.
Coenye, T., Vandamme, P., Govan, J.R.W. and. LiPuma, J.J.. (2001).
Taxonomy and identification of Burkholderia cepacia complex. Journal
of Clinical Microbiology., 39(10): 3427-3436.
Craven, P.A. and Hayasaka, S.S. (1982). Inorganic phosphate solubilization by
rhizosphere bacteria in a Zostera marina community. Canadian Journal
of Microbiology., 28: 605-610.
Cunningham, J.E. and Kuiack, C. (1992). Production of citric and oxalic acids
and solubilization of calcium phosphate by Penicillium bilaii. Applied and
Environmental Microbiology., 58(5): 1451-1458.
Dadhich, S.K., Somani, L.L. and Verma, A. (2006). Improved soybean yield,
nutrient uptake and P enrichment in soil due to co-inoculation of
phosphate solubilizing bacteria and VAM fungi in a clay loam soil. Indian
Journal of Microbiology., 46(4): 405-408.
References 209
Das, A.C. and Debnath, A. (2006). Effect of systemic herbicides on N2-fixing and
phosphate solubilizing microorganisms in relation to availability of
nitrogen and phosphorus in paddy soils of West Bengal. Chemosphere.,
65: 1082-1086.
Das, A.C. and Mukherjee, D. (1994). Effect of insecticides on the availability of
nutrients, nitrogen fixation and phosphate solubility in the rhizosphere
soil of rice. Biology and Fertility of Soils., 18: 37-41.
Das, A.C. and Mukherjee, D. (1998). Insecticidal effects on soil microorganisms
and their biochemical processes related to soil fertility. World Journal of
Microbiology and Biotechnology., 14: 903-909.
Das, A.C. and Mukherjee, D. (1999). Influence of BHC and fenvalerate on
mineralization and availability of some plant nutrients in soil. Bulletin of
Environmental Contamination and Toxicology., 62: 371-376.
Das, A.C., Debnath, A. and Mukherjee, D. (2003). Effect of herbicides
oxadiazon and oxyfluorfen on phosphate solubilizing microorganisms
and their persistence in rice fields. Chemosphere., 53: 217-221.
Das, J. and Dangar, T.K. (2008). Microbial population dynamics, especially
stress tolerant Bacillus thuringiensis, in partially anaerobic rice field soils
during post harvest period of Himalyan, island, brackish water and
costal habitats of India. World Journal of Microbiology and
Biotechnology., 24(8): 1403-1410, DOI 10.1007/s11274-007-9620-3.
Das, K., Katiyar, V. and Goel, R. (2003a). 'P' solubilization potential of plant
growth promoting Pseudomonas mutants at low temperature.
Microbiological Research., 158: 359-62.
210
Datta, M., Banik, S. and Dhiman, K.R. (2002). Efficacy of a phosphobacterium
(Bacillus firmus) in combination with phosphates and organics on rice
productivity in acidic soils. 17th WCSS, 14-21,symposium no.16, paper
no. 7, Thailand.
Datta, M., Banik, S.and Gupta, R.K. (1982). Studies on the efficiency of a
phytohormone producing phosphate solubilizing Bacillus firmus in
augmenting paddy yield in acid soils of Nagaland. Plant and Soil., 69:
365-373.
Dave, A. and Patel, H.H. (2003). Impact of different carbon and nitrogen sources
on phosphate solubilization by Pseudomonas fluorescens. Indian
Journal of Microbiology., 43(1): 33-36.
De Freitas, J.R., Banerjee, M.R. and Germida, J.J. (1997). Phosphate
solubilizing rhizobacteria enhance the growth and yield but not
phosphorus uptake of canola (Brassica napus L.). Biology and Fertility
of Soils., 24: 358-364.
De Oliveira, A,L,M., Canuto, E,L., Urquiaga, S., Reis, V.M. and Baldani, J.I.
(2006). Yield of micropropagated sugarcane varieties in different soil
types following inoculation with diazotrophic bacteria. Plant and Soil.,
284: 23-32.
Delvasto, P., Valverde, A., Ballester, A., Igual, J.M., Munoz, J.A., Gonzalez, F.,
Blazquez, M.L. and Garcia, C. (2006). Characterization of brushite as a
re-crystalisation product formed during bacterial solubilization of
hydroxyapatite in batch cultures. Soil Biology and Biochemistry., 38:
2645-2654.
Deubel, A., Gransee, A. and Merbach, W. (2000). Transformation of organic
rhizodepositions by rhizosphere bacteria and its influence on the
References 211
availability of tertiary calcium phosphate. Journal of Plant Nutrition and
Soil Science., 163: 387-392.
Dhiman, S.K. and Saraf, M. (2003). Efficacy of mixed culture and single culture
inoculums in solubilization of tricalcium phosphate (TCP) in laboratory
conditions. Asian Journal of Microbiology, Biotechnology and
Environmental Sciences., 6(4): 495-498.
Di Simine, C.D., Sayer, J.A. and Gadd, G.M. (1998). Solubilization of zinc
phosphate by a strain of Psedomonas fluorescences isolated from a
forest soil. Biology and Fertility of Soils., 28: 87-94.
Dilly, O. and Nannipieri, P. (2001). Response of ATP content, respiration rate
and enzyme activities in an arable and forest soil to nutrient additions.
Biology and Fertility of Soils., 34: 64-72.
Donate-Correa, J., Leon-Barrios, M. and Perez-Galdona, R. (2004). Screening
for plant growth-promoting rhizobacteria in Chamaecytisus proliferus
(tagasaste), a forage tree-shrub legume endemic to the Canary Islands.
Plant and Soil., 266: 261-272.
Dubey, S.K. and Billore, S.D. (1992). Phosphate solubilizing microorganisms
(PSM) as inoculants and their role in augmenting crop productivity in
India.-a review. Crop Research., 5: 11-24.
Dwivedi, D. and Johri, B.N. (2003). Antifungals from fluorescent Pseudomonads:
Biosynthesis and regulation. Current Science., 85(12): 1693-1701.
Elkoca, E., Kantar, F. and Sahin, F. (2008). Influence of nitrogen fixing and
phosphorus solubilizing bacteria on the nodulation, plant growth and
yield of chickpea. Journal of Plant Nutrition., 31: 157-171.
212
El-Komy, H.M.A. (2005). Coimmobilization of Azospirillum lipoferum and
Bacillus megaterium for successful phosphorus and nitrogen nutrition of
wheat plants. Food Technology and Biotechnology., 43(1): 19-27.
Fankem, H., Nwaga, D., Deubel, A., Dieng, L., Merbach, W. and Etoa, F.X.
(2006). Occurrence and functioning of phosphate solubilizing
microorganisms from oil palm tree (Elaeis guineesis) rhizosphere in
Cameroon. African Journal of Biotechnology., 5(24): 2450-2460.
Faurie, G. and Fardeau, J.C. (1990). Can acidification associated with
nitrification increase available soil phosphate or reduce the rate of
phosphate fixation. Biology and Fertility of Soils., 10: 145-151.
Fernandez, L.A., Zalba, P., Gomez, M.A. and Sagardoy, M.A. (2007).
Phosphate –solubilization activity of bacterial strains in soil and their
effect on soybean growth under green house conditions. Biology and
Fertility of Soils., 43: 805-809.
Ferrer, M.R., Gonzalez-Lopez, J. and Ramos-Cormenzana, A. (1986). Effect of
some hebicides on the biological activity of Azotobacter vinelandii. Soil
Biology and Biochemistry., 18: 237-238.
Foth, H.D.(1990)*. Fundamentals of Soil Science. 8th John Wiley and Sons, New
York, NY.
Fuentes-Ramirez, L.E., Bustillos-Cristales, R., Tapia-Hernandez, A., Jimenez-
Salgado, T.M., Wang, E.T., Martinez-Romero, E. and Caballero-
Mellado, J. (2001). Novel nitrogen fixing acetic acid bacteria,
Gluconacetobacter johannae sp. nov. and Gluconacetobacter
azotocptans sp. nov. associated with coffe plants. International Journal
of Systematic and Evolutionary Microbiology., 51: 1305-1314.
References 213
Fuentes-Ramı́rez, L.E., Caballero-Mellado, J., Sepulveda, J. and Martı́nez-
Romero, E. (1999). Colonization of sugarcane by Acetobacter
diazotrophicus is inhibited by high N-fertilization. FEMS Microbiology
Ecology., 29: 117-128.
Gaind, S. and Gaur, A.C. (1983). Microbial solubilization of phosphates with
particular reference to iron and aluminium phosphate. Science and
Culture., 49: 210-212.
Gaind, S. and Gaur, A.C. (1990). Influence of temperature on the efficiency of
phosphate solubilizing microorganisms. Indian Journal of microbiology.,
30(3): 305-310.
Gaind, S. and Gaur, A.C. (1990a). Shelf life of phosphate solubilizing inoculants
as influenced by type of carrier, high temperature, and low moisture.
Canadian Journal of Microbiology., 36: 846-849.
Gaind, S. and Gaur, A.C. (1991). Thermotolerant phosphate solubilizing
microorganisms and their interaction with mug bean. Plant and Soil.,
133: 141-149.
Garland, J.L. and Mills, A.L. (1991) Classification and characterization of
heterotrophic microbial communities on the basis of patterns of
community-level sole-carbon-source utilization. Applied Environmental
Microbiology., 57: 2351-2359.
Gaur, A.C. (1990). Phosphate solubilizing microorganisms as biofertilizers.
Omega Scientific Publishers, New Delhi, pp 176.
Gaur, A.C. and Gaind, S. (1983). Microbial solubilization of phosphate with
particular reference to iron and aluminium phosphate. Science and
Culture., 49: 110-112.
214
Gaur, A.C. and Sachar, S. (1980). Effect of rock phosphate and glucose
concentration on phosphate solubilization by Aspergillus awamori.
Current Science., 49: 553-554.
Gaur, A.C. and Sachar, S. (1980). Effect of rock phosphate and glucose
concentration on phosphate solubilization by Aspergillus awamori.
Current Science., 49: 553-554.
Gaur, A.C., Arora, D. and Prakash, N. (1979). Electron microscopy of some rock
phosphate dissolving bacteria and fungi. Folia Microbiologica., 24: 314-
317.
Gaur, Y.D., Sen, A.N. and Subba Rao, N.S. (1980). Improved legume-rhizobium
symbiosis by inoculating preceding cereal crop with rhizobium. Plant
and Soil., 54: 313-316.
Gautam, P., Agnihotri, A.K. and Pant, L.M. (2003). Effect of phosphorus rate
and Pseudomonas species in combination with Bradyrhizobium
japonicum and farmyard manure on seed yield and yield attributes of
soybean (Glycine max). Indian Journal of Agricultural Sciences., 73(8):
426-428.
Gibson, B.R. and Mitchell, D.T. (2004). Nutritional influences on the
solubilization of metal phosphate by ericoid mycorrhizal fungi.
Mycological Research., 108(8): 947-954.
Glick, B.R. (1995). The enhancement of plant growth by free living bacteria.
Canadian Journal of Microbiology., 41: 109-117.
Goenadi, D.H., Siswanto and Sugiarto, Y. (2000). Bioactivation of poorly soluble
phosphate rocks with a phosphorus solubilizing fungus. Soil Science
Society of America Journal., 64: 927-932.
References 215
Goldstein, A.H. (1995). Recent progress in understanding the molecular
genetics and biochemistry of calcium phosphate solubilization by Gram
negative bacteria. Biological Agriculture and Horticulture., 12: 185-193.
Goldstein, A.H. and Liu, S.T. (1987). Molecular cloning and regulation of a
mineral phosphate solubilizing gene from Erwinia herbicola.
Biotechnology., 5: 72-74.
Goldstein, A.H., Braverman, K. and Osorio, N. (1999). Evidence for mutualism
between a plant growing in a phosphate-limited desert environment and
a mineral phosphate solubilizing (MPS) rhizobacterium. FEMS
Microbiology Ecology., 30: 295-300.
Gordon, S.A. and Weber, R.P. (1951). Colorimetric estimation of indole
aceticacid. Plant Physiology; 26: 192-195.
Gothwal, R.K., Nigam, V.K., Mohan, M.K., Samuel, D. and Ghosh, P. (2006).
Phosphate solubilizaion by rhizospheric bacterial isolates from
economically important desert plants. Indian Journal of Microbiology.,
46(6): 355-361.
Goyal, S., Kapoor, K.K., Singh, D. and Mundra, M.C. (1998). Influence of crop
rotations on soil microbial biomass and microbial activities. Indian
Journal of Microbiology., 38: 217-220.
Gulati, A., Rahi, P. and Vyas, P. (2008). Characterization of phosphate
solubilizing fluorescent Pseudomonads from the rhizosphere of
seabuckthorn growing in the cold deserts of Himalayas. Current
Microbiology., 56(1): 73-79. DOI 10. 1007/s00284-007-9042-3.
216
Gulati, S.L., Mishra, S.K., Gulati, N. and Tyagi, M.C. (2001). Effect of inoculation
of plant growth promoting rhizobacteria on cowpea. Indian Journal of
Microbiology., 41: 223-224.
Guo, F. and Yost, R.S. (1998). Partitioning soil phosphorus into three discrete
pools of differing availability. Soil Science., 163: 822-833.
Gupta, A., Meyer, J.M. and Goel, R. (2002). Development of heavy metal
resistant mutants of phosphate solubilizing Pseudomonas sp. NBRI
4014 and their characterization. Current Microbiology., 45: 323-327.
Gupta, N., Gaholt, R., Lakshminarayana, K. and Narula, N. (1994). Pesticide
resistance among Azotobacter chorocooum soil isolates and mutants.
Microbiological Research., 149, 391-393.
Gupta, R., Singal, R., Shankar, A., Kuhad, R.C. and Saxena, R.K. (1994a). A
modified plate assay for screening phosphate solubilizing
microorganisms. Journal of General and Applied Microbiology., 40: 255-
260.
Gyaneshwar, P., Naresh Kumar, G. and Parekh, L.J. (1998). Effect of buffering
on the phosphate-solubilizing ability of microorganisms. World Journal
of Microbiology and Biotechnology., 14: 669-673.
Gyaneshwar, P., Naresh Kumar, G., Parekh, L.J. and Poole, P.S. (2002). Role
of soil microorganisms in improving P nutrition of plants. Plant and Soil.,
245: 83-93.
Gyaneshwar, P., Parekh, L.J., Archana, G., Poole, P.S., Collins, M.D., Hutson,
R.A. and.Naresh Kumar, G. (1999). Involvement of a phosphate
starvation inducible glucose dehydrogenase in soil phosphate
References 217
solubilization by Enterobacter asburiae. FEMS Microbiology Letters.,
171:223-229.
Halder, A.K. and Chakrabarty, P.K. (1993). Solubilization of inorganic
phosphates by Rhizobium. Folia Microbiologica., 38: 325-330.
Halder, A.K., Mishra, A.K., Bhattachryya, P. and Chakrabartty, P.K. (1990).
Solubilization of rock phosphate by Rhizobium and Bradyrhizobium.
Journal of General and Applied Microbiology., 36: 81-92.
Halder, A.K., Misra, A.K. and Chakrabarty, P.K. (1992). Role of ammonium and
nitrate on release of soluble phosphate from hydroxyapatite by
Rhizobium and Bradyrhizobium. Journal of Basic Microbiology., 32:
325-330.
Halvorson, H.O., Keynan, A. and Kornberg, H.L. (1990). Utilization of calcium
phosphate for microbial growth at alkaline pH. Soil Biology and
Biochemistry., 22: 887-890.
Hamdali, H., Bouizgarne, B., Hafidi, M., Lebrihi, A., Virolle, M.J. and Ouhdouch,
Y. (2008). Screening for rock phosphate solubilizing Actinomycetes from
Moroccan phosphate mines. Applied Soil Ecology., 38: 12-19.
Hameeda, B., Reddy, Y.H.K., Rupela, O.P., Kumar, G.N. and Reddy, G. (2006).
Effect of carbon substrates on rock phosphate solubilization by bacteria
from composts and macrofauna. Current Microbiology., 53: 298-302.
Hameeda, B., Srijana, M., Rupela, O.P. and Reddy, G. (2007). Effect of bacteria
isolated from composts and macrofauna on sorghum growth and
mycorrhizal colonization. World Journal of Microbiology and
Biotechnology., 23: 883-887.
218
Haque, N.A. and Dave, S.R. (2005). Ecology of phosphate solubilizers in semi-
arid agricultural soils. Indian Journal of Microbiology., 45(1): 27-32.
Hariprasad, P and Niranjana, S.R. (2009). Isolation and characterization of
phosphate solubilizing rhizobacteria to improve plant health of tomato.
Plant and Soil., 316: 13-24.
Harris, J.N., New, P.B. and Martin, P.M. (2006). Laboratory test can predict
beneficial effects of phosphate solubilizing bacteria on plants. Soil
Biology and Biochemistry., 38: 1521-1526.
He, Z.L., Bian, W. and Zhu, J. (2002). Screening and identification of
microorganisms capable of utilizing phosphate absorbed by goethite.
Communications in Soil Science and Plant Annals., 33(5&6): 647-663.
Hebbar, K.B. (2003). Effect of long duration water logging on growth and yield of
upland (Gossypium hirsutum) cotton varieties at early seedling and
flowering stages. Indian Journal of Agricultural Science., 73(3): 172-174.
Hinsinger, P. (2001). Bioavailability of soil inorganic P in the rhizosphere as
affected by root induced chemical changes: a review. Plant and Soil.,
237: 173-195.
Holt, J.G., Krieg, N.R., Sneath, P.H.A., Staloj, J.T and Williams, S.T. (1994).
Bergey‟s Manual of Determinative Bacteriology- 9th Ed. Williams and
Wilkins. Baltimore/London.
Horst, W.J., Kamh, M., Jibrin, J.M. and Chude, V.O. (2001). Agronomic
measures for increasing P availability to crops. Plant and Soil., 237:
211-223.
References 219
Hu, X., Chen, J. and Guo, J. (2006). Two phosphate and potassium solubilizing
bacteria isolated from Tianmu Mountain, Zhejiang, China. World journal
of Microbiology and Biotechnology., 22: 983-990.
Husen, E. (2003). Screening of soil bacteria for plant growth promotion activities
in vitro. Indonesian Journal of Agricultural Science., 4(1): 27-31.
Hwangbo, H., Park, R.D., Kim, Y.W., Rim, Y.S., Park, K.H,, Kim, T.H., Suh, J.S
and Kim, K.Y. (2003). 2-Ketogluconic acid production and phosphate
solubilization by Enterobacter intermedium. Current Microbiology.,
47: 87-92.
Igual, J.M., Valvarde, A., Cervantes, E. and Velazquez, E. (2001). Phosphate-
solubilizing bacteria as inoculants for agriculture: use of updated
molecular techniques in their study. Agronomy., 21: 561-568.
Illmer, P and Schinner, F. (1995a). Phosphate solubilizing microorganisms
under non-sterile conditions. Bodenkultur., 46(3): 197-204.
Illmer, P. and Schinner, F. (1995b). Solubilization of inorganic calcium
phosphates- solubilization mechanisms. Soil Biology and Biochemistry.,
27(3): 257-263.
Illmer, P. and Shinner, F. (1992). Solubilization of inorganic phosphates by
microorganisms isolated from forest soil. Soil Biology and Biochemistry.,
24(4): 389-395.
Illmer, P., Barbato, A. and Schinner, F. (1995). Solubilization of hardly-soluble
AlPO4 with P-solubilizing microorganisms. Soil Biology and
Biochemistry., 27(3): 265-270.
Jackson, M.L. (1973). Soil chemical analysis. Prentice Hall, New Delhi, India.
220
Jacobsen, C.S. (1997). Plant protection and rhizosphere colonization of barley
by seed inoculated herbicide degrading Burkholderia (Pseudomonas)
cepacia DBO1(pRO101) in 2,4-D contaminated soil. Plant and Soil.,
189: 139-144.
Jat, B.L. and Shaktawat, M.S. (2003). Effect of residual phosphorus, sulphar
and biofertilizers on productivity, economics and nutrient content of pearl
millet (Pennisetum glaucum) in fenugreek (Trigonella foenum-graecum)-
pearl millet cropping sequence. Indian Journal of Agricultural Sciences.,
73(3): 134-137.
Jat, R.S. and Ahlawat, I.P.S. (2004). Effect of vermicompost, biofertilizer and
phosphorus on growth, yield and nutrient uptake by gram (Cicer
arietinum) and their residual effect on fodder maize (Zea mays). Indian
Journal of Agricultural Sciences., 74(7): 359-361.
Jayasinghearachchi, H.S. and Seneviratne, G. (2006). Fungal solubilization of
rock phosphate is enhanced by forming fungal-rhizobial biofilms. Soil
Biology and Biochemistry., 38: 405-408.
Jeon, J.S., Lee, S.S., Kim, H.Y., Ahn, T.S and Song, H.G. (2003). Plant growth
promotion in soil by some inoculated microorganisms. The Journal of
Microbiology., 41(4): 271-276.
Jimenez-Salgado T., Fuentes-Rameriz, L.E., Tapia-Hernandez, A., Mascarua,
M.A., Martinez-Romero, E. and Cabellero-Mellado, J. (1997). Coffe
arabica L., a new host plant for Acetobacter diazotrophicus and detect
its occurrence in plat tissues. Canadian Journal of Microbiology., 63:
3676-3683.
Jisha, M.S. and Mathur, R.S. (2005). Effect of phosphate solubilizing
microorganisms (PSM) on mineral phosphate solubilization and on
References 221
productivity of wheat (Triticum aestivum). Asian Journal of Microbiology,
Biotechnology and Environmental Sciences., 7(4): 609-612.
Johri, J.K., Surange, S. and Nautiyal, C.S. (1999). Occurrence of salt, pH, and
temperature tolerant, phosphate solubilizing bacteria in alkaline soils.
Current Microbiology., 39: 89-93.
Jorquera, M.A., Hernandez, M.T., Rengel, Z., Marschner, P. and Mora, M.L.
(2008). Isolation of culturable phosphobacteria with both phytate-
mineralisation and phosphate –solubilization activity from the
rhizosphere of plants grown in a volcanic soil. Biology and Fertility of
Soils., 44: 1025-1034, DOI 10.1007/s00374-008-0288-0.
Joseph, S. and Jisha, M.S. (2007). Selected pesticides inhibit phosphate
solubilizing activity of Gluconacetobacter sp. and Brkholderia
plantarri. Asian Journal of Bioscience., 2(2): 149-155.
Jung, I., Park, D.H. and Park, K. (2002). A study of the growth condition and
solubilization of phosphate from hydroxylapatite by Pantoea
agglomerans. Biotechnology and Bioprocess Engineering., 7: 201-205.
Kalam, A., Tah, J. and Mukherjee, A.K. (2004). Pesticide effects on microbial
population and soil enzyme activities during vermicomposting of
agricultural waste. Journal of Environmental Biology., 25(2): 201-208.
Karaca, A, David C. Naseby and Lynch, J.M. (2002). Effect of cadmium
contamination with sewage sludge and phosphate fertilizer
amendments on soil enzyme activities, microbial structure and available
cadmium. Biology and Fertility of Soils., 35: 428-434.
222
Katiyar, V. and Goel, R. (2003). Solubilization of inorganic phosphate and plant
growth promotion by cold tolerant mutants of Pseudomonas
fluorescens. Microbiological Research., 158: 163-168.
Katznelson, H and Bose, B. (1959). Metabolic activity and phosphate dissolving
capability of bacterial isolates from wheat roots, rhizosphere and non
rhizosphere soil. Canadian Journal of Microbiology., 5: 79-85.
Kaushik, P., Yadav, Y.K., Dilbaghi, N.and Grag, V.K. (2008). Enrichment of
vermicomposts prepared from cow dung spiked solid textile mill sludge
using nitrogen fixing and phosphate solubilzing bacteria.
Environmentalist., 28: 283-287 DOI 10.1007/s10669-007-9141-5.
Kennedy, I.R., Choudhury, A.T.M.A.and Kecskes, M.L. (2004). Non-symbiotic
bacterial diazotrophs in crop-farming systems: can their potential for
plant growth promotion be better exploited. Soil Biology and
Biochemistry., 36: 1229-1244.
Khan, M.R. and Khan, S.M. (2001). Biomanagement of Fusarium wit of toamato
by the soil application of certain phosphate solubilizing microorganisms.
International Journal of Pest Management., 47(3): 227-231.
Khan, M.R. and Khan, S.M. (2002). Effects of root-dip treatment with certain
phosphate solubilizing microorganisms on the fusarial wilt of tomato.
Bioresource Technology., 85: 213-215.
Khan, M.S.and Zaidi, A. (2006). Influence of composite inoculations of
phosphate solubilizing organisms and an arbuscular mycorrhizal fungus
on yield, grain protein and phosphorus and nitrogen uptake by
greengram. Archives of Agronomy and Soil Science., 52(5): 579-590.
References 223
Killham, K. (1994). Soil ecology. Cambridge University Press, Cambridge, pp
40-41.
Kim, C.H., Han, S.H., Kim, K.Y., Cho, B.H., Kim, Y.H., Koo, B.S. and Kim. Y.C.
(2003). Cloning and expression of pyrroloquinoline quinine (PQQ)
genes from a phosphate solubilizing bacterium Enterobacter
intermedium. Current Microbiology., 47: 457-461.
Kim, K.Y., Jordan, D. and Krishnan, H.B. (1997a). Rahnella aquatilis, a
bacterium isolated from soybean rhizosphere, can solubilize
hydroxyapatite. FEMS Microbiology Letters., 153: 273-277.
Kim, K.Y., Jordan, D. and Krishnan, H.B. (1998a). Expression of genes from
Rahnella aquatilis that are necessary for mineral phosphate
solubilization in Escherichia coli. FEMS Microbiology Letters., 159: 121-
127.
Kim, K.Y., Jordan, D. and McDonald, G.A. (1998). Enterobacter agglomerans,
phosphate solubilizing bacteria, and microbial activity in soil: effect of
carbon sources. Soil Biology and Biochemistry., 30: 995-1003.
Kim, K.Y., Jordan, D. and McDonald, G.A. (1998b). Effect of phosphate-
solubilizing bacteria and vesicular-arbuscular mycorrhizae on tomato
growth and soil microbial activity. Biology and Fertility of Soils., 26: 79-87.
Kim, K.Y., MaDonald, G.A. and Jordan, D. (1997b). Solubilization of
hydroxyapatite by Entrobacter agglomerans and cloned Escherichia coli
in culture medium. Biology and Fertility of Soils., 24: 347-352.
Kim, Y., Bae, B. and Choung, Y. (2005). Optimization of biological phosphorus
removal from contaminated sediments with phosphate solubilizing
microorganisms. Journal of Bioscience and Bioengineering., 99(1): 23-29.
224
Kohler, J., Caravaca, F., Carrasco, L. and Roldan, A. (2007). Interaction
between a plant growth promoting rhizobacterium, an AM fungus and a
phosphate-solubilizing fungus in the rhizosphere of Lactuca sativa.
Applied Soil Ecology., 35: 480-487.
Kothamasi, D., Kothamasi, S., Bhattacharyya, A., Kuhad, R.C. and Babu, C.R.
(2006). Arbuscular mycorrhizae and phosphate solubilizing bacteria of
the rhizosphere of the mangrove ecosystem of Great Nicobar island,
India. Biology and Fertility of Soils., 42: 358-361.
Kpomblekou, A.K. and Tabatabai, M.A. (1994). Effect of organic acids on the
release of phosphorus from phosphate rocks. Soil Science, 158: 442-
448.
Krishnaraj, P.U. and Gowda, T.K.S. (1990). Occurrence of phosphate-
solubilizing bacteria in the endorhizosphere of crop plants. Current
Science., 59(19): 933-934.
Krishnaraj, P.U., Khanuja, S.P.S. and Sadasivam, K.V. (1995). Construction of
R-prime plasmids complementing mutations in mineral phosphate
solubilization trait(s) of Pseudomonas striata. Proceedings, National
Symposium, Frontiers in Applied Environmental Microbiology, pp. 159-
160, SES, CUSAT, Cochin.
Krishnaraj, P.U., Sadasivan, K.V. and Khanuja, S.P.S. (1999). Mineral
phosphate solubilization defective mutants of Pseudomonas sp. express
pleiotropic phenotypes. Current Science., 76(7): 1032-1035.
Kucey, R.M.N. (1983). Phosphate-solubilizing bacteria and fungi in various
cultivated and virgin alberta soils. Canadian Journal of Soil Science., 63:
671-678.
References 225
Kucey, R.M.N. (1987). Increased phosphorus uptake by wheat and field beans
inoculated with a phosphorus solubilizing Penicillium bilaji strain and
with Vesicular –Arbuscular mycorrhizal fungi. Applied Environmental
Microbiology., 53: 2699-2703.
Kucey, R.M.N., Janzen, H.H. and Leggett, M.E. (1989). Microbiologically
mediated increase in plant available phosphorus. Advances in
Agronomy., 42: 199-228.
Kuklinsky-Sorbal, J., Araujo, W.L., Mendes, R., Geraldi, I.O., Pizzirani-Kleiner,
A.A. and Azevedo, J.L. (2004). Isolation and characterization of
soybean associated bacteria and their potential for plant growth
promotion. Environmental Microbiology., 6(12): 1244-1251.
Kumar, B.S.D and Bezbaruah, B. (1996). Antibiosis and plant growth promotion
by a Pseudomonas strain isolated from soil under tea cultivation. Indian
Journal of Microbiology., 36: 45-48.
Kumar, N.R., Arasu, V.T., and Gunasekaran, P. (2002). Genotyping of
antifungal compounds producing plant growth promoting rhizobacteria,
Pseudomonas fluorescens. Current Science., 82(12): 1463-1466.
Kumar, V. and Narula, N. (1999). Solubilization of inorganic phosphates and
growth emergence of wheat as affected by Azotobacter chroococcum
mutans. Biology and Fertility of Soils., 28: 301-305.
Kumar, V. and Singh, K.P. (2001). Enriching vermicompost by nitrogen fixing and
phosphate solubilizing bacteria. Bioresource Technology., 76: 173-175.
Kumar, V., Behl, R.K. and Narula, N. (2001). Establishment of phosphate
solubilizing strains of Azotobacter chroococcum in the rhizosphere and
226
their effect on wheat cultivars under green house conditions.
Microbiological Research., 156: 87-93.
Kumutha, K., Sundaram, S.P. and Santhanakrishnan, P. (2003). Influence of
AM fungi on leaf biochemical constituents and root phosphatase
activity in mulberry (Morus alba L.). Asian Journal of Microbiology,
Biotechnology and Environmental Sciences., 5(1): 87-90.
Kundu, B.S. and Gaur, A.C. (1980). Establishment of nitrogen fixing and
phosphate solubilizing bacteria in rhizosphere and their effect on yield
and nutrient uptake of wheat crop. Plant and Soil., 57: 223-230.
Kundu, B.S. and Gaur, A.C. (1984). Rice response to inoculation with N2 fixing
and phosphate solubilizing microorganisms. Plant and Soil., 79: 227-234.
Kundu, B.S., Gera, R., Sharma, N., Bhatia, A. and Sharma, R. (2002). Host
specificity of phosphate solubilizing bacteria. Indian Journal of
Microbiology., 42: 19-21.
Laheurte, F. and Berthelin, J. (1988). Effect of a phosphorus solubilizing bacteria
on maize growth and root exudation over four levels of labile
phosphorus. Plant and Soil., 105: 11-17.
Lee, K.J., Kamala-Kannan, S., Sub, H.S., Seong, C.K. and Lee, G.W. (2008).
Biological control of Phytophthora blight in red pepper (Capsicum
annuum L.) using Bacillus subtilis. World Journal of Microbiology and
Biotechnology., 24(7): 1139-1145, DOI 10.1007/s11274-007-9585-2.
Liba, C.M., Ferrara, F.I.S., Manfio, G.P., Fantinatti-Garboggini, F., Albuquerque,
R.C., Pavan, C., Ramos, P.L., Moreira-Filho, C.A. and Barbosa, H.R.
(2006). Nitrogen-fixing chemo-organotropic bacteria isolated from
cyanobacteria-deprived lichens and their ability to solubilize phosphate
References 227
and to release aminoacids and phytohormones. Journal of Applied
Microbiology., 101: 1076-1086.
Lin, T.F., Huang, H.I., Shen, F.T. and Young, C.C. (2006). The protons of
gluconic acid are the major factor responsible for the dissolution of
tricalcium phosphate by Burkholderia cepacia CC-A174. Bioresource
Technology., 97: 957-960.
Lindsay, W.L. (1979)*. Chemical Equilibrium in Soils. Wiley-Interscience, New
York, NY.
Linu, M.S., Stephen, J., Jisha, M.S. (2009). Phosphate solubilizing
Gluconacetobacter sp., Burkholderia sp.and their potential interaction
with cow pea (Vigna unguiculata (L.) Walp.). International Journal of
Agricultural Research., 4(2): 79-87.
Liu, S.T., Lee, L.Y., Tai, C.Y., Hung, C.H., Chang, Y.S., Wolfram, J.H., Rogers,
R. and. Goldstein, A.H. (1992). Cloning of an Erwinia herbicola gene
necessary for gluconic acid production and enhanced mineral
phosphate solubilization in Escherichia coili HB101: nucleotide
sequence and probable involvement in biosynthesis of coenzyme
pyrroloquinoline quinone. Journal of Bacteriology., 174(18): 5814-5819.
Loganathan, P. and Nair, S. (2003). Crop specific endophytic colonization by novel,
salt tolerant, N2-fixing and phosphate solubilizing Gluconacetobacter sp.
from wild rice. Biotechnology Letters., 25: 497-501.
Loganathan, P. and Nair, S. (2004). Swaminathania salitolerans gen. nov.,
sp.nov., a salt tolerant, nitrogen fixing and phosphate- solubilizing
bacterium from wild rice (Porteresia coarctata Tateoka). International
Journal of Systematic and Evolutionary Microbiology., 54: 1185-1190.
228
Loganathan, P., Sunitha , R., Parida, A.K., Nair, S. (1999). Isolation and
characterization of two genetically distinct groups of Acetobacter
diazotrophicus from a new host Eleusine coracana. Journal of Applied
Microbiology., 87: 167-172.
Madejon, E., Burgos, P., Lopez, R. and Cabrera, F. (2001). Soil enzymatic
response to addition of heavy metals with organic residues. Biology and
Fertility of Soils., 34: 144-150.
Madhaiyan, M., Poonguzhali, S., Hari, K., Saravanan, V.S. and Sa, T. (2006).
Influence of pesticides on the growth rate and plant growth promoting
traits of Gluconacetobacter diazotrophicus. Pesticide Biochemistry and
Physiology., 84: 143-154.
Madhaiyan, M., Saravanan, V.S., Jovi, D.B., Lee, H., Thenmozhi, R., Hari, K.
and Sa, T. (2004). Occurrence of Gluconacetobacter diazotrophicus in
tropical and subtropical plants of Western Ghats, India. Microbiological
Research., 159: 233-243.
Maheshkumar, K.S., Krishnaraj, P.U., Algawadi, P.U. (1999). Mineral phosphate
solubilizing activity of Acetobacter diazotrophicus: a bacterium
associated with sugarcane. Current Science., 76: 874-875.
Mao, S., Lee, S.J., Hwangbo, H., Kim, Y.W., Park, K.H., Cha, G.S., Park, R.D.
and Kim, K.Y. (2006). Isolation and characterization of antifungal
substances from Burkholderia sp. culture broth. Current Microbiology.,
53: 358-364.
Martenez De Oliveira, A.L., Canuto, E.L., Urquiaga, S., Reis, V.M. and Baldani,
J.I. (2006). Yield of micropropagated sugarcane varieties in different soil
types following inoculation with diazotrophic bacteria. Plant and Soil.,
284: 23-32.
References 229
Martinez-Toledo, M.V., Salmeron, V. and Gonzalez-Lopez, J. (1992). Effect of
organophosphorus insecticide, phenofos on agricultural soil microflora.
Chemosphere, 24, 71-80.
Mathew, M.M. (2002). Phosphate solubilizing micro-organisms in agriculture.
Indian Farming., 52(9): 35.
Mba, C.C. (1994). Field studies on two rock phosphate solubilizing
Actinomycetes isolates as biofertilizer sources. Environmental
Management., 18(2): 263-269.
McGill, W.B. and Cole, C.V. (1981). Comparative aspects of cycling of organic
C, N, S and P through soil organic matter. Geoderma., 26: 267-286.
McKenzie, R.H. and Roberts, T.L. (1990)*. Soil and fertilizers phosphorus
update. In Proc. Alberta Soil Science Workshop Proceedings,
Edmonton, Alberta. pp: 84-104.
Medeiros, A.F.A., Polidoro, J.C. and Reis, V.M. (2006). Nitrogen source effect
on Gluconacetobacter diazotrophicus colonization of sugarcane
(Saccharum spp.). Plant and Soil., 279: 141-152.
Mehnaz, S. and Lazarovits, G. (2006). Inoculation effects of Pseudomonas
putida, Gluconacetobacter azotocaptans and Azospirillum lipoferum on
corn plant growth under green house conditions. Microbial Ecology., 51:
326-335.
Mehnaz, S., Weselowski, B. and Lazarovits, G. (2006a). Isolation and
identification of Gluconacetobacter azotocaptans from corn rhizosphere.
Systematic and Applied Microbiology., 29: 496-501.
230
Mehta, S. and Nautiyal, C.S. (2001). An efficient method for qualitative
screening of phosphate solubilizing bacteria. Current Microbiology., 43:
51-56.
MIDI (1990). Identification of bacteria by gas chromatography of cellular fatty
acids. Technical notes # 101. MIDI Inc., 115 Barksdale Prof. Center,
Newark, Delaware.
Mikanova, O. and Novakova, J. (2002). Evaluation of the P-solubilizing activity
of soil microorganisms and its sensitivity to soluble phosphate. Rostlinna
Vyroba., 48(9): 397-400.
Miller, L.T. (1982). Single derivatization method for routine analysis of bacterial
whole-cell wall fatty acid methyl esters, including hydroxyl acids. Journal
of Clinical Microbiology., 16: 584-586.
Mishra, U., Choudhary, K.K., Pabbi, S., Dhar, D.W. and Singh, P.K. (2005).
Influence of blue green algae and azolla inoculation on specific soil
enzymes under paddy cultivation. Asian Journal of Microbiology,
Biotechnology and Environmental Sciences., 7(1): 9-12.
Molla, M.A.Z., Chowdhury, A.A., Islam, A. and Hoque, S. (1984). Microbial
mineralization of organic phosphate in soil. Plant and Soil., 78: 393-399.
Morales, A., Alvea, M., Valenzuela E., Rubio, R. and Bori, F. (2007). Effect of
inoculation with Penicillium albidum, a phosphate-solubilizing fungus, on
the growth of Trifolium pratense cropped in a volcanic soil. Journal of
Basic Microbiology., 47: 275-280.
Mullan, A., Quinn, J.P. and McGrath, J.W. (2002). Enhanced phosphate uptake
and polyphosphate accumulation in Burkholderia cepacia grown under
low pH conditions. Microbial Ecology., 44: 69-77.
References 231
Muthukumar, T., Udaiyan, K. and Rajeshkannan, V. (2001). Response of neem
(Azadirachta indica A. Juss) to indigenous arbuscular mycorrhizal fungi,
phosphate solubilizing and symbiotic nitrogen fixing bacteria under
tropical nursery conditions. Biology and Fertility of Soils., 34: 417-426.
Muthukumarasamy, R., Cleenwerck, I., Revathi, G., Vadivelu, M., Janssens, D.,
Hoste, B., Gum, K.U., Park, K.D., Son, C.Y., Sa, T. and Caballero-
Mellado, J. (2005) Natural association of Gluconacetobacter
diazotrophicus and diazotrophic Acetobacter peroxydans with wetland
rice. Systematic and Applied Microbiology., 28: 277-286.
Muthukumarasamy, R., Govindarajan, M., Vadivelu, M. and Revathi, G. (2006).
N-fertilizer saving by the inoculation of Gluconacetobacter
diazotrophicus and Herbaspirillum sp. in micropropagated sugarcane
plants. Microbiological Research., 161: 238-245.
Muthukumarasamy, R., Revathi, G. and Lakshminarasimhan, C. (1999).
Influence of N fertilization on the isolation of Acetobacter diazotrophicus
and Herbaspirillum from Indian sugarcane varieties. Biology and Fertility
of Soils., 29: 157-164.
Nahas, E. (1996). Factors determining rock phosphate solubilization by
microorganisms isolated from soil. World Journal of Microbiology and
Biotechnology., 12(6): 567-572.
Narsian, V. and Patel, H.H. (1995). Inorganic phosphate solubilization by some
yeast. Indian Journal of Microbiology., 35(2): 127-132.
Narsian, V. and Patel, H.H. (1997). Salt tolerance and phosphate solubilizing
activity of Aspergillus aculeatus. Indian Journal of Microbiology., 37:
43-44.
232
Narsian, V. and Patel, H.H. (2006). Biodiversity of phosphate solubilizing
microorganisms in various rhizosphere soils of Bhavnagar district. Asian
Journal of Microbiology, Biotechnology and Environmental Sciences.,
8(2): 201-204.
Narsian, V., Thakkar, J. and Patel, H.H. (1994). Isolation and screening of
phosphate solubilizing fungi. Indian Journal of Microbiology., 34(2):
113-118.
Narula, N., Kumar, V.,. Behl, R.K.,
Deubel, A., Gransee, A. and
Merbach, W.
(2000). Effect of P-solubilizing Azotobacter chroococcum on N, P, K
uptake in P-responsive wheat genotypes grown under greenhouse
conditions. Journal of Plant Nutrition and Soil Science., 163: 393-398.
Narula, N., Deubel, A., Gransee, A. and Merbach, W. (2007)., Phosphate
solubilizing microorganisms: mechanism of solubilization as influenced
by pH, type of organic acid and sugars. Asian Journal of Microbiology,
Biotechnology and Environmental Sciences., 9(2): 397-404.
Naseby, D.C., Moenne-Loccoz, Y., Powell, J., Gara, F.O. and Lynch, J.M.
(1998). Soil enzyme activities in the rhizosphere of field grown sugar
beet inoculated with the biocontrol agent Pseudomonas fluorescences
F113. Biology and Fertility of Soils., 27: 27-39.
Nautiyal, C,S., Bhadauria, S., Kumar, P., Lal, H., Mondal, R. and Verma. D.
(2000). Stress induced phosphate solubilization in bacteria isolated from
alkaline soils. . FEMS Microbiology Letters. 182: 291-296.
Nautiyal, C.S. (1999). An efficient microbiological growth medium for screening
phosphate solubilizing microorganisms. FEMS Microbiology Letters.,
170: 265-270.
References 233
Nguyen, C., Yan, W., Tacon, F. and Lapeyrie, F. (1992). Genetic variability of
phosphate solubilizing activity by monocaryotic and dicaryotic mycelia of
the ectomycorrhizal fungus Laccaria bicolor (Maire) P.D. Orton. Plant
and Soil., 143: 193-199.
Oberson, A., Friesen, D.K., Rao, I.M, Buhler, S. and Frossard, E. (2001).
Phosphorus transformations in an oxisol under contrasting land use
system: The role of microbial biomass. Plant and Soil., 237; 197-210.
Ocampo, J.A., Barea, J.M. and Montoya, E. (1974). Interaction between
Azotobacter and “phosphobacteria” and their establishment in the
rhizosphere as affected by soil fertility. Canadian Journal of
Microbiology., 21: 1160-1165.
Oehl, F., Obeson, M., Probst, A., Fliessbach, H., Roth, R. and Frossad, E.
(2001). Kinetics of microbial phosphorus uptake in cultivated soils.
Biology and Fertility of Soils., 34:31-41.
Omar, S.A. (1998). The role of rock-phosphate-solubilizing fungi and vesicular-
arbuscular-mycorrhiza (VAM) in growth of wheat plants fertilized with
rock phosphate. World Journal of Microbiology and Biotechnology., 14:
211-218.
Omar, S.A. and Abdel-Satar, M.A. (2001). Microbial populations and enzyme
activities in soil treated with pesticides. Water, Air, and Soil Pollution.,
127: 49-63.
Osorio, N.W. and Habte. M. (2001). Synergistic influence of an arbuscular
mycorrhizal fungus and a phosphate solubilizing fungus on growth and
P uptake of Leucaena leucocephala in an oxisol. Arid Land Research
and Management., 15: 263-274.
234
Ouahmane, L., Revel, J.C., Hafidi, M., Thioulouse, J., Prin, Y., Galiana, A.,
Dreyfus, B. and Duponnois, R. (2009). Response of Pinus halepensis
growth, soil microbial catabolic functions and phosphate solubilizing
bacteria after rock phosphate amendment and ectomycorrhizal
inoculation. Plant and Soil., DOI 10. 10007/s11104-008-9882-z.
Pal., S.S. (1998). Interaction of an acid tolerant strain of phosphate solubilizing
bacteria with a few acid tolerant crops. Plant and Soil., 198: 169-177.
Pandey, A. and Palni, L.M.S. (1998). Isolation of Pseudomonas corrugata from
Sikkim Himalaya. World Journal of Microbiology and Biotechnology.,
14: 411-413.
Pandey, A., Das, N., Kumar, B., Rinu, K and Trivedi, P. (2008). Phosphate
solubilization by Penicillium spp. isolated from soil samples of Indian
Himalayan region. World Journal of Microbiology and Biotechnology.,
24(1): 97-102, DOI 10. 1007/s11274-007-9444-1.
Pandey, A., Durgapal, A., Sharma, E. and Palni, L.M.S. (1995). Isolation and
use of growth promoting Rhizobacteria for improved plant performance
in the hills. Proceedings, National Symposium Frontiers in Applied
Environmental Microbiology, pp. 127-130, SES, CUSAT, Cochin.
Pandey, A., Trivedi, P., Kumar, B.and Palni, L.M.S. (2006). Characterization of a
phosphate solubilizing and antagonistic strain of Pseudomonas putida
(B0) isolated from a sub- alpine location in the Indian central Himalaya.
Current Microbiology., 53: 102-107.
Pandey, P., Kang, S.C. and Maheshwari, D.K. (2005). Isolation of endophytic
plant growth promoting Burkholderia sp. MSSP from root nodules of
Mimosa pudica. Current Science., 89(1): 177-180.
References 235
Patel, D.K., Archana, G. and Kumar, G.N. (2008). Variation in the nature of
organic acid secretion and mineral phosphate solubilization by
Citrobacter sp. DHRSS in the presence of different sugars. Current
Microbiology., 56: 168-174. DOI 10.1007/s007-9053-0.
Paul, J.A.J. and Daniel, T. (2007). Lignolytic and phosphate solubilizing
efficiency of fungal species isolated from municipal solid waste. Asian
Journal of Microbiology Biotechnology and Environmental Sciences.,
9(4): 837-840.
Peix, A., Rivas, R., Mateos, P.F., Martinez-Molina, E., Rodriguez-Barrueco, C.
and Velazquez, E. (2003). Pseudomonas rhizosphaerae sp. nov., a
novel species that actively solubilizes phosphate in vitro. International
Journal of Systematic and Evolutionary Microbiology., 53: 2067-2072.
Peix, A., Rivas, R., Mateos, P.F., Martinez-Molina, E., Rodriguez-Barrueco, C.
and Velazquez, E. (2004). Pseudomonas lutea sp. nov., a novel
phosphate-solubilizing bacterium isolated from the rhizosphere of
grasses. International Journal of Systematic and Evolutionary
Microbiology., 54: 847-850.
Peix, A., Rivas-Boyero, A.A., Mateos, P.F., Rodriguez-Barrueco, C., Martinez-
Molina, E. and Velazquez, E. (2001). Growth promotion of chickpea and
barley by a phosphate solubilizing strain of Mesorhizobium
mediterraneum under growth chamber conditions. Soil Biology and
Biochemistry., 33: 103-110.
Peix, A., Velazquez, E. and Martinez-Molina, E. (2002). Molecular methods for
biodiversity analysis of PSB. In: First International Meeting on Microbial
Phosphate Solubilization. Salamanca, Spain, pp 97-100.
236
Perez, E., Sulbaran, M., Ball, M.M. and Yarzabal, L.A. (2007). Isolation and
characterization of mineral phosphate solubilizing bacteria naturally
colonizing a limonitic crust in the south-eastern Venezuelan region. Soil
Biology and Biochemistry., 39: 2905-2914.
Piccini, D. and. Azcon, R. (1987). Effect of phosphate-solubilizing bacteria and
vesicular-arbuscular mycorrhizal fungi on the utilization of Bayovar rock
phosphate by alfalfa plants using a sand-vermiculite medium. Plant and
Soil., 101: 45-50.
Pierre, M.H. (1938)*. Phosphorus deficiency and soil fertility. Soils and Men.
Year Book of Agriculture. pp. 377-396. U.S.D.A., Washington D.C.
Pikovskaya, R.I. (1948). Mobilization phosphorus in soil in connection with vital
activity of some microbial species. Microbiologiya., 17: 362-370.
Pirone, L., Chiarini, L., Dalmastri, C., Bevivino, A. and Tobacchioni, S. (2005).
Detectionof cultured and uncultured Burkholderia cepacia complex
bacteria naturally occurring in the maize rhizosphere. Environmental
Microbiology., 7(11); 1734-1742.
Pitcher, D.G., Saunders, N.A. and Owen, R.J. (1989). Rapid extraction of
bacteria DNA with guanidium thiocyanate. Letters in Applied
Microbiology., 8: 151-156.
Ponmurugan, P. and Gopi, C. (2006). Distribution pattern of phosphate
solubilizing bacteria isolated from different food and forage crops.
Journal of Agronomy., 5(4): 600-604.
Ponmurugan, P. and Gopi, C. (2006a). In vitro production of growth regulators
and phosphatase activity by phosphate solubilizing bacteria. African
Journal of Biotechnology., 5: 850-854.
References 237
Poonguzhali S, Madhaiyan M and Sa, T., (2008). Isolation and identification of
phosphate solubilizing bacteria from chinese cabbage and their effect
on growth and phosphorus utilization of plants. Journal of Microbiology
and Biotechnology., 18(4): 773-777.
Prabha, J., Gowrisankar, R., Palaniappan, R. and Ramesh, S. (2004).
Tolerance and utilization pattern of paddy field bacterial isolates to
combination herbicide formulation -2,4 D and anilfos (oneshot). Asian
Journal of Microbiology, Biotechnology and Environmental Sciences., 6:
127-131.
Purnomo, E., Mursyid, A., Syarwani, M., Jumberi, A., Hashidoko, Y., Hasegawa,
T., Honma, S. and Osaki, M. (2005). Phosphorus solubilizing
microorganisms in the rhizosphere of local rice varieties grown without
fertilizer on acid sulfate soils. Soil Science and Plant Nutrition., 51(5):
679-681.
Raghothama, K.G. (1999). Phosphate acquisition. Annual Review of Plant
Physiology and Plant Molecular Biology., 50: 665-693.
Raghu K and. MacRae, I.C. (1966). Occurrence of phosphate-dissolving micro-
organisms in the rhizosphere of rice plants and in submerged soils.
Journal of Applied Bacteriology., 29(3): 582-586.
Rajagopal, B.S., Brahamprakash, G.P., Reddy, B.R., Singh, U.D. and
Sethunathan, N. (1984). Effect and persistence of selected carbamate
pesticides in soil. Residues Review, 93, 1-9.
Rao, V.U.. and Rao, A.S. (1994). Effects of inoculation with VAM fungi,
phosphorus solubilizing fungus and phosphate amendments on
blackgram and greengram. Indian Journal of Microbiology., 34(4): 313-316.
238
Rashid, M., Khalil, S., Ayub, N., Alam, S. and Latif, F. (2004). Organic acids
production and phosphate solubilization by phosphate solubilizing
microorganisms (PSM) under in vitro conditions. Pakistan Journal of
Biological Sciences., 7(2): 187-196.
Ratti, N., Kumar, S., Verma, H.N. and Gautam, S.P. (2001). Improvement in
bioavailability of tricalcium phosphate to Cymbopogon martinii var. motia
by rhizobacteria, AMF and Azospirillum inoculation. Microbiological
Research., 156: 145-149.
Ravo, A.V. (2002). Conservation of soil productivity through adoption of soil
biotechnological approaches in Indian arid zone. 12th ISCO Conference,
Beijing.
Reyes, I., Bernier, L. and Antoun, H. (2002). Rock phosphate solubilization and
colonization of maize rhizosphere by wild and genetically modified
strains of Penicillium rugulosum. Microbial Ecology., 44: 39-48.
Reyes, I., Bernier, L., Simard, R.R., Tanguay, P. and Antoun, H., (1999).
Characteristics of phosphate solubilization by an isolate of a tropical
Penicillium rugulosum and two UV-induced mutants. FEMS
Microbiology Ecology., 28: 291-295.
Reyes, I., Valery, A. and Valduz, Z. (2006). Phosphate solubilizing
microorganisms isolated from rhizospheric and bulk soils of colonizer
plants at an abandoned rock phosphate mine. Plant and Soil., 287: 69-75.
Rice, W.A., Olsen, P.E. and Leggett. (1994). Co-culture of Rhizobium meliloti
and a phosphorus solubilizing fungus (Penicillium bilaii) in sterile peat.
Soil Biology and Biochemistry., 27(4/5); 703-705.
References 239
Richardson, A.E., Hadobas, P.A. Hayes, J.E., O‟Hara, C.P. and Simpson, R.J.
(2001). Utilization of phosphorus by pasture plants supplied with myo-
inositol hexaphosphate is enhanced by the presence of soil micro-
organisms. Plant and Soil., 229: 47-56.
Rivas, R., Peix, A., Mateos, P.F., Trujillo, M.E., Martinez-Mollina, E. and
Velazquez, E. (2006). Biodiversity of populations of phosphate
solubilizing rhizobia that nodulates chickpea in different Spanish soils.
Plant and Soil. 287: 23-33.
Rivas, R., Trujillo, M.E., Sanchez, M., Mateos, P.F., Martinez-Molina, E.,
Velazquez, E. (2004). Microbacterium ulmi sp. nov., a xylanolytic,
phosphate-solubilizing bacterium isolated from sawdust of Ulmus nigra.,
International Journal of Systematic and Evolutionary Microbiology., 54:
513-517.
Rodriguez, H. and Fraga, R. (1999). Phosphate solubilizing bacteria and their
role in plant growth promotion. Biotechnology Advances., 17: 319-339.
Rodriguez, H., Fraga, R., Gonzalez, T. and Bashan, Y. (2006). Genetics of
phosphate solubilization and its potential applications for improving plant
growth-promoting bacteria. Plant and Soil., 287: 15-21.
Rodriguez, H., Gonzalez, T. and Selman, G. (2000). Expression of a mineral
phosphate solubilizing gene from Erwinia herbicola in two rhizobacterial
strains. Journal of Biotechnology., 84: 155-161.
Rodriguez, H., Gonzalez, T., Goire, I. and Bashan, Y. (2004). Gluconic acid
production and phosphate solubilization by the plant growth-promoting
bacterium Azospirillum spp. Naturwissenschaften., 91: 552-555.
240
Rodriguez, H., Rossoline, G.M., Gonzalez, T., Li, J .and Glick, B.R. (2000a).
Isolation of a gene from Burkholderia cepacia IS-16 encoding a protein
that facilitates phosphatase activity. Current Microbiology., 40: 362-366.
Roesti, D., Gaur, R., Johri, B.N., Imfeld, G., Sharma, S., Kawaljeet, K. and
Aragno, M. (2006). Plant growth stage, fertilizer management and bio-
inoculation of arbuscular mycorrhizal fungi and plant growth promoting
rhizobacteria affect the rhizobacterial community structure in a rain-fed
wheat fields. Soil Biology and Biochemistry., 38: 1111-1120.
Rojas, A., Holguin, G., Glick, B.R. and Bashan, Y. (2001). Synergism between
Phyllobacterium sp. (N2-fixer) and Bacillus licheniformis (P-solubilizer),
both from a semiarid mangrove rhizosphere. FEMS Microbiology
Ecology., 35: 181-187.
Rose, R.E. (1957). Techniques of determining the effect of microorganisms on
insoluble inorganic phosphates. NewZeland Journal of Science and
Technology., 38: 773-780.
Rudresh, D.L., Shivaprakash, M.K. and Prasad, R.D. (2005a). Effect of
combined application of Rhizobium, phosphate solubilizing bacterium
and Trichoderma spp. on growth, nutrient uptake and yield of chickpea
(Cicer aritenium L.). Applied Soil Ecology., 28: 139-146.
Rudresh, D.L., Shivaprakash, M.K. and Prasad, R.D. (2005b). Tricalcium
phosphate solubilizing abilities of Trichoderma spp. in relation to P
uptake and growth and yield parameters of chickpea (Cicer arietinum
L.). Canadian Journal of Microbiology., 51: 217-222.
Russell, E.W. (1980)*. Soil conditions and plant growth. 10th ed. Longman,
London.
References 241
Sahin F., Cakmakci, R. and Kantar, F. (2004). Sugar beet and barley yields in
relation to inoculation with N2 fixing and phosphate solubilizing bacteria.
Plant and Soil., 265: 123-129.
Sahu, S.N. and Jana, B.B. (2000). Enhancement of the fertilizer value of rock
phosphate engineered through phosphate-solubilizing bacteria.
Ecological Engineering., 15: 27-39.
Salih, H.M., Yahya, A. I., Abdul-Rahem, A. M. and. Munam, B. H. (1989).
Availability of phosphorus in a calcareous soil treated with rock
phosphate or superphosphate as affected by phosphate-dissolving
fungi. Plant and Soil., 120: 181-185.
Salles, J.F., Elsas, J.D.V. and Veen, J.A.V. (2006). Effect of agricultural
management regime on Burkholderia community structure in soil.
Microbial Ecology., 52: 267-279.
Saravanan, V.S., Madhaiyan, M., Osborne, J., Thangaraju, M. and Sa, T.M.
(2008). Ecological occurrence of Gluconacetobacter diazotrophicus and
nitrogen fixing Acetobacteraceae members: Their possible role in plant
growth promotion. Microbial Ecology., 55(1): 130-140, DOI:
10.1007/s00248-007-9258.
Sayer, J.A., Kierans, M. and Gadd, G.M. (1997). Solubilization of some naturally
occurring metal-bearing minerals, limescale and led phosphate by
Aspergillus niger. FEMS Microbiology Letters., 154: 29-35.
Sayyed, R.Z., Patel, D.C. and Patel, P.R. (2007). Plant growth promoting
potential of P solubilizing Pseudomonas sp. occurring in acidic soil of
Jalgaon. Asian Journal of Microbiology, Biotechnology and
Environmental Sciences., 9(4): 925-928.
242
Scheffer, F. and Schachtschabel, P (1992)*. Lehrbuch der Bodenkunde.
Ferdinand Enke Verlag, Stuttgart.
Selvakumar, G., Joshi, P., Nazim, S., Mishra, P.K., Bisht, J.K. and Gupta, H.S.
(2009). Phosphate slubilization and growth promotion by Pseudmonas
fragi CS11RH1 (MTCC 8984) a psychrotolerant bacterium isolated from
a high altitude Himalayan rhizosphere. Biologia., 64(2): 239-245.
Selvakumar, G., Kundu, S., Joshi, P., Nazim, S. Gupta, A.D., Mishra, P.K. and
Gupta, H.S. (2008). Characterization of a cold-tolerant plant growth-
promoting bacterium Pantoea dispersa IA isolated from a sub-alpine soil
in the North Western Indian Himalayas. World Journal of Microbiology
and Biotechnology., 24: 955-960.
Sergeeva, E., Danielle, L.M.H. and Nelson, L.M. (2007). Production of indole-3-
acetic acid, aromatic aminoacid aminotransferase activities and plant
growth promotion by Pantoea agglomerans rhizosphere isolates. Plant
and Soil., 297: 1-13.
Seshadri, S. and Ignacimuthu, S. (2004). Effect of nitrogen and carbon sources
on the inorganic phosphate solubilization by different Aspergillus niger
strains. Chemical Engineering Communications., 191: 1043-1052.
Shafiani, S. and Malik, A. (2003). Tolerance of pesticides and antibiotic
resistance in bacteria isolated from waste water- irrigated soil. World
Journal of Microbiology and Biotechnology., 19: 897-901.
Shahab, S. and Ahmed, N. (2008). Effect of various parameters on the
efficiency of zinc phosphate solubilization by indigenous bacterial
isolates. African Journal of Biotechnology., 7(10): 1543-1549.
References 243
Sharan, A., Shikha., Darmwal, N.S. and Gaur, R. (2008). Xanthamonas
compestris, a novel stress tolerant, phosphate solubilizing bacterial
strain from saline-alkali soils. World Journal of Microbiology and
Biotechnology., 24: 753-759, DOI 10.1007/s11274-007-99535-z.
Sharma, A., Ball, B.K. and Ghule, S. (1995). Production and partial
characterization of alkaline phosphatase activity of Micrococcus varians
1 and Citrobacter koseri. Indian Journal of Microbiology., 35(3): 217-224.
Sharma, A., Khokale, D. and Rajput, S. (2002). Characterization of
phosphatases produced by Citrobacter koseri and Micrococcus varians:
the potent phosphate removers. Indian Journal of Microbiology., 42:
117-120.
Sharma, A., Rajput, S., Khokale. D. and Shridhar, D. (2003). Characterization of
alkaline phosphatases of some potent phosphate removers. Journal of
Environmental Biology., 24(3): 253-259.
Sharma, R.P, Datt, N. and Sharma, P. (2003a). Combined application of
nitrogen, phosphorus, potassium and farmyard manure in onion (Allium
cepa) under high hills, dry temperate conditions of north-western
Himalayas. Indian Journal of Agricultural Sciences., 73(4): 225-227.
Sharma, S.N. (2003). Effect of phosphate solubilizing bacteria on efficiency of
Mussoorie rock phosphate in rice (Oryza sativa)- wheat (Triticum
aestivum) cropping system. Indian Journal of Agricultural Sciences.,
73(9): 178-181.
Sharma, S.N. and Prasad, R. (2003). Yield and P uptake by rice and wheat
grown in a sequence as influenced by phosphate fertilization with
diammonium phosphate and mussoorie rock phosphate with or without
244
crop residues and phosphate solubilizing bacteria. Journal of
Agricultural Sciences., 141: 359-369.
Sharma, T.R., Prachi and Singh, B.M. (1999). Application of polymerase chain
reaction in phytopathogenic microbes. Indian Journal of Microbiology.,
39: 79-91.
Sharma, V., Kumar, V., Archana, G. and Kumar, G.N. (2005). Substrate
specificity of glucose dehydrogenase (GDH) of Enterobacter asburiae
PS13 and rock phosphate solubilization with GDH substrates as C
sources. Canadian Journal of Microbiology., 51: 477-482.
Sharpley, A. (2006)*. Agricultural phosphorus management: Protecting
production and water quality. Lesson 34. USDA- Agricultural Research
Service, MidWest Plant Service. Iowa State Unversity, Ames, Iowa.
Shenoy, V.V. and Kalagudi, G.M. (2005). Enhancing plant phosphorus use
efficiency for sustainable cropping. Biotechnology Advances., 23: 501-
513.
Singal, R., Gupta, R., Kuhad, R.C. and Saxena, R.K. (1991). Solubilization of
inorganic Phosphates by a basidiomycetous fungus Cyathus. Indian
Journal of Microbiology., 31(4): 397-401.
Singh, B., Singh, C.P. and Singh, M. (2003). Response of summer moong
(Vigna radiate L.) to levels of phosphorus and PSM inoculation in sandy
loam soil. Annals Agriculture Research New Series., 24(4): 860-866.
Singh, H.P. (1994). Response to inoculation with Bradyrhizobium, vesicular-
arbuscular mycorrhiza and phosphate solubilizing microbes on
soyabean in a Mollosol. Indian Journal of Microbiology., 34(1): 27-31.
References 245
Singh, H.P., Pareek, R.P. and Singh, T.A. (1984). Solubilization of rock
phosphate by phosphate solubilizers in broth. Current Science., 53:
1212-1213.
Singh, K.K. Srinivasarao, C. and Ali, M. (2005). Root growth, nodulation, grain
yield and phosphorus use efficiency of lentil as influenced by
phosphorus, irrigation, and inoculation. Communications in Soil Science
and Plant Analysis., 36: 1919-1929.
Singh, K.N. and Deka, J. (1990). Integrated nutrient supply system for
sustainable crop production. In : Agronomic Research Towards
Sustainable Agriculture (ed. K.N. Singh and R.P. Singh). pp.35, Indian
Society of Agronomy, IARI, New Delhi.
Singh, S. and Kapoor, K.K. (1998). Effects of inoculation of phosphate-
solubilizing microorganisms and an arbuscular mycorrhizal fungus on
mungbean grown under natural soil conditions. Mycorrhiza., 7: 249-
253.
Singh, S. and Kapoor, K.K. (1999). Inoculation with phosphate solubilizing
microorganisms and a vesicular-arbuscular mycorrhizal fungus
improves dry matter yield and nutrient uptake by wheat grown in a
sandy soil. Biology and Fertility of Soils., 28: 139-144.
Singh, S.K. and Rai, J.P.N. (2004). Soil microbial population and enzyme
activity related to gazing pressure in alpine medows of Nanda Devi
biosphere reserve. Journal of Environmental Microbiology., 25(1): 103-
107.
Singh, T. and Rai, R.K. (2004a). Effect of phosphorus levels and phosphate
solubilizing microorganisms on PDFF, „A‟ Value and phosphorus
246
utilization by wheat (Triticum aestivum L.). Annals of Agricultural
Research., 25(3): 339-342.
Sivakumar, U.and Kumutha, K. (2004). Assessment of Rhizophos and
combined inoculation of Rhizobium and phosphobacteria on nodulation
of cowpea (Vigna unguiculata). Journal of Ecobiology., 16(1): 73-74.
Sivaprasad, P. and Meenakumari, K.S. (2005). National work shop on microbial
inoculants for crop nutrition and health, College of Agriculture, Vellayani,
Thiruvananthapuram, Kerala, India pp.116-118.
Snehalatha, V., Boby, V.U. and Balakrishna, A.N. (2004). Changes in soil
enzymes in an alfisol incubated with organic amendments. Asian
Journal of Microbiology, Biotechnology and Environmental Sciences.,
6(2): 249-252.
Son, H.J., Park, G.T., Cha, M.S. and Heo, M.S. (2006). Solubilization of
insoluble inorganic phosphates by a novel salt- and pH–tolerant
Pantoea agglomerans R-42 isolated from soybean rhizosphere.
Bioresource Technology., 97: 204-210.
Souchie, E.L., Saggin, O.J., Silva, E.M.R., Campello, E.F.C., Azcon, R. and
Brea, J.M. (2006). Communities of P-solubilizing bacteria, fungi and
arbuscular mycirrhizal fungi in grass pasture and secondary forest of
Paraty, RJ- Brazil. Annals of the Brazilian Academy of Science., 78(1):
183-193.
Sperber, J.I. (1958). The incidence of apatite solubilizing organisms in the
rhizosphere and soil. Australian Journal of Agricultural Research., 9:
778-781.
References 247
Sposito, G. (1989)*. The chemistry of soils. Oxford University Press, New York,
NY.
Sridevi, M. and Malaiah, K.V. (2009). Phosphate solubilization by Rhizobium
strains. Indian Journal of Microbiology., 49: 98-102.
Srivastav, S., Yadav, K.S. and Kundu, B.S. (2004). Prospects of using
phosphate solubilizing Pseudomonas as biofungicide. Indian Journal of
Microbiology., 44(2): 91-94.
Stephen, M.P., Oliveira, M., Teixeira, K.R.S., Martinez-Drets, G. and
Dobereiner, J. (1991). Physiology and dinitrogen fixation of Acetobacter
diazotrophicus. FEMES Microbiology Letters., 77: 67-72.
Sujatha, E., Girisham and Reddy, S. (2004). Phosphate solubilization by
thermophilic microorganisms. Indian Journal of Microbiology., 44(2):
101-104.
Sulbaran, M., Perez, E., Ball, M.M., Bahsas, A., Yarzabal, L.A. (2009).
Characterization of the mineral phosphate solubilizing activity of
Pantoea aglomerans MMB051 isolated from iron rich soil in southern
Venezulea (Bolivar State). Current Microbiology., 58: 378-383.
Suman, A., Gaur, A., Shrivastava, A.K. and Yadav, R.L. (2005). Improving
sugarcane growth and nutrient uptake by inoculating Gluconacetobacter
diazotrophicus. Plant Growth Regulation., 47: 155-162.
Sundara, B., Natarajan, V. and Hari, K. (2002). Influence of phosphorus
solubilizing bacteria on the changes in soil available phosphorus and
sugarcane and sugar yield. Field Crops Research., 77: 43-49.
248
Sundari, A. and Sureshkumar, S. M. (2004). Influence of DAP and
phosphobacteria on growth and yield of blackgram under rice-fallow
condition. Journal of Ecobiology., 16(1): 75-77.
Sunil, C., Veeranna, H.K., Nanjappa, H.V. and Swamy, B.C.H. (2007). Growth
attributes and dry matter accumulation in cowpea as influenced by
different sources and levels of phosphorus with P-solubilizer. Mysore
Journal of Agricultural Sciences., 41(3): 354-359.
Suryakala, D., Mahaheswaridevi, P.U., Vijayalakshmy, K. (2004). Chemical
characterization and in vitro antibiosis of siderophores of rhizosphere
fluorescent Pseudomonads. Indian Journal of Microbiology., 44: 105-108.
Taalab, A.S. and Badr, M.A. (2007). Phosphorus availability from compacted
rock phosphate with nitrogen to sorghum inoculated with phospho-
bacterium. Journal of Applied Sciences Research., 3(3): 195-201.
Tabatabai, M.A. and Bremner, J.M. (1969). Use of ρ-nitrophenyl phosphate for
assay of soil phosphatase activity. Soil Biology and Biochemistry., 1:
301-307.
Tahtamouni., M.E.W., Hameed, K.M. and Saadoun, I.M. (2006). Biological
control of Sclerotinia sclerotiorum using indigenous chitinolytic
actinomycetes in Jordan. Plant Pathology Journal., 22: 107-114.
Tamilvendan, K. and Purushothaman, D. (1995). Phosphate solubilizing strains
in Azospirillum. Proceedings of National Symposium, Frontiers in
Applied Environmental Microbiology, pp. 139-143, SES, CUSAT,
Cochin.
References 249
Tandon, H.L.S. (1987). Phosphorus research and agriculture production in India.
Fertilizer development and consultation organization, New Delhi. pp
160.
Tank, N. and Saraf, M. (2003). Phosphate solubilization, exopolysaccharide
production and indole acetic acid secretion by rhizobacteria isolated
from Trigonella foenum-graecum. Indian Journal of Microbiology., 43(1):
37-40.
Tanwar, S.P.S. and Shaktawat, M.S. (2003). Influence of phosphorus sources,
levels and solubilizers on yield, quality and nutrient uptake of soybean
(Glycine max)-wheat (Triticum aestivum) cropping system in southern
Rajasthan. Indian Journal of Agricultural Sciences., 73(1): 3-7.
Tarafdar, J.C., Bareja, M. and Panwar, J. (2003). Efficiency of some
phosphatase producing soil fungi. Indian Journal of Microbiology., 43:
27-32.
Tate, K.R. (1984). The biological transformation of P in the soil. Plant and Soil.,
76: 245-256.
Tate, K.R. and Salcedo, I. (1988). Phosphorus control of soil organic matter
accumulation and cycling. Biogeochemistry., 5: 99-107.
Thakuria, D., Talukdar, N.C., Goswami, C., Hazarika, S., Boro, R.C. and Khan,
R.C. (2004). Charactrization and screening of bacteria from rhizosphere
of rice grown in acidic soils of Assam. Current Science., 86(7): 978-984.
Thamodharan, V., Tewari, L. and Bajpai, G. C. (2004). Genotype × phosphate
solubilizing bacteria interaction in pigeonpea [Cajanus cajan (L.) Millsp.].
Indian Journal of Genetics and Plant Breeding., 64(3). 241-242.
250
Thankammal, L., George, M.K. and George, K.V. (1968). Occurrence of two
spp. of Phytophthora on Hevea brasiliensis in India. Rubber Board
Bulletin., 10: 43.
Thomas, G.V., Shantaram, M.V. and Saraswathy, N. (1985). Occurrence and
activity of phosphate-solubilizing fungi from coconut plantation soils.
Plant and Soil., 87: 357-364.
Thompson, L.M. and Troch, F.R. (1978) *. Soils and soil fertility 4th ed. McGraw-
Hill Inc., New York, NY.
Toro, M., Azcon, R and Herrera, R. (1996). Effects on yield and nutrition of
mycorrhizal and nodulated Puearia phaseoloides exerted by P-
solubilizing rhizobacteria. Biology and Fertility of Soils., 21: 23-29.
Toro, M., Azcon, R., and Barea, J.M. (1997). Improvement of Arbuscular
Mycorrhiza development by inoculation of soil with phosphate
solubilizing rhizobacteria to improve rock phosphate availability and
nutrient cycling. Applied Environmental Microbiology., 63(11): 4408-
4412.
Toro, M., Azcon, R., and Barea, J.M. (1998). The use of isotopic dilution
technique to evaluate the interactive effects of Rhizobium genotype,
mycorrhizal fungi, phosphate solubilizing rhizobacteria and rock
phosphate on nitrogen and phosphorus acquisition by Medicago sativa.
New Phytology., 138: 265-273.
Tripura, A. and Podile, A.R. (2007). Properties of a chimeric glucose
dehydrogenase improved by site directed mutagenesis. Journal of
Biotechnology., 131: 197-204.
References 251
Tripura, C., Reddy, P.S, Reddy, M.K., Sashidhar, B. and Podile, A.R. (2007a).
Glucose dehydrogenase of a rhizobacterial strain of Enterobacter
asburiae involved in mineral phosphate solubilization shares properties
and sequence homology with other members of enterobcteriaceae.
Indian Journal of Microbiology., 47: 126-131.
Tripura, C., Sashidhar, B. and Podile, A.R. (2007b). Ethyl methanesulfonate
mutagenesis-enhanced mineral phosphate solubilization by groundnut-
associated Serratia marcescens GPS-5. Current Microbiology., 54:79-84.
Trivedi, P. and Sa, T. (2008). Pseudomonas corrugata (NRRL B-30409) mutans
increased phosphate solubilization, organic acid production and plant
growth at lower temperatures. Current Microbiology., 56: 140-144, DOI
10.1007/s00284-007-9058-8.
Tu, C.M. (1994). Effects of herbicides and fumigants on microbial activities in
soil. Bulletin Environmental Contamination and Toxicology, 53, 12-17.
Tyagi, M. K., Singh, C. P., Bhattacharayya, P. and Sharma, N.L. (2003). Dual
inoculation effect of Rhizobium and phosphate solubilizing bacteria
(PSB) on pea (Pisum sativum L.). Indian Journal of Agricultural
Research., 37(1): 1-8.
Valverde, A., Burgos, A., Fiscella, T., Rivas, R., Velazquez, E., Rodriguez-
Barrueco, C., Cervantes, E., Chamber, M., Igual, J.M. (2006).
Differential effects of coinoculation with Pseudomonas jessenii PSO6 (a
phosphate solubilizing bacterium) and Mesorhizobium ciceri C-2/2
strains on the growth and seed yield of chickpea under green house and
field conditions. Plant and Soil., 287: 43-50.
Van, V.T., Berge, O., Ke, S.N., Balandreau, J. and Heulin, T. (2000). Repeated
beneficial effects of rice inoculation with a strain of Burkholderia
252
vietnamiensis on early and late yield components in low fertility sulphate
acid soils of Vietnam. Plant and Soil., 218: 273-284.
Vassilev, N. and Vassileva, M. (2003). Biotechnological solubilization of rock
phosphate on media containing agro-industrial wastes. Applied
Microbiology and Biotechnology., 61: 435-440.
Vassilev, N., Vassileva, M and Nikolaeva, I. (2006). Simultaneous P-solubilizing
and biocontrol activity of microorganisms: potential and future trends.
Applied Microbiology and Biotechnology., 71: 137-144.
Vassileva, M., Azcon, R,, Barea, J,M. and Vassilev, N. (1998). Application of an
encapsulated filamentous fungus in solubilization of inorganic
phosphate. Journal of Biotechnolgy., 63; 67-72.
Vazquez, P., Holguin, G., Puente, M.E., Lopez-Cortes, A. and Bashan, Y.
(2000). Phosphate solubilizing microorganisms associated with the
rhizosphere of mangroves in a semiarid costal lagoon. Biology and
Fertility of Soils., 30: 460-468.
Velusamy, P. and Gnanamanickam, S.S. (2003). Identification of 2,4-
diacetylphloroglucinol production by plant associated bacteria and its
role in suppression of rice bacterial blight India. Current Science., 85(9):
1270-1273.
Verma, A., Kukreja, K., Pathak, D.V., Suneja, S. and Narula, N. (2001). In vitro
production of plant growth regulators (PGRs) by Azotobacter
chroococcum. Indian Journal of Microbiology., 41: 305-307.
Vessey, J.K. (2003). Plant growth promoting rhizobacteria as biofertilizers. Plant
and Soil., 255: 571-586.
References 253
Vikram, A. and Hamzehzarghani, H. (2008). Effect of phosphate solubilizing
bacteria on nodulation and growth parameters of greengram (Vigna
radiate L., Wilczek). Research Journal of Microbiology., 3(2): 62-72.
Vikram, A., Alagawadi, A.R., Hamzehzarghani, H. and Krishnaraj, P.U. (2007).
Factors related to the occurrence of phosphate solubilizing bacteria and
their isolation in vertisols. International Journal of Agricultural Research.,
2(7): 571-580.
Vikram, A., Algagawadi, A.R., Krishnaraj, P.U. and Kumar, K.S.M. (2007a).
Transconjugation studies in Azospirillum sp. negative to mineral
phosphate solubilization. World Journal of Microbiology and
Biotechnology., 23: 1333-1337.
Vora, M.S. and Shelat, H.N. (1998). Impact of addition of different carbon and
nitrogen sources on solubilization of rock phosphate by phosphate-
solubilizing micro-organisms. Indian Journal of Agricultural Sciences.,
68(6): 292-294.
Wainwright, M. and Sowden, F.J. (1977). Influence of fungicide treatment on
CaCl2 extractable phosphorus and phosphate solubilizing
microorganisms in soil. Plant and Soil., 48: 335-345.
Wakelin, S.A., Gupta, V.V.S.R., Harvey, P.R. and Ryder, M.H. (2007). The
effect of Penicillium fungi on plant growth and phosphorus mobilization
in neutral to alkaline soils from southern Australia. Canadian Journal of
Microbiology., 53: 106-115.
Wakelin, S.A., Warren, R.A., Harvey, P.R. and Ryder, M.H. (2004). Phosphate
solubilization by Penicillium spp. closely associated with wheat roots.
Biology and Fertility of Soils., 40: 36-43.
254
Wang, S.L., Hisao, W.J. and Chang, W.T. (2002). Purification and
characterization of an antimicrobial chitinase extracellularly produced by
Monascus purpureus CCRC31499 in shrimp and crab shell medium.
Journal of Agriculture Food Chemistry., 50: 2249-2255.
Wani, P.A., Khan, M.S. and Zaidi, A. (2007). Co-inoculation of nitrogen-fixing
and phosphate solubilizing bacteria to promote growth, yield and
nutrient uptake in chick pea. Acta Agronomica Hungarica., 55(3): 315-
323.
Wenzel, C.L., Ashford, A.E. and Summerell, B.A. (1994). Phosphate solubilizing
bacteria associated with proteoid roots of seedlings of waratah (Telopea
speciosissima (Sm.) R.Br.). New Phytologist., 128(3): 487-496.
Whitelaw, M.A. (2000). Growth promotion of plant inoculated with phosphate
solubilizing fungi. Advances in Agronomy., 69: 100-151.
Whitelaw, M.A., Harden, T.J. and Helyar, K.R. (1999). Phosphate solubilization
in solution culture by the soil fungus Penicillium radicum. Soil Biology
and Biochemistry., 31: 655-665.
Williams, J.G.K., Kubelik, A.R., Livak, K.J., Rafalski, J.A. and Tingey, S.V.
(1990). DNA polymorphisms amplified by arbitrary primers are as
genetic markers. Nucleic Acids Research., 18: 6531-6535.
Wu, K.J., Wu, C.S. and Chang, J.S. (2007). Biodegradability and mechanical
properties of polycaprolactone composites encapsulating phosphate-
solubilizing bacterium Bacillus sp. PG01. Process Biochemistry., 42:
669-675.
Xiao, C.Q., Chi, R.A., Huang, X.H., Zhang, W.X., Qiu, G.Z. and Wang, D.Z.
(2008). Optimization for rock phosphate solubilization by phosphate-
References 255
solubilizing fungi isolated from phosphate mines. Ecological
Engineering., 33: 187-193.
Xiao, X., Chen, H., Chen, H., Wang, J., Ren, C. and Wu, L. (2008a). Impact of
Bacillus subtilis JA, a biocontrol strain of fungal plant pathogens, on
arbuscular mycorrhiza formation in Zea mays. World Journal of
Microbiology and Biotechnology., 24: 1133-1137. DOI 10.1007/s11274-
007-9584-3.
Xin, C., Tang Jain-jun, T., Zhi-guo, F. and Shui-jin, H. (2002). Phosphate
solubilizing microbes in rhizosphere soils of 19 weeds in southeastern
China. Journal of Zhejiang University Science., 3: 355-356.
Yadav, B.K. and Tarafdar, J.C. (2007). Ability of Emericella rugulosa to mobilize
unavailable P compounds during pearl millet [Pennisetum glaucum (L.)
r. Br.] crop under arid condition. Indian Journal of Microbiology., 47(1):
57-63.
Yahya, A.I. and Al-Azawi. (1998). Occurrence of phosphate solubilizing bacteria
in some Iraqi soils. Plant and Soil., 117: 135-141.
Yamada, Y., Hoshino, K. and Ishikawa, T. (1997). The phylogeny of acetic acd
bacteria based o the partial sequence of 16S ribosomal RNA: the
elevation of the sub genus Gluconacetobacter to the generic level.
Bioscience, Biotechnology and Biochemistry., 61: 1244-1251.
Yi, Y., Huang, W. and Ge, Y. (2008). Exopolysaccharide: a novel important
factor in the microbial dissolution of tricalcium phosphate. World Journal
of Microbiology and Biotechnology., 24(7): 1059-1065,DOI 10.1007/s
11274-007-9575-4.
256
Zaidi, A. and Khan, M.S. (2006). Co-inoculation effects of phosphate solubilizing
microorganisms and Glomus fasciculatum on green gram-
Bradyrhizobium symbiosis. Turkish Journal of Agriculture and Forestry.,
30: 223-230.
Zaman, M., Cameron, K.C., Di, S.J. and Inubushi, K. (2002). Changes in
mineral N, microbial biomass and enzyme activities in different soil
depths after surface applications of diary shed effluent and chemical
fertilizer. Nurient Cycling in Agroecosystems., 63: 275-290.
Zaman, M., Di, H.J., Cameron, K.C. and Frampton, C.M. (1999). Gross nitrogen
mineralization and nitrification rates and their relationships to enzyme
activities and the soil microbial biomass in soils treated with diary shed
effluent and ammonium fertilizer at different water potentials. Biology
and Fertility of Soils., 29: 178-186.
Zarei, M., Saleh-Rastin, N., Alikhani, H.A. and Aliasgharzadeh, N. (2006).
Responses of Lentil to co-inoculation with phosphate-solubilizing
Rhizobial strains and arbuscular mycorrhizal fungi. Journal of Plant
Nutrition., 29: 1509-1522.
Zayed, G. (1997). Can immobilization of Bacillus megaterium cells in alginate
beads protect them against bacteriophages. Plant and Soil., 197: 1-7.
Zayed, G. and Abdel-Motaal, H. (2005). Bio-production of compost with low pH
and high soluble phosphorus from sugar cane bagasse enriched with
rock phosphate. World Journal of Microbiology and Biotechnology. 21:
747-752.
*original paper not reviewed
