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COMPARATIVE ANALYSIS REVEALS A HYPER-VIRULENT ESCHERICHIA COLI O157:H7 STRAIN ISOLATED FROM A SUPER-SHEDDER
By
LIN TENG
A THESIS PRESENTED TO THE GRADUATE SCHOOL
OF THE UNIVERSITY OF FLORIDA IN PARTIAL FULFILLMENT OF THE REQUIREMENTS FOR THE DEGREE OF
MASTER OF SCIENCE
UNIVERSITY OF FLORIDA
2016
© 2016 Lin Teng
To my dear parents, Lihang Wang and Yongyu Teng, and my dear advisor, Dr. KwangCheol Casey Jeong, who is leading me into the world of science
4
ACKNOWLEDGMENTS
I would like to thank my advisor, Dr. KwangCheol Casey Jeong, for his generous
support, continuous patience and strict training during my entire M.S. program. His
training and direction help me culture my scientific thinking and evoke my interests to
explore the unknown. Thanks to Dr. Soohyoun Ahn for her priceless encouragement
and directions in my thesis. I appreciate Dr. Nicolas Dilorenzo’s kind help for the
arrangement of sample collections at North Florida Research and Education Center.
Thanks to Dr. Dongjin Park for working together with me on this project and giving me
lots of detailed directions.
Special thanks to Raies Mir, Zhengxin Ma, Dr. Alejandro Garrido-Maestu, Dr.
Sarah Markland, Minyoung Kang, Choonghee Lee Amber Ginn and Shinyoung Lee.
Raies has been taking care of me since the first day I joined the lab. With his help and
directions, I was able to quickly adjust to a new life at the University of Florida. Thanks
to Zhengxin for all the detailed directions she gave me for the experiments, course work
and daily life throughout my M.S. career. I appreciate the kind and priceless help and
encouragements from Alejandro in the toughest period during my M.S. program. Sarah
not only helped me with my experiments but also taught me to be optimistic to
overcome the problems I met in the experiments. Minyoung always supported me with
the kind help in the experiments whenever I needed. Choonghee taught me how to
conduct Western blot and maintained the cell lines for my experiments. Amber taught
me phylogenetic analysis and never got tired of my endless questions. I would like to
acknowledge Shinyoung for her efforts to optimize the condition of biofilm assay. In
addition, I appreciate the help from Cheng Ye and Guan Yang. Even though they are
not my lab members, they always cheered me up and motivated me to move forward.
5
I would like to express my deepest and greatest gratitude to my parents, Lihang
Wang and Yongyu Teng for their unconditional support throughout the years. I would
also like to thank my girlfriend, Lanwen Zhou, for her support and encouragement
during the years.
6
TABLE OF CONTENTS page
ACKNOWLEDGMENTS .................................................................................................. 4
LIST OF TABLES ............................................................................................................ 8
LIST OF FIGURES .......................................................................................................... 9
LIST OF ABBREVIATIONS ........................................................................................... 10
ABSTRACT ................................................................................................................... 11
CHAPTER
1 INTRODUCTION .................................................................................................... 13
2 LITERATURE REVIEW .......................................................................................... 15
Shiga Toxin-Producing Escherichia coli O157:H7 .................................................. 15
Virulence Factors and Virulence Related Genes .................................................... 15 Toxins ............................................................................................................... 16
Adhesion .......................................................................................................... 16 Secretion Systems ........................................................................................... 17
Effectors ........................................................................................................... 17
Reservoir and Super-Shedder ................................................................................ 18
Role of Super-Shedder ........................................................................................... 19 Factors Contributing to Supper-Shedding ............................................................... 20
Microbial Factors in Super-Shedding ............................................................... 21
Animal Factors Contributing to Super-Shedding .............................................. 25 Environmental Factors Contributing to Super-Shedding .................................. 26
Conclusion .............................................................................................................. 26
3 COMPARATIVE ANALYSIS REVEALS A HYPER-VIRULENT Escherichia coli O157:H7 STRAIN ISOLATED FROM A SUPER-SHEDDER .................................. 28
Background ............................................................................................................. 28
Materials and Methods............................................................................................ 32 Bacterial Strains ............................................................................................... 32 Genomic DNA Extraction .................................................................................. 32 Stx2 Subtyping ................................................................................................. 32
Phage Induction ............................................................................................... 33 Western Blot Analysis of Stx2 Expression ........................................................ 33 Adherence to HEp-2 Cells ................................................................................ 34 Static Biofilm Formation Assay ......................................................................... 35 Genome Sequencing and Assembly ................................................................ 36 Annotation and Comparative Genomics ........................................................... 36
7
In silico Analysis of LSPA-6 Profile and Phylogenetic Clade ............................ 37 In silico Analysis of IS629 Profile ...................................................................... 38
Function-Based Gene Comparison .................................................................. 38
Phylogenetic Analysis ...................................................................................... 38 Results .................................................................................................................... 39
Shiga Toxin Expression of KCJ1266 ................................................................ 39 Adherence to Epithelial Cell Line ...................................................................... 39 Biofilm Formation ............................................................................................. 40
Lineage Determination Based on LSPA-6 ........................................................ 40 Clade of KCJ1266 ............................................................................................ 40 IS629 Profile Distribution .................................................................................. 41
Overview of KCJ1266 Genome ........................................................................ 41
Comparative Genomic Analyses. ..................................................................... 42 Functional Characterization of the Genome ..................................................... 43 Single Nucleotide Polymorphisms .................................................................... 44
Virulence and Colonization Factors .................................................................. 44
Phage Regions in KCJ1266 ............................................................................. 46 Phylogenetic Analysis ...................................................................................... 47
Discussion .............................................................................................................. 47
Conclusion .............................................................................................................. 51 Figures .................................................................................................................... 56
LIST OF REFERENCES ............................................................................................... 67
BIOGRAPHICAL SKETCH ............................................................................................ 76
8
LIST OF TABLES
Table page 3-1 Genome statistics of KCJ1266 and reference O157 strains .............................. 52
3-2 Function-based gene comparison ..................................................................... 53
3-3 Genome encoded in the 19 phage regions of KCJ1266 .................................... 54
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LIST OF FIGURES
Figure page 3-1 Shiga-toxin II detection.. ..................................................................................... 56
3-2 Adhesion of E. coli O157:H7 isolates to Hep-2 cells ........................................... 57
3-3 Biofilm assay of KCJ1266. EDL933 was used as a positive control and ΔfimH
mutant of EDL933 was used as a negative control............................................. 58
3-4 IS629 profile of KCJ1266, SS17, EC4115 and EDL933.. ................................... 59
3-5 Genome map of KCJ1266 .................................................................................. 60
3-6 Mauve alignments of KCJ1266 with the three reference genome. ..................... 61
3-7 Comparison of O157 plasmids of KCJ1266 and other 3 reference strains ......... 62
3-8 Subsystem category distribution ......................................................................... 63
3-9 Phage comparison of KCJ1266 with reference strains ....................................... 64
3-10 Virulence related genes in KCJ1266 and reference strains. ............................... 65
3-11 Strains are clustered into three groups which belong to Lineage I (green), Lineage II (red) and Lineage I/II (blue). .............................................................. 66
10
LIST OF ABBREVIATIONS
CFU Colony-forming unit
GI Gastrointestinal
HUS Hemolytic-uremic syndrome
HV Hype-virulence
IDP IS629 distribution profile
LEE Locus for enterocyte effacement
LSPA Lineage specific polymorphism analysis
nsSNP Nonsynonymous single-nucleotide polymorphism
PCR Polymerase chain reaction
PFGE Pulsed-field gel electrophoresis
RAJ Recto-anal junction
SB Synteny block
SNP Single-nucleotide polymorphism
SS Super-shedder
sSNP Synonymous single nucleotide polymorphism
STEC Shiga toxin-producing Escherichia coli
TBST 20 Tris-Buffered Saline and Tween 20
tir translocated intimin receptor
TTSS Type three secretion system
WGS Whole genome sequencing
11
Abstract of Thesis Presented to the Graduate School of the University of Florida in Partial Fulfillment of the Requirements for the Degree of Master of Science
COMPARATIVE ANALYSIS REVEALS A HYPER-VIRULENT ESCHERICHIA COLI O157:H7 STRAIN ISOLATED FROM A SUPER-SHEDDER
By
Lin Teng
May 2016
Chair: KwangCheol Casey Jeong Major: Animal Sciences
Shiga toxin-producing Escherichia coli (STEC) O157:H7 is a foodborne pathogen
that threatens public health on a global scale. STEC O157:H7 predominantly colonizes
the terminal recto-anal junction (RAJ) of cattle, which is the major asymptomatic
reservoir of this pathogen. Cattle shedding STEC O157:H7 ≥ 104 CFU/g of feces are
known as super-shedders and are responsible for within-farm and between-farm
transmission of STEC O157:H7. The purpose of this study was to perform genetic
characterization of KCJ1266, a strain isolated from a super-shedder steer from a farm in
North Florida. PacBio sequencing was employed for whole genome sequencing (WGS)
to characterize the genomic features of KCJ1266. A comparative genome analysis of
KCJ1266 with reference genomes including SS17 (strain isolated from a super-
shedder), EC4115 (strain related to spinach outbreak) and EDL933 (strain related to
hamburger outbreak) was conducted. WGS of KCJ1266 revealed that it has a genome
of 5,478,683 bp encoding 5,545 open reading frames and a plasmid, pO157, of 95,910
bp. In silico analysis revealed that KCJ1266 belongs to E. coli lineage I/II and clade 8,
12
which are related to disease-causing isolates. In addition, Mauve alignment showed that
KCJ1266 shares a similar genomic architecture with SS17 and EC4115. Comparative
analyses also revealed that KCJ1266 has the same virulence and similar functional
genes as SS17 and EC4115. Phylogenetic analysis showed that KCJ1266, SS17 and
EC4115 clustered in the same group. Taken together, these results reveal that super-
shedding STEC strain KCJ1266 is a hyper-virulent strain similar to that of SS17 and
EC4115. This is one of the first studies which has utilized PacBio WGS to characterize
a hyper-virulent STEC O157:H7 strain isolated from super-shedding cattle. KCJ1266
can potentially be used as a reference strain for future studies regarding the
phenomenon of super-shedding.
13
CHAPTER 1 INTRODUCTION
Shiga toxin-producing Escherichia coli (STEC) are foodborne pathogens that
threaten public health on a global scale [1]. It causes a variety of symptoms including
bloody diarrhea and life-threatening hemolytic uremic syndrome (HUS) in humans
through the expression of Shiga-like toxin [2-4]. STEC infections cause annual
economic loss of more than $1 billion USD in the US [5]. The human infection caused
by STEC is primarily attributed to the consumption of food products contaminated by
STEC.
Cattle are the primary reservoirs and asymptomatic carriers of STEC. The
terminal recto-anal junction (RAJ), as well as gastrointestinal (GI) tract, are the principle
localization sites of STEC [5]. Among the cattle colonized by STEC, a subset of cattle
shed E. coli O157:H7 at a level of > 104 colony forming unit (CFU) per gram feces and
are defined as “super-shedders” [6, 7]. Previous studies showed that super-shedders
were responsible for most of the within-farm and between-farm transmission events of
STEC [1, 8, 9]. The existence of super-shedders may lead to an increase in the
contamination of animal food products, such as beef and milk, and thus threaten public
health.
Since the phenomenon of super-shedding was first observed, researchers have
been trying to determine the bacterial, host, and environmental factors that contribute to
super-shedding [10]. However, the mechanisms of super-shedding are still unknown. In
order to determine the potential bacterial factors that contribute to super-shedding, we
hypothesized that the super-shedding phenomenon is caused by a group of specific
genomic traits of bacterial strains isolated from super-shedding cattle. The objective of
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this study was to identify the genes which contribute to the specific phenomenon of
super-shedding using comparative genome analysis.
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CHAPTER 2 LITERATURE REVIEW
Shiga Toxin-Producing Escherichia coli O157:H7
Shiga toxin-producing Escherichia coli O157:H7 (STEC) are foodborne
pathogens that globally threaten public health [11]. In 1982, E. coli O157:H7 was first
identified as a foodborne pathogen following an outbreak of hemorrhagic colitis in the
United States [1]. In 1993, a multistate outbreak of E. coli O157:H7 led to the
recognition of E. coli O157:H7 as a crucial pathogen in the U.S [12]. Reports of E. coli
O157:H7 outbreaks from 2003 to 2012 increased when compared to the preceding two
decades. E. coli outbreaks are historically associated with not only beef products, but
also a variety of food sources, including unpasteurized apple juice, spinach and salami
[13, 14]. E. coli O157:H7 quickly became one of the most recognized foodborne
pathogens due to the severity of the disease it caused in humans and the significant
media attention seen during outbreaks. STEC causes a variety of symptoms ranging
from bloody diarrhea to the development of life-threatening hemolytic-uremic syndrome
(HUS). Previous research has shown that STEC infections cause more than $1 billion
USD in economic loss per year [5].
Virulence Factors and Virulence Related Genes
Bacterial virulence and pathogenesis factors play a significant role in infectious
disease etiology. With the development of whole genome sequencing techniques, an
increasing number of virulence factors can be identified by whole genome comparison
[15]. A recent review concluded that about 394 coding sequences were identified as
putative or known virulence factors [15]. Without a good animal model for STEC
infection, it is difficult to determine the contribution of putative virulence genes to its
16
pathogenesis [2], therefore most of the putative virulence genes will not be discussed in
this review.
Toxins
Shiga toxins (Stxs) are encoded by Shiga-toxin converting prophages in the
chromosome of STEC. The diversity of Stxs are caused by the high heterogeneity of
Shiga-toxin converting prophages [16]. There are two major types of Shiga toxins, Stx1
and Stx2, which are encoded by two main sets of genes, stx1AB and stx2AB,
respectively. Both of Stx1 and Stx2 consist of an A subunit of 32-kDa and five identical
B subunits of 7.7kDa [17]. The main receptor of Shiga toxin is globotriaosylceramide
(Gb3) which can be found on human cells, including endothelial cells, epithelial cells
and microvascular endothelial cells [18]. Although Stx1 and Stx2 have similar structure,
their toxic dosage to different cell types vary. An in vitro study showed that Stx2 toxin
was reported to be 1000 times more cytotoxic in human renal microvascular endothelial
cells when compared with Stx1 toxin [19]. In addition, the Stx2 subtypes encoded by
stx2a, stx2b, stx2c, stx2d, stx2e and stx2f differ by a few amino acids, resulting in
diverse toxicity of Stx2 in humans [20]. Among these Stx2 subtypes, Stx2a, Stx2c and
Stx2d are often related to severe human diseases such as hemorrhagic colitis (HC) and
HUS [21-24]. A recent study showed that STEC O157:H7 harboring the stx2a gene can
express Shiga toxin at higher levels than those harboring the stx2c gene [25].
Adhesion
The ability of STEC to adhere to human epithelial cells is believed to be a critical
step for infection because adherence is the initial step in STEC infection [15]. Fimbriae
and curli are two major apparatuses which contribute to adherence ability of STEC.
Type I fimbriae are encoded by the fim operon, including fimB, fimE, fimA, fimI, fimC,
17
fimF, fimG and fimH. Curli play a significant role in surface attachment and biofilm
formation. The formation of curli is controlled by the cgs operon [26]. Long polar filament
encoded by the lpfABCC’DE operon are also involved in adherence [27].
Secretion Systems
E. coli O157 harbors a highly conserved plasmid known as pO157. There are 13
ORFs (open reading frames) named etpC to eptO which encode a type two secretion
system in pO157 [2]. It has been found that this secretion system can secrete StcE (zinc
metalloprotease protein), thus it contributes to the virulence of E. coli O157:H7 [15].
Another secretion system in STEC O157:H7 is the type three secretion system (TTSS),
a needle complex apparatus, by which bacterial effectors are injected into host cells[28].
This apparatus, made up of more than 20 proteins, is necessary for STEC to colonize to
cattle. The structure of the TTSS is encoded by genes, including eprK, eprJ, eprH,
epaQ, epaP, epaO, elvJ, elvI, elvA, elvE, elvG and elvF [15]. When STEC start
colonization, Stx prophages are activated by SOS induction followed by cell lysis of a
subgroup of STEC [28]. The Stx produced by Stx prophages bind to its receptor, Gb3,
on epithelia cells, resulting in redistribution of nucleolin and other factors to the cell
surface [28]. The changed surface structure promotes bacterial attachment by binding
to bacterial surface protein intimin (Eae) [28].
Effectors
Virulence effectors refer to the proteins that are injected to host cells using TTSS
[15]. STEC O157:H7 are able to colonize the intestinal mucosa and cause attaching and
effacing (A/E) lesions. The regions encoding proteins related to A/E lesion were
designated the locus of enterocyte effacement (LEE) [29]. The espH, espZ and espG
are effector genes encoding in LEE. In addition to effectors encoded by LEE, there are
18
numerous non-LEE-encoding effectors. These effectors are encoded by genes including
espY4, nleB1, espW, nleG8-2, espM2, espR4, nleA, nleH1-2, espM1, nleG2-2, nleG6-1,
nleG5-1, espK, espX2, espY1, nleG8-1, nleD, and nleH1-1 [15].
Reservoir and Super-Shedder
Cattle are the primary asymptomatic reservoir of STEC [30]. However, the
shedding amount of E. coli O157:H7 varies greatly from animal to animal [8, 31, 32].
The number of E. coli O157:H7 shed in feces is also affected by the climate, season
and breed of cattle. Previous reports showed that the shedding of E. coli O157:H7 was
observed as a transient event and the typical duration of E. coli O157:H7 shedding lasts
about 1 month [33]. The term “super-shedder”, was first used by Matthews et al. in
2006, which is defined as a subset of cattle that can shed ≥ 104 colony-forming unit
(CFU) /g feces of E. coli O157:H7 [6]. However, the term “super-shedding” are often
used to describe the heterogeneous role that the cattle play in the transmission of E.
coli O157:H7. Based on a review written by Chase-Topping et al. (2008) the super-
shedder is defined as the individual that can shed an extremely high number of
infectious organisms, by which the super-shedder has an increased probability of
infecting other individuals [1].
However, a part of the definition remains unclear, specifically what defines the
duration of the super-shedding state. In a previous study, the duration of super-
shedding lasted up to a month [33]. Since the duration of super-shedding may affect the
identification of a super-shedder, a proper sampling method for isolation of super
shedding bacteria from animals is extremely important. To get an accurate account of
shedding information of E. coli O157:H7, Munns et al. (2015) modified the sampling
method and had each animal sampled twice a day during a 6-day period [10]. The
19
results of that study revealed that super-shedding is a short-term phenomenon and that
shedding amount may not be consistent even between two samplings within the same
day [10]. In this case, it is not easy to identify the low-shedder and super-shedder, since
their status may change within one day.
Role of Super-Shedder
Super-shedders are of significant importance because they are considered to be
responsible for the within-farm and between-farm transmission of E. coli O157:H7, as
well as transmission of E. coli O157:H7 into the environment [1]. It has been observed
that E. coli O157:H7 are heterogeneously shed by cattle within the same farm [6]. In a
previous study, more than 96% of total E. coli O157:H7 were shed by about 9% of the
total 761 cattle tested [34]. In a mathematical modelling study, Matthews et al. (2006) [6]
showed that 20% of the most infectious individuals of cattle were responsible for about
80% of the infections that occurred within the same farm. Stephens et al. (2009) [9]
reported that super-shedders were responsible for 47% of within-farm shedding of E.
coli O157:H7, while this ratio increased to more than 90% in another study [1]. A study
involving Scottish farms showed evidence of between-farm transmission of E. coli
O157:H7, where 15 of 105 pulsed-field gel electrophoresis (PFGE) patterns were
detected in more than one farm [35]. Jeon et al. (2013) traced the presence of E. coli
O157:H7 within a herd of cattle after they were transported to a commercial feedlot,
finding that the PFGE pattern of E. coli O157:H7 isolated in the feedlot was identical to
that of commercial farm isolates [8]. This result indicated that E. coli O157:H7 could be
transferred between farms.
Since super shedder E. coli O157:H7 strains may express high level of Shiga
toxin, they, with their high shedding load, are a potential threat to public health. A study
20
performed by Chase-Topping et al. (2007) showed that the most common phage type in
Scotland was PT 21/28 (41%) [36]. This was found to be correlated with another study
in which 58% of E. coli O157:H7 human infections were caused by PT 21/28 E. coli
O157:H7 [37]. There is more evidence indicating the importance for the control and
surveillance of super-shedding animals, and the types of bacteria that are being shed in
high concentrations. Cote et al. (2015) found that an E. coli O157:H7 strain isolated
from a super-shedding animal in the U.S. Midwest possessed a hyper-virulent
characteristic having two copies of the stx2a gene, allowing the bacteria to produce high
level of Shiga toxin 2 without induction [26].
Factors Contributing to Supper-Shedding
Cattle live in various environments, interact with each other and are exposed to
different environmental pressures. There may be three major factors, including animal
factors, pathogen factors and environmental factors that cause the super-shedding
phenomenon [1, 10]. The animal factors include the status of the animal’s immune
system, susceptibility to intestinal colonization, animal to animal transmission, stress
response and animal breed [8, 10]. The environmental factors include season, animal
housing hygiene, and diet. The bacterial factors include the ability of E. coli O157:H7 to
survive in the gastrointestinal tract, competiveness of super-shedder E. coli O157:H7
vs. commensal E. coli, potential of E. coli O157:H7 to proliferate in rectal contents and
the ability to form biofilms. To date, the most studied among these factors are bacterial
factors, while experiments regarding host and environmental factors are not well
studied.
21
Microbial Factors in Super-Shedding
Previous studies reported that the E. coli O157:H7 isolated from super-shedders
in Scotland shared a primary phage type, PT21/28, suggesting that PT21/28 phenotype
may be a marker of super-shedding strains [1, 36]. However, another study reported
that no PT21/28 were identified, while the most common phage type affecting cattle was
PT4 [38]. Another study [39] examined the phage type in cattle in Canada, finding that
PT14a and PT8 were the most popular among all five of the identified phage types.
Although certain primary phage types are common in certain farms or regions, there is
no one specific phage that is commonly found on a global scale. These results showed
that phage type may not be a good marker for super-shedding strains.
PFGE is believed to be the “gold standard” for epidemiological studies involving
outbreaks [40]. In some of the previous studies, PFGE profiles showed that the strains
isolated from super-shedders and non-super-shedders have similar PFGE patterns.
Jeon et al. (2013) reported that the isolates of super-shedders, including medium-
shedders and low-shedders in North Florida, have the same PFGE patterns, indicating
that these strains are derived from the same source and have the same subtype [8].
Another study performed by Munns et al. (2015) showed a similar result that isolates of
E. coli O157:H7 from super-shedders and low-shedders contained three similar PFGE
patterns [10]. Among all these isolates, 97.6% (123/126) of them had the same PFGE
pattern. These results may reveal that strains with specific characteristics (PFGE
patterns) may have better adaptation abilities than other strains to survive and
proliferate within the host. In contrast, some other studies also showed that the super-
shedders and low-shedders shared different PFGE patterns. According to a study by
Stanford et al. (2012) PFGE patterns of E. coli O157:H7 isolates from super-shedders
22
and low-shedders of two commercial farms were varied [41]. Another study reported by
Dodd et al. (2013) confirmed the theory that super-shedders do not necessarily share
the same PFGE subtype. Arthur et al. (2013) identified 102 stains isolated from cattle of
super-shedders, finding 52 distinct PFGE subtypes [38]. However, there were no
specific PFGE subtypes found to be responsible for super-shedding. All these results
suggest that there is not a specific PFGE pattern of E. coli O157:H7 that is related to
super-shedding.
Octamer-based genome scanning methods could discriminate E. coli O157:H7
according to the size of gene markers. By using octamer-based genome scanning and
microarray-based comparative genomic hybridization, E. coli O157:H7 can be grouped
into three distinct lineages [42, 43]. These three lineages, lineage I, lineage II and
lineage I/II, are usually isolated from different sources. In most of the cases, lineage I
strains are composed of human clinical isolates. Lineage II isolates usually originate
from bovine sources. The lineage I/II isolates are related to strains that can cause
human disease, including foodborne outbreaks [44]. Within these three lineages,
lineage I and I/II are more likely to cause human disease. Studies showed that a
potential hyper-virulent strain isolated from a super-shedding animal belonged to linage
I/II according to a whole genome analysis [26]. An isolate from a super-shedding animal
in the study conducted by Jeon et al.(2013) [8] was analyzed by whole genome
sequencing, and the result showed it also belonged to lineage I/II. According to Munns
et al. (2015) 99.2% and 0.8% of all isolates from super-shedders and low-shedders,
respectively, were from lineage I and lineage I/II [45]. However, a broader study showed
that 30, 35, and 37 out of 102 strains isolated from super-shedders were identified as
23
lineage I, II and I/II isolates, respectively [38]. These results indicate that super-
shedders isolates do not belong to specific lineages.
The translocated intimin receptor (tir) single-nucleotide polymorphism (SNP) is
another typing method used to differentiate E. coli O157:H7 [46]. The translocated
intimin receptor, an effector of the type three secretion system, was previously used as
a marker of virulence because of its significant role in adhering to intestinal epithelial
cells. In this typing method, a nucleotide change (either A or T) at position 255 in the tir
gene was used to predict the virulence of an E. coli O157:H7 strain, with hyper-virulent
isolates having an increased chance to possess the T allele at this position [46]. Among
all the super-shedder strains used in a study by Arthur et al.(2013) 71% harbored the T
allele, while 29% of them harbor the A allele [38]. Munns et al.(2015) reported that in 10
strains isolated from cattle of super-shedder and low-shedder isolates, 9 strains (90%)
displayed the T allele at the 255 position of tir gene [45].
The Shiga toxin-encoding bacteriophage insertion (SBI) assay is typically used to
discriminate the E. coli O157:H7 shed from super- and low-shedders. Among a variety
of Shiga toxin-encoding genes, stx1, stx2a and stx2c are the most frequently studied in
STEC isolated from cattle. Since Shiga toxin-encoding genes may insert within or
adjacent to several distinct chromosomal loci including yehV, wrbA, argW and sbcB. Six
individual polymerase chain reactions (PCR) were previously employed to distinguish
those insertion sites [47]. It was found in a study by Arthur et al. that super-shedding
isolates have a higher chance of harboring either stx2a or stx2c than carrying both
genes [38]. Within 12 groups of super-shedding isolates, 55.9% of isolates were
identified as SBI genotype 1, 2 and 3 [38].
24
Sequencing techniques, including whole genome sequencing, are becoming
increasingly popular to analyze the characteristics of bacteria. Historically, whole
genome sequences of the E. coli O157:H7 strain isolated from the Sakai outbreak in
Japan, was compared with that of the benign laboratory strain K-12. The result of this
whole genome comparison has shown that the Sakai strain has 20 specific tRNAs and
131 potential virulence factors [48]. The whole genome sequence of another E. coli
O157:H7 outbreak strain, EDL933, was also compared with that of K-12 strain, with
1387 specific genes identified in EDL933 [49]. Since whole genome sequencing of
isolates could provide researchers with a variety of pertinent genetic information,
researchers have begun to use this powerful tool in order to determine the differences
between super-shedding and low-shedding strains at the genomic level. The whole
genome sequences of 4 low-shedding isolates and 6 super-shedding isolates were
sequenced in a study by Munns et al.(2015) [45] The results showed that, based on the
analysis of single nucleotide polymorphism, there were no significant genetic
differences between super- and low-shedding strains. Another study including the whole
genome sequencing analysis of a super-shedding strain was conducted by Cote et al.
(2015) [26]. Since phage regions of E. coli O157:H7 contain a variety of genes inserted
by phages, it is possible that the genes which cause the super-shedding phenomenon
are located in phage regions. Cote et al. (2015) compared the phage regions between
EDL933, Sakai and EC4115 [26], but no specific genes were found in these phage
regions. Researchers concluded that no specific gene in phage region was responsible
for super-shedding characteristics. It is possible that super-shedding strains harbor
specific adherence factors which give them ability to be shed in large quantities from the
25
intestinal tract. To examine this hypothesis, Cote et al. (2015) identified all the
adherence factors in a super-shedding strain, SS17 [26]. Through comparison of
adherence factors with those of reference strains, researchers found that no specific
adherence factors could be associated with super-shedding. SNPs are also a potential
factor that could be related to super-shedding bacteria. Recently, a new clustering
method, IS629 profile, was proposed. It discriminates E. coli O157:H7 according to the
presence of insertion sequences in chromosome. This new method may give
researchers more clues for discovering the nature of super-shedding.
Animal Factors Contributing to Super-Shedding
A previous study showed that the prevalence of E. coli O157:H7 strains isolated
from super-, medium- and low-shedders could be affected by genetic and physiological
factors of animals [8]. Jeon et al. (2013) reported that Brahman cattle are more resistant
to E. coli O157:H7 [8]. Some cattle probably have resistance to E. coli O157:H7,
because they cannot be infected by inoculation with different doses of E. coli O157:H7,
as was shown in previous studies [8, 50].
The microbiome of the GI tract of cattle were examined, since microbial
community could potentially reflect host health. High variation in bacterial community
composition was observed among feces of individual animals in recent study [51, 52].
By sequencing 16S rRNA genes of bacteria in feces from 11 super-shedders and 11
non-shedders, Xu et al. (2014) found variation of bacterial composition between two
sets of animals, with super-shedders harboring a richer microbiome than non-shedders
[53]. Some studies showed that changes in the microbiome may lead to a boost in
immune response and exclusion of enteric pathogens [54]. As a result, super-shedding
strains could be able to accumulate to higher numbers.
26
Environmental Factors Contributing to Super-Shedding
As previously mentioned, the environmental factors include season, diet, and
animal housing hygiene. Shedding of STEC, especially E. coli O157:H7, varies
significantly in different seasons, with a peak in summer [55-57]. Diet composition is
another factor that significantly affects super-shedding. Callaway et al. (2011) found a
decrease of E. coli O157:H7 population in ruminants after the animals were fed orange
peel product [58]. In another study, Fox et al. (2007) observed that fecal shedding of E.
coli O157:H7 increased after feeding distillers grains to cattle and claimed that the
change of volatile fatty acids (VFA) concentration was responsible for this increase [59].
When Munns et al. (2015) made a change of feed for cattle, the super-shedders stop
shedding E. coli O157:H7 at a high level [45].
Conclusion
Among all the factors that might cause super-shedding, bacterial factors are
considered to be one of the major ones causing the super-shedding phenomenon in
beef cattle. Although bacterial factors were among the most studied, the exact bacterial
factors causing this phenomenon have not been clearly defined. We have also been
unable to identify the common characteristics between super-shedding isolates. There
are some possible reasons that could explain this. First, the super-shedding
phenomenon is a transient phenomenon, which means that the status of super-
shedders and low-shedders could change in a short period of time. As a result, it may
not be easy to distinguish between super-shedders and low-shedders. In this case, the
strains isolated from “super-shedder” and “low-shedder” may not be good
representatives regarding this phenotype. Second, whole genome sequencing is
thought to be a powerful technology to study bacterial factors attributed to super-
27
shedding. However, by using Illumina sequencing or other sequencing methods, many
gaps will be generated, which means some genetic information present in gaps are
missing. Without accurate sequencing data, the gene traits that cause super-shedding
will be more difficult. A more accurate sequencing technology, such as PacBio
sequencing, should be employed in order to study these bacterial factors. Third,
researchers tend to seek out a certain gene or SNP which is responsible for this
phenomenon. However, it is likely that this phenomenon is modulated by a cluster of
genes, which make this work more difficult.
28
CHAPTER 3 COMPARATIVE ANALYSIS REVEALS A HYPER-VIRULENT Escherichia coli O157:H7
STRAIN ISOLATED FROM A SUPER-SHEDDER
Background
Shiga toxin-producing Escherichia coli (STEC) are foodborne pathogens which
threaten public health on a global scale [10]. It causes a variety of symptoms including
bloody diarrhea and life-threatening hemolytic-uremic syndrome (HUS) [2-4]. STEC
infections cause economic losses of more than $1 billion USD per year, including direct
and indirect costs [5]. The primary reason that people get infected is through the
consumption of food products contaminated by STEC. Since no effective treatment
method is available for patients infected by STEC, contamination of cattle by STEC
must be controlled at the pre-harvest level. Cattle are primary reservoirs of STEC so the
prevention of colonization of STEC in cattle has become an important approach for
preventing STEC infections in humans [30]
The terminal recto-anal junction (RAJ) as well as gastrointestinal (GI) tract, are
the principle localization site by STEC in cattle [60]. Among the cattle colonized by
STEC, a subset of cattle have been found to shed > 104 CFU of E. coli O157 /g feces
and are defined as “super-shedders” [6]. The existence of super-shedders raises the
chances of contamination of animal food products such as animal hides, beef and milk,
and thus threatens public health. Jeon et al.(2013) [8] demonstrated that cattle were
able to transmit super-shedding strains between farms. Previous reports showed that
super-shedding animals within feedlot pens may be responsible for more than 90% of
shedding of E. coli O157:H7 [1, 9]. In another study, Matthew et al. (2006) [6] suggested
that 80% of bacterial transmission was caused by 20% of infectious individuals and
reduction in shedding by the cattle will reduce human infections.
29
Three potential factors causing the phenomenon of super-shedding are bacterial,
animal host, and environmental factors. To understand characteristics of super-
shedding E. coli O157 strains, phenotypic and genotypic difference among super-
shedder strains have been noted in previous studies, including phage type [1, 45],
lineage-specific polymorphisms, tir polymorphisms [61], and the clade of E. coli O157
[62] and the difference in the presence of stx2a and stx2c [10]. Previous studies showed
that most of the STEC O157 isolated from super-shedders in Scotland had a phage
type of 21/28 (PT21/28) [1, 36]. The super-shedder isolates with phage types of PT4
and PT14a were predominantly identified in two studies conducted in the United State
and Canada [10, 38]. Based on a lineage-specific polymorphism assay E. coli O157
isolates can be classified into three lineages: lineage I, lineage II and lineage I/II [42,
63]. A study showed that super-shedder isolates are distributed among all of the three
lineages [38]. Another molecular marker, tir polymorphism, used to differentiate E. coli
O157:H7 strains was based on a nonsynonymous base change (A or T) at position 255
in the tir gene [62]. Bono et al. (2007) [46] found that the tir 255 T allele was more
frequently found in human isolates, suggesting the isolates with a T allele at the 255
position in tir may be more virulent to humans. Other studies showed that super-
shedder isolates harbored both T and A alleles at the 255 position of tir and do not have
an obvious preference [10, 38]. Clade analysis can discriminate E. coli O157:H7
isolates into 9 different clades based on SNPs in 96 loci [62]. Among all the 9 clades,
isolates in clade 8 are believed to be hyper-virulent because they have higher chances
to cause severe patient symptoms. Although the phenotypic and genetic methods have
been conducted, the specific bacterial factors causing super-shedding is still unknown.
30
Recently, a whole genome analysis revealed that a super-shedder strain SS17
isolated from the Recto-anal junction (RAJ) of cattle in U.S. Midwestern states has a
distinctive genome compared with foodborne outbreak strains, Sakai and EDL933, and
spinach associated outbreak strains, TW14359 and EC4115 [26].This study revealed
that SS17 has a unique plasmid pSS17, a large number of non-synonymous SNPs
(nsSNP) and other polymorphisms compared with the reference strains. In addition, the
strong adherence aggregative phenotype associated with SS17 was shown to be
unassociated with the locus for enterocyte effacement (LEE) [26].
Previously super-shedder strains were isolated from cattle shedding O157 at a
level of more than 105 CFU /g feces which is ten times the minimum load defining a
super-shedder [1, 8]. These super-shedder strains shared the same PFGE profile and
genotype of eae+, stx1-, stx2+ and hlyA+ [8]. Further studies showed that all these
super-shedder strains can express Shiga-toxin. With this information, we hypothesize
that the phenomenon of super-shedding is caused by a group of specific genomic traits
of bacterial strains isolated from super-shedding cattle. The representative strain,
KCJ1266, isolated from super-shedding cattle was sequenced using PacBio whole
genome sequencing method, which could generate longer reads and circular bacterial
whole genome sequence than Illumina sequencing, followed by whole genome
comparative analysis.
This study shows that KCJ1266 can adhere to human HEp-2 cell as good as
human pathogen EDL933, has similar biofilm formation ability of EDL933, belongs to E.
coli lineage I/ II and clade 8, and shares a similar genomic architecture and virulence
factors with SS17 and EC4115. Taken together, these results reveal that super-
31
shedding STEC strain KCJ1266 is a hyper-virulent strain similar to that of SS17 and
EC4115. This is one of the first studies which utilizes PacBio WGS to characterize a
hyper-virulent STEC O157 strain isolated from super-shedding cattle. KCJ1266 can
potentially be used as a reference strain for future studies regarding the phenomenon of
super-shedding.
32
Materials and Methods
Bacterial Strains
KCJ1266 is a strain isolated from a super-shedding cattle located in North Florida
in 2012. EDL933 (ATCC48935) is a laboratory strain and was linked to hamburger-
borne outbreak in 1982 in the U.S. The laboratory strains, Δeae (KCJ696) and Δtir
(KCJ698) and ΔfimH (KCJ867), are deletion mutant strains of EDL933.
Genomic DNA Extraction
Genomic DNA of KCJ1266 was isolated by the use of QIAGEN DNA mini Kit
(cat. no. 51304). Briefly, 1 mL overnight culture of KCJ1266 was centrifuged for 10 min
at 5000 x g (7500 rmp). Following the manufacturer’s protocol, the bacterial pellet was
resuspended in buffer ATL and treated with 20 μL proteinase K at 56°C for 30 mins. The
released DNAs were eluted with 100 μL of ddH2O.
Stx2 Subtyping
Polymerase chain reaction (PCR) was performed to determine the stx2 subtypes
(i.e. stx2a and stx2c gene) carried by KCJ1266. Two E. coli O157:H7 strains, EDL933
carrying stx2a and stx1 and FRIK2455 carrying stx2c, were used as controls. Primers
used for detecting stx2a (stx2a-F: 5’-CTTTTCGACCCAACAAAGTTATGT-3’ and stx2a-
R: 5’-CACAGTCCCCAGTATCGCT-3’) and stx2c (stx2c-F: 5’-
TACTGTGCCTGTTACTGGGC-3’ and stx2c-R: 5’-ACAGTGCCCAGTATCGCC-3’) were
designed according to previous study [44]. Each 25 μL PCR reaction mix contains 2.5
mL of 10X buffer, 0.5 mL of dNTP, 0.2 mL of Taq polymerase, and primers. The PCR
reaction condition was set as 94°C for 5 min; 94°C for 30 sec, 54°C for 30 sec, 72°C for
60 sec for 30 cycles and a final extension time of 10 min at 72°C. Amplified PCR
33
product was analyzed in 1% agarose gel electrophoresis and visualized by ethidium
bromide staining.
Phage Induction
Cell lysis cause by phage induction was measured by optical density (OD).
Overnight culture of bacterial strains was inoculated into LB media, Mitomycin C was
added to the cell culture at the final concentration of 0.5 μL/ mL when the OD600 of the
culture reached between 0.6 and 0.7. EDL933 was used as a positive control, while
DH5α were used as a negative control for phage induction. For phage particle
preparation, Mitomycin C was added to 25 mL cell culture when OD600 reached 0.7 to
make a final concentration of 1 μL/ mL. After 18 h incubation, unlysed cells and debris
were removed by centrifugation at 4,000 rpm for 20 min at 4°C, and the resultant
supernatant was filtered with 0.22 μm-pore-size membrane. Precipitation of phage
particles was performed using 0.25 volume of 20% polyethylene glycol 8000 and 10%
NaCl. The polyethylene glycol/NaCl solution containing phage particles was incubated
at 4°C overnight, followed by centrifugation at 12,000 rpm for 1 h. The pellet was
resuspended and stored in 1 ml SM buffer (0.58 g NaCl, 0.2 g MgSO4·7H2O, 0.01 g
Gelatin per 100 ml 1M Tris-Cl pH7.5). SDS-PAGE was used to check the phage protein
profile after an aliquot of the phage suspension was mixed with SDS-loading buffer and
boiled for 5 min.
Western Blot Analysis of Stx2 Expression
The method used for identifying Stx2 expression was described in the previous
paper [64]. Briefly, the exponential phase culture (OD600= 0.7) of a O157 strain was
treated with Mitomycin C to the final concentration of 1 μg/ mL in order to induce the
lytic cycle of phages in the O157 strain and concomitant stx gene expression. Next, the
34
O157 cell culture was incubated for 18 hrs for complete cell lysis. The cell debris was
removed by centrifugation (4,000 rpm for 20 min at 4°C) and the cell-free supernatant
was collected by using 0.22 μm-pore-size membrane filter. The total proteins in the
supernatant were precipitated by adding 1 × volume of 100% trichloroacetic acid (Fisher
Scientific BP555-1) to 4 × volume of the cell-free culture. The mixture was incubated for
30 min on ice and centrifuged at 14,000 rpm, 4°C for 30 min. The protein pellet was
finally washed using cold acetone. The total proteins were separated by 12% sodium
dodecyl sulfate polyacrylamide gel and transferred to a polyvinylidene difluoride
membrane (0.45 μm pores, Immobilon-P, Millipore) for Western blot. The membrane
was blocked using 5% skim milk in TBST (10 mM Tris-HCL [pH 7.4], 150 mM NaCl, and
0.05% Tween-20) at room temperature for 1 h. Later, the membrane was incubated
overnight at 4°C with Monoclonal Verotoxin II-a subunit antibody (Meridian, Life Science
Inc.), and washed using TBST at room temperature for 1 h. The membrane was then
incubated with HRP conjugated secondary antibody (GE Healthcare) diluted 1:10000 in
TBST, washed with TBST, and incubated with a chemiluminescent substrate (ECL Plus,
GE Healthcare). Finally, the membrane was exposed to Kodak BioMax film (Carestream
Kodak X-Omat LS film, F1274 Sigma).
Adherence to HEp-2 Cells
The ability of KCJ1266 to adhere to human epithelial type-2 (HEp-2) cells was
evaluated. EDL933 was used as a positive control and eae and tir mutant of EDL933
was used as a negative control. HEp-2 cells were maintained in Dulbecco’s Modified
Eagle Medium (DMEM) (Coring, 10-017-CV) composed of 10% (vol/vol) heat-
inactivated fetal bovine serum at 37°C and 5% CO2. Approximately 105 of HEp-2 cells
were seeded into a 24-well polystyrene plate as measured using a hemocytometer and
35
allowed to grow until 90% confluent (approximately 24 h). Bacterial cultures were grown
overnight at 37°C in LB broth and washed with sterile phosphate buffered saline (PBS)
three times. The final cell pellet was resuspended in PBS to a final concentration of
O.D.600=1 (5x108 CFU). An aliquot (20µl) of the resuspended culture was inoculated
into 480µL of DMEM. Then 500 µl DMEM containing 107 bacteria was added to each
well (MOI 100). After a three-hour incubation at 37°C with 5% CO2, the bacterial
suspension was aspirated and 500 µl of new DMEM was added to each well, and this
process was repeated once more. The infected cell monolayer was washed using sterile
PBS three times to remove any unattached bacteria. To detach the HEp-2 cells from the
plate, 1mL of 0.1% Triton X 100 in PBS buffer was added to each well and allowed to
incubate for 5 min. The media was removed from each well and serially diluted in LB
broth and plated on TSA plates to enumerate the number of attached bacterial cells.
The adherence assay of each strain was conducted in triplicate. Statistical significance
between the level of attachments of isolates to the negative and positive controls were
accessed using a student’s t-test (α = 0.05).
Static Biofilm Formation Assay
The method used in the biofilm formation assay was the same as previously
described one [26]. Briefly, EDL933 strain and ΔfimH mutant of EDL933 were used as a
positive and a negative control, respectively. Strains were inoculated in LB media at
37°C with overnight shaking. The overnight culture was diluted (1:100) into M9 medium
supplemented with glucose (0.8% wt/vol) and minerals (1.16 mM MgSO4, 2 µM FeCl3, 8
µMCaCl2 and 16 µM MnCl2) and incubated at 37 °C with shaking for 48 h. Then the
overnight cultures were diluted (1:100) into the same medium and 200 µL of diluted cell
36
cultures were pipetted into a 96-well plate (Corning, NY, USA) in 6 replicates. The cell
cultures were incubated at 30°C for 48 h, removed the supernatant and washed 3 times
using PBS. The plate was dried at 37°C for 20 min until there were no water in the well,
followed by staining the biofilm using 0.1% crystal violet (wt/vol) for 2 min. Then the
crystal violet was removed and wells were washed using PBS for 3 times to remove the
remaining crystal violet. The plate was dried at 37°C for 20 min to remove all the liquid
in the wells, followed by adding 200 µl of 80% (vol/vol) ethanol and 20% (vol/vol)
acetone to release the stain. The released stain was measured by microplate reader
using the absorbance at λ 595 nm.
Genome Sequencing and Assembly
To acquire the whole genome sequence of KCJ1266, whole genome PacBio
sequencing was performed in this study. Eighty-five thousand reads with a mean
subread length of 7660 bases were obtained with 115.7 fold coverage. To obtain
contigs of genome and plasmid, de novo assembly was conducted by Falcon
(https://github.com/PacificBiosciences/FALCON). RS HGAP Assembly.3 protocol was
used with control filtering set as ‘KeepControlReads’.1.xml. Option details were set as
shown below: Minimum subread length was 500. Minimum polymerase read quality was
set as 0.80. Minimum polymerase read length was 100. At this analysis, the minimum
seed read length was adjusted to 2000. Target coverage, overlapper error rate,
overlapper min length and overlapper K-Mer were set as 25, 0.06, 40 and 14. Contigs
were connected to form a circular DNA by overlapping each end of contigs.
Annotation and Comparative Genomics
The genome of KCJ1266 was automatically annotated by RAST (Rapid
Annotation using Subsystem Technology). A FASTA file of KCJ1266 was unloaded to
37
RAST (http://rast.nmpdr.org/). Mauve 2.3.1 (default setting) was employed to align the
genome of KCJ1266 and reference strains. The SNPs between KCJ1266 and reference
strains was identified using galaxy in HiPergator of the University of Florida.
To identify the position of phage related genes, the PHAge Search Tool (PHAST)
(http://phast.wishartlab.com/ ) was used. After assembly was done and the contig of
genome of KCJ1266 was available, FASTA file of the genome was submitted to the
PHAST web server. The genome of was circularly presented by CGview [8]. Genes
encoding known and putative virulence factors in the genome of KCJ1266 were found
using VFDB [65-68] in Patric [69-71]. Multilocus sequence typing (MLST) of KCJ1266
and reference strains was conducted using Center for Genomic of Epidemiology (CGE).
Reference genomes used for comparative analysis were E. coli O157 strain
EDL933 [NC_008957] and EC4115 [NC_011353], and super-shedding strain SS17
[NZ_CP008805].
In silico Analysis of LSPA-6 Profile and Phylogenetic Clade
Six pairs of primers described in Yang, et al. were used to perform BLAST
against whole genome sequence of KCJ1266 using SnapGen View. LSPA-6 profile of
KCJ1266 was decided based on the length of a region targeted by each pair of the
primers. An Isolate that has a LSPA-6 profile of 111111 was defined as lineage I. A
strain possessing 222222 or 222223 was defined as lineage II. Other genotypes were
defined as lineage I/II [44].
Two methods were used to identify the clade of KCJ1266. An In silico clade 8
rhsA assay, the presence of a SNP (3468C) in the rhsA gene, was used to determine
whether the isolate belongs to the Clade 8 [72]. Besides, another In silico analysis
based on 32 SNPs was also conducted [62].
38
In silico Analysis of IS629 Profile
A total of thirty-two pairs of primers were used to detect IS629-distribution profile
[44]. The primers were aligned against KCJ1266 using BLAST in NCBI. EC4115,
EDL933 and SS17 were used as control. Positive was assigned if the in silico PCR
amplicon has the same size as expected, while negative if the in silico PCR amplicon
has either no IS629 or different size of amplicon [44].
Function-Based Gene Comparison
Whole genome sequence of KCJ1266, SS17, EC4115 and EDL933 were
submitted to RAST (http://rast.nmpdr.org/). Then subsystem information of each strain
was available for function-based analysis. The RAST supply the function of function-
based comparison of two strains and output the unique genes that only exist in one of
the strain.
Phylogenetic Analysis
The whole genome sequences of 28 E. coli O157 reference strains for building
phylogenetic tree were downloaded from Patric
(https://www.patricbrc.org/portal/portal/patric/Home). Mauve was used to align all the 29
sequences, including sequences of KCJ1266 and the reference strains, using
HiPerGator, a super computer located in University of Florida. The output file was
converted to a fasta alignment using an in house perl script, followed by extracting the
variable sites within contig position of each strain using MEGA6. The MEGA6 output
fasta file containing variable sites was submitted to IQtree webserver to construct a
maximum likelihood phylogeny performing 1000 bootstrap iterations for branch support
with the Kimura-2 nucleotide substitution model. Figtree (v.1.4.2) was used to edit the
phylogenetic tree.
39
Results
Shiga Toxin Expression of KCJ1266
Super-shedder isolate of O157 strain, KCJ1266, was collected from cattle in
North Florida Research and Education Center (NFREC) [8]. Fecal samples from rectal
anal junction were collected using sterile cotton swab as previously described [8]. Since
all the strains isolated from super-shedder, medium-shedder and low-shedder have stx2
gene and same PFGE pattern, KCJ1266 was chosen as a representative strain for
further analysis [8]. PCR, Mitomycin C treatment, SDS-PAGE and Western blot were
conducted to subtype stx2 gene and identify expression of Shiga toxin (Figure 3-1). The
result shows that KCJ1266 contains both stx2a and stx2c genes and express Stx2 at a
similar level of EDL933.
Adherence to Epithelial Cell Line
The adherence ability of STEC to epithelial cells plays a significant role in
bacterial colonization and persistence in cattle. Since SS17 has been shown to have
high levels of adherence ability to Hep-2 cells [26], we hypothesized that the high
adherence ability may be a conserved genetic property in supper-shedder strains. To
test the hypothesis, we compared the adherent ability of KCJ1266 to Hep-2 cells with
that of control strains including EDL933, Δeae, Δtir and DH5α strains. The data showed
that KCJ1266 has similar adherence ability to Hep-2 cells compared with EDL933
(Figure 3-2), while the KCJ1266 shows significant difference (P < 0.05) in adherence to
Hep-2 cells compared with Δeae, Δtir and DH5α strains. This result reveals that
KCJ1266 have a high adherence ability to the epithelial cells.
40
Biofilm Formation
A better bacterial biofilm formation ability is related to a better survival ability in
the environment. In the biofilm assay, the biofilm formation of EDL933 shows significant
higher than its fimH gene mutant (Figure 3-3.). At the same time, the KCJ1266 showed
significant higher ability of biofilm formation on polystyrene surface. This result suggests
that KCJ1266 may have a strong ability to survive in the environment, contaminate farm
products and reinoculate other cattle.
Lineage Determination Based on LSPA-6
Previous studies show that O157 could be classified into three groups, lineage I,
lineage II and lineage I/II, which of each is characterized by distinct genome structure,
host origin, and virulence potential [73, 74]. Lineage I and I/II strains are usually isolated
from clinical and bovine source, while Lineage II isolates usually originate from bovine
source [44, 73]. In particular, Lineage I/II include Spinach outbreak strain that displayed
high virulence and Stx expression [75]. Previously, the super-shedder strain SS17 was
shown to belong to lineage I/II [26]. The lineage of KCJ1266 determined by LSPA-6 [43]
showed a profile of (211111) which is the same as that of SS17 (Figure 3-4.). This result
reveals that the two independent super shedder strains, SS17 and KCJ1266 belong to
lineage I/II, implying their potential epidemiological significance.
Clade of KCJ1266
Manning et al. identified the presence of a hyper-virulence clade (clade 8) among
E. coli O157 strains, based on an SNP analysis of 32 loci [62]. Clade 8 strains were
characterized by high expression of Stx and high cytotoxicity [62]. In silico analysis
shows that KCJ1266 belongs to clade 8 (Figure 3-4). Previously, SS17 was also shown
to belongs to clade 8, indicating that KCJ1266 and SS17 are closely related. The
41
findings that KCJ1266 and SS17 belong to the same hyper-virulence clade and share
super-shedding property, together with their distinct geological origins imply that this
type of O157 strain characterized by super-shedder (SS) and hyper-virulence (HV) may
be more prevalent in the natural habitat than was previously considered.
IS629 Profile Distribution
To further investigate the genetic relatedness between KCJ1266, SS17, and the
prototypic strain EC4115, we performed IS629 distribution profile (IDP) analysis, a
method that can be used for not only lineage typing but also genetic differentiation
within a given lineage [44].
IDP of KCJ1266 was determined by In silico analysis, and compared with IDP of
SS17 EC4115 (lineage I/II control) and EDL933 (lineage I control). As expected, IDP of
KCJ1266, SS17 and EC4115 displayed typical IDP of lineage I/II and were distinctive
from lineage I type IDP represented by EDL933 (Figure 3-4). Interestingly, IDPs among
the 3 lineage I/II strains were not identical but varied, reflecting their genetic divergence
at the sub-strain level. Five IDP loci are polymorphic between KCJ1266 and SS17, all of
which locate in prophage regions (Figure 2), indicating prophage polymorphisms are a
primary attribute for sub-strain diversification in E. coli O157.
Overview of KCJ1266 Genome
In order to further detail the genetic traits of KCJ1266 its whole genome
sequence was determined using PacBio sequencing technology. The KCJ1266 has a
chromosome of 5478683 bp which encodes for 5545 open reading frames, 106 tRNA
and 22 rRNA (Fig.3-5). The KCJ1266 genome contains a plasmid, pO157, of 95910 bp.
This plasmid contains 117 genes, including genes translate the type V secretion serine
protease (espP), hemolysin (hlyABCD), cytotoxin (toxB), catalase peroxidase (katP) and
42
the type III secreted proteins (etp operon). The overall genomic features of KCJ1266
are summarized in comparison to reference strains; SS17, EC4115, and EDL933 in
Table 1. The size of KCJ1266 genome is smaller than other two lineage I/II strains,
SS17 and EC4115. It contains a 95.91 Kbp plasmid which is homologous to the pO157
plasmid of SS17 and pO157 plasmid of EC4115, but lacks the additional plasmid
commonly possessed by SS17 and EC4115. These data indicate that KCJ1266
contains reduced genomic features compared to its close relatives.
Comparative Genomic Analyses.
LSPA-6 typing, clade analysis and IDP revealed that all three lineage I/II strains
investigated in this study, KCJ1266, SS17, and EC4115, commonly belong to hyper-
virulence clade but have been diverged genetically. Further, genetic makeup of
KCJ1266 and SS17 seem to be divergent each other despite they shared super-
shedding phenotype. To understand the genetic diversity of the lineage I/II strains in the
context of HV and SS properties, we conducted a series of comparative genomic
analysis of KCJ1266, SS17, and EC4115.
The homology of KCJ1266 and reference strains was showed by the use of
progressive Mauve, displaying 7 different synteny blocks (Figure 3-6). Aligned against
genome of SS17, EC4115 and EDL933, the genome of KCJ1266 has a higher
homology to SS17 and EC4115 than to EDL933. The non-homology region between
KCJ1266 and reference strains were identified to be primarily phage regions.
In details, the lengths of the 7 synteny blocks (SB) varied from ~45.4 kb to
~2,276 kb (Fig.3-6). SB1 is a ~1,249 kb sequence containing phage region 1 to 4. SB2,
a sequence of ~429 kb, SB3 with a length of ~ 45.4 kb contains part of phage region 8
(Table 3-3). SB4 of ~338.5 kb is inverted in EDL933. This block contains sections of
43
phage region 8 and 9. SB5 is a ~1,077.8 kb sequence that contains phage regions 10 to
14 and a section of phage region 9. SB6 with a ~62 kb length contains part of phage
region 15. In the whole genome of EDL933, this block was moved, inverted and inserted
between homologs of SB1 and SB2 of KCJ1266. SB7 contains phage regions of 16 to
19 and part of phage region 15 where a non-homology area was found. According to
the analysis, most of the non-homology areas between KCJ1266 and SS17 exist in
phage regions, suggesting that KCJ1266 and SS17 share highly conserved core
genome region. However, when the genome of KCJ1266 was compared to EC4115 and
EDL933, non-homology regions were frequently found in the core genome regions.
The plasmid of KCJ1266 was also compared with plasmids of reference strains.
There are 99% query coverage and 99% identity of pO157 plasmids between KCJ1266
and SS17 (Figure 3-7).
Functional Characterization of the Genome
KCJ1266 have 5545 coding sequences (CDS). Fifty-five percent (3082) of the
total CDS, including 2914 non-hypothetical and 168 hypothetical CDS, were categorized
into 27 main subsystem categories, including a total of 599 subsystems categories (Fig.
5). The other 44% (2463) of the total CDS were not included in these 599 subsystem
categories (Figure. 3-8).
Pair-wise comparisons of the functional genomes between KCJ1266 and the 3
reference strains were conducted based on the subsystem categories in order to find
unique gene entities in each genome (Table 3-2). In comparison between KCJ1266 and
SS17, KCJ1266 had three unique genes encoding nitrogen regulation protein NR (I),
DNA adenine methyltransferase (phage-associated) and KefF (glutathione-regulated
potassium-efflux system ancillary protein), while SS17 have one unique gene encoding
44
type III secretion protein SsaH. When KCJ1266 and EC4115 were compared with each
other, KCJ1266 had three unique genes encoding Nitrogen regulation protein NR (I),
DNA adenine methyltransferase and LSU ribosomal protein L32p, while EC4115 has
one unique gene encoding SsaH protein. Seventeen unique genes present in genome
of KCJ1266, when KCJ1266 were compared with EDL933. Beside the five genes shown
in Table 2, 12 phage encoding genes encoding phage tails and proteins were among
the KCJ1266 genes absent in the genome of EDL933.
All together, a majority of genes assigned to the subsystem categories in the
genome of KCJ1266 are also present in SS17 and EC4115, except a few variable
genes listed in Table 3-2. Genetic or physiological impacts of these minor differences, if
any, are not known.
Single Nucleotide Polymorphisms
By comparing coding sequences of KCJ1266 and the reference strains, SNPs of
KCJ1266 were identified. KCJ1266 has 109 and 196 SNPs compared with SS17 and
EDL933, respectively.
Of the 109 SNPs between SS17 and KCJ1266, 22 are non-synonymous single
nucleotide polymorphisms (nsSNP). ORFs containing the nsSNPs encode putative
functions including tetratricopeptide repeat protein, Alpha-ketoglutarate permease, and
PTS system glucitol/sorbitol-specific transporter subunit IIA.
Virulence and Colonization Factors
Since KCJ1266 belongs to the hyper-virulence clade 8 and displays supper-
shedder property we analyzed genes known to be involved in virulence and colonization
of this bacterium. A total of 252 genes related to virulence and colonization were
identified in KCJ1266. Of these, 232 genes are encoded by chromosome and 20 are
45
encoded by pO157 plasmid. According to their putative protein function, these genes
are divided into five groups, adhesion, effectors and toxins, secretion systems and other
virulence-associated genes.
In chromosome of KCJ1266, there are 85 genes in adhesion group, including fim
operon, encoding fimbrial proteins and csg operon encoding curli related proteins. Other
genes, such as fliC, efa-1 and ompA, which are not in operons are also found.
The effectors contain LEE-encoded effectors and non-LEE-encoded effectors.
The LEE-encoded effectors are EspA, EspB, EspF, EspG, EspH, EspZ, Tir, and
mitochondrial associated type III secreted effector protein encoded by map. Non-LEE-
encoded protein contains effectors encoded by nleA, nleC and nleD. The stx2 that
encodes A and B subunits of Shiga-Like-toxin 2 are found in chromosome of KCJ1266.
KCJ1266 contains both stx2a and stx2c genes, which is the same as reference strains,
SS17 and EC4115.
The secretion system group is consisted of genes that encode type three
secretion system (TTSS). Among these genes, TTSS components are encoded by
sepL, escD and escQ. The needle structure of TTSS is encoded by escC.
The other virulence-associated genes contain iron uptake genes, such as chuA,
chuS, chuT, chuU, chuW, chuX, chuY and iroB. These genes may play critical roles in
iron acquisition that will affect the outcome of the infection significantly in bacteria-host
interactions
Virulence factors of reference strains were also analyzed. The result shows that
KCJ1266, EC4115 and SS17 have almost the same virulence factors (Figure 3-9). All of
46
KCJ1266, SS17, EC4115 share similar composition of virulence genes, suggesting that
KCJ1266 may have the same virulence as EDL933, EC4115 and SS17.
Phage Regions in KCJ1266
A typical E. coli O157:H7 genome contains multiple lambdoid prophages which
are known to be a major contributor for the genomic diversity among strains.
Consistently, the IDP profile and MAUVE analyses in this study revealed that prophage-
related polymorphisms are a main contributor for genetic dynamics detected in
KCJ1266 and its relative strains. In addition, stx genes and a multitude of putative
virulence genes are carried by prophages. The integration sites for stx2a and stx2c in
the phage regions are shown to be argW and sbcB, respectively, in most of lineage I/II
and are conserved in KCJ1266. A total number of 19 phage regions were found across
the genome of KCJ1266 and major genes encoded in each phage region are
summarized in Table 3-3 and Figure 3-10. The completeness of phage regions are
describe as intact, incomplete and questionable based on the scoring of each phage
region, which is decided by the number of phage related coding sequences and the
homology of suspected regions to the sequences of phage regions in the database [76].
Most of these genes in phage regions of KCJ1266 were also present in phage regions
of SS17.
Previous study showed that Stx2a-encoding phage could be classified into four
major and two minor subtypes [25]. In silico analysis showed that KCJ1266 belongs to
Stx2a phage subtype of ϕStx2a_γ that can produce high level of Shiga toxin, suggesting
the hyper-virulence property of KCJ1266.
47
Phylogenetic Analysis
To understand the evolutionary position of KCJ1266, the phylogenetic analysis
was performed using whole genome sequences of 28 E. coli O157 strains, including
strains of human source, bovine source and outbreaks (i.e., Spinach outbreak and Taco
bell outbreak). Figure 3-11 shows that these strains were clustered into three major
groups which are congruent to the lineage I, lineage II, and lineage I/II. As expected,
KCJ1266, SS17, EC4115, other spinach outbreak strains, and Taco bell outbreak
strains formed a discrete lineage I/II group while EDL933 and Sakai strains belonged to
the lineage I group, and selected stains of bovine source form a lineage II group.
Lineage I/II group contained two distinct clusters; cluster 1 (10 spinach outbreak strains)
and cluster 2 (2 Taco bell outbreak strains). KCJ1266, SS17, another super shedder
SS52, EC4115 and two other spinach outbreak strains (EC4024 and EC4192) were
shown to be outgroups without forming a distinct cluster (Figure 3-11). KCJ1266 is
closest to EC4192. Eppinger et al. previously classified Spinach outbreak strains based
on SNP genotypes [73]. In this classification, all three EC4115, EC4024, and EC4192
strains were genotyped as Group B while stains in the inner Spinach outbreak cluster
were genotyped as either Group A or Bovine genotype II. All lineage I/II strains included
in this study have clade 8 genotype. All together, these data support that KCJ1266 are
closely related to the phylogenetically distinctive outgroups of lineage I/II, yet
possessing high virulence potentials.
Discussion
To discover the genetic traits that contribute to super-shedding, whole genome
sequencing and a variety of gene markers have been used in previous studies. The
Illumina sequencing method has been identified as one of the most popular methods
48
used for whole genome sequencing, however, gaps are generated within whole genome
sequence. At the same time, a large amount of Illumina sequencing data is not able to
be closed. In the current study PacBio sequencing was employed in order to generate a
gap free whole genome sequence to better characterize KCJ1266.
Whole genome sequencing data of KCJ1266 was compared with other reference
strains at a genomic level (Table.3-1), proving KCJ1266 a super-shedder-hyper-
virulence strain by analyses of phage regions, virulence factors, LSPA-6, IS629 profile,
function-based gene, whole genome, SNPs and phylogeny.
In this study we identified several critical features of E. coli O157:H7 KCJ1266
isolated from a super-shedding cow. KCJ1266, SS17 and EDL933 strains belong to
clade 8 and have the same LSPA-6, revealing they share the same phenomenon of
hyper-virulence. Second, IS629 typing shows the additional genetic variability among
these three closely related strains. This relationship and diversity are further detailed by
genomic characterization of KCJ1266 and comparative analysis with SS17 and
EC4115. In addition, virulence factors of KCJ1266 are highly similar with other
reference strains, suggesting that KCJ1266 is a hyper-virulent strain.
It is commonly believed that the phenomenon of super-shedding is caused by
three major factors which are bacterial, host and environmental factors [1, 8]. Among all
these factors, bacterial factors are studied the most based on phenotypic and genetic
characteristics. Manning et al. (2015) showed that clade 8 E. coli O157:H7 strains were
more likely to cause hemolytic uremic syndrome in humans after testing more than 500
E. coli O157:H7 strains [62]. Another study showed that E. coli O157:H7 strains of clade
8 isolated from cattle may partially be responsible for the high amount of HUS cases in
49
Argentina [77]. In this study, KCJ1266 was identified as a clade 8 strain belonging to
lineage I/II, suggesting that KCJ1266 may have hyper-virulence characteristics. This
result is consistent with the comparison of virulence related genes among KCJ1266 and
reference strains. Except one phage related gene, all the virulence related genes in
hyper-virulence reference strain (EDL933) were found to be present in KCJ1266. Ogura
et al. tested STEC O157:H7 isolates harboring different stx2 genes, finding that strains
harboring stx2a or both stx2a and stx2c could express higher levels of Stx2 than those
strains harboring only stx2c [25]. This finding is also consistent with the hyper-virulence
properties of KCJ1266. LSPA profile of KCJ1266 (211111) is the same as SS17 and
EC4115, which is consistent with phylogenetic analysis, suggesting that they are
phylogenetically related to each other. Although KCJ1266, SS17 and EC4115 are
phylogenetically related to each other, diversity in their IS629 profiles were observed.
The difference among inserted sequence based profiles may be representative of the
diversity of these three strains.
Its super-shedding and virulence gene characteristics are major factors that
identify KCJ1266 as a hyper-virulent strain. Since KCJ1266 was isolated from cattle
shedding STEC O157:H7 at a level of > 104 CFU/g feces, there is a greater chance for
this isolate to contaminate the environment and farm-related products. In addition, the
enhanced ability of KCJ1266 to produce biofilms indicates that KCJ1266 has enhanced
environmental fitness. The ability to produce biofilms means this strain may survive in
animal food products after food processing. In addition, the enhanced biofilm formation
ability of KCJ1266 suggests that it may have high affinity in cattle, which means
KCJ1266 may have enhanced within-farm and between-farm transmission.
50
The whole genome sequence of a low-shedder E. coli O157:H7 would have been
an additional reference to help identify the genetic traits that contribute to super-
shedding. However, there is no such whole genome sequence available. The reference
strains, SS17, EC4115 and EDL933, were chosen because they have similar genome
architecture and good quality. This may explain why no such specific genes responsible
for super-shedding were identified. In addition, the whole genome analysis at the
genomic level may not reflect the differences between super-shedder strains and low-
shedder strains. The existence of a gene in two different isolates does not necessarily
mean the same level of transcription and expression of this gene. Even in the same
isolate, the transcription and expression level of a gene may be affected or regulated by
other stimulus. It should be noted that a comparison of transcriptome and proteomics of
super-shedder isolates and low-shedder isolates may help understand the essence of
the phenomenon of super-shedding.
Although this research focuses on the bacterial factors related to super-shedding,
animal host factors are also related to super-shedding. A previous study showed that
the prevalence of E. coli O157:H7 strains isolated from super-, medium- and low-
shedders could be affected by genetic and physiological factors of animals [8]. Jeon et
al. (2013) reported that Brahman cattle are more resistant to E. coli O157:H7 [8]. Some
cattle probably be resistant to E. coli O157:H7, because they cannot be infected by
inoculation with different doses of E. coli O157:H7 [50, 78]. In addition, the innate and
adaptive immune response of the host are believed to be the critical host factors [10].
Although cattle have no receptor for Shiga toxin [79], its innate immune response can
be induced by colonization of E. coli in the GI tract [10]. In addition, dietary animal
51
husbandry practices play important roles in super-shedding. Diet composition, feed
processing and bactericidal properties of ruminal and volatile fatty acids could impact E.
coli shedding and surviving.
Conclusion
This study characterized a hyper-virulent STEC O157:H7 strain, KCJ1266, isolated from
a super-shedder. Although the genes related to super-shedding phenotype are not
identified in this study, the identification of the accurate, gap-free, and circular whole
genome sequence of KCJ1266 is a cornerstone for the optimization of outbreak source
tracking. In addition, KCJ1266 will serve as an ideal reference for the future study of the
super-shedding phenomenon.
There are several possible reasons explaining the result that none of the genes related
to super-shedding were identified in this experiment. The experimental setting was not
perfect for identifying super-shedding phenotype. Instead of comparing stains used in
this experiment, it will be better to compare the whole genomes of isolates from super-
shedders and low-shedders. In addition, the expression of proteins is not only related to
presence of genes, but also regulated by transcription factors. In this case, the
transcriptome and proteome of strains isolated from super- and low-shedders should be
compared. Furthermore, animal factors and environmental factors are also critical.
There is a probability that animal factors are modulating super-shedding phenotype.
52
Table 3-1. Genome statistics of KCJ1266 and reference O157 strains
KCJ1266 SS17 EC4115 EDL933
Length of Sequence (Mb) 5.48 5.52 5.57 5.53
G+C ratio (%) 50.5 50.5 50.5 50.4
Coding DNA Sequence (CDSs)
5274 5430 5608 5587
No. rRNA 22 22 22 22
No. tRNA 106 107 109 100
No. Plasmid 1 2 2 1
53
Table 3-2. Function-based gene comparison
Protein KCJ1266 SS17 EC4115 EDL933 EDL933 Function of protein
NR (I) + - - - - Nitrogen regulation
Enzyme + - - + + DNA adenine methyltransferase
KefF + - + + + Glutathione-regulated potassium-efflux system ancillary protein
SsaH - + + + + Type III secretion protein
L32p + + - - - LSU ribosomal protein
RTX + + + - - T1SS secreted agglutinin
YopD + + + - - Type III secretion host injection and negative regulator protein
tRNA dihydrouridine synthase A
+ + + - - RNA metabolism
54
Table 3-3. Genome encoded in the 19 phage regions of KCJ1266
Phage Regions
Size (Kbp)
Completeness Synteny block
Encoded genes Possible Phage name
SS17 EC4115 EDL933
1 26.5 Intact SB1 Phage DNA invertase; Phage integrase; and phage assembly protein
Entero SfI NC 027339
- + +
2 38.5 Intact SB1 Lysozyme and Attachment invasion locus protein precursor
Entero cdtI NC 009514
+ - -
3 38 Incomplete SB1 Phage assembly proteins and 3 tRNAs
Shigel POCJ13 NC 025434
- - +
4 29.4 Intact SB1 Attachment invasion locus protein precursor and phage lysis
Entero BP 4795 NC 004813
+ + +
5 50.5 Intact SB2 Integrase and phage assembly proteins
Entero BP 4795 NC 004813
+ + +
6 46.5 Intact SB2 Integrase, phage lysin, attachment invasion locus protein precursor
Entero lambda NC 001416
+ + +
7 8 Questionable SB2 Mobile element proteins Stx2 converting 1717 NC 011357
+ + +
8 57 Intact SB2 and SB3
Attachment invasion locus protein precursor, 2 tRNAs, phage lysis, acfC, and integrase
Entero HK629 NC 019711
- - -
9 94.8 Intact SB4 and SB5
Attachment invasion locus protein precursor, phage lysis 5 tRNAs and integrase
Entero YYZ 2008 NC 011356
+ + +
10 24.8 Incomplete SB5 Integrase and 3 tRNAs Entero P88 NC 026014
- + +
55
Table 3-3. Continued
Phage Regions
Size (Kbp)
Completeness Synteny block
Encoded genes Possible Phage name
SS17 EC4115 EDL933
11 54 Intact SB5 Integrase, phage lysin, inv and 5 tRNAs
Entero BP 4795 NC 004813
+ + +
12 61.2 Intact SB5
Attachment invasion locus protein precursor, integrase, yeeV, yeeX, stx2A, stx2Bc and 3 tRNAs
Stx2 converting 1717 NC 011357
+ + +
13 24 Intact SB5 Phage assembly proteins and Phage lysin
Entero P2 NC 001895
+ - -
14 73.5 Intact SB5 Integrase and attachment invasion locus protein precursor
Entero BP 4795 NC 004813
+ + +
15 77.2 Questionable
SB5, SB6 and SB7
Integrase, attachment invasion locus protein precursor, Phage lysin, stx2A, stx2B and 4 tRNAs
Stx2 converting I NC 003525
+ + +
16 23.9 Questionable SB7 Phage lysin and integrase Stx2 converting 1717 NC 011357
+ + +
17 13.1 Questionable SB7 Mobile element proteins Stx2 converting 1717 NC 011357
+ + +
18 20.5 Questionable SB7 Integrase, yeeU, yeeV, espA, espB, espD, espF, sseE, yscL, escD, eae, and tir chaperone
Entero Sf6 NC 005344
+ - +
19 21.7 Questionable SB7 Integrase and phage eae Entero mEp460 NC 019716
+ + +
56
Figures
Figure 3-1. Shiga-toxin II detection. A. Phage induction was measured. MMC was add to cell culture of EDL933,
KCJ1266 and DH5α at the 3rd, 3rd and 4th hour, respectively (Red arrows). B. PCR of stx2a and stx2c C. SDS-PAGE analysis of phage proteins. D. Western blot.
57
Figure 3-2. Adhesion of E. coli O157:H7 isolates to Hep-2 cells, MOI: 100. The Assay was performed in triplicate.
58
Figure 3-3. Biofilm assay of KCJ1266. EDL933 was used as a positive control and ΔfimH mutant of EDL933 was used as
a negative control
59
Figure 3-4. IS629 profile of KCJ1266, SS17, EC4115 and EDL933. A shaded gray box indicates the presence of the in
silico amplicon with correct size and locus, while an unshaded white box indicates a negative in silico result. The three reference strains (EDL933, EC4115 and SS17) are compared.
Str
ain
stx
1
stx
2a
(wrb
A)
stx
2a
(ye
hV
)
stx
2a
(arg
W)
stx
2c
Cla
de
LS
PA
-6
pro
file
Lin
ea
ge
LI-
US
-8
LI-
DS
-17
LI-
US
-9
LI-
DS
-11
LI-
DS
-18
LI-
DS
-1
LI-
DS
-7
LI-
US
-16
LI-
DS
-10
LI-
DS
-19
LI-
DS
-5
LI-
DS
-15
LI-
DS
-6
LI-
US
-13
LI-
DS
-14
LI/
II-D
S-1
5
LI/
II-D
S-4
LI/
II-D
S-7
LI/
II-D
S-1
0
LI/
II-D
S-1
2
LI/
II-D
S-1
3
LI/
II-D
S-1
6
LI/
II-D
S-1
8
LI/
II-D
S-3
LII
-DS
-11
LII
-DS
-3
LII
-DS
-2
LII
-DS
-8
LII
-US
-1
LII
-DS
-10
LII
-DS
-6
LII
-DS
-9
EDL933 3 111111 I
EC4115 8 211111 I/II
SS17 8 211111 I/II
KCJ1266 8 211111 I/II
* * * * * * * * * * * * * * * * * * *
60
Figure 3-5. Genome map of KCJ1266. Marked characteristics are shown from outside to the center. KCJ1266: CDS on
forward strand, tRNA and rRNA in forward strand, tRNA and rRNA in reward strand, CDS on reverse strand, GC content and GC skew; pO157: CDS on forward strand, tRNA and rRNA in forward strand, tRNA and rRNA in reward strand, CDS on reverse strand, GC content and GC skew.
61
Figure 3-6. Mauve alignments of KCJ1266 with the three reference genome. Alignment of KCJ1266 with the three
reference strains (SS17, EC4115 and EDL933) reveal 7 blocks of homology each of varying from ~45.4 kb to ~ 2,276 kb. Each block is a different color with lines connecting corresponding homologous blocks, with the white regions indicating non-homology. (* indicates the block that only exists in SS17 and EDL933)
62
Figure 3-7. Comparison of O157 plasmids of KCJ1266 and other 3 reference strains
63
Figure 3-8. Subsystem category distribution. The subsystem contains 56% of total genes. The other 46% of genes don’t
belong to any of the subsystem.
64
Figure 3-9. Phage comparison of KCJ1266 with reference strains. From inner ring: phage regions of EC4115, phage regions of SS17, phage regions of KCJ1266. The same color represent homologous regions.
65
Figure 3-10. Virulence related genes in KCJ1266 and reference strains. A. Known genes detected in KCJ1266 B. Putative
genes, hypothetical genes, mobile genes and phage related genes detected in KCJ1266
66
Figure 3-11. Strains are clustered into three groups which belong to Lineage I (green), Lineage II (red) and Lineage I/II
(blue). Within Lineage I/II, there are three subgroups which are cluster1, cluster2 and outgroup. KCJ1266, EC4115 and SS17 belong to outgroup of Lineage I/II.
67
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BIOGRAPHICAL SKETCH
Lin Teng was born in Fuzhou, Fujian, China in 1990. He enrolled at the
Huazhong Agricultural University in Wuhan, China, one of the most foremost
Agricultural Universities in China in 2008. His B.S. project focused on constructing
deletion mutant strains of extraintestinal pathogenic Escherichia coli and evaluating the
change of toxicity of mutant strains. Lin earned his Bachelor of Agronomy degree at
Huazhong Agricultural University in 2012. After graduation from the university, Lin
served in Fujian Fengze Group Cooperation, a feed and meat producer, for one year as
a research assistant. In 2014, he was accepted by the Department of Animal Science of
University of Florida as a M.S. student and joined Dr. KwangCheol Casey Jeong’s lab.
During his M.S. program, he got scientific training and participated in some other project,
such as the projects of Chitosan nanoparticles and antimicrobial resistance. His long-
term plan is to work in the industry in China. His immediate plan is to learn more
bioinformatics techniques in the current lab and finish his other ongoing projects.