Tricarboxylic Acid Cycle and One-Carbon Metabolism Pathways Are Important in Edwardsiella ictaluri Virulence

Edwardsiella ictaluri is a Gram-negative facultative intracellular pathogen causing enteric septicemia of channel catfish (ESC). The disease causes considerable economic losses in the commercial catfish industry in the United States. Although antibiotics are used as feed additive, vaccination is a better alternative for prevention of the disease. Here we report the development and characterization of novel live attenuated E. ictaluri mutants. To accomplish this, several tricarboxylic acid cycle (sdhC, mdh, and frdA) and one-carbon metabolism genes (gcvP and glyA) were deleted in wild type E. ictaluri strain 93-146 by allelic exchange. Following bioluminescence tagging of the E. ictaluri ΔsdhC, Δmdh, ΔfrdA, ΔgcvP, and ΔglyA mutants, their dissemination, attenuation, and vaccine efficacy were determined in catfish fingerlings by in vivo imaging technology. Immunogenicity of each mutant was also determined in catfish fingerlings. Results indicated that all of the E. ictaluri mutants were attenuated significantly in catfish compared to the parent strain as evidenced by 2,265-fold average reduction in bioluminescence signal from all the mutants at 144 h post-infection. Catfish immunized with the E. ictaluri ΔsdhC, Δmdh, ΔfrdA, and ΔglyA mutants had 100% relative percent survival (RPS), while E. ictaluri ΔgcvP vaccinated catfish had 31.23% RPS after re-challenge with the wild type E. ictaluri.     

In vitro and in vivo interaction of macrophages from vaccinated and non-vaccinated channel catfish (Ictalurus punctatus) to Edwardsiella ictaluri

Macrophages from catfish vaccinated with an Edwardsiella ictaluri vaccine and macrophages from non-vaccinated catfish were used in in vitro and in vivo studies with red-fluorescent E. ictaluri to assess phagocytic ability, reactive oxygen and nitric oxide production and bactericidal activity. In the in vitro experiment, macrophages were harvested from vaccinated and non-vaccinated fish and then exposed to red-fluorescent E. ictaluri. Results of this study showed that E. ictaluri can survive and replicate in macrophages from non-vaccinated catfish (relative percent killing, RPK, from 0.011 to 0.620 and from ?0.904 to 0.042 with macrophage:bacteria ratios of 1:20 and 1:100, respectively) even in the presence of reactive oxygen and nitrogen products. Macrophages from vaccinated fish were significantly (p < 0.05) more efficient in killing E. ictaluri (RPK from 0.656 to 0.978 and from 0.011 to 0.620 with macrophage:bacteria ratios of 1:20 and 1:100, respectively) and produced significantly (p < 0.05) higher amounts of ROS (10-fold increase) and nitrogen oxide (about 10-fold increase) than macrophages from non-vaccinated fish. In the in vivo experiment, vaccinated and non-vaccinated catfish were injected with red-fluorescent E. ictaluri to allow the interaction between macrophages and other components of the immune system. After 6 h, macrophages were harvested from the fish and seeded in glass chamber slides and bactericidal activity was measured in vitro. Results showed in vivo interaction of other components of the immune system enhanced bactericidal activity of macrophages from vaccinated fish. In another set of experiments, catfish were intraperitoneally injected with fluorescent bacteria opsonized with immune serum or non-opsonized and necropsied in the first 48 h after bacterial challenge to observe localization of E. ictaluri between vaccinated and non-vaccinated catfish. Vaccinated fish were able to control the dispersion of E. ictaluri in the body and red-fluorescent bacteria were observed only in the spleen, anterior and trunk kidney. In non-vaccinated fish E. ictaluri was able to replicate and invade all organs with the exception of the brain. We further determined that macrophages seeded with E. ictaluri could cause infection in non-vaccinated fish upon reinoculation with in vitro infected-macrophages. Overall, the results indicated that macrophages from vaccinated fish are activated and responsible for rapid clearance of infection upon re-exposure to virulent E. ictaluri.     

Susceptibility of European catfish (Silurus gianis) to Edwardsiella ictaluri

European catfish (Silurus glanis) were tested for their susceptibility to the bacterium Edwardsiella ictaluri. The LD₅₀ of E. ictaluri when injected into European catfish was 5.4 × 10⁶ compared to 7.1 times; 10⁴ for channel catfish (Ictalurus punctatus). E. ictaluri was isolated from dead and moribund European catfish and the bacterium was also detected in kidney smears by an indirect fluorescent antibody (FA) technique. The bacterium was not isolated or detected by FA from surviving fish 15 days after injection. No clinical signs of E. ictaluri infection were noted in European catfish, but these were prevalent in the channel catfish. These experiments indicate that under experimental conditions European catfish are not as susceptible to E. ictaluri as channel catfish.     

Immune system of channel catfish: An overture on immunity to Edwardsiella ictaluri

Edwardsiella ictaluri is a gram negative rod that causes enteric septicemia of catfish (ESC). The E. ictaluri disease complex includes acute and chronic ESC. One of the most economically important diseases of channel catfish, Ictalurus punctatus, ESC is difficult to control. Although the bacterium is usually susceptible to antibiotics, resistant strains are emerging. Immunization is a more attractive approach to control. Vaccine efficacy is not well documented, in part due to a lack of basic information about immune system components and their interactions after E. ictaluri infection. Channel catfish vaccinated by immersion in E. ictaluri bacterin are only partly protected against ESC. Specific antibody responses are poor in the vaccinates. E. ictaluri infection causes both humoral and cell-mediated immune responses. A vaccine that stimulates both types of immunity may provide better ESC immunity. Diagnosis of E. ictaluri infection is accomplished by detection of specific antibody. Recently the discovery of an immunodominant E. ictaluri exoantigen is allowing the development of accurate and rapid diagnostic tests that can detect infection before clinical ESC occurs. Health management programs for food animals depend on serological tests to detect early infections and carriers; the value of these tests is now realized in the channel catfish industry. This review documents factors that influence the immune responses of channel catfish. These factors include the influence of water temperature, seasons, stressful conditions, diet, and E. ictaluri carrier status.     

Structure and expression of transferrin gene of channel catfish,Ictalurus punctatus

Transferrin is important in iron metabolism and has been reported to be involved in disease defence responses after bacterial infection. In this study, we identified, sequenced, and characterized the transferrin gene from channel catfish, Ictalurus punctatus. The catfish transferrin gene was similar to those of other vertebrate species with 17 exons and 16 introns. Sequence analysis indicated the presence of the two duplicated lobes, each containing two sub-domains separated by a cleft harboring the iron-binding site, suggesting their structural conservation. The channel catfish transferrin cDNA encodes 679 amino acids with 42–56% similarity to known transferrin genes from various species. Southern blot analysis suggested the presence of two copies of the transferrin gene in the catfish genome, perhaps arranged in a tandem fashion. The catfish transferrin gene was mapped to a catfish BAC-based physical map. The catfish transferrin gene was highly expressed in the liver, but expression was low in most other tested tissues. Transferrin expression was significantly up-regulated after infection with Edwardsiella ictaluri, the causative agent of enteric septicemia of catfish. Such induction was also found with co-injection of iron-dextran and E. ictaluri, while transferrin expression was not significantly induced with the injection of iron-dextran alone.     

Edwardsiella ictaluri Encodes an Acid-Activated Urease That Is Required for Intracellular Replication in Channel Catfish (Ictalurus punctatus) Macrophages

Genomic analysis indicated that Edwardsiella ictaluri encodes a putative urease pathogenicity island containing the products of nine open reading frames, including urea and ammonium transporters. In vitro studies with wild-type E. ictaluri and a ureG::kan urease mutant strain indicated that E. ictaluri is significantly tolerant of acid conditions (pH 3.0) but that urease activity is not required for acid tolerance. Growth studies demonstrated that E. ictaluri is unable to grow at pH 5 in the absence of urea but is able to elevate the environmental pH from pH 5 to pH 7 and grow when exogenous urea is available. Substantial production of ammonia was observed for wild-type E. ictaluri in vitro in the presence of urea at low pH, and optimal activity occurred at pH 2 to 3. No ammonia production was detected for the urease mutant. Proteomic analysis with two-dimensional gel electrophoresis indicated that urease proteins are expressed at both pH 5 and pH 7, although urease activity is detectable only at pH 5. Urease was not required for initial invasion of catfish but was required for subsequent proliferation and virulence. Urease was not required for initial uptake or survival in head kidney-derived macrophages but was required for intracellular replication. Intracellular replication of wild-type E. ictaluri was significantly enhanced when urea was present, indicating that urease plays an important role in intracellular survival and replication, possibly through neutralization of the acidic environment of the phagosome.Identification of virulence factors is vitally important to an understanding of the pathogenesis of Edwardsiella ictaluri and to the development of methods for controlling the spread of disease. Although the pathogenesis of E. ictaluri was reviewed in 1993 (28, 31), recent reports demonstrated that E. ictaluri is a facultative intracellular pathogen (3) and that a type III secretion system is required for intracellular survival and replication within channel catfish head kidney-derived macrophages (HKDM) (30). Using signature-tagged mutagenesis (STM) in an immersion challenge model for E. ictaluri, Thune et al. (30) identified 50 transconjugants carrying transposon insertions in genes required for survival and replication in the channel catfish host. Two of those mutants had insertions in genes encoding homologs of UreG and UreF, proteins that are essential for the production of an active urease enzyme in other bacteria (6, 10, 14, 26). UreG is a GTP-binding accessory protein that functions in energy-dependent assembly of the urease holoenzyme (19), while UreF is a urease accessory protein that functions in the generation or delivery of carbon dioxide to the urease metallocenter assembly site (19). Both the ureG and ureF mutant strains were further characterized in a competitive challenge with the wild-type (WT) parental strain and were confirmed to be significantly attenuated (30). The identification of two mutants with insertions in urease-associated genes suggests an important role for urease activity in E. ictaluri pathogenesis, despite the fact that E. ictaluri is urease negative in standard biochemical tests. Consequently, the objectives of this study are to characterize the E. ictaluri urease pathogenicity island (PAI), to evaluate conditions for E. ictaluri urease activity, and to establish a possible role for urease in E. ictaluri pathogenesis.     

Edwardsiella ictaluri in a Colony of Zebrafish (Danio rerio) Used in a Teaching Laboratory

A small colony of zebrafish (Danio rerio) experienced 30% acute mortality within a few days after receipt from a commercial source. A few fish presented with small areas of raised scales or tissue necrosis, primarily near the caudal peduncle. Edwardsiella ictaluri (E. ictaluri) was identified by real-time PCR of pooled zebrafish and swabs of the pre-filter and fine filter pads, with subsequent sequence analysis. E. ictaluri is most commonly associated with an enteric septicemia in catfish species and can have significant economic impact on commercial catfish fisheries. However, several references report naturally occurring E. ictaluri infection of nonictalurid fishes, including zebrafish. Ours is the first report demonstrating the use of environmental sampling to identify E. ictaluri in a zebrafish colony by real-time PCR. Moreover, our report indicates that E. ictaluri is a relevant disease for institutions using zebrafish as research species and emphasizes the importance of carefully considering importation and quarantine practices.

Edwardsiella ictaluri (E. ictaluri) is a gram-negative facultative intracellular bacterium, known primarily for its economic impact in catfish (Ictalurus spp.) aquaculture in the United States. E. ictaluri is the causative agent for Enteric Septicemia of Catfish (ESC), or Hole-in-the-Head disease of catfish, and is one of the most commonly reported diseases by US catfish producers.^6,17,22,25 The significant economic impact of ESC has driven ongoing research and development of various vaccines administered through immersion and feeding.^17,22,39 Disease transmission among fish occurs by direct contact through the fecal-oral route, nasal passages, and gills.^6,12,17 In catfish, E. ictaluri infection can present as areas of hemorrhage around the base of fins, skin ulceration in various locations, bulging eyes, and a distended abdomen, with mortality of 10 to 50% in populations of pond-raised channel catfish (Ictalurus punctatus).^6,12 Nonictalurid fish that are susceptible to spontaneous infection are phylogenetically diverse. These species of fish include: Ayu (Plecoglossus altevelis),³⁴ Bengal danios (Devario devario),³⁸ green knifefish (Eigemannia virescens),¹⁶ a red-bellied piranha (Pygocentris nattereri),¹⁹ Nile tilapia (Oreochromis niloticus),³⁷ and hybrid red tilapia (Oreochromis sp.).⁷ Naturally occurring epizootics have been reported in 3 laboratory zebrafish colonies,¹² and since 2013 IDEXX BioAnalytics has identified E. ictaluri as the cause of morbidity and mortality in zebrafish colonies from 6 institutions. Clinical presentation of edwardsiellosis caused by E. ictaluri in zebrafish can include tissue necrosis, abdominal distention, general lethargy, raised scales, and skin hemorrhage, although acute mortality without clinical signs is also common.^12,26 The disease is generally systemic. A number of organs can be affected including the kidney, spleen, and brain with large quantities of bacteria present, often located within macrophages. ¹² Experimental E. ictaluri infections have also been described in many nonictalurid hosts such as rainbow trout (Oncorhynchus mykiss), Chinook salmon (Oncorhynchus tshawytscha),³ and blue tilapia (Oreochromis aureus).²⁸ Zebrafish have been used as an experimental model for ESC.^14,26,33,36 This article describes an outbreak of Edwardsiella ictaluri in zebrafish purchased for use in undergraduate studies. The diagnosis was based on clinical signs, identification of E. ictaluri by real-time PCR in both clinically diseased fish and environmental samples from the tank filter, and sequence analysis. To our knowledge, this is the first report demonstrating the use of environmental sampling to identify Edwardsiella ictaluri in a colony of zebrafish.     

Identification of Bacillus Strains for Biological Control of Catfish Pathogens

Bacillus strains isolated from soil or channel catfish intestine were screened for their antagonism against Edwardsiella ictaluri and Aeromonas hydrophila, the causative agents of enteric septicemia of catfish (ESC) and motile aeromonad septicaemia (MAS), respectively. Twenty one strains were selected and their antagonistic activity against other aquatic pathogens was also tested. Each of the top 21 strains expressed antagonistic activity against multiple aquatic bacterial pathogens including Edwardsiella tarda, Streptococcus iniae, Yersinia ruckeri, Flavobacterium columnare, and/or the oomycete Saprolegnia ferax. Survival of the 21 Bacillus strains in the intestine of catfish was determined as Bacillus CFU/g of intestinal tissue of catfish after feeding Bacillus spore-supplemented feed for seven days followed by normal feed for three days. Five Bacillus strains that showed good antimicrobial activity and intestinal survival were incorporated into feed in spore form at a dose of 8×10⁷ CFU/g and fed to channel catfish for 14 days before they were challenged by E. ictaluri in replicate. Two Bacillus subtilis strains conferred significant benefit in reducing catfish mortality (P<0.05). A similar challenge experiment conducted in Vietnam with four of the five Bacillus strains also showed protective effects against E. ictaluri in striped catfish. Safety of the four strains exhibiting the strongest biological control in vivo was also investigated in terms of whether the strains contain plasmids or express resistance to clinically important antibiotics. The Bacillus strains identified from this study have good potential to mediate disease control as probiotic feed additives for catfish aquaculture.     

Genome-Wide Identification of Hsp40 Genes in Channel Catfish and Their Regulated Expression after Bacterial Infection

Heat shock proteins (HSPs) consist of a large group of chaperones whose expression is induced by high temperature, hypoxia, infection and a number of other stresses. Among all the HSPs, Hsp40 is the largest HSP family, which bind to Hsp70 ATPase domain in assisting protein folding. In this study, we identified 57 hsp40s in channel catfish (Ictalurus punctatus) through in silico analysis using RNA-Seq and genome databases. These genes can be classified into three different types, Type I, II and III, based on their structural similarities. Phylogenetic and syntenic analyses provided strong evidence in supporting the orthologies of these HSPs. Meta-analyses of RNA-Seq datasets were conducted to analyze expression profile of Hsp40s following bacterial infection. Twenty seven hsp40s were found to be significantly up- or down-regulated in the liver after infection with E. ictaluri; 19 hsp40s were found to be significantly regulated in the intestine after infection with E. ictaluri; and 19 hsp40s were found to be significantly regulated in the gill following infection with F. columnare. Altogether, a total of 42 Hsp40 genes were regulated under disease situations involving three tissues and two bacterial infections. The significant regulated expression of Hsp40 genes after bacterial infection suggested their involvement in disease defenses in catfish.     

Use of Fluorescent Immuno-Chemistry for the detection of Edwardsiella ictaluri in channel catfish (I. punctatus) samples

While Edwardsiella ictaluri is a major pathogen of channel catfish Ictalurus punctatus and has been discovered nearly three decades ago ^1,2, so far, to the best of these authors'' knowledge, no method has been developed to allow for the in situ visualization of the bacteria in histological sections.While bacterial localization has been determined in vivo in previous studies using plate counts ³, radiometric labeled ⁴, or bioluminescent bacteria ⁵, most of these studies have only been performed at the gross organ level, with one exception ⁶. This limitation is of particular concern because E. ictaluri has a complex infection cycle ^1,7, and it has a variety of virulence factors ^8,9. The complex interaction of E. ictaluri with its host is similar in many respects to Salmonella typhi ¹⁰, which is in the same taxonomic family.Here we describe a technique allowing for the detection of bacteria using indirect immuno-histochemistry using the monoclonal Ed9 antibody described by Ainsworth et al.¹¹.Briefly, a blocking serum is applied to paraffin embedded histological sections to prevent non-specific biding. Then, the sections are incubated with the primary antibody: E. ictaluri specific monoclonal antibody Ed9. Excess antibodies are rinsed away and the FitC labeled secondary antibodies are added. After rinsing, the sections are mounted with a fluorescent specific mounting medium.This allowed for the detection of E. ictaluri in situ in histological sections of channel catfish tissues.Download video file.^{(33M, mov)}     

Detection of Quorum Sensing Signal Molecules in Edwardsiella ictaluri Ei-151

Edwardsiella ictaluri is a Gram-negative pathogenic bacterium in the family Enterobacteriaceae that causes enteric septicemia of catfish, which has become a significant problem in the aquaculture of striped catfish (Pangasianodon hypophthalmus) in Vietnam. In this study, a bacterium designated as Ei-151 was isolated from diseased striped catfish and proved to be virulent. Based on 16S rDNA sequencing and phenotypic tests, the pathogenic bacterium was identified as Edw. ictaluri. The presence of quorum sensing signal molecules in Edw. ictaluri Ei-151 was detected with different biosensor strains. The results showed that Ei-151 produced at least three kinds of acylated homoserine lactone (AHL) signal molecules as detected with the biosensor Agrobacterium tumefaciens KYC55, and the AHLs fingerprint was similar to that of Edw. tarda. During its entire growth, the levels of AHLs and autoinducer-2 produced by Ei-151 peaked at the stationary phase (OD₆₀₀ 1.8), which suggested that both of them may function at the stationary phase. No Cholerae autoinducer-1-like activity (including Edw. ictaluri LMG7860^T) was detected.     

Proteome analysis of Edwardsiella ictaluri

Edwardsiella ictaluri is a facultative intracellular Gram‐negative bacterium causing enteric septicemia of catfish (ESC), the most prevalent disease affecting farm‐raised channel catfish in the United States. Despite its economic importance, studies addressing high‐throughput proteomics were not possible because of lack of comprehensive protein database. Here, we report the first high‐throughput proteomics analysis of E. ictaluri using 2‐D LC ESI MS/MS and 2‐DE MALDI TOF/TOF MS. Proteins identified in this study and predicted from the whole E. ictaluri genome were clustered into functional groups using clusters of orthologous groups (COG), and their subcellular locations were predicted. Possible functional relationships among proteins were determined using pathway analysis. The total number of unique E. ictaluri proteins identified using both 2‐D LC and 2‐DE approaches was 788, of which 15.48% (122) were identified by both methods while 78.43% (618) and 6.09% (48) were unique in 2‐D LC and 2‐DE, respectively. COG groupings and subcellular localizations were quite similar between our data set and proteins predicted from the whole genome. Twelve pathways were significantly represented in our dataset (p <0.05). Results from this study provided experimental evidence for many proteins that were predicted from the E. ictaluri genome annotation, and they should accelerate future functional and comparative studies aimed at understanding virulence mechanisms of this important pathogen.     

Molecular characterization of three L-type lectin genes from channel catfish, Ictalurus punctatus and their responses to Edwardsiella ictaluri challenge

L-type lectins have a leguminous lectin domain and can bind to high-mannose type oligosaccharides. In the secretory pathway, L-type lectins play crucial roles in selective protein trafficking, sorting and targeting. Three L-type lectins were cloned in the channel catfish, Ictalurus punctatus, the 53 kDa endoplasmic reticulum ER-Golgi intermediate compartment protein (ERGIC-53), the vesicular integral protein of 36 kDa (VIP36) and VIP36-like. Phylogenetic analysis indicated that the catfish genes are orthologous to their counterparts in other species. Southern blot analysis demonstrated that all three L-type lectin genes are likely single-copy genes in the catfish genome. Analysis of expression in healthy tissues using quantitative real time RT-PCR indicated that all three genes are expressed widely in all tested tissues, but with strong tissue preference of expression: ERGIC-53 was found to be abundantly expressed in the liver, VIP36 was found to be abundantly expressed in the head-kidney, whereas VIP36-like was found to be abundantly expressed in the brain. Upon infection with Edwardsiella ictaluri, expressions of the three genes all had significant up-regulation in the head-kidney, but had distinct expression patterns: ERGIC-53 was gradually induced with the highest expression 7 days after challenge in the head-kidney, but was down-regulated in the liver, spleen, and brain. VIP36 was highly induced in the head-kidney, and 3 days after challenge in the brain, but was not up-regulated in any other tissues or timepoints after challenge. Expression levels of the catfish VIP36-like gene appeared to also respond to infection, albeit with differing patterns among the tested tissues. Taken together, our results indicate that all three L-type lectin genes may be involved in the immune responses of catfish after infection with E. ictaluri.     

Toll-like receptor 3 and TICAM genes in catfish: species-specific expression profiles following infection with Edwardsiella ictaluri

Toll-like receptors (TLRs) are a family of transmembrane proteins that recognize specific pathogen-associated molecular patterns and use conserved signaling pathways to activate proinflammatory cytokines and type-1 interferons to fight infection. TLR3 in mammals is best known for its recognition of dsRNA as ligand and its MyD88-independent signaling. TLR3, upon recognition of dsRNA, recruits and binds its adaptor protein TIR domain-containing adapter molecule (TICAM) 1. Here we report the genomic sequences and structures of TLR3 and a TICAM adaptor from channel catfish (Ictalurus punctatus). Whereas a partial TLR3 cDNA sequence has been reported from channel catfish, and complete TLR3 genes are known from other teleost fish species, a complete TICAM sequence has not been previously reported from a nonmammalian species. Analysis of catfish TLR3 and TICAM expression after infection with Edwardsiella ictaluri, the causative agent of enteric septicemia of catfish (ESC), suggested a conserved TLR3-TICAM receptor–adaptor relation in catfish. Comparison of TLR3 and TICAM expression profiles in channel catfish with those from the closely related blue catfish species (Ictalurus furcatus), which exhibits strong resistance to ESC, revealed a striking pattern of species-specific expression. A dramatic downregulation of TLR3 and TICAM gene expression was observed in blue catfish head kidney and spleen, which we speculate may be the result of maturation and migration of different cell types to and from the lymphoid tissues following infection.Electronic supplementary material Supplementary material is available in the online version of this article at and is accessible for authorized users.Puttharat Baoprasertkul and Eric Peatman contributed equally to this work.     

Identification and characterization of bacteriophages specific to the catfish pathogen,Edwardsiella ictaluri

Aims: To identify and characterize bacteriophages specific for Edwardsiella ictaluri, the causative agent for enteric septicemia of catfish (ESC). Methods and Results: Two bacteriophages were isolated that infect Edw. ictaluri. They both produce clear plaques, have icosahedral heads with a non‐rigid tail, and are tentatively classified as Siphoviridae. Phages ΦeiDWF and ΦeiAU are dsDNA viruses with approximate genome sizes of 40 and 45 kb, respectively. The addition of 500 μmol l^?1 CaCl₂ enhanced phage titres. Both phages have a latent period of 40 min and an estimated burst size of 270. Every Edw. ictaluri strain tested was susceptible to phage infection with variable plaquing efficiencies and with no evidence of lysogeny, with no plaques detected on other bacterial species. Conclusions: Two unique bacteriophages were isolated that show host‐specificity for Edw. ictaluri, have temperature and metal cation‐dependent infectivity, and are tentatively placed within the family Siphoviridae. Significance and Impact of the Study: This is the first report of bacteriophages specific to Edw. ictaluri, an important fish pathogen affecting farm‐raised channel catfish. Initial characterization of these bacteriophages has demonstrated their potential use as biotherapeutic and diagnostic agents associated with ESC.     

Comparison of 61 Sequenced Escherichia coli Genomes

Escherichia coli is an important component of the biosphere and is an ideal model for studies of processes involved in bacterial genome evolution. Sixty-one publically available E. coli and Shigella spp. sequenced genomes are compared, using basic methods to produce phylogenetic and proteomics trees, and to identify the pan- and core genomes of this set of sequenced strains. A hierarchical clustering of variable genes allowed clear separation of the strains into clusters, including known pathotypes; clinically relevant serotypes can also be resolved in this way. In contrast, when in silico MLST was performed, many of the various strains appear jumbled and less well resolved. The predicted pan-genome comprises 15,741 gene families, and only 993 (6%) of the families are represented in every genome, comprising the core genome. The variable or ‘accessory’ genes thus make up more than 90% of the pan-genome and about 80% of a typical genome; some of these variable genes tend to be co-localized on genomic islands. The diversity within the species E. coli, and the overlap in gene content between this and related species, suggests a continuum rather than sharp species borders in this group of Enterobacteriaceae.