Cryptic Lineages of the Genus
            <i>Escherichia</i>

Walk, Seth T.; Alm, Elizabeth Wheeler; Gordon, David M.; Ram, Jeffrey L.; Toranzos, Gary A.; Tiedje, James M.; Whittam, Thomas S.

doi:10.1128/aem.01262-09

Cited by 238 publications

(259 citation statements)

References 64 publications

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“…The small distances and consistent grouping of the two environmentals in all culture conditions, together with differences in their ecological strategy compared with other strains, suggest that they do indeed form a separate ecotype as proposed earlier, where extra-intestinal open environments serve as their primary habitat (Walk et al, 2009;Luo et al, 2011). It should be noted that E. coli strains belonging to the same clades as the strains used in this study are commonly detected in bird feces as well (Clermont et al, 2011), but it is currently not clear if these strains cycle between birds and the environment or whether different ecotypes with distinct primary habitats do exist within those lineages.…”

Section: Signatures Of Ecological Adaptationmentioning

confidence: 86%

“…It spans a genetic continuum from the human associated enteric E. coli to several atypical clades that are frequently detected in the environment and in birds (Clermont et al, 2011). All clades share the same core genes (that is, atypical strains exhibit all genes considered typical for enteric E. coli) and show remarkable biochemical similarities, which left them categorized as the same species (Walk et al, 2009). Subsequently, a taxonomic placement of these atypical clades as different species was proposed because (i) phylogenetic analysis cluster human enteric strains together and apart from atypical strains, (ii) several genes that are considered important for adaptation to distinct primary habitats (the human gut versus the environment) are specifically enriched in the individual groups and (iii) the exchange of genetic material has been shown to occur predominantly within strains sharing the same primary habitat (Luo et al, 2011).…”

Section: Introductionmentioning

confidence: 99%

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Gene expression analysis of E. coli strains provides insights into the role of gene regulation in diversification

et al. 2014

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Escherichia coli spans a genetic continuum from enteric strains to several phylogenetically distinct, atypical lineages that are rare in humans, but more common in extra-intestinal environments. To investigate the link between gene regulation, phylogeny and diversification in this species, we analyzed global gene expression profiles of four strains representing distinct evolutionary lineages, including a well-studied laboratory strain, a typical commensal (enteric) strain and two environmental strains. RNA-Seq was employed to compare the whole transcriptomes of strains grown under batch, chemostat and starvation conditions. Highly differentially expressed genes showed a significantly lower nucleotide sequence identity compared with other genes, indicating that gene regulation and coding sequence conservation are directly connected. Overall, distances between the strains based on gene expression profiles were largely dependent on the culture condition and did not reflect phylogenetic relatedness. Expression differences of commonly shared genes (all four strains) and E. coli core genes were consistently smaller between strains characterized by more similar primary habitats. For instance, environmental strains exhibited increased expression of stress defense genes under carbon-limited growth and entered a more pronounced survival-like phenotype during starvation compared with other strains, which stayed more alert for substrate scavenging and catabolism during no-growth conditions. Since those environmental strains show similar genetic distance to each other and to the other two strains, these findings cannot be simply attributed to genetic relatedness but suggest physiological adaptations. Our study provides new insights into ecologically relevant gene-expression and underscores the role of (differential) gene regulation for the diversification of the model bacterial species.

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Section: Signatures Of Ecological Adaptationmentioning

confidence: 86%

Section: Introductionmentioning

confidence: 99%

Gene expression analysis of E. coli strains provides insights into the role of gene regulation in diversification

et al. 2014

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“…The orders-of-magnitude higher abundances of these clades in environmental samples relative to those in human feces and the clinic (9) indicate that they represent truly environmentally adapted organisms (meaning that they are not associated primarily with mammal hosts). Consistent with this interpretation, a recent study found that strains of clades C-III, -IV, and -V form biofilms more readily, outcompete typical E. coli strains at low temperatures (which characterize the environment compared with the gastrointestinal tract of warm-blooded hosts), and are nonpathogenic in a mouse model of septicemia (13).…”

Section: Resultsmentioning

confidence: 99%

“…Consistent with this interpretation, a recent study found that strains of clades C-III, -IV, and -V form biofilms more readily, outcompete typical E. coli strains at low temperatures (which characterize the environment compared with the gastrointestinal tract of warm-blooded hosts), and are nonpathogenic in a mouse model of septicemia (13). Furthermore, screening of 2,701 strains from humans, animals, and the environment identified an additional 57 environmental clade strains, and these strains were found more often in environmental and bird samples than in human samples (9). These studies consistently support the hypothesis that the environmental clades substantially expand the known ecological niche of E. coli.…”

Section: Resultsmentioning

confidence: 99%

“…We recently described five Escherichia clades (C-I to C-V) that were recovered primarily from environmental sources and are indistinguishable from typical E. coli based on traditional phenotypic tests included in either the API20E Identification System (bioMerieux, Inc.) or the BBL Crystal Identification System (Becton, Dickinson and Company) (9). To provide genomic insights into the phylogenetic diversity and metabolic potential of these clades, we sequenced the genome of nine representatives from clades C-I, -III, -IV, and -V (Table 1, Table S1, and Fig.…”

Section: Resultsmentioning

confidence: 99%

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Genome sequencing of environmental Escherichia coli expands understanding of the ecology and speciation of the model bacterial species

Luo¹,

Walk

Gordon

et al. 2011

Proc. Natl. Acad. Sci. U.S.A.

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Defining bacterial species remains a challenging problem even for the model bacterium Escherichia coli and has major practical consequences for reliable diagnosis of infectious disease agents and regulations for transport and possession of organisms of economic importance. E. coli traditionally is thought to live within the gastrointestinal tract of humans and other warm-blooded animals and not to survive for extended periods outside its host; this understanding is the basis for its widespread use as a fecal contamination indicator. Here, we report the genome sequences of nine environmentally adapted strains that are phenotypically and taxonomically indistinguishable from typical E. coli (commensal or pathogenic). We find, however, that the commensal genomes encode for more functions that are important for fitness in the human gut, do not exchange genetic material with their environmental counterparts, and hence do not evolve according to the recently proposed fragmented speciation model. These findings are consistent with a more stringent and ecologic definition for bacterial species than the current definition and provide means to start replacing traditional approaches of defining distinctive phenotypes for new species with omics-based procedures. They also have important implications for reliable diagnosis and regulation of pathogenic E. coli and for the coliform cell-counting test.evolution | genomics | species concept

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Quantitative analysis of commensal Escherichia coli populations reveals host‐specific enterotypes at the intra‐species level

et al. 2015

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The primary habitat of the Escherichia coli species is the gut of warm-blooded vertebrates. The E. coli species is structured into four main phylogenetic groups A, B1, B2, and D. We estimated the relative proportions of these phylogroups in the feces of 137 wild and domesticated animals with various diets living in the Ile de France (Paris) region by real-time PCR. We distinguished three main clusters characterized by a particular abundance of two or more phylogroups within the E. coli animal commensal populations, which we called “enterocolitypes” by analogy with the enterotypes defined in the human gut microbiota at the genus level. These enterocolitypes were characterized by a dominant (>50%) B2, B1, or A phylogroup and were associated with different host species, diets, and habitats: wild and herbivorous species (wild rabbits and deer), domesticated herbivorous species (domesticated rabbits, horses, sheep, and cows), and omnivorous species (boar, pigs, and chickens), respectively. By analyzing retrospectively the data obtained using the same approach from 98 healthy humans living in Ile de France (Smati et al. 2013, Appl. Environ. Microbiol. 79, 5005–5012), we identified a specific human enterocolitype characterized by the dominant and/or exclusive (>90%) presence of phylogroup B2. We then compared B2 strains isolated from animals and humans, and revealed that human and animal strains differ regarding O-type and B2 subgroup. Moreover, two genes, sfa/foc and clbQ, were associated with the exclusive character of strains, observed only in humans. In conclusion, a complex network of interactions exists at several levels (genus and intra-species) within the intestinal microbiota.

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Cryptic Lineages of the Genus Escherichia

Cited by 238 publications

References 64 publications

Gene expression analysis of E. coli strains provides insights into the role of gene regulation in diversification

Gene expression analysis of E. coli strains provides insights into the role of gene regulation in diversification

Genome sequencing of environmental Escherichia coli expands understanding of the ecology and speciation of the model bacterial species

Quantitative analysis of commensal Escherichia coli populations reveals host‐specific enterotypes at the intra‐species level

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