Characterization of Environmentally Persistent Escherichia coli Isolates Leached from an Irish Soil

Soils are typically considered to be suboptimal environments for enteric organisms, but there is increasing evidence that Escherichia coli populations can become resident in soil under favorable conditions. Previous work reported the growth of autochthonous E. coli in a maritime temperate Luvic Stagnosol soil, and this study aimed to characterize, by molecular and physiological means, the genetic diversity and physiology of environmentally persistent E. coli isolates leached from the soil. Molecular analysis (16S rRNA sequencing, enterobacterial repetitive intergenic consensus PCR, pulsed-field gel electrophoresis, and a multiplex PCR method) established the genetic diversity of the isolates (n = 7), while physiological methods determined the metabolic capability and environmental fitness of the isolates, relative to those of laboratory strains, under the conditions tested. Genotypic analysis indicated that the leached isolates do not form a single genetic grouping but that multiple genotypic groups are capable of surviving and proliferating in this environment. In physiological studies, environmental isolates grew well across a broad range of temperatures and media, in comparison with the growth of laboratory strains. These findings suggest that certain E. coli strains may have the ability to colonize and adapt to soil conditions. The resulting lack of fecal specificity has implications for the use of E. coli as an indicator of fecal pollution in the environment.Escherichia coli is a well-established indicator of fecal contamination in the environment. The organism''s validity as an indicator of water pollution is dependent, among other factors, on its fecal specificity and its inability to multiply outside the primary host, the gastrointestinal tracts of humans and warm-blooded animals (9). While many pathogens and indicator organisms are considered to be poorly adapted for long-term survival, or proliferation, outside their primary hosts (24), there is increasing evidence that this view needs to be reconsidered with respect to E. coli (17, 38). In particular, questions remain about its fate and survival capacity in environmental matrices, such as soil. While the habitat within the primary host is characterized by constant warm temperature conditions and a ready availability of nutrients and carbon, that of soil is often characterized by oligotrophic and highly dynamic conditions, temperature and pH variation, predatory populations, and competition with environmentally adapted indigenous microflora (39). Soils are thus typically considered to be suboptimal environments for enteric organisms, and growth is thought to be negligible, with die-off of organisms at rates reported to be a function of the interaction of numerous factors, including the type and physiological state of the microorganism, the physical, chemical, and biological properties of the soil, atmospheric conditions (including sunlight, moisture, and temperature), and organism application method (10).In recent years, the growth of E. coli in soils, sediments, and water in tropical and subtropical regions has been widely documented, and the organism is considered to be an established part of the soil biota within these regions (4, 5, 7, 12, 14, 19, 25, 32). The integration of E. coli as a component of the indigenous microflora in soils of tropical and subtropical regions may be attributable to the nutrient-rich nature and warm temperatures of these habitats (21, 39), combined with the metabolic versatility of the organism and its simple nutritional requirements (21). In addition to tropical and subtropical regions, the presence of autochthonous E. coli populations in the cooler soils of temperate and northern temperate regions has also been reported (6, 20, 22, 37), with one report on an alpine soil (34) and, most recently, a report on a maritime temperate grassland soil (3). The growth of E. coli within soils can act as a reservoir for the further contamination of bodies of water (20, 31, 32), compromising the indicator status of E. coli within these regions. As such, an understanding of the ecological characteristics of E. coli in soil is critical to its validation as an indicator organism. With respect to the input of pathogenic E. coli into the environment, this knowledge becomes essential for assessing the potential health risk to human and animal hosts from agricultural activities such as landspreading of manures and slurries (24).It has been suggested that E. coli can sustain autochthonous populations within soils in temperate regions, wherever favorable conditions exist (21). The phenotypic traits of the organism (including its metabolic diversity and its ability to grow both aerobically and anaerobically in a broad temperature range) may assist the persistence, colonization, and growth of E. coli when conditions permit. The challenging nature of the soil environment and the disparity of conditions between the primary host and the secondary habitat raises the question of how these E. coli populations survive and compete for niche space among the highly competitive and diverse coexisting populations of the indigenous microflora (15, 21). There is some evidence that naturalized E. coli may form genetically distinct populations in the environment (17, 20, 34, 36). This suggests that autochthonous E. coli populations in soil may have increased environmental fitness, facilitating their residence in soil (20, 34, 38). Little is known, however, of the physiology of these organisms, and their capacity for survival in soil remains poorly understood (21).Previous work (3) recorded continuous low-level leaching of viable E. coli from lysimeters of a poorly drained Luvic Stagnosol soil type, more than 9 years after the last application of fecal material. This finding was indicative of the growth of E. coli within the soil and suggested the presence of autochthonous E. coli populations within the soil that could be leached subsequently. To our knowledge, prior to this report, naturalized autochthonous E. coli populations persisting under the relatively oligotrophic, low-temperature conditions of maritime temperate soil environments had not been described previously. Growth within this soil was attributed chiefly to favorable characteristics of the soil, which include high clay and moisture contents, nutrient retention, and the presence of anaerobic zones. The objective of this work was to characterize, by molecular and physiological means, the genetic diversity and physiology of environmentally persistent E. coli isolates leached. In particular, we were interested in determining if the isolates possessed phenotypic characteristics that may enhance their capacity to survive and occupy niche space within the soil. This study tested the hypothesis that E. coli clones persisting in lysimeters of this soil form a genetically distinct grouping and possess a physiology tailored to the soil environment.     

Rapid Microarray-Based Genotyping of Enterohemorrhagic Escherichia coli Serotype O156:H25/H?/Hnt Isolates from Cattle and Clonal Relationship Analysis

Since enterohemorrhagic Escherichia coli (EHEC) isolates of serogroup O156 have been obtained from human diarrhea patients and asymptomatic carriers, we studied cattle as a potential reservoir for these bacteria. E. coli isolates serotyped by agglutination as O156:H25/H−/Hnt strains (n = 32) were isolated from three cattle farms during a period of 21 months and characterized by rapid microarray-based genotyping. The serotyping by agglutination of the O156 isolates was not confirmed in some cases by the results of DNA-based serotyping as only 25 of the 32 isolates were conclusively identified as O156:H25. In the multilocus sequence typing (MLST) analysis, all EHEC O156:H25 isolates were characterized as sequence type 300 (ST300) and ST688, which differ by a single-nucleotide exchange in the purA gene. Oligonucleotide microarrays allow simultaneous detection of a wider range of EHEC-associated and other E. coli virulence markers than other methods. All O156:H25 isolates showed a wide spectrum of virulence factors typical for EHEC. The stx₁ genes combined with the EHEC hlyA (hlyA_EHEC) gene, the eae gene of the ζ subtype, as well as numerous other virulence markers were present in all EHEC O156:H25 strains. The behavior of eight different cluster groups, including four that were EHEC O156:H25, was monitored in space and time. Variations in the O156 cluster groups were detected. The results of the cluster analysis suggest that some O156:H25 strains had the genetic potential for a long persistence in the host and on the farm, while other strains did not. As judged by their pattern of virulence markers, E. coli O156:H25 isolates of bovine origin may represent a considerable risk for human infection. Our results showed that the miniaturized E. coli oligonucleotide arrays are an excellent tool for the rapid detection of a large number of virulence markers.Shiga toxin-producing Escherichia coli (STEC) strains comprise a group of zoonotic enteric pathogens (45). In humans, infections with some STEC serotypes may result in hemorrhagic or nonhemorrhagic diarrhea, which can be complicated by the hemolytic uremic syndrome (HUS) (32). These STEC strains are also designated enterohemorrhagic Escherichia coli (EHEC). Consequently, EHEC strains represent a subgroup of STEC with high pathogenic potential for humans. Although E. coli O157:H7 is the most frequent EHEC serotype implicated in HUS, other serotypes can also cause this complication. Non-O157:H7 EHEC strains including serotypes O26:H11/H−, O103:H2/H−, O111:H8/H10/H−, and O145:H28/H25/H− and sorbitol-fermenting E. coli O157:H− isolates are present in about 50% of stool cultures from German HUS patients (10, 42). However, STEC strains that cause human infection belong to a large number of E. coli serotypes, although a small number of STEC isolates of serogroup O156 were associated with human disease (7). Strains of the serotypes O156:H1/H8/H21/H25 were found in human cases of diarrhea or asymptomatic infections (9, 22, 25, 26). The detection of STEC of serogroup O156 from healthy and diseased ruminants such as cattle, sheep, and goats was reported by several authors (1, 11-13, 21, 39, 46, 50, 52). Additional EHEC-associated virulence genes such as stx, eae, hlyA_EHEC, or nlaA were found preferentially in the serotypes O156:H25 and O156:H− (11-13, 21, 22, 50, 52).Numerous methods exist for the detection of pathogenic E. coli, including genotypic and phenotypic marker assays for the detection of virulence genes and their products (19, 47, 55, 57). All of these methods have the common drawback of screening a relatively small number of determinants simultaneously. A diagnostic DNA microarray based on the ArrayTube format of CLONDIAG GmbH was developed as a viable alternative due to its ability to screen multiple virulence markers simultaneously (2). Further microarray layouts working with the same principle but different gene targets were developed for the rapid identification of antimicrobial resistance genes in Gram-negative bacteria (5) and for the rapid DNA-based serotyping of E. coli (4). In addition, a protein microarray for E. coli O serotyping based on the ArrayTube format was described by Anjum et al. (3).The aim of our study was the molecular genotyping of bovine E. coli field isolates of serogroup O156 based on miniaturized E. coli oligonucleotide arrays in the ArrayStrip format and to combine the screening of E. coli virulence markers, antimicrobial resistance genes, and DNA serotyping targets, some of which were partially described previously for separate arrays (2, 4, 5). The epidemiological situation in the beef herds from which the isolates were obtained and the spatial and temporal behavior of the clonal distribution of E. coli serogroup O156 were analyzed during the observation period. The potential risk of the isolates inducing disease in humans was assessed.     

Conjugative Plasmid Transfer and Adhesion Dynamics in an Escherichia coli Biofilm

A conjugative plasmid from the catheter-associated urinary tract infection strain Escherichia coli MS2027 was sequenced and annotated. This 42,644-bp plasmid, designated pMAS2027, contains 58 putative genes and is most closely related to plasmids belonging to incompatibility group X (IncX1). Plasmid pMAS2027 encodes two important virulence factors: type 3 fimbriae and a type IV secretion (T4S) system. Type 3 fimbriae, recently found to be functionally expressed in E. coli, played an important role in biofilm formation. Biofilm formation by E. coli MS2027 was specifically due to expression of type 3 fimbriae and not the T4S system. The T4S system, however, accounted for the conjugative ability of pMAS2027 and enabled a non-biofilm-forming strain to grow as part of a mixed biofilm following acquisition of this plasmid. Thus, the importance of conjugation as a mechanism to spread biofilm determinants was demonstrated. Conjugation may represent an important mechanism by which type 3 fimbria genes are transferred among the Enterobacteriaceae that cause device-related infections in nosocomial settings.Bacterial biofilms are complex communities of bacterial cells living in close association with a surface (17). Bacterial cells in these protected environments are often resistant to multiple factors, including antimicrobials, changes in the pH, oxygen radicals, and host immune defenses (19, 38). Biofilm formation is a property of many bacterial species, and a range of molecular mechanisms that facilitate this process have been described (2, 3, 11, 14, 16, 29, 33, 34). Often, the ability to form a biofilm is dependent on the production of adhesins on the bacterial cell surface. In Escherichia coli, biofilm formation is enhanced by the production of certain types of fimbriae (e.g., type 1 fimbriae, type 3 fimbriae, F1C, F9, curli, and conjugative pili) (14, 23, 25, 29, 33, 39, 46), cell surface adhesins (e.g., autotransporter proteins such as antigen 43, AidA, TibA, EhaA, and UpaG) (21, 34, 35, 40, 43), and flagella (22, 45).The close proximity of bacterial cells in biofilms creates an environment conducive for the exchange of genetic material. Indeed, plasmid-mediated conjugation in monospecific and mixed E. coli biofilms has been demonstrated (6, 18, 24, 31). The F plasmid represents the best-characterized conjugative system for biofilm formation by E. coli. The F pilus mediates adhesion to abiotic surfaces and stabilizes the biofilm structure through cell-cell interactions (16, 30). Many other conjugative plasmids also contribute directly to biofilm formation upon derepression of the conjugative function (16).One example of a conjugative system employed by gram-negative Enterobacteriaceae is the type 4 secretion (T4S) system. The T4S system is a multisubunit structure that spans the cell envelope and contains a secretion channel often linked to a pilus or other surface filament or protein (8). The Agrobacterium tumefaciens VirB-VirD4 system is the archetypical T4S system and is encoded by 11 genes in the virB operon and one gene (virD4) in the virD operon (7, 8). Genes with strong homology to genes in the virB operon have also been identified on other conjugative plasmids. For example, the pilX1 to pilX11 genes on the E. coli R6K IncX plasmid and the virB1 to virB11 genes are highly conserved at the nucleotide level (28).We recently described identification and characterization of the mrk genes encoding type 3 fimbriae in a uropathogenic strain of E. coli isolated from a patient with a nosocomial catheter-associated urinary tract infection (CAUTI) (29). The mrk genes were located on a conjugative plasmid (pMAS2027) and were strongly associated with biofilm formation. In this study we determined the entire sequence of plasmid pMAS2027 and revealed the presence of conjugative transfer genes homologous to the pilX1 to pilX11 genes of E. coli R6K (in addition to the mrk genes). We show here that biofilm formation is driven primarily by type 3 fimbriae and that the T4S apparatus is unable to mediate biofilm growth in the absence of the mrk genes. Finally, we demonstrate that conjugative transfer of pMAS2027 within a mixed biofilm confers biofilm formation properties on recipient cells due to acquisition of the type 3 fimbria-encoding mrk genes.     

Rapid Affinity Immunochromatography Column-Based Tests for Sensitive Detection of Clostridium botulinum Neurotoxins and Escherichia coli O157

Existing methods for detection of food-borne pathogens and their toxins are frequently time-consuming, require specialized equipment, and involve lengthy culture procedures and/or animal testing and are thus unsuitable for a rapid response to an emergency public health situation. A series of simple and rapid affinity immunochromatography column (AICC) assays were developed to detect Clostridium botulinum neurotoxin types A, B, E, and F and Escherichia coli O157 in food matrices. Specifically, for milk, grape juice with peach juice, and bottled water, the detection limit for the botulinum neurotoxin type A complex was 0.5 ng. Use of this method with a 10-ml sample would therefore result in a detection limit of 50 pg ml^−l. Thus, this assay is approximately 2 orders of magnitude more sensitive than a comparable lateral-flow assay. For botulinum neurotoxin complex types B, E, and F, the minimum detection limit was 5 ng to 50 ng. Sensitive detection of E. coli O157 was achieved, and the detection limit was 500 cells. The AICC test was also shown to be specific, rapid, and user friendly. This test takes only 15 to 30 min to complete without any specialized equipment and thus is suitable for use in the field. It has the potential to replace existing methods for presumptive detection of botulinum neurotoxin types A, B, E, and F and E. coli O157 in contaminated matrices without a requirement for preenrichment.The majority of conventional methods used for detection and identification of pathogenic microorganisms, viruses, and/or their toxins lack the speed and sensitivity necessary for use in the field (they typically are not completed in a single day) and also require specialized equipment (20). Rapid methods, including antibody-based and nucleic acid-based assays, have revolutionized the methodology for detection of microbial pathogens and their toxins in foods (16). However, while most antibody-based and nucleic acid-based assays are rapid, specialized equipment is often required, and specific enrichment is needed to achieve the necessary sensitivity. This means that the analysis time can still be several days (16). Lateral-flow assays (LFAs) and column flow assays are tests that have considerable merit in terms of rapidity and ease of use in the field without specialized equipment (4, 5, 8, 19, 34).Two contrasting agents were used as detection targets in this study: (i) a potent microbial toxin (Clostridium botulinum neurotoxin), including type A, B, E, and F neurotoxins; and (ii) an infectious pathogen, Escherichia coli O157. These two targets present different problems for detection; the first target is a protein toxin, and the second target is intact bacterial cells. The botulinum neurotoxin is the most potent toxin known, and as little as 30 to 100 ng has the potential to be fatal to humans (28). It is responsible for botulism, a severe neuroparalytic disease that affects humans and also animals and birds (28). There are seven antigenically distinct botulinum neurotoxins (types A to G), and a number of subtypes have also been described (9, 11, 15, 28, 36). Botulism in humans is associated principally with neurotoxin types A, B, E, and F (27, 29). Since the botulinum neurotoxins are the toxic agents and they can be produced by six physiologically distinct clostridia (28), considerable emphasis has been placed on detection of the neurotoxins rather than the bacteria. The “gold standard” method for detecting botulinum neurotoxins is the mouse bioassay due to its high levels of sensitivity and specificity. However, this technique is also problematic (33). It typically requires 24 to 48 h to yield results, is expensive, and is becoming less favored because of its use of animals (4). The alternative tests include enzyme-linked immunosorbent assays (ELISAs), lateral-flow assays (LFAs), a chemiluminescent slot blot immunoassay, surface plasmon resonance (SPR), the assay with a large immunosorbent surface area (ALISSA) test, and quantum dot immunoassays (4, 5, 7, 22, 43, 46). Lateral-flow assays are available and are convenient for toxin testing as they are easy to perform and rapid (<30 min) and no additional equipment is required. However, their poor sensitivity has limited their use (23).E. coli O157 produces a cytotoxin (verotoxin), and an E. coli O157 infection can lead to severe bloody diarrhea, kidney failure, brain damage, and death. Enumeration, identification, and control of this pathogen are challenging due to the low infectious dose necessary to cause disease, which is between 2 and 2,000 ingested cells (41). Sources of E. coli O157 infection include ground beef and unpasteurized milk and apple juice (1), raw milk (6), and spinach and lettuce (42). Isolation of E. coli O157:H7 from water, food, and environmental samples is laborious. Culture is difficult due to the large competing microflora that either overgrows or mimics the non-sorbitol-fermenting organism E. coli O157:H7 (12). According to Tokarskyy and Marshall (41), the largest group of rapid test kits commercially available for testing for the presence of E. coli O157 in food includes immunological methods, such as latex agglutination, reverse passive latex agglutination, immunodiffusion, ELISA, immunomagnetic separation (IMS), and immunoprecipitation. The other methods that have been developed include a dipstick test device (2), a lateral-flow immunoassay (8), real-time PCR (39), and an enzyme-linked immunomagnetic chemiluminescent assay (17). However, in many cases these tests require preenrichment or have limited sensitivity.The objective of the work described here was to develop a rapid sensitive diagnostic test for detection of botulinum neurotoxins A, B, E, and F and E. coli O157 that can be used without preenrichment.     

Comparative Structure-Function Analysis of Mannose-Specific FimH Adhesins from Klebsiella pneumoniae and Escherichia coli

FimH, the adhesive subunit of type 1 fimbriae expressed by many enterobacteria, mediates mannose-sensitive binding to target host cells. At the same time, fine receptor-structural specificities of FimH from different species can be substantially different, affecting bacterial tissue tropism and, as a result, the role of the particular fimbriae in pathogenesis. In this study, we compared functional properties of the FimH proteins from Escherichia coli and Klebsiella pneumoniae, which are both 279 amino acids in length but differ by some ∼15% of residues. We show that K. pneumoniae FimH is unable to mediate adhesion in a monomannose-specific manner via terminally exposed Manα(1-2) residues in N-linked oligosaccharides, which are the structural basis of the tropism of E. coli FimH for uroepithelial cells. However, K. pneumoniae FimH can bind to the terminally exposed Manα(1-3)Manβ(1-4)GlcNAcβ1 trisaccharide, though only in a shear-dependent manner, wherein the binding is marginal at low shear force but enhanced sevenfold under increased shear. A single mutation in the K. pneumoniae FimH, S62A, converts the mode of binding from shear dependent to shear independent. This mutation has occurred naturally in the course of endemic circulation of a nosocomial uropathogenic clone and is identical to a pathogenicity-adaptive mutation found in highly virulent uropathogenic strains of E. coli, in which it also eliminates the dependence of E. coli binding on shear. The shear-dependent binding properties of the K. pneumoniae and E. coli FimH proteins are mediated via an allosteric catch bond mechanism. Thus, despite differences in FimH structure and fine receptor specificity, the shear-dependent nature of FimH-mediated adhesion is highly conserved between bacterial species, supporting its remarkable physiological significance.The most common type of adhesive organelle in the Enterobacteriaceae is the type 1 fimbria, which has been most extensively studied in Escherichia coli. The corresponding structures of Klebsiella pneumoniae are similar to those of E. coli with regard to genetic composition and regulation (15). Type 1 fimbriae are composed primarily of the structural subunit FimA, with minor amounts of three ancillary subunits, FimF, FimG, and the mannose-specific adhesin FimH. The FimH adhesin is an allosteric protein that mediates the catch bond mechanism of adhesion where the binding is increased under increased shear stress (48).It has been demonstrated in E. coli that FimH has two domains, the mannose-binding lectin domain (from amino acid [aa] 1 through 156) and the fimbria-incorporating pilin domain (from aa 160 through 279), connected via a 3-aa-long linker chain (6). A mannose-binding site is located at the top of the lectin domain, at the opposite end from the interdomain linker (17).Several studies have demonstrated that type 1 fimbriae play an important role in E. coli urinary tract infection (UTI) (7, 21, 23, 35). In addition, in urinary E. coli isolates, the FimH adhesin accumulates amino acid replacements which increase tropism for the uroepithelium and various components of basement membranes (21, 30, 35, 37, 49). Most of the replacements increase the monomannose binding capability of FimH under low shear, by altering allosteric catch bond properties of the protein (48). The mutated FimH variants were shown to provide an advantage in colonization of the urinary tract in the mouse model (35) and correlate with the overall extraintestinal virulence of E. coli (16). Thus, FimH mutations are pathoadaptive in nature.Klebsiella pneumoniae is recognized as an important opportunistic pathogen frequently causing UTIs, septicemia, or pneumonia in immunocompromised individuals (29). It is responsible for up to 10% of all nosocomial bacterial infections (18, 41). K. pneumoniae is ubiquitous in nature, and it has been shown that environmental isolates are phenotypically indistinguishable from clinical isolates (22, 26, 27, 29, 33). Furthermore, it has been demonstrated that environmental isolates of K. pneumoniae are as virulent as clinical isolates (28, 45).K. pneumoniae possesses a number of known virulence factors, including a pronounced capsule, type 3 fimbriae, and type 1 fimbriae (29, 44). Type 1 fimbriae produced by K. pneumoniae are described as functionally and structurally similar to type 1 fimbriae from E. coli (25) and have been shown to play a significant role in K. pneumoniae UTI (32, 43).We have previously shown that mature FimH from 54 isolates of K. pneumoniae (isolated from urine, blood, liver, and the environment) is represented by seven protein variants due to point amino acid replacements. (42) When K. pneumoniae FimH was aligned with the FimH of E. coli, they showed ∼85% similarity at the amino acid level. Furthermore, a majority (14 out of 21 isolates) of the K. pneumoniae strains isolated from patients with UTI grouped into a single clonal group based on multilocus sequence typing, but fimH in one isolate in the group differed from the others by a single nucleotide mutation resulting in an amino acid change, serine to alanine, in position 62 (42). The same mutation has been found in FimH of a highly uropathogenic clone of E. coli and significantly increases the adhesin''s ability to adhere to monomannose under low or no shear (19, 39, 50).In this study, we describe the extent and pattern of structural variability of the FimH protein from K. pneumoniae and perform comparative analyses of the functional properties of FimH from both K. pneumonae and E. coli.     

Long-Term Persistence and Leaching of Escherichia coli in Temperate Maritime Soils

Enteropathogen contamination of groundwater, including potable water sources, is a global concern. The spreading on land of animal slurries and manures, which can contain a broad range of pathogenic microorganisms, is considered a major contributor to this contamination. Some of the pathogenic microorganisms applied to soil have been observed to leach through the soil into groundwater, which poses a risk to public health. There is a critical need, therefore, for characterization of pathogen movement through the vadose zone for assessment of the risk to groundwater quality due to agricultural activities. A lysimeter experiment was performed to investigate the effect of soil type and condition on the fate and transport of potential bacterial pathogens, using Escherichia coli as a marker, in four Irish soils (n = 9). Cattle slurry (34 tonnes per ha) was spread on intact soil monoliths (depth, 1 m; diameter, 0.6 m) in the spring and summer. No effect of treatment or the initial soil moisture on the E. coli that leached from the soil was observed. Leaching of E. coli was observed predominantly from one soil type (average, 1.11 ± 0.77 CFU ml⁻¹), a poorly drained Luvic Stagnosol, under natural rainfall conditions, and preferential flow was an important transport mechanism. E. coli was found to have persisted in control soils for more than 9 years, indicating that autochthonous E. coli populations are capable of becoming naturalized in the low-temperature environments of temperate maritime soils and that they can move through soil. This may compromise the use of E. coli as an indicator of fecal pollution of waters in these regions.The contamination of groundwater, including potable water supplies, with microbial pathogens continues to be a global concern (52, 59). Of particular importance in developed countries are the high levels of contamination associated with small-scale and very-small-scale drinking water supplies (5, 19, 57), often groundwater, which serve an estimated 10% of the total population in the European Union (13). The high numbers of these water supplies found to be contaminated with fecal bacteria and thus considered to be unfit for human consumption are worrying because the water from them is often untreated or inadequately treated prior to consumption. Microbial pathogens are known to survive for considerable periods of time in groundwater (29), which increases the health risk due to utilization of contaminated supplies. There are various sources of contamination, but evidence suggests that contamination from the spreading of animal slurries and manures on land can be a significant contributor (3, 33, 53). Spreading of agricultural slurries and manures on land is used by the agricultural sector as a means of nutrient recycling. The health risks associated with the spreading of animal and human wastes containing enteric pathogens have been recognized for a long time (10, 18). Animal manure and wastewaters may contain a broad range of pathogenic microorganisms, including Escherichia coli O157:H7, Campylobacter, Cryptosporidium, Salmonella spp., and pathogenic viruses, which are released into the environment during spreading (15, 22, 55). The levels and incidence of pathogens present in animal manures and slurries are influenced by a number of factors, including herd health, age demographics, stress factors, diet, season, and manure management and storage (37, 39).Soils (and subsoils) often act as a zone for mitigating microbial contamination of groundwater associated with the spreading of animal slurries and manures on land. Some of the pathogenic microorganisms applied to agricultural soils have, however, been observed to leach through the soil into groundwater, which can affect drinking water quality and pose a risk to public health (16, 26, 28, 42, 50), confirming that soil is not always a sufficient obstruction for protection of groundwater (16, 53). Consequently, characterization of the movement of pathogens through the unsaturated soil and subsoil zone (vadose zone) has become critical for assessment of the risk to groundwater posed by agricultural activities (8, 14, 42). The soil and subsoil type is believed to be a major factor influencing the potential transfer of pathogens through soil to groundwater (3, 34, 41, 50). The preapplication moisture status of a soil, which may be influenced by the season, also impacts pathogen survival, fate, and transport (2, 11, 43, 54).E. coli is widely used as an indicator of fecal contamination of water, and certain strains are known to be pathogenic (12). Thus, characterizing this organism''s transport through soil is important because of the health risk posed by the organism itself and with regard to its validity as an indicator of the fate of enteropathogens in the environment. E. coli strains have diverse properties and capabilities that affect their survival and transport in soils (9, 36, 56, 60). Consequently, data obtained by using total E. coli rather than individual surrogate strains can be more representative of the fate and transport of E. coli present in animal slurries. E. coli O157 die-off in soils has been reported to be the same as or quicker than total E. coli die-off, suggesting that data for total E. coli provide a conservative estimate of the survival potential (38, 56). Although many field and laboratory studies have investigated E. coli transport through soil columns (4, 6, 16, 43, 46, 47, 50, 51), most studies have investigated transport through soil to a depth of less than 30 cm. For assessment of the risk of transport to groundwater, such studies may not take into account the variation in soil physical and chemical characteristics with depth (e.g., the frequency and continuity of macropores, organic matter, and moisture contents) that affect bacterial transport. Furthermore, rainfall was often simulated in previous studies, which allows experimental conditions to be controlled but may not be representative of the risk due to variable natural rainfall events over time. In this study, we used intact soil monoliths that were 1 m deep to assess the risk of leaching of total E. coli in four representative Irish soil types under natural rainfall and environmental conditions.The objective of this study was to quantitatively investigate the impact of soil type and season (soil moisture content) on the fate and transport of E. coli spread on four different temperate maritime soil types under natural rainfall conditions. We hypothesized that there would be a greater microbial risk to underlying groundwater with better-drained soil types than with relatively poorly drained soil types following the application of animal slurry. In addition, we hypothesized that E. coli cells spread on wetter spring soils would be transported in greater numbers than E. coli cells spread on drier soils in the summer.     

ICEEc2, a New Integrative and Conjugative Element Belonging to the pKLC102/PAGI-2 Family,Identified in Escherichia coli Strain BEN374

The diversity of the Escherichia coli species is in part due to the large number of mobile genetic elements that are exchanged between strains. We report here the identification of a new integrative and conjugative element (ICE) of the pKLC102/PAGI-2 family located downstream of the tRNA gene pheU in the E. coli strain BEN374. Indeed, this new region, which we called ICEEc2, can be transferred by conjugation from strain BEN374 to the E. coli strain C600. We were also able to transfer this region into a Salmonella enterica serovar Typhimurium strain and into a Yersinia pseudotuberculosis strain. This transfer was then followed by the integration of ICEEc2 into the host chromosome downstream of a phe tRNA gene. Our data indicated that this transfer involved a set of three genes encoding DNA mobility enzymes and a type IV pilus encoded by genes present on ICEEc2. Given the wide distribution of members of this family, these mobile genetic elements are likely to play an important role in the diversification of bacteria.The fantastic diversity of the Escherichia coli species has been known for a long time. With modern sequencing strategies, the molecular bases of this diversity are now being unraveled (49). Analyzing the genome of 20 E. coli strains, Touchon et al. recently showed that only a minority of genes, approximately 1,900 genes, were shared by all E. coli strains and constituted the core genome of the E. coli species (50). Additionally, the total number of genes found in all E. coli strains, the pan-genome, is an order of magnitude larger than this core genome (50). The non-core genome of a strain, also called flexible gene pool, is therefore made of a wide diversity of genes. This genetic diversity of the E. coli species translates into a diversity of phenotypic properties. While most E. coli strains are commensal of the gastrointestinal tract of humans and warm-blooded animals, a significant number are responsible for different diseases in humans and animals (22), including extraintestinal infections in chickens; strains isolated from such cases are designated by the term APEC for avian pathogenic E. coli (10).This diversity arises from frequent horizontal gene transfers of mobile genetic elements such as transposons, plasmids, phages, genomic islands, or integrative and conjugative elements (ICEs) (11, 21, 34). Among these mobile genetic elements, ICEs have a particular place as they share properties with both plasmids, genomic islands, and transposons; they can be defined as elements that encode all the necessary machineries that allow their excision from the chromosome, their transfer to a recipient strain, and their integration into the recipient strain''s genome (5, 6, 46, 54). Well-known representatives of this class of genetic elements include Tn916 discovered in Enterococcus faecalis, the conjugative transposon CTnDOT in Bacteroides thetaiotaomicron, ICEKp1 in Klebsiella pneumoniae, SXT/R391-related elements, PFGI-1 in Pseudomonas fluorescens, and the clc element in Pseudomonas sp. strain B13 as well as ICEBs1 in Bacillus subtilis and ICEEc1 in the E. coli strain ECOR31 (1, 39, 44, 46, 54). Typically, ICEs contain at least three modules that are required for key steps in the ICE''s life cycle: an excision/integration module, a transfer module, and a regulation module (54). Besides these, ICEs often contain cargo regions that confer on their host a diverse array of properties, such as virulence properties (ICEEc1), antibiotic resistance (SXT), or degradation of chemical compounds (clc). Because of their self-transfer abilities and their diverse accessory gene repertoires, ICEs are very likely to play a major role in bacteria evolution (46).A new family of ICEs has recently gained interest and was named the pKLC102/PAGI-2 family. The first element of this family, the clc element, was discovered in Pseudomonas sp. strain B13 and confers on the bacteria the possibility to degrade aromatic compounds (42). The transfer of this element was discovered long before its complete sequence was characterized (16). Other members of this family include several elements present in Pseudomonas strains such as PAGI-1 and PAGI-2 as well as the pKLC102 element first considered to be a plasmid but later on shown to be an ICE because of its ability to integrate into the chromosome of its host (23, 52). pKLC102/PAGI-2 elements share a set of core genes (33) and, like most ICEs and genomic islands, are all integrated downstream of tRNA genes (26, 52). The transfer between strains has been demonstrated, albeit with different frequencies, for only a few members, such as the clc element, Pseudomonas aeruginosa pathogenicity island 1 (PAPI-1), and ICEHin1056 from Haemophilus influenzae (20, 37, 41); this transfer involves the type IV pilus (20), the integrase (40), and in some cases the formation of a circular intermediate of the excised ICE (24).In order to identify new accessory genes of APEC strains, we previously described tRNA loci in the E. coli genome that could represent potential insertion sites for new genomic islands (18). We had already used this strategy to characterize the AGI-3 region that is involved in the virulence of an avian pathogenic E. coli strain and that confers the ability to grow on fructooligosaccharides (7, 43). During this tRNA screening, we showed that genomic islands might potentially be present downstream of the tRNA genes argW, leuX, pheU, pheV, selC, serU, and thrW in several APEC strains.In this report, we describe the identification of a new genomic island located downstream of pheU in the APEC strain BEN374. This region, which we named ICEEc2, was fully sequenced, and its properties were analyzed in detail; ICEEc2 is a new ICE found in E. coli and belongs to the pKLC102/PAGI-2 family described above.     

Multiple Interaction Domains in FtsL,a Protein Component of the Widely Conserved Bacterial FtsLBQ Cell Division Complex

A bioinformatic analysis of nearly 400 genomes indicates that the overwhelming majority of bacteria possess homologs of the Escherichia coli proteins FtsL, FtsB, and FtsQ, three proteins essential for cell division in that bacterium. These three bitopic membrane proteins form a subcomplex in vivo, independent of the other cell division proteins. Here we analyze the domains of E. coli FtsL that are involved in the interaction with other cell division proteins and important for the assembly of the divisome. We show that FtsL, as we have found previously with FtsB, packs an enormous amount of information in its sequence for interactions with proteins upstream and downstream in the assembly pathway. Given their size, it is likely that the sole function of the complex of these two proteins is to act as a scaffold for divisome assembly.The division of an Escherichia coli cell into two daughter cells requires a complex of proteins, the divisome, to coordinate the constriction of the three layers of the Gram-negative cell envelope. In E. coli, there are 10 proteins known to be essential for cell division; in the absence of any one of these proteins, cells continue to elongate and to replicate and segregate their chromosomes but fail to divide (29). Numerous additional nonessential proteins have been identified that localize to midcell and assist in cell division (7-9, 20, 25, 34, 56, 59).A localization dependency pathway has been determined for the 10 essential division proteins (FtsZ→FtsA/ZipA→FtsK→FtsQ→FtsL/FtsB→FtsW→FtsI→FtsN), suggesting that the divisome assembles in a hierarchical manner (29). Based on this pathway, a given protein depends on the presence of all upstream proteins (to the left) for its localization and that protein is then required for the localization of the downstream division proteins (to the right). While the localization dependency pathway of cell division proteins suggests that a sequence of interactions is necessary for divisome formation, recent work using a variety of techniques reveals that a more complex web of interactions among these proteins is necessary for a functionally stable complex (6, 10, 19, 23, 24, 30-32, 40). While numerous interactions have been identified between division proteins, further work is needed to define which domains are involved and which interactions are necessary for assembly of the divisome.One subcomplex of the divisome, composed of the bitopic membrane proteins FtsB, FtsL, and FtsQ, appears to be the bridge between the predominantly cytoplasmic cell division proteins and the predominantly periplasmic cell division proteins (10). FtsB, FtsL, and FtsQ share a similar topology: short amino-terminal cytoplasmic domains and larger carboxy-terminal periplasmic domains. This tripartite complex can be divided further into a subcomplex of FtsB and FtsL, which forms in the absence of FtsQ and interacts with the downstream division proteins FtsW and FtsI in the absence of FtsQ (30). The presence of an FtsB/FtsL/FtsQ subcomplex appears to be evolutionarily conserved, as there is evidence that the homologs of FtsB, FtsL, and FtsQ in the Gram-positive bacteria Bacillus subtilis and Streptococcus pneumoniae also assemble into complexes (18, 52, 55).The assembly of the FtsB/FtsL/FtsQ complex is important for the stabilization and localization of one or more of its component proteins in both E. coli and B. subtilis (11, 16, 18, 33). In E. coli, FtsB and FtsL are codependent for their stabilization and for localization to midcell, while FtsQ does not require either FtsB or FtsL for its stabilization or localization to midcell (11, 33). Both FtsL and FtsB require FtsQ for localization to midcell, and in the absence of FtsQ the levels of full-length FtsB are significantly reduced (11, 33). The observed reduction in full-length FtsB levels that occurs in the absence of FtsQ or FtsL results from the degradation of the FtsB C terminus (33). However, the C-terminally degraded FtsB generated upon depletion of FtsQ can still interact with and stabilize FtsL (33).While a portion of the FtsB C terminus is dispensable for interaction with FtsL and for the recruitment of the downstream division proteins FtsW and FtsI, it is required for interaction with FtsQ (33). Correspondingly, the FtsQ C terminus also appears to be important for interaction with FtsB and FtsL (32, 61). The interaction between FtsB and FtsL appears to be mediated by the predicted coiled-coil motifs within the periplasmic domains of the two proteins, although only the membrane-proximal half of the FtsB coiled coil is necessary for interaction with FtsL (10, 32, 33). Additionally, the transmembrane domains of FtsB and FtsL are important for their interaction with each other, while the cytoplasmic domain of FtsL is not necessary for interaction with FtsB, which has only a short 3-amino-acid cytoplasmic domain (10, 33).In this study, we focused on the interaction domains of FtsL. We find that, as with FtsB, the C terminus of FtsL is required for the interaction of FtsQ with the FtsB/FtsL subcomplex while the cytoplasmic domain of FtsL is involved in recruitment of the downstream division proteins. Finally, we provide a comprehensive analysis of the presence of FtsB, FtsL, and FtsQ homologs among bacteria and find that the proteins of this complex are likely more widely distributed among bacteria than was previously thought.     

Genomic Regions Conserved in Lineage II Escherichia coli O157:H7 Strains

Populations of the food- and waterborne pathogen Escherichia coli O157:H7 are comprised of two major lineages. Recent studies have shown that specific genotypes within these lineages differ substantially in the frequencies with which they are associated with human clinical disease. While the nucleotide sequences of the genomes of lineage I strains E. coli O157 Sakai and EDL9333 have been determined, much less is known about the genomes of lineage II strains. In this study, suppression subtractive hybridization (SSH) was used to identify genomic features that define lineage II populations. Three SSH experiments were performed, yielding 1,085 genomic fragments consisting of 811 contigs. Bacteriophage sequences were identified in 11.3% of the contigs, 9% showed insertions and 2.3% deletions with respect to E. coli O157:H7 Sakai, and 23.2% did not have significant identity to annotated sequences in GenBank. In order to test for the presence of these novel loci in lineage I and II strains, 27 PCR primer sets were designed based on sequences from these contigs. All but two of these PCR targets were found in the majority (51.9% to 100%) of 27 lineage II strains but in no more than one (<6%) of the 17 lineage I strains. Several of these linage II-related fragments contain insertions/deletions that may play an important role in virulence. These lineage II-related loci were also shown to be useful markers for genotyping of E. coli O157:H7 strains isolated from human and animal sources.Enterohemorrhagic Escherichia coli is associated with diarrhea, hemorrhagic colitis, and hemolytic-uremic syndrome in humans (31). E. coli serotype O157:H7 predominates in epidemics and sporadic cases of enterohemorrhagic E. coli-related infections in the United States, Canada, Japan, and the United Kingdom (12). Cattle are considered the most important reservoir of E. coli O157:H7 (10, 24, 37, 41), and foods contaminated with bovine feces are thought to be the most common source of human infection with this pathogen (27, 33). The two most important virulence factors of the organism are the production of one or more Shiga toxins (Stx) (6, 20, 32) and the ability to attach to and efface microvilli of host intestinal cells (AE). Stx genes are encoded by temperate bacteriophage inserted in the bacterial chromosome, and genes responsible for the AE phenotype are located on the locus of enterocyte effacement (LEE) as well as other pathogenicity islands (4, 17). All E. coli O157:H7 strains also possess a large plasmid which is thought to play a role in virulence (10, 40, 42).Octamer-based genome scanning (OBGS) was first used to show that E. coli O157 strains from the United States and Australia could be subdivided into two genetically distinct lineages (21, 22, 46). While both E. coli O157:H7 lineages are associated with human disease and are isolated from cattle, there is a bias in the host distribution between the two lineages, with a significantly higher proportion of lineage I strains isolated from humans than lineage II strains. Several recent studies have shown that there are inherent differences in gene content and expression between populations of lineage I and lineage II E. coli O157:H7 strains. Lejeune et al. (26) reported that the antiterminator Q gene of the stx₂-converting bacteriophage 933W was found in all nine OBGS lineage I strains examined but in only two of seven lineage II strains, suggesting that there may be lineage-specific differences in toxin production. Dowd and Ishizaki (9) used DNA microarray analysis to examine expression of 610 E. coli O157:H7 genes and showed that lineage I and lineage II E. coli O157:H7 strains have evolved distinct patterns of gene expression which may alter their virulence and their ability to survive in different microenvironments and colonize the intestines of different hosts (9, 28, 38).The observations of lineage host bias have been supported and extended by studies using a six-locus-based multiplex PCR termed the lineage-specific polymorphism assay (LSPA-6) (46). However, Ziebell et al. (48) have recently shown that not all LSPA-6 types within lineage II are host biased; e.g., LSPA-6 type 211111 isolation rates from humans and cattle were significantly different from those of other lineage II LSPA-6 types. Therefore, a clearer definition is required of not only the differences between lineages but also the differences among clonal groups within lineages.The genome sequences of two E. coli O157:H7 strains, Sakai and EDL933 (14, 36), have been determined; however, both of these strains are of lineage I, and there are presently no completed and fully annotated genome sequences available for lineage II strains. In our laboratory, comparative studies utilizing suppression subtractive hybridization (SSH) and comparative genomic hybridization revealed numerous potential virulence factors that are conserved in lineage I strains and that are rare or absent in lineage II strains (42, 47). In this study, we have used SSH to identify genomic regions present in E. coli O157:H7 lineage II strains that are absent from lineage I strains. We wished to examine the distribution of these novel gene segments in E. coli O157:H7 strains and gain insight into their origins and functions. We also attempted to identify molecular markers specific to lineage II strains as well as other markers that would be useful in the genetic subtyping or molecular fingerprinting of E. coli O157:H7 strains in population and epidemiological studies (25). This information may be helpful in the identification of genotypes of the organism associated with specific phenotypes of both lesser and greater virulence (29).     

Clonal Relationship among Atypical Enteropathogenic Escherichia coli Strains Isolated from Different Animal Species and Humans

Forty-nine typical and atypical enteropathogenic Escherichia coli (EPEC) strains belonging to different serotypes and isolated from humans, pets (cats and dogs), farm animals (bovines, sheep, and rabbits), and wild animals (monkeys) were investigated for virulence markers and clonal similarity by pulsed-field gel electrophoresis (PFGE) and multilocus sequence typing (MLST). The virulence markers analyzed revealed that atypical EPEC strains isolated from animals have the potential to cause diarrhea in humans. A close clonal relationship between human and animal isolates was found by MLST and PFGE. These results indicate that these animals act as atypical EPEC reservoirs and may represent sources of infection for humans. Since humans also act as a reservoir of atypical EPEC strains, the cycle of mutual infection of atypical EPEC between animals and humans, mainly pets and their owners, cannot be ruled out since the transmission dynamics between the reservoirs are not yet clearly understood.Enteropathogenic Escherichia coli (EPEC) strains are among the major causes of infantile diarrhea in developing countries (71) and can be classified as typical and atypical, depending on the presence or absence of the E. coli adherence factor plasmid (pEAF), respectively (39).The pathogenesis of EPEC resides in the ability to cause the attaching and effacing (A/E) lesion in the gut mucosa of human or animal hosts, leading to diarrheal illness (40). The genes responsible for the A/E lesion formation are located in a chromosomal pathogenicity island of ∼35 kb, known as the locus of enterocyte effacement (LEE) (23, 47). LEE encodes an adhesin called intimin (38), its translocated receptor (Tir) (42), components of a type III secretion system (36), and effector molecules, named E. coli-secreted proteins (Esp proteins) (41). These virulence factors have a crucial role in A/E lesion formation, and their detection in EPEC strains is an indicator of their potential to produce these lesions (19, 56).Atypical EPEC strains have been associated with diarrhea outbreaks in developed countries (31, 73, 77) and with sporadic cases of diarrhea in developing and developed countries (1, 12, 26, 52, 55). At present, the prevalence of atypical EPEC is higher than that of typical EPEC in several countries (1, 12, 26, 52, 55, 65).Different from the situation in developed countries, where atypical EPEC outbreaks and sporadic infections are associated with children and adults, atypical EPEC infection in Brazil is mainly associated with children''s illnesses (32, 71).Typical EPEC strains are rarely isolated from animals, and humans are the major natural reservoir for these pathogens (14, 32, 53, 71). In contrast, atypical EPEC strains are present in both healthy and diseased animals (dog, monkey, cats, and bovines) and humans (4, 6, 18, 28, 71). Some studies have associated pets and farm and wild animals as reservoirs and infection sources of atypical EPEC strains for humans (32). However, these studies did not compare atypical EPEC strains isolated from humans and animals by gold-standard molecular methods like multilocus sequence typing (MLST) or pulsed-field gel electrophoresis (PFGE) (15, 35, 43, 53). For this reason, there are some doubts about whether atypical EPEC strains isolated from animals represent risks for human health and whether animals really play the role of reservoirs of atypical EPEC.The aim of this study was to compare atypical EPEC strains isolated from humans and different animals, including pets (cats and dogs), farm animals (bovines, ovines, and rabbits), and wild animals (monkeys), by molecular phylogenetic techniques to verify the role of animals as reservoirs of and sources of infection with atypical EPEC in humans.