DNA sequence of a ColV plasmid and prevalence of selected plasmid-encoded virulence genes among avian Escherichia coli strains

ColV plasmids have long been associated with the virulence of Escherichia coli, despite the fact that their namesake trait, ColV production, does not appear to contribute to virulence. Such plasmids or their associated sequences appear to be quite common among avian pathogenic E. coli (APEC) and are strongly linked to the virulence of these organisms. In the present study, a 180-kb ColV plasmid was sequenced and analyzed. This plasmid, pAPEC-O2-ColV, possesses a 93-kb region containing several putative virulence traits, including iss, tsh, and four putative iron acquisition and transport systems. The iron acquisition and transport systems include those encoding aerobactin and salmochelin, the sit ABC iron transport system, and a putative iron transport system novel to APEC, eit. In order to determine the prevalence of the virulence-associated genes within this region among avian E. coli strains, 595 APEC and 199 avian commensal E. coli isolates were examined for genes of this region using PCR. Results indicate that genes contained within a portion of this putative virulence region are highly conserved among APEC and that the genes of this region occur significantly more often in APEC than in avian commensal E. coli. The region of pAPEC-O2-ColV containing genes that are highly prevalent among APEC appears to be a distinguishing trait of APEC strains.     

V型分泌系统(T5SS)在禽致病性大肠杆菌中的分布及流行情况

【背景】禽致病性大肠杆菌(Avian pathogenic Escherichia coli,APEC)可引起禽的大肠杆菌病,严重危害养禽业。V型分泌系统(Type V secretion system,T5SS)在APEC感染过程中发挥重要作用。【目的】分析不同致病型大肠杆菌的T5SS在APEC中的分布规律,探讨T5SS与APEC的大肠杆菌进化分群及其他毒力因子的关联性。【方法】根据大肠杆菌的15个T5SS序列设计特异性引物,采用PCR检测T5SS在APEC临床分离株中的分布;分析APEC菌株的系统进化分群及毒力因子分布,探讨T5SS分布和APEC系统进化分群及毒力因子的相关性。【结果】T5SS在APEC临床分离株中广泛分布,其中ydeK和pplfP的分布率最高,分别为98.55%和92.03%;而upaC和pic的分布率均低于10%。系统进化分群结果显示,APEC主要属于A、B1和D进化分群,B2群较少;T5SS分布和进化分群分析发现ehaA、ehaB、pic、vat在D进化分群APEC菌株中分布率较高,而ehaG、ag43/flu、apaC主要分布于A及B1群APEC中。然而,T5SS和APEC其他毒力基因分布无明显的关联性。【结论】T5SS广泛存在于APEC分离株中,且部分T5SS分布与大肠杆菌系统进化分群存在关联性。     

Complete DNA sequence of a ColBM plasmid from avian pathogenic Escherichia coli suggests that it evolved from closely related ColV virulence plasmids

Avian pathogenic Escherichia coli (APEC), an extraintestinal pathogenic E. coli causing colibacillosis in birds, is responsible for significant economic losses for the poultry industry. Recently, we reported that the APEC pathotype was characterized by possession of a set of genes contained within a 94-kb cluster linked to a ColV plasmid, pAPEC-O2-ColV. These included sitABCD, genes of the aerobactin operon, hlyF, iss, genes of the salmochelin operon, and the 5' end of cvaB of the ColV operon. However, the results of gene prevalence studies performed among APEC isolates revealed that these traits were not always linked to ColV plasmids. Here, we present the complete sequence of a 174-kb plasmid, pAPEC-O1-ColBM, which contains a putative virulence cluster similar to that of pAPEC-O2-ColV. These two F-type plasmids share remarkable similarity, except that they encode the production of different colicins; pAPEC-O2-ColV contains an intact ColV operon, and pAPEC-O1-ColBM encodes the colicins B and M. Interestingly, remnants of the ColV operon exist in pAPEC-O1-ColBM, hinting that ColBM-type plasmids may have evolved from ColV plasmids. Among APEC isolates, the prevalence of ColBM sequences helps account for the previously observed differences in prevalence between genes of the "conserved" portion of the putative virulence cluster of pAPEC-O2-ColV and those genes within its "variable" portion. These results, in conjunction with Southern blotting and probing of representative ColBM-positive strains, indicate that this "conserved" cluster of putative virulence genes is primarily linked to F-type virulence plasmids among the APEC isolates studied.     

Genotypic analyses of Escherichia coli isolated from chickens with colibacillosis and apparently healthy chickens in Japan

A genotypic comparison using pulsed-field gel electrophoresis (PFGE), amplified ribosomal restriction analysis (ARDRA) as well as PCRs targeting virulence associated genes reported elsewhere in avian pathogenic Escherichia coli(APEC) was made between E. coli strains isolated from chickens with colibacillosis and those from the feces of apparently healthy chickens in Japan. The majority (67%) of clinical isolates belonged to a certain phylogenetic ARDRA but not PFGE cluster, with virulence-related genes carried by ColV plasmid being markedly prevalent. The result suggests that APEC strains originated from the same "ancestor" in the course of E. coli evolution.     

New Role for the ibeA Gene in H2O2 Stress Resistance of Escherichia coli

ibeA is a virulence factor found in some extraintestinal pathogenic Escherichia coli (ExPEC) strains from the B2 phylogenetic group and particularly in newborn meningitic and avian pathogenic strains. It was shown to be involved in the invasion process of the newborn meningitic strain RS218. In a previous work, we showed that in the avian pathogenic E. coli (APEC) strain BEN2908, isolated from a colibacillosis case, ibeA was rather involved in adhesion to eukaryotic cells by modulating type 1 fimbria synthesis (M. A. Cortes et al., Infect. Immun. 76:4129-4136, 2008). In this study, we demonstrate a new role for ibeA in oxidative stress resistance. We showed that an ibeA mutant of E. coli BEN2908 was more sensitive than its wild-type counterpart to H(2)O(2) killing. This phenotype was also observed in a mutant deleted for the whole GimA genomic region carrying ibeA and might be linked to alterations in the expression of a subset of genes involved in the oxidative stress response. We also showed that RpoS expression was not altered by the ibeA deletion. Moreover, the transfer of an ibeA-expressing plasmid into an E. coli K-12 strain, expressing or not expressing type 1 fimbriae, rendered it more resistant to an H(2)O(2) challenge. Altogether, these results show that ibeA by itself is able to confer increased H(2)O(2) resistance to E. coli. This feature could partly explain the role played by ibeA in the virulence of pathogenic strains.     

New insights into the bacterial fitness-associated mechanisms revealed by the characterization of large plasmids of an avian pathogenic E. coli

Extra-intestinal pathogenic E. coli (ExPEC), including avian pathogenic E. coli (APEC), pose a considerable threat to both human and animal health, with illness causing substantial economic loss. APEC strain χ7122 (O78∶K80∶H9), containing three large plasmids [pChi7122-1 (IncFIB/FIIA-FIC), pChi7122-2 (IncFII), and pChi7122-3 (IncI(2))]; and a small plasmid pChi7122-4 (ColE2-like), has been used for many years as a model strain to study the molecular mechanisms of ExPEC pathogenicity and zoonotic potential. We previously sequenced and characterized the plasmid pChi7122-1 and determined its importance in systemic APEC infection; however the roles of the other pChi7122 plasmids were still ambiguous. Herein we present the sequence of the remaining pChi7122 plasmids, confirming that pChi7122-2 and pChi7122-3 encode an ABC iron transport system (eitABCD) and a putative type IV fimbriae respectively, whereas pChi7122-4 is a cryptic plasmid. New features were also identified, including a gene cluster on pChi7122-2 that is not present in other E. coli strains but is found in Salmonella serovars and is predicted to encode the sugars catabolic pathways. In vitro evaluation of the APEC χ7122 derivative strains with the three large plasmids, either individually or in combinations, provided new insights into the role of plasmids in biofilm formation, bile and acid tolerance, and the interaction of E. coli strains with 3-D cultures of intestinal epithelial cells. In this study, we show that the nature and combinations of plasmids, as well as the background of the host strains, have an effect on these phenomena. Our data reveal new insights into the role of extra-chromosomal sequences in fitness and diversity of ExPEC in their phenotypes.     

Antimicrobial resistance and virulence genes of Escherichia coli isolates from swine in Ontario

A total of 318 Escherichia coli isolates obtained from diarrheic and healthy pigs in Ontario from 2001 to 2003 were examined for their susceptibility to 19 antimicrobial agents. They were tested by PCR for the presence of resistance genes for tetracycline, streptomycin, sulfonamides, and apramycin and of 12 common virulence genes of porcine E. coli. Antimicrobial resistance frequency among E. coli isolates from swine in Ontario was moderate in comparison with other countries and was higher in isolates from pigs with diarrhea than in isolates from healthy finisher pigs. Resistance profiles suggest that cephamycinases may be produced by > or = 8% of enterotoxigenic E. coli (ETEC). Resistance to quinolones was detected only in enterotoxigenic E. coli (< or = 3%). The presence of sul3 was demonstrated for the first time in Canada in porcine E. coli isolates. Associations were observed among tetA, sul1, aadA, and aac(3)IV and among tetB, sul2, and strA/strB, with a strong negative association between tetA and tetB. The paa and sepA genes were detected in 92% of porcine ETEC, and strong statistical associations due to colocation on a large plasmid were observed between tetA, estA, paa, and sepA. Due at least in part to gene linkages, the distribution of resistance genes was very different between ETEC isolates and other porcine E. coli isolates. This demonstrates that antimicrobial resistance epidemiology differs significantly between pathogenic and commensal E. coli isolates. These results may have important implications with regards to the spread and persistence of resistance and virulence genes in bacterial populations and to the prudent use of antimicrobial agents.     

Prevalence of avian-pathogenic Escherichia coli strain O1 genomic islands among extraintestinal and commensal E. coli isolates

Escherichia coli strains that cause disease outside the intestine are known as extraintestinal pathogenic E. coli (ExPEC) and include pathogens of humans and animals. Previously, the genome of avian-pathogenic E. coli (APEC) O1:K1:H7 strain O1, from ST95, was sequenced and compared to those of several other E. coli strains, identifying 43 genomic islands. Here, the genomic islands of APEC O1 were compared to those of other sequenced E. coli strains, and the distribution of 81 genes belonging to 12 APEC O1 genomic islands among 828 human and avian ExPEC and commensal E. coli isolates was determined. Multiple islands were highly prevalent among isolates belonging to the O1 and O18 serogroups within phylogenetic group B2, which are implicated in human neonatal meningitis. Because of the extensive genomic similarities between APEC O1 and other human ExPEC strains belonging to the ST95 phylogenetic lineage, its ability to cause disease in a rat model of sepsis and meningitis was assessed. Unlike other ST95 lineage strains, APEC O1 was unable to cause bacteremia or meningitis in the neonatal rat model and was significantly less virulent than uropathogenic E. coli (UPEC) CFT073 in a mouse sepsis model, despite carrying multiple neonatal meningitis E. coli (NMEC) virulence factors and belonging to the ST95 phylogenetic lineage. These results suggest that host adaptation or genome modifications have occurred either in APEC O1 or in highly virulent ExPEC isolates, resulting in differences in pathogenicity. Overall, the genomic islands examined provide targets for further discrimination of the different ExPEC subpathotypes, serogroups, phylogenetic types, and sequence types.     

Roles of iron acquisition systems in virulence of extraintestinal pathogenic Escherichia coli: salmochelin and aerobactin contribute more to virulence than heme in a chicken infection model

ABSTRACT: BACKGROUND: Avian pathogenic Escherichia coli (APEC) and uropathogenic E. coli (UPEC) are the two main subsets of extraintestinal pathogenic E. coli (ExPEC). Both types have multiple iron acquisition systems, including heme and siderophores. Although iron transport systems involved in the pathogenesis of APEC or UPEC have been documented individually in corresponding animal models, the contribution of these systems during simultaneous APEC and UPEC infection is not well described. To determine the contribution of each individual iron acquisition system to the virulence of APEC and UPEC, isogenic mutants affecting iron uptake in APEC E058 and UPEC U17 were constructed and compared in a chicken challenge model. RESULTS: Salmochelin-defective mutants E058DeltairoD and U17DeltairoD showed significantly decreased pathogenicity compared to the wild-type strains. Aerobactin defective mutants E058DeltaiucD and U17DeltaiucD demonstrated reduced colonization in several internal organs, whereas the heme defective mutants E058DeltachuT and U17DeltachuT colonized internal organs to the same extent as their wild-type strains. The triple mutant DeltachuTDeltairoDDeltaiucD in both E058 and U17 showed decreased pathogenicity compared to each of the single mutants. The histopathological lesions in visceral organs of birds challenged with the wild-type strains were more severe than those from birds challenged with DeltairoD, DeltaiucD or the triple mutants. Conversely, chickens inoculated with the DeltachuT mutants had lesions comparable to those in chickens inoculated with the wild-type strains. However, no significant differences were observed between the mutants and the wild-type strains in resistance to serum, cellular invasion and intracellular survival in HD-11, and growth in iron-rich or iron-restricted medium. CONCLUSIONS: Results indicated that APEC and UPEC utilize similar iron acquisition mechanisms in chickens. Both salmochelin and aerobactin systems appeared to be important in APEC and UPEC virulence, while salmochelin contributed more to the virulence. Heme bounded by ChuT in the periplasm appeared to be redundant in this model, indicating that other periplasmic binding proteins likely contributed to the observed no phenotype for the heme uptake mutant. No differences were observed between the mutants and their wild-type parents in other phenotypic traits, suggesting that other virulence mechanisms compensate for the effect of the mutations.     

酰基高丝氨酸内脂合成酶LasI对禽致病性大肠杆菌生物学特性的影响

【背景】禽致病性大肠杆菌(Avian pathogenic Escherichia coli, APEC)是禽类主要病原菌之一,群体感应(Quorumsensing,QS)系统可通过信号分子调控其生物学特性。在APEC中信号分子AHL对其生物学特性的影响目前尚不清楚。【目的】研究信号分子AHL对APEC生物学特性的影响。【方法】将含铜绿假单胞菌酰基高丝氨酸内脂合成酶(Acyl-homoserine-lactone synthase,lasI)基因的表达质粒转化至APEC菌株DE17中,构建重组菌株DE17-lasI,利用LasI在DE17中合成AHL。比较野生株和重组菌株产生AHL信号分子、生长特性、生物被膜形成能力、运动性以及耐药性等生物学特性的差异;运用Real-timePCR技术,比较野生株和重组菌株中与生物被膜形成、运动性以及毒力因子相关基因的转录水平。【结果】对重组菌株AHL信号分子检测表明,DE17-lasI能够产生AHL信号分子,与野生株DE17相比,DE17-lasI生物被膜形成能力和运动性显著降低(P0.01),但其生长特性和耐药性无显著变化(P0.05);Real-time PCR检测结果表明,重组菌株的毒力因子fimH转录水平上调了58.8倍,而ompA、iss分别下调了95.4%、77.3%。与生物被膜形成相关基因agn43下调了75%,鞭毛合成基因flhA下调了80.8%。此外,AHL受体sdiA的转录水平上调了19.8倍。【结论】转化lasI至APEC中,能促进其在APEC中合成信号分子AHL,并显著影响APEC的部分生物学特性,为进一步探讨AHL型群体感应系统对APEC的调控作用提供参考。     

尿道致病性大肠杆菌HEC4株和禽源致病性大肠杆菌E058株毒力相关特性的比较

对人尿道致病性大肠杆菌(uropathogenic Escherichia coli,UPEC)HEC4株和禽致病性大肠杆菌(avian pathogen-ic Escherichia coli,APEC)E058株进行毒力基因和其他相关特性的比较,结果显示,它们具有一些共同的毒力基因,包括一些存在于APEC中一个大的可传递质粒上的基因;同时,它们也具有一些相似的生化特性。对SPF鸡的致病性试验显示,这两株分离株具有相似的致病力。因此,对于APEC和UPEC的相关性,以及APEC是否有可能导致人尿道感染或者成为UPEC的毒力基因贮主,有待进一步研究。     

禽致病性大肠杆菌IMT5155 疑似毒力基因在人源及动物源大肠杆菌中的分布

[目的]检测禽致病性大肠杆菌IMT5155自分泌黏附素基因等具有代表性的疑似毒力基因在不同来源大肠杆菌中的分布,为进一步研究其致病机理提供依据.[方法]采用PCR和Dot blot,检测疑似毒力基因在不同地区(101株大肠杆菌中国分离株和121株大肠杆菌德国分离株)、不同来源(人源、禽源及猪源)大肠杆菌中的分布,并分析其和大肠杆菌系统进化分群的关系.[结果]自分泌黏附素基因B11等11个疑似毒力基因在禽致病性大肠杆菌中分布率较高,阳性率分别为:A1 36.4%(32/88)、A8 53.4%(47/88)、A1063.6%(56/88)、B1137.5%(33/88)、F3 59.1%(52/88)等,且疑似毒力基因主要存在于大肠杆菌B2进化群中.值得注意的是,D1、E9和F11基因片段在新生儿脑膜炎大肠杆菌中有较高的分布率,分别为60%(6/10)、80%(8/10)和90%(9/10),而在新生儿脑膜炎大肠杆菌中未检测到B11基因.[结论]自分泌黏附素B11等疑似毒力基因与禽致病性大肠杆菌关系密切,但疑似毒力基因D1、E9和F11与新生儿脑膜炎大肠杆菌密切相关,提示禽致病性大肠杆菌可能是新生儿脑膜炎大肠杆菌的毒力基因储库.     

Pathotype and Antibiotic Resistance Gene Distributions of Escherichia coli Isolates from Broiler Chickens Raised on Antimicrobial-Supplemented Diets

The impact of feed supplementation with bambermycin, monensin, narasin, virginiamycin, chlortetracycline, penicillin, salinomycin, and bacitracin on the distribution of Escherichia coli pathotypes in broiler chickens was investigated using an E. coli virulence DNA microarray. Among 256 E. coli isolates examined, 59 (23%) were classified as potentially extraintestinal pathogenic E. coli (ExPEC), while 197 (77%) were considered commensal. Except for chlortetracycline treatment, the pathotype distribution was not significantly different among treatments (P > 0.05). Within the 59 ExPEC isolates, 44 (75%) were determined to be potentially avian pathogenic E. coli (APEC), with the remaining 15 (25%) considered potentially “other” ExPEC isolates. The distribution within phylogenetic groups showed that 52 (88%) of the ExPEC isolates belonged to groups B2 and D, with the majority of APEC isolates classified as group D and most commensal isolates (170, 86%) as group A or B1. Indirect assessment of the presence of the virulence plasmid pAPEC-O2-ColV showed a strong association of the plasmid with APEC isolates. Among the 256 isolates, 224 (88%) possessed at least one antimicrobial resistance gene, with nearly half (107, 42%) showing multiple resistance genes. The majority of resistance genes were distributed among commensal isolates. Considering that the simultaneous detection of antimicrobial resistance tet(A), sulI, and bla_TEM genes and the integron class I indicated a potential presence of the resistance pAPEC-O2-R plasmid, the results revealed that 35 (14%) of the isolates, all commensals, possessed this multigene resistance plasmid. The virulence plasmid was never found in combination with the antimicrobial resistance plasmid. The presence of the ColV plasmid or the combination of iss and tsh genes in the majority of APEC isolates supports the notion that when found together, the plasmid, iss, and tsh serve as good markers for APEC. These data indicate that different resistant E. coli pathotypes can be found in broiler chickens and that the distribution of such pathotypes and certain virulence determinants could be modulated by antimicrobial agent feed supplementation.Several classes of antimicrobial agents, such as glycolipids (bambermycin), cyclic peptides (bacitracin), ionophores (monensin and salinomycin), streptogramins (virginiamycin), and β-lactams (penicillin), are widely used as food additives in modern animal husbandry to prevent infections and promote growth (6). Increasing antimicrobial resistance in animals and its potential threat to human health led to the ban of bacitracin, spiramycin, tylosin, and virginiamycin as feeding additives by the European Union in 1999 (7, 46). Although this precautionary measure is still controversial because of being seen as having a negligible impact on human health, negative consequences for animal health and welfare, including economic losses for farmers, were subsequently observed in Europe (7). In stark contrast, however, the ban has been beneficial in reducing the total quantity of antibiotics administered to food animals (7, 47). Under good production conditions and correct use of antibiotics, poultry production is reported to be competitive (14, 47, 48) and even beneficial in reducing antimicrobial resistance in important food animal reservoirs and thus the potential threat to public health (48).Escherichia coli is generally considered a commensal member of the normal gastrointestinal microflora in humans and animals, yet some strains are known to cause serious morbidity and mortality. The expression of various virulence factors, which affect cellular processes, can result in different clinical diseases, such as cystitis, pyelonephritis, sepsis/meningitis, and gastroenteritis. The possession of different virulence gene subsets can further define the E. coli pathotype (31). The extraintestinal pathogenic E. coli (ExPEC) strains are epidemiologically and phylogenetically distinct from both intestinal pathogenic and commensal strains (43). In North America, annually, several million cases of urinary tract infections, abdominal infections, pelvic infections, pneumonia, meningitis, and sepsis are caused by ExPEC (42). In poultry production, avian pathogenic E. coli (APEC) is responsible for significant economic losses. APEC strains induce extraintestinal diseases such as air sacculitis, colibacillosis, polysorositis, and septicemia in birds (9, 21, 22, 31, 35, 45). Although no specific set of virulence factors has been clearly linked to APEC strains, most identified virulence factors are similar to those frequently associated with ExPEC (36).Bearing in mind that the avian intestinal environment has been considered a reservoir of E. coli having zoonotic potential (15) and the possible contamination of poultry products with such bacteria during slaughter, the impact of antimicrobial feeding additives on the distribution and dissemination of bacterial pathotypes and antibiotic resistance needs to be explored to address human, animal, and environmental health concerns. To this end, an E. coli DNA virulence microarray previously employed to assess the genotypes (virulence and antibiotic resistance genes) of E. coli strains isolated from different environmental ecosystems and from the chicken intestinal tract (1, 10, 19, 20, 33) was used. The aim of the present trial was to investigate the distributions of pathotypes and of virulence and antibiotic resistance genes in E. coli isolates from broilers fed with antimicrobial supplementation diets including bambermycin, penicillin, salinomycin, bacitracin, chlortetracycline, virginiamycin, monensin, and narasin.     

Plasmid replicon typing of commensal and pathogenic Escherichia coli isolates

Despite the critical role of plasmids in horizontal gene transfer, few studies have characterized plasmid relatedness among different bacterial populations. Recently, a multiplex PCR replicon typing protocol was developed for classification of plasmids occurring in members of the Enterobacteriaceae. Here, a simplified version of this replicon typing procedure which requires only three multiplex panels to identify 18 plasmid replicons is described. This method was used to screen 1,015 Escherichia coli isolates of avian, human, and poultry meat origin for plasmid replicon types. Additionally, the isolates were assessed for their content of several colicin-associated genes. Overall, a high degree of plasmid variability was observed, with 221 different profiles occurring among the 1,015 isolates examined. IncFIB plasmids were the most common type identified, regardless of the source type of E. coli. IncFIB plasmids occurred significantly more often in avian pathogenic E. coli (APEC) and retail poultry E. coli (RPEC) than in uropathogenic E. coli (UPEC) and avian and human fecal commensal E. coli isolates (AFEC and HFEC, respectively). APEC and RPEC were also significantly more likely than UPEC, HFEC, and AFEC to possess the colicin-associated genes cvaC, cbi, and/or cma in conjunction with one or more plasmid replicons. The results suggest that E. coli isolates contaminating retail poultry are notably similar to APEC with regard to plasmid profiles, with both generally containing multiple plasmid replicon types in conjunction with colicin-related genes. In contrast, UPEC and human and avian commensal E. coli isolates generally lack the plasmid replicons and colicin-related genes seen in APEC and RPEC, suggesting limited dissemination of such plasmids among these bacterial populations.     

Occurrence of virulence and antimicrobial resistance genes in Escherichia coli isolates from different aquatic ecosystems within the St. Clair River and Detroit River areas

Although the number of Escherichia coli bacteria in surface waters can differ greatly between locations, relatively little is known about the distribution of E. coli pathotypes in surface waters used as sources for drinking or recreation. DNA microarray technology is a suitable tool for this type of study due to its ability to detect high numbers of virulence and antimicrobial resistance genes simultaneously. Pathotype, phylogenetic group, and antimicrobial resistance gene profiles were determined for 308 E. coli isolates from surface water samples collected from diverse aquatic ecosystems at six different sites in the St. Clair River and Detroit River areas. A higher frequency (48%) of E. coli isolates possessing virulence and antimicrobial resistance genes was observed in an urban site located downstream of wastewater effluent outfalls than in the other examined sites (average of 24%). Most E. coli pathotypes were extraintestinal pathogenic E. coli (ExPEC) pathotypes and belonged to phylogenetic groups B2 and D. The ExPEC pathotypes were found to occur across all aquatic ecosystems investigated, including riverine, estuarine, and offshore lake locations. The results of this environmental study using DNA microarrays highlight the widespread distribution of E. coli pathotypes in aquatic ecosystems and the potential public health threat of E. coli pathotypes originating from municipal wastewater sources.     

Virulence, resistance genes, and transformation amongst environmental isolates of Escherichia coli and Acinetobacter spp

The association of verotoxic E. coli and Acinetobacter spp. with various antibiotic-resistant, diarrhogenic, and nosocomial infections has been a cause for concern worldwide. E. coli and A. haemolyticus isolated on a number of selective media were screened for virulence factors, antibiotic resistance, and transformation of resistance genes. Out of 69 E. coli isolates obtained, 25 (35.23%), 14 (20.30%), and 28 (40.58%) were positive for Vtx1&2, Vtx1, and Vtx2, respectively, 49 (71.015%) for extendedspectrum beta-lactamases (ESBLs), 34 (49.28%) for serum resistance, 57 (82.61%) for cell surface hydrophobicity, 48 (69.57%) for gelatinase production, and 37 (53.62%) for hemolysin production. For the 14 A. haemolyticus isolates, only 2 (14.29%) in each case from all the samples investigated were positive for Vtx1, Vtx2 and Vtx1&2 respectively, 8 (57.14%) for ESBLs, 7 (50.00%) for serum resistance, 11 (78.57%) for cell surface hydrophobicity, 4 (28.57%) for gelatinase production, and 8 (57.14%) for hemolysin production. Although transformation occurred among the E. coli and Acinetobacter isolates (transformation frequency: 13.3 × 10(-7) -53.4(-7)), there was poor curing of the plasmid genes, a confirmation of the presence of stable antibiotic-resistant genes (DNA concentration between 42.7 and 123.8 microgram) and intragenetic transfer of multidrugresistant genes among the isolates. The isolates were potentially virulent and contained potentially transferable antibiotic resistance genes. Detection of virulence factors, antibiotic resistance genes, and transformation among these isolates is a very significant outcome that will influence approaches to proactive preventive and control measures and future investigations. However, continued surveillance for drug resistance among these bacteria and further investigation of the mechanism of action of their virulence factors are a necessity.     

Genotypic and phenotypic traits that distinguish neonatal meningitis-associated Escherichia coli from fecal E. coli isolates of healthy human hosts

Neonatal meningitis Escherichia coli (NMEC) is one of the top causes of neonatal meningitis worldwide. Here, 85 NMEC and 204 fecal E. coli isolates from healthy humans (HFEC) were compared for possession of traits related to virulence, antimicrobial resistance, and plasmid content. This comparison was done to identify traits that typify NMEC and distinguish it from commensal strains to refine the definition of the NMEC subpathotype, identify traits that might contribute to NMEC pathogenesis, and facilitate choices of NMEC strains for future study. A large number of E. coli strains from both groups were untypeable, with the most common serogroups occurring among NMEC being O18, followed by O83, O7, O12, and O1. NMEC strains were more likely than HFEC strains to be assigned to the B2 phylogenetic group. Few NMEC or HFEC strains were resistant to antimicrobials. Genes that best discriminated between NMEC and HFEC strains and that were present in more than 50% of NMEC isolates were mainly from extraintestinal pathogenic E. coli genomic and plasmid pathogenicity islands. Several of these defining traits had not previously been associated with NMEC pathogenesis, are of unknown function, and are plasmid located. Several genes that had been previously associated with NMEC virulence did not dominate among the NMEC isolates. These data suggest that there is much about NMEC virulence that is unknown and that there are pitfalls to studying single NMEC isolates to represent the entire subpathotype.     

Characterization of antibiotic-resistant and potentially pathogenic Escherichia coli from soil fertilized with litter of broiler chickens fed antimicrobial-supplemented diets

The objective of this study was to characterize antimicrobial resistance and virulence determinants of Escherichia coli from soil amended with litter from 36-day-old broiler chickens ( Gallus gallus domesticus ) fed with diets supplemented with a variety of antimicrobial agents. Soil samples were collected from plots before and periodically after litter application in August to measure E. coli numbers. A total of 295 E.?coli were isolated from fertilized soil samples between August and March. Antibiotic susceptibility was determined by Sensititre, and polymerase chain reaction was performed to detect the presence of resistance and virulence genes. The results confirmed that E.?coli survived and could be quantified by direct plate count for at least 7 months in soil following litter application in August. The effects of feed supplementation were observed on E.?coli numbers in November and January. Among the 295 E.?coli, the highest antibiotic resistance level was observed against tetracycline and β-lactams associated mainly with the resistance genes tetB and bla(CMY-2), respectively. Significant treatment effects were observed for phylogenetic groups, antibiotic resistance profiles, and virulence gene frequencies. Serotyping, phylogenetic grouping, and pulsed-field gel electrophoresis confirmed that multiple-antibiotic-resistant and potentially pathogenic E.?coli can survive in soil fertilized with litter for several months regardless of antimicrobials used in the feed.     

Studies on diarrheagenic Escherichia coli isolated from children with diarrhea in Myanmar

Escherichia coli isolates from 217 children in Myanmar with diarrhea were investigated for the presence of virulence genes related to diarrhea by colony hybridization and PCR. The genes examined were lt, stI, stII, stx1, stx2, eae, bfp, pCVD (which is the representative gene of plasmid of pCVD of EAEC), and ial (which is invasion-associated locus of the invasion plasmid found in EIEC). Isolates from 47 of 217 children (21.7%) possessed virulence genes characteristic of diarrheagenic E. coli. No instance was found of co-existence of different E. coli strains with different virulence genes in the same patient. Diarrheagenic E. coli are currently classified into five categories based on their virulence markers: ETEC, EHEC, EPEC, EAEC, and EIEC. Of the 47 isolates examined, 30 were EAEC, 12 were EPEC and 5 were ETEC. Susceptibility tests for antimicrobial agents showed that almost all diarrheagenic isolates were resistant to penicillin, tetracycline and streptomycin. However, the majority of strains were sensitive to cephalexin, nalidixic acid and norfloxacin. In particular, 42 of the 47 isolates were sensitive to norfloxacin, which is a fluoroquinolone. This study shows EAEC and EPEC are responsible for sporadic diarrhea in Myanmar and fluoroquinolones appear to be effective in the treatment of these patients.     

Transfer of multiple drug resistance plasmids between bacteria of diverse origins in natural microenvironments

Plasmids harboring multiple antimicrobial-resistance determinants (R plasmids) were transferred in simulated natural microenvironments from various bacterial pathogens of human, animal, or fish origin to susceptible strains isolated from a different ecological niche. R plasmids in a strain of the human pathogen Vibrio cholerae O1 E1 Tor and a bovine Escherichia coli strain were conjugated to a susceptible strain of the fish pathogenic bacterium Aeromonas salmonicida subsp. salmonicida in marine water. Conjugations of R plasmids between a resistant bovine pathogenic E. coli strain and a susceptible E. coli strain of human origin were performed on a hand towel contaminated with milk from a cow with mastitis. A similar conjugation event between a resistant porcine pathogenic E. coli strain of human origin was studied in minced meat on a cutting board. Conjugation of R plasmids between a resistant strain of the fish pathogenic bacterium A. salmonicida subsp. salmonicida and a susceptible E. coli strain of human origin was performed in raw salmon on a cutting board. R plasmids in a strain of A. salmonicida subsp. salmonicida and a human pathogenic E. coli strain were conjugated to a susceptible porcine E. coli strain in porcine feces. Transfer of the different R plasmids was confirmed by plasmid profile analyses and determination of the resistance pattern of the transconjugants. The different R plasmids were transferred equally well under simulated natural conditions and under controlled laboratory conditions, with median conjugation frequencies ranging from 3 x 10(-6) to 8 x 10(-3). The present study demonstrates that conjugation and transfer of R plasmids is a phenomenon that belongs to the environment and can occur between bacterial strains of human, animal, and fish origins that are unrelated either evolutionarily or ecologically even in the absence of antibiotics. Consequently, the contamination of the environment with bacterial pathogens resistant to antimicrobial agents is a real threat not only as a source of disease but also as a source from which R plasmids can easily spread to other pathogens of diverse origins.