Genotyping of Escherichia coli from environmental and animal samples

The triplex PCR of Clermont et al. [Clermont, O., Bonacorsi, S., Bingen, E., 2000. Rapid and simple determination of the Escherichia coli phylogenetic groups. Appl. Environ. Microbiol. 66, 4555-4558.] was used to genotype E. coli isolates from the Mid-Atlantic region of the USA, obtained from freshwater, animal internal organs, and feces. Of 445 isolates subjected to genotyping, 118 isolates (26%) were genotype A, 111 (25%) genotype D, 140 (31%) genotype B1, and 76 (17%) genotype B2. All four genotypes were present in three sets of freshwater stream samples. When isolates from chicken cecal ingesta, cecal mucosa, and tracheal mucosa were screened, there was selective distribution of genotypes in these organs. Genotype D was rarely encountered in feces, milk, and intestinal tissues of dairy cows, while all four genotypes were represented in goose feces. Isolates from the feces of zoo animals reared in the US demonstrated a predominance of genotype B1. Thirty-six of the A isolates in our overall collection were subgenotype A(0), in which none of the three amplicons are observed; confirmation that these isolates were E. coli was done using an ancillary lacZ PCR assay. We conclude that the genotyping triplex PCR assay, used in combination with traditional culture methods, can be useful in categorizing E. coli from environmental and veterinary sources in the Mid-Atlantic region of the USA.     

Characterization of the cryptic Escherichia lineages: rapid identification and prevalence

Strains phenotypically indistinguishable from Escherichia coli and belonging to at least five distinct cryptic lineages, named Escherichia clades I to V, that are genetically divergent from E. coli yet members of the genus have been recently found using multi-locus sequence typing (MLST). Very few epidemiological data are available on these strains as their detection by MLST is not suitable for large-scale studies. In this work, we developed a rapid PCR method based on aes and chuA allele-specific amplifications that assigns a strain a cryptic lineage membership. By screening more than 3500 strains with this approach, we show that the cryptic lineages of Escherichia are unlikely to be detected in human faecal samples (2-3% frequency) and even less likely to be isolated from extra-intestinal body sites (< 1% frequency). They are more abundant in animal faeces ranging from 3-8% in non-human mammals to 8-28% in birds. Overall, the strains from the clade V are the most abundant and from the clade II very rare. These results suggest that members of the cryptic clades are unlikely to be of significance to human and health but may influence the use of 'E. coli' as an indicator of water quality.     

Multiple-Locus Variable-Number Tandem-Repeats Analysis of Escherichia coli O157 using PCR multiplexing and multi-colored capillary electrophoresis

The Multiple-Locus Variable-Number Tandem-Repeats Analysis (MLVA) method is currently being used as the primary typing tool for Shiga-toxin-producing Escherichia coli (STEC) O157 isolates in our laboratory. The initial assay was performed using a single fluorescent dye and the different patterns were assigned using a gel image. Here, we present a significantly improved assay using multiple dye colors and enhanced PCR multiplexing to increase speed, and ease the interpretation of the results. The different MLVA patterns are now based on allele sizes entered as character values, thus removing the uncertainties introduced when analyzing band patterns from the gel image. We additionally propose an easy numbering scheme for the identification of separate isolates that will facilitate exchange of typing data. Seventy-two human and animal strains of Shiga-toxin-producing E. coli O157 were used for the development of the improved MLVA assay. The method is based on capillary separation of multiplexed PCR products of VNTR loci in the E. coli O157 genome labeled with multiple fluorescent dyes. The different alleles at each locus were then assigned to allele numbers, which were used for strain comparison.     

Broad diversity of conjugative plasmids in integron-carrying bacteria from wastewater environments

In this study we assessed the occurrence, diversity and conjugative potential of plasmids in integron-carrying Aeromonas and Enterobacteriaceae from wastewaters. Sixty-six strains were included as donors in mating assays using rifampicin-resistant Escherichia coli and Pseudomonas putida recipient strains. The diversity of plasmids from donors and transconjugants (resistant to tetracycline or streptomycin) was evaluated by restriction analysis and replicon typing targeting 19 incompatibility groups. Restriction patterns revealed a diverse plasmid pool present in these strains. Plasmids were assigned to FrepB (Aeromonas salmonicida, Aeromonas veronii, Aeromonas sp., E.?coli, Enterobacter sp.), FIC (A.?salmonicida, Aeromonas sp.), FIA (Shigella sp.), I1 (A.?veronii, Aeromonas sp., E.?coli), HI1 (E.?coli) and U (Aeromonas media) replicons. Nevertheless, 50% of the plasmids could not be assigned to any replicon type. Among integron-positive transconjugants, FrepB, I1 and HI1 replicons were detected. Results showed that wastewaters enclose a rich plasmid pool associated with integron-carrying bacteria, capable of conjugating to different bacterial hosts. Moreover, replicons detected in this study in Aeromonas strains expand our current knowledge of plasmid diversity in this genus.     

Statistical superiority of genome-probing microarrays as genomic DNA-DNA hybridization in revealing the bacterial phylogenetic relationship compared to conventional methods

The genomic DNA-DNA hybridization (DDH) method has been widely used as a practical method for the determination of phylogenetic relationships between closely related biological strains. Traditional DDH methods have serious limitations including low reproducibility, a high background and a time-consuming procedure. The DDH method using a genome-probing microarray (GPM) has been recently developed to complement conventional methods and could be used to overcome the limitations that are typically encountered. It is necessary to compare the GPM-based DDH method to the conventional methods before using the GPM for the estimation of genomic similarities since all of the previous scientific data have been entirely dependent on conventional DDH methods. In order to address this issue we compared the DDH values obtained using the GPM, microplate and nylon membrane methods to multi-locus sequence typing (MLST) data for 9 Salmonella genomes and an Escherichia coli type strain. The results showed that the genome similarity values and the degrees of standard deviation obtained using the GPM method were lower than those obtained with the microplate and nylon membrane methods. The dendrogram from the cluster analysis of GPM DDH values was consistent with the phylogenetic tree obtained from the multi-locus sequence typing (MLST) data but was not similar to those obtained using the microplate and nylon membrane methods. Although the signal intensity had to be maximal when the targets were hybridized to their own probe, the methods using membranes and microplates frequently produced higher signals in the heterologous hybridizations than those obtained in the homologous hybridizations. Only the GPM method produced the highest signal intensity in homologous hybridizations. These results show that the GPM method can be used to obtain results that are more accurate than those generated by the other methods tested.     

Amplified intergenic locus polymorphism as a basis for bacterial typing of Listeria spp. and Escherichia coli

DNA-based methods are increasingly important for bacterial typing. The high number of polymorphic sites present among closely related bacterial genomes is the basis for the presented method. The method identifies multilocus genomic polymorphisms in intergenic regions termed AILP (amplified intergenic locus polymorphism). For each locus, a pair of unique PCR primers was designed to amplify an intergenic sequence from one open reading frame (ORF) to the adjacent ORF. Presence, absence, and size variation of the amplification products were identified and used as genetic markers for rapidly differentiating among strains. Polymorphism was evaluated using 18 AILP sites among 28 strains of Listeria monocytogenes and 6 strains of Listeria spp. and 30 AILP markers among 27 strains of Escherichia coli. Up to four alleles per locus were identified among Listeria strains, and up to six were identified among E. coli strains. In both species, more than half of the AILP sites revealed intraspecies polymorphism. The AILP data were applied to phylogenetic analysis among Listeria and E. coli strains. A clear distinction between L. monocytogenes and Listeria spp. was demonstrated. In addition, the method separated L. monocytogenes into the three known lineages and discriminated the most common virulent serotypic group, 4b. In E. coli, AILP analysis separated the known groups as well as the virulent O157:H7 isolates. These findings for both Listeria and E. coli are in agreement with other phylogenetic studies using molecular markers. The AILP method was found to be rapid, simple, reproducible, and a low-cost method for initial bacterial typing that could serve as a basis for epidemiological investigation.     

Identification of Escherichia coli Recovered from Milk of Sows with Coliform Mastitis by Random Amplified Polymorphic DNA (RAPD) Using Standardized Reagents

A standardized-reagents commercial kit for random amplified polymorphic DNA (RAPD) analysis was used for typing 58 Escherichia coli strains that were recovered from the milk of sows, having coliform mastitis, within a single swineherd in Sweden. Previously, the 58 E. coli strains were characterized serologically and profiled biochemically. They were also evaluated for their serum resistance and their ability to adhere to fibronectin and bovine fetal fibroblasts. The RAPD analysis was fast, easily performed, and required only a nanogram of DNA. The indistinguishable banding patterns obtained with repeated analyses of 2 isolates from each strain demonstrated that RAPD analysis using standardized beads is a technique that provides reproducible results for typing E. coli strains that cause mastitis in sows. The results of the RAPD analyses demonstrated that E. coli sow mastitis strains are highly variable in serotype, biochemical profiles, virulence factors, and RAPD type, and that all 58 strains can be differentiated by means of the RAPD technique. The strains grouped into 24 RAPD types by combining the results of 2 primers, and into 38 groups by combining the results of serotype and RAPD type. No relationship between serotypes, virulence factors and RAPD types was found.     

Single-nucleotide polymorphism phylotyping of Escherichia coli

We describe a rapid and easily automated phylogenetic grouping technique based on analysis of bacterial genome single-nucleotide polymorphisms (SNPs). We selected 13 SNPs derived from a complete sequence analysis of 11 essential genes previously used for multilocus sequence typing (MLST) of 30 Escherichia coli strains representing the genetic diversity of the species. The 13 SNPs were localized in five genes, trpA, trpB, putP, icdA, and polB, and were selected to allow recovery of the main phylogenetic groups (groups A, B1, E, D, and B2) and subgroups of the species. In the first step, we validated the SNP approach in silico by extracting SNP data from the complete sequences of the five genes for a panel of 65 pathogenic strains belonging to different E. coli pathovars, which were previously analyzed by MLST. In the second step, we determined these SNPs by dideoxy single-base extension of unlabeled oligonucleotide primers for a collection of 183 commensal and extraintestinal clinical E. coli isolates and compared the SNP phylotyping method to previous well-established typing methods. This SNP phylotyping method proved to be consistent with the other methods for assigning phylogenetic groups to the different E. coli strains. In contrast to the other typing methods, such as multilocus enzyme electrophoresis, ribotyping, or PCR phylotyping using the presence/absence of three genomic DNA fragments, the SNP typing method described here is derived from a solid phylogenetic analysis, and the results obtained by this method are more meaningful. Our results indicate that similar approaches may be used for a wide variety of bacterial species.     

Strategy for chromosomal gene targeting in RecA-deficient Escherichia coli strains

Reengineering DNA by homologous recombination in Escherichia coli often depends on helper functions provided on a temporarily introduced replicon that is subsequently cured from the cells. The suicide vector pKSS offers a new curing strategy. pKSS specifies a variant of phenylalanyl-transfer RNA (tRNA) synthetase conferring relaxed substrate specificity towards phenylalanine analogs that results in their lethal incorporation into cellular proteins. Consequently, the presence of p-chlorophenylalanine selects for strains that have lost pKSS. This principle, in conjunction with a plasmid-borne recA gene, was exploited for targeted chromosomal mutagenesis by double homologous recombination in RecA-negative E. coli strains. Gene replacement with a kanamycin-resistance cassette was possible in a single step by plating on kanamycin and p-chlorophenylalanine agar plates and incubating at 37 degrees C. The presence of the correct chromosomal mutation and the absence of the plasmid were established by several control experiments. A simple screen confirmed the desired resistance phenotype in 44% of the initially selected clones, and 75% of these had the correct genotype.     

<Emphasis Type="Italic">Escherichia coli</Emphasis> phylogenetic group determination and its application in the identification of the major animal source of fecal contamination

Background  

Escherichia coli strains are commonly found in the gut microflora of warm-blooded animals. These strains can be assigned to one of the four main phylogenetic groups, A, B1, B2 and D, which can be divided into seven subgroups (A₀, A₁, B1, B2₂, B2₃, D₁ and D₂), according to the combination of the three genetic markers chuA, yjaA and DNA fragment TspE4.C2. Distinct studies have demonstrated that these phylo-groups differ in the presence of virulence factors, ecological niches and life-history. Therefore, the aim of this work was to analyze the distribution of these E. coli phylo-groups in 94 human strains, 13 chicken strains, 50 cow strains, 16 goat strains, 39 pig strains and 29 sheep strains and to verify the potential of this analysis to investigate the source of fecal contamination.     

The multi-locus VNTR-analysis in studies of the population structure of Yersinia pestis in natural foci

A collection of Yersinia pestis strains was investigated by the multi-locus VNTR analysis. All 9 used locuses were diverse, although they differed between themselves by the quantity of genotypes displaying 4 to 13 variations in the sample. The diversity index (DI) ranged from 0.18 (ms21) to 0.86 (ms46); 8 locuses had DI > 0.5. The statistical processing showed 55 individual genotypes in a group of 81 examined strains, which denoted a high discriminative potentiality of the typing system (DP = 0.98). On the basis of the cluster analysis, the genotypes were shared between 11 main groups. The strains belonging to one genotype group were found to originate, as a rule, from one natural focus. The suggested scheme of typing and of creating the databases of genotypes of plaque agent can be used to establish, with a high probability degree, the source of strains.     

合肥地区动物源性大肠埃希菌的血清型分布与耐药性分析

目的了解安徽省合肥地区动物源性大肠埃希菌的血清型分布和耐药状况,以期筛选出菌苗株和指导临床合理用药。方法对46份疑似大肠埃希菌病病料进行细菌分离培养、生化编码鉴定和致病性测定。采用玻片凝集试验对分离到的46株致病性大肠埃希菌进行血清型鉴定。同时分别采用K-B纸片琼脂扩散法和双纸片增效法检测致病性大肠埃希菌的耐药性和ESBLs阳性菌株。结果46株致病性大肠埃希菌中,除7株细菌未能定型外,其余39株细菌分布于10个血清型,O127：K63血清型为优势血清型,占定型菌株的33．33％。46株致病性大肠埃希菌对21种抗菌药物均呈现不同程度的耐药性,15个ESBLs阳性菌株表现为多重耐药,对各种抗菌药物的耐药率均高于ESBLs阴性菌株。结论O127：K63血清型为优势血清型,可作为菌苗株。合肥地区动物源性大肠埃希菌耐药性较为严重,尤其是产ESBLs大肠埃希菌多重耐药更为突出。     

Use of multiple primers in RAPD analysis of clonal organisms provides limited improvement in discrimination.

Randomly amplified polymorphic DNA (RAPD) analysis using two or more primers has been reported to provide additional discriminatory ability over one primer used individually. This may be of particular application in epidemiological typing of clonal organisms, such as Shiga toxin-producing E. coli O157, where strain differentiation can be difficult. Using four arbitrary primers individually, and in all possible permutations, E. coli O157 isolates and other arbitrarily chosen E. coli strains were typed using RAPD analysis. For most nonclonal strains, the use of two primers resulted in increased differentiation between isolates; however, more than two primers did not increase further the discriminatory capacity. E. coli O157 isolates that produced virtually identical profiles using one primer did not show increased differentiation when using two or more primers, demonstrating that in some cases, where strains of an organism are highly related, there is limited advantage to using more than one primer in RAPD analysis.     

Ambivalent bacteriophages of different species active on Escherichia coli K12 and Salmonella sps. strains

A study was made of several bacteriophages (including phages U2 and LB related to T-even phages of Escherichia coli) that grow both on E. coli K12 and on some Salmonella strains. Such phages were termed ambivalent. T-even ambivalent phages (U2 and LB) are rare and have a limited number of hosts among Salmonella strains. U2 and LB are similar to canonical E. coli-specific T-even phages in morphological type and size of the phage particle and in reaction with specific anti-T4 serum. Phages U2 and LB have identical sets of structural proteins, some of which are similar in size to structural proteins of phages T2 and T4. DNA restriction patterns of phages U2 and LB differ from each other and from those of T2 and T4. Still, DNAs of all four phages have considerable homology. Unexpectedly, phages U2 and LB grown on Salmonella bungori were unstable during centrifugation in a CsCl gradient. Ambivalent bacteriophages were found in species other than T-even phages and were similar in morphotype to lambdoid and other E. coli phages. One of the ambivalent phages was highly similar to well-known Felix01, which is specific for Salmonella. Ambivalent phages can be used to develop a new set for phage typing in Salmonella. An obvious advantage is that ambivalent phages can be reproduced in the E. coli K12 laboratory strain, which does not produce active temperate phages. Consequently, the resulting typing phage preparation is devoid of an admixture of temperate phages, which are common in Salmonella. The presence of temperate phages in phage-typing preparations may cause false-positive results in identifying specific Salmonella strains isolated from the environment or salmonellosis patients. Ambivalent phages are potentially useful for phage therapy and prevention of salmonellosis in humans and animals.     

Genomic and SNP analyses demonstrate a distant separation of the hospital and community-associated clades of Enterococcus faecium

Recent studies have pointed to the existence of two subpopulations of Enterococcus faecium, one containing primarily commensal/community-associated (CA) strains and one that contains most clinical or hospital-associated (HA) strains, including those classified by multi-locus sequence typing (MLST) as belonging to the CC17 group. The HA subpopulation more frequently has IS16, pathogenicity island(s), and plasmids or genes associated with antibiotic resistance, colonization, and/or virulence. Supporting the two clades concept, we previously found a 3-10% difference between four genes from HA-clade strains vs. CA-clade strains, including 5% difference between pbp5-R of ampicillin-resistant, HA strains and pbp5-S of ampicillin-sensitive, CA strains. To further investigate the core genome of these subpopulations, we studied 100 genes from 21 E. faecium genome sequences; our analyses of concatenated sequences, SNPs, and individual genes all identified two distinct groups. With the concatenated sequence, HA-clade strains differed by 0-1% from one another while CA clade strains differed from each other by 0-1.1%, with 3.5-4.2% difference between the two clades. While many strains had a few genes that grouped in one clade with most of their genes in the other clade, one strain had 28% of its genes in the CA clade and 72% in the HA clade, consistent with the predicted role of recombination in the evolution of E. faecium. Using estimates for Escherichia coli, molecular clock calculations using sSNP analysis indicate that these two clades may have diverged ≥1 million years ago or, using the higher mutation rate for Bacillus anthracis, ～300,000 years ago. These data confirm the existence of two clades of E. faecium and show that the differences between the HA and CA clades occur at the core genomic level and long preceded the modern antibiotic era.     

Sample size, library composition, and genotypic diversity among natural populations of Escherichia coli from different animals influence accuracy of determining sources of fecal pollution

A horizontal, fluorophore-enhanced, repetitive extragenic palindromic-PCR (rep-PCR) DNA fingerprinting technique (HFERP) was developed and evaluated as a means to differentiate human from animal sources of Escherichia coli. Box A1R primers and PCR were used to generate 2,466 rep-PCR and 1,531 HFERP DNA fingerprints from E. coli strains isolated from fecal material from known human and 12 animal sources: dogs, cats, horses, deer, geese, ducks, chickens, turkeys, cows, pigs, goats, and sheep. HFERP DNA fingerprinting reduced within-gel grouping of DNA fingerprints and improved alignment of DNA fingerprints between gels, relative to that achieved using rep-PCR DNA fingerprinting. Jackknife analysis of the complete rep-PCR DNA fingerprint library, done using Pearson's product-moment correlation coefficient, indicated that animal and human isolates were assigned to the correct source groups with an 82.2% average rate of correct classification. However, when only unique isolates were examined, isolates from a single animal having a unique DNA fingerprint, Jackknife analysis showed that isolates were assigned to the correct source groups with a 60.5% average rate of correct classification. The percentages of correctly classified isolates were about 15 and 17% greater for rep-PCR and HFERP, respectively, when analyses were done using the curve-based Pearson's product-moment correlation coefficient, rather than the band-based Jaccard algorithm. Rarefaction analysis indicated that, despite the relatively large size of the known-source database, genetic diversity in E. coli was very great and is most likely accounting for our inability to correctly classify many environmental E. coli isolates. Our data indicate that removal of duplicate genotypes within DNA fingerprint libraries, increased database size, proper methods of statistical analysis, and correct alignment of band data within and between gels improve the accuracy of microbial source tracking methods.     

Statistical superiority of genome-probing microarrays as genomic DNA–DNA hybridization in revealing the bacterial phylogenetic relationship compared to conventional methods

The genomic DNA–DNA hybridization (DDH) method has been widely used as a practical method for the determination of phylogenetic relationships between closely related biological strains. Traditional DDH methods have serious limitations including low reproducibility, a high background and a time-consuming procedure. The DDH method using a genome-probing microarray (GPM) has been recently developed to complement conventional methods and could be used to overcome the limitations that are typically encountered. It is necessary to compare the GPM-based DDH method to the conventional methods before using the GPM for the estimation of genomic similarities since all of the previous scientific data have been entirely dependent on conventional DDH methods. In order to address this issue we compared the DDH values obtained using the GPM, microplate and nylon membrane methods to multi-locus sequence typing (MLST) data for 9 Salmonella genomes and an Escherichia coli type strain. The results showed that the genome similarity values and the degrees of standard deviation obtained using the GPM method were lower than those obtained with the microplate and nylon membrane methods. The dendrogram from the cluster analysis of GPM DDH values was consistent with the phylogenetic tree obtained from the multi-locus sequence typing (MLST) data but was not similar to those obtained using the microplate and nylon membrane methods. Although the signal intensity had to be maximal when the targets were hybridized to their own probe, the methods using membranes and microplates frequently produced higher signals in the heterologous hybridizations than those obtained in the homologous hybridizations. Only the GPM method produced the highest signal intensity in homologous hybridizations. These results show that the GPM method can be used to obtain results that are more accurate than those generated by the other methods tested.     

Bacteriophage Types and O Antigen Groups of Escherichia coli from Urine

Urinary strains of Escherichia coli from seven geographical regions were typed serologically for O-specific antigens and with phages capable of lysing the majority of urinary isolated. The O antigen groups 4, 6, 75, 1, 50, 7, and 25 were the common ones found. Of the 454 cultures tested, 66.1% were phage typable and 65.2% were serotypable with the 48 antisera employed. Also, 71.6% of the cultures for which an O group could be determined were phage typable. Furthermore, of those seven O-antigen groups implicated in urinary tract infection, 80.2% exhibited a phage pattern. Various phage types were found within an O-antigen group, and, although one phage type associated a high percentage of the time with one O-antigen group, no correlation was observed between other O-antigen groups and phage types. Studies with bacteriuric patients by phage typing showed the presence of two strains of E. coli within an O-antigen group. Serogrouping and phage typing of fecal isolates of E. coli revealed the presence of some O-antigen groups and phage types also found as predominant types among urinary isolates. Phage typability correlated highly with hemolysis of human erythrocytes. Elevated temperatures of incubation and a chemical curing agent were used to enhance typability of cultures refractory to the typing phages. Phage typing, due to its rapidity, ease, and ability to distinguish strains of E. coli within an O-antigenic group, is suggested as a possible method by which a better insight into the epidemiology of urinary tract infections may be obtained.     

An improved Escherichia coli donor strain for diparental mating

We present a new method for diparental mating with the outstanding advantage that counterselection of the Escherichia coli donor strain is not required. This improved method uses a new donor strain, E. coli ST18, a hemA deletion mutant defective in tetrapyrrole biosynthesis. The hemA mutation can be complemented by addition of 5-aminolevulinic acid. Therefore, counterselection is carried out only using standard media and growth conditions optimal for the recipient strain. Consequently, recipient strains are isolated in a significantly shorter period.     

Comparison of traditional and molecular typing methods of Escherichia coli O157

An account is given using typing methods and detection of virulence genes of different serotypes of Escherichia coli isolated in Hungary. By hybridization using SLT-I and SLT-II probes and PCR method using stx1-2, eae and ehx primers we could differentiate O157 strains of different serotypes into eight (stx, eae, ehxA positive; stx, eae positive; stx, ehxA positive; stx positive; eae, ehxA positive; eae positive; ehxA positive; stx, eae, ehxA negative) types. The discriminatory power of phage typing proves to be much higher than that of the plasmid profile. RAPD typing with different primers could confirm or exclude the subtypes identity of the isolated E. coli O157 serotypes. Escherichia coli O157:HNM isolates could be sorted in six different phage types and six different RAPD types with ERIC-1, in five RAPD types with ERIC-2 and in seven types with M13 primers. Escherichia coli O157:H7 showed six different phage types and three RAPD types with ERIC-1 and ERIC-2 and five types with M13 primers. According to our results the standard PFGE protocol [32] gives the opportunity to differentiate epidemiologically independent but evolutionary related or unrelated isolates, but the practical value of PFGE method for epidemiological purposes must be confirmed by other or more restriction enzymes or using an other protocol. Summarizing our results we suggest the use of phage and RAPD typing and in doubtful cases the PFGE method.