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

Comparison of pulsed-field gel electrophoresis and a novel amplified intergenic locus polymorphism method for molecular typing of Campylobacter jejuni

Campylobacter is regarded as the leading cause of zoonotic diseases and Campylobacter jejuni (C. jejuni) is one of the predominant pathogenic species. To track C. jejuni infections, various genotyping methods have been used. In this study, amplified intergenic locus polymorphism (AILP) was used to type C. jejuni for the first time. To confirm its feasibility, pulsed-field gel electrophoresis (PFGE) was performed as a control, and the results obtained by the AILP and PFGE methods were compared. Fifty-one isolates were resolved into 34 and 29 different genotypes with Simpson's indices of 0.976 and 0.967 using the AILP and PFGE methods, respectively. The adjusted Rand coefficient of the two approaches was as high as 0.845. In summary, the data showed that the two genotyping methods were similar for discriminating isolates and were both appropriate methods to distinguish whether two isolates were indistinguishable, but the AILP was faster and less costly than PFGE. Therefore, the AILP is a reliable, rapid, and highly discriminative method to genotype C. jejuni collected from poultry meat, which is helpful to effectively monitor C. jejuni.

Subtyping of Campylobacter coli isolated from raw poultry meat in retail markets using amplified intergenic locus polymorphism - A novel rapid subtyping method

In order to provide more phylogenetic information of Campylobacter coli in large-scale epidemiological investigation, this work was undertaken to develop a novel genotyping method based on amplified intergenic locus polymorphism (AILP), by using pulsed-field gel electrophoresis (PFGE; using SmaI enzymes) as control. Eleven pairs of primers were selected to type C. coli strains for this purpose. A total of 68 C. coli isolates recovered from 51 retail raw chicken and 37 retail raw duck were subtyped. The Simpson's index of diversity (SID) of AILP and PFGE, as well as the adjusted Rand index (AR) and the adjusted Wallace coefficient (AW) between AILP and PFGE, were calculated. The new AILP method differentiated 68 C. coli isolates into 55 different subtypes (SID = 0.993), compared with 46 different profiles obtained from PFGE (SID = 0.980). The SID value of the AILP method was improved with the increasing number of primers, and a combination of 7 loci was selected as the optimal combination. The congruent analysis of the AILP method and PFGE showed moderate congruence between the two methods (AR = 0.462). The AW indicated that if AILP data is the available one can confidently predict the PFGE cluster. The results of this study showed that the AILP method had higher discrimination than PFGE and also allowed for significant reduction in time and cost.

Diversity, transmission and persistence of Escherichia coli in a cohort of mothers and their infants

Despite that Escherichia coli is one of the most important bacteria in early infant colonization and immune modulation, we have limited knowledge about diversity, transmission and persistence within human populations for this bacterium. Here we have utilized a novel, growth-independent, direct typing approach to describe E. coli mother-to-child transmission and persistence within infants in a well-defined cohort of 86 mothers and their infants in Norway. Seven gene multilocus sequence typing of 28 study isolates, three probiotic strains, eight Norwegian pathogenic isolates and the ECOR strain collection added a phylogenetic framework to the direct sequencing data. We found that a type B2 subpopulation of the maternal E. coli strains was the main group transmitted to the infants and that the proportion of children carrying their mothers' strain decreased as the children age. Using species richness estimates we also found a limited number of strains within the cohort compared with total E. coli diversity, constraints on infant colonization, and that infant strain diversity levels increased towards maternal diversity levels over time. This knowledge about inheritance and diversity forms a foundation for future understanding of E. coli in human health and disease.

Rapid determination of multi-locus sequence types of Listeria monocytogenes by microtemperature-gradient gel electrophoresis

This report presents a new method for identifying multi-locus sequence types of Listeria monocytogenes by microtemperature-gradient gel electrophoresis (mu-TGGE). Genomic comparison of L. monocytogenes serovar 1/2a strains EGD-e and F6854 allowed selection of novel polymorphic sequences lmo0386 and lmo0428 as optimum regions for mu-TGGE analysis, in addition to the previously identified lmo0297 gene. Sequence analysis of a total of 48 standard strains revealed that the strains could be grouped into 7 (lmo0386), 8 (lmo0428) and 12 (lmo0297) sequence types. The PCR products from 2, 4 and 4 sequence types of the lmo0386, lmo0428 and lmo0297 genes were selected as marker alleles, and mu-TGGE analysis of the mixture revealed adequate band separation on a single gel. Furthermore, the primer sets could be successfully mixed in a single tube for multiplex PCR, yielding a rapid and easy strategy for sequence type identification. For practical application, multiplex PCR was performed with Cy3-labeled primers against a sequence type-unknown sample isolated from meat. The resulting products were mixed with Cy5-labeled products of marker alleles whose sequence types were known, and mu-TGGE analysis was performed. Overlapping Cy3 and Cy5 patterns allowed identification of the sequence types at all 3 loci on a single gel. Moreover, the mu-TGGE analysis step took only 9 min. Thus, this novel method of multiplex PCR followed by mu-TGGE analysis could prove useful as a rapid and discriminative tool for tracing the strain types, contamination routes and sources of L. monocytogenes.

Vibrio vulnificus typing based on simple sequence repeats: insights into the biotype 3 group

Vibrio vulnificus is an opportunistic, highly invasive human pathogen with worldwide distribution. V. vulnificus strains are commonly divided into three biochemical groups (biotypes), most members of which are pathogenic. Simple sequence repeats (SSR) provide a source of high-level genomic polymorphism used in bacterial typing. Here, we describe the use of variations in mutable SSR loci for accurate and rapid genotyping of V. vulnificus. An in silico screen of the genomes of two V. vulnificus strains revealed thousands of SSR tracts. Twelve SSR with core motifs longer than 5 bp in a panel of 32 characterized and 56 other V. vulnificus isolates, including both clinical and environmental isolates from all three biotypes, were tested for polymorphism. All tested SSR were polymorphic, and diversity indices ranged from 0.17 to 0.90, allowing a high degree of discrimination among isolates (27 of 32 characterized isolates). Genetic analysis of the SSR data resulted in the clear distinction of isolates that belong to the highly virulent biotype 3 group. Despite the clonal nature of this new group, SSR analysis demonstrated high-level discriminatory power within the biotype 3 group, as opposed to other molecular methods that failed to differentiate these isolates. Thus, SSR are suitable for rapid typing and classification of V. vulnificus strains by high-throughput capillary electrophoresis methods. SSR (>/=5 bp) by their nature enable the identification of variations occurring on a small scale and, therefore, may provide new insights into the newly emerged biotype 3 group of V. vulnificus and may be used as an efficient tool in epidemiological studies.

Vibrio cholerae strain typing and phylogeny study based on simple sequence repeats

Vibrio cholerae is the etiological agent of cholera. Its natural reservoir is the aquatic environment. To date, practical typing of V. cholerae is mainly serological and requires about 200 antisera. Simple sequence repeats (SSR), also termed VNTR (for variable number of tandem repeats), provide a source of high genomic polymorphism used in bacterial typing. Here we describe an SSR-based typing method that combines the variation in highly mutable SSR loci, with that of shorter, relatively more stable mononucleotide repeat (MNR) loci, for accurate and rapid typing of V. cholerae. In silico screening of the V. cholerae genome revealed thousands of perfect SSR tracts with an average frequency of one SSR every 152 bp. A panel of 32 V. cholerae strains, representing both clinical and environmental isolates, was tested for polymorphism in SSR loci. Two strategies were applied to identify SSR variation: polymorphism of SSR tracts longer than 12 bp (L-SSR) assessed by capillary fragment-size analysis and MNR polymorphism assessed by sequencing. The nine L-SSR loci tested were all polymorphic, displaying 2 to 13 alleles per locus. Sequence analysis of eight MNR-containing loci (MNR-multilocus sequence typing [MLST]) provided information on both variations in the MNR tract itself, and single nucleotide polymorphism (SNP) in their flanking sequences. Phylogenetic analysis of the combined SSR data showed a clear discrimination between the clinical strains belonging to O1 and O139 serogroups, and the environmental isolates. Furthermore, discrimination between 27 strains of the 32 strains was achieved. SSR-based typing methods combining L-SSR and MNR-MLST were found to be efficient for V. cholerae typing.

Rapid discrimination of Listeria monocytogenes strains by microtemperature gradient gel electrophoresis

Microtemperature gradient gel electrophoresis (mu-TGGE) was examined for use for the rapid subtyping of Listeria monocytogenes strains. Comparison of genomes between L. monocytogenes strains F2365 and H7858 identified a sequence encoding a portion of the PRT/PTS system IIA 2 protein domain as appropriate for mu-TGGE analysis. Thirty-one strains belonging to 10 different serovar types were tested by PCR, and sequence analysis of the amplified products revealed that the strains comprise 11 groups. All 55 possible pairs within the 11 groups were examined by mu-TGGE analysis. Of these, 47 pairs could be successfully discriminated, with a total electrophoresis time of only 7 min. Moreover, Cy3/Cy5 labeling allowed rapid identification of the sequence type in unknown strains of L. monocytogenes isolated from meat. These findings collectively indicate that mu-TGGE can be used for the rapid analysis of L. monocytogenes strains, facilitating determination of routes of contamination when these bacteria are found in food products.