Extended phage locus typing of Salmonella enterica serovar Typhimurium, using multiplex PCR-based reverse line blot hybridization (original) (raw)
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Eurosurveillance: bulletin europeen sur les maladies transmissibles = European communicable disease bulletin
Phage typing has for decades been useful as a phenotypical, definitive method for epidemiological characterisation of Salmonella Typhimurium. The system recommended by the World Health Organization (WHO) Collaborative Centre for phage typing of Salmonella has, however, become rather complex, and the present study illustrates the challenges of sufficient standardisation of the interpretation of lysis results to make sure that the same strain is assigned to the same phage type in different laboratories. Even though molecular typing methods will replace phenotypic characterisation methods in the future, it is our opinion that phage typing will remain for some time a useful tool to strengthen global Salmonella surveillance. Therefore, improved standardisation and quality assurance is essential to obtain a robust and harmonized method that allows comparison of results between laboratories.
Journal of Clinical Microbiology, 2003
Seventy-eight human and environmental strains of Salmonella enterica subsp. enterica serovar Typhimurium, as well as 18 isolates of other Salmonella serovars and 6 isolates of Escherichia coli, were subjected to a novel variable number of tandem repeats (VNTR)-based fingerprinting method that showed high discrimination and reproducibility for typing serovar Typhimurium isolates. The method is based on capillary separation of PCR products from fluorescence-labeled VNTR in the serovar Typhimurium genome. The serovar Typhimurium isolates displayed 54 VNTR patterns, and the VNTR assay correctly identified strains from a well-characterized outbreak. Among 37 serovar Typhimurium phage type DT104 isolates, 28 distinct VNTR patterns were found. This VNTR-based method is fast and suitable for complete automation. Our VNTR-based method was capable of high discrimination within the homogeneous serovar Typhimurium DT104 phage type and can be used to trace outbreaks and to monitor DT104 as well as other phage types. The VNTR assay was compared to XbaI pulsed-field gel electrophoresis, amplified fragment length polymorphism analysis, integron-cassette profiles and gene PCR of intI1, qacE⌬1, sulI1, and floR. The VNTR assay showed greatly improved resolution compared to all other tested methods in this study.
Journal of Microbiological Methods, 2012
In this study we developed a preliminary proof of concept of method for Salmonella typhimurium subtyping using multiplex PCR-based phage locus typing and a multiplex Luminex DNA suspension array for product detection. Thirty markers were selected from prophages ST64B, ST64T, ST104, P22, Gifsy-1, sopEΦ and mostly phage-related AFLP fragments, and organised into two multiplex PCRs of 15 markers each. A two-group DNA suspension array was developed using a combination of flow cytometry and Luminex xMAP® technology. To assess its subtyping capability the method was applied to 438 non-epidemiological related S. typhimurium isolates of 56 phage types. Eighty-one profiles were generated. Isolates were divided into sixteen main prophage marker profile types. There was a strong tendency for isolates with the same phage type to have the same or closely related profiles and for groups of phage types to share the same profile. The discriminatory power of this method expressed as the Simpson's Index of Diversity (D) was 0.954. A panel of 12 selected markers achieved almost the same D value (0.952) as the 30 markers. This new method provides an alternative typing scheme for S. typhimurium epidemiological investigations. The developed array is in a high-throughput format which could easily be semi-automated, making the test fast and economical.
Scientific Reports, 2023
The Anderson phage typing scheme has been successfully used worldwide for epidemiological surveillance of Salmonella enterica serovar Typhimurium. Although the scheme is being replaced by whole genome sequence subtyping methods, it can provide a valuable model system for study of phage-host interaction. The phage typing scheme distinguishes more than 300 definitive types of Salmonella Typhimurium based on their patterns of lysis to a unique collection of 30 specific Salmonella phages. In this study, we sequenced the genomes of 28 Anderson typing phages of Salmonella Typhimurium to begin to characterize the genetic determinants that are responsible for the differences in these phage type profiles. Genomic analysis of typing phages reveals that Anderson phages can be classified into three different groups, the P22-like, ES18-like and SETP3-like clusters. Most Anderson phages are short tailed P22-like viruses (genus Lederbergvirus); but phages STMP8 and STMP18 are very closely related to the lambdoid long tailed phage ES18, and phages STMP12 and STMP13 are related to the long noncontractile tailed, virulent phage SETP3. Most of these typing phages have complex genome relationships, but interestingly, two phage pairs STMP5 and STMP16 as well as STMP12 and STMP13 differ by a single nucleotide. The former affects a P22-like protein involved in DNA passage through the periplasm during its injection, and the latter affects a gene whose function is unknown. Using the Anderson phage typing scheme would provide insights into phage biology and the development of phage therapy for the treatment of antibiotic resistant bacterial infections. Foodborne salmonellosis is an important concern for public health. It is caused by the enteric pathogen Salmonella enterica, which includes more than 2600 serovars. Although non-typhoidal Salmonella (NTS) serovars such as Typhimurium, Enteritidis and Dublin are predominantly associated with a self-limiting gastrointestinal illness, they have adapted to cause invasive diseases 1,2. Human infection by invasive non-typhoidal Salmonella (iNTS) can result in serious systemic illnesses, bacteremia and focal systemic infections 3,4. There is no licensed human vaccine against iNTS serovars; moreover, management of iNTS illness is complicated by the emergence of multidrug resistant strains 5. Human outbreaks of NTS have been reported in several countries around the world including high-income countries 6-8. It is therefore crucial to use accurate, reliable, and highly discriminative subtyping methods for NTS epidemiological characterisation and outbreak investigation. The Anderson phage typing scheme has been used worldwide for epidemiological surveillance of Salmonella enterica serovar Typhimurium (hereafter called Salmonella Typhimurium) 9. However, this scheme is dependent on original Anderson stocks which will not last forever, and it is being replaced by the whole genome sequencing (WGS)
Journal of Medical Microbiology, 1992
The Phene Plate (PhP) system of biochemical fingerprinting of bacteria is a computerised typing system, based on quantitative measurements of the kinetics of several biochemical reactions of bacteria grown in liquid medium in microtitration plates. For each isolate tested, it yields a biochemical fingerprint comprising several kinds of quantitative data which are useful for establishing similarities among strains with a personal-computer program. In this study, a set of 16 specific substrates was chosen to differentiate strains of Salmonella of serotype Typhimurium. The system was evaluated for its typability, reproducibility and discriminatory power in tests with a collection of 100 epidemiologically unrelated Typhimurium strains and results were compared with those obtained by phage typing. At an identity level of 0.980, strains were assigned by this method to 51 biochemical phenotypes (BPTs), giving a diversity index of 0.963 and a resolution index of 0.210. In contrast, 24 phage types (PTs) were identified among these isolates (a diversity index of 0.901). The combined use of biochemical fingerprinting by the PhP system and phage typing discriminated 82 phenotypes (a diversity index of 0.994). Stability of markers in each of the methods was also evaluated after subculture of 20 strains for 21 consecutive days. Only nine biochemical reactions were found that were subject to small, but measurable, changes for at least one isolate. These changes slightly decreased the mean similarity coefficients among strains but the overall BPTs of the strains showed changes in four strains (20 %). In contrast, eight strains (40 %) showed changes in their PTs after this treatment. It is concluded that the PhP system is a highly discriminatory and reproducible method for typing Typhimurium strains. It is easy to perform, and may be used alone or in combination with phage typing in epidemiological studies of Typhimurium strains.
Brazilian Journal of Microbiology, 2007
Salmonella Typhimurium has become a widespread cause of salmonellosis among humans and animals worldwide. In Brazil, Salmonella Typhimurium (STM) is one of the most prevalent serovars isolated from food for human consumption. The uncontrolled sale and use of antimicrobials in agriculture and for treating human patients contributes to increase multidrug resistance of this serovar. In the present study, a total of 278 STM isolates from different sources and regions of Brazil over the period 1999 to 2004 were phage typed and analyzed for their antimicrobial resistance profile at Laboratory of Enterobacteria, Oswaldo Cruz Institute, FIOCRUZ. The main STM phage types isolated were DT 193 (64.3%), DT 19 (17.4%) and DT 18 (4%). Others phage types as DT 10 (2%), DT 27 (3.24%), DT 13 (0.36%), DT 22 (0.36%), DT 28 (0.36%), DT 29 (0.36%) and DT 149 (0.36%) were obtained in low percentages. A total of 54% STM strains were resistant to three or more antimicrobial classes, while no resistance to third generation cephalosporin or ciprofloxacin was identified in these strains. Those results show the STM phage types circulating among animals, food for human consumption and humans in Brazil as well as the increasing of multidrug resistance. The surveillance of STM strains based on phage typing and antimicrobial resistance profile are useful for detecting outbreaks, identifying sources of infection and implementing prevention and control measures.