Clonal relationship among Vibrio parahaemolyticus isolated from Mediterranean mussels (Mytilus galloprovincialis) and grooved carpet shells (Ruditapes decussatus) harvested in Sardinia (Italy).

The aim of the present study was to investigate the genetic variability of Vibrio parahaemolyticus strains isolated from naturally contaminated Mediterranean mussels (Mytilus galloprovincialis) and Grooved carpet shells (Ruditapes decussatus) from three harvesting areas of Sardinia (Italy) using a combination of different typing methods: traditional phenotypic systems and molecular techniques. Ninety-nine putative V. parahaemolyticus strains isolated from shellfish collected before and after purification were included in the study. Seventy-two isolates were confirmed as V. parahaemolyticus and were submitted to REP, ERIC and BOX PCRs. The combined dendrogram showed the similarity of the data set of the three typing methods and demonstrates how the different techniques grouped the strains in two clusters in accordance with each singular dendrogram. Several strains rendered a unique pattern regardless of the typing method, which indicates the high discriminatory power of the methods. Moreover, the use of multiple typing methods allowed a more accurate characterization of the genetic profiles of isolates and the identification of clones hardly revealed through the common techniques. The intraspecific typing of environmental V. parahaemolyticus can be of great interest in order to recognize clonal relationships between environmental contamination, foodborne disease, and geographical/temporal distribution of this pathogen. The comparative analysis focusing on the obtained genetic profiles supports the possibility for typing methods to discriminate strains with similar phenotypic profile, identifying the level of genetic correlation among the strains and the presence of genetic clones.

Phylogeography of Yersinia ruckeri reveals effects of past evolutionary events on the current strain distribution and explains variations in the global transmission of enteric redmouth (ERM) disease.

Phylogeographic patterns and population genetic structure of Yersinia ruckeri, the pathological agent of enteric redmouth disease (ERM) in salmonids, were investigated on the basis of concatenated multiloci sequences from isolates of different phenotypes obtained between 1965 and 2009 from diverse areas and hosts. Sequence analyses revealed genetic differentiation among subpopulations with the largest genetic distance occurring between subpopulations of Europe and Canada and/or South America. Bayesian analysis indicated the presence of three ancestral population clusters. Mismatch distribution displayed signatures characteristic of changes in size due to demographic and spatial expansions in the overall Y. ruckeri population, and also in the geographically separate subpopulations. Furthermore, a weak signal of isolation by distance was determined. A significant positive correlation between genetic and geographical distances was observed. These results revealed that the population of Y. ruckeri has undergone both ancient and recent population changes that were probably induced by biogeography forces in the past and, much more recently, by adaptive processes forced by aquaculture expansion. These findings have important implications for future studies on Y. ruckeri population dynamics, on the potential role of genetic structure to explain variations in ERM transmission, and on the effect of past evolutionary events on current estimations of gene flow.

Disentangling the population structure and evolution of the clam pathogen Vibrio tapetis.

Vibrio tapetis is a fastidious slow-growing microorganism that causes the Brown Ring Disease in clams. Recently, two subspecies for this bacterial pathogen have been proposed. We have developed a multilocus sequence typing scheme and performed evolutionary studies of V. tapetis population using the great majority of isolates of V. tapetis obtained worldwide until now (30 isolates). V. tapetis constitutes a high polymorphic population, showing low diversity indexes and some genetic discontinuity among the isolates. Mutation events are more frequent than recombination, although both are approximately equally important for genetic diversification. In fact, the divergence between subspecies occurred exclusively by mutation but the diversity observed among isolates of the same subspecies appeared to be generated mostly by recombination. Between the subspecies, genetic distance is very high and almost no recurrent gene flow exists. This pathogen displays a non-clonal population structure with an ancient spatial segregation population and some degree of geographical isolation, followed by a population expansion, at least for V. tapetis subsp. tapetis. A database from this study was created and hosted on publmlst.org ( http://pubmlst.org/vtapetis/ ).

Highly sensitive detection and quantification of the pathogen Yersinia ruckeri in fish tissues by using real-time PCR.

Yersinia ruckeri is the causative agent of enteric redmouth diseases (ERM) and one of the major bacterial pathogens causing losses in salmonid aquaculture. Since recent ERM vaccine breakdowns have been described mostly attributed to emergence of Y. ruckeri biotype 2 strains, rapid, reproducible, and sensitive methods for detection are needed. In this study, a real-time polymerase chain reaction (PCR) primer/probe set based on recombination protein A (recA) gene was designed and optimized to improve the detection of Y. ruckeri. The primer/probe set proved to have a 100 % analytical specificity and a sensitivity of 1.8 ag µl(-1), equivalent to 1.7 colony-forming units (CFU) ml(-1), for purified DNA, 3.4 CFU g(-1) for seeded liver, kidney, and spleen tissues, and 0.34 CFU/100 µl(-1) for seeded blood, respectively. The assay was highly reproducible with low variation coefficient values for intra- and inter-run experiments (2.9 % and 9.5 %, respectively). Following optimization, the assay was used to detect changes in the bacterial load during experimental infection. Rainbow trout (Onchorhynchus mykiss) were exposed to two strains of Y. ruckeri (biotype 1 and biotype 2) by intraperitoneal inoculation. Internal organs (liver, kidney, spleen) and blood were biopsied from dead fish daily for 15 days to quantify copies of pathogen DNA per gram of tissue. The findings showed the efficacy of this real-time PCR assay to quantify Y. ruckeri cells in the fish tissues and also confirmed this assay as a non-lethal method for the detection of this pathogen in blood samples.

A polyphasic approach to study the intraspecific diversity of Yersinia ruckeri strains isolated from recent outbreaks in salmonid culture.

A polyphasic analysis was carried out on Yersinia ruckeri strains isolated from recently outbreaks in vaccinated fish using a combination of different phenotypic and molecular typing methods in order to study their variability and epidemiological relationships. Eighty strains were subjected to biotyping with conventional tests and API 20E system, serotyping, outer membrane protein (OMP) and lipopolysaccharide (LPS) profiling, and genetic fingerprinting by ERIC-PCR and REP-PCR techniques. The strains showed a high diversity, as evidenced by the formation of different phenotypic groups mainly related to the serotypes, LPS and OMP profiles. The diversity among all isolates, calculated as Simpson's diversity index (Di), varied between 0.35 (REP-PCR) and 0.70 (OMP). The most discriminative values (Di value ≥0.86) were obtained from any combination of three methods including biotype, serotype, API 20E profile, LPS or OMP. With the combination of all typing methods used a Di value of 0.90 was obtained. Association between different groups to the host species was evidenced. Furthermore, it seems that strains with similar characteristics are associated with recent outbreaks occurred in vaccinated fish in certain geographical areas. Our results emphasize the usefulness of using a combination of several different typing methods for epidemiological and bacterial diversity studies.

Multilocus sequence typing reveals high genetic diversity and epidemic population structure for the fish pathogen Yersinia ruckeri.

Yersinia ruckeri is the causative agent of enteric redmouth in fish and one of the major bacterial pathogens causing losses in salmonid aquaculture. Previously typing methods, including restriction enzyme analysis, pulsed-field gel electrophoresis and multilocus enzyme electrophoresis (MLEE) have indicated a clonal population structure. In this work, we describe a multilocus sequence typing (MLST) scheme for Y.ruckeri based on the internal fragment sequence of six housekeeping genes. This MLST scheme was applied to 103 Y.ruckeri strains from diverse geographic areas and hosts as well as environmental sources. Sequences obtained from this work were deposited and are available in a public database (http://publmst.org/yruckeri/). Thirty different sequence types (ST) were identified, 21 of which were represented by a single isolate, evidencing high genetic diversity. ST2 comprised more than one-third of the isolates and was most frequently observed among isolates from trout. Two major clonal complexes (CC) were identified by eBURST analysis showing a common evolutionary origin for 94 isolates forming 21 STs into CC1 and for 6 isolates of 6 STs in the CC2. It was also possible to associate some unique ST with isolates from recent outbreaks in vaccinated salmonid fish.

Effectiveness of bivalent vaccines against Aeromonas hydrophila and Lactococcus garvieae infections in rainbow trout Oncorhynchus mykiss (Walbaum).

Lactococcus garvieae and Aeromonas hydrophila are bacterial pathogens affecting salmonids and other fish species and cause of heavy losses in aquaculture. Diseases caused by these bacteria can be controlled satisfactory by immunization using monovalent vaccines. In this study, the protective efficacy of two bivalent vaccines against L. garvieae and A. hydrophila was evaluated in rainbow trout (Oncorhynchus mykiss). Bivalent formulations, containing formalin-inactivated bacteria, were prepared as an aqueous bacterin and as an adjuvanted vaccine using montanide ISA-763. Protection against L. garvieae and A. hydrophila was tested at day 30 and 90 post-vaccination. High levels of protection were achieved for the aqueous and adjuvanted bivalent vaccines against L. garvieae (RPS of 100% and 95.3%) and A. hydrophila (RPS of 100% and 95.3%) at day 30 post-vaccination. Significant differences (p < 0.05) were found between the RPS at days 30 and 90 post-immunization with a decrease in the protection levels for the aqueous bivalent vaccine against L. garvieae (RPS 76.2%) and A. hydrophila (RPS 85%), but not for the adjuvanted vaccine (RPS of 90% against L. garvieae and 95% against A. hydrophila). In addition, high antibody levels were observed in the vaccinated fish at day 15 post-immunization using both vaccines. Our results demonstrate that these bivalent vaccines can effectively protect rainbow trout against L. garvieae and A. hydrophila and could offer an appropriate strategy to prevent these infections in rainbow trout farms.