Differential detection of vibrios pathogenic to shrimp by multiplex PCR

The research was focused on the multiplex polymerase chain reaction (PCR) differential detection of shrimp pathogens Vibrio harveyi, Vibrio campbellii and isolates from a variant strain of Vibrio (referred to as Philippine Vibrio isolates in this study) exhibiting characteristics distinct from these two species. Sequence alignment of the hemolysin gene from type strains Vibrio harveyi (NBRC 15634) and Vibrio campbellii (NBRC 15631), as well as 10 variant Philippine Vibrio isolates, was performed in order to design a set of hemolysin-targeted primers for the specific detection of the Philippine Vibrio isolates. Primer PNhemo amplified a 320-bp hemolysin gene fragment of the Philippine Vibrio isolates in PCR using 65 degrees C annealing temperature, but did not amplify the target gene fragment in type strains V. harveyi and V. campbellii. Another new primer (VcatoxR) targeting the toxR gene was designed for the specific detection of type strain V. campbellii under stringent 65 degrees C annealing temperature. PCR using VcatoxR primer resulted in the specific amplification of a 245-bp V. campbellii toxR fragment. The simultaneous use of three primer sets in PCR, including PNhemo and VcatoxR (the two new primers designed in this study), and a primer VhtoxR (previously reported for the specific detection of V. harveyi), resulted in differential profiles with 390-bp, 245-bp, and 320-bp amplicons for V. harveyi, V. campbellii, and variant Philippine Vibrio isolates, respectively. Presence of all three types of Vibrio shrimp pathogens in the sample could be detected with a multiplex PCR profile containing all the expected size amplicons.     

Sequence analysis of partial toxR gene from Philippine Vibrio isolates and design of toxR-targeted primers for detection

Vibriosis in penaeid species cultured in the Philippines results in massive mortalities and consequently in severe economic losses in the shrimp industry. Rapid and accurate detection of the causative agent of the disease is imperative. In this study, toxR gene sequence analysis of ten Vibrio isolates (from several provinces of the Philippines) implicated in disease affecting the penaeid shrimp (Penaeus monodon) was performed in order to develop a toxR-targeted PCR detection of similar strains of shrimp pathogens. Analysis of the partial toxR gene revealed 97-100% sequence similarity among the ten Philippine Vibrio isolates. Distinct sequence variation of the toxR gene, however, was observed between the Philippine Vibrio isolates and the type strains, with the Philippine isolates exhibiting only 92-93% and 74-75% sequence similarity with the type strain V. campbellii (NBRC 15631T) and V. harveyi (NBRC 15634T), respectively. The use of a PCR primer set that was designed based on toxR sequences of the Philippine Vibrio isolates amplified the expected 226-bp toxR fragment using templates from all ten Philippine Vibrio isolates. No amplified product was observed in PCR using templates from type strains of V. harveyi, V. campbellii, and other non-target bacteria, suggesting that the primers were specific for the Philippine Vibrio isolates. The toxR-targeted PCR primers reported in this study could be useful in the detection of Philippine Vibrio isolates associated with mortalities in the shrimp industry, which could not be detected in PCR using primers designed for type strains of V. harveyi and V. campbellii.     

Amplification and sequence analysis of the full length toxR gene in Vibrio harveyi

This study was focused on obtaining the complete gene sequence of the toxR gene in V. harveyi by using toxR-targeted PCR to amplify 5' and 3' regions flanking the 576-bp Vibrio harveyi (NBRC 15634) toxR gene fragment previously amplified using degenerate PCR. To obtain the 5' flanking sequences, a forward PCR primer (VhtoxRpv) was designed based on known sequences upstream of toxR in V. parahaemolyticus and V. vulnificus. The reverse primer (VctoxR2R) was based on the sequence of the 576-bp Vibrio harveyi toxR fragment. The resulting 750-bp amplicon was sequenced, providing the 5' sequences of the V. harveyi (NBRC 15634) toxR gene. The 3' flanking region was amplified using a primer pair toxRS1 and toxRS2 based on V. parahaemolyticus and V. vulnificus toxR and toxS, resulting in a 900-bp amplicon that contained the remaining 3' sequences of the V. harveyi NBRC 15634 toxR. This paper reports, for the first time, a complete 882-bp nucleotide sequence for toxR in Vibrio harveyi. Sequence analysis and alignment revealed that the complete toxR gene in V. harveyi shares 87% sequence similarity with toxR of V. parahaemolyticus, 84% similarity with V. fluvialis, 83% with V. vulnificus and partial sequence of V. campbellii. The phylogenetic trees revealed wider divergence in toxR compared to 16S rRNA genes, so that V. harveyi could easily be distinguished from V. campbellii and V. parahaemolyticus.     

Analysis of gyrB and toxR gene sequences of Vibrio hollisae and development of gyrB- and toxR-targeted PCR methods for isolation of V. hollisae from the environment and its identification

Isolation of Vibrio hollisae strains, particularly from the environment, is rare. This may be due, in part, to the difficulty encountered when using conventional biochemical tests to identify the microorganism. In this study, we evaluated whether two particular genes may be useful for the identification of V. hollisae. The two genes are presumed to be conserved among the bacterial species (gyrB) or among the species of the genus Vibrio (toxR). A portion of the gyrB sequence of V. hollisae was cloned by PCR using a set of degenerate primers. The sequence showed 80% identity with the corresponding Vibrio parahaemolyticus gyrB sequence. The toxR gene of V. hollisae was cloned utilizing a htpG gene probe derived from the V. parahaemolyticus htpG gene, which is known to be linked to the toxR gene in V. hollisae. The coding sequence of the cloned V. hollisae toxR gene had 59% identity with the V. parahaemolyticus toxR coding sequence. The results of DNA colony hybridization tests using the DNA probes derived from the two genes of V. hollisae indicated that these gene sequences could be utilized for differentiation of V. hollisae from other Vibrio species and from microorganisms found in marine fish. PCR methods targeting the two gene sequences were established. Both PCR methods were shown to specifically detect the respective target sequences of V. hollisae but not other organisms. A strain of V. hollisae added at a concentration of 1 to 10(2) CFU/ml to alkaline peptone water containing a seafood sample could be detected by a 4-h enrichment incubation in alkaline peptone water at 37 degrees C followed by quick DNA extraction with an extraction kit and 35-cycle PCR specific for the V. hollisae toxR gene. We conclude that screening of seafood samples by this 35-cycle, V. hollisae toxR-specific PCR, followed by isolation on a differential medium and identification by the above htpG- and toxR-targeted PCR methods, can be useful for isolation from the environment and identification of V. hollisae.     

Comparison of different primers for rapid detection of Vibrio parahaemolyticus using the polymerase chain reaction

AIMS: The aim of this study was to compare different primers for rapid and effective detection of Vibrio parahaemolyticus by polymerase chain reaction (PCR). METHODS AND RESULTS: A total of four pairs of primers, three previously published and one based on a newly developed V. parahaemolyticus metalloprotease (vpm) gene, have been assayed for PCR detection of V. parahaemolyticus. They have been tested for specificity and sensitivity on a total of 101 strains including reference and environment isolates belonging to V. parahaemolyticus and other species in Vibrio. Of the four sets of primers tested, the one designed on the basis of the metalloprotease gene (675 bp) gave optimal results with bacterial strains examined as they only amplified the specific fragment in strains that had been genetically and biochemically assessed as V. parahaemolyticus and the limit of detection was 4 pg of purified target DNA. CONCLUSIONS: The primers designed on the metalloprotease gene gave optimal results for specific, sensitive and rapid detection of V. parahaemolyticus by PCR. SIGNIFICANCE AND IMPACT OF THE STUDY: PCR amplification with the optimal primer set VPM1/VPM2 could facilitate the rapid diagnosis and surveillance of potentially pathogenic strains of V. parahaemolyticus and reduce food-borne illness.     

PCR detection of hemolysin (vhh) gene in Vibrio harveyi

The Vibrio harveyi hemolysin gene (vhh), which encodes for a virulence factor involved in pathogenicity to fish and shellfish species, may be targeted for species detection or strain differentiation. Primers designed for this gene were used in detection studies of V. harveyi strains from various hosts. One primer set among four tested, could amplify the expected gene fragment in PCR using templates from all 11 V. harveyi strains studied. Detection of the presence of the hemolysin gene could therefore serve as a suitable detection marker of Vibrio harveyi isolates potentially pathogenic to fish and shrimps.     

Identification of vhhP2, a novel genetic marker of Vibrio harveyi, and its application in the quick detection of V. harveyi from animal specimens and environmental samples

Aims:  To investigate the species-specific prevalence of vhhP2 among Vibrio harveyi isolates and the applicability of vhhP2 in the specific detection of V. harveyi from crude samples of animal and environmental origins.
Methods and Results:  A gene ( vhhP2 ) encoding an outer membrane protein of unknown function was identified from a pathogenic V. harveyi isolate. vhhP2 is present in 24  V. harveyi strains isolated from different geographical locations but is absent in 24 strains representing 17 different non- V. harveyi species, including V. parahaemolyticus and V. alginolyticus . A simple polymerase chain reaction method for the identification of V. harveyi was developed based on the conserved sequence of vhhP2 . This method was demonstrated to be applicable to the quick detection of V. harveyi from crude animal specimens and environmental samples. The specificity of this method was tested by applying it to the examination of two strains of V. campbellii , which is most closely related to V. harveyi . One of the V. campbellii strains was falsely identified as V. harveyi .
Conclusions:  vhhP2 is ubiquitously present in the V. harveyi species and is absent in most of the non- V. harveyi species; this feature enables vhhP2 to serve as a genetic marker for the rapid identification of V. harveyi . However, this method can not distinguish some V. campbellii strains from V. harveyi .
Significance and Impact of the Study:  the significance of our study is the identification of a novel gene of V. harveyi and the development of a simple method for the relatively accurate detection of V. harveyi from animal specimens and environmental samples.     

A novel multiplex PCR for the identification of Vibrio parahaemolyticus, Vibrio cholerae and Vibrio vulnificus

AIM: To establish a simple multiplex polymerase chain reaction (PCR) that will identify Vibrio parahaemolyticus, Vibrio cholerae and Vibrio vulnificus. METHODS AND RESULTS: A total of 429 Vibrio spp. from various origins were tested with the novel primers targeting toxR. The reverse primers were all designed to be species specific, while the forward primer was universal. The primers correctly identified all the V. parahaemolyticus, V. cholerae and V. vulnificus isolates tested. CONCLUSIONS: The toxR multiplex PCR works well when the initial colony morphology is known. If not, Vibrio alginolyticus might represent a diagnostic obstacle. SIGNIFICANCE AND IMPACT OF THE STUDY: The method provides a fast and reliable way of identifying the main Vibrio spp. involved in food-borne disease. The method could prove very useful for laboratories working with identification of these Vibrio spp.     

Distribution of Vibrio cholerae virulence genes among different Vibrio species isolated in Sardinia, Italy

The members of the genus Vibrio include harmless aquatic strains as well as strains capable of causing epidemics of cholera. Diarrhoea caused by Vibrio cholerae is attributed to cholerae enterotoxin (CT) codified by the ctx operon and regulated by a number of virulence genes such as toxT, toxR and toxS. Fifty-two Vibrio strains were isolated from different aquatic environments in and around Sardinia and searched by PCR for the presence of ctxA, zot, ace, toxR, toxS, toxT, tcpA and vpi virulence genes in the genomes of the isolates. The toxR operon was found in 27 Vibrio alginolyticus strains out of 42 analysed, in three out of four V. cholerae non-O1 strains and in three Vibrio parahaemolyticus isolates. A positive amplification for the virulence pathogenic island (vpi) was produced by five V. alginolyticus strains. Finally, the ace expected amplification fragment was found in two V. alginolyticus isolates whereas the amplification with zot primers produced the expected fragment in one V. alginolyticus isolate. Differentiation of these strains with a PCR fingerprinting technique revealed no association between the presence of virulence genes and a particular fingerprinting pattern. Although most Vibrio species are considered non-pathogenic or only potentially harmful to humans, the finding of V. cholerae virulence genes in other members of the genus Vibrio, and the recent reports of the creation and evolution of pandemic strains of V. cholerae, may give a new perspective to the significance of these results.     

Occurrence of pathogenic vibrios in coastal areas of France

AIMS: This study was carried out to investigate the occurrence of potentially pathogenic species of Vibrio in French marine and estuarine environments. METHODS AND RESULTS: Samples of coastal waters and mussels collected between July and September 1999 were analysed by culture, using selective media including thiosulphate-citrate-bile salts-sucrose and modified cellobiose-polymixin B-colistin agar. Presumptive Vibrio colonies were isolated and identified using selected biochemical tests. Specific primers based on flanking sequences of the cytolysin, vvhA gene, pR72H DNA fragment and 16S-23S rRNA intergenic spacer region (ISR) were used in a polymerase chain reaction (PCR) to confirm the identification of Vibrio vulnificus, V. parahaemolyticus and V. cholerae, respectively. In this study, V. alginolyticus (99 of 189) was the predominant species, followed by V. parahaemolyticus (41 of 189), V. vulnificus (20 of 189) and non-O1/non-O139 V. cholerae (three of 189). All 20 V. vulnificus isolates showed PCR amplification of the vvhA gene, 16 of which had been isolated from estuarine water. The PCR amplification of the pR72H DNA fragment in 41 V. parahaemolyticus isolates generated two unique amplicons of 387 and 320 bp. The latter, present in 24.4% of these isolates, had not previously been found in V. parahaemolyticus strains examined to date. Amplification of the trh gene in two of the isolates suggested these to be virulent strains. Three strains identified as V. cholerae by amplification of the 16S-23S rRNA ISR were confirmed to be non-cholera (non-O1/non-O139) strains. CONCLUSIONS: The results of this study demonstrated the presence of pathogenic Vibrio species in French coastal waters. Furthermore, the PCR approach proved useful for the rapid and reliable confirmation of species identification. SIGNIFICANCE AND IMPACT OF THE STUDY: These findings indicate the potential sanitary risk associated with the presence of pathogenic Vibrio spp. in cultivated mussels and in the aquatic environment. The PCR can be used to detect pathogenic vibrios directly in environmental samples.     

The ability of two different Vibrio spp. bacteriophages to infect Vibrio harveyi, Vibrio cholerae and Vibrio mimicus

AIMS: To determine the host range of the Vibrio harveyi myovirus-like bacteriophage (VHML) and the cholera toxin conversion bacteriophage (CTX Phi) within a range of Vibrio cholerae and V. mimicus and V. harveyi, V. cholerae and V. mimicus isolates respectively. METHODS AND RESULTS: Three V. harveyi, eight V. cholerae and five V. mimicus isolates were incubated with VHML and CTX Phi. Polymerase chain reaction (PCR) was used to determine the presence of VHML and CTX Phi in infected isolates. We demonstrated that it was possible to infect one isolate of V. cholerae (isolate ACM #2773/ATCC #14035) with VHML. This isolate successfully incorporated VHML into its genome as evident by positive PCR amplification of the sequence coding part of the tail sheath of VHML. Attempts to infect all other V. cholerae and V. mimicus isolates with VHML were unsuccessful. Attempts to infect V. cholerae non-01, V. harveyi and V. mimicus isolates with CTX Phi were unsuccessful. CONCLUSIONS: Bacteriophage infection is limited by bacteriophage-exclusion systems operating within bacterial strains and these systems appear to be highly selective. One system may allow the co-existence of one bacteriophage while excluding another. VHML appears to have a narrow host range which may be related to a common receptor protein in such strains. The lack of the vibrio pathogenicity island bacteriophage (VPI Phi) in the isolates used in this study may explain why infections with CTX Phi were unsuccessful. SIGNIFICANCE AND IMPACT OF THE STUDY: The current study has demonstrated that Vibrio spp. bacteriophages may infect other Vibrio spp.     

Changes to the phenotypic profile of Vibrio harveyi when infected with the Vibrio harveyi myovirus-like (VHML) bacteriophage

AIMS: To determine if infection of Vibrio harveyi with the V. harveyi myovirus-like (VHML) bacteriophage causes a change to the phenotypic profile of this species. METHODS AND RESULTS: Using 46 biochemical and metabolic tests, phenotypic profiles for noninfected V. harveyi and VHML infected V. harveyi were developed. Comparison of the infected and bacteriophage-infected strains of V. harveyi 645, 20 and 45 were found to have different test results for d-gluconate utilization, gamma-glutamyl transpeptidase and sulfatase activity, respectively. Using probabilistic identification, VHML infected and noninfected strains were identified as V. harveyi and had similar Willcox probability scores though the modal likelihood scores were reduced for VHML infected strains. One VHML infected strain, 642b, was misidentified as V. campbellii by phenotyping but not by PCR. It would appear that the phenotype of V. harveyi strains infected with VHML, are sufficiently altered that they occur at the margins of the known range of strain variation for V. harveyi. CONCLUSION: Infection of V. harveyi with VHML causes the phenotypic profile of the bacterium to change. This change reduces the modal likelihood score resulting in a poorer level of assurance for an identification of V. harveyi, especially in the natural host, strain 642. The bacteriophage VHML integrates into different sites in different strains of V. harveyi. SIGNIFICANCE AND IMPACT OF THE STUDY: The identification of V. harveyi as the causative agent of mortality in aquatic organisms is predominantly achieved through phenotyping. Since bacteriophages alter virulence in V. harveyi, understanding the effect they have on phenotype is important.     

Detection of virulence associated genes in clinical strains of vibrio mimicus

A total of 42 clinical strains of Vibrio mimicus were examined for the presence of virulence associated genes toxR, toxS, toxT, tcpP, ctx and tcpA by PCR assay. Almost all strains were shown to have the toxR gene, while the toxS gene was found in 27 strains. On the other hand, five strains possessed both toxT and tcpP genes, but others had neither. Only two strains were positive for amplification of the ctx gene, whereas no PCR product with tcpA primers was detected. The results indicate the incomplete copies of virulence cascade in V mimicus strains. The pathogenesis and epidemic potential of this species is also discussed.     

Development of a SYBR Green I real-time PCR for quantitative detection of Vibrio alginolyticus in seawater and seafood

AIM: Vibrio alginolyticus is an economically important micro-organism. The main aim of the present study was to develop a real-time polymerase chain reaction (PCR) assay for rapid, sensitive and effective quantification of V. alginolyticus in seawater and seafood. METHODS AND RESULTS: Purified DNA of V. alginolyticus, artificially inoculated seawater and seafood tissue homogenates were subjected to the gyrB-targeted real-time PCR assay. Natural seawater and seafood samples were analysed by this real-time PCR protocol. Specificity tests showed that positive result was obtained only with V. alginolyticus strains. The detection sensitivity was determined to be 0.4 pg of genomic DNA equivalent to 72 cells per PCR in pure culture and 100 cells in 1 ml of seawater or seafood tissue homogenates. Single cell detection is achieved after 3 h of sample enrichment. CONCLUSIONS: A sensitive and specific SYBR Green I-based real-time PCR assay targeting gyrB gene was successfully developed to quantify V. alginolyticus within 6 h in seawater and seafood samples. SIGNIFICANCE AND IMPACT OF THE STUDY: No report on the molecular-based method was available for quantitative detection of V. alginolyticus. This work will provide a novel method for evaluation of the risk of V. alginolyticus to marine environmental health and seafood safety.     

Identification of intestinal bacteria from Japanese flounder (Paralichthys olivaceus) and their ability to digest chitin

AIMS: The aim of the present study was to clarify the taxonomic status of intestinal bacteria isolated from Japanese flounder (Paralichthys olivaceus) and describe their ability to digest chitin. METHODS AND RESULTS: Phylogenetic analysis based on 16S ribosomal DNA (rDNA) sequences showed that 82 representative isolates were closely related to three major species of marine vibrios, Vibrio scophthalmi-Vibrio ichthyoenteri group (41 isolates), Vibrio fischeri (39 isolates) and Vibrio harveyi (two isolates), with similarities of 97.2-99.8%, 96.4-100% and 98.6-99.5% respectively. These findings indicate that V. scophthalmi-V. ichthyoenteri group is indigenous to the intestinal tract of Japanese flounder. Moreover, the ability of 82 isolates to digest chitin was examined using the agar plate method and PCR amplification of the chiA gene. The two V. harveyi isolates and 36 of 41 V. scophthalmi-V. ichthyoenteri isolates digested chitin and were chiA PCR positive, whereas all 39 V. fischeri isolates digested chitin but were chiA PCR negative. CONCLUSIONS: Intestinal bacteria from Japanese flounder were mainly composed of Vibrio scophthalmi-V. ichthyoenteri group and V. fischeri. Taken together, the results showed that 81 of 82 isolates could digest chitin. However, only 38 of these isolates possessed a chiA homologue which could be identified by PCR. SIGNIFICANCE AND IMPACT OF THE STUDY: The present study shows that Japanese flounder harbours bacteria of the V. scophthalmi-V. ichthyoenteri group, and these results are similar to what has been found for turbot (Scophthalmus maximus).     

Rapid detection of Vibrio vulnificus in shellfish and Gulf of Mexico water by real-time PCR

In this paper we describe optimization of SYBR Green I-based real-time PCR parameters and testing of a large number of microbial species with vvh-specific oligonucleotide primers to establish a rapid, specific, and sensitive method for detection of Vibrio vulnificus in oyster tissue homogenate and Gulf of Mexico water (gulf water). Selected oligonucleotide primers for the vvh gene were tested for PCR amplification of a 205-bp DNA fragment with a melting temperature of approximately 87 degrees C for 84 clinical and environmental strains of V. vulnificus. No amplification was observed with other vibrios or nonvibrio strains with these primers. The minimum level of detection by the real-time PCR method was 1 pg of purified genomic DNA or 10(2) V. vulnificus cells in 1 g of unenriched oyster tissue homogenate or 10 ml of gulf water. It was possible to improve the level of detection to one V. vulnificus cell in samples that were enriched for 5 h. The standard curves prepared from the real-time PCR cycle threshold values revealed that there was a strong correlation between the number of cells in unenriched samples and the number of cells in enriched samples. Detection of a single cell of V. vulnificus in 1 g of enriched oyster tissue homogenate is in compliance with the recent Interstate Shellfish Sanitation Conference guidelines. The entire detection method, including sample processing, enrichment, and real-time PCR amplification, was completed within 8 h, making it a rapid single-day assay. Rapid and sensitive detection of V. vulnificus would ensure a steady supply of postharvest treated oysters to consumers, which should help decrease the number of illnesses or outbreaks caused by this pathogen.     

The use of PCR to aid in the rapid identification of Vibrio harveyi isolates

AIMS: Vibrio harveyi is an important pathogen, causing potential devastation to marine aquaculture. This organism, however, is extremely difficult to identify because it is phenotypically diverse. Biochemical identification can involve many tests and take weeks to perform. The aim of this work is to develop a PCR that can reduce the number of biochemical tests, and the time taken, to get a definitive identification of this organism. METHODS AND RESULTS: The PCR was developed using 16S rDNA sequences from a number of V. harveyi strains, and other vibrios. The described test gave positive results for all strains of V. harveyi tested. However, some strains of V. alginolyticus also gave positive results and a small number of biochemical tests were required to differentiate between these two species. This indicated that preisolation of the bacteria was needed and therefore the test was not applicable to the testing of mixed populations directly. CONCLUSION, SIGNIFICANCE AND IMPACT OF THE STUDY: The duration of identification of this species was significantly reduced from a number of weeks to a few days. Hence, diagnosis of affected animals will be faster and earlier treatment can be administered which may increase the survival rate from vibriosis.     

Development of a quantitative real-time polymerase chain reaction targeted to the toxR for detection of Vibrio vulnificus

The TaqMan assay, a quantitative real-time polymerase chain reaction (PCR), was developed to target the ToxR gene (toxR) of Vibrio vulnificus. The toxR of V. vulnificus was cloned and sequenced. Based on these results, we designed specific primers and a probe for use in the quantitative PCR assay. Twenty-nine strains of V. vulnificus that were obtained from various sources produced a single PCR product. The amount of final amplification product and threshold cycle number were the same among the strains. We used the method to detect V. vulnificus in seawater and oyster samples. We developed standard curves to quantitate V. vulnificus numbers using the PCR from seawater and oyster samples. The standard curves were not different from that of the pure culture of V. vulnificus. We found the assay was very sensitive detecting as few as 10 microbes per milliliter of seawater and oyster homogenate. Moreover, we evaluated the TaqMan assay to detect V. vulnificus in seawater samples. The numbers of V. vulnificus counted by the TaqMan assay were similar to those by a culture method in almost samples. The TaqMan assay was performed within 2 h compared to days using the culture method. The results indicate the TaqMan assay method used in this study was rapid, effective and quantitative for monitoring V. vulnificus contamination in seawater and seafoods such as oysters.