Rapid detection and enumeration of trh-carrying Vibrio parahaemolyticus with the alkaline phosphatase-labelled oligonucleotide probe

An alkaline phosphatase (AP)-labelled oligonucleotide probe was developed to detect and enumerate trh(+)Vibrio parahaemolyticus in seafood. The probe was evaluated using 40 isolates of V. parahaemolyticus, 45 isolates of other vibrios and 55 non-vibrio isolates. The probe reacted specifically with V. parahaemolyticus possessing either the trh1 or trh2 variant of the trh gene and was found to be 100% specific for trh(+)V. parahaemolyticus. Using the trh probe, V. parahaemolyticus carrying trh gene was targeted in 34 seafood samples by direct plating and colony hybridization procedure. The trh(+)V. parahaemolyticus could be detected in five of 34 (14.7%) samples and the levels ranged from 5.0 x 10(2) to 3.4 x 10(3) cfu g(-1). Colonies of trh(+)V.parahaemolyticus were isolated from the five positive samples. Forty seafood samples were analysed for trh(+)V. parahaemolyticus by colony hybridization following enrichment in alkaline peptone water. 16 samples (40%) were positive for trh gene and trh(+)V. parahaemolyticus was isolated from 15 samples (37.5%). To assess the sensitivity of the trh probe, seafood homogenates spiked with known concentrations of trh-positive V. parahaemolyticus were plated and hybridized. Counts obtained using the probe were similar to those of inocula. The results suggest that the AP-labelled trh probe is useful for the detection and enumeration of trh(+)V. parahaemolyticus in seafood.     

Comparison of a commercial biochemical kit and an oligonucleotide probe for identification of environmental isolates of Vibrio vulnificus

A. DALSGAARD, I. DALSGAARD, L. HØI AND J.L. LARSEN. 1996. Methods for the identification and isolation of environmental isolates of Vibrio vulnificus were evaluated. Alkaline peptone water supplemented with polymyxin B and colistin-polymyxin B-cellobiose agar were employed for the isolation of suspected V. vulnificus from water, sediment and shellfish samples. When comparing the identification of putative V. vulnificus obtained with the API 20E assay and an oligonucleotide probe, 29 API 20E profiles were obtained with only four profiles (representing 20 isolates) reaching the identification threshold of V. vulnificus among a total of 66 isolates hybridizing with the probe. The results indicated that, compared with colony hybridization, the API 20E assay was not adequate for the identification of environmental isolates of V. vulnificus .     

Rapid serological identification of Vibrio vulnificus by anti-H coagglutination.

Staphylococcus aureus Cowan 1 cells were armed with anti-flagellar (anti-H) antibody produced in rabbits immunized with flagellar core protein prepared from Vibrio vulnificus. This reagent was assessed by coagglutination for its capacity to agglutinate and identify V. vulnificus. A species-specific H antigen is expressed in the core proteins of the polar flagella of V. vulnificus. Of 435 V. vulnificus isolates identified bacteriologically, 432 (99.3%) were agglutinated in the slide test within 2 min after the addition of the anti-V. vulnificus H coagglutination reagent. Other than Vibrio pelagius, the reagent did not agglutinate 19 heterologous Vibrio spp. tested, including 290 V. cholerae, 22 V. mimicus, 395 V. parahaemolyticus, and 16 V. fluvialis isolates recovered from seafood and the marine environment. The serological resolution of the coagglutination reaction was enhanced if the organism under test was suspended in 0.1 M Tris buffer-0.1 mM EDTA-1.0% Triton X-100 (TET) for 24 h before serological examination. The TET buffer also increased the sensitivity of the coagglutination reaction 100-fold over that for isolates suspended in 0.3% formalinized phosphate-buffered saline before testing. The anti-H coagglutination test is a rapid, serologically specific, and inexpensive procedure for identifying V. vulnificus one step beyond primary isolation.     

Rapid serological identification of Vibrio vulnificus by anti-H coagglutination

Staphylococcus aureus Cowan 1 cells were armed with anti-flagellar (anti-H) antibody produced in rabbits immunized with flagellar core protein prepared from Vibrio vulnificus. This reagent was assessed by coagglutination for its capacity to agglutinate and identify V. vulnificus. A species-specific H antigen is expressed in the core proteins of the polar flagella of V. vulnificus. Of 435 V. vulnificus isolates identified bacteriologically, 432 (99.3%) were agglutinated in the slide test within 2 min after the addition of the anti-V. vulnificus H coagglutination reagent. Other than Vibrio pelagius, the reagent did not agglutinate 19 heterologous Vibrio spp. tested, including 290 V. cholerae, 22 V. mimicus, 395 V. parahaemolyticus, and 16 V. fluvialis isolates recovered from seafood and the marine environment. The serological resolution of the coagglutination reaction was enhanced if the organism under test was suspended in 0.1 M Tris buffer-0.1 mM EDTA-1.0% Triton X-100 (TET) for 24 h before serological examination. The TET buffer also increased the sensitivity of the coagglutination reaction 100-fold over that for isolates suspended in 0.3% formalinized phosphate-buffered saline before testing. The anti-H coagglutination test is a rapid, serologically specific, and inexpensive procedure for identifying V. vulnificus one step beyond primary isolation.     

Rapid detection and identification of Vibrio anguillarum by using a specific oligonucleotide probe complementary to 16S rRNA.

Partial 16S rDNA from Vibrio collection type strains and recent isolates of Vibrio-related strains were sequenced and compared with previously published sequences. A 24-base DNA oligonucleotide (VaV3) was designed and used as a specific probe for detection and identification of Vibrio anguillarum. Its specificity was tested against collection type strains and environmental isolates and no cross-reaction was found. The probe detected 8 of the 10 V. anguillarum serovars. It was applied to screen different Vibrio-related strains isolated from marine hatcheries and fish farms. The detection limit in DNA-DNA slot blot hybridization was 150 pg.     

Enumeration of Vibrio vulnificus on membrane filters with a fluorescently labeled oligonucleotide probe specific for kingdom-level 16S rRNA sequences.

Vibrio vulnificus was enumerated on membrane filters after hybridization with a fluorescent oligonucleotide eubacterial probe. Cells were hybridized in liquid buffer or directly on membrane filters. There was no significant difference between fluorescent oligonucleotide direct counts and acridine orange direct counts (P > 0.05). Liquid buffer hybridization was preferable to direct filter hybridization.     

Rapid identification of Aerococcus viridans using the polymerase chain reaction and an oligonucleotide probe

A polymerase chain reaction/oligonucleotide probe method was developed for the specific identification of the Gram-positive bacterium Aerococcus viridans. Primers for the enzymatic amplification reaction were designed from specific sequences within the 16S rRNA. The method was also highly sensitive and 10 cfu of A. viridans could be detected in 5 h although the reliability of detection was poor in mixed cultures with Escherichia coli.     

Use of an oligonucleotide probe to detect Vibrio parahaemolyticus in artificially contaminated oysters.

A 26-mer oligonucleotide specific to Vibrio parahaemolyticus was synthesized from a 1,275-bp thermostable direct hemolysin (tdh) gene. This oligonucleotide probe specifically reacted with DNA from 89 of 95 V. parahaemolyticus isolates but not with DNA from other vibrios or other enteric and nonenteric organisms (n = 48). The probe hybridized with Southern blots of 0.5-kb HindIII-restricted chromosomal DNA fragments from all but five V. parahaemolyticus test isolates. The probe could be used to directly identify V. parahaemolyticus in artificially contaminated food without an isolation step.     

Use of an oligonucleotide probe to detect Vibrio parahaemolyticus in artificially contaminated oysters.

A 26-mer oligonucleotide specific to Vibrio parahaemolyticus was synthesized from a 1,275-bp thermostable direct hemolysin (tdh) gene. This oligonucleotide probe specifically reacted with DNA from 89 of 95 V. parahaemolyticus isolates but not with DNA from other vibrios or other enteric and nonenteric organisms (n = 48). The probe hybridized with Southern blots of 0.5-kb HindIII-restricted chromosomal DNA fragments from all but five V. parahaemolyticus test isolates. The probe could be used to directly identify V. parahaemolyticus in artificially contaminated food without an isolation step.     

An in situ hybridization histochemistry method for the use of alkaline phosphatase-labeled oligonucleotide probes in small intestine.

We have developed a method of non-radioactive in situ hybridization histochemistry using alkaline phosphatase-labeled oligonucleotide probes to detect gene expression in the intestine. Because the intestine contains a large amount of endogenous alkaline phosphatase activity, mild acid pretreatment of the tissue sections was required to inactivate the alkaline phosphatase. Acid pre-treatment dramatically reduced the endogenous activity without affecting the efficiency of hybridization or the probe's ability to reveal a positive mRNA signal. Furthermore, the addition of polyvinyl alcohol to the substrate solution helped to keep the background staining low without adversely affecting the intensity of the signal. The current protocol allows rapid and sensitive detection of sites of gene expression in intestinal tissue.     

Identification of environmental Vibrio vulnificus isolates with a DNA probe for the cytotoxin-hemolysin gene.

We screened 44 lactose-positive Vibrio strains isolated from the marine environment for homology with a 3.2-kilobase DNA fragment encoding the Vibrio vulnificus cytotoxin-hemolysin gene. All 29 marine isolates identified as V. vulnificus on the basis of numerical taxonomy and DNA-DNA hybridization studies hybridized with the cytotoxin gene probe, as did all V. vulnificus reference strains. Homologous gene sequences were identified in no other lactose-positive marine vibrio isolates nor in 10 other Vibrio species.     

Polymerase chain reaction identification of Vibrio vulnificus in artificially contaminated oysters.

DNAs extracted from Vibrio vulnificus seeded into oyster homogenates were evaluated as templates for the polymerase chain reaction. Several extraction procedures were examined, and it was determined that DNA recovered from cells lysed by guanidine isothiocyanate, extracted with chloroform, and precipitated with ethanol was most suitable for use as a polymerase chain reaction template. The region targeted was a 519-bp portion of the cytotoxin-hemolysin gene of V. vulnificus. This region was amplified only when DNA from this species was present in the homogenate. V. vulnificus seeded into oyster homogenates at an initial level of 10(2) CFU/g of oyster meat was consistently observed after 24 h of incubation in alkaline peptone water.     

Identification of environmental Vibrio vulnificus isolates with a DNA probe for the cytotoxin-hemolysin gene

We screened 44 lactose-positive Vibrio strains isolated from the marine environment for homology with a 3.2-kilobase DNA fragment encoding the Vibrio vulnificus cytotoxin-hemolysin gene. All 29 marine isolates identified as V. vulnificus on the basis of numerical taxonomy and DNA-DNA hybridization studies hybridized with the cytotoxin gene probe, as did all V. vulnificus reference strains. Homologous gene sequences were identified in no other lactose-positive marine vibrio isolates nor in 10 other Vibrio species.     

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.     

Antacid increases survival of Vibrio vulnificus and Vibrio vulnificus phage in a gastrointestinal model.

Viable counts of three strains of Vibrio vulnificus and its phage were determined during exposure to a mechanical gastrointestinal model with or without antacid for 9 h at 37 degrees C. V. vulnificus was eliminated (>4-log reduction) within 30 min in the gastric compartment (pH decline from 5.0 to 3.5). Viable V. vulnificus cells delivered from the gastric compartment during the first 30 min of exposure reached 10(6) to 10(8) CFU/ml in the intestinal compartment after 9 h (pH 7.0). Phages were eliminated within 45 min in the gastric compartment (pH decline from 5.1 to 2.5). Less than a 2-log reduction of phage was observed in the intestinal compartment after 9 h (pH 7.0). When the gastric compartment contained antacid V. vulnificus counts decreased slightly (<2 log) during 2 h of exposure (pH decline from 7.7 to 6.0), while counts in the intestinal compartment (pH 7.5) reached 10(7) to 10(9) CFU/ml. Phage numbers decreased 1 log after 2 h in the gastric compartment (pH decline from 7.7 to 5.7) containing antacid and decreased 1 log in the intestinal compartment (pH 7.6) after 9 h. Presence of antacid in the gastric compartment of the model greatly increased the ability of both V. vulnificus and its phage to survive simulated gastrointestinal transit and may be a factor involved with oyster-associated illness.     

A selective medium and a specific probe for detection of Vibrio vulnificus

A selective medium (VVM) and a specific 16S rRNA gene (rDNA) probe (V3VV) for the detection of Vibrio vulnificus were developed. The medium contains D-(+)-cellobiose as the main carbon source and electrolytes (MgCl(2)-6H(2)O and KCl), which stimulate bacterial growth. Polymyxin B, colistin, and moderate alkalinity and salinity provide selectivity properties. V. vulnificus grows on VVM as flat, bright yellow colonies. Other Vibrio species tested either did not grow or showed green-bluish colonies, with the exception of V. campbelli, V. carchariae, and V. navarrensis. There is a higher colony count on VVM agar than on cellobiose-colistin agar or on modified cellobiose-polymyxin B-colistin agar. The specific probe was evaluated by colony hybridization and dot blot hybridization with PCR-amplified 16S rDNA using collection strains and environmental isolates. No strain studied other than V. vulnificus showed positive hybridization with this oligonucleotide. The combined use of VVM agar and the V3VV probe provided the recovery of V. vulnificus from mixed bacterial suspensions and spiked mussels.     

Choline acetyltransferase expression studied with an oligonucleotide probe

1. The localization of choline acetyltransferase messenger RNA has been studied using a digoxigenin-tailed complementary oligodeoxynucleotide probe for in situ hybridization. 2. Putative cholinergic cells of the rat and ferret spinal cord and the ferret retina were labeled. 3. This technique affords superior resolution compared to radioactively labeled probes, with apparently equal sensitivity.     

Vibrio vulnificus. Hazard on the half shell.

Vibrio vulnificus is an extremely invasive gram-negative bacillus that causes bacteremia and shock. It should be suspected in any patient who is immunocompromised or has liver disease or hemochromatosis. Reduced gastric acidity may also increase the risk of infection if a patient presents with a history of ingesting raw shellfish (especially oysters) or trauma in brackish waters and skin lesions. Patients most commonly present with one of three clinical syndromes: primary septicemia, wound infection, or gastroenteritis. Treatment includes aggressive wound debridement, antibiotic therapy, and supportive care. Rapidly diagnosing and promptly initiating therapy are critical because V vulnificus infection is rapidly progressive and mortality approaches 100% if septic shock occurs.     

USER Friendly Cloning Coupled with Chitin-Based Natural Transformation Enables Rapid Mutagenesis of Vibrio vulnificus

Vibrio vulnificus is a bacterial contaminant of shellfish and causes highly lethal sepsis and destructive wound infections. A definitive identification of virulence factors using the molecular version of Koch''s postulates has been hindered because of difficulties in performing molecular genetic analysis of this opportunistic pathogen. For example, conjugation is required to introduce plasmid DNA, and allelic exchange suicide vectors that rely on sucrose sensitivity for counterselection are not efficient. We therefore incorporated USER friendly cloning techniques into pCVD442-based allelic exchange suicide vectors and other expression vectors to enable the rapid and efficient capture of PCR amplicons. Upstream and downstream DNA sequences flanking genes targeted for deletion were cloned together in a single step. Based on results from Vibrio cholerae, we determined that V. vulnificus becomes naturally transformable with linear DNA during growth on chitin in the form of crab shells. By combining USER friendly cloning and chitin-based transformation, we rapidly and efficiently produced targeted deletions in V. vulnificus, bypassing the need for two-step, suicide vector-mediated allelic exchange. These methods were used to examine the roles of two flagellin loci (flaCDE and flaFBA), the motAB genes, and the cheY-3 gene in motility and to create deletions of rtxC, rtxA1, and fadR. Additionally, chitin-based transformation was useful in moving antibiotic resistance-labeled mutations between V. vulnificus strains by simply coculturing the strains on crab shells. The methods and genetic tools that we developed should be of general use to those performing molecular genetic analysis and manipulation of other gram-negative bacteria.Vibrio vulnificus is a halophilic bacterium present naturally in estuarine waters and often contaminates oysters and other shellfish (for a review, see reference 15). V. vulnificus is an opportunistic pathogen of humans, causing primary septicemia and wound infection in susceptible individuals, and is the leading cause of reported seafood-related deaths in the United States. In susceptible humans, V. vulnificus causes a rapid, fulminating disease process resulting in extensive tissue damage. Mortality rates for susceptible individuals who develop fulminating primary septicemia are greater than 50% (17). Skin infections can lead to severe cellulitis, necrotizing fasciitis, and myositis requiring surgical debridement of infected tissues or amputation of the limb (4, 29, 42). Therapeutic intervention is often difficult since death can occur in less than 24 h after contact with the bacteria. In a mouse model of infection, V. vulnificus replicates extremely rapidly in host tissues (40, 41) and kills host cells including neutrophils (41).Over 20 years of genetic analysis, only a few virulence factors have been identified and confirmed by using the molecular version of Koch''s postulates (15). Among the confirmed virulence factors are capsular polysaccharide (49), acquisition of iron (34, 52), type IV pilus (37), RTX toxins (21, 25, 30), and flagella (22, 26). Despite these advances, the full spectrum of virulence factors responsible for the rapid and destructive disease process has not been elucidated. A major hindrance to the molecular genetic analysis of V. vulnificus is the fact that the bacteria cannot be effectively electroporated, nor can the bacteria be chemically transformed. Therefore, the only effective means of introducing plasmid DNA is by conjugation. This limitation severely restricts the availability of plasmids for creating and complementing mutations for molecular genetic analysis.A classical method to create mutants of V. vulnificus is the use of suicide vectors containing transposons, such as TnphoA (31), mini-Tn5phoA (12), mini-Tn5Km2 (12), mini-Tn5lacZ1 (12), mini-Tn10/kan (23), and Himar (1). However, transposon mutagenesis can cause polar mutations and truncated genes. The most definitive genetic analyses can be performed by deleting the genes of interest. The standard method for deleting genes is to clone the flanking upstream and downstream sequences into an allelic exchange suicide vector and introducing the plasmid into the target strain. The suicide vector integrates into the target genome via one of the flanking DNA sequences by a single-crossover event. This process is selected using antibiotic resistance encoded on the vector. The single-crossover strain is then grown without selection to allow for a second crossover that excises the allelic exchange vector. The excision event is enriched using a counterselectable marker encoded on the allelic exchange vector. A commonly used counterselectable marker is sucrose sensitivity, encoded by the sacB gene (13). If the second crossover is in the same flanking sequence as the first, the wild-type genotype is restored; however, if the second crossover is in the opposite flanking sequence, the targeted gene is deleted.This method of mutagenesis is problematic for V. vulnificus. First, one of the easiest ways to clone PCR amplicons is by TA topoisomerase-mediated ligation (TOPO TA cloning) with commercially available vectors such as pCR2.1 TOPO (Invitrogen, Carlsbad, CA). Unfortunately, these vectors are not mobilizable; hence, they cannot be used directly with V. vulnificus. Furthermore, there are no available TA topoisomerase allelic exchange vectors. Site-specific recombination vectors such as Gateway (Invitrogen) have facilitated PCR-mediated cloning and gene expression; however, none of the relevant vectors is mobilizable. Therefore, essentially all cloning for expression in or mutagenesis of V. vulnificus requires multiple subcloning steps. Second, sucrose sensitivity counterselection is not very efficient with V. vulnificus, as it is time-consuming and involves the screening of large numbers of colonies to find truly sucrose-resistant colonies. In some cases, sacB counterselection has completely failed. Another method for introducing mutations into target strains is the lambda phage red recombinase system (11). However, this procedure involves introducing additional helper plasmids into the target strain, and mobilizable helper plasmids have not been made. Finally, no generalized transducing phages and no methods for transformation have been described for V. vulnificus. Therefore, if one desires to move mutations between strains, the mutations must be cloned into suicide vectors, and the inefficient two-step allelic exchange process must be repeated for each strain.We describe here the adaption of USER (uracil-specific excision reagent) friendly cloning (3, 14) into allelic exchange and expression vectors that are commonly used with V. vulnificus. USER friendly cloning enables the creation of 3′ overhangs in PCR amplicons by use of deoxyuridine in PCR primers and treatment with USER enzyme mix (uracil DNA glycosylase and DNA glycosylase-lyase endonuclease VIII). The overhangs are complementary to overhangs created in vectors. The method is very adaptable, with immense leeway in choosing the DNA sequences of the overhangs independent of restriction enzyme cleavage sites. USER friendly cloning methods and vectors enable the rapid creation of upstream-downstream clones to delete genes or loci of interest. To alleviate inefficiencies of subcloning into V. vulnificus vectors, we created an array of USER friendly cloning allelic exchange and expression vectors that should be useful to many investigators.Meibom et al. (32) recently described the ability of Vibrio cholerae to become naturally transformable during growth in the presence of chitin, as either chitohexose or crab shell fragments. We adapted their crab shell system and determined that V. vulnificus can also become naturally transformable during growth on chitin. The bacteria take up linear DNA; hence, as long as selectable markers are used, allelic exchange mutagenesis can be accomplished without the need for inefficient counterselection involving sucrose. We used these methods to create antibiotic resistance-marked deletions in V. vulnificus of the two loci encoding flagellins, flaCDE and flaFBA, and the genes encoding the following functions: the flagellar motor motAB; a critical element of signal transduction for chemotaxis, cheY-3; an RTX toxin, rtxA1; a putative RtxA-modifying enzyme, rtxC; and a regulator of fatty acid metabolism, fadR. These genetic tools and methods will facilitate the molecular genetic analysis of V. vulnificus as well as those of other gram-negative bacteria.