The complete nucleotide sequence of the Vibrio harveyi bacteriophage VHML

Molecular characterization of Vibrio harveyi bacteriophages isolated from aquaculture environments along the coast of India

Seven bacteriophages specific to Vibrio harveyi, the causative agent of luminous vibriosis in shrimp, were isolated from coastal aquaculture systems like shrimp farms, hatcheries and tidal creeks along the east and west coast of India. All the seven phages were found to have the typical head and tail morphology with double-stranded DNA as genetic material. Morphologically, six phages were grouped under family Siphoviridae and one under Myoviridae. These phages were further characterized with respect to host range, morphology and structural proteins. Genomic fingerprinting was carried out using restriction fragment length polymorphism (RFLP) and randomly amplified polymorphic DNA (RAPD). Major capsid proteins of all the phages detected by SDS-PAGE were distinct from one another. All the phages were found to be highly lytic for V. harveyi and had different lytic spectrum for the large number of isolates tested. Six of the seven phages isolated had a broad lytic spectrum and could be potential candidates for biocontrol of V. harveyi in aquaculture systems.

Identification of a diagnostic marker to detect freshwater cyanophages of filamentous cyanobacteria

Cyanophages are viruses that infect the cyanobacteria, globally important photosynthetic microorganisms. Cyanophages are considered significant components of microbial communities, playing major roles in influencing host community diversity and primary productivity, terminating cyanobacterial water blooms, and influencing biogeochemical cycles. Cyanophages are ubiquitous in both marine and freshwater systems; however, the majority of molecular research has been biased toward the study of marine cyanophages. In this study, a diagnostic probe was developed to detect freshwater cyanophages in natural waters. Oligonucleotide PCR-based primers were designed to specifically amplify the major capsid protein gene from previously characterized freshwater cyanomyoviruses that are infectious to the filamentous, nitrogen-fixing cyanobacterial genera Anabaena and Nostoc. The primers were also successful in yielding PCR products from mixed virus communities concentrated from water samples collected from freshwater lakes in the United Kingdom. The probes are thought to provide a useful tool for the investigation of cyanophage diversity in freshwater environments.

Vibrio harveyi: a significant pathogen of marine vertebrates and invertebrates

Vibrio harveyi, which now includes Vibrio carchariae as a junior synonym, is a serious pathogen of marine fish and invertebrates, particularly penaeid shrimp. In fish, the diseases include vasculitis, gastro-enteritis and eye lesions. With shrimp, the pathogen is associated with luminous vibriosis and Bolitas negricans. Yet, the pathogenicity mechanisms are imprecisely understood, with likely mechanisms involving the ability to attach and form biofilms, quorum sensing, various extracellular products including proteases and haemolysins, lipopolysaccharide, and interaction with bacteriophage and bacteriocin-like substances.

Study on the relationship of protease production and luminescence in Vibrio harveyi

AIMS

To demonstrate that Vibrio harveyi produces various types of toxins and how the production of those toxins is related with luminescence.

METHODS AND RESULTS

Luminescence and toxicity of eight V. harveyi were evaluated. We demonstrated that all V. harveyi emitting luminescence were isolated from marine organisms and also showed that they were highly pathogenic when compared with culture collection V. harveyi based on cytotoxic assay test. On the contrary, V. harveyi isolated from shrimp farm showed no luminescence but showed high pathogenicity based on toxicity test. The effect of protease inhibitors on pathogenicity and luminescence was also investigated. We demonstrated that light emission of pathogenic V. harveyi remarkably decreased after addition of protease inhibitor. Furthermore, extracellular proteins from cell-free culture supernatant of luminescent and nonluminescent V. harveyi were compared using SDS-PAGE analysis. Results showed that there were differences in molecular weight and amount of proteins.

CONCLUSIONS

Vibrio harveyi parasiting marine organisms have both luminescence and pathogenicity. Based on this study, luminescence and protease toxin activity in V. harveyi are related. Moreover, this paper clarified that V. harveyi produces various types of toxins.

SIGNIFICANCE AND IMPACT OF THE STUDY

The current study demonstrated that V. harveyi produces two kinds of toxins, haemolysin and protease toxin. It may be clear roots of V. harveyi toxin.

Unstable lysogeny and pseudolysogeny in Vibrio harveyi siphovirus-like phage 1

Exposure of Vibrio harveyi (strain VH1114) to V. harveyi siphovirus-like phage 1 (VHS1) resulted in the production of a low percentage of lysogenized clones of variable stability. These were retrieved most easily as small colonies within dot plaques. Analysis revealed that VHS1 prophage was most likely carried by VH1114 as an episome rather than integrated into the host chromosome. In the late exponential growth phase, lysogenized VH1114 continuously produced VHS1 but also gave rise to a large number of cured progeny. The absence of phage DNA in the cured progeny was confirmed by the absence of VHS1 DNA in Southern blot and PCR assays. Curiously, these very stable, cured subclones did not show the parental phenotype of clear plaques with VHS1 but instead showed turbid plaques, both in overlaid lawns and in dot plaque assays. This phenotypic difference from the original parental isolate suggested that transient lysogeny by VHS1 had resulted in a stable genetic change in the cured clones. Such clones may be called pseudolysogens (i.e., false lysogens), since they have undergone transient lysogeny and have retained some resistance to full lytic phage development, despite the loss of viable or detectable prophage.

Partial characterization of a novel bacteriophage of Vibrio harveyi isolated from shrimp culture ponds in Thailand

A bacteriophage was isolated together with Vibrio harveyi (VH) 1114 a from a black tiger shrimp-rearing pond in Thailand. By negative staining transmission electron microscopy (TEM), the phage had an icosahedral head (diameter 60-62 nm), a rigid, non-contractile tail (9-10 nm x 100-120 nm) without a collar or terminal fibers and a genome of double stranded DNA of approximately 80 kb as determined by analysis of restriction enzyme digestion fragments. Since these features would place it in the family Siphoviridae, it was tentatively named V. harveyi siphoviridae-like phage or VHS1. VHS1 could also infect two VH reference strains LMD 22.30 and LMD 80.33 (=ATCC 14126) but yielded smaller plaques than with VH1114. The phage tolerated temperatures as high as 60 degrees C for up to 2h and overnight exposure to a broad range of pH. VHS1 lysogens of VH1114 were unstable, contained unaltered VHS1 DNA, were immune to VHS1 lysis and spontaneously released VHS1 in liquid cultures. Approximately 20 kb of the genome has been sequenced and deposited at GenBank but it mostly showed no significant homology with existing sequences in the database.

Complete genome sequence of phiHSIC, a pseudotemperate marine phage of Listonella pelagia

The genome for the marine pseudotemperate member of the Siphoviridae phiHSIC has been sequenced using a combination of linker amplification library construction, restriction digest library construction, and primer walking. phiHSIC enters into a pseudolysogenic relationship with its host, Listonella pelagia, characterized by sigmoidal growth curves producing >10(9) cells/ml and >10(11) phage/ml. The genome (37,966 bp; G+C content, 44%) contained 47 putative open reading frames (ORFs), 17 of which had significant BLASTP hits in GenBank, including a beta subunit of DNA polymerase III, a helicase, a helicase-like subunit of a resolvasome complex, a terminase, a tail tape measure protein, several phage-like structural proteins, and 1 ORF that may assist in host pathogenicity (an ADP ribosyltransferase). The genome was circularly permuted, with no physical ends detected by sequencing or restriction enzyme digestion analysis, and lacked a cos site. This evidence is consistent with a headful packaging mechanism similar to that of Salmonella phage P22 and Shigella phage Sf6. Because none of the phage-like ORFs were closely related to any existing phage sequences in GenBank (i.e., none more than 62% identical and most <25% identical at the amino acid level), phiHSIC is unique among phages that have been sequenced to date. These results further emphasize the need to sequence phages from the marine environment, perhaps the largest reservoir of untapped genetic information.

Marine phage genomics: what have we learned?

Marine phages are the most abundant and diverse form of life on the planet, and their genomes have been described as the largest untapped reservoir of genomic information. To date, however, the complete genome sequences of only 17 marine phage are known. Nevertheless, these genomes have revealed some interesting features, including the presence of photosynthetic genes in cyanophage and common patterns of genomic organization. Intriguing findings are also being made from studies of the uncultivated marine viral community genome ('metavirome'). The greatest challenge in interpreting the biology of these phages, and for making comparisons with their terrestrial counterparts, is the high proportion of unidentifiable open reading frames (approximately 60%). Future studies are likely to focus on sequencing more marine phage genomes from disparate hosts and diverse environments and on further basic studies of the biology of existing marine phages.

Genomic analysis of bacteriophage PhiJL001: insights into its interaction with a sponge-associated alpha-proteobacterium

Bacteriophage PhiJL001 infects a novel marine bacterium in the alpha subclass of the Proteobacteria isolated from the marine sponge Ircinia strobilina. PhiJL001 is a siphovirus and forms turbid plaques on its host. The genome sequence of PhiJL001 was determined in order to better understand the interaction between the marine phage and its sponge-associated host bacterium. The complete genome sequence of PhiJL001 comprised 63,469 bp with an overall G+C content of 62%. The genome has 91 predicted open reading frames (ORFs), and 17 ORFs have been assigned putative functions. PhiJL001 appears to be a temperate phage, and the integrase gene was identified in the genome. DNA hybridization analysis showed that the PhiJL001 genome does not integrate into the host chromosome under the conditions tested. DNA hybridization experiments therefore suggested that PhiJL001 has some pseudolysogenic characteristics. The genome of PhiJL001 contains many putative genes involved in phage DNA replication (e.g., helicase, DNA polymerase, and thymidylate synthase genes) and also contains a putative integrase gene associated with the lysogenic cycle. Phylogeny based on DNA polymerase gene sequences indicates that PhiJL001 is related to a group of siphoviruses that infect mycobacteria. Designation of PhiJL001 as a siphovirus is consistent with the morphology of the phage visualized by transmission electron microscopy. The unique marine phage-host system described here provides a model system for studying the role of phages in sponge microbial communities.

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.

Biodiversity of vibrios

Vibrios are ubiquitous and abundant in the aquatic environment. A high abundance of vibrios is also detected in tissues and/or organs of various marine algae and animals, e.g., abalones, bivalves, corals, fish, shrimp, sponges, squid, and zooplankton. Vibrios harbour a wealth of diverse genomes as revealed by different genomic techniques including amplified fragment length polymorphism, multilocus sequence typing, repetetive extragenic palindrome PCR, ribotyping, and whole-genome sequencing. The 74 species of this group are distributed among four different families, i.e., Enterovibrionaceae, Photobacteriaceae, Salinivibrionaceae, and Vibrionaceae. Two new genera, i.e., Enterovibrio norvegicus and Grimontia hollisae, and 20 novel species, i.e., Enterovibrio coralii, Photobacterium eurosenbergii, V. brasiliensis, V. chagasii, V. coralliillyticus, V. crassostreae, V. fortis, V. gallicus, V. hepatarius, V. hispanicus, V. kanaloaei, V. neonatus, V. neptunius, V. pomeroyi, V. pacinii, V. rotiferianus, V. superstes, V. tasmaniensis, V. ezurae, and V. xuii, have been described in the last few years. Comparative genome analyses have already revealed a variety of genomic events, including mutations, chromosomal rearrangements, loss of genes by decay or deletion, and gene acquisitions through duplication or horizontal transfer (e.g., in the acquisition of bacteriophages, pathogenicity islands, and super-integrons), that are probably important driving forces in the evolution and speciation of vibrios. Whole-genome sequencing and comparative genomics through the application of, e.g., microarrays will facilitate the investigation of the gene repertoire at the species level. Based on such new genomic information, the taxonomy and the species concept for vibrios will be reviewed in the next years.

Burkholderia cenocepacia phage BcepMu and a family of Mu-like phages encoding potential pathogenesis factors

We have isolated BcepMu, a Mu-like bacteriophage whose host range includes human pathogenic Burkholderia cenocepacia (formally B. cepacia genomovar III) isolates, and determined its complete 36748 bp genomic sequence. Like enteric bacteriophage Mu, the BcepMu genomic DNA is flanked by variable host sequences, a result of transposon-mediated replication. The BcepMu genome encodes 53 proteins, including capsid assembly components related to those of Mu, and tail sheath and tube proteins related to those of bacteriophage P2. Seventeen of the BcepMu genes were demonstrated to encode homotypic interacting domains by using a cI fusion system. Most BcepMu genes have close homologs to prophage elements present in the two published Salmonella typhi genomes, and in the database sequences of Photorhabdus luminescens, and Chromobacterium violaceum. These prophage elements, designated SalMu, PhotoMu and ChromoMu, respectively, are collinear with BcepMu through nearly their entire lengths and show only limited mosaicism, despite the divergent characters of their hosts. The BcepMu family of Mu-like phages has a number of notable differences from Mu. Most significantly, the critical left end region of BcepMu is inverted with respect to Mu, and the BcepMu family of transposases is clearly of a distinct lineage with different molecular requirements at the transposon ends. Interestingly, a survey of 33 B.cepacia complex strains indicated that the BcepMu prophage is widespread in human pathogenic B.cenocepacia ET12 lineage isolates, but not in isolates from the PHDC or Midwest lineages. Identified members of the BcepMu family all contain a gene possibly involved in bacterial pathogenicity, a homolog of the type-two-secretion component exeA, but only BcepMu also carries a lipopolysaccharide modification acyltransferase which may also contribute a pathogenicity factor.

Protelomerase uses a topoisomerase IB/Y-recombinase type mechanism to generate DNA hairpin ends

Protelomerases are enzymes responsible for the generation of closed hairpin ends in linear DNA. It is proposed that they use a breaking-and-rejoin type mechanism to affect DNA rearrangement on specific DNA sequences. In doing so, one strand turns around and becomes the complementary strand. Using the purified enzyme from the Escherichia coli phage N15 and the Klebsiella phage phiKO2 and synthetic oligonucleotide substrates, we directly demonstrate the location where the cutting/re-ligation occurs. We identified a pair of transient staggered cleavages six base-pairs apart centered around the axis of dyad symmetry of the target site. Two molecules of the protelomerase form a pair of protein-linked DNA intermediates at each 3' end of the cleaved openings leaving a 5'-OH. Then, in a process not yet clearly defined, the partners of the two initial openings are exchanged, and the transient breaks are resealed to generate hairpin ends. The formation of 3'-covalent DNA-protein intermediates is a hallmark of the topoisomerase IB type reaction, and we have thus shown experimentally that protelomerase is a member of the tyrosine-recombinase superfamily. In addition, by introducing single nicks in the substrates as perturbation, we found that the integrity of the nucleotide chain 4 bp away from the cutting site as well as this nucleotide's complementary location on the stem if the strands were to fold into a cruciform structure are required for activity, suggesting that these locations may be important substrate-protein contacts. We determined that N15 and phiKO2 protelomerases are monomers in solution and two molecules are needed to interact with the substrate to form two closed hairpin products. The target sites of protelomerases invariably consist of inverted repeats. Comparative studies using the related target sites of different protelomerases suggest that these proteins may require both sequence-specific and structure (possibly cruciform)-specific recognition for activity.

Genome sequences of two closely related Vibrio parahaemolyticus phages, VP16T and VP16C

Two bacteriophages of an environmental isolate of Vibrio parahaemolyticus were isolated and sequenced. The VP16T and VP16C phages were separated from a mixed lysate based on plaque morphology and exhibit 73 to 88% sequence identity over about 80% of their genomes. Only about 25% of their predicted open reading frames are similar to genes with known functions in the GenBank database. Both phages have cos sites and open reading frames encoding proteins closely related to coliphage lambda's terminase protein (the large subunit). Like in coliphage lambda and other siphophages, a large operon in each phage appears to encode proteins involved in DNA packaging and capsid assembly and presumably in host lysis; we refer to this as the structural operon. In addition, both phages have open reading frames closely related to genes encoding DNA polymerase and helicase proteins. Both phages also encode several putative transcription regulators, an apparent polypeptide deformylase, and a protein related to a virulence-associated protein, VapE, of Dichelobacter nodosus. Despite the similarity of the proteins and genome organization, each of the phages also encodes a few proteins not encoded by the other. We did not identify genes closely related to genes encoding integrase proteins belonging to either the tyrosine or serine recombinase family, and we have no evidence so far that these phages can lysogenize the V. parahaemolyticus strain 16 host. Surprisingly for active lytic viruses, the two phages have a codon usage that is very different than that of the host, suggesting the possibility that they may be relative newcomers to growth in V. parahaemolyticus. The DNA sequences should allow us to characterize the lifestyles of VP16T and VP16C and the interactions between these phages and their host at the molecular level, as well as their relationships to other marine and nonmarine phages.