Miguel Balado

The Photobacterium damselae subsp. damselae hemolysins damselysin and HlyA are encoded within a new virulence plasmid.

ABSTRACT Photobacterium damselae subsp. damselae (formerly Vibrio damsela) is a marine bacterium that causes infections and fatal disease in a wide range of marine animals and in humans. Highly hemolytic strains produce damselysin (Dly), a cytolysin encoded by the dly gene that is lethal for mice and has hemolytic activity. We found that Dly is encoded in the highly hemolytic strain RM-71 within a 153,429-bp conjugative plasmid that we dubbed pPHDD1. In addition to Dly, pPHDD1 also encodes a homologue of the pore-forming toxin HlyA. We found a direct correlation between presence of pPHDD1 and a strong hemolytic phenotype in a collection of P. damselae subsp. damselae isolates. Hemolysis was strongly reduced in a double dly hlyA mutant, demonstrating the role of the two pPHDD1-encoded genes in hemolysis. Interestingly, although single hlyA and dly mutants showed different levels of hemolysis reduction depending on the erythrocyte source, hemolysis was not abolished in any of the single mutants, suggesting that the hemolytic phenotype is the result of the additive effect of Dly and HlyA. We found that pPHDD1-encoded dly and hlyA genes are necessary for full virulence for mice and fish. Our results suggest that pPHDD1 can be considered as a driving force for the emergence of a highly hemolytic lineage of P. damselae subsp. damselae.

Synergistic and Additive Effects of Chromosomal and Plasmid-Encoded Hemolysins Contribute to Hemolysis and Virulence in Photobacterium damselae subsp. damselae

ABSTRACT Photobacterium damselae subsp. damselae causes infections and fatal disease in marine animals and in humans. Highly hemolytic strains produce damselysin (Dly) and plasmid-encoded HlyA (HlyApl). These hemolysins are encoded by plasmid pPHDD1 and contribute to hemolysis and virulence for fish and mice. In this study, we report that all the hemolytic strains produce a hitherto uncharacterized chromosome-encoded HlyA (HlyAch). Hemolysis was completely abolished in a single hlyAch mutant of a plasmidless strain and in a dly hlyApl hlyAch triple mutant. We found that Dly, HlyApl, and HlyAch are needed for full hemolytic values in strains harboring pPHDD1, and these values are the result of the additive effects between HlyApl and HlyAch, on the one hand, and of the synergistic effect of Dly with HlyApl and HlyAch, on the other hand. Interestingly, Dly-producing strains produced synergistic effects with strains lacking Dly production but secreting HlyA, constituting a case of the CAMP (Christie, Atkins, and Munch-Petersen) reaction. Environmental factors such as iron starvation and salt concentration were found to regulate the expression of the three hemolysins. We found that the contributions, in terms of the individual and combined effects, of the three hemolysins to hemolysis and virulence varied depending on the animal species tested. While Dly and HlyApl were found to be main contributors in the virulence for mice, we observed that the contribution of hemolysins to virulence for fish was mainly based on the synergistic effects between Dly and either of the two HlyA hemolysins rather than on their individual effects.

Biosynthetic and regulatory elements involved in the production of the siderophore vanchrobactin in Vibrio anguillarum

Some Vibrio anguillarum strains produce a catechol-type siderophore named vanchrobactin, whose biosynthetic pathway has not been completely elucidated. In addition to the previously described genes vabA, vabC, vabB, vabE, vabF, vabS and vabH, in the present study we have identified the genes encoding a DAHP (3-deoxy-d-arabino-heptulosonate-7-phosphate) synthetase (vabG), a phosphopantheteinyl transferase (vabD), a LysR-family transcriptional regulator (vabR) and a putative siderophore receptor (fvtA). A deletion affecting vabG or vabD greatly reduced growth under iron-limiting conditions, whereas deletion of vabR did not have significant effects. Vanchrobactin production was abolished in the vabD mutant, whereas the vabG mutant retained a residual vanchrobactin production ability. Reverse transcriptase-mediated PCR indicated that this 11-gene cluster is organized into six iron-regulated transcriptional units. Transcriptional lacZ fusions demonstrated that the ferric uptake regulator (Fur) protein is the main iron-responsive regulator of these genes. Interestingly, the vabG gene was strongly iron-repressed, but Fur was not essential for this repression. In addition, the maximal expression from the vabG promoter was achieved only in the presence of an intact copy of vabR. Analysis of the beta-galactosidase activities of a fvtA : : lacZ fusion in a vabB mutant and in the presence of added vanchrobactin suggested that a ferric-vanchrobactin-dependent activator plays a positive regulatory role in transcription of the fvtA-vabD operon. This possibility is reinforced by the presence of a predicted AraC box upstream of fvtA. We propose that vanchrobactin biosynthesis is subjected to a complex regulatory circuitry aimed at adjusting vanchrobactin production for the maintenance of iron homeostasis in V. anguillarum.

FvtA is the receptor for the siderophore vanchrobactin in Vibrio anguillarum: utility as a route of entry for vanchrobactin analogues.

ABSTRACT Some strains of Vibrio anguillarum, the causative agent of vibriosis in a variety of marine animals, produce a catechol-type siderophore named vanchrobactin. The biosynthetic pathway and regulation of vanchrobactin are quite well understood. However, aspects concerning its entry into the cell have remained uncharacterized. In the present study we characterized two genes, fvtA and orf13, encoding potential TonB-dependent ferric-vanchrobactin receptors in serotype O2 V. anguillarum strain RV22. We found that an fvtA mutant was defective for growth under iron limitation conditions and for utilization of vanchrobactin, suggesting that fvtA encodes the vanchrobactin receptor of V. anguillarum. Interestingly, an orf13 mutant was not significantly affected, and results of reverse transcriptase PCR, as well as analysis of outer membrane proteins by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, suggested that this gene is not expressed. Furthermore, fatA, a plasmid gene coding for the anguibactin receptor in plasmid pJM1-harboring strains, is also present in the chromosome of RV22, although it is inactivated by insertion of transposases. In addition, we found that FvtA is the route of entry for vanchrobactin analogues, and there is evidence that it recognizes primarily the catechol-iron center. These analogues are potential candidate vectors for a Trojan horse strategy aimed at generating antimicrobial compounds exploiting the same route of entry for native siderophores. We found that fvtA and vanchrobactin biosynthesis genes are ubiquitous in both vanchrobactin- and anguibactin-producing V. anguillarum strains, which reinforces the utility of the vanchrobactin route of entry for the design of future strategies for the control of vibriosis.

Synthesis and antibacterial activity of conjugates between norfloxacin and analogues of the siderophore vanchrobactin

From synthetic functionalized analogues of vanchrobactin, a siderophore produced by the fish pathogenic bacteria Vibrio anguillarum serotype O2, several vanchrobactin analogues-norfloxacin conjugates were obtained and their antimicrobial activities against the wild-type and mutant strains of Vibrio anguillarum serotype O2 have been determined.

A Transmissible Plasmid-Borne Pathogenicity Island Confers Piscibactin Biosynthesis in the Fish Pathogen Photobacterium damselae subsp. piscicida

ABSTRACT The fish pathogen Photobacterium damselae subsp. piscicida produces the siderophore piscibactin. A gene cluster that resembles the Yersinia high-pathogenicity island (HPI) encodes piscibactin biosynthesis. Here, we report that this HPI-like cluster is part of a hitherto-uncharacterized 68-kb plasmid dubbed pPHDP70. This plasmid lacks homologs of genes that mediate conjugation, but we found that it could be transferred at low frequencies from P. damselae subsp. piscicida to a mollusk pathogenic Vibrio alginolyticus strain and to other Gram-negative bacteria, likely dependent on the conjugative functions of the coresident plasmid pPHDP60. Following its conjugative transfer, pPHDP70 restored the capacity of a vibrioferrin mutant of V. alginolyticus to grow under low-iron conditions, and piscibactin became detectable in its supernatant. Thus, pPHDP70 appears to harbor all the genes required for piscibactin biosynthesis and transport. P. damselae subsp. piscicida strains cured of pPHDP70 no longer produced piscibactin, had impaired growth under iron-limited conditions, and exhibited markedly decreased virulence in fish. Collectively, our findings highlight the importance of pPHDP70, with its capacity for piscibactin-mediated iron acquisition, in the virulence of P. damselae subsp. piscicida. Horizontal transmission of this plasmid-borne piscibactin synthesis gene cluster in the marine environment may facilitate the emergence of new pathogens.

Genetic characterization of pAsa6, a new plasmid from Aeromonas salmonicida subsp. salmonicida that encodes a type III effector protein AopH homolog

A new plasmid designated pAsa6 from an Aeromonas salmonicida subsp. salmonicida strain isolated from diseased turbot has been characterized. pAsa6 consists of 18536bp, has a G+C content of 53.8% and encodes 20 predicted open-reading frames (ORFs). Eight ORFs showed homology to transposases, of which six are complete and two are partial IS sequences. Two ORFs showed homology to replication proteins, and six ORFs showed homology to hypothetical proteins. Two ORFs are truncated homologs of putative A. salmonicida sulfatases. Two genes, aopH and sycH encode homologs of an effector protein for which a role in fish colonization by A. salmonicida has been previously reported, and its chaperone, respectively. The results of filter conjugation experiments suggested that pAsa6 is not mobilizable, as it failed to be conjugally-transferred to several species of marine bacteria tested. All the ORFs of pAsa6 with the exception of four copies of a IS1 transposase gene, have a counterpart in the recently sequenced 155-kb A. salmonicida plasmid pAsa5, suggesting either that pAsa6 is a derivative of pAsa5, or that pAsa5 is the result of the fusion of a pAsa6-like plasmid and a larger plasmid of ca. 135-kb. The pAsa6-encoded repA and aopH genes could be PCR-amplified from strains lacking pAsa6, suggesting presence of a large, possibly pAsa5-like plasmid that was not detected on agarose gels, or the existence of chromosome-integrated plasmid sequences. This study demonstrates that genomic locations for the aopH gene different to pAsa5 or pAsa5-like plasmids exist in A. salmonicida.

Anguibactin- versus vanchrobactin-mediated iron uptake in Vibrio anguillarum: evolution and ecology of a fish pathogen.

Vibrio anguillarum is a marine bacterium that is present in many marine aquatic environments and that is the main cause of vibriosis in diverse wild and cultured fish species. Two siderophore-mediated iron uptake systems have been described in V. anguillarum. One, mediated by the siderophore anguibactin, is encoded by the pJM1-type plasmids and is restricted to serotype O1 strains. The second one is mediated by the vanchrobactin siderophore and is widespread in many strains belonging to different serotypes. Both siderophores belong to the catecholate group of siderophores, sharing a 2,3-dihydroxybenzoic acid moiety. Vanchrobactin biosynthesis and transport genes are present in all strains examined although the siderophore is not produced in serotype O1 strains harbouring a pJM1-type plasmid. In these strains the insertion of an IS element in the main vanchrobactin biosynthetic gene vabF leads to the fact that only anguibactin is produced. From our current knowledge we can presume that vanchrobactin is the ancestral siderophore in this species and that the anguibactin-mediated system was later acquired during evolution, likely by horizontal transfer. The role of these two different iron uptake mechanisms in the biology, evolution and ecology of V. anguillarum is discussed although they are still far from being completely understood.

Two Catechol Siderophores, Acinetobactin and Amonabactin, Are Simultaneously Produced by Aeromonas salmonicida subsp. salmonicida Sharing Part of the Biosynthetic Pathway

The iron uptake mechanisms based on siderophore synthesis used by the fish pathogen Aeromonas salmonicida subsp. salmonicida are still not completely understood, and the precise structure of the siderophore(s) is unknown. The analysis of genome sequences revealed that this bacterium possesses two gene clusters putatively involved in the synthesis of siderophores. One cluster is a candidate to encode the synthesis of acinetobactin, the siderophore of the human pathogen Acinetobacter baumannii, while the second cluster shows high similarity to the genes encoding amonabactin synthesis in Aeromonas hydrophila. Using a combination of genomic analysis, mutagenesis, biological assays, chemical purification, and structural determination procedures, here we demonstrate that most A. salmonicida subsp. salmonicida strains produce simultaneously the two siderophores, acinetobactin and amonabactin. Interestingly, the synthesis of both siderophores relies on a single copy of the genes encoding the synthesis of the catechol moiety (2,3-dihydroxybenzoic acid) and on one encoding a phosphopantetheinyl transferase. These genes are present only in the amonabactin cluster, and a single mutation in any of them abolishes production of both siderophores. We could also demonstrate that some strains, isolated from fish raised in seawater, produce only acinetobactin since they present a deletion in the amonabactin biosynthesis gene amoG. Our study represents the first evidence of simultaneous production of acinetobactin and amonabactin by a bacterial pathogen and reveals the plasticity of bacterial genomes and biosynthetic pathways. The fact that the same siderophore is produced by unrelated pathogens highlights the importance of these systems and their interchangeability between different bacteria.

A proteomic analysis of the iron response of Photobacterium damselae subsp. damselae reveals metabolic adaptations to iron levels changes and novel potential virulence factors

Photobacterium damselae subsp. damselae (Pdd) is a marine bacterium that can infect numerous species of marine fish as well as other species including humans. Low iron availability is one of the signs that bacterial pathogens can detect in order to begin colonizing their host, and the reduction of iron levels is a nonspecific host defense strategy that prevents bacterial proliferation. In this work a proteomic approach was used to study the gene expression adaptations of a Pdd strain in response to iron availability. A comparative analysis of induced proteins in both high- and low-iron conditions showed profound cellular metabolic adaptations that result, for instance, in amino acid requirement. It also provided important information about the changes that occur in the energetic metabolism induced by the surrounding iron levels, allowing for the identification of novel potential virulence factors. Among others, genes involved in the synthesis and transport of a vibrioferrin-like siderophore were identified for the first time. In addition to plasmid pPHDD1-encoded Dly and HlyA hemolysins, a pPHDD1-borne operon, which may encode a transferrin receptor, was also found. This operon identification suggests that this virulence plasmid could encode so-far unknown additional virulence factors other than hemolysins.