Cell-to-cell communication and virulence in Vibrio anguillarum

Lindell, Kristoffer

January 2012

Quorum sensing (QS) is a type of cell-to-cell communication that allows the bacteria to communicate via small molecules to coordinate activities such as growth, biofilm formation, virulence, and stress response as a population. QS depends on the accumulation of signal molecules as the bacterial population increases. After a critical threshold of the signal molecules are reached, the bacteria induce a cellular response allowing the bacteria to coordinate their activities as a population. In Vibrio anguillarum, three parallel quorum-sensing phosphorelay systems channels information via three hybrid sensor kinases VanN, VanQ, and CqsS that function as receptors for signal molecules produced by the synthases VanM, VanS, and CqsA, respectively. The phosphorelay systems converge onto a single regulatory pathway via the phosphotransferase VanU, which phosphorylates the response regulator VanO. Together with the alternative sigma factor RpoN, VanO activates the expression of a small RNA, Qrr1 (Quorum regulatory RNA), which in conjunction with the small RNA chaperone Hfq, destabilizes vanT mRNA, which encode the major quorum-sensing regulator in V. anguillarum. This thesis furthers the knowledge on the quorum-sensing phosphorelay systems in V. anguillarum. In this study, three additional qrr genes were identified, which were expressed during late logarithmic growth phase. The signal synthase VanM activated the expression of the Qrr1-4, which stands in contrast to Qrr regulation in other vibrios. Moreover, in addition to VanO, we predict the presence of a second response regulator which can be phosphorylated by VanU and repress Qrr1-4 expression. Thus, VanU functions as a branch point that can regulate the quorum-sensing regulon by activating or repressing VanT expression. Furthermore, VanT was shown to directly activate VanM expression and thus forming a negative regulatory loop, in which VanM represses VanT expression indirectly via Qrr1-4. In addition, VanM expression was negatively regulated post-transcriptionally by Hfq. Furthermore, a universal stress protein UspA repressed VanM expression via the repression of VanT expression. We showed that UspA binds Hfq, thus we suggest that UspA plays a role in sequestering Hfq and indirectly affect gene expression. This thesis also investigated the mechanism by which V. anguillarum can attach to and colonize fish skin tissue. We show unequivocally that fish skin epithelial cells can internalize bacteria, thus keeping the skin clear from pathogens. In turn, V. anguillarum utilized the lipopolysaccharide O-antigen to evade internalization by the fish skin epithelial cells. This study provides new insights into the molecular mechanism by which pathogen interacts with marine animals to cause disease.

vibrio anguillarum

quorum sensing

stress response

keratocyte

Specific humoral response of rainbow trout (Onchorhynchus mykiss) to injection, immersion, and oral immunization against Vibrio anguillarum /

Palm, Roger Carl,

January 1996

Thesis (Ph. D.)--University of Washington, 1996. / Vita. Includes bibliographical references (leaves [99]-112).

VanT, a central regulator of quorum sensing signalling in Vibrio anguillarum

Croxatto, Antony

January 2006

Many bacteria produce signal molecules that serve in a cell-to-cell communication system termed quorum sensing. This signalling system allows a bacterial population to co-ordinately regulate functions according to their cell number in a defined environment. As bacterial growth progresses towards the stationary phase, signalling molecules accumulate in the growth medium and, above a certain threshold level, regulate the expression of genes involved in diverse functions. Most of the functions monitored by quorum sensing are most beneficial when they are performed as a population than by single cells, such as virulence factor production, biofilm formation, conjugation and bioluminescence. Vibrio anguillarum is a bacterial pathogen that causes terminal hemorrhagic septicaemia in marine fish. V. anguillarum possesses multiple quorum sensing circuits similar to the LuxI/LuxR and the V. harveyi-type systems. In this study, a characterisation of the quorum sensing-regulated transcriptional activator VanT was made. VanT belongs to the V. harveyi LuxR family of transcriptional regulators, which play a central role in quorum sensing signalling in Vibrio species. VanT was shown to regulate serine, metalloprotease, pigment, exopolysaccharide (EPS) and biofilm production. VanT repressed an EPS locus that plays a critical role in bacterial colonization of the fish integument and virulence. The V. harveyi-like quorum sensing systems were shown to limit rather than induce vanT expression throughout growth in V. anguillarum. In contrast to homologous proteins in other Vibrio spp., the quorum sensing phosphorelay protein VanU and the response regulator VanO had antagonistic roles in the regulation of vanT expression. Unlike other members of the luxR family, vanT was expressed at low cell density and no significant induction due to quorum sensing regulation was seen. Interestingly, VanT expression was induced by the alternative sigma factor RpoS as the cells entered stationary phase. RpoS was shown to regulate VanT expression post-transcriptionally by promoting vanT mRNA stability. VanT and RpoS were important for bacterial survival under stress conditions, indicating that VanT is likely an essential factor of V. anguillarum stress response.

Vibriosis

Vibrio anguillarum

quorum sensing

two-component phosphorelay systems

Molecular biology

Molekylärbiologi

Stress response and virulence in Vibrio anguillarum

Weber, Barbara

January 2010

Bacteria use quorum sensing, a cell to cell signaling mechanism mediated by small molecules that are produced by specific signal molecule synthases, to regulate gene expression in response to population density. In Vibrio anguillarum, the quorum-sensing phosphorelay channels information from three hybrid sensor kinases VanN, VanQ, CqsS that sense signal molecules produced by the synthases VanM, VanS and CqsA, onto the phosphotransferase VanU, to regulate activity of the response regulator VanO. VanO activates transcription of quorum-sensing regulatory RNAs (Qrr), which work together with the RNA chaperone Hfq to repress expression of the transcriptional regulator VanT. The work presented in this thesis characterizes quorum-sensing independent and quorum-sensing dependent mechanisms that regulate VanT expression. Moreover, an in vivo imaging system was established, as a means to study V. anguillarum infections in the rainbow trout infection model. Two quorum-sensing independent mechanisms regulating VanT expression were identified. First, the sigma factor RpoS indirectly activates VanT expression during transition into stationary growth phase by inhibiting hfq expression. Both, RpoS and VanT are crucial for stress response. Second, a type VI secretion system (T6SS) has a novel function as a signal sensing mechanism to regulate rpoS and vanT expression. Consequently, RpoS, quorum sensing and T6SS form a global network that senses stress and modulates stress response to ensure survival of the bacteria. Further analysis of the quorum-sensing dependent regulation of VanT expression by the phosphorelay system revealed that four qrr genes are expressed continuously during growth. The phosphotransferase VanU is suggested to activate two response regulators, VanO and a predicted second response regulator. Activated VanO induces expression of the Qrr sRNAs, whereas, the predicted response regulator represses expression of the Qrr sRNAs. Thus, VanU has a pivotal role in the regulation of VanT expression. The signal synthase VanM and VanT form a regulatory loop, in which VanM represses VanT by inducing expression of the Qrr sRNAs and VanT directly activates vanM expression to repress its own expression. Moreover, Hfq destabilizes vanM mRNA, repressing vanM expression. VanT forms another regulatory loop with the transcriptional regulator LuxT, in which LuxT activates vanT expression and VanT directly represses luxT expression. V. anguillarum is an opportunistic pathogen that causes vibriosis, a terminal hemorrhagic septicemia. The spatial and temporal progression of the infection was analyzed using the whole animal with an in vivo bioluminescent imaging method. Initial studies showed that colonization of the fish skin requires the siderophore, the RNA chaperone Hfq and the exopolysaccharide transport system, which protects against the innate immunity on the skin. Colonization of the fish skin is crucial for disease.

Vibrio anguillarum

quorum sensing

Type VI secretion

stress response

virulence

skin colonization

Molecular biology

Molekylärbiologi

Characterisation of Vibrio anguillarum for the development of vaccine in cod (Gadus morhua)

Gratacap, Remi M. L.

January 2008

Atlantic cod (Gadus morhua L.) is one of the most promising new fish species introduced to cold water aquaculture due to the large established market in Europe and the USA and the decline in wild stock. So far, the production of farmed cod has been relatively low, with the main hindrance due to diseases. Vibrio anguillarum has been recognised as the biggest disease problem of farmed cod and has slowed the development of a successful cod aquaculture industry. When the first incidences of V. anguillarum occurred in cod aquaculture, vaccines designed for vibriosis in Atlantic salmon (Salmo salar L.) were used in an attempt to combat the disease. However, these vaccines did not provide sufficient protection, possibly because they lacked serotype O2b, which is known to affect cod and to a lesser extent salmonids. Recently, vibriosis vaccines specifically designed to protect Atlantic cod have been formulated, but outbreaks of vibriosis in vaccinated fish are still being reported, suggesting that these formulations are inadequate. The aim of this project was to develop a whole cell inactivated vaccine formulation specifically tailored to protect Atlantic cod against Vibrio anguillarum. The serological classification of V. anguillarum was first investigated by producing a set of monoclonal antibodies (mAbs). Using lipopolysaccharides (LPS) extracted with butan-1-ol, 4 mAbs were selected and shown to react specifically with V. anguillarum serotypes O1, O2a and O2b. A collection of over 150 V. anguillarum isolates were screened using these, which revealed that most of the isolates had been previously correctly classified. A new sub-serotype of V. anguillarum O2 was identified from isolates recovered from outbreaks of vibriosis in Norway as well as Scotland. This new sub-serotype was referred to as O2d since the subserotype O2c has been recently identified in vibriosis cases from Atlantic cod. However, it was shown that the O2c sub-serotype might not belong to the O2 serotype, but in fact belongs to another serotype. To protect Atlantic cod against all the V. anguillarum serotypes (and subserotypes) which they are susceptible to, it is recommended that isolates from serotypes O1, O2a, O2b, O2c and O2d should all be included in a bacterin vaccine for cod. In order to determine which isolates from each of the serotypes to include in the vaccine, a variety of virulence factors of V. anguillarum were investigated in vitro. The interaction of some candidate isolates from O1, O2a and O2b serotypes (O2c and O2d were not identified at the time this part of the study took place) with cod phagocytic cells were studied using flow cytometry. Phagocytosis and respiratory burst of cod macrophages and neutrophils as well as cod serum killing of V. anguillarum were quantified. It was found that isolates within the same serotype displayed varying degrees of resistance to phagocytosis and the subsequent respiratory burst activity as well as that all the V. anguillarum strains tested were resistant to Atlantic cod serum killing. These in vitro assays were found to be very useful in assessing the virulence of V. anguillarum. The isolate within each serotype eliciting the highest percentage of positive phagocytic cells was selected in order to increase the antigen presentation pathway, thus theoretically enhancing the protection elicited by the vaccine. A multivalent formalin-inactivated non-adjuvanted vaccine was prepared which included all the serotypes previously described and was injected intraperitoneally into Atlantic cod. A bath challenge was performed on vaccinated and mock-vaccinated fish, 6 weeks post immunisation, using V. anguillarum isolates from the serotypes O2b, O2c and O2d that were not included in the vaccine. An excellent level of protection was obtained against O2b and O2d (relative percentage survival 100% and 96.4%, respectively), but the challenge with the sub-serotype O2c isolate did not produce any mortality in the control group and needs to be repeated. The vaccine formulation was very efficient at protecting Atlantic cod against vibriosis but further challenges need to be performed with other serotypes included in the vaccine (O1 and O2a), as well as with more isolates from the O2b, O2c and O2d sub-serotype. To conclude, Atlantic cod is a species which will certainly have a major influence in marine aquaculture, but many areas have to be improved. The development of an effective and broad range vaccine to protect cod against Vibrio anguillarum offers another advance which should help Atlantic cod aquaculture to reach its full potential.

639.3

Virulence and required genes in the fish pathogen Vibrio anguillarum

McMillan, Stuart

January 2016

Vibrio anguillarum infects many fish species in aquaculture, reducing farm productivity and negatively impacting fish welfare. Deeper understanding of the biology of V. anguillarum, particularly during infections in vivo, will help to improve disease prevention and control. Thus, the aim of this thesis was to provide further insight into the infection biology of V. anguillarum with a view to identifying better ways to reduce the impact of this pathogen in aquaculture. Conventional studies on virulence, particularly those aiming to identify novel virulence factors, often employ transposon mutagenesis where the functions of individual genes in the bacterium are disrupted. These mutant libraries are screened to identify those with attenuated virulence, allowing subsequent identification of the gene responsible. Usually the native fish host would be used but such studies are increasingly difficult to perform due to regulations on vertebrate experiments and ethical concerns. As a result, alternative invertebrate hosts are now an important means to studying microbial infections, but few models have been assessed for bacterial pathogens of fish. In this thesis, larvae of the greater wax moth Galleria mellonella were evaluated as an alternative host to investigate V. anguillarum virulence. Wild-type V. anguillarum isolates killed larvae in a dose-dependent manner, replicated in the haemolymph, and larvae infected with a lethal dose of bacteria could be rescued by antibiotic therapy, thus indicating that V. anguillarum established an infection in G. mellonella. Crucially, virulence of 11 wild-type V. anguillarum isolates correlated significantly between larva and Atlantic salmon infection models, and studies with isogenic mutants knocked out for various virulence determinants revealed conserved roles for some in larva and fish infections, including the pJM1 virulence plasmid and rtxA toxin. Thereafter, 350 strains from a V. anguillarum random transposon insertion library were screened for attenuated virulence in G. mellonella. In total, 12 strains had reduced virulence and in these mutants the transposon had inserted into genes encoding several recognised and putative virulence factors, including a haemolytic toxin (vah1) and proteins involved in iron sequestration (angB/G and angN). Importantly, the transposon in one strain had inserted into an uncharacterised hypothetical protein. Preliminary investigations found this putative novel virulence factor to contain a GlyGly-CTERM sorting domain motif, with sequence similarity to VesB of Vibrio cholerae which is involved in post-translational processing of cholera toxin. Finally, three transposon insertion libraries were mass sequenced on a MiSeq platform to identify V. anguillarum genes lacking transposon insertions. These genes were assumed to be ‘required’ for viability in the conditions under which the mutants were selected, in this case tryptone soya agar. In total, 248 genes lacked a transposon insertion and were the putative ‘required’ genes, and these may be important chemotherapeutic targets for new approaches to combat V. anguillarum infections. This thesis has furthered our understanding of the biology of the important fish pathogen V. anguillarum using an ethically acceptable approach, and the findings may assist with new ways to reduce the burden of this bacterium in aquaculture.

639.3

Characterisation of chromatin extracellular traps in rainbow trout (Oncorhynchus mykiss)

Van, Andre P.

January 2018

One of the greatest challenges in finfish aquaculture is combating losses caused by infectious bacterial diseases, and a better understanding of the interactions between the host immune system and pathogens is essential for developing new methods to manage infections and outbreaks. Extracellular traps (ETs) are decondensed nuclear chromatin released by neutrophils into the extracellular matrix that can ensnare and kill microbes. Since the discovery of ETs in humans, these innate immune effectors have been characterised across the animal kingdom, including in some fish species, though their existence the salmonids has yet to be confirmed. Therefore, the aim of this thesis was to confirm and characterise the release of ETs in the rainbow trout (Oncorhynchus mykiss) and investigate the interaction of these structures with fish pathogenic bacteria. To do this, a triple-layer Percoll gradient technique was employed to give highly enriched cell suspensions of polymorphonuclear cells (PMNs) derived from head-kidney tissue preparations. Treatment of PMN-enriched cell suspensions with the nucleic-acid-specific stain, SYTOX Green, revealed the presence of ET-like structures that had been released without stimulation. These ET-like structures were confirmed by immunostaining techniques to contain the diagnostic proteinaceous markers of ETs: neutrophil elastase, myeloperoxidase and the H2A histone. Previously characterised inhibitors and inducers of ET release from phagocytic immune cells in other animals confirmed that calcium ionophore (CaI), flagellin, and cytochalasin D shared similar activities for ET-release by rainbow trout PMNs. However, interestingly, as the common ET-inducer phorbol-myristate acetate (PMA) and ET-inhibitor diphenyleneiodonium (DPI) did not exert their expected potency in ET release assays with the PMNs, perhaps indicating that these fish cells are less dependent on NADPH oxidase signalling for ET release compared to mammals and most invertebrate species. The PMN-derived ETs were demonstrated to bind to and trap the extracellular nuclease-deficient bacterial fish pathogen, Vibrio anguillarum (Vib 87) when co-cultured. Finally, extracellular nuclease activity produced by a V. anguillarum isolate (Vib 6) during culture was able to degrade ETs released by rainbow trout PMNs in a dose-dependent manner. Moreover, viable colony counts, fluorescent and phase contrast microscopy demonstrated that V. anguillarum Vib 6 eluded trapping by ETs, while an extracellular nuclease-deficient isolate did not. These observations are consistent with the suggestion that nucleases are a microbial virulence factor during host infection. Confirming the existence and antimicrobial potential of extracellular traps released by rainbow trout PMNs may provide a platform towards the development of novel therapeutics to reduce mortalities in finfish aquaculture caused by infectious microbial pathogens.