Defined Deletion Mutants Demonstrate that the Major Secreted Toxins Are Not Essential for the Virulence of Aeromonas salmonicida

The importance of the two major extracellular enzymes of Aeromonas salmonicida, glycerophospholipid:cholesterol acyltransferase (GCAT) and a serine protease (AspA), to the pathology and mortality of salmonid fish with furunculosis had been indicated in toxicity studies. In this study, the genes encoding GCAT (satA) and AspA (aspA) have been cloned and mutagenized by marker replacement of internal deletions, and the constructs have been used for the creation of isogenic satA and aspA mutants of A. salmonicida. A pSUP202 derivative (pSUP202sac) carrying the sacRB genes was constructed to facilitate the selection of mutants. The requirement of serine protease for processing of pro-GCAT was demonstrated. Processing involved the removal of a short internal fragment. Surprisingly, pathogenicity trials revealed no major decrease in virulence of the A. salmonicida ΔsatA::kan or A. salmonicida ΔaspA::kan mutants compared to the wild-type parent strains when Atlantic salmon (Salmo salar L.) were challenged by intraperitoneal injection. Moreover, using a cohabitation model, which more closely mimics the natural disease, there was also no significant decrease in the relative cumulative mortality following infection with either of the deletion mutants compared to the parent strain. Thus, although these two toxins may confer some competitive advantage to A. salmonicida, neither toxin is essential for the very high virulence of A. salmonicida in Atlantic salmon. This first report of defined deletion mutations within any proposed extracellular virulence factor of A. salmonicida raises crucial questions about the pathogenesis of this important fish pathogen.     

Mutation of a novel virulence-related gene mltD in Vibrio anguillarum enhances lethality in zebra fish

Vibrio anguillarum, a halophilic Gram-negative bacterium, is the causative agent of vibriosis, which is a major problem for the aquaculture industry worldwide. Previously, a virulence-related gene fragment of V. anguillarum was obtained from a suppression subtractive hybridization (SSH) library. In this study, the complete gene sequence was obtained by long and accurate PCR (LA-PCR). After sequence analysis and homologous comparison, this new virulence-related gene was revealed to encode a putative membrane-bound lytic murein transglycosylase D (MltD), which consisted of 547 amino acids, and showed 34% identity to the MltD in Escherichia coli. An mltD mutant of pathogenic V. anguillarum CW-1 was constructed by homologous recombination. Production of extracellular gelatinase and protease of the mltD mutant decreased markedly compared with those of the wild-type strain, and the hemolytic activity was totally lost. Sodium chloride challenge and antibiotic sensitivity assay showed that the resistance of the mltD mutant to high concentrations of sodium chloride, and rocephin, fortun, cefobid, gentamicin, kanamycin and carbenicillin was enhanced. Most importantly, virulence of the mltD mutant was enhanced compared with that of the wild type when it was inoculated intraperitoneally into zebra fish; the LD₅₀ of the wild type and the mutant was 3.92 × 10³ CFU and 1.01 × 10² CFU fish⁻¹, respectively. The mltD was cloned and overexpressed in E. coli, and the recombinant MltD protein showed hemolytic, phospholipase, gelatinase and diastase activities. This is the first report that MltD possibly has a virulence-related function.     

Comparison of 16SrDNA and toxR genes as targets for detection of Vibrio anguillarum in Dicentrarchus labrax kidney and liver

Vibrio anguillarum is a pathogen that causes high mortality in marine and freshwater fish. The aim of this study was to develop a real-time PCR assay for identification and quantification of V. anguillarum in fish tissue. The assay was carried out using two target genes, 16SrDNA and toxR, to evaluate the influence of differences in the operon copy number in quantitative assessment, both in pure cultures of V. anguillarum serovar O1 (strain 975/I), as a reference, and in the liver and kidney of a sea bass (Dicentrarchus labrax) specimen. Real-time PCR analysis showed high specificity for both target genes, with a detection limit of approximately 1-10 bacterial cells per reaction in pure culture and 10/100 V. anguillarum cells per reaction in fish tissue, which corresponds to 2 × 10²/2 × 10³ cells g⁻¹ fish tissue. Moreover, both genes showed high specificity but differing sensitivity due to the different operon copy number; as a result, it is possible to target the high copy number gene to improve sensitivity. Our results suggest that the protocol we tested can be used as a sensitive and specific molecular method for the detection of the fish pathogen V. anguillarum in fish tissue.     

Campylobacter jejuni: A brief overview on pathogenicity-associated factors and disease-mediating mechanisms

Campylobacter jejuni has long been recognized as a cause of bacterial food-borne illness, and surprisingly, it remains the most prevalent bacterial food-borne pathogen in the industrial world to date. Natural reservoirs for this Gram-negative, spiral-shaped bacterium are wild birds, whose intestines offer a suitable biological niche for the survival and dissemination of C. jejuni Chickens become colonized shortly after birth and are the most important source for human infection. In the last decade, effective intervention strategies to limit infections caused by this elusive pathogen were hindered mainly because of a paucity in understanding the virulence mechanisms of C. jejuni and in part, unavailability of an adequate animal model for the disease. However, recent developments in deciphering molecular mechanisms of virulence of C. jejuni made it clear that C. jejuni is a unique pathogen, being able to execute N-linked glycosylation of more than 30 proteins related to colonization, adherence, and invasion. Moreover, the flagellum is not only depicted to facilitate motility but as well secretion of Campylobacter invasive antigens (Cia). The only toxin of C. jejuni, the so-called cytolethal distending toxin (CdtA,B,C), seems to be important for cell cycle control and induction of host cell apoptosis and has been recognized as a major pathogenicity-associated factor. In contrast to other diarrhoea-causing bacteria, no other classical virulence factors have yet been identified in C. jejuni. Instead, host factors seem to play a major role for pathogenesis of campylobacteriosis of man. Indeed, several lines of evidence suggest exploitation of different adaptation strategies by this pathogen depending on its requirement, whether to establish itself in the natural avian reservoir or during the course of human infection.     

Transfer of serum and cells from Yersinia ruckeri vaccinated doubled-haploid hot creek rainbow trout into outcross F1 progeny elucidates mechanisms of vaccine-induced protection

Yersinia ruckeri is a well-established bacterial pathogen for many salmonid species, against which a formalin-killed bacterin vaccine has been effective in reducing disease outbreaks. Previous studies have reported conflicting results about the protective value of the systemic humoral response to Y. ruckeri vaccination. Here we directly demonstrate that plasma contains the long-term protective component elicited by both immersion and intraperitoneal injection vaccination of rainbow trout. A total of 0.5 μL of plasma from vaccinated fish provided almost complete protection against experimental challenge. Conversely, the cells obtained from peripheral blood conferred little or no protection in naïve recipients. The protective component of immune sera was IgM based on size exclusion chromatography and recognition by monoclonal antibody Warr 1–14. Immune plasma generated against a Y. ruckeri biotype 1 strain protected equally against challenges with Y. ruckeri biotype 1 and 2 strains. These results illustrate the importance of the humoral IgM response against Y. ruckeri and the use of doubled haploid rainbow trout (Oncorhynchus mykiss) and transfer of plasma/serum and cells into F1 outcross progeny as a model system for dissection of the mechanism(s) of vaccine-induced protection.     

The Aeromonas dsbA mutation decreased their virulence by triggering type III secretion system but not flagella production

Pathogenesis of Aeromonas species have been reported to be associated with virulence factors such as lipopolysaccharides (LPS), bacterial toxins, bacterial secretion systems, flagella, and other surface molecules. Dsb (Disulfide bond) proteins play an important role in catalyzing disulfide bond formation in proteins within the periplasmic space. An A. hydrophila dsbA mutant with attenuated virulence using Dictyostelium amoebae as an alternative host model was identified. The attenuated virulence was tested in other animal models (by intraperitoneal injection in fish and mice) and was correlated with the presence of a defective type III secretion system for the first time in non enteric bacteria. The dsbA mutation was shown in several enteric bacteria to involve the outer membrane secretin. The defect in Aeromonas also seems to involve the outer membrane secretin homologue named AscC. However, unlike what happen in Escherichia coli, no changes in motility or flagella expression were observed for A. hydrophila dsbA mutants. The loss of E. coli motility caused by deletion of dsbA is likely due to defective disulfide bond formation in FlgI, a component of the flagella. No disulfide bond formation in FlgI homologues in Aeromonas flagella biogenesis, either polar or lateral, could be expected according to their amino acid residues sequences.     

Visualisation of zebrafish infection by GFP-labelled Vibrio anguillarum

Vibrio anguillarum is an invasive pathogen of fish causing a septicaemia called vibriosis. In this work, transparent zebrafish were immersed in water containing green fluorescent protein labelled V. anguillarum. The infection was visualised at the whole fish and single bacterium levels using microscopy. The gastrointestinal tract was the first site where the pathogen was detected. This enteric localisation occurred independently of the flagellum or motility. On the other hand, chemotactic motility was essential for association of the pathogen with the fish surface. In conclusion, the zebrafish infection model provides evidence that the intestine and skin represent sites of infection by V. anguillarum and suggests a host site where chemotaxis may function in virulence.     

H-NS: an overarching regulator of the Vibrio cholerae life cycle

Vibrio cholerae has become a model organism for studies connecting virulence, pathogen evolution and infectious disease ecology. The coordinate expression of motility, virulence and biofilm enhances its pathogenicity, environmental fitness and fecal-oral transmission. The histone-like nucleoid structuring protein negatively regulates gene expression at multiple phases of the V. cholerae life cycle. Here we discuss: (i) the regulatory and structural implications of H-NS chromatin-binding in the two-chromosome cholera bacterium; (ii) the factors that counteract H-NS repression; and (iii) a model for the regulation of the V. cholerae life cycle that integrates H-NS repression, cyclic diguanylic acid signaling and the general stress response.     

LitR of Vibrio salmonicida is a salinity-sensitive quorum-sensing regulator of phenotypes involved in host interactions and virulence

Vibrio (Aliivibrio) salmonicida is the causal agent of cold-water vibriosis, a fatal bacterial septicemia primarily of farmed salmonid fish. The molecular mechanisms of invasion, colonization, and growth of V. salmonicida in the host are still largely unknown, and few virulence factors have been identified. Quorum sensing (QS) is a cell-to-cell communication system known to regulate virulence and other activities in several bacterial species. The genome of V. salmonicida LFI1238 encodes products presumably involved in several QS systems. In this study, the gene encoding LitR, a homolog of the master regulator of QS in V. fischeri, was deleted. Compared to the parental strain, the litR mutant showed increased motility, adhesion, cell-to-cell aggregation, and biofilm formation. Furthermore, the litR mutant produced less cryptic bioluminescence, whereas production of acylhomoserine lactones was unaffected. Our results also indicate a salinity-sensitive regulation of LitR. Finally, reduced mortality was observed in Atlantic salmon infected with the litR mutant, implying that the fish were more susceptible to infection with the wild type than with the mutant strain. We hypothesize that LitR inhibits biofilm formation and favors planktonic growth, with the latter being more adapted for pathogenesis in the fish host.     

The outer membrane protein A (OmpA) of Yersinia pestis promotes intracellular survival and virulence in mice

The plague bacterium Yersinia pestis has a number of well-described strategies to protect itself from both host cells and soluble factors. In an effort to identify additional anti-host factors, we employed a transposon site hybridization (TraSH)-based approach to screen 10⁵Y. pestis mutants in an in vitro infection system. In addition to loci encoding various components of the well-characterized type III secretion system (T3SS), our screen unambiguously identified ompA as a pro-survival gene. We go on to show that an engineered Y. pestis ΔompA strain, as well as a ΔompA strain of the closely related pathogen Yersinia pseudotuberculosis, have fully functioning T3SSs but are specifically defective in surviving within macrophages. Additionally, the Y. pestis ΔompA strain was out competed by the wild-type strain in a mouse co-infection assay. Unlike in other bacterial pathogens in which OmpA can promote adherence, invasion, or serum resistance, the OmpA of Y. pestis is restricted to enhancing intracellular survival. Our data show that OmpA of the pathogenic Yersinia is a virulence factor on par with the T3SS.     

Aeromonas salmonicida Binds Differentially to Mucins Isolated from Skin and Intestinal Regions of Atlantic Salmon in an N-Acetylneuraminic Acid-Dependent Manner

Aeromonas salmonicida subsp. salmonicida infection, also known as furunculosis disease, is associated with high morbidity and mortality in salmonid aquaculture. The first line of defense the pathogen encounters is the mucus layer, which is predominantly comprised of secreted mucins. Here we isolated and characterized mucins from the skin and intestinal tract of healthy Atlantic salmon and studied how A. salmonicida bound to them. The mucins from the skin, pyloric ceca, and proximal and distal intestine mainly consisted of mucins soluble in chaotropic agents. The mucin density and mucin glycan chain length from the skin were lower than were seen with mucin from the intestinal tract. A. salmonicida bound to the mucins isolated from the intestinal tract to a greater extent than to the skin mucins. The mucins from the intestinal regions had higher levels of sialylation than the skin mucins. Desialylating intestinal mucins decreased A. salmonicida binding, whereas desialylation of skin mucins resulted in complete loss of binding. In line with this, A. salmonicida also bound better to mammalian mucins with high levels of sialylation, and N-acetylneuraminic acid appeared to be the sialic acid whose presence was imperative for binding. Thus, sialylated structures are important for A. salmonicida binding, suggesting a pivotal role for sialylation in mucosal defense. The marked differences in sialylation as well as A. salmonicida binding between the skin and intestinal tract suggest interorgan differences in the host-pathogen interaction and in the mucin defense against A. salmonicida.     

The winter ulcer bacterium Moritella viscosa demonstrates adhesion and cytotoxicity in a fish cell model

Moritella viscosa is considered the main aetiological agent of ‘winter ulcer’ disease in farmed salmonid fish. To further understand the pathogenesis of this disease, M. viscosa interaction with fish cells was studied using a Chinook salmon embryo cell line (CHSE-214). As winter ulcer appears exclusively at temperatures below 7–8 °C, we attempted to identify if this connection is explained by temperature regulated bacterial virulence. Therefore, infection studies were performed at a temperature range from 4 to 15 °C. At all temperatures, M. viscosa caused CHSE cells to retract and round up, lose their attachment abilities and finally disintegrate. The bacterium adhered to CHSE cells and caused changes to the cytoskeleton, however, it did not invade the cells. Increased adherence was demonstrated at 4 °C compared to adherence at higher temperatures. Extracellular proteins exerted rapid pore formation and lysis of CHSE cells at a temperature range from 4 to 22 °C. Furthermore, only small differences were found comparing extracellular proteomes of M. viscosa from 4 and 15 °C. We propose that the pathogenic mechanisms exerted by M. viscosa on CHSE cells are disruption of the cytoskeleton which affects cell rigidity and structure, followed by pore formation and lysis caused by secreted products from the bacterium. These processes can also occur at temperatures above those experienced from winter ulcer outbreaks. However, the adhesion mechanisms appear to be temperature regulated and may contribute to temperature dependent disease outbreaks.     

IscR Is a Global Regulator Essential for Pathogenesis of Vibrio vulnificus and Induced by Host Cells

A mutant that exhibited less cytotoxic activity toward INT-407 human intestinal epithelial cells than the wild type was screened from a random transposon mutant library of Vibrio vulnificus, and an open reading frame encoding an Fe-S cluster regulator, IscR, was identified using a transposon-tagging method. A mutational analysis demonstrated that IscR contributes to mouse mortality as well as cytotoxicity toward the INT-407 cells, indicating that IscR is essential for the pathogenesis of V. vulnificus. A whole-genome microarray analysis revealed that IscR influenced the expression of 67 genes, of which 52 were upregulated and 15 were downregulated. Among these, 12 genes most likely involved in motility and adhesion to host cells, hemolytic activity, and survival under oxidative stress of the pathogen during infection were selected and experimentally verified to be upregulated by IscR. Accordingly, the disruption of iscR resulted in a significant reduction in motility and adhesion to INT-407 cells, in hemolytic activity, and in resistance to reactive oxygen species (ROS) such as H₂O₂ and tert-butyl hydroperoxide (t-BOOH). Furthermore, the present study demonstrated that iscR expression was induced by exposure of V. vulnificus to the INT-407 cells, and the induction appeared to be mediated by ROS generated by the host cells during infection. Consequently, the combined results indicated that IscR is a global regulator that contributes to the overall success in the pathogenesis of V. vulnificus by regulating the expression of various virulence and survival genes in addition to Fe-S cluster genes.     

Zebrafish as a useful model for zoonotic Vibrio parahaemolyticus pathogenicity in fish and human

Vibrio parahaemolyticus is an important aquatic zoonotic pathogen worldwide that causes vibriosis in many marine fish, and sepsis, gastroenteritis and wound infection in humans. However, the pathogenesis of different sources of V. parahaemolyticus is not fully understood. Here, we examined the pathogenicity and histopathology of fish (V. parahaemolyticus 1.2164) and human (V. parahaemolyticus 17) strains in a zebrafish (Danio rerio). We found that different infection routes resulted in different mortality in zebrafish. Moreover, death due to V. parahaemolyticus 1.2164 infection occurred quicker than that caused by V. parahaemolyticus 17 infection. Hematoxylin-eosin staining of liver, kidney and intestine sections showed histological lesions in all three organs after infection with either strain. V. parahaemolyticus 1.2164 caused more severe damage than V. parahaemolyticus 17. In particular, V. parahaemolyticus 1.2164 treatment induced more serious hydropic degeneration and venous sinus necrosis in the liver than V. parahaemolyticus 17 treatment. The expression levels of three proinflammatory cytokines, interleukin 1β (il1β), interferon phi 1 (ifnϕ1) and tumor necrosis factor α (tnfα), as determined by quantitative real-time PCR, were upregulated in all examined tissues of infected fish. Notably, the peak levels of tnfα were significantly higher than those of il1β and ifnϕ1, suggesting, together with pathological results, that tnfα and il1β play an important role in acute sepsis. High amounts of tnfα may be related to acute liver necrosis, while ifnϕ1 may respond to V. parahaemolyticus and play an antibacterial role for chronically infected adult zebrafish. Taken together, our results suggest that the zebrafish model of V. parahaemolyticus infection is useful for studying strain differences in V. parahaemolyticus pathogenesis.     

The bane of coastal marine environment: A fatal case of Vibrio vulnificus associated cellulitis and septicaemia

Vibrio vulnificus is a Gram negative motile bacterium known to cause fatal septicaemia and wound infection. It is commonly associated with the consumption of under-cooked seafood or exposure to marine environment. We report a case of a 55 year old male patient, who was presented with right lower limb cellulitis and septicaemia due to V. vulnificus. V. vulnificus infection in India are rare. However, increasing reports of V. vulnificus from India recommends considering the pathogen while dealing necrotising fasciitis especially in the proximity of marine environment.     

Large antibiotic-resistance plasmid of Edwardsiella tarda contributes to virulence in fish

Edwardsiella tarda, an enteric gram negative bacterium, infects a wide range of fish and causes a systemic fish disease called edwardsiellosis. E. tarda CK41, isolated from Japanese flounder diagnosed with edwardsiellosis, has exhibited a high degree of resistance to multiple antibiotics, including kanamycin, tetracycline, streptomycin, among others. As the bacterial antibiotic-resistance genes are usually contained in plasmids, we hypothesized that E. tarda CK41 may harbor one or more plasmids for antibiotic resistance. We showed the existence of plasmids in E. tarda CK41, and the size of the plasmid, designated as pCK41, was estimated to be approximately 70 kb. Escherichia coli DH5α transformed by the pCK41 plasmid exhibited an antibiotic-resistance phenotype against kanamycin (30 μg/mL), tetracycline (30 μg/mL), and streptomycin (10 μg/mL), indicating the existence of at least 3 antibiotic-resistance genes in pCK41. Through a procedure for pCK41 plasmid curing, a plasmid-cured strain, designated as E. tarda CK108, was identified, which was unable to grow in the presence of either kanamycin or tetracycline. As virulence-associated genes are occasionally encoded in bacterial plasmids, we examined the virulence of E. tarda CK108 in Japanese flounder. The virulence of plasmid-cured E. tarda CK108 was lower (survival rate 80%) than that of CK41 (20%), indicating the existence of virulence-associated genes in pCK41. The strain also appeared to be attenuated in both goldfish and zebrafish pathogenesis models. To analyze genes for antibiotic resistance and virulence in pCK41, the entire nucleotide sequences of pCK41 were determined (GenBank accession number: HQ332785). A total of 84 open reading frames (ORFs) were annotated. The pCK41 plasmid consists of potential virulence genes, transposases, plasmid maintenance genes, antibiotic-resistance genes (including kanamycin, tetracycline, and streptomycin), conjugal transfer genes, and unknown ORFs. These results suggest that pCK41 is a virulence plasmid of substantial importance in the E. tarda pathogenesis to fish.