Identification of vhhP2, a novel genetic marker of Vibrio harveyi, and its application in the quick detection of V. harveyi from animal specimens and environmental samples

Vibrio harveyi co-infected with Cryptocaryon irritans to orange-spotted groupers Epinephelus coioides

The orange-spotted grouper (Epinephelus coioides) is a high economic value aquacultural fish in China, however, it often suffers from the outbreak of parasitic ciliate Cryptocaryon irritans as well as bacterium Vibrio harveyi which bring great loss in grouper farming. In the present study, we established a high dose C. irritans local-infected model which caused the mortality of groupers which showed low vitality and histopathological analysis demonstrated inflammatory response and degeneration in infected skin, gill and liver. In addition, gene expression of inflammatory cytokines was detected to assist the estimate of inflammatory response. Furthermore, we also found that the activity of Na⁺/K⁺ ATPase in gill was decreased in groupers infected C. irritans and the concentration of Na⁺/Cl^- in blood were varied. Base on the morbidity symptom occurring in noninfected organs, we hypothesized that the result of morbidity and mortality were due to secondary bacterial infection post parasitism of C. irritans. Moreover, four strains of bacteria were isolated from the infected site skin and liver of local-infected groupers which were identified as V. harveyi in accordance of phenotypic traits, biochemical characterization and molecular analysis of 16S rDNA genes, housekeeping genes (gyrB and cpn60) and species-specific gene Vhhp2. Regression tests of injecting the isolated strain V. harveyi has showed high pathogenicity to groupers. In conclusion, these findings provide the evidence of coinfections with C. irritans and V. harveyi in orange-spotted grouper.

Vibrio harveyi: a serious pathogen of fish and invertebrates in mariculture

Vibrio harveyi, which belongs to family Vibrionaceae of class Gammaproteobacteria, includes the species V. carchariae and V. trachuri as its junior synonyms. The organism is a well-recognized and serious bacterial pathogen of marine fish and invertebrates, including penaeid shrimp, in aquaculture. Diseased fish may exhibit a range of lesions, including eye lesions/blindness, gastro-enteritis, muscle necrosis, skin ulcers, and tail rot disease. In shrimp, V. harveyi is regarded as the etiological agent of luminous vibriosis in which affected animals glow in the dark. There is a second condition of shrimp known as Bolitas negricans where the digestive tract is filled with spheres of sloughed-off tissue. It is recognized that the pathogenicity mechanisms of V. harveyi may be different in fish and penaeid shrimp. In shrimp, the pathogenicity mechanisms involved the endotoxin lipopolysaccharide, and extracellular proteases, and interaction with bacteriophages. In fish, the pathogenicity mechanisms involved extracellular hemolysin (encoded by duplicate hemolysin genes), which was identified as a phospholipase B and could inactivate fish cells by apoptosis, via the caspase activation pathway. V. harveyi may enter the so-called viable but nonculturable (VBNC) state, and resuscitation of the VBNC cells may be an important reason for vibriosis outbreaks in aquaculture. Disease control measures center on dietary supplements (including probiotics), nonspecific immunostimulants, and vaccines and to a lesser extent antibiotics and other antimicrobial compounds.

The management and exploitation of naturally light-emitting bacteria as a flexible analytical tool: A tutorial

Conventional detection of toxic contaminants on surfaces, in food, and in the environment takes time. Current analytical approaches to chemical detection can be of limited utility due to long detection times, high costs, and the need for a laboratory and trained personnel. A non-specific but easy, rapid, and inexpensive screening test can be useful to quickly classify a specimen as toxic or non toxic, so prompt appropriate measures can be taken, exactly where required. The bioluminescent bacteria-based tests meet all these characteristics. Bioluminescence methods are extremely attractive because of their high sensitivity, speed, ease of implementation, and statistical significance. They are usually sensitive enough to detect the majority of pollutants toxic to humans and mammals. This tutorial provides practical guidelines for isolating, cultivating, and exploiting marine bioluminescent bacteria as a simple and versatile analytical tool. Although mostly applied for aqueous phase sample and organic extracts, the test can also be conducted directly on soil and sediment samples so as to reflect the true toxicity due to the bioavailability fraction. Because tests can be performed with freeze-dried cell preparations, they could make a major contribution to field screening activity. They can be easily conducted in a mobile environmental laboratory and may be adaptable to miniaturized field instruments and field test kits.

Ferritin M of Cynoglossus semilaevis: an iron-binding protein and a broad-spectrum antimicrobial that depends on the integrity of the ferroxidase center and nucleation center for biological activity

Ferritin is a major intracellular iron storage protein in higher vertebrates and plays an important role in iron metabolism. In this study, we identified and analyzed the biological activity of a ferritin M subunit (CsFerM) from half-smooth tongue sole (Cynoglossus semilaevis). The open reading frame (ORF) of CsFerM is 534 bp and encodes a protein that shares 79.7-86.4% overall sequence identities with the ferritin M subunits of a number of teleosts. In silico analysis identified in CsFerM a eukaryotic ferritin domain with conserved ferroxidase diiron center and ferrihydrite nucleation center. Quantitative real time RT-PCR analysis showed that under normal physiological conditions, expression of CsFerM was highest in liver, moderate in gill, spleen, and muscle, and low in gut, heart, and brain. Following experimental challenge with bacterial pathogens, CsFerM expression was significantly upregulated in kidney, spleen, and liver in time-dependent manners. Biological activity analysis showed that recombinant CsFerM purified from Escherichia coli exhibited apparent iron-binding activity and, when present in the culture medium of six different species of fish bacterial pathogens, completely inhibited bacterial growth. In contrast, a mutant CsFerM that bears alanine substitution at two conserved residues of the ferroxidase diiron center and ferrihydrite nucleation center was abolished in both iron-binding and antimicrobial capacity. These results demonstrate that CsFerM is a biologically active iron chelator with broad-spectrum antibacterial activity, which suggests a role for CsFerM in not only iron storage but also innate immunity. These results also indicate the importance of the conserved iron uptake and mineralization sites to the function of CsFerM.

The g-type lysozyme of Scophthalmus maximus has a broad substrate spectrum and is involved in the immune response against bacterial infection

Lysozyme is a muramidase that inflicts damage on bacterial cell wall by catalyzing the cleavage of the beta-1,4-glycosidic bond between N-acetylmuramic acid and N-acetylglucosamine in peptidoglycan. Lysozymes are classified into several types, one of which is the goose-type (g-type). In this study, we identified and analyzed a g-type lysozyme (SmLysG) from turbot Scophthalmus maximus. The deduced amino acid sequence of SmLysG contains 193 residues and is most closely related to that of the g-type lysozyme of Scophthalmus rhombus (94% overall identity). SmLysG possesses a Goose Egg White Lysozyme (GEWL) domain with conserved residues essential for catalytic activity. Recombinant SmLysG (rSmLysG) purified from yeast exhibits strong lysozyme activity against Micrococcus luteus. Enzyme assays showed that the optimal temperature and pH of rSmLysG are 30°C and pH 7.0, respectively. Substrate spectrum analysis indicated that rSmLysG inhibited the growth of a number of important fish pathogens of both Gram-negative and Gram-positive natures. SmLysG transcription was detected in multiple tissues and was upregulated in kidney and spleen by experimental challenges with lipopolysaccharide and bacterial pathogens that are, respectively, sensitive to and resistant against the lytic effect of rSmLysG. Comparative analysis showed that although bacterial infection also induced the expression of c-type lysozyme, the induction levels were much lower than those of SmLysG. Taken together, these results indicate that SmLysG is a functional g-type lysozyme with a wide working range and is involved in innate immune defense against general bacterial infection.