Characterization of an iridovirus detected from cultured turbot Scophthalmus maximus in Korea

Juvenile turbot Scophthalmus maximus that became sick during an outbreak of disease at mariculture facilities at Go-Chang, Korea, in 2003, were examined to identify the cause of the disease. The fish had pale body color, an enlarged abdomen, protruding eyes, an enlarged spleen and kidney, and pale gills and/or liver. Histopathogical examination revealed basophilic enlarged cells in the kidney, spleen, gills, heart, stomach, intestine, liver, pancreas and skin. Hexagonal viral particles with a diameter of 136 to 159 nm were observed in the enlarged cells. A specific 1299 bp fragment of the major capsid protein (MCP) gene of the turbot iridovirus (TBIV) was amplified by PCR. Sequence homology was greater than 93.76% between the MCP gene in TBIV and the same gene in 5 viruses in the tentatively proposed genus Tropivirus (family Iridoviridae): red sea bream iridovirus, sea bass iridovirus, grouper sleepy disease iridovirus, African lampeye iridovirus and dwarf gourami iridovirus. These results suggest that the virus detected from turbot is similar to the proposed genus Tropivirus.     

云斑尖塘鳢肿大细胞病毒属虹彩病毒的分离与鉴定

2009年10月, 广东顺德地区一云斑尖塘鳢养殖场暴发不明病因疾病, 发病尖塘鳢体长15-18 cm不等,死亡率约85%, 濒死尖塘鳢从池塘底层游至水面, 呈现游动失衡状态直至死亡。死亡尖塘鳢腹部膨大,剖检可见肝脏、脾脏、肾脏肿大, 有出血斑点, 从内脏器官肝脏、脾脏和肾脏未分离到致病菌。病鱼内脏组织研磨过滤除菌后,腹腔注射20尾尖塘鳢, 7d后开始出现死亡, 10d后全部死亡, 对照组无死亡。自然发病鱼和人工感染鱼的病理切片显示肝脏、脾脏和肾脏出现大量肿大细胞,超薄切片经电子显微镜观察, 肝脏、脾脏和肾脏观察到大量病毒颗粒。电镜下病毒呈六边形,直径约135 nm,形态与虹彩病毒相似。针对虹彩病毒主衣壳蛋白(Major capsid protein,MCP)序列设计引物,提取自然发病鱼和人工感染鱼的DNA作为模板, 均能扩增出预期大小的特异性产物。利用NCBI的Blast搜索, 结果显示扩增序列与肿大细胞病毒属的传染性脾肾坏死病毒(ISKNV)、闪电丽鱼虹彩病毒(DGIV)和条石鲷虹彩病毒(RBIV)MCP核苷酸序列同源性分别为98.8%、98.1%和94.7%。利用MCP序列构建的系统发育树显示, 导致云斑尖塘鳢发病死亡的病毒为肿大细胞病毒属虹彩病毒, 暂命名云斑尖塘鳢虹彩病毒(MSGIV)。       

Development of siRNA expression vector utilizing rock bream β-actin promoter: a potential therapeutic tool against viral infection in fish

In the present study, we have developed short interfering RNA (siRNA) expression vector utilizing rock bream β-actin promoter and examined the possible use for the inhibition of highly pathogenic fish virus, rock bream iridovirus (RBIV), replication in vitro. Initially, in order to express siRNA effectively, we added several modifications to wild-type rock bream β-actin promoter. Next, we succeeded in knocking down the expression of enhanced green fluorescent protein reporter gene expression in fish cells using newly developed vector more effectively than the fugu U6 promoter-driven vector we described previously. Finally, we could observe that cells transfected with modified rock bream β-actin promoter-driven siRNA expression vector targeting major capsid protein (MCP) gene of RBIV exhibited more resistance to RBIV challenge than other control cells. Our results indicate that this novel siRNA expression vector can be used as a new tool for therapeutics in virus infection in fish species.     

Pathology, isolation, and preliminary molecular characterization of a novel iridovirus from tiger salamanders in Saskatchewan.

All iridovirus was confirmed to be the cause of an epizootic in larval and adult tiger salamanders (Ambystoma tigrinum diaboli) from four separate ponds in southern Saskatchewan (Canada) during the summer of 1997. This organism also is suspected, based on electron microscopic findings, to be the cause of mortality of larval tiger salamanders in a pond over 200 km to the north during the same year. Salamanders developed a generalized viremia which resulted in various lesions including: necrotizing, vesicular and ulcerative dermatitis; gastrointestinal ulceration; and necrosis of hepatic, splenic, renal, lymphoid, and hematopoietic tissues. In cells associated with these lesions, large lightly basophilic cytoplasmic inclusions and vacuolated nuclei with marginated chromatin were consistently found. Virus was isolated from tissue homogenates of infected salamanders following inoculation of epithelioma papilloma cyprini (EPC) cells. The virus, provisionally designated Regina ranavirus (RRV), was initially identified as an iridovirus by electron microscopy. Subsequent molecular characterization, including partial sequence analysis of the major capsid protein (MCP) gene, confirmed this assignment and established that RRV was a ranavirus distinct from frog virus 3 (FV3) and other members of the genus Ranavirus. Intraperitoneal inoculation of 5 x 10(6.23) TCID50 of the field isolate caused mortality in inoculated salamanders at 13 days post infection. Field, clinical, and molecular studies jointly suggest that the etiological agent of recent salamander mortalities is a highly infectious novel ranavirus.     

鳜鱼传染性脾肾坏死病毒(ISKNV)PCR检测方法的建立及虹彩病毒新证据

利用真鲷虹彩病毒（ＲＳＩＶ）核苷酸还原酶小亚单位（ＲＮＲＳ）基因保守区设计的一对引物,建立了鳜鱼传染性脾肾坏死病毒（ＩＳＫＮＶ）特异的ＰＣＲ检测体系。运用该体系检测ＩＳＫＮＶ,具有简便、快速、敏感、特异等特点,为诊断与预防ＩＳＫＮＶ提供了一个重要的手段。通过对ＰＣＲ产物的克隆与序列分析,发现ＩＳＫＮＶ ＰＣＲ扩增产物与ＲＳＩＶ ＲＮＲＳ基因相应序列的同源性很高,达到９２．５％,进一步证明ＩＳＫＮＶ     

Production and characterization of polyclonal antibody against recombinant ORF 049L of rock bream (Oplegnathus fasciatus) iridovirus

Rock bream iridovirus (RBIV) is a causative agent of epizootics among cultured rock bream (Oplegnathus fasciatus) in Korea. The structure of the isolated RBIV was observed by an electron microscope, and the virus particles were icosahedral and 120–130 nm in diameter. From the complete genomic DNA sequence of RBIV, the protein encoded in ORF 049L (RBIV-049L) was selected and the property of protein was evaluated with the transmembrane sequence TMHMM 2.0 tool. The ORF 049L gene of RBIV (RBIV-049L) was cloned into pGEX-4T-1 expression vector. The recombinant RBIV-049L was overexpressed in Escherichia coli BL21 (DE3) as a fusion protein (GST-049L, 42 kDa) with a glutathione S-transferase. Antiserum against this recombinant GST-049L protein was prepared in mouse. Dot blot analysis was carried out to identify the reaction abilities and sensitivity of anti-RBIV-049L polyclonal antibody to RBIV-infected rock bream with enzyme linked immunosorbent assay (ELISA) and one-step PCR. These novel RBIV-049L protein and anti-RBIV-049L polyclonal antibody will facilitate the development of more specific and standardized diagnostic techniques.     

Histopathological and ultrastructural features of enlarged cells of humpback grouper Cromileptes altivelis challenged with Megalocytivirus (family Iridoviridae) after vaccination

The genus Megalocytivirus in the family Iridoviridae encompasses isolates of red sea bream iridovirus (RSIV) and grouper sleepy disease iridovirus (GSDIV). In the present study, humpback grouper Cromileptes altivelis juveniles were challenged with GSDIV after vaccination with a commercial RSIV vaccine. The unvaccinated group (in duplicate) showed higher mortalities (59.3 to 66.7%) than the vaccination group (0% mortalitiy, in duplicate). Surviving fish in the vaccinated group displayed masses of enlarged cells in the spleen. Electron microscopy revealed that they contained hemosiderin granules within the cytoplasm. In contrast, moribund fish from the unvaccinated group exhibited large numbers of inclusion body-bearing cells (IBCs) in the spleen, while surviving fish displayed masses of enlarged cells in which a small number of GSDIV virions were assembled.     

Iridoviruses associated with epizootic haematopoietic necrosis (EHN) in aquaculture

Systemic infections of teleost fishes caused by iridoviruses have recently been recognized in Australia, Asia, Europe and the USA. These iridoviruses are different from those of the established genera Lymphocystivirus and Goldfish Virus 1-like Viruses of the family Iridoviridae. The agents exhibit similar physicochemical properties, are antigenically related and prove to be of high virulence to different teleost fishes in aquaculture. The first iridovirus, epizootic haematopoietic necrosis virus, responsible for an epizootic outbreak of haematopoietic necrosis in redfin perch, was reported in Australia. Some years later, similar iridovirus epizootics occurred in sheatfish and catfish in Europe. The Australian and the European isolates proved to be antigenically related and showed properties in common with frog virus 3, the type species of the genus Ranavirus of the Iridoviridae. Further iridovirus isolates from fish, amphibians and reptiles exhibited a close relationship with each other and with frog virus 3. It is important to note that the Australian amphibian iridovirus, Bohle iridovirus, was experimentally transmitted to teleost fish inducing high mortalities. The occurrence of similar viruses in different host species in the aquatic environment and their inter-species transmission emphasize the importance of health control in aquaculture.     

Evidence for emergence of an amphibian iridoviral disease because of human-enhanced spread

Our understanding of origins and spread of emerging infectious diseases has increased dramatically because of recent applications of phylogenetic theory. Iridoviruses are emerging pathogens that cause global amphibian epizootics, including tiger salamander (Ambystoma tigrinum) die-offs throughout western North America. To explain phylogeographical relationships and potential causes for emergence of western North American salamander iridovirus strains, we sequenced major capsid protein and DNA methyltransferase genes, as well as two noncoding regions from 18 geographically widespread isolates. Phylogenetic analyses of sequence data from the capsid protein gene showed shallow genetic divergence (< 1%) among salamander iridovirus strains and monophyly relative to available fish, reptile, and other amphibian iridovirus strains from the genus Ranavirus, suggesting a single introduction and radiation. Analysis of capsid protein sequences also provided support for a closer relationship of tiger salamander virus strains to those isolated from sport fish (e.g. rainbow trout) than other amphibian isolates. Despite monophyly based on capsid protein sequences, there was low genetic divergence among all strains (< 1.1%) based on a supergene analysis of the capsid protein and the two noncoding regions. These analyses also showed polyphyly of strains from Arizona and Colorado, suggesting recent spread. Nested clade analyses indicated both range expansion and long-distance colonization in clades containing virus strains isolated from bait salamanders and the Indiana University axolotl (Ambystoma mexicanum) colony. Human enhancement of viral movement is a mechanism consistent with these results. These findings suggest North American salamander ranaviruses cause emerging disease, as evidenced by apparent recent spread over a broad geographical area.     

Duck plague epizootics in the United States, 1967-1995

In 1967, the first confirmed diagnosis of duck plague (DP) in the USA was made from pekin ducks (Anas platyrhynchos domesticus) on commercial duck farms on Long Island, New York. Within 10 mo, DP was confirmed as the cause of death in migratory waterfowl on a Long Island bay. This paper reviews 120 DP epizootics reported from 1967 to 1995 that involved waterfowl species native to North America or were reported in areas with free-flying waterfowl at risk. Duck plague epizootics occurred in 21 states with the greatest number reported in Maryland (29), New York (18), California (16), and Pennsylvania (13). The greatest frequency of epizootics (86%) was detected during the months of March to June. At least 40 waterfowl species were affected with the highest frequency of epizootics reported in captive or captive-reared ducks including muscovy ducks (Cairina moschata) (68%), mallard ducks (A. platyrhynchos) (18%) and black ducks (A. rubripes) (14%). The greatest number of waterfowl died in three epizootics that involved primarily migratory birds in 1967 and 1994 in New York (USA) and 1973 in South Dakota (USA). The greatest number of DP epizootics reported since 1967 appear to have involved flocks of non-migratory rather than migratory waterfowl; therefore, in our opinion it remains unknown if DP is enzootic in either non-migratory or migratory waterfowl.     

Identification of an iridovirus in Acetes erythraeus (Sergestidae) and the development of in situ hybridization and PCR method for its detection

An iridovirus (tentatively named SIV, sergestid iridovirus) that causes high mortality in the sergestid shrimp, Acetes erythraeus, was found in Madagascar in 2004. Severely affected shrimp exhibit a blue-green opalescence. Histological examination revealed massive cytoplasmic inclusions in the cuticular epithelial cells, connective tissues, ovary and testes. The electron microscopic examination showed paracrystalline arrays of virions at a size of 140nm, suggesting infection with an iridovirus. A pair of PCR primers were selected from the conserved region of the major capsid protein (MCP)-coding sequence among insect iridoviruses and used to amplify a 1.0kb fragment from the infected A. erythraeus. This fragment was cloned, sequenced and found to be highly similar (upto 80% similarity in translated amino acids with an E value of 1e-124) to the MCP of invertebrate iridoviruses. This clone was then labeled with digoxigenin-11-dUTP and hybridized to tissue sections of infected A. erythraeus, which reacted positively to the probe. The reacting tissues included epithelial cells, connective tissues, and the germinal cells; the same cells as those with inclusions. A PCR method was also developed from the MCP coding sequence for detecting SIV.     

Red sea bream iridoviral disease

The first outbreak of red sea bream iridoviral disease caused by red sea bream iridovirus (RSIV) was recorded in cultured red sea bream Pagrus major in Shikoku Island, Japan in 1990. Since 1991, the disease has caused mass mortalities of cultured marine fishes not only red sea bream but also many other species. The affected fish were lethargic and exhibited severe anemia, petechiae of the gills, and enlargement of the spleen. The causative agent was a large, icosahedral, cytoplasmic DNA virus classified as a member of the family Iridoviridae and was designated as red sea bream iridovirus (RSIV). The genome of RSIV is liner dsDNA and considered to be circularly permitted and terminally redundant like other iridoviruses. The length of physical map of RSIV genome is 112,415bp. An indirect immunofluorescence test with a monoclonal antibody and PCR are commonly used for the rapid diagnosis of RSIV infected fish in the field. For the control of this disease, a formalin-killed vaccine against red sea bream iridoviral disease was developed and now commercially available.     

Systemic iridovirus from threespine stickleback Gasterosteus aculeatus represents a new megalocytivirus species (family Iridoviridae)

Megalocytiviruses have been associated with epizootics resulting in significant economic losses in public aquaria and food-fish and ornamental fish industries, as well as threatening wild fish stocks. The present report describes characteristics of the first megalocytivirus from a wild temperate North American fish, the threespine stickleback Gasterosteus aculeatus. Moribund and dead fish sampled after transfer to quarantine for an aquarium exhibit had amphophilic to basophilic intracytoplasmic inclusions (histopathology) and icosahedral virions (transmission electron microscopy) consistent with an iridovirus infection. Phylogenetic analyses of the major capsid, ATPase, and DNA polymerase genes confirmed the virus as the first known member of the genus Megalocytivirus (family Iridoviridae) from a gasterosteid fish. The unique biologic and genetic properties of this virus are sufficient to establish a new Megalocytivirus species to be formally known as the threespine stickleback iridovirus (TSIV). The threespine stickleback is widely distributed throughout the northern hemisphere in both freshwater and estuarine environments. The presence of megalocytiviruses with broad host specificity and detrimental economic and ecologic impacts among such a widely dispersed fish species indicates the need for sampling of other stickleback populations as well as other North American sympatric marine and freshwater ichthyofauna.     

Characterization of a novel ranavirus isolated from grouper Epinephelus tauvina

A large icosahedral virus was isolated from diseased grouper Epinephelus tauvina. The virus grew well in several cultured fish cell lines, with stable and high infectivity after serial passages in grouper cell line (GP). The virus was sensitive to both acid and heat treatments. Virus replication was inhibited by 5-iodo-2-deoxyuridine (IUDR), indicative of a DNA-containing genome. The virus infectivity was reduced with ether treatment, suggesting that the virus was lipid-enveloped. Electron micrographs showed abundant cytoplasmic icosahedral virons in the virus-infected GP cells. The size of the intracellular nucleocapsid was 154 nm between the opposite sides, or 176 nm between the opposite vertices with an inner electron-dense core of 93 nm. Virus particles were released through budding from plasma membranes with a size of 200 nm in diameter. SDS-PAGE of purified virus revealed 20 structural protein bands and a major capsid protein (MCP) of 49 kDa. A DNA fragment of approximately 500 nucleotides was successfully amplified by polymerase chain reaction (PCR) using the primers from conserved regions of the MCP gene of frog virus 3 (FV3), the type species of Ranavirus. Subsequent multiple alignment and phylogenetic analysis showed that the newly isolated grouper virus was closely related to largemouth bass virus (LMBV), FV3 and Regina ranavirus (RRV). Our data suggests that the virus isolate is a novel member of genus Ranavirus, family Iridoviridae. We tentatively name the virus as Singapore grouper iridovirus (SGIV). SGIV was able to cause serious systemic disease capable of killing 96% of grouper fry.     

Identification of an iridovirus in Acetes erythraeus (Sergestidae) and the development of in situ hybridization and PCR method for its detection

An iridovirus (tentatively named SIV, sergestid iridovirus) that causes high mortality in the sergestid shrimp, Acetes erythraeus, was found in Madagascar in 2004. Severely affected shrimp exhibit a blue–green opalescence. Histological examination revealed massive cytoplasmic inclusions in the cuticular epithelial cells, connective tissues, ovary and testes. The electron microscopic examination showed paracrystalline arrays of virions at a size of 140 nm, suggesting infection with an iridovirus. A pair of PCR primers were selected from the conserved region of the major capsid protein (MCP)-coding sequence among insect iridoviruses and used to amplify a 1.0 kb fragment from the infected A. erythraeus. This fragment was cloned, sequenced and found to be highly similar (upto 80% similarity in translated amino acids with an E value of 1e−124) to the MCP of invertebrate iridoviruses. This clone was then labeled with digoxigenin-11-dUTP and hybridized to tissue sections of infected A. erythraeus, which reacted positively to the probe. The reacting tissues included epithelial cells, connective tissues, and the germinal cells; the same cells as those with inclusions. A PCR method was also developed from the MCP coding sequence for detecting SIV.     

Characterization of an iridovirus from the cultured pig frog Rana grylio with lethal syndrome

Three virus isolates, RGV-9506, RGV-9807 and RGV-9808, were obtained from cultured pig frogs Rana grylio undergoing lethal infections. Previously, the first isolate, RGV-9506, was shown to be an iridovirus based on ultrastructural and morphological studies. In the present study, the original isolate, along with 2 recent ones, were more extensively characterized by experimental infection studies, histopathology, electron microscopy, serological reactivity, gel electrophoresis of viral polypeptides and DNA restriction fragments, PCR amplification, and nucleic acid sequence analysis of the major capsid protein (MCP) gene. The 3 isolates were shown to be identical to each other, and very similar to FV3, the type species of the genus Ranavirus (family Iridoviridae). These results suggest that RGV should be considered a strain of FV3, and indicate that FV3-like iridoviruses are capable of causing widespread, severe disease among cultured frogs.     

Effectiveness of a vaccine against red sea bream iridoviral disease in a field trial test.

Since 1990, red sea bream iridovirus (RSIV) has caused high mortalities in the summertime in cultured red sea bream Pagrus major in southwest Japan. To establish control measures for red sea bream iridoviral disease (RSIVD), the effectiveness of a formalin-killed viral vaccine was evaluated in a field trial. Two groups each consisting of 1000 juvenile red sea bream were either intraperitoneally inoculated with vaccine (vaccinated group) or were not vaccinated (non-vaccinated group). After vaccination, the fish were held for 1 wk, then transferred to a marine net pen and observed for 12 wk. The cumulative mortalities caused by RSIVD in the vaccinated group or control group were 19.2 and 68.5%, respectively. Additionally, the presence of virus antigen in the spleen was investigated and body weight was measured 6 and 12 wk post vaccination. In the vaccinated group, viral antigen was not detected. The increase in body weight of vaccinated fish was significantly (p < 0.05) greater than that of control fish. These results suggest that the vaccine against RSIVD was effective in 1 field trial.     

Phytase can reduce theneedfor monocalcium phosphate supplementation in soybean and rapeseed meal‐based diets of black sea bream,Acanthopagrus schlegelii (Bleeker, 1854)

A feeding trial was conducted to study the effect of partial replacement of dietary monocalcium phosphate (MCP) with phytase on growth performance, feed utilization and phosphorus discharge in black sea bream, Acanthopagrus schlegelii. In the feeding trial, the control diet (designated as P1.5) was prepared with 1.5% MCP but without phytase, and the three other diets (designated as PP1.0, PP0.5 and PP0, respectively) were supplemented with 1.0%, 0.5% and 0% MCP, respectively, along with 200 mg (400 U) phytase/kg diet in each. Each diet was tested in triplicate tanks and fish were fed twice daily to satiation. After an 8‐week feeding trial in indoor flow‐through cylindrical fibreglass tanks (25 fish per tank, initial body weight: 11.5 ± 0.12 g), fish fed with PP1.0 and PP0.5 had no significant change in weight gain (WG), specific growth rate (SGR), protein efficiency rate (PER) or feed conversion ratio (FCR) compared to the control (p > .05), whereas fish fed with PP0 showed a significantly lower growth performance in the above parameters (p < .05). The addition of phytase did not affect the body composition or muscle composition. The apparent digestibility coefficients (ADCs) of crude protein and phosphorus increased when fish were fed diets in which MCP was replaced by phytase. Phosphorus discharge was also significantly reduced in fish fed diets in which MCP was replaced by phytase (10.2 ± 0.50 to 8.01 ± 0.47 g/kg weight gain). The present study suggests that dietary MCP can be reduced when phytase is added to the black sea bream diet, with a maximum MCP reduction level of up to 1% when phytase is supplemented at 200 mg (400 U)/kg diet. Thus, phytase in the diet of black sea bream is economically and ecologically beneficial.     

Outbreaks and risks of infectious spleen and kidney necrosis virus disease in freshwater ornamental fishes

We examined the distribution of iridoviruses in 10 freshwater ornamental fish species hatched in Korea and imported from other Asian countries using both 1-step and 2-step polymerase chain reation (PCR). None of the 10 fish species analyzed were free of iridovirus as shown by 2-step PCR positive results, and 3 species yielded 1-step PCR positive results with associated mortality. Cloned PCR amplicons of the adenosine triphosphatase (ATPase) and major capsid protein (MCP) genes in genomic DNA of iridovirus showed the same nucleotide sequences as that of infectious spleen and kidney necrosis virus (ISKNV) isolated from the mandarinfish Siniperca chuatsi. These results indicate the presence of ISKNV disease in various ornamental fish as new host species and that the disease is widespread throughout different Asian countries including Korea, Singapore and China. Such infections were either clinical with associated mortality (and 1-step PCR positive) or asymptomatic in fish that were externally healthy (and only positive in 2-step PCR). Molecular analyses of the K2 region performed on iridovirus samples isolated from freshwater ornamental fishes revealed deletion/insertion of repetitive sequences of various lengths (42 to 339 bp), depending on the ISKNV isolates, without substitutions. Experimental infection of pearl gourami Trichogaster leeri and silver gourami T. microlepis with a tissue homogenate of pearl gourami infected by ISKNV induced 70 and 20% cumulative mortalities in the pearl and silver gourami, respectively.