Phylogenetic analysis of viral haemorrhagic septicaemia virus (VHSV) isolates from France (1971-1999).

The nucleotide sequences of a specific region of the glycoprotein gene were compared among 63 strains of viral haemorrhagic septicaemia virus (VHSV) isolated from fish in France between 1971 and 1999. The analysis was performed on a region corresponding to amino acids 238 to 331 of the glycoprotein gene, also designated the V2 region and previously shown to accumulate most of the mutations. The sequences of many VHSV isolates were found to be identical or very conserved. An isolate, designated L59X, obtained from elver in the Loire estuary, depicted a higher degree of divergence compared to the other French isolates. The deduced amino-acid sequences were analysed together with the results of neutralisation tests performed using monoclonal antibody 168m4 specific to serotype 1. Non-neutralised VHSV strains had mutations in the region corresponding to the previously described 168m4 epitope. Phylogenetic analysis showed that all the VHSV isolates studied, except L59X, belong to genotype I, previously described as containing VHSV strains isolated from continental Europe. Most of the VHSV isolates studied were found to be genetically related to one of the previously described VHSV strains representative of the major serotypes. Isolate L59X, which was the only French marine strain studied, was found to belong to genotype II, previously shown to encompass the VHSV strains isolated from the British Isles coastal waters. Overall there was a good correlation between the geographical origin of the studied isolates and their genetic characteristics.

Sea bream Sparus aurata, an asymptomatic contagious fish host for nodavirus.

During an epidemiological survey of viral encephalopathy and retinopathy (VER) in diseased sea bass Dicentrarchus labrax, a nodavirus isolate was recovered from net pen-reared sea bream Sparus aurata harboured in the same farming premises. After the virus was isolated and identified by immunofluorescence on SSN-1 cells, sequence analysis with a PCR product from the T4 region of the capsid protein gene indicated that the virus shared 100% identity with a pathogenic virus strain isolated from sea bass. Infection trials demonstrated the pathogenicity of the sea bream virus isolate for juvenile sea bass whereas sea bream infected with the same virus isolate remained asymptomatic even following intramuscular injection of virus. Nevertheless, the sea bream appeared to be a potential carrier of nodavirus, as juvenile sea bass became infected when maintained in a tank containing experimentally contaminated sea bream.

An RT-PCR-based method for the diagnosis of the sleeping disease virus in experimentally and naturally infected salmonids.

The sleeping disease (SD) of rainbow trout (Oncorhynchus mykiss) is a worldwide disease for which the causative agent, the sleeping disease virus (SDV), has been recently characterized as an atypical alphavirus (Villoing et al. 2000). Up to now, no diagnostic tools were available and thus no epidemiological studies have been undertaken to evaluate the occurrence of this disease on the field. We present in this paper a sensitive and highly specific 1 working day method, which allows the detection of SDV from experimentally and naturally infected fishes. This method, based on a reverse transcriptase/polymerase chain reaction (RT-PCR) assay on total RNA extracted from SDV-infected fish organs, enables the specific DNA amplification of part of the gene encoding the SDV glycoprotein E2, as early as 2 d post-infection (d.p.i.) and as late as 70 d.p.i., at which time clinical signs of infection are no longer apparent. Moreover, we show that this RT-PCR method can be successfully used for the diagnosis of fish infected by a closely related virus, namely salmon pancreas disease virus (SPDV). This report is the first description of a very powerful diagnostic assay which could provide a more accurate replacement for the classical virological, histological and immunochemistry methods.

Comparative study of viral encephalopathy and retinopathy in juvenile sea bass Dicentrarchus labrax infected in different ways.

The transmission of viral encephalopathy and retinopathy (VER) was investigated in juvenile sea bass (3 g) Dicentrarchus labrax by using cell culture supernatant (SSN-1 cell line) containing nodavirus. Five methods of infection were tested: intramuscular injection (IM), intraperitoneal injection (IP), oral infection, bath exposure and cohabitation of healthy fish with infected fish. Some differences were observed in time of disease onset and severity of symptoms depending on the mode of infection used. Clinical symptoms such as whirling swimming and lethargic or hyperactive behaviour were generally reproduced, except for fish infected via oral and IP infection. First mortalities occurred 3 d after IM and IP infection and 6 d after for the other modes of infection. Cumulative mortalities were also variable: 100% after IM infection, 10% after IP infection, 32% for bath exposure, 43% after cohabitation and 24% via oral infection. Histopathologically, vacuolation was observed in the central nervous tissues and in the retina. The observed lesions were more or less severe depending on the mode of infection, the sampling time and the organs: lesions on the surviving fish (42 days post infection, d p.i.) seemed to be generally more conspicuous in the retina than in the brain of the same fish. In most cases, the presence of nodavirus was confirmed in the same samples of brain and retina by immunohistochemistry and reverse transcriptase-polymerase chain reaction (RT-PCR). The virus was not detected in other organs examined. The present results suggest that 2 forms of VER can be induced: IM injection leads to an acute form (severe nervous disorders with high and fast mortality) whereas oral infection, bath exposure and cohabitation induce a subacute form (less severe disorders and weak daily mortality). This experiment demonstrates experimentally induced horizontal transmission of VER in sea bass for the first time.

Highly sensitive immunoassay for direct diagnosis of viral hemorrhagic septicemia which uses antinucleocapsid monoclonal antibodies.

An antigen capture enzyme-linked immunosorbent assay (ELISA) based on the detection of the viral nucleocapsid (anti-N system) was developed for the diagnosis of viral hemorrhagic septicemia. Four monoclonal antibodies directed against the viral nucleocapsid were produced; they all recognized the four viral hemorrhagic septicemia virus (VHSV) serotypes. Three of these monoclonal antibodies were used in a new antigen capture ELISA. The efficiency of the anti-N system in detecting purified and crude viruses as well as the virus in infected-organ extracts and infected blood was compared with that of a recently described antigen capture ELISA based on the detection of viral envelope glycoprotein Gp (anti-G system). For the detection of purified virus, the anti-N system was found to be as sensitive as the anti-G system (detection limit, 1 ng of total viral protein per ml), but the anti-N system was much more sensitive than the anti-G system for the detection of crude VHSV I (detection limits, 1 x 10(4) PFU/ml versus 5 x 10(5) PFU/ml). In organ extracts, VHSV I could be detected by both systems 3 days postinfection. The signal for the assay of VHSV I in blood 24 h postinfection was higher with the anti-N system than the anti-G system. Furthermore, VHSV I could be detected in 80% of the brain samples of surviving trout by the anti-N system and also by the anti-G system, but with a lower signal. In conclusion, we have developed a highly sensitive immunoassay for VHSV I that is more rapid and easier to perform than the currently used plaque assay.