Rhabdovirus infection induces public and private T cell responses in teleost fish.

Many viruses induce a strong T cell response that contributes to the elimination of infected cells presenting viral peptides by MHC molecules. The structure and expression of genes encoding molecules homologous to mammalian alphabeta TCRs have been recently characterized in rainbow trout and in several teleost species, but the alphabeta T cell response against pathogens has not been directly demonstrated. To study the modifications of the T cell repertoire during an acute viral infection in rainbow trout, we adapted the immunoscope methodology, which consists of spectratyping the complementarity-determining region 3 length of the TCRbeta chain. We showed that the naive T cell repertoire is polyclonal and highly diverse in the naive rainbow trout. Using viral hemorrhagic septicemia virus (VHSV), which provokes an acute infection in rainbow trout, we identified skewed complementarity-determining region 3 size profiles for several VbetaJbeta combinations, corresponding to T cell clonal expansions during primary and secondary response to VHSV. Both public and private T cell expansions were shown by immunoscope analysis of spleen cells from several infected individuals of a rainbow trout clone sharing the same genetic background. The public response to VHSV consisted of expansion of Vbeta4Jbeta1 T cell, which appeared early during the primary response and was strongly boosted during the secondary response.     

Viral hemorrhagic septicemia of rainbow trout: selection of a thermoresistant virus variant and comparison of polypeptide synthesis with the wild-type virus strain.

Serial passage of viral hemorrhagic septicemia virus at gradually increasing temperature selected for a variant virus that replicates at 25 degrees C and has a low pathogenicity for rainbow trout. Viral hemorrhagic septicemia virus-specific polypeptide synthesis was examined in epithelioma papulosum cyprini cells infected with either a wild-type strain or a thermoresistant variant. The wild-type N and M1 proteins were synthesized throughout the course of infection, whereas L, G, and M2 were more actively translated later in the replication cycle. The wild-type strain was more cytotoxic at 25 than at 14 degrees C despite the fact that no translation could be evidenced when the temperature was raised. When epithelioma papulosum cyprini cells were infected with the variant virus, the kinetic study was obstructed since protein synthesis was difficult to observe by the pulse method at a low multiplicity of infection and aborted when the multiplicity of infection was raised. The variant was less cytotoxic at 25 degrees C than wild-type virus.     

Viral hemorrhagic septicemia (VHS) of nonsalmonids

Viral hemorrhagic septicemia (VHS) is a viscerotropic disease of fish that can cause enormous losses in European rainbow trout populations. Although previously thought to be species specific, recent reports have indicated that other nonsalmonid fish species, such as pike, whitefish, grayling, turbot, and herring, can become mortally infected with VHS. This paper reviews several cases of natural VHS-outbreaks in nonsalmonids. Pike, whitefish, grayling, turbot and Pacific herring infected with VHS displayed symptoms typical of hemorrhagic septicemia. The isolation and serological identification of the viruses from all of the infected fish species revealed a close relation to the Egtved-virus strain F1. The virus isolates from diseased pike and rainbow trout were capable of infecting their respective host fish. Experimental infections of pike, whitefish, and grayling fry with Egtved virus strain F1 resulted in high mortalities, with symptoms typical of VHS. Although experiments with older fish suggested an age-dependent decrease in susceptibility, the virus could be isolated from most of the infected fish after several months of experimental infection (carrier status). Histological and electron microscopical findings were comparable to those seen in VHS-infected rainbow trout. The susceptibility of nonsalmonid species to VHS infection is disconcerting with respect to the potential losses of the economically important turbot, Pacific herring, and whitefish, as well as the ecologically valuable grayling which is threatened by extinction. If the VHS susceptible nonsalmonid species can also support the propagation of the Egtved-virus, it could acquire carrier-status and, as a result, represent a “natural” reservoir for the virus.     

Fish Rhabdovirus Cell Entry Is Mediated by Fibronectin

Three monoclonal antibodies (MAbs) generated against rainbow trout gonad cells (RTG-2) have been selected for their ability to protect cells from the viral hemorrhagic septicemia virus (VHSV) infection, a salmonid rhabdovirus. Protection from infection was restricted to the salmonid-derived cell lines indicating species specificity of the blocking MAbs. Surprisingly, the blocking activity of these MAbs was also effective against other nonantigenically related fish rhabdoviruses. Indirect immunofluorescence and immunoelectron microscopy observations demonstrated that the three MAbs were all directed against an abundant cell plasma membrane component, and immunoprecipitation studies indicated that the target consisted of a heterodimeric complex with molecular masses of 200 and 44 kDa. Biochemical data provided the following evidence that fibronectin is part of this complex and that it could represent the main receptor for fish rhabdoviruses. (i) An antiserum generated against the 200-kDa protein reacted against the recombinant rainbow trout fibronectin expressed in Escherichia coli. (ii) The purified rainbow trout fibronectin was able to bind specifically to VHSV. To our knowledge, this is the first identification of a cellular component acting as a primary receptor for a virus replicating in lower vertebrates and, more interestingly, for viruses belonging to the Rhabdoviridae family.     

Evolutional conservation of molecular structure and antiviral function of a viral RNA receptor, LGP2, in Japanese flounder, Paralichthys olivaceus

LGP2 is an important intracellular receptor that recognizes viral RNAs in innate immunity. To understand the mechanism of viral RNA recognition, we cloned an LGP2 cDNA and gene in Japanese flounder (Paralichthys olivaceus). Viral hemorrhagic septicemia virus-induced expressions of LGP2 mRNA were evaluated in vivo and in vitro by quantitative real-time PCR (Q-PCR) using primers based on the clone sequences. The expression of LGP2 mRNA in the kidney dramatically increased at 3 d postinfection. The expression of LGP2 mRNA also increased in the head kidney leukocytes stimulated with artificial dsRNA (polyinosin-polycytidylic acid) in vitro. To evaluate the antiviral activity of the flounder LGP2, three expression constructs containing pcDNA4-LGP2 (full-length), pcDNA4-LGP2ΔRD (regulatory domain deleted), and pcDNA4-Empty (as a negative control) were transfected into the hirame (flounder) natural embryo (hirame natural embryo) cell line. Forty-eight hours after transfection, the transfected cells were infected with ssRNA viruses, viral hemorrhagic septicemia virus, or hirame rhabdovirus. The cytopathic effects of the viruses were delayed by the overexpression of Japanese flounder LGP2. The Q-PCR demonstrated that mRNA expression levels of type I IFN and IFN-inducible genes (Mx and ISG15) in the hirame natural embryo cells overexpressing LGP2 were increased by polyinosin-polycytidylic acid and viral infections. These results suggest that Japanese flounder LGP2 plays an important role in the recognition of both viral ssRNA and dsRNA to induce the antiviral activity by the production of IFN-stimulated proteins.     

Differential effects of viral hemorrhagic septicaemia virus (VHSV) genotypes IVa and IVb on gill epithelial and spleen macrophage cell lines from rainbow trout (Oncorhynchus mykiss)

The two most prominent genotypes of viral hemorrhagic septicemia virus (VHSV) are -I in the Northeastern Atlantic region and -IV in North America, but much more is known about the cellular pathogenesis of genotype -I than -IV. VHSV genotype -IV is divided into -IVa from the Northeast Pacific Ocean and -IVb from the Great Lakes and both of which are less virulent to rainbow trout than genotype -I. In this work, infections of VHSV-IVa and -IVb have been studied in two rainbow trout cell lines, RTgill-W1 from the gill epithelium, and RTS11 from spleen macrophages. RTgill-W1 produced infectious progeny of both VHSV-IVa and -IVb. However, VHSV-IVa was more infectious than -IVb toward RTgill-W1: -IVa caused cytopathic effect (CPE) at a lower viral titre, elicited CPE earlier, and yielded higher titres. By contrast, no CPE and no increase in viral titre were observed in RTS11 cultures infected with either genotype. Yet in RTS11 all six VHSV genes were expressed and antiviral genes, Mx2 and Mx3, were up regulated by VHSV-IVb and -IVa. However, replication appeared to terminate at the translational stage as viral N protein, presumably the most abundant of the VSHV proteins, was not detected in either infected RTS11 cultures. In RTgill-W1, Mx2 and Mx3 were up regulated to similar levels by both viral genotypes, while VHSV-IVa induced higher levels of IFN1, IFN2 and LGP2A than VHSV-IVb.     

Differences in virulence of marine and freshwater isolates of viral hemorrhagic septicemia virus in vivo correlate with in vitro ability to infect gill epithelial cells and macrophages of rainbow trout (Oncorhynchus mykiss)

Two strains of viral hemorrhagic septicemia virus (VHSV) with known different virulence characteristics in vivo were studied (by a time course approach) for their abilities to infect and translocate across a primary culture of gill epithelial cells (GEC) of rainbow trout (RBT; Oncorhynchus mykiss). The strains included one low-virulence marine VHSV (ma-VHSV) strain, ma-1p8, and a highly pathogenic freshwater VHSV (fw-VHSV) strain, fw-DK-3592B. Infectivities toward trout head kidney macrophages were also studied (by a time course method), and differences in in vivo virulence were reconfirmed, the aim being to determine any correlation between in vivo virulence and in vitro infectivity. The in vitro studies showed that the fw-VHSV isolate infected and caused a cytotoxic effect in monolayers of GEC (demonstrating virulence) at an early time point (2 h postinoculation) and that the same virus strain had translocated over a confluent, polarized GEC layer by 2 h postinoculation. The marine isolate did not infect monolayers of GEC, and delayed translocation across polarized GEC was seen by 48 h postinoculation. Primary cultures of head kidney macrophages were also infected with fw-VHSV, with a maximum of 9.5% virus-positive cells by 3 days postinfection, while for the ma-VHSV strain, only 0.5% of the macrophages were positive after 3 days of culture. In vivo studies showed that the fw-VHSV strain was highly virulent for RBT fry and caused high mortality, with classical features of viral hemorrhagic septicemia. The ma-VHSV showed a very low level of virulence (only one pool of samples from the dead fish was VHSV positive). This study has shown that the differences in virulence between marine and freshwater strains of VHSV following the in vivo infection of RBT correlate with in vitro abilities to infect primary cultures of GEC and head kidney macrophages of the same species.     

Interferon response following infection with genetically similar isolates of viral haemorrhagic septicaemia virus (VHSV) exhibiting contrasting virulence in rainbow trout

Isolates of viral haemorrhagic septicaemia virus (VHSV) were identified which are genetically similar yet, based on their isolation history were considered likely to differ in virulence in juvenile rainbow trout. An experimental infection study was performed in order to verify this hypothesis and provide an experimental infectivity model with which to investigate the basis for susceptibility of rainbow trout to this commercially important virus. Significant differences in mortality were obtained following both intraperitoneal (IP) injection and immersion challenges with an early marine (DK-M.Rhabdo) and early rainbow trout VHSV isolate (DK-F1) respectively. Expression of Type I IFN, Mx1 (an IFN-inducible protein), and viral genes (encoding nucleo-, phospho-, matrix, glyco- and non-viron proteins) was studied in sequential tissue samples using real-time quantitative PCR (QPCR). Resulting data revealed a significant increase in IFN and Mx1 expression detected in fish challenged by IP injection with both isolates. Expression levels of these genes were directly related to the degree of viral replication as measured by the expression of VHSV RNAs. In immersion-challenged fish a significant increase in Mx1 was observed only when using the virulent isolate DK-F1; however no elevated host response was detectable in fish challenged with the marine isolate DK-M.Rhabdo. Quintessentially the inability to detect any virus in trout challenged with the marine isolate via immersion suggests the virus was incapable of establishing infection. The mechanisms for this appear to be more related to initial cellular entry and replication rather than due to the overcoming of initial infection via an elevated host innate immune response.     

Staphylococcal coagglutination, a rapid method of identifying infectious hematopoietic necrosis virus.

A staphylococcal coagglutination test was developed for the rapid detection of infectious hematopoietic necrosis virus (IHNV) in cell cultures and infected fish. The test could be completed in 15 min but required a minimum IHNV titer of 10(6) PFU/ml to obtain a positive reaction. All IHNV isolates, representing the five electropherotypes taken from a wide variety of species and different geographic ranges, caused coagglutination of Staphylococcus aureus cells sensitized with rabbit polyclonal serum against the Round Butte IHNV isolate. The coagglutination reaction was blocked by preincubation of IHNV with homologous antiserum, and IHNV did not cause coagglutination of S. aureus cells sensitized with normal rabbit serum. In specificity tests, cells sensitized with rabbit anti-IHNV serum or normal serum did not coagglutinate in the presence of infectious pancreatic necrosis virus, viral hemorrhagic septicemia virus, cell culture medium components, or media from cultures of cell lines of salmonid and nonsalmonid origin. Most importantly, the coagglutination test was able to detect and identify IHNV directly from experimentally infected rainbow trout fry, the organs of naturally infected adult kokanee salmon and winter steelhead trout, and ovarian fluids of the winter steelhead trout. The coagglutination test is very suitable for field use, since it is inexpensive, simple to interpret, sensitive, and rapid and requires no specialized equipment.     

Staphylococcal coagglutination, a rapid method of identifying infectious hematopoietic necrosis virus.

A staphylococcal coagglutination test was developed for the rapid detection of infectious hematopoietic necrosis virus (IHNV) in cell cultures and infected fish. The test could be completed in 15 min but required a minimum IHNV titer of 10(6) PFU/ml to obtain a positive reaction. All IHNV isolates, representing the five electropherotypes taken from a wide variety of species and different geographic ranges, caused coagglutination of Staphylococcus aureus cells sensitized with rabbit polyclonal serum against the Round Butte IHNV isolate. The coagglutination reaction was blocked by preincubation of IHNV with homologous antiserum, and IHNV did not cause coagglutination of S. aureus cells sensitized with normal rabbit serum. In specificity tests, cells sensitized with rabbit anti-IHNV serum or normal serum did not coagglutinate in the presence of infectious pancreatic necrosis virus, viral hemorrhagic septicemia virus, cell culture medium components, or media from cultures of cell lines of salmonid and nonsalmonid origin. Most importantly, the coagglutination test was able to detect and identify IHNV directly from experimentally infected rainbow trout fry, the organs of naturally infected adult kokanee salmon and winter steelhead trout, and ovarian fluids of the winter steelhead trout. The coagglutination test is very suitable for field use, since it is inexpensive, simple to interpret, sensitive, and rapid and requires no specialized equipment.