Cloning of the rainbow trout (Oncorhynchus mykiss) Mx2 and Mx3 cDNAs and characterization of trout Mx protein expression in salmon cells.

Two rainbow trout (Oncorhynchus mykiss) Mx cDNAs were cloned by using RACE (rapid amplification of cDNA ends) PCR and were designated RBTMx2 and RBTMx3. The deduced RBTMx2 and RBTMx3 proteins were 636 and 623 amino acids in length with molecular masses of 72 and 70.8 kDa, respectively. These proteins, along with the previously described RBTMx1 protein (G. D. Trobridge and J. A. Leong, J. Interferon Cytokine Res. 15:691-702, 1995), have between 88.7 and 96.6% identity at the amino acid level. All three proteins contain the tripartite GTP binding domain and leucine zipper motif common to Mx proteins. A monospecific polyclonal antiserum to an Escherichia coli-expressed fragment of RBTMx3 was generated, and that reagent was found to react with all three rainbow trout Mx proteins. Subsequently, endogenous Mx production in RTG-2 cells induced with poly(IC) double-stranded RNA was detected by immunoblot analysis. The cellular localization of the rainbow trout proteins was determined by transient expression of the RBTMx cDNAs in CHSE-214 (chinook salmon embryo) cells. A single-cell transient-transfection assay was used to examine the ability of each Mx cDNA clone to inhibit replication of the fish rhabdovirus infectious hematopoietic necrosis virus (IHNV). No significant inhibition in the accumulation of the IHNV nucleoprotein was observed in cells expressing either trout Mx1, Mx2, or Mx3 in transiently transfected cells.     

DNA vaccines encoding viral glycoproteins induce nonspecific immunity and Mx protein synthesis in fish

Protective immunity by vaccination with plasmid DNA encoding a viral glycoprotein (G) has long been assumed to result from the induction of a specific immune response. We report here that the initial protection may be due to the induction of alpha/beta interferon, with long-term protection due to a specific response to the encoded viral G. DNA vaccines encoding the Gs of three serologically unrelated fish rhabdoviruses were used to vaccinate rainbow trout against a lethal challenge with infectious hematopoietic necrosis virus (IHNV). All three vaccines, each encoding the G gene of either IHNV (IHNV-G), snakehead rhabdovirus (SHRV) (SHRV-G), or spring viremia of carp virus (SVCV) (SVCV-G), elicited protective immunity against IHNV. Vaccinated fish were challenged at 30 or 70 days postvaccination with lethal doses of IHNV. At 30 days postvaccination, only 5% of fish that had received any of the G vaccines died, whereas more than 50% of the control fish succumbed to virus challenge. When fish were vaccinated and challenged at 70 days postvaccination, only 12% of the IHNV-G-vaccinated fish died compared to 68% for the SHRV-G- and 76% for the SVCV-G-vaccinated fish. Assays for trout Mx protein, an indicator of alpha/beta interferon induction, showed that only fish vaccinated with a G-containing plasmid produced high levels of Mx protein in the kidneys and liver. Interestingly, at day 7 after virus challenge, all of the fish vaccinated with the IHNV-G plasmid were negative for Mx, but the SHRV-G- and SVCV-G-vaccinated fish still showed detectable levels of Mx. These results suggest that DNA vaccines in fish induce an early, nonspecific antiviral protection mediated by an alpha/beta interferon and, later, a specific immune response.     

Specificity of DNA vaccines against the U and M genogroups of infectious hematopoietic necrosis virus (IHNV) in rainbow trout (Oncorhynchus mykiss)

Infectious hematopoietic necrosis virus (IHNV) is a fish rhabdovirus that causes significant mortality in salmonid species. In North America IHNV has three major genogroups designated U, M, and L. Host-specificity of the M and U genogroups of IHNV has been established both in the field and in experimental challenges, with M isolates being more prevalent and more virulent in rainbow trout (Oncorhynchus mykiss), and U isolates being more prevalent and highly virulent in sockeye salmon (Oncorhynchus nerka). In this study, efficacy of DNA vaccines containing either M (pM) or U (pU) virus glycoprotein genes was investigated during intra- and cross-genogroup challenges in rainbow trout. In virus challenges at 7 days post-vaccination (early antiviral response), both pM and pU were highly protective against either M or U IHNV. In challenges at 28 days post-vaccination (specific antiviral response), both pM and pU were protective against M IHNV but the homologous pM vaccine was significantly more protective than pU in one of two experiments. At this stage both pM and pU induced comparably high protection against U IHNV challenge. Correlates of protection were also investigated by assessing the expression of the interferon-stimulated gene Mx-1 and the production of neutralizing antibodies (NAbs) following pM or pU DNA vaccination. Mx-1 gene expression, measured at 4 and 7 days post-vaccination as an indicator of the host innate immune response, was found to be significantly higher after pM than pU vaccination in some cases. Neutralizing antibody was produced in response to the two vaccines, but antibody titers did not show consistent correlation with protection. The results show that the rainbow trout innate and adaptive immune responses have some ability to distinguish between the U and M genogroup IHNV, but overall the pM and pU vaccines were protective against both homologous and cross-genogroup challenges.     

Molecular epidemiology of infectious hematopoietic necrosis virus reveals complex virus traffic and evolution within southern Idaho aquaculture

Infectious hematopoietic necrosis virus (IHNV) is a rhabdovirus which infects salmon and trout and may cause disease with up to 90% mortality. In the Hagerman Valley of Idaho, IHNV is endemic or epidemic among numerous fish farms and resource mitigation hatcheries. A previous study characterizing the genetic diversity among 84 IHNV isolates at 4 virus-endemic rainbow trout farms indicated that multiple lineages of relatively high diversity co-circulated at these facilities (Troyer et al. 2000 J Gen Virol. 81:2823-2832). We tested the hypothesis that high IHNV genetic diversity and co-circulating lineages are present in aquaculture facilities throughout this region. In this study, 73 virus isolates from 14 rainbow trout farms and 3 state hatcheries in the Hagerman Valley, isolated between 1978 and 1999, were genetically characterized by sequence analysis of a 303 nucleotide region of the glycoprotein gene. Phylogenetic and epidemiological analyses showed that multiple IHNV lineages co-circulate in a complex pattern throughout private trout farms and state hatcheries in the valley. IHNV maintained within the valley appears to have evolved significantly over the 22 yr study period.     

Age- and weight-dependent susceptibility of rainbow trout Oncorhynchus mykiss to isolates of infectious haematopoietic necrosis virus (IHNV) of varying virulence

The virulence of 5 European and 1 North American isolate of infectious haematopoietic necrosis virus (IHNV) was compared by infecting female sibling rainbow trout ('Isle of Man' strain) of different weights and ages (2, 20 and 50 g). The fish were exposed to 10(4) TCID50 IHNV per ml of water by immersion, and the mortality was recorded for 28 d. Two new IHNV isolates from Germany were included in the investigation. One was isolated from European eels kept at 23 degrees C (+/- 2 degrees C) and the other was not detectable by immunofluorescence with commercially available monoclonal antibodies recognising the viral G protein. The results showed that IHNV isolates of high or low virulence persisted in rainbow trout of all ages/weights for 28 d, with the exception of fish over 15 g in the eel IHNV (DF [diagnostic fish] 13/98)-infected groups from which the virus could not be reisolated on Day 28. The smallest fish were most susceptible to an infection with any of the IHNV isolates. The lowest cumulative mortality (18%) was observed in fingerlings infected with the North American isolate HAG (obtained from Hagerman Valley), and the highest mortality (100%) in DF 04/99 infected fish. The DF 04/99 and O-13/95 viruses caused mortality in fish independent of their weight or age. The isolates FR-32/87 and I-4008 were virulent in fish up to a weight of 20 g and caused no mortality in larger fish. In the IHNV HAG- and DF 13/98 (eel)-infected rainbow trout, no signs of disease were observed in fish weighing between 15 and 50 g. An age/weight related susceptibility of rainbow trout was demonstrated under the defined conditions for all IHNV isolates tested.     

Efficacy of an infectious hematopoietic necrosis (IHN) virus DNA vaccine in Chinook Oncorhynchus tshawytscha and sockeye O. nerka salmon

The level of protective immunity was determined for Chinook Oncorhynchus tshawytscha and sockeye/kokanee salmon (anadromous and landlocked) O. nerka following intramuscular vaccination with a DNA vaccine against the aquatic rhabdovirus, infectious hematopoietic necrosis virus (IHNV). A DNA vaccine containing the glycoprotein gene of IHNV protected Chinook and sockeye/kokanee salmon against waterborne or injection challenge with IHNV, and relative percent survival (RPS) values of 23 to 86% were obtained under a variety of lethal challenge conditions. Although this is significant protection, it is less than RPS values obtained in previous studies with rainbow trout (O. mykiss). In addition to the variability in the severity of the challenge and inherent host susceptibility differences, it appears that use of a cross-genogroup challenge virus strain may lead to reduced efficacy of the DNA vaccine. Neutralizing antibody titers were detected in both Chinook and sockeye that had been vaccinated with 1.0 and 0.1 pg doses of the DNA vaccine, and vaccinated fish responded to viral challenges with higher antibody titers than mock-vaccinated control fish.     

Evaluation of the protective immunogenicity of the N, P, M, NV and G proteins of infectious hematopoietic necrosis virus in rainbow trout oncorhynchus mykiss using DNA vaccines.

The protective immunogenicity of the nucleoprotein (N), phosphoprotein (P), matrix protein (M), non-virion protein (NV) and glycoprotein (G) of the rhabdovirus infectious hematopoietic necrosis virus (IHNV) was assessed in rainbow trout using DNA vaccine technology. DNA vaccines were produced by amplifying and cloning the viral genes in the plasmid pCDNA 3.1. The protective immunity elicited by each vaccine was evaluated through survival of immunized fry after challenge with live virus. Neutralizing antibody titers were also determined in vaccinated rainbow trout Oncorhynchus mykiss fry (mean weight 2 g) and 150 g sockeye salmon Oncorhynchus nerka. The serum from the 150 g fish was also used in passive immunization studies with naive fry. Our results showed that neither the internal structural proteins (N, P and M) nor the NV protein of IHNV induced protective immunity in fry or neutralizing antibodies in fry and 150 g fish when expressed by a DNA vaccine construct. The G protein, however, did confer significant protection in fry up to 80 d post-immunization and induced protective neutralizing antibodies. We are currently investigating the role of different arms of the fish immune system that contribute to the high level of protection against IHNV seen in vaccinated fish.     

Fish DNA vaccine against infectious hematopoietic necrosis virus: efficacy of various routes of immunisation

The DNA vaccine, pIHNVw-G, contains the gene for the glycoprotein (G) of the rhabdovirus infectious hematopoietic necrosis virus (IHNV), a major pathogen of salmon and trout. The relative efficacy of various routes of immunisation with pIHNVw-G was evaluated using 1.8 g rainbow trout fry vaccinated via intramuscular injection, scarification of the skin, intraperitoneal injection, intrabuccal administration, cutaneous particle bombardment using a gene gun, or immersion in water containing DNA vaccine-coated beads. Twenty-seven days after vaccination neutralising antibody titres were determined, and 2 days later groups of vaccinated and control unvaccinated fish were subjected to an IHNV immersion challenge. Results of the virus challenge showed that the intramuscular injection and the gene gun immunisation induced protective immunity in fry, while intraperitoneal injection provided partial protection. Neutralising antibodies were not detected in sera of vaccinated fish regardless of the route of immunisation used, suggesting that cell mediated immunity may be at least partially responsible for the observed protection.     

Neutralization-resistant variants of infectious hematopoietic necrosis virus have altered virulence and tissue tropism.

Infectious hematopoietic necrosis virus (IHNV) is a rhabdovirus that causes an acute disease in salmon and trout. In this study, a correlation between changes in tissue tropism and specific changes in the virus genome appeared to be made by examining four IHNV neutralization-resistant variants (RB-1, RB-2, RB-3, and RB-4) that had been selected with the glycoprotein (G)-specific monoclonal antibody RB/B5. These variants were compared with the parental strain (RB-76) for their virulence and pathogenicity in rainbow trout after waterborne challenge. Variants RB-2, RB-3, and RB-4 were only slightly attenuated and showed distributions of viral antigen in the livers and hematopoietic tissues of infected fish similar to those of the parental strain. Variant RB-1, however, was highly attenuated and the tissue distribution of viral antigen in RB-1-infected fish was markedly different, with more viral antigen in brain tissue. The sequences of the G genes of all four variants and RB-76 were determined. No significant changes were found for the slightly attenuated variants, but RB-1 G had two changes at amino acids 78 and 218 that dramatically altered its predicted secondary structure. These changes are thought to be responsible for the altered tissue tropism of the virus. Thus, IHNV G, like that of rabies virus and vesicular stomatitis virus, plays an integral part in the pathogenesis of viral infection.     

Study of the viral interference between infectious pancreatic necrosis virus (IPNV) and infectious haematopoietic necrosis virus (IHNV) in rainbow trout (Oncorhynchus mykiss)

The resistance of rainbow trout (Oncorhynchus mykiss) to an infectious haematopoietic necrosis virus (IHNV) challenge following a preceding non-lethal infection with infectious pancreatic necrosis virus (IPNV) was investigated through experimental dual infections. Trout initially infected with IPNV were inoculated 14 days later with IHNV. Single infections of trout with 1 of the 2 viruses or with cell culture supernatant were also carried out and constituted control groups. No mortality was noted in fish after a single infection with IPNV. This virus had no influence on the head kidney leucocyte phagocytic activity and plasma haemolytic complement activity. IHNV induced a high mortality (72%) and reduced the macrophage phagocytic activity and complement haemolytic activity. It also induced a late production of anti-IHNV antibodies which occurred after clearance of the virus in the fish. In trout co-infected with both viruses, a mortality rate of 2% occurred and the immune parameters were similar to those observed in the fish infected with IPNV only, demonstrating that in co-infected trout IPNV inhibits the effects of IHNV. The studied parameters did not allow us to define the mechanism of interference occurring between these 2 viruses, but some hypothesis are put forward to explain the interference between the 2 viruses.     

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.     

Effects of salmonid fish viruses on Mx gene expression and resistance to single or dual viral infections

We examined the ability of several fish viruses to induce protection against homologous or heterologous viruses in single or double infections, and assessed whether such protection is correlated with innate immunity or expression of the Mx gene. Monolayers of BF2 cells pre-treated with supernatants of brown trout (Salmo trutta L.) macrophage cultures that had been stimulated with either polyinosinic polycytidylic acid (poly I:C) or viruses, such as infectious pancreatic necrosis virus (IPNV), infectious haematopoietic necrosis virus (IHNV) or a mixture of the two, showed varying degrees of protection against viral infections. The virus showing the strongest induction was IPNV, and the antiviral activity against IHNV was also high: around 6 log(10) reduction of virus yield. Consequently, the IPNV-IHNV co-infection yield was also reduced by varying amounts. In vivo, the cumulative mortality observed in the IPNV-IHNV co-infected fish was always less than that in those with a single infection. Stimulation with poly I:C for 7 days significantly reduced cumulative mortality in single-infected fish, but not in the double-infected, in which the IPNV was the only virus isolated from moribund animals. By RT-PCR, Mx was expressed in all the organ samples tested (kidney, liver and spleen) from virus-stimulated fish at 1, 2 and 3 days. By qRT-PCR the extent and timing of Mx expression was shown to differ in the poly I:C and the single or dual viral infections. The highest increase in Mx expression (21.6-fold above basal levels) occurred (after 24 h) in fish infected with the IHNV, and expression remained high until day 7. Mx expression in fish infected with IPNV peaked later, at 2 days post infection, and also remained high until day 7. The dual infection with IPNV-IHNV induced high Mx expression on day 1, which peaked on day 2 and remained high until day 7. These results indicate that activation of the immune system could explain the interference and loss of IHNV in the IPNV-IHNV co-infections.     

Wide range of susceptibility to rhabdoviruses in homozygous clones of rainbow trout

Inbred lines differentially susceptible to diseases are a powerful tool to get insights into the mechanisms of genetic resistance to pathogens. In fish, chromosome manipulation techniques allow a quick production of such homozygous lines. Using gynogenesis, we produced nine homozygous clones of rainbow trout from a domestic population (INRA Sy strain). We examined the variability between clones for resistance to two rhabdoviruses, the viral haemorrhagic septicaemia virus (VHSV) and the infectious haematopoietic necrosis virus (IHNV). Intraperitoneal injections and waterborne infections were performed in parallel for both viruses. No survival was recorded after intraperitoneal injection of VHSV or IHNV, indicating that fish from all clones were fully susceptible to both viruses by this route of infection. In contrast, the different clones showed a wide range of survival frequency after waterborne infection. The resistance levels to VHSV ranged from 0 to 99% and resistance was not abrogated when resistant and sensitive animals were mixed and subjected to waterborne infection. VHSV was recovered from 10% of resistant fish after waterborne infection, confirming that virus replication was possible in this context but effective only in a low proportion of the population. The different clones also exhibited a wide range of survival (0-68%) after a waterborne infection with IHNV. Although VHSV-resistant clones were not fully resistant to IHNV, the susceptibility to IHNV and VHSV tended to be correlated, suggesting that non-specific mechanisms common to both viruses were involved.     

Polymorphisms in major histocompatibility complex class IIα genes are associated with resistance to infectious hematopoietic necrosis in rainbow trout,Oncorhynchus mykiss (Walbaum, 1792)

Infectious hematopoietic necrosis is a serious viral disease of salmonids, including rainbow trout Oncorhynchus mykiss, and causes tremendous economic losses to the rainbow trout farming industry. Major histocompatibility complex (MHC) genes are crucial elements of adaptive immunity in vertebrate organisms and have been linked with the resistance to numerous pathogenic diseases. In this study, polymerase chain reaction‐single strand conformation polymorphism (PCR‐SSCP) followed by cloning and sequencing were used to examine polymorphisms in the DAA genes (specifically DAA exon 2 of MHC class IIα) of rainbow trout and investigate their association with the infectious hematopoietic necrosis virus (IHNV) resistance in rainbow trout. Seventeen alleles were resolved, including 13 novel alleles. Individuals possessed between two and five alleles, indicating that the genome harbours at least three closely‐related DAA exon 2 loci. The ratio of non‐synonymous to synonymous nucleotide substitutions suggested that DAA exon 2 is under positive selection. A greater variability of amino acids and non‐synonymous nucleotide substitution rate was evident in the peptide‐binding region (PBR) than in the non‐PBR (27.75%). Importantly, the analyses revealed that certain MHC class IIα alleles appear to confer resistance to IHNV in rainbow trout, while others confer susceptibility. The most common alleles in the resistant populations of rainbow trout, Onmy‐DAA*1301 and Onmy‐DAA*0304, confer resistance to IHNV and were not present in the susceptible population. Hence, these alleles may be ideal molecular markers that can assist the breeding of IHNV resistance in rainbow trout.     

Detection of truncated virus particles in a persistent RNA virus infection in vivo.

Infectious hematopoietic necrosis virus (IHNV) is a rhabdovirus which causes devastating epizootics of trout and salmon fry in hatcheries around the world. In laboratory and field studies, epizootic survivors are negative for infectious virus by plaque assay at about 50 days postexposure. Survivors are considered virus free with no sequelae and, thus, are subsequently released into the wild. When adults return to spawn, infectious virus can again be isolated. Two hypotheses have been proposed to account for the source of virus in these adults. One hypothesis contends that virus in the epizootic survivors is cleared and that the adults are reinfected with IHNV from a secondary source during their migration upstream. The second hypothesis contends that IHNV persists in a subclinical or latent form and the virus is reactivated during the stress of spawning. Numerous studies have been carried out to test these hypotheses and, after 20 years, questions still remain regarding the maintenance of IHNV in salmonid fish populations. In the study reported here, IHNV-specific lesions in the hematopoietic tissues of rainbow trout survivors, reared in specific-pathogen-free water, were detected 1 year after the epizootic. The fish did not produce infectious virus. The presence of viral protein detected by immunohistochemistry, in viral RNA by PCR amplification, and in IHNV-truncated particles by immunogold electron microscopy confirmed the presence of IHNV in the survivors and provided the first evidence for subclinical persistence of virus in the tissues of IHNV survivors.     

Polymorphisms in MHC class Ia genes and resistance to IHNV in rainbow trout (Oncorhynchus mykiss)

Infectious haematopoietic necrosis virus (IHNV) is detrimental to the farming of rainbow trout (Oncorhynchus mykiss) and other salmonids in the Northern hemisphere. The major histocompatibility complex (MHC) plays a key role in immune response in invertebrates, as evidenced by the close correlation of MHC polymorphisms with disease resistance/susceptibility. To analyse the correlation between rainbow trout resistance and susceptibility to IHNV and genetic variation in exon 2 of MHC class Ia gene, UBA, we employed two approaches, namely, polymerase chain reaction-single strand conformation polymorphism analysis and cloning/sequencing. From 102 resistant and 82 susceptible individuals, a total of 12 alleles in UBA exon 2 (GenBank: JX136662–JX136673) were identified, including 11 novel alleles. The maximum number of these alleles in a single individual was four, suggesting that UBA exon 2 most likely resides on at least two loci in the genome. Most of the variations in UBA exon 2 were located in the peptide-binding region and were determined to have been subject to positive selection during evolution. Correlation analysis revealed that Onmy-UBA*0111 and Onmy-UBA*0107 are highly associated with IHNV susceptibility (P = 0.001), whereas Onmy-UBA*0101, Onmy-UBA*0102, and Onmy-UBA*0103 are highly related to IHNV resistance (P = 0.000). In addition, the three resistant alleles were predominant in the IHNV disease-resistant population; thus, these molecular markers can be used for anti-IHNV breeding of rainbow trout.     

Genetic resistance to rhabdovirus infection in teleost fish is paralleled to the derived cell resistance status

Genetic factors of resistance and predisposition to viral diseases explain a significant part of the clinical variability observed within host populations. Predisposition to viral diseases has been associated to MHC haplotypes and T cell immunity, but a growing repertoire of innate/intrinsic factors are implicated in the genetic determinism of the host susceptibility to viruses. In a long-term study of the genetics of host resistance to fish rhabdoviruses, we produced a collection of double-haploid rainbow trout clones showing a wide range of susceptibility to Viral Hemorrhagic Septicemia Virus (VHSV) waterborne infection. The susceptibility of fibroblastic cell lines derived from these clonal fish was fully consistent with the susceptibility of the parental fish clones. The mechanisms determining the host resistance therefore did not associate with specific host immunity, but rather with innate or intrinsic factors. One cell line was resistant to rhabdovirus infection due to the combination of an early interferon IFN induction--that was not observed in the susceptible cells--and of yet unknown factors that hamper the first steps of the viral cycle. The implication of IFN was well consistent with the wide range of resistance of this genetic background to VSHV and IHNV, to the birnavirus IPNV and the orthomyxovirus ISAV. Another cell line was even more refractory to the VHSV infection through different antiviral mechanisms. This collection of clonal fish and isogenic cell lines provides an interesting model to analyze the relative contribution of antiviral pathways to the resistance to different viruses.     

Immunogenicity of a recombinant infectious hematopoietic necrosis virus glycoprotein produced in insect cells.

A recombinant infectious hematopoietic necrosis virus (IHNV) glycoprotein (G protein), produced in Spodoptera frugiperda (Sf9) cells following infection with a baculovirus vector containing the full-length (1.6 kb) glycoprotein gene, provided very limited protection in rainbow trout Oncorhynchus mykiss challenged with IHNV. Fish were injected intraperitoneally (i.p.) with Sf9 cells grown at 20 degrees C (RecGlow) or 27 degrees C (RecGhigh) expressing the glycoprotein gene. Various antigen (Ag) preparations were administered to adult rainbow trout or rainbow trout fry. Sera collected from adult fish were evaluated for IHNV neutralization activity by a complement-dependent neutralization assay. Anti-IHNV neutralizing activity was observed in sera, but the percent of fish responding was significantly lower (p < 0.05) in comparison to fish immunized with a low virulence strain of IHNV (LV-IHNV). A small number of fish immunized with RecGlow or RecGhigh possessed IHNV G protein specific antibodies (Abs) in their serum. Cumulative mortality (CM) of rainbow trout fry (mean weight, 1 g) vaccinated by i.p. injection of freeze/thawed Sf9 cells producing RecGlow was 18% in initial trials following IHNV challenge. This level of protection was significant (p < 0.05) but was not long lasting, and neutralizing Abs were not detected in pooled serum samples. When trout fry (mean weight, 0.6 g) were vaccinated with supernatant collected from sonicated Sf9 cells, Sf9 cells producing RecGlow, or Sf9 cells producing RecGhigh, CM averaged 46%. Protection was enhanced over negative controls, but not the positive controls (2% CM), suggesting that in the first trial soluble cellular proteins may have provided some level of non-specific protection, regardless of recombinant protein expression. Although some immunity was elicited in fish, and RecGlow provided short-term protection from IHNV, Ab-mediated protection could not be demonstrated. The results suggest that recombinant G proteins produced in insect cells lack the immunogenicity associated with vaccination of fish with an attenuated strain of IHNV.     

Recombinant infectious hematopoietic necrosis viruses induce protection for rainbow trout Oncorhynchus mykiss

Infectious hematopoietic necrosis virus (IHNV) and viral hemorrhagic septicaemia virus (VHSV) are rhabdoviruses that infect salmonids, producing serious economic losses. Two recombinant IHN viruses were generated by reverse genetics. For one (rIHNV GFP) the IHNV NV gene was replaced with the green fluorescent protein (GFP) gene. In the other (rIHNV-Gvhsv GFP) the G gene was also exchanged for that of VHSV. No mortalities, external signs or histological lesions were observed in experimental infections conducted with the recombinant viruses. Neither the rIHNV GFP nor rIHNV-Gvhsv GFP was detected by RT-PCR in any of the examined tissues from experimentally infected fish. In order to assess their potential as vaccines against the wild type viruses, rainbow trout were vaccinated with the recombinant viruses by intraperitoneal injection and challenged 30 d later with virulent IHNV or VHSV. The GFP viruses provided protection against both wild type viruses. None of the recombinant viruses induced antibody production, and the expression of interferon (IFNalpha4) and interferon induced genes such as Mx protein and ISG-15 was not different to that of controls. The rIHNV-Gvhsv GFP did not inhibit cellular apoptosis as it was observed in an IHNV inoculated fish cell line. These studies suggest that the recombinant rIHNV-Gvhsv GFP is a promising candidate as a live recombinant vaccine and also provides a good model to further study viral pathogenicity and the molecular basis of protection against these viral infections.