Molecular analysis of grass carp reovirus HZ08 genome segments 1-3 and 5-6

Identification, Virulence, and Molecular Characterization of a Recombinant Isolate of Grass Carp Reovirus Genotype I

The hemorrhagic disease of grass carp (HDGC) caused by grass carp reovirus (GCRV) still poses a great threat to the grass carp industry. Isolation and identification of the GCRV genotype I (GCRV-I) has been rarely reported in the past decade. In this study, a new GCRV was isolated from diseased fish with severe symptoms of enteritis and mild hemorrhages on the body surface. The isolate was further identified by cell culture, transmission electron, indirect immunofluorescence, and SDS-PAGE electrophoretic pattern analysis of genomic RNA. The results were consistent with the new isolate as a GCRV-I member and tentatively named GCRV-GZ1208. Both grass carp and rare minnow infected by the GCRV-GZ1208 have no obvious hemorrhagic symptoms, and the final mortality rate was ≤10%, indicating that it may be a low virulent isolate. GZ1208 possessed highest genomic homology to 873/GCHV (GCRV-I) and golden shiner reovirus (GSRV). Additionally, it was found a 90.7-98.3% nucleotide identity, a 96.4-100% amino acid identity, and <50% identity with GCRV-II and III genotypes. Interestingly, the sequences of some segments of GZ1208 were similar to GCRV-8733/GCHV, whereas the remaining segments were more closely related to GSRV, suggesting that a recombination event had occurred. Bootscan analysis of the complete genomic sequence confirmed this hypothesis, and recombination events between 873/GCHV and other GSRV-like viruses were also accompanied by gene mutations.

TBK1 regulates the induction of innate immune response against GCRV by phosphorylating IRF3 in rare minnow (Gobiocypris rarus)

Rare minnow (Gobiocypris rarus), a small cyprinid species that is highly sensitive to the grass carp reovirus (GCRV), is regarded as an ideal model to study the mechanisms of innate immunity in fish. In the present study, a TBK1 homologue from rare minnow (GrTBK1) was identified and its roles in defence against viral infection were investigated. Sequence analysis showed that GrTBK1 encoded a 727-amino acid peptide which shared 98% and 72% identity to the black carp (Mylopharyngodon piceus) and human (Homo sapiens) orthologues, respectively. The amino acid sequence analysis demonstrated that GrTBK1 contains a conserved Serine/Threonine protein kinases catalytic domain (S_TKc) at the N-terminus. Furthermore, cellular distribution proved that GrTBK1 was located in the cytoplasm region. Quantitative real-time PCR analysis revealed that GrTBK1 was ubiquitously expressed in all examined organs, but especially highly in liver. Temporal expression analysis in vivo showed that the expression levels of GrTBK1 were obviously up-regulated in response to GCRV infection. Meanwhile, qRT-PCR assay revealed that the levels of S7 RNA, an important segment of GCRV genome, were higher in the liver than in other tissues. This indicates that GrTBK1 might play a crucial role in responses to GCRV infection in fish. In addition, GrTBK1 activated several type I interferon (IFN) promoters and induced the expression of downstream type I IFN-stimulated genes (ISGs). Furthermore, GrTBK1 obviously phosphorylated the interferon regulatory factor 3 (IRF3). Furthermore, overexpression of GrTBK1 remarkably decreased the GCRV proliferation. In summary, we systematically characterized GrTBK1 and illustrated its role in the innate immune response to GCRV infections.

Studies on the clinical symptoms, virus distribution, and mRNA expression of several antiviral immunity-related genes in grass carp after infection with genotype II grass carp reovirus

The viral hemorrhage disease caused by grass carp reovirus (GCRV) is a serious contagious disease of grass carp that mainly infects fingerlings and yearlings. Epidemiological studies have shown that GCRV genotype II is currently the prominent genotype. However, little is known about the histopathological characteristics, virus distribution, and expression of immunity-related genes in grass carp infected by GCRV genotype II. In this study, we found that grass carp infected by GCRV genotype II lost appetite, swam alone, and rolled, and their fins, eyes, operculum, oral cavity, abdomen, intestine, and muscles showed pronounced punctate hemorrhage. Congestion, swelling, deformation, thinning of membranes, dilatation and darkened color of nucleoli, cathepsis, erythrocyte infiltration, and vacuole formation were observed in some infected tissues. A qRT-PCR test showed that the 11 genome segments of GCRV had similar expression patterns in different tissues. The S8 segment, with unknown function and no homologous sequences, had the highest expression level, while the most conserved segment, L2, had the lowest expression level. GCRV particles were distributed in different tissues, especially in the intestine. In the infected intestine, the expression of various receptors and adaptor molecules was modulated at different levels. Pro-inflammatory cytokine interleukin-1β (IL-1β) expression was 2160.9 times higher than that in the control group. The upregulation of immunity-related genes activated the antiviral immunity pathways. Therefore, the intestine might play a dual role in mediating GCRV infection and the antiviral immune response. This study provides detailed information about the pathogenicity of GCRV and expression of immunity-related genes, laying the foundation for further research on virus control and treatment.

A developed subunit vaccine based on fiber protein VP56 of grass carp reovirus providing immune protection against grass carp hemorrhagic disease

Grass carp reovirus (GCRV) is the main viral pathogen that endangers grass carp seriously. Application of vaccine has been considered to be the most effective way to prevent virus infection. VP56 is a protein encoded by gene segment 7 of grass carp reovirus, and is predicted to share homology with fiber protein of mammalian reovirus (MRV). In our study, the immunogenicity of VP56 was evaluated by neutralization test. GCRV was incubated with mouse anti-VP56 antibody, and then was injected into grass carp. Results showed that disease progress and death occurrence was hindered in the experimental group compared with the control group. For further study, the recombinant VP56 protein (rVP56) expressed by pET-32a (+) vector was purified, and was used as subunit vaccine to immunize grass carp. After each fish (15 ± 1.5 g) was injected with 30 μg purified rVP56 intraperitoneally, the immune protective efficacy of recombinant VP56 protein was assessed by a series of immune parameters. The population of red blood cells in immunized fish increased significantly after 5 d post injection (dpi), and reached a peak with (2.98 ± 0.17) × 10⁹/ml at 7 dpi (p < 0.05). The numbers of white blood cells peaked with (8.42 ± 1.01) × 10⁷/ml at 7 dpi (p < 0.05). Additionally, the percentage of monocytes and neutrophils rose to a peak with (9.05 ± 0.92)% and (25.93 ± 2.60)% respectively at 5 dpi (p < 0.05 or p < 0.01), whereas lymphocytes reached the highest value of (85.81 ± 2.73) % at 14 dpi (p < 0.01). Serum antibody titer in the vaccinated fish increased significantly and reached a peak at 21 dpi (p < 0.01). The mRNA expression levels of type I interferon (IFN1), major histocompatibility complex class I (MHC I), Toll-like receptor 22 (TLR22), and immunoglobulin M (IgM) were significantly up-regulated in head kidney and spleen (p < 0.05 or p < 0.01). The GCRV challenge test showed that the relative survival rate in immunized group was 71%-75%. Collectively, the results indicated that rVP56 protein can induce immune protection in grass carp, and can be consider as a candidate vaccine against GCRV infection.

Development of indirect immunofluorescence assay for TCID50 measurement of grass carp reovirus genotype II without cytopathic effect onto cells

Grass carp reovirus (GCRV) caused severe hemorrhagic disease with significant losses of fingerling and yearling grass carp, Cyenopharyngodon idellus, in southeast Asian. It was first isolated in 1983 in China, and clade analysis of the different GCRV isolates indicates there are at least three different genotypes I, II, and III. In recent years, GCRV genotype II has been determined as a dominant virus type which cause severe obvious clinical signs in fish but no cytopathic effect onto presently available cell culture. TCID₅₀ is one of standard method to quantity infectious virus particles. In the present study, an indirect immunofluorescence assay (IFA) was developed using antibody against a protein encoded by segment 10 of GCRV genotype II. Moreover, the specific assay to differentitate GCRV of different genotypes and a sensitive assay for determination of GCRV genotype II were developed respectively. The results showed the IFA only can recognize genotype II virus at the lowest initial concentration of 550 genomic copies/ml. Furthermore, comparison of results obtained from qPCR and the TCID₅₀ assay combined IFA was conducted. The results indicated that TCID₅₀ of GCRV isolates JX0901 and HZ08 differs with 2 log steps reduction in the numbers of viruses compared with the number of genome copies detected by qPCR. The immunofluorescence assay developed is sensitive, specific, and the TCID₅₀ combined with IFA will be a standardizable technique for the quantitation and detection of infectious GCRV in cell culture without cytolysis.

Structure and function of S9 segment of grass carp reovirus Anhui strain

A highly virulent grass carp reovirus (GCRV) strain, named GCRV-AH528, was recently purified from a diseased grass carp with hemorrhage disease in Anhui, China. GCRV-AH528 S9 segment was 1320 nucleotides in length and encoded a 418 amino acid VP6 protein. BLAST search showed that the VP6 protein owned a conserved domain belonging to the reoviral σ2 family. Phylogenetic analysis of VP6 presented that GCRV-AH528 belonged to GCRV genotype II, which was more closely related to Orthoreovirus than GCRV genotype I and genotype III. Further analysis revealed that GCRV-AH528 S9 and mammalian orthoreovirus S8 might have evolved from a common ancestral precursor and have identical mechanism in virus assembly. The expression level of vp6 gene was detected by quantitative real-time PCR (qRT-PCR). Over time, the expression level of vp6 gradually increased in Ctenopharyngodon idellus kidney cells. However, the level of vp6 expression in blood sharply increased at 4-6 days, and then decreased to a low level after GCRV-AH528 challenge (P < 0.05). The vp6 gene was detected in all tissues examined, whereas at relatively higher levels in blood, kidney, and liver (P < 0.05). The yeast two-hybrid (Y2H) system was used to identify VP6 self-interaction, while no interaction was detected in VP6-VP6. This study not only revealed the S9 segment structure and expression pattern but also analyzed the VP6 mechanism by yeast hybridization method. The present study provides valuable informations for further experimental design and investigation of VP6 functions.

Moroxydine hydrochloride inhibits grass carp reovirus replication and suppresses apoptosis in Ctenopharyngodon idella kidney cells

Moroxydine hydrochloride (Mor) is known to have multi-antiviral activities against DNA and RNA viruses but very little information exists on its pharmacology. The paper was undertaken to explore the antiviral response and antiapoptotic mechanism of Mor against grass carp reovirus (GCRV) in Ctenopharyngodon idella kidney (CIK) cells. The results showed that exposing GCRV-infected cell to 6.3 μg mL(-1) of Mor for 96 h avoid ca. 50% apoptosis. Meanwhile, Mor had lower cytotoxicity than ribavirin (Rib) as the value of safe concentration was threefold higher than effective concentration and the compound could ensure sufficient into and out of cells within 4 h when tested at the maximal safe concentration. Mor blocked the GCRV-induced cytopathic effects and eliminated nucleocapsids in CIK cells to keep the normal morphological structure. Moreover, the expressions of viral protein genes were significantly inhibited especially the guanylyl transferase and RNA-dependent RNA polymerase related expression. Furthermore, GCRV caused Bcl-2 down-regulation and Bax mitochondrial translocation was prevented by treatment of CIK cells with Mor. The downstream effector, caspase activity was also significantly inhibited in Mor treated cells. The potential mechanism might be that mitochondrial apoptotic signals were not activated by the intervention of Mor for targeting viral gene expression. Taken together, Mor showed high anti-GCRV activity and had been proved as a secure and promising agent in viral controlling in aquaculture industry.

Development and application of monoclonal antibodies for detection and analysis of aquareoviruses

Monoclonal antibodies (mAbs) play an important role in detection of aquareoviruses. Three mAbs against grass carp reovirus (GCRV) were prepared. Isotyping revealed that all three mAbs were of subclass IgG2b. Western blot assay showed that all three mAbs reacted with GCRV 69 kDa protein (the putative VP5). In addition to the 69 kDa protein of GCRV, mAb 4B6 also recognize a 54 kDa protein. All three mAbs were used for detecting aquareovirus by Western blot assay and indirect immunofluorescence assay (IFA). All of them reacted with GCRV, and mAb 4A3 could also react with turbot Scophthalmus maximus reovirus (SMReV) and largemouth bass Microptererus salmonides reovirus (MsReV). Viral antigens were only observed in the cytoplasm of infected cells. Finally, syncytia formation was observed with light microscopy and fluorescence microscopy using fluorescein labelled 4A3 mAb at various times post-infection. Syncytia were observed at 36 hr post-infection (hpi) by light microscopy and at 12 hpi by fluorescence microscopy. The immunofluorescence based assay allowed earlier detection of virus than observation of virus-induced cytopathic effect (CPE) assay in inoculated cell cultures. The sensitivity and specificity of these mAbs may be useful for diagnosis and monitoring of aquareoviruses.

Fish reovirus GCReV-109 VP33 protein elicits protective immunity in rare minnows

Grass carp reovirus strain 109 (GCReV-109) was previously isolated from a grass carp (Ctenopharyngodon idellus) with hemorrhagic disease, and its complete genome has been sequenced. However, the infectivity of GCReV-109 has not been studied, and the viral protein VP33, encoded on genome segment S11, had no detectable sequence homology to other known reovirus proteins. In this study, we characterized GCReV-109 infections in vivo and in vitro, as well as the VP33 protein. Infectivity analysis showed that GCReV-109 caused severe hemorrhagic disease and 100% mortality at dilutions up to 10(-4) in rare minnows (Gobiocypris rarus) by 8 days postinfection, but no visible cytopathic effect was observed in GCReV-109-infected subcultured grass carp muscle (GCM) cells. To confirm that GCReV-109 could be propagated in GCM cells, three virus genome segments were detected by RT-PCR, and large numbers of virus particles were observed by transmission electron microscopy in samples from the infected GCM cells. The suspension of GCReV-109-infected GCM cells was pathogenic to rare minnows. VP33 protein was expressed and purified for generation of an anti-VP33 antiserum. In western blot analysis of purified GCReV-109 particles, the antiserum specifically recognized a protein band (approximately 33 kDa). This revealed that VP33 is a major structural protein of GCReV-109 that might have immunogenic properties. The protective efficacy of the anti-VP33 antiserum against GCReV-109 infection was tested. The death of infected fish was delayed and the mortality fell to 10% when fish were treated with the anti-VP33 antiserum, suggesting that it might be useful for the prevention and control of fish reoviral disease.

Proteomic analysis of cellular protein expression profiles in response to grass carp reovirus infection

Grass carp (Ctenopharyngodon idella) hemorrhagic disease, caused by grass carp reovirus (GCRV), is emerging as a serious problem in grass carp aquaculture. To better understand the molecular responses to GCRV infection, two-dimensional electrophoresis (2-DE) and matrix-assisted laser desorption/ionization tandem mass spectroscopy were performed to investigate altered proteins in C. idella kidney (CIK) cells. Differentially expressed proteins in mock infected CIK cells and GCRV-infected CIK cells were compared. Twenty-three differentially expressed spots were identified (22 upregulated spots and 1 downregulated spot), which included cytoskeleton proteins, macromolecular biosynthesis-associated proteins, stress response proteins, signal transduction proteins, energy metabolism-associated proteins and ubiquitin proteasome pathway-associated proteins. Moreover, 10 of the corresponding genes of the differentially expressed proteins were quantified by real-time reverse transcription polymerase chain reaction to examine their transcriptional profiles. The T cell internal antigen 1 (TIA1) and Ras-GTPase-activating SH3-domain-binding protein1 (G3BP1) of the cellular stress granule pathway from grass carp C. idella (designated as CiTIA1 and CiG3BP1) were upregulated and downregulated during GCRV infection, respectively. The full-length cDNA of CiTIA1 was 2753 bp, with an open reading frame (ORF) of 1155bp, which encodes a putative 385-amino acid protein. The 2271 bp full-length cDNA of CiG3BP1 comprised an ORF of 1455 bp that encodes a putative 485-amino acid protein. Phylogenetic analysis revealed that the complete ORFs of CiTIA1 and CiG3BP1 were very similar to zebrafish and well-characterized mammalian homologs. The expressions of the cellular proteins CiTIA1 and CiG3BP1 in response to GCRV were validated by western blotting, which indicated that the GCRV should unlink TIA1 aggregation and stress granule formation. This study provides useful information on the proteomic and cellular stress granule pathway's responses to GCRV infection, which adds to our understanding of viral pathogenesis.

Insights into the antiviral immunity against grass carp (Ctenopharyngodon idella) reovirus (GCRV) in grass carp

Global fish production from aquaculture has rapidly grown over the past decades, and grass carp shares the largest portion. However, hemorrhagic disease caused by grass carp reovirus (GCRV) results in tremendous loss of grass carp (Ctenopharyngodon idella) industry. During the past years, development of molecular biology and cellular biology technologies has promoted significant advances in the understanding of the pathogen and the immune system. Immunoprophylaxis based on stimulation of the immune system of fish has also got some achievements. In this review, authors summarize the recent progresses in basic researches on GCRV; viral nucleic acid sensors, high-mobility group box proteins (HMGBs); pattern recognition receptors (PRRs), Toll-like receptors (TLRs) and retinoic acid inducible gene I- (RIG-I-) like receptors (RLRs); antiviral immune responses induced by PRRs-mediated signaling cascades of type I interferon (IFN-I) and IFN-stimulated genes (ISGs) activation. The present review also notices the potential applications of molecule genetic markers. Additionally, authors discuss the current preventive and therapeutic strategies (vaccines, RNAi, and prevention medicine) and highlight the importance of innate immunity in long term control for grass carp hemorrhagic disease.

A one-step duplex rRT-PCR assay for the simultaneous detection of grass carp reovirus genotypes I and II

Hemorrhagic disease of grass carp, caused by grass carp reovirus (GCRV), leads to severe economic losses in the grass carp farming industry in China. GCRV has been divided into three genotypes based on genome sequence. Genotypes I and II (GCRV-1 and GCRV-II, respectively) are the dominant genotypes and co-infections of GCRV-I and GCRV-II are common in grass carp aquaculture. A one-step duplex real-time reverse transcriptase polymerase chain reaction (rRT-PCR) assay was developed for simultaneous detection of GCRV-I and GCRV-II. The PCR assay is suitable for early diagnosis of grass carp hemorrhagic disease and for epidemiological surveillance. The detection limit of the assay is 10 copies for both GCRV-I and GCRV-II, which is as high as single-target rRT-PCR and higher than conventional RT-PCR. No cross reactivity with other GCRV subtypes or other viruses was observed. One hundred and twelve samples from grass carp suspected of hemorrhagic disease were collected from South and Central China. Eleven samples were positive for GCRV-I by RT-PCR alone, and fourteen samples were positive by single-target and duplex rRT-PCR. Forty two samples were positive for GCRV-II by RT-PCR alone and forty seven samples were positive by single-target and duplex rRT-PCR. Mixed infections were found in eight samples when analyzed by RT-PCR alone and in ten samples analyzed by single-target and duplex rRT-PCR. The duplex rRT-PCR system provides a sensitive and specific method to detect and differentiate between GCRV-I and GCRV-II in a single sample. This rRT-PCR assay could be a useful tool for the routine diagnosis of these two viruses and for epidemiology studies in grass carp aquaculture.

Phylogenetic analysis of newly isolated grass carp reovirus

Grass carp reovirus (GCRV) is a causative agent of haemorrhagic disease in grass carp that drastically affects grass carp aquaculture. Here we report a novel GCRV isolate isolated from sick grass carp that induces obvious cytopathic effect in CIK cells and name it as GCRV096. A large number of GCRV 096 viral particles were found in the infected CIK cells by electron microscope. The shape, size and the arrangement of this virus were similar to those of grass carp reovirus. With the primers designed according to GCRV 873 genome sequences, specific bands were amplified from sick grass carp and the infected CIK cells. The homology rates among vp4, vp6 and vp7 gene in GCRV 096 and those of some GCRV isolates were over 89%. In this study, the sequences of vp4, vp6 and vp7 were used to analyse sequence variation, phylogenetic relationships and genotypes in twenty five GCRV isolates. The results indicated these twenty five GCRV isolates should be attributed to four genotypes. And there were no obvious characteristics in the geographical distribution of GCRV genotype. The study should provide the exact foundation for developing more effective prevention strategies of grass carp haemorrhagic disease.

Complete genome sequence and comparative analysis of grass carp reovirus strain 109 (GCReV-109) with other grass carp reovirus strains reveals no significant correlation with regional distribution

A new grass carp reovirus strain, tentatively named GCReV-109, was isolated in Hubei, China, and its complete genome sequence was determined. The genome contained 11 double-stranded RNA segments (S1-S11) covering 24,620 base pairs. All of the segments had conserved terminal nucleotides, with GUAA(U)/CU at the 5' end and UCAUC at the 3' end. Protein sequence comparison showed that GCReV-109 was most closely related to GCRV-GD108 and shared 96.6-99.5 % protein sequence identity but only shared 16.7-46.1 and 15.1-45.4 % identity with GCRV-873 and HGDRV, respectively. Phylogenetic analysis showed that grass carp reovirus strains in China can be divided into three genotypes. Further analysis revealed homology between the GCRV-109 VP56 and HGDRV VP55 proteins, as well as GCReV-109 NS38, GCRV-873 NS38, and HGDRV VP39. The results of these comparisons also indicated that the homology between viruses was not necessarily linked to their geographical distribution. Our study will help in recognizing and understanding the genome structure and genetic diversity of grass carp reovirus.

Proteomic identification, characterization and expression analysis of Ctenopharyngodon idella VDAC1 upregulated by grass carp reovirus infection

Voltage-dependent anion channels (VDACs) located in the mitochondrial outer membrane are mitochondrial porins that play central roles in regulating cell life and death. In this present report, the VDAC protein 1 from grass carp Ctenopharyngodon idella (designated as CiVDAC1) was found to be upregulated by grass carp reovirus (GCRV) infection through two-dimensional gel electrophoresis and protein analysis of infected C. idella kidney (CIK) cells. The full-length cDNA of CiVDAC1 was 995 bp with an open reading frame (ORF) of 852 bp that encodes a putative 283-amino acid protein. Phylogenic analysis revealed that the complete ORF of CiVDAC1 demonstrated high identity with well characterized mammalian homologs. The deduced CiVDAC1 protein contains an α-helix at the amino terminal, 19 membrane-spanning β-strands, and one eukaryotic mitochondrial porin signature motif. Tissue tropism analysis indicated that CiVDAC1 is abundant in muscle, heart, skin, swim bladder, trunk kidney and spleen. Transcriptional expression profiles indicated that the CiVDAC1 gene was upregulated upon viral challenge in a manner similar to the Mx2 gene, which is a marker gene used to indicate activation of innate antiviral immunity. Similar expression patterns of the CiVDAC1 gene were observed in CIK cells stimulated with poly (I:C), as well as grass carp kidney tissue challenged with GCRV in vivo. CiVDAC1 silencing in CIK cells had no impact on progeny virus production, but over-expression of CiVDAC1 in vivo showed strongly protect against challenge with live virus. To interpret the role of other VDAC proteins in viral pathogenesis, CiVDAC2 was characterized and showed to respond positively to GCRV challenge, which suggested that CiVDAC2 might functionally complement CiVDAC1 in C. idella. The present data did demonstrate that CiVDAC1 might be mediated grass carp antiviral immune response.

A cross-sectional study of the association between risk factors and hemorrhagic disease of grass carp in ponds in Southern China

A cross-sectional survey of 215 Grass Carp Ctenopharyngodon idella ponds was conducted in southern China between May 2010 and November 2011. An in-depth questionnaire was developed to evaluate a series of biosecurity practices, environmental factors, and management factors at the farm level. Fish samples with clinical hemorrhagic signs were also collected from each pond to assess the clinical disease of Grass Carp reovirus by using reverse transcription (RT) PCR assay. The association between the incidence of Grass Carp hemorrhagic disease (GCHD) and risk factors was analyzed using logistic regression. Of the 215 ponds, 144 showed GCHD-positive responses to RT-PCR assay. In addition, survey results revealed that inferior environmental conditions occurred in most ponds with an incidence of GCHD; such conditions included a thick mud layer; no cleansing and restoration practices (CRPs) before culture; and poor water quality (i.e., high ammonia nitrogen and nitrite concentrations and low transparency). Logistic regression model results suggested that decreased risks were associated with fry vaccination, a safe water source, and deepening of the water level, whereas increased risk factors mainly included no CRPs, excessive rearing density, disease history, and inferior water quality. Presently, control efforts are restricted to immunization of Grass Carp as the best management option for farms. Deepening the water levels and improving water sources can also effectively reduce the incidence of GCHD by diluting the pond rearing densities.

Molecular cloning and immune responsive expression of a ribonuclease III orthologue involved in RNA interference, dicer, in grass carp Ctenopharyngodon idella

In this study, the dicer gene (designated as cidicer) was identified and characterized from grass carp Ctenopharyngodon idella. The complementary DNA (cDNA) of cidicer contained an open reading frame (ORF) of 5646 nucleotides (nts) encoding a putative protein of 1881 amino acids (aa). The deduced Dicer protein contained all known functional domains identified in other organisms. Tissue tropism analysis indicated that cidicer is abundantly expressed in brain, gill, head kidney, liver, spleen, heart, muscle and intestine. In the C. idella kidney (CIK) cells, messenger RNA (mRNA) expression of cidicer was significantly up-regulated at 24 h (6·36-fold, P < 0·01) after grass carp reovirus (GCRV) infection, and its transcriptional expression level was also transiently induced to a high level (6·54-fold, P < 0·01) at 2 h post-stimulation of synthetic double-stranded polyinosinic-polycytidylic potassium salt [poly(I:C)]. In vivo analysis further showed that the expression of cidicer mRNA in the liver was induced to a significantly high level at 12 h (8·46-fold, P < 0·01), and then dropped to normal level at 72 h post-challenge with GCRV. The transcriptional expression pattern of cidicer in the spleen tissue was similar to that of liver tissue upon GCRV challenge. These results collectively implied that the identified cidicer was an inducible gene responding to viral infection both in vitro and in vivo, and the data would shed light on the interaction between RNA interference (RNAi) antiviral pathway and aquareovirus infection.

Identification and genomic characterization of a novel fish reovirus, Hubei grass carp disease reovirus, isolated in 2009 in China

A novel fish reovirus, Hubei grass carp disease reovirus (HGDRV; formerly grass carp reovirus strain 104, GCRV104), was isolated from diseased grass carp in China in 2009 and the full genome sequence was determined. This reovirus was propagated in a grass carp kidney cell line with a typical cytopathic effect. The total size of the genome was 23 706 bp with a 51 mol% G+C content, and the 11 dsRNA segments encoded 12 proteins (two proteins encoded by segment 11). A nucleotide sequence similarity search using blastn found no significant matches except for segment 2, which partially matched that of the RNA-dependent RNA polymerase (RdRp) from several viruses in the genera Aquareovirus and Orthoreovirus of the family Reoviridae. At the amino acid level, seven segments (Seg-1 to Seg-6, and Seg-8) matched with species in the genera Aquareovirus (15-46 % identities) and Orthoreovirus (12-44 % identities), while for four segments (Seg-7, Seg-9, Seg-10 and Seg-11) no similarities in these genera were found. Conserved terminal sequences, 5'-GAAUU----UCAUC-3', were found in each HGDRV segment at the 5' and 3' ends, and the 5'-terminal nucleotides were different from any known species in the genus Aquareovirus. Phylogenetic analysis based on RdRp amino acid sequences from members of the family Reoviridae showed that HGDRV clustered with aquareoviruses prior to joining a branch common with orthoreoviruses. Based on these observations, we propose that HGDRV is a new species in the genus Aquareovirus that is distantly related to any known species within this genus.

Quantitative in vivo and in vitro characterization of co-infection by two genetically distant grass carp reoviruses

Grass carp reovirus (GCRV) is one of the most serious pathogens threatening grass carp (Ctenopharyngodon idella) production in China. Through sequence analysis, the co-existence of two genetically distant grass carp reoviruses, named GCRV-JX01 and GCRV-JX02, was revealed in the same diseased grass carp sample collected in 2011. GCRV-JX01 and GCRV-JX02 shared high levels of homology with GCRV-873 and GCRV-GD108, respectively. In contrast to GCRV-JX01, GCRV-JX02 induced no cytopathic effect in infected cells. A quantitative real-time PCR assay was employed to monitor the replication efficiency of both virus strains in either Ctenopharyngodon idella kidney (CIK) cells or infected cell supernatant. The results demonstrated that, although GCRV-JX02 did reduce the cellular replication level of GCRV-JX01 up to 10-fold during co-infection, there was no significant impact on the productive virus progeny level in supernatant compared to that of cells infected by GCRV-JX01 alone. To validate the hypothesis that both viruses might co-infect grass carp without significant interference in the field, we collected clinical samples from two different fish farms in 2012 and monitored virus loads for each fish. The data showed that 55 % of the collected fish samples were co-infected by GCRV-JX01 and GCRV-JX02, and the single virus infection rate was 10 % for GCRV-JX01 and 20 % for GCRV-JX02. For both viruses, the in vivo viral loads under co-infection and single viral infection were similar. No serological cross-reaction or cross-protection occurred between GCRV-JX01 and JX02 in our immunization and challenge tests. This new information on co-infection by two genetically distant virus strains should be helpful for designing vaccines targeting the causative agents of grass carp haemorrhagic disease.

A one-step molecular biology method for simple and rapid detection of grass carp Ctenopharyngodon idella reovirus (GCRV) HZ08 strain

Six reverse-transcription loop-mediated isothermal amplification (RT-LAMP) primers designed against conserved regions of segment 6 (s6) gene were used for the detection of grass carp Ctenopharyngodon idella reovirus (GCRV) HZ08 subtype. The entire amplification could be completed within 40 min at 62·3° C. The RT-LAMP showed higher sensitivity than reverse-transcription polymerase chain reaction (RT-PCR). The RNA detection limit was 10 copies µl⁻¹ for RT-LAMP assay and 100 copies µl⁻¹ for conventional RT-PCR. In specificity tests, no cross-reactivity was detected in other viruses from common aquatic animals. In addition, the reaction results can be visualized by using calcein fluorescent dye. Furthermore, a total of 86 samples were tested by RT-LAMP, RT-PCR and virus isolation. The results demonstrated that all 54 specimens identified as positive by virus isolation were also positive when detected by RT-LAMP. Seven out of 54 samples, however, were misidentified by RT-PCR. The RT-LAMP method is more accurate than conventional RT-PCR. The results indicate that RT-LAMP has potential as a simple and rapid diagnosis technique for the detection of GCRV HZ08 subtype infection.

Suppression of RNA interference pathway in vitro by Grass carp reovirus

The means of survival of genomic dsRNA of reoviruses from dsRNA-triggered and Dicer-initiated RNAi pathway remains to be defined. The present study aimed to investigate the effect of Grass carp reovirus (GCRV) replication on the RNAi pathway of grass carp kidney cells (CIK). The dsRNA-triggered RNAi pathway was demonstrated unimpaired in CIK cells through RNAi assay. GCRV-specific siRNA was generated in CIK cells transfected with purified GCRV genomic dsRNA in Northern blot analysis; while in GCRV-infected CIK cells, no GCRV-specific siRNA could be detected. Infection and transfection experiments further indicated that replication of GCRV correlated with the increased transcription level of the Dicer gene and functional inhibition of in vitro synthesized egfp-siRNA in silencing the EGFP reporter gene. These data demonstrated that although only the genomic dsRNA of GCRV was sensitive to the cellular RNAi pathway, unidentified RNAi suppressor protein(s) might contribute to the survival of the viral genome and efficient viral replication.

Turbot reovirus (SMReV) genome encoding a FAST protein with a non-AUG start site

Background

A virus was isolated from diseased turbot Scophthalmus maximus in China. Biophysical and biochemical assays, electron microscopy, and genome electrophoresis revealed that the virus belonged to the genus Aquareovirus, and was named Scophthalmus maximus reovirus (SMReV). To the best of our knowledge, no complete sequence of an aquareovirus from marine fish has been determined. Therefore, the complete characterization and analysis of the genome of this novel aquareovirus will facilitate further understanding of the taxonomic distribution of aquareovirus species and the molecular mechanism of its pathogenesis.

Results

The full-length genome sequences of SMReV were determined. It comprises eleven dsRNA segments covering 24,042 base pairs and has the largest S4 genome segment in the sequenced aquareoviruses. Sequence analysis showed that all of the segments contained six conserved nucleotides at the 5' end and five conserved nucleotides at the 3' end (5'-GUUUUA ---- UCAUC-3'). The encoded amino acid sequences share the highest sequence identities with the respective proteins of aquareoviruses in species group Aquareovirus A. Phylogenetic analysis based on the major outer capsid protein VP7 and RNA-dependent RNA polymerase were performed. Members in Aquareovirus were clustered in two groups, one from fresh water fish and the other from marine fish. Furthermore, a fusion associated small transmembrane (FAST) protein NS22, which is translated from a non-AUG start site, was identified in the S7 segment.

Conclusions

This study has provided the complete genome sequence of a novel isolated aquareovirus from marine fish. Amino acids comparison and phylogenetic analysis suggested that SMReV was a new aquareovirus in the species group Aquareovirus A. Phylogenetic analysis among aquareoviruses revealed that VP7 could be used as a reference to divide the aquareovirus from hosts in fresh water or marine. In addition, a FAST protein with a non-AUG start site was identified, which partially contributed to the cytopathic effect caused by the virus infection. These results provide new insights into the virus-host and virus-environment interactions.

The use of an in vitro microneutralization assay to evaluate the potential of recombinant VP5 protein as an antigen for vaccinating against Grass carp reovirus

Background

Grass carp reovirus (GCRV) is the causative pathogen of grass carp hemorrhagic disease, one of the major diseases damaging grass carp Ctenopharyngon idellus breeding industry in China. Prevention and control of the disease is impeded largely due to the lack of research in economic subunit vaccine development. This study aimed to evaluate the potential of viral outer shell protein VP5 as subunit vaccine.

Methods

The vp5 gene was isolated from the viral genome through RT-PCR and genetically engineered to express the recombinant VP5 protein in E coli. The viral origin of the recombinant protein was confirmed by Western blot analysis with a monoclonal antibody against viral VP5 protein. Polyclonal antibody against the recombinant VP5 protein was prepared from mice. A microneutralization assay was developed to test its neutralizing ability against GCRV infection in cell culture.

Results

The GST-VP5 fusion protein (rVP5) was produced from E. Coli with expected molecular weight of 90 kDa. The protein was purified and employed to prepare anti-VP5 polyclonal antibody from mice. The anti-VP5 antibody was found to neutralize GCRV through in vitro microneutralization assay and viral progeny quantification analysis.

Conclusions

The present study showed that the viral VP5 protein was involved in viral infection and bacterially-expressed VP5 could be suitable for developing subunit vaccine for the control of GCRV infection.