Keisuke Nakagawa

Rabies Virus Nucleoprotein Functions To Evade Activation of the RIG-I-Mediated Antiviral Response

ABSTRACT The rabies virus Ni-CE strain causes nonlethal infection in adult mice after intracerebral inoculation, whereas the parental Nishigahara (Ni) strain kills mice. We previously reported that the chimeric CE(NiN) strain with the N gene from the Ni strain in the genetic background of the Ni-CE strain kills adult mice, indicating that the N gene is related to the different pathogenicities of Ni and Ni-CE strains. In the present study, to obtain an insight into the mechanism by which the N gene determines viral pathogenicity, we compared the effects of Ni, Ni-CE, and CE(NiN) infections on host gene expressions using a human neuroblastoma cell line. Microarray analysis of these infected cells revealed that the expression levels of particular genes in Ni- and CE(NiN)-infected cells, including beta interferon (IFN-β) and chemokine genes (i.e., CXCL10 and CCL5) were lower than those in Ni-CE-infected cells. We also demonstrated that Ni-CE infection activated the interferon regulatory factor 3 (IRF-3)-dependent IFN-β promoter and induced IRF-3 nuclear translocation more efficiently than did Ni or CE(NiN) infection. Furthermore, we showed that Ni-CE infection, but not Ni or CE(NiN) infection, strongly activates the IRF-3 pathway through activation of RIG-I, which is known as a cellular sensor of virus infection. These findings indicate that the N protein of rabies virus (Ni strain) has a function to evade the activation of RIG-I. To our knowledge, this is the first report that the Mononegavirales N protein functions to evade induction of host IFN and chemokines.

Role of Interferon Antagonist Activity of Rabies Virus Phosphoprotein in Viral Pathogenicity

ABSTRACT The fixed rabies virus (RV) strain Nishigahara kills adult mice after intracerebral inoculation, whereas the chicken embryo fibroblast cell-adapted strain Ni-CE causes nonlethal infection in adult mice. We previously reported that the chimeric CE(NiP) strain, which has the phosphoprotein (P protein) gene from the Nishigahara strain in the genetic background of the Ni-CE strain, causes lethal infection in adult mice, indicating that the P gene is responsible for the different pathogenicities of the Nishigahara and Ni-CE strains. Previous studies demonstrated that RV P protein binds to the interferon (IFN)-activated transcription factor STAT1 and blocks IFN signaling by preventing its translocation to the nucleus. In this study, we examine the molecular mechanism by which RV P protein determines viral pathogenicity by comparing the IFN antagonist activities of the Nishigahara and Ni-CE P proteins. The results, obtained from both RV-infected cells and cells transfected to express P protein only, show that Ni-CE P protein is significantly impaired for its capacity to block IFN-activated STAT1 nuclear translocation and, consequently, inhibits IFN signaling less efficiently than Nishigahara P protein. Further, it was demonstrated that a defect in the nuclear export of Ni-CE P protein correlates with a defect in its ability to cause the mislocalization of STAT1. These data provide the first evidence that the capacity of the RV P protein to inhibit STAT1 nuclear translocation and IFN signaling correlates with the viral pathogenicity.

Whole genome characterization of new bovine rotavirus G21P(29) and G24P(33) strains provides evidence for interspecies transmission

We have reported a novel bovine rotavirus, the AzuK-1 (G21P[29]) strain, isolated from an asymptomatic calf. We isolated another bovine rotavirus, the Dai-10 strain, bearing new G24P[33] genotypes, assigned by the Rotavirus Classification Working Group (RCWG), from an asymptomatic cow in Hyogo Prefecture, Japan in 2007. To gain an insight into the origins and evolution of these strains, we determined the complete ORF sequences of all 11 genes of the two strains. The NSP3 genes of both strains were confirmed to belong to a new NSP3 genotype, T9, by the RCWG. Genotype determination of AzuK-1 and Dai-10 strains revealed that eight gene segments of both strains possessed genotypes typically observed in bovine rotaviruses, with the exception of VP4, VP7 and NSP3 gene segments. Unexpectedly, phylogenetic analyses showed that VP6 and NSP2 gene segments of the AzuK-1 and Dai-10 strains were clustered with those of simian or canine/feline rotaviruses, rather than with those of bovine rotaviruses. These findings indicate the possibility that both strains originated by interspecies transmission and multiple reassortment events involving bovine, simian and canine/feline rotaviruses, resulting in the introduction of some genes into the genetic background of bovine rotaviruses.

Amino acids at positions 273 and 394 in rabies virus nucleoprotein are important for both evasion of host RIG-I-mediated antiviral response and pathogenicity

We previously reported that nucleoprotein (N) is related to the different pathogenicities of the virulent rabies virus strain Nishigahara (Ni) and avirulent strain Ni-CE and also that Ni N, but not Ni-CE N, functions to evade retinoic acid-inducible gene I (RIG-I)-mediated innate immunity. There are three amino acid differences between Ni and Ni-CE N (at positions 273, 394 and 395), indicating that one of these mutations or a combination of mutations is important for the pathogenicity and evasion of innate immunity. We generated Ni-CE mutants in which the amino acids in Ni-CE N were replaced with those of Ni in all combinations. Among the mutants, CE(NiN273/394) with mutations at positions 273 and 394 evaded activation of RIG-I-mediated signaling most efficiently and also showed the highest pathogenicity. This correlation reinforces the relation between evasion of host RIG-I-mediated innate immunity and pathogenicity of rabies virus.

Involvement of the Rabies Virus Phosphoprotein Gene in Neuroinvasiveness

ABSTRACT Rabies virus (RABV), which is transmitted via a bite wound caused by a rabid animal, infects peripheral nerves and then spreads to the central nervous system (CNS) before causing severe neurological symptoms and death in the infected individual. Despite the importance of this ability of the virus to spread from a peripheral site to the CNS (neuroinvasiveness) in the pathogenesis of rabies, little is known about the mechanism underlying the neuroinvasiveness of RABV. In this study, to obtain insights into the mechanism, we conducted comparative analysis of two fixed RABV strains, Nishigahara and the derivative strain Ni-CE, which cause lethal and asymptomatic infections, respectively, in mice after intramuscular inoculation. Examination of a series of chimeric viruses harboring the respective genes from Nishigahara in the genetic background of Ni-CE revealed that the Nishigahara phosphoprotein (P) gene plays a major role in the neuroinvasiveness by mediating infection of peripheral nerves. The results obtained from both in vivo and in vitro experiments strongly suggested that the Nishigahara P gene, but not the Ni-CE P gene, is important for stable viral replication in muscle cells. Further investigation based on the previous finding that RABV phosphoprotein counteracts the host interferon (IFN) system demonstrated that the Nishigahara P gene, but not the Ni-CE P gene, functions to suppress expression of the beta interferon (IFN-β) gene (Ifn-β) and IFN-stimulated genes in muscle cells. In conclusion, we provide the first data strongly suggesting that RABV phosphoprotein assists viral replication in muscle cells by counteracting the host IFN system and, consequently, enhances infection of peripheral nerves.

Importance of rabies virus nucleoprotein in viral evasion of interferon response in the brain

By using a cultured neuroblastoma cell line, the present authors recently showed that the N protein of virulent rabies virus fixed strain Nishigahara (Ni), but not that of the attenuated derivative Ni‐CE, mediates evasion of induction of type I interferon (IFN). In this study, to determine whether Ni N protein indeed fulfills this function in vivo, the abilities to suppress IFN responses in the mouse brain of Ni‐CE and the virulent chimeric virus CE(NiN), which has the N gene from Ni in the genetic background of Ni‐CE, were compared. It was demonstrated that CE(NiN) propagates and spreads more efficiently than does Ni‐CE in the brain and that IFN response in brains infected with CE(NiN) is weaker than in those infected with Ni‐CE. It was also shown that amino acids at positions 273 and 394 in the N protein, which are known as pathogenic determinants, affect the ability of the viruses to suppress IFN response in the brain. These findings strongly suggest that, in the brain, rabies virus N protein plays important roles in evasion of innate immune responses and thereby in efficient propagation and spread of virus leading to lethal outcomes of infection.

Evidence of natural transmission of group A rotavirus between domestic pigs and wild boars (Sus scrofa) in Japan.

Group A rotaviruses (RVAs) are a major cause of acute dehydrating diarrhea in infants and young animals worldwide. RVAs have also been detected in several wild and zoo animals, indicating wide susceptibility of wild animals. However, the role of wild animals in the infection cycle of RVAs is unclear. Wild boars are indigenous in many countries in the world. Japanese wild boars (Sus scrofa leucomystax) have been migrating close to human habitats in Japan, indicating the possibility of natural transmission between domestic animals or humans and wild boars. We investigated infection of RVAs in wild boars in Japan to identify types of RVAs infecting wild animals. We obtained stool samples from 90 wild boars and detected a VP4 gene of RVAs by RT-semi-nested PCR. RVAs were detected in samples from four of the 90 wild boars. Nucleotide analyses of VP7 and VP4 genes revealed that the four strains belong to G9P[23], G4P[23], G9P[13] and G4P[6], suggesting a relation to porcine and human RVAs. We therefore characterized RVAs circulating among domestic pigs living in the same area as the wild boars. We collected stool samples from 82 domestic pigs. RVAs were detected in samples from 49 of the 82 domestic pigs. Phylogenetic and similarity analyses provided evidence for natural transmission between domestic pigs and wild boars. The results also suggested that natural reassortment events occurred before or after transmission between domestic pigs and wild boars. Our findings indicate the possibility that RVAs circulate among wild animals, humans and domestic animals in nature.

Amino acid substitutions at positions 242, 255 and 268 in rabies virus glycoprotein affect spread of viral infection

Rabies virus Nishigahara strain kills adult mice after intracerebral inoculation, whereas the derivative RC‐HL strain does not. It has previously been reported by us that the R(G 242/255/268) strain, in which amino acids at positions 242, 255 and 268 on the G protein have been replaced by those from the Nishigahara strain in the genetic background of the RC‐HL strain, kills adult mice. This indicates that these three amino acids of G protein are important for pathogenicity of the Nishigahara strain. In order to obtain insights into the mechanism by which these amino acids affect pathogenicity, in this study spread of viral infection and apoptosis‐inducing ability of the attenuated RC‐HL strain and the virulent R(G 242/255/268) strain were compared. RC‐HL infection spread less efficiently in the mouse brain than did R(G 242/255/268) infection. However, the apoptosis‐inducing abilities of both viruses were almost identical, as shown by both in vitro and in vivo experiments. It was demonstrated that cell‐to‐cell spread of RC‐HL strain was less efficient than that of R(G 242/255/268) strain in mouse neuroblastoma cells. These results indicate that the three amino acid substitutions affect efficiency of cell‐to‐cell spread but not apoptosis‐inducing ability, probably resulting in the distinct distributions of RC‐HL and R(G 242/255/268) strain‐infected cells in the mouse brain and, consequently, the different pathogenicities of these strains.

Generation of a live rabies vaccine strain attenuated by multiple mutations and evaluation of its safety and efficacy

An amino acid substitution at position 333 in rabies virus G protein is known to determine the pathogenicity: strains with Arg or Lys at that position kill adult mice after intracerebral inoculation, whereas strains with other amino acids cause non-lethal infection. Based on those findings, attenuated rabies virus strains have been established and used for oral vaccines mainly for wild animals. However, considering the possibility of back-mutation to the virulent phenotype, a strain that is attenuated by multiple mutations not only in the G protein but also in other viral proteins would be more appropriate as a safe live vaccine. We previously demonstrated that the fixed rabies virus Ni-CE strain, which causes only transient body weight loss in adult mice after intracerebral inoculation, is mainly attenuated by mutations in the N, P and M proteins, while this strain has virulent-type Arg at position 333 in the G protein. In this study, to obtain a live vaccine strain that is attenuated by multiple mutations, we generated Ni-CE mutant, Ni-CE(G333Glu) strain, which has an Arg-to-Glu mutation at position 333 in the G protein, and examined its pathogenicity and immunogenicity. We found that, in contrast to Ni-CE strain, Ni-CE(G333Glu) strain did not cause transient body weight loss in adult mice after intracerebral inoculation. The attenuated phenotype of Ni-CE(G333Glu) strain did not change even after 10 serial intracerebral passages in suckling mice. We also demonstrated that inoculation of Ni-CE(G333Glu) strain induced virus-neutralizing antibody in immunized mice and protected the mice from lethal challenge. These results indicate that Ni-CE(G333Glu) strain is a promising candidate for development of a live rabies vaccine with a high safety level.

A single immunization with recombinant rabies virus (ERAG3G) confers complete protection against rabies in mice

Purpose New alternative bait rabies vaccines applicable to pet dogs and wild animals are needed to eradicate rabies in Korea. In this study, recombinant rabies virus, ERAG3G strain was constructed using reverse genetic system and the safety, efficacy and immunogenicity of the ERAG3G strain was evaluated in mice and dogs. Materials and Methods Using the full-length genome mutated amino acid at position 333 of glycoprotein of rabies virus (RABV) and helper plasmids, the ERAG3G strain was rescued in BHK/T7-9 cells successfully. Mice were inoculated with the ERAG3G strain for safety and efficacy. Safety and immunogenicity of the dog inoculated with the ERAG3G strain (1 mL, 108.0 FAID50/mL) via intramuscular route was evaluated for 28 days after inoculation. Results The ERAG3G strain rescued by reverse genetic system was propagated well in the mouse neuroblastoma cells revealing titer of 108.5 FAID50/mL and was not pathogenic to 4- or 6-week-old mice that received by intramuscular or intracranical route. Immunization with the ERAG3G strain conferred complete protection from lethal RABV in mice. Dogs inoculated with the vaccine candidate via intramuscular route showed high neutralizing antibody titer ranging from 2.62 to 23.9 IU/mL at 28 days postinoculation. Conclusion Our findings suggest that the ERAG3G strain plays an important role in inducing protective efficacy in mice and causes to arise anti-rabies neutralizing antibody in dogs.