Toshio Kinjo

Linear and Conformation‐Dependent Antigenic Sites on the Nucleoprotein of Rabies Virus

A set of 29 monoclonal antibodies (MAbs) specific for the rabies virus nucleoprotein (N protein) was prepared and used to analyze the topography of antigenic sites. At least four partially overlapping antigenic sites were delineated on the N protein of rabies virus by competitive binding assays. Indirect immunofluorescent antibody tests using MAbs with a series of rabies and rabies‐related viruses showed that epitopes shared by various fixed and street strains of rabies virus were mainly localized at antigenic sites II and III, while epitopes representing the genus‐specific antigen of Lyssavirus were widely presented at sites I, III and IV. All but one of seven MAbs specific for antigenic sites I, IV and bridge site (I and II) reacted with the antigen that had been denatured by sodium dodecyl sulfate or 2‐mercaptoethanol, as well as with the denatured N protein in Western blotting assays. However, none of the MAbs against antigenic sites II and III reacted with the denatured antigen. These data indicate that antigenic sites I and IV, and sites II and III on the N protein of rabies virus are composed of linear and conformation‐dependent epitopes, respectively.

Mapping of epitopes and structural analysis of antigenic sites in the nucleoprotein of rabies virus

Linear epitopes on the rabies virus nucleoprotein (N) recognized by six MAbs raised against antigenic sites I (MAbs 6-4, 12-2 and 13-27) and IV (MAbs 6-9, 7-12 and 8-1) were investigated. Based on our previous studies on sites I and IV, 24 consecutively overlapping octapeptides and N- and C-terminal-deleted mutant N proteins were prepared. Results showed that all three site I epitopes studied and two site IV epitopes (for MAbs 8-1 and 6-9) mapped to aa 358-367, and that the other site IV epitope of MAb 7-12 mapped to aa 375-383. Tests using chimeric and truncated proteins showed that MAb 8-1 also requires the N-terminal sequence of the N protein to recognize its binding region more efficiently. Immunofluorescence studies demonstrated that all three site I-specific MAbs and one site IV-specific MAb (7-12) stained the N antigen that was diffusely distributed in the whole cytoplasm; the other two site IV-specific MAbs (6-9 and 8-1) detected only the N antigen in the cytoplasmic inclusion bodies (CIB). An antigenic site II-specific MAb (6-17) also detected CIB-associated N antigen alone. Furthermore, the level of diffuse N antigens decreased after treatment of infected cells with cycloheximide. These results suggest that epitopes at site I are expressed on the immature form of the N protein, but epitope structures of site IV MAbs 6-9 and 8-1 are created and/or exposed only after maturation of the N protein.

Serological Evidence of Coxiella burnetii Infection in Wild Animals in Japan

One hundred and thirty-four (26%) of 511 sera from 11 wild animal species in eight prefectures in Japan had antibody titers to Coxiella burnetii by the enzyme-linked immunosorbent assay. High prevalences were observed in Japanese black bears (Ursus thibetanus) (78%), Hokkaido deer (Cervus nippon yesoensis) (69%), Japanese hares (Lepus brachyurus) (63%), Japanese deer (Cervus nippon centralis) (56%), and to some extent in Japanese monkeys (Macaca fuscata) (28%). A low prevalence (13%) was observed in nutrias (Myocastor coypus). Japanese serows (Capricornis crispus), wild rats (Muroides sp.), raccoon dogs (Nyctereutes procyonoides viverrinus), wild pigs (Sus scrofa leucomystax), and masked palm civets (Paguma larvata) had no detectable antibodies to C. burnetii. Thus, six of 11 wild animal species in Japan were exposed to C. burnetii. Based on the high prevalences in some species, they may be a potential source of infection to both domestic animal and human populations.

A virus-neutralizing epitope on the glycoprotein of rabies virus that contains Trp251 is a linear epitope

We have established a hybridoma producing monoclonal antibody (MAb) against a linear epitope of glycoprotein (G protein) of the RC-HL strain of rabies virus. This MAb15-13 showed almost the same neutralizing activity to all of five rabies fixed strains, including RC-HL, and reacted to the denatured G protein in western blot analysis. To characterize and map this linear epitope, an antigenic variant NR15-13 was selected from RC-HL strain in the presence of neutralizing MAb15-13. The variant reacted with MAb15-13 in an immunofluorescent antibody test but was not neutralized by the antibody and the antibody did not bind to the variant G protein in a Western blot analysis. The variant NR15-13 had an amino acid substitution at position 251 of the G protein, where tryptophan of the parental RC-HL strain was replaced by arginine. Site-directed mutagenesis analysis using the expression system in simian COS7 cells revealed that a single amino acid substitution at 251-tryptophan by arginine on the G protein of the parental RC-HL strain abolished the antigenicity of the epitope for MAb15-13 in western blot analysis, and the replacement of 251-arginine by tryptophan recovered the activity. These results strongly suggest that tryptophan at position 251 on the G protein is essential for construction of the linear epitope against MAb15-13.

Antigenic and Functional Analyses of Glycoprotein of Rabies Virus Using Monoclonal Antibodies

Thirty‐five monoclonal antibodies (MAbs) against glycoprotein (G protein) of the RC‐HL strain of the rabies virus have been established. Using these MAbs, two antigenic sites (I and II) were delineated on the G protein of the RC‐HL strain in a competitive binding assay. Of these, 34 MAbs recognized the epitopes on site IL Site II was further categorized into 10 subsites according to their patterns in a competitive binding assay. Each site II‐specific MAb showed 5 to 23 nonreciprocal competitions. The reactivities of 35 MAbs to rabies and rabies‐related viruses in an indirect immunofluorescent antibody test showed that six MAbs in group A binded to rabies and rabies‐related viruses and eight MAbs in group E reacted only with rabies viruses, considering that the former represent the genus‐specific of Lyssavirus and the latter are rabies virus‐specific. From biological assays, 28 of the 35 MAbs showed neutralization activity, 31 showed hemagglutination inhibition (HI) activity, and 18 showed immunolysis (IL) activity. The MAbs recognizing neutralization epitopes fell into at least three groups: those exhibiting both HI and IL activity, those showing only HI activity, and those showing neither HI nor IL activity. All IL epitopes overlap with HA epitopes. Five of the nine MAbs which reacted with the antigen treated by sodium dodecyl sulfate in ELISA were not reduced, or reduced only slightly, in the titer. None of the MAbs reacted with 2‐mercaptoethanol‐treated antigen. Only one MAb that recognized site I reacted with the denatured G protein in a Western blotting assay, indicating that its epitope is linear. These results suggest that almost all of the epitopes on the G protein of the rabies virus are conformation‐dependent and the G protein forms a complicated antigenic structure.

Expression of the nucleoprotein of rabies virus in Escherichia coli and mapping of antigenic sites.

SummaryInvestigations were performed to delineate the antigenic sites I and IV of rabies virus nucleoprotein (N), the former of which is well conserved among the rabies and rabies-related viruses. The N cDNA of the RC-HL strain was inserted into an expression vector pET3a, with which theE. coli BL21(DE3) was transformed. Upon induction with isopropyl-1-thio-ß-D-galactoside, the transformants produced a protein with a size (56k-Da) almost identical to that of the authentic N protein. The protein also reacted with a panel of our N protein-specific monoclonal antibodies (N-MAbs) including the antibodies against the antigenic sites I and IV. By using the cDNA, various deletion mutants were generated and expressed inE. coli to examine the reactivity of mutant proteins with N-MAbs by Western blot analysis. Deletion of the C-terminal 67 amino acid residues did not abolish their reactivity with any of the N-MAbs specific for the sites I and IV. When 91 residues or more were deleted from the C-terminus, however, the protein lost the reactivity, indicating that the antigenic sites I and IV are mapped to a small region which is comprised of at most 24 amino acid residues from positions 360 to 383. Comparison of the 24-amino acid sequence with the corresponding region of N protein of several other Lyssavirus strains suggests that the antigenic site I is mapped to positions 360 to 369.

Nucleotide sequence of the nucleoprotein gene of the RC.HL strain of rabies virus, a seed strain used for animal vaccine production in Japan.

By using a phage vector (lambda ZAP II) and the mRNA extracted from IMR-32 cells infected with the RC·HL strain of rabies virus, we constructed a cDNA library from which four nucleoprotein (N)-specific cDNA clones were obtained by Southern blot hybridization. These clones contained a cDNA insert of about 1.4 kb, in which the longest open reading frame was the same length as that reported for the N cDNA of three fixed strains, CVS, PV, and SAD B19. When the nucleotide and deduced amino acid sequences were compared between the RC·HL and the three strains, homology was within the range of 91.5–91.8% and 95.1–96.0%, respectively. Of 183 nucleotides of the RC·HL N-cDNA that were not identical to that of the corresponding site of at least one of the three strains, 41 were shared with the CVS strain, whereas only three were shared with either of the other two strains. In the amino acid sequence, we found 29 residues that were not shared in common with all of the four strains, 11 of which were the substitutions with radically different amino acids that might cause conformational changes of the protein, and, in addition, five of which were located in the region close to the C terminus. The number of such amino acid substitutions between the RC·HL and CVS strains was smaller than that of the other three strains. These results are not inconsistent with the presumption that the RC·HL and CVS strains originated from the same laboratory strain of the Pasteur viruses.

A Unique Mutation of Glycoprotein Gene of the Attenuated RC-HL Strain of Rabies Virus, a Seed Virus Used for Production of Animal Vaccine in Japan

Although the RC‐HL strain of rabies virus is avirulent in adult mice, the amino acid at position 333 of its G protein is arginine, which is thought to be necessary for virulence in adult mice upon intracerebral inoculation of the virus. This result suggests that besides arginine at position 333, some other positions of G protein might also be involved in determining the virulence of rabies virus.

Antigenic analysis of avian rotavirus VP6 using monoclonal antibodies

SummaryMonoclonal antibodies (MAbs) were prepared to analyze antigens on the major inner capsid protein, VP 6 of avian group A rotavirus. Based on the results of a competitive binding assay using 15 MAbs directed against VP 6 of the PO-13 rotavirus strain, isolated from a pigeon in Japan, it was found that VP 6 of avian rotavirus possesses at least four spatially distinct antigenic sites. Two antigenic sites (I and II) were topologically distinct from the other two (III and IV), which were in close proximity. From the reaction of MAbs in indirect immunofluorescent antibody tests to a series of known rotaviruses, epitopes representing common antigens of all group A rotavirus including avian rotavirus were localized in sites II and III. One epitope in site IV appeared to have a subgroup antigenic specificity that reacted only with rotaviruses belonging to subgroup I. Interestingly, avian rotaviruses isolated from turkeys and chickens in Northern Ireland also reacted only with these subgroup I specific MAbs, but not with subgroup II specific MAb. This indicates that avian rotavirus has subgroup I specific antigen, which is antigenically similar to that of other mammalian rotavirus strains.

Characterization of Monoclonal Antibodies against Four Structural Proteins of Rinderpest Virus

Twenty-four monoclonal antibodies (MAbs) against rinderpest virus (RPV) were established and characterized by several serological tests. Of the 24 MAbs. 10 recognized the nucleoprotein (NP), six the phosphoprotein (P), four the haemagglutinin (H), and two the fusion (F) protein as determined by radioimmunoprecipitation assay. The specificities of the remaining two MAbs could not be determined. From a competitive binding assay using MAbs against each structural protein, at least five, four and two separate antigenic sites were identified on the NP, P and H proteins, respectively. MAbs against the H protein neutralized the infectivity of the virus, but those against the F protein were only neutralizing in the presence of guinea-pig complement. The reactivities of each of the MAbs for other strains of morbillivirus were tested using an indirect immunofluorescent antibody assay. The MAbs against four out five antigenic sites on the NP showed cross-reactivity amongst all the strains of morbillivirus tested whereas the fifth antibody reacted only with RPV. Of the antibodies specific for the P protein, the antibody against one site was cross-reactive with all the strains of RPV, measles virus (MV) and canine distemper virus (CDV), the antibody against another site was reactive with RPV and MV but not with CDV, and the antibodies against the other two sites were specific for RPV.