Synthesis of tacaribe viral proteins

Immunological identification of Tacaribe virus proteins

Tacaribe virus (TV), an arenavirus, is an enveloped virus with genetic information encoded in two segments of single-stranded RNA. The completed sequence of TV led to the identification of four open reading frames (ORF). In order to establish a direct link between ORFs in the sequence of TV and proteins present in virus particles and virus-infected cells, segments of the molecularly cloned TV genome were engineered so as to be expressed in Escherichia coli to produce fusion proteins that were used to raise antisera. The antisera were in turn employed to identify the TV gene products. Serum to the putative nucleocapsid (N) protein reacted with a 68-kDa protein, both in TV particles and in the infected cells. Sera raised to the glycoprotein precursor (GPC) immunoprecipitated two proteins of 68 and 70 kDa from infected cell lysates. Analysis of GPC synthesis in the presence of tunicamycin revealed that the unglycosylated GPC appeared as two polypeptides of 43 and 46 kDa. The putative RNA polymerase gene product (L) was detected as a approximately 240-kDa protein. Serum to the small zinc-binding domain protein (p11-Z) recognized a protein of approximately 11kDa. Immunological evidence is presented that in addition to N and L, two glycoproteins (GP1 and GP2) and p11-Z are structural components of Tacaribe virions.

Resistance of mice vaccinated with rabies virus internal structural proteins to lethal infection

Mice were vaccinated with recombinant vaccinia virus (rVac) expressing the glycoprotein (G), nucleoprotein (N), phosphoprotein (NS) or matrix protein (M) of rabies virus and their resistance to peripheral lethal infection with street rabies virus was examined. Mice vaccinated with rVac-G or rVac-N developed strong antibody responses to the corresponding proteins and essentially all mice survived challenge infection. Mice vaccinated with rVac-NS or rVac-M developed only a slight antibody response, however, a significant protection (59%) was observed in the rVac-NS-vaccinated mice, whereas rVac-M-vaccinated mice were not protected. No anti-G antibodies were detected in the sera of mice which has been vaccinated with rVac-N or rVac-NS and survived challenge infection. Passive transfer of anti-N monoclonal antibodies (MAbs) recognizing an epitope located on amino acids 1-224 of the protein prior to challenge resulted in significant protection, although the protection was not complete even with a high amount of antibodies. In contrast, none of the mice given MAbs recognizing an epitope of amino acids 247-415 or F(ab')2 fragments from a protective MAb IgG were protected. Administration of anti-CD 8 MAb to rVac-N-vaccinated mice showed no significant effect on protection. Our observations suggest that a considerable part of the protection achieved by the vaccination with rVac-N can be ascribed to the intact anti-N antibodies recognizing an epitope located on amino acids 1-224 of the protein.

Mapping of the antigenic determinants recognized by monoclonal antibodies against the M2 protein of rabies virus

Twenty-one hybridomas producing monoclonal antibodies (moAbs) against the M2 protein of the Nishigahara (RECH) strain of rabies virus were prepared using the SDS-polyacrylamide gel-purified M2 protein as the immunogen. All moAbs reacted with the protein after Western blotting of rabies virus. By combinations of competitive binding assays, examination of the reactivity of moAbs to the cells infected with parent RCEH and two other strains, CVS and HEP-Flury, and immunoprecipitation with in vitro translation products derived from full-length and truncated cDNAs of the M2 gene, these moAbs could be classified into seven epitope groups. Of these, 20 moAbs belonging to six epitope groups were suggested to recognize an antigenic determinant in the amino-terminal region, from the 1st to the 72nd amino acid of the protein (8 moAbs from two groups directed to amino acids 1 to 72; 2 moAbs from a group directed to amino acids 9 to 72; 5 moAbs from a group directed to amino acids 17-72; 5 moAbs from two groups directed to amino acids 32 to 72). The antigenic determinant recognized by the remaining 1 moAb was shown to be located in the amino acid region from 50 to 171. These moAbs should be useful for further studies on the biological functions of the M2 protein of rabies virus.

Protection of mice against Sendai virus pneumonia by non-neutralizing anti-F monoclonal antibodies

Nine monoclonal antibodies (MAbs) directed to F protein of Sendai virus were obtained and characterized for their protective ability against Sendai virus infection in mice. None of the MAbs showed hemagglutination-inhibition (HI), hemolysis-inhibition (HLI), or neutralization (NT) activities in vitro when assayed by standard methods. Some of the MAbs, however, showed complement-requiring NT (C-NT) and complement-requiring hemolysis (C-HL) activities when assayed in the presence of complement. Passive immunization experiments revealed that the MAbs with higher C-NT and C-HL activities showed protective activity against Sendai virus pneumonia in mice, and that some MAbs with IgG1 isotype having neither C-NT nor C-HL activity also showed the protective activity. Digestion of the MAbs with pepsin which split immunoglobulin molecules into F(ab')2 and Fc fragments greatly suppressed the protective activity. These results suggest that not only complement-mediated immunological responses such as immune virolysis but also antibody-dependent cellular cytotoxicity (ADCC) and/or immune phagocytosis, in which complement system is not necessarily involved, play an important role in the protection of mice from Sendai virus infection.

Nontemplated bases at the 5' ends of Tacaribe virus mRNAs

Centrifugation of Tacaribe arenavirus-infected cell extracts on CsCl density gradients was used to separate genomes and antigenomes, which band at 1.31 g/ml as nucleocapsids, from mRNAs which pellet. Primer extensions on the banded RNAs showed that the 5' ends of the genomes and antigenomes were unique, whereas primer extensions on the mRNAs showed that their 5' ends were heterogenous in length, extending 0-4 bases beyond the 3' ends of the templates for their synthesis. This suggests that arenavirus mRNAs may initiate by a cap-snatching mechanism, somewhat similar to influenza viruses and bunyaviruses. We also found an extra G residue at the 5' end of the genome RNA, which was not predicted according to current models. This is now the third time that the unexpected G residue has been found at the 5' end of arenavirus genomes.

Nucleotide sequence of the Lassa virus (Josiah strain) S genome RNA and amino acid sequence comparison of the N and GPC proteins to other arenaviruses

The complete nucleotide sequence of the S genome RNA of the Josiah strain of Lassa virus was determined from cloned cDNA. The S RNA is 3402 nucleotides long with a calculated molecular weight of 1.09 x 10(6) Da. The nucleotide base composition is 26.84% adenine, 21.40% guanine, 22.75% cytosine, and 29.01% uridine. The 5' and 3' terminal nucleotide sequences are conserved and complimentary for 19 nucleotides, the nucleoprotein and glycoprotein genes are arranged in ambisense coding strategy, and the intergenic region contains an inverted complimentary sequence, as do all other arenavirus S RNAs characterized to date. Amino acid sequence comparisons between the nucleoproteins and glycoproteins of the Josiah and Nigerian (N sequences only) strains of Lassa virus, the WE and ARM strains of lymphocytic choriomeningitis virus (LCMV), Tacaribe, and Pichinde viruses are presented. These findings reveal that the G2 envelope glycoprotein is more conserved among different arenaviruses than the internal nucleoprotein.

Effect of actinomycin D on arenavirus growth and estimation of the generation time for a virus particle

In an attempt to define the involvement of host transcription in arenavirus growth, a study was made of the effect of actinomycin D (AMD) on the yields of infectious Pichinde, Tacaribe and Junin viruses. The drug was added either immediately after virus adsorption or later after infection, at the stationary phase of virus growth. The time of exposure of the infected cells to the inhibitor was so chosen that the generation and release of virus into the medium took place in the presence of AMD. A double label technique was used to estimate the generation time of an arenavirus particle. This was found to be 6 h or less for all of the arenaviruses examined. The results indicated that treatment of the host cells with AMD, either immediately after virus adsorption or later after infection, does not affect the yield of infectious Pichinde, Tacaribe or Junin viruses, thus implying that continuous host transcription is not required for the replication cycle of these arenaviruses.

Detection of antibody to M protein of measles virus in patients with subacute sclerosing panencephalitis: a comparative study on immunoprecipitation

Consistent results have not been obtained yet on the presence of antibody to the M protein of measles virus in the sera of patients with subacute sclerosing panencephalitis (SSPE). We performed a comparative study on various immunoprecipitation systems which appeared in the literature and found that the difference in the composition of the solubilizing buffer produced a large variety of results on the immunoprecipitation. [35S]Methionine-labeled Vero cells infected with the Edmonston strain of measles virus were solubilized by 10 different buffers and reacted with hyperimmune rabbit serum to whole virus, monospecific antisera to H, NP, and M proteins of the virus, normal adults' sera, and the sera from 16 SSPE patients. The immune complex was absorbed by protein A and both solubilization and precipitation rates were compared with each viral protein. Although viral proteins were solubilized by all buffers, the solubilization rate varied considerably. M protein was solubilized and was not coprecipitated nonspecifically with any of the other viral proteins. Purified protein A conjugated to Sepharose was preferable to Staphylococcus aureus for absorption of the immune complex since the latter absorbed both viral and host proteins nonspecifically. The precipitation rates of the viral proteins also varied according to the buffers. Better solubilization of the viral proteins seemed to reduce their rate of precipitation for which the presence of SDS may be responsible, and the presence of the protease inhibitors may also affect the results of immunoprecipitation. Detection of M protein in the immunoprecipitates was largely influenced by the kind of buffer used: some buffers could detect it clearly, but others could not defect it at all. Among the solubilizing buffers tested, Saleh's buffer (Virology 93: 369-376 (1979)),, which contains 0.5% DOC and 0.5% Triton X-100, was most reliable for detection of the anti-M antibody in the rabbit serum, because it showed a high solubilization and high precipitation rates of viral proteins without nonspecific absorption by protein A or coprecipitation of M proteins with any of the other proteins. Using this buffer, we could definitely detect M proteins in the immunoprecipitates from the sera of all six healthy adults and 15 out of 16 patients with SSPE. It was found, however, that the amount of M proteins in SSPE patients was lower than that in healthy adults and varied considerably.

Synthesis of Tacaribe virus polypeptides in an in vitro coupled transcription and translation system

We have analyzed polypeptides synthesized in a coupled in vitro transcription and translation system in response to detergent-disrupted Tacaribe virus. Analysis of the major Tacaribe virus-specified product by two-dimensional polyacrylamide gel electrophoresis indicated that it had an isoelectric point similar to that of the Tacaribe nucleocapsid polypeptide N; however, the in vitro product had an approximate mol. wt. of 73 000, compared to a mol. wt. of 68 000 for the N protein. The 73 000 dalton product was found to yield proteolytic cleavage products with similar electrophoretic mobilities to those obtained from the virion P and N proteins. These results, as well as pulse-chase experiments in Tacaribe virus-infected cells, suggest that a 73 000 dalton polypeptide may be processed to yield the N polypeptide. The polypeptides synthesized in the coupled system depended on the amount and type of virus added; addition of purified Shark River (SR) virus, a member of the Patois group of bunyaviruses, resulted in synthesis of a polypeptide of mol. wt. 22 000 which corresponds to the SR nucleocapsid protein.

Machupo virus polypeptides: identification by immunoprecipitation

The most abundant protein in purified Machupo virions (Corvallo strain) labelled with 14C-Protein hydrolysate is a 64 K polypeptide which is associated with virion RNAs. Another structural polypeptide, 37 K, solubilized by nonionic detergent seems to be a major surface glycoprotein. In addition to this, a 78 K polypeptide and a minor 50 K polypeptide have been detected. In Machupo virus infected cells three virus-specific polypeptides similar in size to those described for structural polypeptides were immunoprecipitated with anti-Machupo virus serum. The most abundant virus-specific polypeptide was nonglycosylated (64 K, NP), and the others were glycosylated polypeptides (78 K and 37 K). The synthesis of NP and 78 K polypeptides was recognized at the beginning of a log phase of virus replication. Pulse-chase experiments as well as experiments with an arginine analogue, canavanine (to block proteolytic processing) suggest that 78 K is a precursor for structural glycoproteins of Machupo virions.

Protection of mice from wild-type Sendai virus infection by a trypsin-resistant mutant, TR-2

A trypsin-resistant mutant of Sendai virus, TR-2, which could be activated by chymotrypsin but not by trypsin or the protease present in mouse lung, was inoculated intranasally into mice after being activated in vitro. TR-2 hardly brought about clinical illness or lung lesions in mice; the protease present in the lung could not activate the progeny virus, and the infection terminated after one-step replication. Nevertheless, the immunoglobulin A antibody against wild-type Sendai virus was produced in the respiratory tracts as well as the serum immunoglobulin G antibody, and the mice were protected from the challenge of the wild-type Sendai virus. On the basis of these results, TR-2 may provide a new model of live vaccine for paramyxoviruses; its availability as a live vaccine is also discussed.

Analysis of polypeptides in Tacaribe virus-infected cells

Two virus-induced polypeptides designated p79 (mol wt, 79,000) and p105 (mol wt, 105,000) in BHK21 or Vero cells infected with Tacaribe (Tac) virus have been identified. Both polypeptides were found in immune precipitates with antiserum to Tac virus, suggesting that they are virus specific. Two-dimensional gel analysis of Tac virus-infected Vero cell extracts indicated that p79 and p105 were acidic proteins which did not comigrate with any polypeptides from uninfected cells. Neither of the polypeptides was found to be phosphorylated under conditions in which phosphorylation of the N (nucleocapsid) protein was detected. Comparison of one-dimensional peptide maps of the p79 polypeptide and the nucleoprotein indicated that they are unrelated in primary sequences.