Replication of measles virus in Vero cells at elevated temperatures

In one-step growth experiment of measles virus (MV) in Vero cells at 39 C, the appearance of MV infectivity was delayed for 24 hr and the maximum titer was reduced by approximately 1,000-fold, when compared with those at 35 C. MV infectivity was thermolabile at the high temperature. Penetration was rather enhanced at 39 C. By Northern blot hybridization, viral RNAs including 50S genome-sized RNA and mRNAs were first detectable 24 hr post-infection (PI) at 35 C and 36 hr PI at 39 C, respectively. Rapid degradation of viral mRNAs was not observed in the infected cells at 39 C. The synthesis of N, F, and M proteins was relatively reduced at the high temperature and appearance of the other viral protein was delayed, in agreement with the time course of viral RNA synthesis. All these data suggest that less efficient synthesis of viral RNA, restriction of synthesis of N, F, and M proteins at translational level and thermolability of infectivity are all involved in the suppressed MV production in Vero cells at 39 C.     

Selective translation initiation on bicistronic simian virus 40 late mRNA.

We described previously a simian virus 40 (SV40) mutant, pSVAdL, that was defective in synthesis of the late viral protein VP1. This mutant, which contains a 100-base-pair fragment of adenovirus DNA encompassing the major late promoter inserted in the SV40 late promoter region (SV40 nucleotide 294), efficiently synthesizes agnoprotein, a protein encoded by the leader region of the same mRNA that encodes VP1. When the agnoprotein AUG initiation codon in pSVAdL was mutated to UUG, agnoprotein synthesis was abolished, and VP1 synthesis was elevated to wild-type levels. Because levels of late mRNA synthesis were not affected by this mutation, these results support a scanning model of translation initiation and suggest that internal translational reinitiation does not occur efficiently in this situation.     

Selective inhibition of cell-free translation by oligonucleotides targeted to a mRNA hairpin structure.

Using an in vitro selection approach we have previously isolated oligodeoxy aptamers that can bind to a DNA hairpin structure without disrupting the double-stranded stem. We report here that these oligomers can bind to the RNA version of this hairpin, mostly through pairing with a designed 6 nt anchor. The part of the aptamer selected against the DNA hairpin did not increase stability of the RNA-aptamer complex. However, it contributed to the binding site for Escherichia coli RNase H, leading to very efficient cleavage of the target RNA. In addition, a 2'- O -methyloligoribonucleotide analogue of one selected sequence selectively blocked in vitro translation of luciferase in wheat germ extract by binding to the hairpin region inserted upstream of the initiation codon of the reporter gene. Therefore, non-complementary oligomers can exhibit antisense properties following hybridization with the target RNA. Our study also suggests that in vitro selection might provide a means to extend the repertoire of sequences that can be targetted by antisense oligonucleotides to structured RNA motifs of biological importance.     

Essential elements in the coding region of mRNA for translation of ColE2 Rep protein

Translation initiation of mRNA encoding the plasmid-specified initiator protein (Rep) required for initiation of the ColE2 plasmid DNA replication is fairly efficient in Escherichia coli despite the absence of a canonical Shine-Dalgarno sequence. Although a GA cluster sequence exists upstream the initiation codon, its activity as the SD sequence has been shown to be very inefficient. Deletion analyses have shown that there are sequences important for the Rep translation in the regions upstream the GA cluster sequence and downstream the initiation codon. To further define regions important for translation of the Rep mRNA, a set of the ColE2 rep genes bearing single-base substitution mutations in the coding region near the initiation codon was generated and their translation activities examined. We showed that translation of the Rep mRNA was reduced by some of these mutations in a region ranging at least 70 nucleotides from the initiation codon in the coding region, indicating the presence of translation enhancer(s) outside the translation initiation region which is covered by the ribosome bound to the initiation codon. Some of them seem to be essential and specific for translation of the ColE2 Rep mRNA due to the absence of a canonical SD sequence.     

Cell-free translation of influenza virus mRNA.

Cytoplasmic poly (A)-rich RNA extracted from fowl plague virus-infected cells was found to program efficiently the translation of two major peptides in the wheat germ cell-free system. These peptides have the same electrophoretic mobility, on polyacrylamide gels, as the two major virion proteins M and NP. [35S] methionine tryptic peptide analysis by one-dimensionalthin-layer ionophoresis and finger printing by two-dimensional thin-layer ionophoresis and chromatography show a high degree of similarity between the two in vitro products and the authentic viral proteins M and NP. Although virion RNA is devoid of any poly (A) sequence, it is confirmed here that the viral complementary cytoplasmic RNA contains poly (A) stretches of varying lengths. Intact purified virion was found to promote the synthesis of very low amounts of the same NP and M proteins in this cell-free system. Quantitative aspects of data would indicate that this is due to minute amounts of complementary viral RNA associated with the virion or with the virion RNA itself. In conclusion, it is shown diectly by cell-free translation of authentic viral products that the influenza virion is "negative stranded" (Baltimore, 1971), at least for its two major structural proteins.     

Isolation and translation of mRNA coding for the variant surface antigens of Paramecium.

In the poly(A)+RNA isolated from the ciliate Paramecium primaurelia is found a discrete and abundant mRNA species of high molecular weight (corresponding to about 9,000 nucleotides). This mRNA species has size and abundance characteristics that identify it tentatively as the message coding for the variant cell-surface antigens. After microinjection of the high molecular weight mRNA into amphibian oocytes, polypeptides are synthesized that are immunoprecipitated specifically with antibodies directed against the homologous Paramecium antigen. On collecting the culture medium of oocytes microinjected with Paramecium mRNA, newly-synthesized complete antigen molecules (Mr approximately 300,000) can be recovered by immunoprecipitation.     

Respiratory syncytial virus mRNA coding assignments.

The polypeptide coding assignments for six of the respiratory syncytial virus-specific mRNAs were determined by translation of the individual mRNAs in vitro. The coding assignments of the RNAs are as follows. RNA band 1 is complex and can be separated into at least two components on the basis of electrophoretic mobility (molecular weights [MWs] approximately equal to 0.21 X 10(6) and 0.31 X 10(6), respectively) that code for three polypeptides of 9.5, 11, and 14 kilodaltons (K). RNA 2 (MW, 0.39 X 10(6)) codes for a 34K polypeptide; RNA 3 (MW, 0.40 X 10(6)) codes for a 26K polypeptide; RNA 4 (MW, 0.47 X 10(6)) codes for a 42K polypeptide; and RNA 5 (MW, 0.74 X 10(6)) codes for a 59K polypeptide. By limited-digest peptide mapping, the 34, 26, and 42K polypeptides synthesized in vitro appeared to be unique. Additionally, peptide mapping showed that the 34, 26, and 42K polypeptides synthesized in vitro were indistinguishable from their counterparts synthesized in infected cells. Thus, the 34, 26, and 42K polypeptides coded for by mRNAs 2, 3, and 4, respectively, were identified as the respiratory syncytial virus phosphoprotein (34K), matrix protein (26K), and nucleocapsid protein (42K), respectively. RNA 5 was shown to code for a 59K polypeptide. The 59K polypeptide synthesized in vitro did not comigrate with any polypeptide specific to infected cells, suggesting that it is a candidate for co- or post-translational modification.     

7-Methylguanosine-dependent inhibition of globin mRNA translation by methylglyoxal.

Studies on the inhibition of translation by methylglyoxal of capped and chemically decapped globin mRNAs in the rabbit reciculocyte system strongly suggest that it is cap-dependent. Concentrations of methylglyoxal (0.2 mM), which effected substantial inhibition (80%) of capped mRNA, were only slightly inhibitory (10%) to the decapped species. In addition, the inhibition was K+-dependent with maximal inhibition occurring at the K+ optimum for translation of the capped species, suggesting cap recognition is required for the effect. Results with endogenous mRNA further substantiate that initiation and not elongation is the site of action. These results are consistent with an inhibition due to a newly discovered, rapid reaction of methylglyoxal with the 7-methylguanosine of the cap structure.     

The regulatory VirA protein of Agrobacterium tumefaciens does not function at elevated temperatures.

Previous studies have shown that Agrobacterium tumefaciens causes tumors on plants only at temperatures below 32 degrees C, and virulence gene expression is specifically inhibited at temperatures above 32 degrees C. We show here that this effect persists even when the virA and virG loci are expressed under the control of a lac promoter whose activity is temperature independent. This finding suggests that one or more steps in the signal transduction process mediated by the VirA and VirG proteins are temperature sensitive. Both the autophosphorylation of VirA and the subsequent transfer of phosphate to VirG are shown to be sensitive to high temperatures (> 32 degrees C), and this correlates with the reduced vir gene expression observed at these temperatures. At temperatures of 32 degrees C and higher, the VirA molecule undergoes a reversible inactivation while the VirG molecule is not affected. vir gene induction is temperature sensitive in an acetosyringone-independent virA mutant background but not in a virG constitutive mutant which is virA and acetosyringone independent. These observations all support the notion that the VirA protein is responsible for the thermosensitivity of vir gene expression. However, an Agrobacterium strain containing a constitutive virG locus still cannot cause tumors on Kalanchoe plants at 32 degrees C. This strain induces normal-size tumors at temperatures up to 30 degrees C, whereas the wild-type Agrobacterium strain produces almost no tumors at 30 degrees C. These results suggest that at temperatures above 32 degrees C, the plant becomes more resistant to infection by A. tumefaciens and/or functions of some other vir gene products are lost in spite of their normal levels of expression.     

Mapping of the influenza virus genome. III. Identification of genes coding for nucleoprotein, membrane protein, and nonstructural protein.

In previous communications we reported that the eight RNA segments of influenza A/PR/8/34 (HON1) virus could be distinguished from corresponding segments of influenza A/Hong Kong/8/68 (H3N2) virus by migration on polyacrylamide-urea gels. Examination of the RNA patterns of the two parent viruses and recombinants derived from them in concert with serological identification of surface proteins and analysis of the other proteins on sodium dodecyl sulfate gradient gels permitted the identification of the genes coding for hemagglutinin, neuraminidase, and the P1, P2, and P3 proteins (Palese and Schulman, 1976; P. Palese et al., Virology, in press). In the present report we have extended these observations using similar techniques to examine other recombinants and have identified the genes coding for the remaining virus-specific moving RNA segment as 1) and segment 6 of Hong Kong virus coding for the respective nucleoproteins, and that segment 7 of both viruses codes for the membtane protein and RNA segment 8 codes for the nonstructural protein. This completes the mapping of the influenza A virus genome.     

Internal initiation of translation on the vesicular stomatitis virus phosphoprotein mRNA yields a second protein.

In vitro translation of a mixture of the vesicular stomatitis virus (VSV) polyadenylated mRNAs yielded a previously undetected protein with a molecular weight of approximately 7,000 (7K protein). Hybrid-arrested translation demonstrated that both the 7K protein and the VSV phosphoprotein (P protein) were encoded by the P protein message. Immunoprecipitation of the 7K protein with monoclonal antiserum directed against the P protein indicated that the two products were encoded in the same open reading frame. A protein of approximately the same size was immunoprecipitated from cytoplasmic extracts of VSV-infected cells by both the polyclonal and monoclonal antisera, and it is likely that it was a previously unrecognized viral gene product. Translational mapping of the P protein mRNA in vitro indicated that the 7K protein was encoded in the 3' one-third of the sequence. The synthesis of the 7K protein in vitro was unaffected by hybrid arrest conditions which blocked the 5' two-thirds of the mRNA and inhibited synthesis of the P protein. These results imply that the ribosomes bind and initiate translation internally on the P protein mRNA at a site located hundreds of nucleotides downstream from the capped 5' end.     

Conformational maturation of measles virus nucleocapsid protein.

We have obtained a polyclonal antiserum, N-BE, against the denatured, amino-terminal half of the measles virus (MV) nucleocapsid (N) protein and a monoclonal antibody (MAb), N46, which recognizes a conformation-dependent epitope in the same region. Amino acid residues 23 to 239 were required and sufficient for the formation of the conformational epitope. Using these antibodies, we show that the N protein of MV is synthesized as a relatively unfolded protein which first appears in the free-protein pool. This nascent N protein undergoes a conformational change into a more folded mature form. This change does not require the participation of other viral proteins or genomic RNA. The mature N protein does not accumulate in the free-protein pool but is quickly and selectively incorporated into the viral nucleocapsids. The mature N protein is a target for interaction with the phosphoprotein (P protein) of MV. This interaction interferes with the recognition of the N protein by the N46 MAb. This suggests that the association with the P protein may mask the binding site for the N46 MAb or that it induces a conformational change in the N protein.     

Human membrane cofactor protein (CD46) acts as a cellular receptor for measles virus.

A monoclonal antibody (MCI20.6) which inhibited measles virus (MV) binding to host cells was previously used to characterize a 57- to 67-kDa cell surface glycoprotein as a potential MV receptor. In the present work, this glycoprotein (gp57/67) was immunopurified, and N-terminal amino acid sequencing identified it as human membrane cofactor protein (CD46), a member of the regulators of complement activation gene cluster. Transfection of nonpermissive murine cells with a recombinant expression vector containing CD46 cDNA conferred three major properties expected of cells permissive to MV infection. First, expression of CD46 enabled MV to bind to murine cells. Second, the CD46-expressing murine cells were able to undergo cell-cell fusion when both MV hemagglutinin and MV fusion glycoproteins were expressed after infection with a vaccinia virus recombinant encoding both MV glycoproteins. Third, M12.CD46 murine B cells were able to support MV replication, as shown by production of infectious virus and by cell biosynthesis of viral hemagglutinin after metabolic labeling of infected cells with [35S]methionine. These results show that the human CD46 molecule serves as an MV receptor allowing virus-cell binding, fusion, and viral replication and open new perspectives in the study of MV pathogenesis.