Polyoma Virus DNA: Complete Nucleotide Sequence of the Gene Which Codes for Polyoma Virus Capsid Protein VP1 and Overlaps the VP2/VP3 Genes

The nucleotide sequence of part of the late region of the polyoma virus genome was determined. It contains coding information for the major capsid protein VP1 and the C-terminal region of the minor proteins VP2 and VP3. In the sequence with the same polarity as late mRNA's, all coding frames are blocked by termination codons in a region around 48 units on the physical map. This is the region where the N-terminus of VP1 and the C-termini of VP2 and VP3 have been located (T. Hunter and W. Gibson, J. Virol. 28:240-253, 1978; S. G. Siddell and A. E. Smith, J. Virol. 27:427-431, 1978; Smith et al., Cell 9:481-487, 1976). There are two long uninterrupted coding frames in the late region of polyoma virus DNA. One lies at the 5' end of the sequence and contains potential coding sequences for VP2 and VP3. The other contains 383 consecutive sense codons starting with the ATG at nucleotide position 1,218, extends from 47.5 to 25.8 units counterclockwise on the physical map, and is located where the VP1 gene has been mapped. The VP1 gene overlaps the genes for proteins VP2/VP3 by 32 nucleotides and uses a different coding frame. From the DNA sequence, the amino acid sequence of VP1 was predicted. The proposed VP1 sequence is in good agreement with other data, namely, with the partial N-terminal amino acid sequence and the total amino acid composition. The VP1 coding frame terminates with a TAA codon at 25.8 map units. This is followed by an AATAAA sequence, which may act as a processing signal for the viral late mRNA's. When both nucleotide and amino acid sequences are compared with their counterparts in the related simian virus 40, extensive homologies are found over the entire region of the two viral genomes. Maximum homology appears to occur in those regions which code for the C-termini of the VP1 proteins. The overlap region of VP1 with VP2/VP3 of polyoma virus is shorter by 90 nucleotides than is that of simian virus 40 and shows very limited homology with the simian virus 40 sequence. This leads to the suggestion that the overlap segments of both viruses have been freed from stringency imposed on drifting during evolution and that proteins VP2 and VP3 of polyoma virus may have been truncated by the appearance of a termination codon within the sequence.     

Polyoma virus complementary RNA directs the in vitro synthesis of capsid proteins VP1 and VP2.

Polyoma virus complementary RNA, synthesized in vitro by using highly purified Escherichia coli RNA polymerase and nondefective form I polyoma DNA, was translated in a wheat germ cell-free system. Polypeptides were synthesized that comigrated on sodium dodecyl sulfate-polyacrylamide gels with the polyoma capsid proteins VP1 and VP2, although most of the cell-free products were of smaller molecular weights. The VP1-size protein specifically immunoprecipitated with anti-polyoma virus serum, and upon digestion by trypsin yielded [35S]methionine-labeled tryptic peptides that co-chromatographed with the [3H]methionine-labeled tryptic peptides of virion-derived VP1 on both cation-exchange and anion-exchange resins. The VP2-size in vitro product contained all the virion VP2 methionine-labeled tryptic peptides, as shown by cation- and anion-exchange chromatography and two-dimensional fingerprinting on cellulose. We conclude that full-length polyoma VP1 and VP2 are synthesized in response to complementary RNA and consequently that the viral capsid proteins VP1, VP2, and VP3 are entirely virus coded.     

Characterization of the mRNA''s for the polyoma virus capsid proteins VP1, VP2, and VP3.

Polyadenylated cytoplasmic RNA from polyoma virus-infected cells can be translated in the wheat germ system to yield all there polyoma virus capsid proteins, VP1, VP2, and VP3. The translation products of RNA selected from total cytoplasmic RNA of infected cells by hybridization to polyoma virus DNA showed a high degree of enrichment for VP1, VP2, and VP3. The identity of the in vitro products with authentic virion proteins was established in two ways. First, tryptic peptide maps of the in vitro products were found to be essentially identical to those of their in vivo counterparts. Second, the mobilities of the in vitro products on two-dimensional gels were the same as those of viral proteins labeled in vivo. VP1, VP2, and vp3 were all labeled with [35S] formylmethionine when they were synthesized in the presence of [35S] formylmethionyl-tRNAfmet. We determined the sizes of the polyadenylated mRNA's for VP1, VP2, and VP3 by fractionation on gels. The sizes of the major mRNA species for the capsid proteins are as follows: VP2, 8.5 X 10(5) daltons; VP3, 7.4 X 10(5) daltons; and VP1, 4.6 X 10(5) daltons. We conclude that all three viral capsid proteins are synthesized independently in vitro, that all three viral capsid proteins are virally coded, and that each of the capsid proteins has a discrete mRNA.     

Nucleotides sequence of the genes for the simian virus 40 proteins VP2 and VP3.

We have determined the nucleotide sequence of the DNA of simian virus 40. The proceeding report (Dhar, R., Reddy, V.B., and Weissman, S.M. (1978) J. Biol. Chem. 253, 612-620) presents the sequence of a portion of the simian virus 40 DNA that overlaps the region encoding the 5' end of the minor structural protein VP2. We report here the sequence of the remainder of the genes for minor structural proteins VP2 and VP3. The results indicate that the mRNA for the two proteins is read in the same phase and the initiation site for VP3 lies within the structural gene of VP2. The codons of the COOH-terminal amino acids of VP2 and VP3 are read in a second phase as the codons of the NH2-terminal amino acids of VP1.     

Rubella virus 40S genome RNA specifies a 24S subgenomic mRNA that codes for a precursor to structural proteins.

We have analyzed the structure of the rubella virus genome RNA and the virus-specific RNA species synthesized in B-Vero cells infected with rubella virus. A single-stranded, capped, and polyadenylated RNA species sedimenting at 40S in a sucrose gradient was released from purified virions treated with sodium dodecyl sulfate. This RNA species migrated with an Mr of about 3.8 X 10(6) in an agarose gel after denaturation with glyoxal and dimethyl sulfoxide. Infected cells labeled with [3H]uridine in the presence of actinomycin D contained, in addition to the 40S RNA, a single-stranded polyadenylated 24S RNA species as shown by sucrose gradient analysis. In a Northern blot analysis, this RNA hybridized to a cDNA probe derived from the 3' portion of the genomic 40S RNA. In vitro translation of the 24S RNA species yielded a 110,000-dalton polypeptide, in addition to some smaller products which were immunoprecipitated with an antiserum prepared against the structural proteins E1, E2a, E2b, and C. Since the sum of the molecular weights of the nonglycosylated envelope proteins and the capsid protein has been estimated to be about 116,000 (C. Oker-Blom et al., J. Virol. 46:964-973, 1983), these results suggest that the 24S RNA species represents a subgenomic mRNA coding for a precursor (p110) to the structural proteins of rubella virus. Thus, the strategy of gene expression of rubella virus appears to be similar to that of the alphaviruses.     

Location of the sequences coding for capsid proteins VP1 and VP2 on polyoma virus DNA.

The 19S and 16S polyoma virus late mRNAs have been separated on sucrose-formamide density gradients and translated in vitro. The 16S RNA codes only for polyoma capsid protein VP1, while the 19S RNA codes in addition for capsid protein VP2. Since the 19S and 16S species have been previously mapped on the viral genome, these results allow us to deduce the location of the sequences coding for VP1 and VP2. Comparison of the chain lengths of the capsid proteins with the size of the viral mRNAs coding for them suggests that VP1 and VP2 are entirely virus-coded. Purified polyoma 19S RNA directs the synthesis of very little VP1 in vitro, although it contains all the sequences required to code for the protein. The initiation site for VP1 synthesis which is located at an internal position on the messenger is probably inactive either because it is inaccessible or because it lacks an adjacent "capped" 5' terminus. Similar inactive internal initiation sites have been reported for other eucarotic viral mRNAs (for example, Semliki forest virus, Brome mosaic virus, and tobacco mosaic virus), suggesting that while eucaryotic mRNAs may have more than one initiation site for protein synthesis, only those sites nearer the 5' terminus of the mRNA are active.     

The 3' end of Norwalk virus mRNA contains determinants that regulate the expression and stability of the viral capsid protein VP1: a novel function for the VP2 protein

Norwalk virus (NV) is the prototype strain of a group of noncultivable human caliciviruses responsible for epidemic outbreaks of acute gastroenteritis. The capsid protein VP1 is synthesized from a subgenomic RNA that contains two open reading frames (ORFs), ORF2 and ORF3, and the 3' untranslated region (UTR). ORF2 and ORF3 code for the capsid protein (VP1) and a small structural basic protein (VP2), respectively. We discovered that the yields of virus-like particles (VLPs) composed of VP1 are significantly reduced when this protein is expressed from ORF2 alone. To determine how the 3' terminus of the NV subgenomic RNA regulates VP1 expression, we compared VP1 expression levels by using recombinant baculovirus constructs containing different 3' elements. High VP1 levels were detected by using a recombinant baculovirus that contained ORF2, ORF3, and the 3'UTR (ORF2+3+3'UTR). In contrast, expression of VP1 from constructs that lacked the 3'UTR (ORF2+3), ORF3 (ORF2+3'UTR), or both (ORF2 alone) was highly reduced. Elimination of VP2 synthesis from the subgenomic RNA by mutation resulted in VP1 levels similar to those obtained with the ORF2 construct alone, suggesting a cis role for VP2 in upregulation of VP1 expression levels. Comparisons of the kinetics of RNA and capsid protein expression levels by using constructs with or without ORF3 or the 3'UTR revealed that the 3'UTR increased the levels of VP1 RNA, whereas the presence of VP2 resulted in increased levels of VP1. Furthermore, VP2 increased VP1 stability and protected VP1 from disassembly and protease degradation. The increase in VP1 expression levels caused by the presence of VP2 in cis was also observed in mammalian cells.     

Respiratory syncytial virus fusion glycoprotein: nucleotide sequence of mRNA, identification of cleavage activation site and amino acid sequence of N-terminus of F1 subunit.

The amino acid sequence of respiratory syncytial virus fusion protein (Fo) was deduced from the sequence of a partial cDNA clone of mRNA and from the 5' mRNA sequence obtained by primer extension and dideoxysequencing. The encoded protein of 574 amino acids is extremely hydrophobic and has a molecular weight of 63371 daltons. The site of proteolytic cleavage within this protein was accurately mapped by determining a partial amino acid sequence of the N-terminus of the larger subunit (F1) purified by radioimmunoprecipitation using monoclonal antibodies. Alignment of the N-terminus of the F1 subunit within the deduced amino acid sequence of Fo permitted us to identify a sequence of lys-lys-arg-lys-arg-arg at the C-terminus of the smaller N-terminal F2 subunit that appears to represent the cleavage/activation domain. Five potential sites of glycosylation, four within the F2 subunit, were also identified. Three extremely hydrophobic domains are present in the protein; a) the N-terminal signal sequence, b) the N-terminus of the F1 subunit that is analogous to the N-terminus of the paramyxovirus F1 subunit and the HA2 subunit of influenza virus hemagglutinin, and c) the putative membrane anchorage domain near the C-terminus of F1.     

Both VP2 and VP3 are synthesized from each of the alternative spliced late 19S RNA species of simian virus 40.

The late 19S RNAs of simian virus 40 consist of a family of alternatively spliced RNAs, each of which contains open reading frames corresponding to all three of the virion proteins. Two approaches were used to test the hypothesis that each alternatively spliced 19S RNA species is translated to synthesize preferentially only one of the virion proteins. First, we analyzed the synthesis of virion proteins in simian virus 40 mutant-infected monkey cells that accumulate predominantly either only one spliced 19S RNA species or only the 19S RNAs. Second, we determined the virion proteins synthesized in a rabbit reticulocyte lysate programmed with specific, in vitro-transcribed 19S RNA species. These results indicated that VP2 and VP3, but not VP1, are synthesized from all 19S RNA species. Quantitative analysis of these data indicated that individual 19S RNA species containing a translation initiation signal upstream of the VP2 AUG codon were translated in a cell extract three- to fivefold less efficiently than were 19S RNA species lacking this signal and that the precise rate of synthesis of VP2 relative to VP3 varied somewhat with the sequence of the leader region. These data are consistent with the synthesis of VP2 and VP3 occurring by a leaky scanning mechanism in which initiation of translation at a specific AUG codon is affected by both (i) the intrinsic efficiency of ribosomes recognizing the sequences surrounding the AUG codon as an initiation signal and (ii) partial interference from 5'-proximal initiation signals and their corresponding open reading frames.     

Complete sequence of bluetongue virus L2 RNA that codes for the antigen recognized by neutralizing antibodies.

The complete sequence of the RNA which encodes the major outer-shell-neutralizing antigen (VP2) of bluetongue virus serotype 10 was determined from overlapping cDNA clones inserted into pBR322. The segment L2 RNA was 2,926 base pairs long (1.87 X 10(6) daltons) and had, in one strand, an open reading frame capable of coding for a protein that had a calculated size of 111,122 daltons (956 amino acids) and a +11.5 net charge. The coding strands of both the L2 gene and the group-specific L3 gene of bluetongue virus serotype 17 (M. Purdy, J. Petre, and P. Roy, J. Virol. 51:754-759, 1984) had common sequences of some six nucleotides at their 5' termini (namely, GUUAAA...) and eight nucleotides (namely, ...ACACUUAC) at their 3' termini. Both had short 5' noncoding regions with AUG codons at residues 20 to 22 (L2) and 18 to 20 (L3). The sequences flanking these AUG codons were similar (A/GCCAUGG). The 3' noncoding regions were longer (36 nucleotides for L2, 49 nucleotides for L3). The predicted amino acid sequence of the L2, compared with the similarly sized L3 gene product, was rich in cysteine residues and charged amino acids.     

A domain of SV40 capsid polypeptide VP1 that specifies migration into the cell nucleus.

In order to identify the determinants responsible for the nuclear migration of simian virus 40 (SV40) polypeptide VP1, the 5'-terminal portion of the SV40 VP1 gene was fused with the complete cDNA sequence of poliovirus capsid polypeptide VP1 and the hybrid gene was inserted into an SV40 vector in place of the normal SV40 VP1 gene. Deletions of various length were generated in the SV40 VP1 portion of the hybrid gene, resulting in a set of truncated genes encoding 2-40 NH2-terminal amino acids from SV40 VP1, followed by poliovirus VP1. Monkey kidney cells were infected by the deleted hybrid viruses in the presence of an early SV40 amber mutant as helper, and the subcellular localization of the fusion proteins was determined by indirect immunofluorescence using an anti-poliovirus VP1 immune serum. The presence of the first 11 NH2-terminal amino acids from SV40 VP1 was found to be sufficient to target the fusion protein to the cell nucleus. Deletions extending from the NH2- towards the COOH-terminal end of the protein were next generated. Transport of the SV40 VP1-poliovirus VP1 fusion polypeptide to the nucleus was abolished when the first eight amino acids from SV40 VP1 were deleted. Thus the sequence of the first eight NH2-terminal amino acids of SV40 VP1 appears to contain a nuclear migration signal which is sufficient to target the protein to the cell nucleus.     

The length but not the sequence of the polyoma virus late leader exon is important for both late RNA splicing and stability.

Polyoma virus late RNA processing provides a convenient model system in which to study the mechanics of splicing in vivo. In order to understand further the role of the untranslated "late leader" unit in late RNA processing we have constructed a group of polyoma viruses with deletions and substitutions in the leader exon. This has allowed us to determine that there is a minimum exon size required for both pre-mRNA splicing and stability in this system. We show here that the non-viability of a mutant (ALM) with a 9 base late leader unit is due to a general defect in late RNA splicing. In addition, ALM-infected cells show at least 40-fold depression in the accumulation of late nuclear RNA (spliced or unspliced). The ALM late promoter, however, functions nearly normally. Substituted leader variants with 51- to 96-base long exons of unrelated sequence are viable (G. Adami and G. Carmichael, J. Virol. 58, 417-425, 1986). We show here that late RNA from one of these substituted leader mutants (containing a 51-base leader exon) is spliced at wild type levels, with virtually no defect in accumulation. Thus, in the polyoma system, splice sites separated by only 9 bases can inhibit each others usage, presumably by steric interference. We suggest that this type of inhibition leads to extreme RNA instability.