Direct biochemical mapping of eukaryotic viral DNA by means of a linked transcription-translation cell-free system

Maize chloroplast DNA fragment encoding the large subunit of ribulosebisphosphate carboxylase

In vitro linked transcription-translation of chloroplast DNA has been used to show that the large subunit of ribulose-1,5-bisphosphate carboxylase [3-phospho-D-glycerate carboxy-lyase (dimerizing), EC 4.1.1.39] is encoded by Zea mays chloroplast DNA. A BamHI-generated chloroplast DNA sequence cloned in Escherichia coli is shown to direct the in vitro synthesis of this protein identified as large subunit by its size, serological properties, and limited proteolytic digestion products.

Cytomegalovirus assembly protein nested gene family: four 3'-coterminal transcripts encode four in-frame, overlapping proteins

The genomic region encoding the assembly protein of simian cytomegalovirus (CMV) strain Colburn has been cloned, sequenced, and found to be organized as a nested set of four in-frame, 3'-coterminal genes, each with its own TATA promoter element and translational start codon, and all using a single 3' polyadenylation signal. The 3' end of the longest open reading frame (1.770 bp) was identical to the 930-bp sequence coding for the assembly protein precursor, as determined from a cDNA clone. The assembly protein coding region of human CMV strain AD169 was similarly organized, suggesting that both viral genomes could give rise to four independently transcribed 3'-coterminal RNAs coding for four overlapping, in-frame, carboxy-coterminal proteins. These predictions were tested and confirmed. Four mRNAs corresponding in size and sequence to those predicted were identified in both human and simian CMV-infected cells by using transcript-specific antisense oligonucleotide probes in Northern (RNA blot) assays. The 5' ends of the three largest of these Colburn transcripts were determined by S1 nuclease protection assays and found to map between the anticipated TATA sequences and corresponding translational start codons. The four predicted overlapping proteins were identified by immunoassays in lysates of simian and human CMV-infected cells by using an antiserum specific for the carboxyl end of the assembly protein precursor. The structural relationship of both sets of proteins was verified by comparing their peptide patterns following protein cleavage at tryptophan residues by N-chlorosuccinimide. The similar organization of the homologous coding regions in other herpesviruses into at least two nested, in-frame, 3'-coterminal genes is discussed.

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.

The intranuclear location of simian virus 40 polypeptides VP2 and VP3 depends on a specific amino acid sequence

A cDNA fragment coding for poliovirus capsid polypeptide VP1 was inserted into a simian virus 40 (SV40) genome in the place of the SV40 VP1 gene and fused in phase to the 3' end of the VP2-VP3 genes. Simian cells were infected with the resulting hybrid virus in the presence of an early SV40 mutant used as a helper. Indirect immunofluorescence analysis of the infected cells using anti-poliovirus VP1 immune serum revealed that the SV40/poliovirus fusion protein was located inside the cell nucleus. Deletions of various lengths were generated in the SV40 VP2-VP3 portion of the hybrid gene using BAL31 nuclease. The resulting virus genomes expressed spliced fusion proteins whose intracellular location was either intranuclear or intracytoplasmic, depending on the presence or absence of VP2 amino acid residues 317 to 323 (Pro-Asn-Lys-Lys-Lys-Arg-Lys). This was confirmed by site-directed mutagenesis of the Lys residue at position 320. Modification of Lys-320 into either Thr or Asn abolished the nuclear accumulation of the fusion protein. It is concluded that at least part of the sequence of VP2 amino acids 317 to 323 allows VP2 and VP3 to remain stably located inside the cell nucleus. The proteins are most probably transported from the cell cytoplasm to the cell nucleus by interaction, with VP1 acting as a carrier.

Developmental expression of three proteins from the first gene of the RNA polymerase sigma 43 operon of Bacillus subtilis

The first gene of the Bacillus subtilis RNA polymerase sigma 43 operon, P23, has a protein-coding capacity of 23,000 daltons. Sequence analysis revealed three potential translational initiation sites within the same reading frame, which could encode proteins of 23,000 (P23), 19,000 (P19), and 9,000 (P9) daltons, respectively. An internal promoter (P3), which is expressed only during the sporulation stage, is located between the second and the third translational start sites. By protein fusion to the Escherichia coli beta-galactosidase gene, we showed that all three translational initiation sites of the P23 gene are used in vivo in both E. coli and B. subtilis, and regulation for differential expression of the three proteins during the development of B. subtilis is coupled to the transcriptional promoter switching mechanism. The physiological function of these multiple gene products is unknown and is currently under investigation.

Antipeptide antibodies directed against the carboxy-terminal region of SV40 structural proteins VP2 and VP3

Rabbits were immunized with a synthetic heptapeptide of the sequence Arg-Asn-Arg-Ser-Ser-Arg-Ser corresponding to the carboxy-terminal region of the SV40 viral proteins VP2 and VP3. The raised antibodies recognize the viral proteins in enzyme-linked immunosorbent (ELISA) and Western blot assay. Specificity of the antibodies were confirmed by competition experiments. The antibodies recognize VP2 and VP3 in infected cells by immunofluorescence and in subcellular fractions by ELISA. No interaction with virions was observed.

Subcellular distribution of viral structural proteins during simian virus 40 infection

The amounts of simian virus 40 structural polypeptides Vp1, Vp2, and Vp3 in different subcellular fractions at various times after lytic infection were determined by a quantitative immunoblotting procedure. Simian virus 40-infected cells were lysed with a buffer containing Nonidet P-40 to yield a soluble fraction. The Nonidet P-40-insoluble fraction was further fractionated in the presence of deoxycholate and Tween 40 to yield a soluble fraction (cytoskeletal) and an insoluble fraction (Nuc), which is primarily cell nuclei. At 33 h postinfection, the majority of viral structural proteins was found in the cell nucleus, whereas, at 48 to 65 h postinfection, Vp1 was distributed evenly among all cell fractions and Vp2 and Vp3 were found predominantly in the cytoskeletal and Nuc fractions. Thus, not all of the viral polypeptides synthesized in the cytoplasm migrated into the cell nucleus. Throughout infection, the molar ratio (Vp3/Vp2) was rather constant in all subcellular fractions, indicating that the synthesis or processing or both of Vp2 and Vp3 are coordinately regulated. The molar ratio of Vp1/(Vp2 + Vp3) varied among the fractions. The Vp1/(Vp2 + Vp3) molar ratio in the soluble fraction varied during the course of infection; however, constant ratios were maintained in the cytoskeletal and Nuc fractions. Thus, the mechanism which controls the movement of Vp1 to different compartments of the cell appears to be different from that of Vp2 and Vp3. The Vp1/(Vp2 + Vp3) value in the Nuc fraction was similar to the ratio found in virus particles. The constant molar distribution of Vp1, Vp2, and Vp3 in the Nuc fraction throughout infection suggests that there is a specific mechanism which regulates the transport of viral structural proteins. These results support the hypothesis that the structural proteins of simian virus 40 are transported into the cell nucleus in precise proportions.

Simian virus 40 and polyoma virus induce synthesis of heat shock proteins in permissive cells

During the lytic infection of monkey and mouse cells with simian virus 40 and polyoma virus, respectively, the preferentially increased synthesis of two host proteins of 92,000 and 72,000 Mr was observed by 15 to 20 h after infection besides the general stimulation of most cellular proteins. The incubation of uninfected monkey and mouse cell cultures for 30 to 60 min at 43.5 degrees C induced the enhanced synthesis of at least three proteins of 92,000, 72,000 and 70,000 Mr, the last one being the major heat shock protein of mammalian cells. Two-dimensional gel electrophoresis and partial proteolytic digestion confirmed that the same 92,000- and 72,000-Mr proteins are stimulated by virus infection and thermal treatment. In simian virus 40-infected CV-1 cells, we also observed the weak stimulation of a 70,000-Mr protein comigrating in gel electrophoresis with the major heat shock protein. The 92,000-, 72,000- and 70,000-Mr proteins of monkey cells are structurally very similar to the corresponding proteins of mouse cells. In immunoprecipitations, no specific association of these proteins to simian virus 40 T antigens was noticed.

A simian virus 40-encoded protein of Mr 74,000 daltons is structurally related to the capsid proteins of the virus

We have demonstrated the synthesis of a 74,000-dalton protein (74K protein) in African green monkey kidney cells infected with simian virus (SV)40. The 74K protein was detected late during the lytic cycle. Its synthesis was inhibited by arabinosyl cytosine as was the synthesis of the capsid proteins. Monospecific antibodies raised against VP1 and VP3 precipitated the structural proteins and the 74K protein. The 74K protein was not found in purified virions. Tryptic peptide analysis demonstrated that the 74K protein shares methionine- and serine-containing peptides with VP1 and VP3 and thus is structurally related to the capsid proteins.

Simian virus 40 and polyoma virus induce synthesis of heat shock proteins in permissive cells

During the lytic infection of monkey and mouse cells with simian virus 40 and polyoma virus, respectively, the preferentially increased synthesis of two host proteins of 92,000 and 72,000 Mr was observed by 15 to 20 h after infection besides the general stimulation of most cellular proteins. The incubation of uninfected monkey and mouse cell cultures for 30 to 60 min at 43.5 degrees C induced the enhanced synthesis of at least three proteins of 92,000, 72,000 and 70,000 Mr, the last one being the major heat shock protein of mammalian cells. Two-dimensional gel electrophoresis and partial proteolytic digestion confirmed that the same 92,000- and 72,000-Mr proteins are stimulated by virus infection and thermal treatment. In simian virus 40-infected CV-1 cells, we also observed the weak stimulation of a 70,000-Mr protein comigrating in gel electrophoresis with the major heat shock protein. The 92,000-, 72,000- and 70,000-Mr proteins of monkey cells are structurally very similar to the corresponding proteins of mouse cells. In immunoprecipitations, no specific association of these proteins to simian virus 40 T antigens was noticed.

Evolutionary changes of nucleotide sequences of papova viruses BKV and SV40: they are possibly hybrids

Complete nucleotide sequences were compared between papova viruses BKV and SV40 and the degrees of sequence divergences were compared between structurally and/or functionally different segments or genes in details. It was shown that the rate of synonymous substitution is not only very high but also approximately uniform among different genes in these viruses as in eukaryotic genes examined to date. While all the non-coding regions including the intron showed marked sequence preservation which is in sharp contrasted with the case of eukaryotic genes where the large bulk of non-coding regions evolve at a rate as rapidly as that of synonymous substitution. It is remarkable that a long continuous stretch of sequence including the putative VPX gene and a 5' half of VP2 gene showed strong homology between BKV and SV40. A close examination of the pattern of base substitutions revealed that this unusual homology was derived by recombination between the two viruses during their evolution. On the basis of the pattern of base substitutions and the bias in code word utilization, we also showed that the putative VPX gene actually could code for a functional polypeptide. In papova viruses, the 3' terminal sequence of VP2/3 gene overlaps with the 5' terminal sequence of VPI gene. The pattern of base substitutions in the overlapping segment was examined in detail in comparison with those in the non-overlapping portions of VP2/3 and VP1 genes. It was shown that the evolutionary mode of the overlapping genes is in good agreement with our previous prediction.

Sequential transcription-translation of simian virus 40 by using mammalian cell extracts

Ribonucleic acids (RNAs) transcribed in vitro by using the whole-cell extract system of Manley et al. (Proc. Natl. Acad. Sci. U.S.A. 77:3855-3859, 1980) were tested for their efficiency and fidelity in directing protein synthesis in reticulocyte lysates. Simian virus 40 deoxyribonucleic acid (DNA), cleaved by various restriction endonucleases, was used as the template. Successful translation of the small tumor antigen t, as well as the capsid proteins VP1, VP2, and VP3, was detected by immunoprecipitation analysis. Although no synthesis of large T antigen was detected, use of this technology allows detection of large T synthesis resulting from the correct splicing of as little as 0.2% of the in vitro RNA transcripts, making it ideal for use as an in vitro splicing assay. Transcripts synthesized in vitro were used as messages at least as efficiently as were viral messenger RNA's (mRNA's) synthesized in vivo; and in the case of small t, there was more efficient translation of small t mRNA synthesized in vitro than of small t mRNA synthesized in vivo. The transcripts that served as mRNA's for the various polypeptides were identified by using the following two criteria. (i) The sensitivity of synthesis of a given protein to digestion of the template DNA with restriction enzymes allowed the localization of the promoter and coding regions. (ii) Translation of size-fractionated RNA allowed confirmation of the transcript-mRNA assignments. With these techniques we found that VP2, VP3 and, in some cases, VP1 synthesis resulted from the initiation of translation at internal AUG codons. In fact, families of polypeptides were produced by initiation of translation at AUG codons within sequences coding for VP1 and T, presumably as a result of transcription initiation events that generated 5' ends immediately upstream from these AUGs. Application of this technology for the identification of coding regions within cloned DNA fragments is discussed.

Isolation of a monoclonal antibody viral polypeptide VP2 of simian virus 40

A stable hybridoma cell line, IIG8-203-2, that secretes a monoclonal antibody of the immunoglobulin subclass M was obtained by fusion of mouse myeloma cells with spleen cells of mice that had been immunized with the viral polypeptide VP2 of simian virus 40. The monoclonal antibody recognizes viral polypeptides that migrate with VP2 polypeptides in a sodium dodecyl sulfate-polyacrylamide gel. It also recognizes two intracellular polypeptides (29,000 and 37,000 daltons) in a detergent-insoluble fraction extracted 30 h after virus infection of TC7 cells.

Sequential transcription-translation of simian virus 40 by using mammalian cell extracts

Ribonucleic acids (RNAs) transcribed in vitro by using the whole-cell extract system of Manley et al. (Proc. Natl. Acad. Sci. U.S.A. 77:3855-3859, 1980) were tested for their efficiency and fidelity in directing protein synthesis in reticulocyte lysates. Simian virus 40 deoxyribonucleic acid (DNA), cleaved by various restriction endonucleases, was used as the template. Successful translation of the small tumor antigen t, as well as the capsid proteins VP1, VP2, and VP3, was detected by immunoprecipitation analysis. Although no synthesis of large T antigen was detected, use of this technology allows detection of large T synthesis resulting from the correct splicing of as little as 0.2% of the in vitro RNA transcripts, making it ideal for use as an in vitro splicing assay. Transcripts synthesized in vitro were used as messages at least as efficiently as were viral messenger RNA's (mRNA's) synthesized in vivo; and in the case of small t, there was more efficient translation of small t mRNA synthesized in vitro than of small t mRNA synthesized in vivo. The transcripts that served as mRNA's for the various polypeptides were identified by using the following two criteria. (i) The sensitivity of synthesis of a given protein to digestion of the template DNA with restriction enzymes allowed the localization of the promoter and coding regions. (ii) Translation of size-fractionated RNA allowed confirmation of the transcript-mRNA assignments. With these techniques we found that VP2, VP3 and, in some cases, VP1 synthesis resulted from the initiation of translation at internal AUG codons. In fact, families of polypeptides were produced by initiation of translation at AUG codons within sequences coding for VP1 and T, presumably as a result of transcription initiation events that generated 5' ends immediately upstream from these AUGs. Application of this technology for the identification of coding regions within cloned DNA fragments is discussed.

Morphogenetic genes C and Nu3 overlap in bacteriophage lambda

In bacteriophage lambda, genes C and Nu3, two of the four cistrons which are essential for normal prohead formation, have overlapping nucleotide sequences. These genes are translated in the same reading frame so that the Nu3 protein is identical to the COOH-terminal one-third of the C protein. This structural relationship may provide for the functional interaction of the C and Nu3 proteins through their regions of structural homology during prohead assembly. The in-phase overlapping organisation of genes may constitute a general strategy to facilitate the mutual interaction of a pair of proteins through their common structural domains.

Translation of specific vaccinia virus RNAs purified as RNA-DNA hybrids on potassium iodide gradients

A procedure has been developed for purifying specific mRNAs by hybridization to fragments of DNA and isolation of the hybrids by potassium iodide equilibrium buoyant density centrifugation. The hybrids obtained are essentially free of unhybridized RNA as well as double-stranded RNA. Moreover, the RNA in the hybrids is undamaged and can be translated in vitro. Application of this procedure to mapping vaccinia virus genes is described. A total of 34 polypeptides have been assigned to three regions of the viral genome.

Vp1 affects intracellular localization of Vp3 polypeptide during simian virus 40 infection

In order to understand the functions of simian virus 40 genes, permissive cells (TC7) were infected with mutants temperature sensitive in the complementation groups A, B, C, BC, and D at permissive and nonpermissive temperatures. Cells were examined for the localization of viral polypeptide antigens by immunofluorescent staining with monospecific antibodies. The results are as follows: (i) The appearance of Vp1 antigen in cells infected by tsB, C, or BC mutants was not affected appreciably by the mutations. (ii) The appearance of Vp3 antigen was affected by the mutations in B, C, or BC. Vp3 antigen is confined to the nuclei in cells infected by wild-type virus. With mutant virus infection, Vp3 antigen is found in the cytoplasm, perinuclear region, and nucleoli. (iii) The tsD mutants and the tsA mutants did not express either Vp1 or Vp3 antigens at the nonpermissive temperature. (iv) Nucleoli seem to play an essential role in the biosynthesis and assembly of viral polypeptides. Thus, mutations in any one of complementation groups B, C, or BC, which are within the structural gene for Vp1, cause an alteration of intracellular distribution of another late gene product, Vp3. These results suggest that the amino acid sequences of Vp1 polypeptide play a role(s) in the transport of viral antigens across internal membranes or in virus assembly processes or in both.

Cell-free translation of simian virus 40 16S and 19S L-strand-specific mRNA classes to simian virus 40 major VP-1 and minor VP-2 and VP-3 capsid proteins

Simian virus 40 capsid proteins VP-1, VP-2, and VP-3 have been synthesized in wheat germ and reticulocyte cell-free systems in response to either poly(A)-containing mRNA from the cytoplasm of infected cells or viral RNA purified by hybridization to simian virus 40 DNA linked to Sepharose. All three viral polypeptides synthesized in vitro are specifically immunoprecipitated with anti-simian virus 40 capsid serum. VP-2 and VP-3 are related by tryptic peptide mapping to each other but not to VP-1. The most abundant class of L-strand-specific viral mRNA, the 16S species, codes for the major capsid protein. The relatively minor 19S class directs the cell-free synthesis of VP-1, VP-2, and VP-3. Whether the 19S RNA represents more than one distinct species of mRNA is not yet clear. VP-1 mRNA can be isolated from the cytoplasm, detergent-washed nuclei, and the nuclear wash fraction. The mRNA from the nuclear wash fraction is enriched for VP-2 mRNA when compared to other viral or cellular polypeptides.

The 3' noncoding region of beta-globin mRNA is not essential for in vitro translation

Rabbit beta globin DNA sequence, excised from plasmid pbetaG1, directs in vitro synthesis of beta-globin in a transcription-translation cell-free system, even after specific elimination of the entire 3'-noncoding region. A DNA restriction fragment carrying this 3' noncoding region and hybridized to globin mRNA cannot arrest the cell-free translation of beta-globin mRNA.

DNAs of simian virus 40 and polyoma direct the synthesis of viral tumor antigens and capsid proteins in Xenopus oocytes

Purified simian virus 40 and polyoma DNAs injected into nuclei of Xenopus oocytes were transcribed and subsequently translated into virus-specific tumor antigens and capsid proteins. Simian virus 40 large and small tumor antigens synthesized in the oocytes were indistinguishable, by gel electrophoresis and [35S]methionine-labeled tryptic peptide mapping, from the corresponding polypeptides synthesized in CV-1 African green monkey cells. The synthesis of large simian virus 40 tumor antigen implies the correct splicing of its mRNA, which is complementary to nonadjacent nucleotide sequences in the early region of the viral genome. Polyoma DNA directed synthesis of two polyoma tumor antigen polypeptides, 57,000 Mr and small tumor antigen, and of the main capsid protein.

Nucleotide sequence of the simian virus 40 Hind II + III restriction fragment J and the total amino acid sequence of the major structural protein VP1

The HindII + III restriction fragment J (Hind-J) represents 4.58% of the simian virus 40 genome. The information present in Hind-J is expressed as part of the major, late 16-S messenger RNA, which codes for the structural protein VP1. The nucleotide sequence of the 240-base-pairs-long Hind fragment J has been determined by analysis of each oligonucleotide from both strands resulting from T1 or pancreatic RNase digestion of RNA transcribed from the DNA and from RNase digestion of ribo-substituted DNA. Large oligonucleotide blocks which could be constructed mainly on the basis of complementarity were subsequently ordered by partial chemical degradation of terminally labeled DNA. This direct DNA sequencing approach also completely confirmed the results obtained by both aforementioned RNase degradation methods. In the strand with the same polarity as the late mRNA, triplets corresponding to termination codons are present in two of the three reading frames. The one open reading frame connects in phase with the open reading frame of the neighboring HindII/ III fragments K, F and G, which have been published previously and which together with Hind-J span the total VP1 gene. Some features of the primary nucleotide sequence of this VP1 gene and the derived VP1 amino acid sequence are discussed.

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.

Polyoma virus has three late mRNA's: one for each virion protein

Polyoma virus mRNA, isolated from the cytoplasm of 3T6 cells late after infection and purified by hybridization to HpaII fragment 3 of polyoma virus DNA, was separated on 50% formamide-containing sucrose density gradients, and the fractionated RNA was recovered and translated in vitro. Analysis of the cell-free products showed that the minor virion protein VP3 was synthesized from an mRNA sedimenting at approximately 18S betweeen the 19S VP2 mRN and the 16S VP1 mRNA. Other experiments showed that the VP2 and VP3 can be labeled with formyl methionine from initiator tRNA. We conclude that there are three late polyoma virus mRNA's, each directing the synthesis of only one viral capsid protein.

Complete nucleotide sequence of the simian-virus 40 Hind-G fragment and localisation of the carboxyl terminus of the VP1 protein

The restriction fragment Hind-G represents 7.0% of the simian virus 40 (SV40) genome. The information present in fragment Hind-G is expressed as part of the major, late 16-S messenger RNA. The complete nucleotide sequence of the fragment Hind-G has now been determined by application of the procedure of Maxam and Gilbert [Proc. Natl Acad. Sci. U.S.A. (1977) 74, 560-564]. It contains 369 nucleotide base pairs. On the basis of the termination code words in the strand with the same polarity as the late mRNA, two illegitimate reading frames can be defined. Therefore the third, open frame must code for the carboxyl terminal part of the VP1 protein. It terminates within fragment Hind-G with a TGA signal. This stop codon is followed by a non-translated region of the mRNA of about 83 nucleotides. The latter contains the sequence A-A-U-A-A-A, common to all other eukaryotic mRNA molecules so far studied. The Hind-G fragment also contains sequences which presumably play a role in the synthesis, processing and/or expression of early mRNA; these aspects are discussed in the following paper.

Nucleotide sequence of the restriction fragment Hind-F-EcoRI1 of simian-virus-40 DNA (part of the VP1 gene)

The nucleotide sequence of the simian virus 40 (SV40) genome region between the cleavage sites for restriction endonucleases EcoRI (map position 0) and HindII (map position 0.05) has been determined mainly by the partial chemical DNA degradation procedure of Maxam and Gilbert. This fragment represents 5.3% of the genome of SV40 and is located in the late region, internally in the VP1 gene. The message strand shows only one open reading frame for translation into protein, which connects to the one for the preceding fragment. On this basis part of the amino acid sequence of the VP1 protein is presented.

Complete nucleotide sequence of SV40 DNA

The determination of the total 5,224 base-pair DNA sequence of the virus SV40 has enabled us to locate precisely the known genes on the genome. At least 15.2% of the genome is presumably not translated into polypeptides. Particular points of interest revealed by the complete sequence are the initiation of the early t and T antigens at the same position and the fact that the T antigen is coded by two non-contiguous regions of the genome; the T antigen mRNA is spliced in the coding region. In the late region the gene for the major protein VP1 overlaps those for proteins VP2 and VP3 over 122 nucleotides but is read in a different frame. The almost complete amino acid sequences of the two early proteins as well as those of the late proteins have been deduced from the nucleotide sequence. The mRNAs for the latter three proteins are presumably spliced out of a common primary RNA transcript. The use of degenerate codons is decidedly non-random, but is similar for the early and late regions. Codons of the type NUC, NCG and CGN are absent or very rare.

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.

Electron microscope study of the base sequence homology between simian virus 40 and human papovavirus BK

The base sequence homology between the genomes of simian virus 40 (SV40) and human papovavirus BK (BKV) was studied by the heteroduplex method of Ferguson and Davis (J. Mol. Biol. 94:135-149, 1975). When mounted for microscopy in 30% formamide (Tm-35 degrees C), BKV/SV40 heteroduplexes were an average of 92% double-stranded and contained only two small nonhomologous regions that mapped near the junctions between the early and late regions of the SV40 Genome. At higher formamide concentrations, the fraction of duplex DNA in the BKV/SV40 heteroduplexes decreased, indicating significant base mismatching in the homologous regions. The strongest regions of homology were located in the late region.

Comparison of two viable variants of simian virus 40

The DNAs of two viable strains of simian virus 40, 776 and 777, have been compared by using restriction endonucleases. Differences between the two strains were detected at five separate points on the simian virus 40 genome. One of these differences, in the region of DNA coding for the major viral coat protein, was confirmed by tryptic peptide analysis of coat proteins from the two strains. Some physiological differences between the two strains were examined and can, in general, be explained by differences observed between the DNAs of the two strains. In addition, defective variants derived from strain 777 interfere more efficiently with the replication of strain 777 than with the replication of strain 776.

5'-Terminal sequences and coding region of late simian virus 40 mRNAs are derived from noncontiguous segments of the viral genome

The region of the simian virus 40 genome complementary to the 5' end of the most abundant poly(A)-containing 19S and 16S mRNAs was mapped by hybridization of double-labeled RNA ([3H]methyl group and [14C]uridine) to specific DNA fragments. Chemical identification of methylated residues indicated that a common "leader" sequence adjacent to the 5' terminus of both 19S and 16S mRNA is transcribed from DNA sequences located between 0.67 and 0.76 map units. The estimated size of this "leader" RNA, which does not code for any known viral protein, is 170-200 nucleotides. Our results indicate that sequences complementary to the "leader" region and coding portion of 16S mRNA are located in separate parts of the simian virus 40 genome.

Physical and genetic characterization of deletion mutants of simian virus 40 constructed in vitro

Mutants of simian virus 40 (SV40), with deletions ranging in size from fewer than 3 to 750 base pairs located throughout the SV40 genome, were obtained by infecting CV-1P cells with linear SV40 DNA and DNA of an appropriate helper virus. The linear DNA was obtained by complete cleavage of closed circular DNA with Hae II or Bam HI endonuclease or partial cleavage with either Hae III endonuclease or nuclease S1, followed, in some cases, by mild digestion with phage lambda 5' -exonuclease. The following mutants with deletions in the late region of the SV40 genome were obtained and characterized. Ten, containing deletions at the Hae II endonuclease site (map location 0.83), define a new genetic complementation group, E, grow extremely slowly without helper virus, and cause alterations only in VP2. Two mutants with deletions in the region 0.92 to 0.945 affect both VP2 and VP3, demonstrating that VP3 shares sequences with the C-terminal portion of VP2. The mutant with a deletion at 0.93 is the first deletion mutant in the D complementation group and is also temperature sensitive; the mutant with a deletion at 0.94 is viable and grows normally. Three mutants with deletions at the EcoRI endonuclease site (0/1.0) and eleven with deletions at the BamHI endonuclease site (0.15) fall into the B/C complementation group. Six additional mutants with deletions at the BamHI endonuclease site are viable, growing more slowly than wild type. VP1 is the only polypeptide affected by mutants in the B/C group. A mutant with a deletion of the region 0.72 to 0.80 has a polar effect, failing to express the E, D, and B/C genes. Mutants with deletions in the early region (0.67 counterclockwise to 0.17) at 0.66 to 0.59, 0.48, 0.47, 0.33, and 0.285 to 0.205 are all members of the A complementation group. Thus, the A gene is the only viral gene in the early region whose expression is necessary for productive infection of permissive cells. Since mutants with deletions in the region 0.59 to 0.54 are viable, two separate regions are essential for expression of the gene A function: 0.66 to 0.59 and 0.54 to 0.21. Mutants with deletions at 0.21 and 0.18 are viable. Approximate map locations of SV40 genes and possible models for their regulation are discussed.

Novel mechanism for RNA maturation: the leader sequences of simian virus 40 mRNA are not transcribed adjacent to the coding sequences

The 5'-terminal 100-200 ribonucleotides of late simian virus 40 (SV40) mRNAs are not transcribed immediately adjacent to their coding sequences. This conclusion is based on the following observations. The major late SV40 cytoplasmic RNA species, 16S and 19S, were purified from poly(A)-containing cytoplasmic RNA by hybridization to and elution from an SV40 DNA fragment that maps between 0.67 and 0.76. This fragment is remote from the DNA fragments that include the coding sequences. The RNA transcripts from the fragment located between 0.67 and 0.76 were found in abundance. Even though selected on oligo(dT)-cellulose columns, the 5'-terminal sequences did not contain poly(A) tails directly adjacent to their 3' termini. The 5' terminus of the 16S mRNA, as monitored by hybridization of the sequences adjacent to the "cap" structure, was found adjacent to the coding sequences when intact [3H]methyl-labeled RNA was hybridized with restriction fragments. However, after fragmentation, the methyl label of this same RNA hybridized with a fragment that is remote from the coding sequences and maps between 0.67 and 0.73. These results imply a novel mechanism for biosynthesis of SV40 mRNA.

Genetic analysis of host range mutant viruses suggests an uncoating defect in simian virus 40-resistant monkey cells

Host range mutations that permit simian virus 40 (SV40) to grow with increased efficiency on SV40-resistant monkey cells have been positioned within the viral B/C gene by a mapping method that relies on the coupling of specific DNA fragments. Pairs of restriction endonucleases that each cleave SV40 DNA at only one site were used to generate pairs of specific DNA fragments. Corresponding pairs of fragments were purified from host range mutant and wild-type DNA and joined in known combinations to determine the location of the host range mutations. The map position of the host range mutations was confirmed by using the same technique to generate and couple genetically marked viral DNA fragments to produce the predicted double mutants. Three different double mutants were constructed that carry both host range and temperature-sensitive A mutations. The mutations in three independently isolated host range mutant viruses are located at very close, perhaps identical, sites, because no wild type viruses were produced from the cell-mediated repair of pairwise heteroduplexes between them. The location of these host range mutations suggests that their phenotype results from mutational alteration of the major capsid protein, the product of the B/C gene. In addition it was demonstrated that monkey cells can efficiently join appropriate pairs of restriction endonuclease fragments intracellularly to produce infectious genomes. That reaction has been partially characterized. The general utility of fragment coupling (in vitro and in vivo) and heteroduplex repair for constructing and analyzing multiple mutants of SV40 is discussed.

DNA complementary to parathyroid mRNA directs synthesis of pre-proparathyroid hormone in a linked transcription-translation system

DNA complementary in sequence to the messenger RNA for pre-proparathyroid hormone was synthesised using reverse transcriptase. In a linked transcription-translation system using RNA polymerase and cell-free extract from wheat germ, the DNA directed the synthesis of a protein identified as pre-proparathyroid hormone by N-terminal sequencing and by electrophoretic and immunologic criteria.

Cell-free synthesis of herpes simplex virus proteins

Polyribosomes isolated from herpes simplex virus type I (HSV-1)-infected cells have been used to program a eucaryotic cell-free translation system. At least 10 HSV-specific polypeptides, with apparent molecular weights of 25,000 to 160,000, are synthesized by wild-type HSV-infected polyribosomes. Polyribosomes prepared from thymidine kinase-negative mutants of HSV direct the synthesis of three putative nonsense termination polypeptides. HSV-specific polypeptides synthesized in vitro are precipitated with antiserum to HSV-infected cell proteins.

Nucleotide sequence of the restriction fragment Hind F-Eco RI2 of SV40 DNA

The nucleotide sequence of the SV40 genome region between the Hind K fragment and the Eco RI cleavage site has been determined by a combination of three different approaches : analysis of RNA products obtained by transcription with Escherichia coli DNA dependent RNA polymerase, partial degradations with snake venom exonuclease and base-specific chemical degradation of 5'-terminal labeled restriction fragments. This nucleotide sequence shows only one open reading frame and allows the deduction of a small segment of the amino acid sequence of VP1, the major structural protein.

Identification of simian virus 40 tumor and U antigens

The synthesis and identity of the tumor and U antigens of simian virus 40 (SV 40) have been examined during productive infection in monkey cells, abortive infection in mouse cells, and in SV40-transformed mouse cells by using sodium dodecyl sulfate/polyacrylamide slab gel electrophoresis to analyze [35S]methionine-labeled radioimmune precipitates. The following observations were made: (i) the tumor and U antigenic sites are on the same 94,000, 89,000, and 84,000 molecular weight species detected during productive infection; a 94,000 species made during abortive infection; and a 94,000 species found in transformed cells. (ii) The 94,000 species is relatively unstable compared to the relatively stable 89,000 and 84,000 species produced during productive infection. (iii) The stable 89,000 and 84,000 molecular weight species are differentially extracted from productively infected cells, which suggests an intracellular compartmentation and/or different affinities of these species for cellular substrates. (iv) The 94,000 species synthesized during abortive infection is more stable than the comparable 94,000 species synthesized in transformed cells. (v) Three tsA group mutants overproduce several unstable species of tumor antigen at restrictive temperature.