Nucleotide sequence of the simian virus 40 small-t gene

The nucleotide sequence of the segment of simian virus 40 DNA between standard map positions 0.53 and 0.65, i.e., approximately half of the restriction fragment Hind A, is reported. This segment is located near the beginning of the early region and is transcribed counterclockwise. There is a potential initiating ATG signal at 13 nucleotides from the Hind C-Hind A junction in the strand with the same polarity as the early mRNA. From this signal on, an open reading frame is present which would allow the synthesis of a polypeptide of 174 amino acids until a TAA termination codon is reached at nucleotide 602 (map position 0.547). This polypeptide, revealed by the DNA sequence, corresponds almost certainly to small-t antigen. Correlation of the deduced amino acid sequence with the NH(2)-terminal sequences of small-t and large-T (tumor) antigens of simian virus 40, as established by Paucha et al. [Paucha, E., Mellor, A., Harvey, R., Smith, A. E., Hewick, R. M. & Waterfield, M. D. (1978) [Proc. Natl. Acad. Sci. USA 75, 2165-2169], strongly argues that both proteins are indeed initiated at the ATG triplet. Because the DNA region between 0.547 and 0.534 is blocked for translation in all three reading frames by multiple termination condons, we conclude that the large-T antigen must be coded for by two noncontiguous DNA segments: the segment from 0.65 to around 0.60, which small-t and large-T antigens share, and another segment starting at some point after position 0.534 and continuing counterclockwise until it terminates at map position 0.174. Small-t antigen is methionine-rich and has a remarkably high number of cysteine residues clustered mainly in its COOH-terminal half. It is rich in both basic and acidic residues, the former being slightly in excess.     

Structure of a large segment of the genome of simian virus 40 that does not encode known proteins.

The nucleotide sequence of the region of DNA of simian virus 40 extending from 0.595 to 0.790 map unit has been derived. The sequence includes the DNA complementary to the 5' end of early mRNA and to the 5' end of some of the forms of late RNA. Because there are termination codons in all three phases in early and late RNA, there is a sequence of almost 800 nucleotides of simian virus 40 DNA that probably does not code for known viral proteins. The sequence spans the 5' end of the early mRNA at 0.67 map unit and overlaps a species of late RNA whose 5' end is at 0.65 map unit and whose 3' end is at 0.77 map unit. This RNA is retained on oligo(dT)-cellulose columns in high salt concentrations. Analysis of the sequence of late strand RNA suggests that this RNA is not covalently linked to the mRNA that encodes structural proteins. There is another species of late RNA of simian virus 40 whose 5' end is at 0.775 map unit. The nucleotide sequence of this region of simian virus 40 DNA contains several examples of repeated sequences, most of which are located in DNA that does not encode known peptides. These may be analogous to the reiterated sequences that have been described in animal cell DNA.     

BK virus DNA sequence: extent of homology with simian virus 40 DNA.

The primary nucleotide sequence of three regions of BK virus (BKV) variant (MM) DNA has been determined. The region between map positions 0.715 and 0.900 includes the initiation points and partial coding sequences of the putative VP2 and VP3 proteins of BKV(MM), the amino acid sequences of which show over 80% homology with those of VP2 and VP3 of simian virus 40. The sequence of a potential leader protein X, 66 amino acids long for BKV(MM) and 62 long for simian virus 40, is also deduced. The regions between 0.595 and 0.398 and 0.310 and 0.175 include the coding sequence for the entire small t antigen and most of the large T antigen of BKV(MM). The DNA sequence within these regions comprises over 50% of the complete BKV(MM) genome and shows a 70% sequence homology with the corresponding regions of simian virus 40 DNA. This high degree of homology is at variance with the reported homology values of 11--20% estimated by hybridization measurements of heteroduplex analyses. Possible explanations for the discrepancy are discussed.     

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.     

Recognition site of Escherichia coli B restriction enzyme on ?XsB1 and simian virus 40 DNAs: An interrupted sequence

Methyl groups placed on varphiXsB1 replicative form DNA by the Escherichia coli B modification enzyme are located in the overlap between fragments Mbo II-3 and Alu I-2, a 61-base-pair DNA segment. Mutations that led to loss of susceptibility to restriction by E. coli B occurred within this segment at three positions spanning 14 nucleotides. A sequence difference between varphiXsB1 and varphiXam3cs70, a varphiX174 strain not restricted by E. coli B, occurs at one of these positions. The site on simian virus 40 DNA methylated by the modification enzyme is located in the 115-base-pair overlap between fragments Hae III-I and Alu I-G. The sequences of these segments of varphiXsB1 and simian virus 40 DNA and two regions of phage f1 DNA recognized by the E. coli B restriction enzyme [Ravetch, J. V., Horiuchi, K. & Zinder, N. D. (1978) Proc. Natl. Acad. Sci. USA 75, 2266-2270] contain a homology of nine bases in the configuration:5'-T-G-A... 8N... T-G-C-T... 9N... T-N-N-T-3'.The sequence 5'-T-G-A... 8N... T-G-C-T-3' may constitute the restriction enzyme recognition site since it does not occur in varphiXam3cs70 DNA and occurs only once in simian virus 40 DNA, and since all observed mutations leading to loss of the site occur at one of the bases specified by this sequence. Analysis of the sequence of varphiXam3cs70 showed that if no other residues are recognized, all seven of these bases are essential for recognition and the interval between the two groups of specified bases must be precisely eight.     

Amino- and carboxyl-terminal amino acid sequences of proteins coded by gag gene of murine leukemia virus

The amino- and carboxyl-terminal amino acid sequences of proteins (p10, p12, p15, and p30) coded by the gag gene of Rauscher and AKR murine leukemia viruses were determined. Among these proteins, p15 from both viruses appears to have a blocked amino end. Proline was found to be the common NH(2) terminus of both p30s and both p12s, and alanine of both p10s. The amino-terminal sequences of p30s are identical, as are those of p10s, while the p12 sequences are clearly distinctive but also show substantial homology. The carboxyl-terminal amino acids of both viral p30s and p12s are leucine and phenylalanine, respectively. Rauscher leukemia virus p15 has tyrosine as the carboxyl terminus while AKR virus p15 has phenylalanine in this position. The compositional and sequence data provide definite chemical criteria for the identification of analogous gag gene products and for the comparison of viral proteins isolated in different laboratories. On the basis of amino acid sequences and the previously proposed H-p15-p12-p30-p10-COOH peptide sequence in the precursor polyprotein, a model for cleavage sites involved in the post-translational processing of the precursor coded for by the gag gene is proposed.     

Cloning and nucleotide sequence of the gene for protein X from Saccharomyces cerevisiae.

The gene encoding the protein X component of the pyruvate dehydrogenase complex from Saccharomyces cerevisiae has been cloned and sequenced. A 487-base fragment of yeast genomic DNA encoding the amino-terminal region of protein X was amplified by the polymerase chain reaction using synthetic oligonucleotide primers based on amino-terminal and internal amino acid sequences. This DNA fragment was used as a probe to select two genomic DNA restriction fragments, which were cloned and sequenced. A 2.1-kilobase insert contains the complete sequence of the protein X gene. This insert has an open reading frame of 1230 nucleotides encoding a presequence of 30 amino acid residues and a mature protein of 380 amino acid residues (Mr, 42,052). Hybridization analysis showed that there is a single copy of the protein X gene and that the size of the mRNA is approximately 1.5 kilobases. Comparison of the deduced amino acid sequences of yeast protein X and dihydrolipoamide acetyltransferase indicates that the two proteins evolved from a common ancestor. The amino-terminal part of protein X (residues 1-195) resembles the acetyltransferase, but the remainder is quite different. There is strong homology between protein X and the acetyltransferase in the amino-terminal region (residues 1-84) that corresponds to the putative lipoyl domain. Protein X lacks the highly conserved sequence His-Xaa-Xaa-Xaa-Asp-Gly near the carboxyl terminus, which is thought to be part of the active site of all dihydrolipoamide acyltransferases.     

Common methionine-tryptic peptides near the amino-terminal end of primate papovavirus tumor antigens

The tumor antigens directed by human papovaviruses BK and JC and the monkey papovavirus simian virus 40 have two methionine-containing tryptic peptides in common. These peptides are constituents of the small forms of papovavirus tumor antigen (17,000 daltons) which are present in lytically infected and transformed cells and which are believed to share some amino acid sequences with the amino-terminal portion of the larger tumor antigen species (97,000 daltons). In addition to the two peptides, which are present in all three papovavirus tumor antigens, the larger forms of the tumor antigens specified by simian virus 40 and BK virus share four other methionine-containing tryptic peptides, two of which are also present in the smaller (17,000 daltons) species of antigen. The occurrence of common peptides at the amino-terminal portion of tumor antigens of primate papovaviruses suggests that these conserved regions may play a fundamental role in the function of these proteins and in the propagation of these viruses in nature. The tryptic peptides of the small forms of papovavirus tumor antigen were examined and compared to those present in the large species. Out of a total of nine and ten methionine-containing peptides in the 17,000-dalton tumor antigens of simian virus 40 and BK virus, seven and nine peptides, respectively, are constituents of the corresponding larger (97,000 daltons) forms of the antigen.     

Complete nucleotide sequence of the neuraminidase gene of influenza B virus.

The complete nucleotide sequence of the neuraminidase gene of influenza virus B/Lee/40 was derived from a cloned cDNA copy of virion RNA segment 6 and its corresponding mRNA. The RNA segment contains 1,557 virus-specific nucleotides, and the protein encoded by the longest open reading frame has a total of 466 amino acids with a molecular weight of 51,721. As is the case with the influenza A virus neuraminidases, the deduced amino acid sequence of the influenza B protein includes a single hydrophobic region near the amino terminus which would be capable of spanning the lipid bilayer of the viral or cell membrane. There are four potential glycosylation sites in the protein, two of which are near the amino-terminal hydrophobic region. Comparisons of the nucleotide and amino acid sequences with those of influenza A virus neuraminidases revealed seven regions of extensive homology within the central portion of the molecules, including 12 conserved cysteine residues. Five other cysteine residues in the terminal portions were also conserved.     

Some sequence similarities among cloned mouse DNA segments that code for lambda and kappa light chains of immunoglobulins.

A comparison between the cloned mouse DNA segments that were found to code for the lambda and kappa light chains of immunoglobulins established that there were seven short nucleotide sequences, two of which matched 6 out of 7, two 7 out of 8, two 8 out of 9, and one 9 out of 10 bases; these sequences were located either at homologous amino acid positions or at positions displaced by four amino acids or less. They all occurred in the framework regions (FRs), five next to the complementarity-determining regions (CDRs). Three of these were unique and did not occur elsewhere in the immunoglobulin nucleotides sequenced thus far or in DNA's of phage phi X174, phage G4, or simian virus 40. Five could serve as sites of joining by recombination or insertion of CDR to FR segments, and the invariant tryptophan that is the first residue of the second FR might serve as a sixth. These sites are consistent with the mini-gene or insertional hypotheses for the generation of antibody diversity but could also serve as points of recognition for a mutator enzyme or could serve to limit somatic mutation to the CDRs.     

Analysis of temperature-sensitive mutations in the simian virus 40 gene encoding virion protein 1.

Temperature-sensitive (ts) assembly mutants of the tumorigenic virus simian virus 40 (SV40) fail to follow the normal pathway of virion morphogenesis at 40 degrees C. The mutations were previously mapped to the gene coding for the major virion protein VP1 and fall into three groups: tsB, tsBC, and tsC. We have determined the tsB/C mutations by DNA sequence analysis and deduced the corresponding amino acid substitutions. We find that the mutations are global and span 68% of the VP1 gene. They result predominantly in single amino acid substitutions. The B mutations are localized between nucleotides 1667 and 2091, spanning the VP1 amino acid residues 54-195. With the exception of one mutation in tsC260, the C group mutations occur between the nucleotides 2141 and 2262, spanning VP1 residues 212-252. The tsBC substitutions are not localized within a distinct region. We present a model for the VP1 structure. The model correlates the distribution of ts assembly mutations in the SV40 VP1 gene with the VP1 functional domains, deduced form the phenotypes exhibited by the assembly mutants, and the VP1 structural domains, deduced recently from the cryoelectron microscopic studies of the SV40 virions. We summarize the behavior of the SV40 ts mutants and discuss the possible relationship between the ts phenotype and amino acid substitutions.     

Isolation and characterization of a cDNA coding for human factor IX.

A cDNA library prepared from human liver has been screened for factor IX (Christmas factor), a clotting factor that participates in the middle phase of blood coagulation. The library was screened with a single-stranded DNA prepared from enriched mRNA for baboon factor IX and a synthetic oligonucleotide mixture. A plasmid was identified that contained a cDNA insert of 1,466 base pairs coding for human factor IX. The insert is flanked by G-C tails of 11 and 18 base pairs at the 5' and 3' ends, respectively. It also included 138 base pairs that code for an amino-terminal leader sequence, 1,248 base pairs that code for the mature protein, a stop codon, and 48 base pairs of noncoding sequence at the 3' end. The leader sequence contains 46 amino acid residues, and it is proposed that this sequence includes both a signal sequence and a pro sequence for the mature protein that circulates in plasma. The 1,248 base pairs code for a polypeptide chain composed of 416 amino acids. The amino-terminal region for this protein contains 12 glutamic acid residues that are converted to gamma-carboxyglutamic acid in the mature protein. These glutamic acid residues are coded for by both GAA and GAG. The arginyl peptide bonds that are cleaved in the conversion of human factor IX to factor IXa by factor XIa were identified as Arg145-Ala146 and Arg180-Val181. The cleavage of these two internal peptide bonds results in the formation of an activation peptide (35 amino acids) and factor IXa, a serine protease composed of a light chain (145 amino acids) and a heavy chain (236 amino acids), and these two chains are held together by a disulfide bond(s). The active site residues including histidine, aspartate, and serine are located in the heavy chain at positions 221, 270, and 366, respectively. These amino acids are homologous with His57, Asp102, and Ser195 in the active site of chymotrypsin. Two potential carbohydrate binding sites (Asn-X-Thr) were identified in the activation peptide, and these were located at Asn157 and Asn167. The homology in the amino acid sequence between human and bovine factor IX was found to be 83%.     

Characterization of an almost full-length cDNA coding for human blood coagulation factor X.

A human liver cDNA library was screened by colony hybridization with a bovine factor X cDNA probe. Three of the positive plasmids contained overlapping DNA that coded for most of human factor X mRNA. DNA sequence analysis of these three clones allowed the prediction of the complete amino acid sequence of plasma factor X. From these studies, we predict that human factor X is synthesized as a single polypeptide chain precursor in which the light and heavy chains of plasma factor X are linked by the tripeptide Arg-Lys-Arg. The cDNA sequence also predicts that human factor X is synthesized as a preproprotein having an amino-terminal leader peptide of at least 28 amino acid residues. A comparison of the amino acid sequences of human and bovine factor X shows high sequence identity around the calcium-binding regions and catalytic regions but low sequence identity around the nonfunctional regions.     

Oncogenicity of simian virus 40 deletion mutants that induce altered 17-kilodalton t-proteins.

Plaque-purified viable simian virus 40 deletion mutants containing deletions between map positions 0.54 and 0.59 induced tumors in 21--92% of LSH hamsters inoculated during the first 24 hr of life. HinfI restriction endonuclease digestion patterns of the genomes of virions rescued from the tumor cells and the distribution of simian virus 40 early proteins in these cells associated tumor induction with the inoculated mutants. These results imply that the DNA sequences comprising that portion of the early simian virus 40 genome between map positions 0.54 and 0.59 are not essential for simian virus 40 oncogenicity.     

The alpha and beta chains of human platelet glycoprotein Ib are both transmembrane proteins containing a leucine-rich amino acid sequence.

The primary structure of the beta chain of human glycoprotein Ib (GPIb), the platelet receptor for von Willebrand factor, has been established by a combination of cDNA cloning and amino acid sequence analysis. A lambda phage cDNA expression library prepared from human erythroleukemia cells (HEL cells) was screened with a radiolabeled affinity-purified rabbit polyclonal antibody to the beta chain of GPIb. Eighteen positive clones were isolated and plaque-purified and the nucleotide sequences of three were determined. The composite sequence spanned 968 nucleotides and included a 5' untranslated region of 22 nucleotides, an open reading frame of 618 nucleotides encoding a signal peptide of 28 amino acids and a mature protein of 181 amino acids, a stop codon, and a 3' noncoding region of 307 nucleotides. The 3' noncoding sequence also contained a polyadenylylation signal (AATAAA) 14 nucleotides upstream from the poly(A) tail of 18 nucleotides. Edman degradation of the intact beta chain and of peptides produced by chemical cleavage yielded amino acid sequences spanning 76 residues that were identical to those predicted from the cDNA. The amino-terminal region of the beta chain contains a leucine-rich sequence of 24 amino acids that is similar to a sequence that occurs as seven tandem repeats in the alpha chain of GPIb and nine tandem repeats in leucine-rich alpha 2-glycoprotein. The leucine-rich sequence in the beta chain of GPIb is flanked on both sides by amino acid sequences that are similar to those flanking the leucine-rich tandem repeats of the alpha chain of GPIb and leucine-rich alpha 2-glycoprotein. The amino-terminal region of the beta chain of GPIb is followed by a transmembrane segment of 25 amino acids and an intracellular segment of 34 amino acids at the carboxyl terminus of the protein. The intracellular segment contains an unpaired cysteine and two potential sites for phosphorylation by cAMP-dependent protein kinase.     

Alcohol dehydrogenase gene of Drosophila melanogaster: relationship of intervening sequences to functional domains in the protein

The gene that codes for Drosophila alcohol dehydrogenase (ADH; alcohol:NAD+ oxidoreductase EC 1.1.1.1) was identified in a bacteriophage lambda library of genomic Drosophila DNA by using ADH cDNA cloned DNA as a probe. The DNA sequence of the protein encoding region was shown to be in agreement with the amino acid sequence of the ADH. Two intervening DNA sequences (introns) were identified within the protein encoding region: one was 65 nucleotides and located between the codons for amino acid residues 32 and 33, and one was 70 nucleotides and located between the codons for amino acid residues 167 and 168. Both contained the 5' G-T and 3' A-G dinucleotides characteristic of intron boundaries of eukaryotic genes. On the basis of secondary structure predictions, the first 140 amino acid residues of Drosophila ADH are in an alternating beta-sheet/alpha-helix arrangement which is characteristic of the coenzyme binding domain of dehydrogenases. The smaller of the two introns interrupts the domain predicted to bind the adenine portion of the coenzyme.     

Position 22 of the V3 loop is associated with co-receptor usage and disease progression in HIV-1 subtype B isolates

Our goal in this study was to analyze position 22 of the V3 loop associated with co-receptor usage and disease progression in human immunodeficiency virus type 1 (HIV-1) subtype B infection. Bioinformatics approaches were used to compare the amino acid sequence and secondary structure of the V3 loop of the CCR5-tropic virus and CXCR4-tropic virus in HIV-1 subtype B. HIV-1 subtype B V3 amino acid sequence files in the FASTA format were collected from the HIV Sequence Database. The amino acid sequences of different tropism were multiple-aligned with CLUSTAL W program, and the frequencies of the amino acids at each position of the V3 loop sequences of two groups were calculated and sorted in descending order. The secondary structure of the consensus V3 amino acid sequences from CCR5-tropic and CXCR4-tropic viruses were predicted with the APSSP2 method. The amino acids at positions 11, 22, and 25 of V3 were different between the CCR5-tropic virus and CXCR4-tropic virus. The consensus amino acid frequencies were found to be 71.9% S, 66.7% A, and 56.0% D for the CCR5-tropic virus and 50.0% R, 57.1% T, and 26.2% Q for the CXCR4- tropic virus at positions 11, 22, and 25, respectively. There was a strong association between the identity of the residues at position 11, 22, and 25 of the V3 loop amino acid sequence and CD4+ T cell counts of different patients. The change of the residue at position 22 in the R5-tropic or X4-tropic viruses is expected to likely change the secondary structure to be similar to the X4-tropic or R5-tropic viruses. Our study indicates that position 22 of the V3 loop amino acid sequence is significantly associated with viral tropism and disease progression in HIV-1 subtype B.     

Comparison of Vif sequences from diverse geographical isolates of HIV type 1 and SIV(cpz) identifies substitutions common to subtype C isolates and extensive variation in a proposed nuclear transport inhibition signal

We compared the Vif sequences from more than 100 group M and O strains of HIV-1 isolated from diverse geographical regions and various subtypes, in order to identify regions of high variability and those amino acid residues that were highly conserved or invariant. Our analysis found that there were 10 highly conserved domains with additional invariant residues located throughout the protein. Our analysis revealed that in the highly conserved amino-terminal domain, all subtype C isolates examined had a methionine-to-leucine substitution at position 8 and most subtype C isolates had an arginine-to-lysine substitution at position 17 of the protein. Our analysis revealed that the MAP kinase phosphorylation sites, and the cysteine residues at positions 114 and 133, were conserved in Vif sequences from group M, group O, and SIV cpz isolates. Our analysis also shows that the RKKR motif at positions 90--93, proposed as a nuclear transport inhibition signal (NTIS), was conserved neither in different geographical group M and O HIV-1 isolates nor in SIVcpz.     

Homologous recombination between a defective virus and a chromosomal sequence in mammalian cells.

Replacement of the early region of simian virus 40 results in virus that cannot replicate in a normal host, CV-1 cells, but can replicate in COS cells, a derivative of CV-1 cells that constitutively express simian virus 40 tumor antigen (T antigen). However, passage of such an early replacement simian virus 40 mutant in COS cells results in the emergence of virus that can propagate in CV-1 cells. Analysis of this virus revealed that the mutant rescued the integrated T-antigen gene from the COS cell genome. Comparison of the sequence of the recovered virus with that of the viral DNA resident in COS cells (strain 776) and the mutant used in our studies (derived from strain 777) proves that the mutant virus acquired the T-antigen gene from the COS cell chromosome via homologous recombination. Most probably this process was mediated by a direct genetic exchange.