Nucleotide sequence of the simian virus 40 HindII + III restriction fragment A (second part of the T antigen gene)

The nucleotide sequence of the second part of the simian virus 40 DNA HindII + III restriction fragment A is presented. The sequence extends from map position 0.533 to 0.424 and together with the first part of Hind-A [Volckaert et al. Proc. Natl Acad. Sci. U.S.A. 75, 2160--2164 (1978)] completes the total hind-A sequence, comprising 1169 base pairs. The second half of Hind-A includes the region corresponding to the second splicing boundary common to small tumor antigen (small-t) and large tumor antigen (large-T) mRNA and it contains coding information for an internal portion of large-T antigen. Two similar secondary structures of reasonable thermodynamic stability can be proposed for the nucleotide sequence of the pre-mRNA corresponding to the region reported here. Their possible relevance to the splicing of the SV40 early mRNAs is discussed. The deduced amino acid sequence is 188 residues long and contains a Lys-Lys-Lys-Arg-Lys-stretch which may be involved in the DNA binding capacity of large-T. A presumptive phosphorylation site is also present.     

The sequence of the 3'' non-coding region of the hexon mRNA discloses a novel adenovirus gene.

We report the sequence of a 1164 nucleotide long DNA segment, located between map positions 59.5 and 62.8 on the adenovirus type 2 genome. The sequence comprises the 701 nucleotides long 3' non-coding region of the hexon mRNA as well as several important processing signals. The sequence revealed unexpectedly that the 3' non-coding region of the hexon mRNA contains a 609 nucleotide long uninterrupted translational reading frame following a potential initiator AUG. A late 14S mRNA, corresponding to the open reading frame, could be identified by S1 nuclease mapping and electronmicroscopy. The mRNA shares a poly(A) addition site with the hexon and pVI mRNAs, and carries a leader sequence which is related, and probably identical, to the tripartite leader, found in late adenovirus mRNAs. The junction between the leader and the body of this novel mRNA is located within the coding part of the hexon gene.     

Nucleotide sequence of the EcoRI D fragment of adenovirus 2 genome

The entire nucleotide sequence of the Ad. 2 EcoRI D fragment has been determined using the Maxam and Gilbert method. This sequence of 2678 bp contains informations relative to late mRNAs ending at position 78 and for which an AATAAA sequence corresponding to their 3' ends is found at residue number 833. Position of the PVIII mRNA is determined thus allowing deduction of the probable amino acid sequence of the PVIII protein. The position and the sequence of the first leader of early 3 mRNAs is determined as well as the sequence and position of the second early leader of region 3 mRNAs, which also correspond to the "y" leader of the fiber mRNA. Following the localization of an open reading frame in which an ATG could initiate protein synthesis it can be predicted that 3a, b, c mRNAs code for the 16K early protein and the probable amino acid sequence of this protein can be deduced. The CAGTTT sequence frequently present at the 5' end of a leader or of a mRNA body as well as the GGTGAG sequence which is found at the 3' end of several leaders were used to postulate the position of various early mRNAs of region 3 and to suggest the existence of an additional splicing event during the processing of mRNAs 3a, b and c. They were also used to predict the position of the additional "x" late leaders. The imbrication of information concerning (i) the family of late mRNAs ending at position 78, (ii) the position of the "x" leader and the "y" leader and (iii) the beginning of early region 3 is also depicted.     

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.     

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.     

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.     

Nucleotide sequence of the EcoRI E fragment of adenovirus 2 genome.

The entire nucleotide sequence of the Ad.2 EcoRI E fragment has been determined using the Maxam and Gilbert method. This sequence of 2222 bp, which maps between coordinate 83.4 and 89.7 contains information relative to the early 3 region and to the fiber gene. Altogether with fragment EcoRI D which has been recently sequenced, they cover the entire Early 3 region in which several mRNA were mapped. The aminoacid sequence of the 16K and 14K protein is deduced. The localization of the 14.5K mRNA directing the synthesis of the third E3 known protein is discussed, as well as the hypothetical existence of three other early 3 proteins, which would have a molecular weight of 11K. The initiator ATG triplet of the fiber protein has been found at coordinate 86.1, it is followed up to the end of the fragment by an open reading frame allowing deduction of 80% of the aminoacid sequence of this protein. Sequences known to be frequently present at the border of exon sequence were used to tentatively localize the additional "Z" late leader.     

Overlapping of the VP2-VP3 gene and the VP1 gene in the SV40 genome.

The nucleotide sequence of the SV40 Hind E fragment has been determined mainly by the partial chemical degradation procedure of Maxam and Gilbert (1977). The sequence of the strand with the same polarity as the late messenger RNA shows only one open reading frame for translation. Considering that VP3 corresponds to the carbosyl terminal part of VP2, and considering various evidence which indicates that the SV40 Hind E segment is part of the amino acid sequence of VP2-VP3. It continues clockwise in Hind K, where it terminates with a UAA signal. The latter is located 110 nucleotides beyond the initiation signal for the major structural protein VP1 (Fiers et al., 1975; Van de Voorde et al., 1976). Hence this small overlapping region of the genome codes for the synthesis of three different proteins in two different reading frames. The deduced amino acid sequence covers a major part of the vp3 poly peptide, and the amino acid composition is in good agreement with published values (Greenaway and Levine, 1973).     

Analysis of the human apolipoprotein B gene; complete structure of the B-74 region

In this paper we describe the nucleotide sequence of the B-74 region of human apolipoprotein B-100 mRNA. This region comprises the 3'-proximal three-quarters of the mRNA and contains 10,089 nucleotides (nt), 9786 of which are coding. Combining our data with the published sequence of the 5'-proximal one-quarter (i.e., the B-26 region [Protter et al., Proc. Natl. Acad. Sci. USA 83 (1986) 5678-5682] assigns 14,059 nt to the apoB-100 mRNA. The coding sequence spans 13,548 nt or 4516 amino acids (leader peptide excluded). The B-74 part of the apoB gene is built up of five exons separated by small introns, and is dominated by an unusually large exon of 7.5 kb. The derivation of two (EcoRI and XbaI) restriction fragment length polymorphisms occurring in the coding region is discussed.     

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.     

Polyoma virus DNA: Sequence from the late region that specifies the leader sequence for late mRNA and codes for VP2, VP3, and the N-terminus of VP1.

The DNA sequence of part of the late region of the polyoma virus genome is presented. This sequence of 1,348 nucleotide pairs encompasses the leader region for late mRNA and the coding sequence for the two minor capsid proteins VP2 and VP3. The coding sequence for the N-terminus of the major capsid protein overlaps the C-terminus of VP2/VP3 by 32 nucleotide pairs. From the DNA sequence the sizes and sequences of VP2 and VP3 could be predicted. Potential splicing signals for the processing of late mRNA's could be identified. Comparisons are made between the sequence of polyoma virus DNA and corresponding regions of simian virus 40 DNA.     

Cloning and nucleotide sequence of ovine prolactin cDNA

A cDNA expression library was constructed in the lambda gt 11 phage vector using ovine (o) pituitary mRNA. The clone, pOP1, carrying a 934-bp insert contains an open reading frame beginning with the first nucleotide (nt) and ending with the stop codon TAA at nt position 781. Two potential translation start codons (ATGs) are present in the 5' region of this cDNA. Translation initiation could occur at the 5' proximal ATG at nt position 61. The nucleotide sequence around this ATG (TCCATGG), resembles the optimum sequence context for translation initiation by the eukaryotic ribosomes, as defined by mutational analysis [Kozak, Cell 44 (1986) 283-292)], with its substitution of the A at -3 of the consensus sequence by a T residue in this clone. Translation initiated at this codon could potentially code for the entire pre-prolactin (pre-PRL) molecule. The 3'-untranslated region is 154 nt long and contains a polyadenylation signal AATAAA. The deduced amino acid sequence agrees in totality with the published amino acid sequence of the mature hormone. The present study reports on the nucleotide sequence of o-PRL mRNA and the deduced amino acid sequence in the signal peptide of the hormone.     

Nucleotide sequence of the Hind-C fragment of simian virus 40 DNA. Comparison of the 5'-untranslated region of wild-type virus and of some deletion Mutants.

We report here the nucleotide sequence of the wild-type simian virus 40 (strain 776) restriction fragment Hind-C-P1 DNA and of the homologous region of various mutant DNAs which lack part of this fragment. During this work, we detected between EcoRII fragments N and G an additional, 17-base-pair EcoRII fragment, fragment P, which had previously been overlooked. Also, an additional dTpdG dinucleotide at residues L 339--340 was observed by sequence analysis of the DNA minus (E) strand; the presence of this dinucleotide was masked on sequencing patterns of the plus strand due to the persistence (during gel electrophoresis) of some secondary structures in the strand's 5'-terminal region. These nucleotide additions raise the total length of SV40 DNA to 5243 base pairs. The longest tandemly repeated segment in SV40 DNA now extends over 72 base pairs. SV40 deletion mutants dl 893 and dl 894 and SV40 strains Rh 911 and 1801 all lack an identical 72-base-pair-long DNA segment in the Hind-C region. This deletion corresponds precisely to one of the two aforementioned large tandemly repeated sequences. Mutant dl 895 lacks 66 base pairs, 63 of which are part of the former repetition. All these mutants, except dl 895, very probably were generated by an intramolecular, homologous recombination event. The 40-base-pair deletion in mutant dl 1811 includes the major capping site of SV40 late RNA. dl 1812 lacks only three base pairs, which are part of the overlapping HhaI and HpaII restriction sites at position 0.725--0.726.