Evolutionary relationships of the primate papovaviruses: base sequence homology among the genomes of simian virus 40, stump-tailed macaque virus, and SA12 virus.

Physical maps of the genomes of the two newly discovered primate papovaviruses, SA12 and stump-tailed macaque virus (STMV), were generated by restriction endonuclease analysis. The base sequence homologies among the genomes of SA12, stump-tailed macaque virus, and simian virus 40 (SV40) were studied by heteroduplex analysis. Heteroduplexes between SA12 and SV40 DNAs and stump-tailed macaque virus and SV40 DNAs were constructed and mounted for electron microscopy in various amounts of formamide to achieve a range of effective temperatures. At each effective temperature, the regions of duplex DNA in the heteroduplexes were measured and localized on the SV40 physical and functional maps. By analyzing the data from this study and rom our previous study (N. Newell, C. J. Lai, G. Khoury, and T. J. Kelly Jr., J. Virol. 25:193-201, 1978) on the base sequence homology between the genomes of BK virus and SV40, some general conclusions have been drawn concerning the evolutionary relationships among the genomes of the primate papovaviruses. The extent of homology among the viral genomes does not reflect the phylogenetic relationships of their hosts. At comparable effective temperatures Tm - 33 degrees C), the heteroduplexes between the DNAs of BK virus and SV40 contained the largest amount of duplex (about 90%). The heteroduplexes made between SA12 and SV40 DNAs were slightly less homologous, containing about 80% duplex. The heteroduplexes made between SV40 and stump-tailed macaque virus DNAs were only 20% duplex under the same conditions. When the various heteroduplexes were mounted for microscopy at effective temperatures greater than Tm - 33 degrees C, the fraction of the duplex DNA decreased in each case, indicating the existence of considerable base mismatching in the homologous regions. When specific coding or noncoding regions of the viral genomes were compared, the data indicated that the extent of sequence divergence differed markedly from one region to another. In all the heteroduplexes studied, there were two regions, located near the junctions between early and late regions on the SV40 map, which were essentially nonhomologous. All of the heteroduplexes studied showed significantly greater homology in the late region than in early region. Within the late region, the sequences coding for the major capsid polypeptide, VP1, were the most highly conserved.     

Comparative study of papovavirus DNA: BKV(MM), BKV(WT) and SV40.

Extensive physical mapping revealed that approximately 90% of the genomes of BKV(prototype, WT) and BKV (MM strain) are identical or closely related. Nucleotide sequences of the non-homologous regions and a large portion of the homologous regions have been determined for both genomes. The coding sequence of small t antigen of BKV(MM) is 216 nucleotides shorter than that of BKV(WT), even though no differences in biological function of the t antigen was observed. Both genomes contain three similar sets of 44-61 base-pair repeated sequences. However, the DNA sequence of the tandem repeats is totally different between BKV (human cell as host) and SV40 (monkey cell as host). On the other hand, the region between the N-terminus of the T antigen genes and the origin of replication is dominated by a similar set of palindromic sequences in BKV and SV40 DNA. There is also extensive homology between the regions which code for proteins in BKV and SV40, suggesting a close evolutionary relationship.     

Cloning and sequencing of viral integration site in human fibroblasts immortalized by simian virus 40.

We have analyzed cellular DNA sequences at the viral genome integration site in a human fibroblast cell line VA13 immortalized by simian virus 40 (SV40). The computer analysis of the junctional cellular DNA sequences did not show any homology to the DNA sequences previously reported. This suggests that immortalization by SV40 was not induced by the destruction of any known oncogene or anti-oncogene at the integration site. We did not find the precise substantial sequence homology at the junctional site between the cellular DNA and SV40 DNA, indicating that the recombination mechanism involved does not require precise sequence homology and therefore, SV40 genome was probably not integrated by homologous recombination. Short direct and inverted repeats of 5 to 29 nucleotides were found in the junctional cellular and SV40 DNA. Cellular DNA abutting SV40 DNA was found by the Northern blot analysis to be expressed in diploid human fibroblasts and SV40-transformed cells. The nature of this RNA is now under study.     

Nucleotide sequence and genetic organization of the polyoma late region: features common to the polyoma early region and SV40.

The nucleotide sequence of the late region of the polyoma genome has been determined. It consists of 2366 bp and encodes the virion capsid proteins VP1, VP2 and VP3. Extensive open reading frames identify the possible coding sequences of VP2 and VP3 toward the 5′ end of the late region, and of the major capsid protein VP1 toward the 3′ end of the late region. The 5′ end of the sequence encoding VP1 overlaps the 3′ VP2/VP3 region by 29 nucleotides and is in a different reading frame. The predicted amino acid sequences for all three known capsid proteins show extensive homology with the analogous capsid proteins of SV40 throughout most of their length. The VP2/VP3 amino acid homology between the two viruses is 34%, while the major capsid protein VP1 is much more highly conserved, showing 54% homology. These homologies together with the extent of open reading frames help to define the extent of the coding sequences. The VP2 initiator begins at position 269 and the coding region extends to the first termination codon beginning at 1226. The predicted size of VP2 is 35,007 daltons. A probable VP3 initiator is within the VP2 coding sequence at position 614 and is in the same frame as VP2. This coding sequence can also utilize the terminator at position 1226, and the predicted size of the VP3 translation product is 22,979 daltons. The VP1 coding region begins at position 1197 and continues in a frame different from that of VP2/ VP3 to a termination point at 2349. The molecular weight of VP1 is predicted to be 42,834 daltons. The 5′ untranslated region contains sequences that resemble a potential ribosomal binding site and a possible mRNA capping sequence similar to those found in other eucaryotic systems. There is also a sequence (5′-TCAAGTAAGTGA-3′) almost identical to one found in two regions containing potential splice sites in the early region of polyoma. The 5′ untranslated region does not show the extensive repeated sequences found in the similar region of SV40. The 3′ untranslated region contains the sequence 5′-AATAAA-3′, thought to represent a polyadenylation signal. As in the early region of polyoma, the extensive nucleotide and deduced amino acid homology with SV40 indicate a close evolutionary relationship between the two viruses, and help to identify regions of common and important structure-function relationships.     

Occurrence of reiterated sequences in an untranslated region of Simian virus 40 DNA determined by nucleotide sequence analysis.

An earlier report (Subramanian, Dhar, and Weissman, 1977c) presented the nucleotide sequence of Eco RII-G fragment of SV40 DNA, which contains the origin of DNA replication. The nucleotide sequence of Eco RII-N fragment located next to Eco RII-G on the physical map of SV40 DNA is presented in this report. Eco RII-N is found to be a tandem duplication of the last 55 nucleotides of Eco RII-G. This tandem repeat is immediately preceded by two other reiterated sequences occurring within Eco RII-G, one of them being a tandem repeat of 21 nucleotides and the other a nontandem repeat of 10 nucleotides. These repetitive sequences occur in close proximity to the origin of DNA replication which is known to contain other specialized sequences such as a few palindromes (one of which is 27 long and possesses a perfect 2-fold axis of symmetry), one "true" palindrome, and a long A/T-rich cluster. The repeats (and the replication origin) occur within an untranslated region of SV40 DNA flanked by (the few) structural genes coding for the "late" proteins on the one side and that (those) coding for the "early" protein(s) on the other side. The reiterated sequences are comparable in some respects to repetitive sequences occurring in eucaryotic DNAs. Possible biological functions of the repeats are discussed.     

Human papillomavirus 1a complete DNA sequence: a novel type of genome organization among papovaviridae

The complete nucleotide sequence of human papillomavirus type 1a (7811 nucleotides) has been established. The overall organization of the viral genome is different from that of other related papovaviruses (SV40, BKV, polyoma). Firstly, genetic information seems to be coded by one strand. Secondly, no significant homology is found with SV40 or polyoma coding sequence for either DNA or deducted protein sequences. The relatedness of human and bovine papillomaviruses is revealed by a conserved coding sequence in the two species. Two regions can be defined on the viral genome: the putative early region contains two large open reading frames of 1446 and 966 nucleotides, together with several split ones, and corresponds to the transforming part of the bovine papillomavirus type 1 genome, and the remaining sequences, which include two open reading frames likely to encode structural polypeptide(s). The DNA sequence is analysed and putative signals for regulation of gene expression, and homologies with the Alu family of human ubiquitous repeats and the SV40 72-bp repeat are outlines.