Molecular cloning of covalently closed circular DNA of bovine leukemia virus

The two species of covalently closed circular DNA molecules of bovine leukemia virus were cloned in the lambda phage vector lambda gtWES X lambda B. Of the nine independent recombinant lambda-bovine leukemia virus clones that were analyzed, three were derived from the small and six were derived from the large circular molecules carrying, respectively, one and two copies of the long terminal repeat sequences. Comprehensive restriction endonuclease mapping of the unintegrated bovine leukemia virus and the cloned DNA molecules showed that eight of the nine clones carried viral information without any detectable deletions or insertions of more than ca. 50 base pairs. One of the nine clones, which carries a retroviral insert with one copy of the long terminal repeat, had a deletion of ca. 150 base pairs.     

The 3'' region of bovine leukemia virus genome encodes a trans-activator protein.

The genome of bovine leukemia virus (BLV) contains several overlapping, long open reading frames 3' to the envelope gene. Experiments presented here show that the cDNA encompassing the X region open reading frames encodes a trans-activator function capable of increasing the level of gene expression directed by the BLV long terminal repeat sequences. This study provides further evidence of the structural and functional similarities of the bovine leukemia virus and the human T lymphotropic viruses, HTLV-I and HTLV-II.     

Nucleotide sequence analysis of the long terminal repeat of avian myeloblastosis virus and adjacent host sequences.

The nucleotide sequence of the integrated avian myeloblastosis virus long terminal repeat has been determined. The sequence is 385 base pairs long and is present at both ends of the viral DNA. The cell-virus junctions at each end consist of a 6-base-pair direct repeat of cell DNA next to the inverted repeat of viral DNA. The long terminal repeat also contains promoter-like sequences, an mRNA capping site, and polyadenylation signals. Several features of this long terminal repeat suggest a structural and functional similarity with sequences of transposable and other genetic elements. Comparison of these sequences with long terminal repeats of other avian retroviruses indicates that there is a great variation in the 3' unique sequence (U3), whereas the 5' specific sequences (U5) and the R region are highly conserved.     

Structural diversity and nuclear protein binding sites in the long terminal repeats of feline leukemia virus.

The long terminal repeat U3 sequences were determined for multiple feline leukemia virus proviruses isolated from naturally occurring T-cell tumors. Heterogeneity was evident, even among proviruses cloned from individual tumors. Proviruses with one, two, or three repeats of the long terminal repeat enhancer sequences coexisted in one tumor, while two proviruses with distinct direct repeats were found in another. The enhancer repeats are characteristic of retrovirus variants with accelerated leukemogenic potential and occur between -155 and -244 base pairs relative to the RNA cap site. The termini of the repeats occur at or near sequence features which have been recognized at other retrovirus recombinational junctions. In vitro footprint analysis of the feline leukemia virus enhancer revealed three major nuclear protein binding sites, located at consensus sequences for the simian virus 40 core enhancer, the nuclear factor 1 binding site, and an indirect repeat which is homologous to the PEA2 binding site in the polyomavirus enhancer. Only the simian virus 40 core enhancer sequence is present in all of the enhancer repeats. Cell type differences in binding activities to the three motifs may underlie the selective process which leads to outgrowth of viruses with specific sequence duplications.     

Generation of a uniform 3'' end RNA of murine leukemia virus.

Using the S1 nuclease mapping technique, we demonstrated that the majority of Moloney murine leukemia RNA molecules, isolated either from the nucleus or cytoplasm of infected mouse cells, share a uniform 3' end located at the border of the R and U-5 regions of the long terminal repeat. When the long terminal repeat sequences were inserted in the pSV plasmid downstream of the simian virus 40 late promoter, the 3' end of the viral RNA was also generated close to the R region of the long terminal repeat. These results demonstrate that the long terminal repeat signals the generation of an authentic 3' end when situated downstream of an actively transcribed region.     

Structure and expression of mouse VL30 genes.

DNA sequencing and blot hybridization analyses have been used to study the structure of a mouse VL30 gene and the molecular nature of VL30-related RNA which is induced upon the stimulation of cultured AKR mouse embryo cells with defined peptide growth factors. An integrated mouse VL30 gene was found to contain identical 601-base-pair long terminal repeats (LTRs) which were themselves terminated in short inverted repeats. The entire VL30 gene was flanked by a 4-base-pair direct repeat of cellular DNA. Thus, VL30 genes are structurally analogous to integrated forms of retrovirus proviruses and certain other classes of mobile genetic elements. The LTR sequence was found to contain putative promoter and polyadenylation signals and generally exhibited little sequence homology to murine leukemia virus proviral LTRs. Certain short regions of sequence conservation, however, were evident, including the inverted terminal repeat, LTR-adjacent regions corresponding to origins of murine leukemia virus proviral DNA synthesis, and a 36-base-pair direct repeat bearing homology to the 72-base-pair direct repeat (enhancer sequence) of the murine leukemia virus-related Moloney sarcoma virus. Upon mitogenic stimulation of quiescent cells with epidermal growth factor and insulin, a major 5.5-kilobase VL30-specific RNA complementary to both LTR and non-LTR sequences was rapidly induced. We conclude that a complete VL30 gene(s) is highly regulated by peptide growth factor binding to specific membrane receptors in these cells.     

Molecular Cloning and Analysis of the Endogenous Retrovirus Chemically Induced from RFM/Un Mouse Cell Cultures

We molecularly cloned and analyzed an N-tropic ecotropic retrovirus induced with iododeoxyuridine from RFM/Un mouse cell cultures. Based on the restriction map, the RFM/Un virus appears to be indistinguishable from other induced N-tropic retroviruses. A nucleotide sequence analysis of the long terminal repeat of an infectious clone revealed structural features characteristic of murine type C retrovirus long terminal repeats. The U3 region of the RFM/Un virus long terminal repeat, however, contained no short sequence duplication or insertion found in other murine leukemia virus isolates.     

Discrete regions of sequence homology between cloned rodent VL30 genetic elements and AKV-related MuLV provirus genomes

Southern blot analyses using reduced stringency hybridization conditions have been employed to search for sequence homologies between rodent VL30 genes and murine leukemia virus (MuLV) proviruses. These constitute two classes of transposon-like elements previously believed to be genetically unrelated. Our results demonstrate that cloned representatives of both ecotropic and xenotropic-like proviruses share discrete regions of sequence homology with VL30 genes of both rat and mouse origin. These regions of homology exist in both 3' and 5' halves of the MuLV genome but do not include extensive portions of the long terminal repeat (LTR) or a 0.4 Kbp segment of the env gene specific for recently acquired ecotropic-type MuLV proviruses. DNA sequencing, however, revealed that the short inverted terminal repeat sequence of MuLV proviral LTRs is almost perfectly conserved at the terminus of an integrated mouse VL30 gene. These results suggest that recombination events with rodent VL30-type sequences occurred during early MuLV evolution. The strong conservation of the inverted terminal repeat sequence may reflect a common integration mechanism for VL30 elements and MuLV proviruses.     

Envelope and long terminal repeat sequences of a cloned infectious NZB xenotropic murine leukemia virus

An infectious NZB xenotropic murine leukemia virus (MuLV) provirus (NZB was molecularly cloned from the Hirt supernatant of NZB-IU-6-infected mink cells, and the nucleotide sequence of its env gene and long terminal repeat (LTR) was determined. The partial nucleotide sequence previously reported for the env gene of NFS-Th-1 xenotropic proviral DNA (Repaske, et al., J. Virol. 46:204-211, 1983) is identical to that of the infectious NZB xenotropic MuLV DNA reported here. Alignment of nucleotide or deduced amino acid sequences, or both, of xenotropic, mink cell focus-forming, and ecotropic MuLV proviral DNAs in the env region identified sequence differences among the three host range classes of C-type MuLVs. Major differences were confined to the 5' half of env; a high degree of homology was found among the three classes of MuLVs in the 3' half of env. Alignment of the nucleotide sequence of the LTR of NZB xenotropic MuLV with those of the LTRs of NFS-Th-1 xenotropic, mink cell focus-forming, and ecotropic MuLVs revealed extensive homology between the LTRs of xenotropic and MCF247 MuLVs. An inserted 6-base-pair repeat 5' to the TATA box was a unique feature of both NZB and NFS-Th-1 xenotropic LTRs.     

Sequence comparisons of the anemia- and polycythemia-inducing strains of Friend spleen focus-forming virus.

A nucleotide sequence analysis carried out on the envelope gene of the anemia-inducing strain of the Friend spleen focus-forming virus (F-SFFVA) reveals that its product has some unique features in common with previously described polycythemia-inducing strains of F-SFFV (F-SFFVP). (i) It contains an amino terminus that is highly related to the gp70 of mink cell focus-inducing viruses, (ii) it is a fusion protein containing the amino terminus of gp70 and the carboxy terminus of p15E, and (iii) it lacks the R-peptide normally found at the carboxy end of the p15E region. Although the envelope genes of F-SFFVA and F-SFFVP are quite similar overall, they do show sequence variation, particularly at the 3' end in the p15E-related region. These variations may contribute to previously observed differences in the response of F-SFFVP- and F-SFFVA-infected erythroid cells to regulatory hormone or to differences in the way the envelope glycoproteins are processed. The long terminal repeat regions of F-SFFVA and the Lilly-Steeves strain of F-SFFVP were also sequenced and compared with each other and with a previously published sequence of another F-SFFVP long terminal repeat. The sequences were found to be reasonably similar to each other but different from their ecotropic parent, Friend murine leukemia virus, as a result of a deletion of one copy of the direct tandem repeat in the enhancer regions. The observation that all SFFVS have this common change in the long terminal repeat enhancer region raises the possibility that it is required for pathogenicity.     

Conservation of protein coding potential in the long terminal repeats of exogenous and endogenous mouse mammary tumor viruses

In vitro protein synthesis and DNA sequence analysis indicate that mouse mammary tumor virus differs from other well-characterized retroviruses in that the long terminal repeat region of the provirus has the capacity to encode proteins. Different exogenously transmitted mouse mammary tumor virus strains and endogenous proviral units conserved this open reading frame feature in the long terminal repeat despite a variation in nucleotide sequence. The proteins encoded by the different long terminal repeats were clearly related, but showed minor variations in size and tryptic peptide maps. In each case, the largest in vitro product had a molecular weight of about 36,000 to 37,000, suggesting that the open reading frame sequences must extend for approximately 1,000 nucleotides beginning at the extreme 5' end of the long terminal repeat. The fact that the reading frame was conserved among these viruses argues in favor of an in vivo function for the open reading frame protein.