Retroviruses as mutagens: Insertion and excision of a nontransforming provirus alter expression of a resident transforming provirus

Integration of retroviral DNA appears to occur randomly in host genomes, suggesting that retroviruses can act as insertion mutagens. We have confirmed this prediction by showing that the nontransforming retrovirus, Moloney murine leukemia virus (M-MuLV), can insert its provirus within the selectable target provided by a single provirus in a clonal rat cell line (B31) transformed by Rous sarcoma virus (RSV). Analysis of over 60 morphological revertants of M-MuLV-superinfected B31 cells revealed two lines with inserts of M-MuLV proviruses within the RSV provirus but outside the transforming gene of RSV (src), at sites 0.6 and 4.0 kb from the 5′ end. The inserts did not inactivate initiation of RSV RNA synthesis but did affect elongation or processing, or both, generating species with the 5′ end of RSV RNA linked to sequences that presumably derive from the inserted M-MuLV DNA. In one mutant line, most of the insert was excised at low frequency, apparently by homologous recombination between repeated sequences at the ends of M-MuLV DNA. After excision, RSV src mRNA was present in normal amounts, and the cells resumed a transformed appearance. In at least four independent lines, large portions of the left end of the RSV provirus (from 1 to 6 kb) and variable amounts of leftward flanking cellular DNA (from 0.5 to 10–15 kb or more) were deleted, without nearby insertions of M-MuLV DNA. The deletions removed the putative promoter for synthesis of RSV RNA; in the two cases examined, no RSV RNA was detected. These deletions may represent a second mutational effect of the superinfection by M-MuLV.     

Two distinct sequence elements mediate retroviral gene expression in embryonal carcinoma cells.

Moloney murine leukemia virus (M-MuLV) and M-MuLV-derived retroviral vectors are not expressed in early mouse embryos or in embryonal carcinoma cells. M-MuLV-derived mutants or M-MuLV-related variants which transduce the neomycin phosphotransferase gene can, however, induce drug resistance in embryonal carcinoma cells with high efficiency. In this study we investigated the sequences critical for retroviral gene expression in two different embryonal carcinoma cell lines, F9 and PCC4. We show that two synergistically acting sequence elements mediate expression in embryonal carcinoma cells. One of these is located within the U3 region of the viral long terminal repeat, and the second one is in the 5' untranslated region of the retrovirus. The latter element, characterized by a single point mutation, affects the level of stable RNA in infected cells, suggesting a regulatory mechanism similar to that of human immunodeficiency virus in human T cells.     

Evidence for a stem cell-specific repressor of Moloney murine leukemia virus expression in embryonal carcinoma cells.

A negative regulatory element (NRE) spanning the tRNA primer-binding site (PBS) of Moloney murine leukemia virus (M-MuLV) mediates repression of M-MuLV expression specifically in embryonal carcinoma (EC) cells. We precisely defined the element by base-pair mutagenesis to an 18-base-pair segment of the tRNA PBS and showed that the element also restricted expression when moved upstream of the long terminal repeat. A DNA-binding activity specific for the M-MuLV NRE was detected in vitro by using crude EC nuclear extracts in exonuclease III protection assays. Binding was strongly correlated with repression in EC cells. Mutations within the NRE that relieved repression disrupted binding activity. Also, nuclear extracts prepared from permissive, differentiated EC cell cultures showed reduced binding activity for the NRE. These results indicate the presence of a stem cell-specific repressor that extinguishes M-MuLV expression via the NRE at the tRNA PBS.     

Mutants and pseudorevertants of Moloney murine leukemia virus with alterations at the integration site

Soon after infection, retroviruses synthesize a DNA copy of the genomic RNA and insert that DNA into the cellular genome by recombination at inverted repeat sequences at the termini of the viral genome. We have generated mutations that alter one terminus of the genome of Moloney murine leukemia virus (M-MuLV). Some mutations did not prevent integration of the viral DNA even though the very terminal bases were disrupted. Other mutations had dramatic effects on the efficiency of infection; in these cases the formation of preintegrative DNA was normal but the establishment of the productive provirus was prevented. One of these defective mutants gave rise to a pseudorevertant which differed from the wild type but displayed normal infectivity. An unusual number of bases of viral DNA were removed during the integration reaction carried out by this virus.     

Determinants of retrovirus gene expression in embryonal carcinoma cells.

The expression of Moloney murine leukemia virus is restricted in embryonal carcinoma (EC) cells. To characterize specific mutations necessary for expression of retroviruses in EC cells, we analyzed the expression of retrovirus mutants and recombinants thereof in EC cell lines F9 and PCC4. DNA sequence comparison and functional studies allowed us to define three point mutations in the enhancer region of the viral mutants at positions -345, -326, and -166 and two point mutations within the 5'-untranslated region of the viral genome at positions +164 and +165 that were essential for retrovirus expression in EC cells. DNA fragments derived from either the wild type or mutant viruses were used to search for sequence-specific DNA-binding factors in nuclear extracts from undifferentiated PCC4 cells. A cellular factor was found to bind strongly to sequences within the enhancer region (-354 to -306) of wild-type viruses but only weakly to sequences derived from mutant viruses. This factor was named ECF-I (for EC cell factor I). Retroviral expression in EC cells correlates with decreased binding affinity for ECF-I.     

Precise identification of endogenous proviruses of NFS/N mice participating in recombination with moloney ecotropic murine leukemia virus (MuLV) to generate polytropic MuLVs

Polytropic murine leukemia viruses (MuLVs) are generated by recombination of ecotropic MuLVs with env genes of a family of endogenous proviruses in mice, resulting in viruses with an expanded host range and greater virulence. Inbred mouse strains contain numerous endogenous proviruses that are potential donors of the env gene sequences of polytropic MuLVs; however, the precise identification of those proviruses that participate in recombination has been elusive. Three different structural groups of proviruses in NFS/N mice have been described and different ecotropic MuLVs preferentially recombine with different groups of proviruses. In contrast to other ecotropic MuLVs such as Friend MuLV or Akv that recombine predominantly with a single group of proviruses, Moloney MuLV (M-MuLV) recombines with at least two distinct groups. In this study, we determined that only three endogenous proviruses, two of one group and one of another group, are major participants in recombination with M-MuLV. Furthermore, the distinction between the polytropic MuLVs generated by M-MuLV and other ecotropic MuLVs is the result of recombination with a single endogenous provirus. This provirus exhibits a frameshift mutation in the 3' region of the surface glycoprotein-encoding sequences that is excluded in recombinants with M-MuLV. The sites of recombination between the env genes of M-MuLV and endogenous proviruses were confined to a short region exhibiting maximum homology between the ecotropic and polytropic env sequences and maximum stability of predicted RNA secondary structure. These observations suggest a possible mechanism for the specificity of recombination observed for different ecotropic MuLVs.     

Independent mechanisms involved in suppression of the Moloney leukemia virus genome during differentiation of murine teratocarcinoma cells

Expression and DNA methylation of the Moloney murine leukemia virus (M-MuLV) genome were investigated in murine teratocarcinoma cells after virus infection. The newly acquired viral genome was devoid of methylation, yet its expression was repressed. The integrated viral genome in undifferentiated teratocarcinoma cells was methylated within 15 days after infection. Although 5-azacytidine decreased the level of DNA methylation, it did not activate M-MuLV in undifferentiated cells. Activation by 5-azacytidine occurred only in differentiated teratocarcinoma cells. Thus two independent mechanisms seem to regulate gene expression during the course of differentiation. The first mechanism operates in undifferentiated cells to block expression of M-MuLV and other exogeneously acquired viral genes, such as SV40 and polyoma virus, and does not depend on DNA methylation. The second mechanism relates only to differentiated cells and represses expression of genes in which DNA is methylated.     

Secondary structural features in the 70S RNAs of Moloney murine leukemia and Rous sarcoma viruses as observed by electron microscopy.

The secondary structural features in the 70S RNAs of the Prague strain of avian Rous sarcoma virus, subgroup A (PR-RSV-A), and Moloney murine leukemia virus (M-MuLV) were compared by electron microscopy. The PR-RSV-A genome contained two subunits joined by a linkage structure as in the genomes of M-MuLV and other mammalian retroviruses. In both viral genomes, a highly reproducible hairpin occurred at about 70 nucleotides from the 5' end of each subunit and contained 320 +/- 8 nucleotides. The stable point of linkage between the subunits in both viral genomes involved fewer than 50 nucleotides and occurred at 466 +/- 9 nucleotides from the 5' end. This places the linkage about 350 nucleotides further toward the 3' end of the subunit than the binding site of primer tRNA. Another structural feature common to both genomes was a loop in each subunit. In M-MuLV, the loop contained 3.9 +/- 0.10 kilobases (kb) and occurred at a distance of 2.2 +/- 0.05 kb from the 5' end. In PR-RSV-A, the loop was smaller (2.3 +/- 0.10 kb) and further (3.3 +/- 0.10 kb) from the 5' end. When M-MuLV RNA was heated to 70, 85, or 90 degrees C and cooled, the hairpin consistently reformed at the 5' end. No other structures typical of the native molecules reappeared. In RNA samples heated to 70 degrees C, a new loop reproducibly occurred near the 5' end of each subunit, but this loop was not found in samples heated to higher temperatures. Based on all of these findings, we conclude that the genome of PR-RSV-A shares several features with M-MuLV and other mammalian retroviruses and that the primer tRNA molecules are not involved in the linkage of the two subunits in either genome. We also conclude that the dimer linkage and the loops in subunits are typical of the native molecules and that their formation requires a special environment.