High molecular weight RNAs from Rous sarcoma virus and Moloney murine leukemia virus contain two subunits.

The molecular weights of the large genomic RNAs from Rous sarcoma and Moloney murine leukemia viruses were determined by a combination of sedimentation coefficients and retardation coefficients from gel electrophoresis. Six RNA standards, ranging from 0.7 X 10(6) to 5.3 X 10(6) daltons, were employed. Studies in the presence of varying concentrations of Mg2+ showed that the method provided valid molecular weights for RNAs of differing amounts of ordered structure. The molecular weight (X 10(-6)) of the high molecular weight RNA complexe from Rous sarcoma virus was 7.6 (+/-0.3) and from murine leukemia virus was 6.9 (+/-0.3). The molecular weights (X 10 (-6) of their Subunits were 3.3 (+/-0.1) and 2.8 (+/-0.2), respectively. Hence, the large complexes consisted of two, not three or more, subunits plus small associated RNAs. The high molecular weight RNA from cloned Rous sarcoma virus was heterogenous in molecular weight although the apparent molecular radius was constant; stuides were performed on subfractions of the RNA as well as on RNA from virus harvested at various time intervals. The preparations with lowest molecular weight approached a mass equal to twice that of the subunit, with hydrodynamic properties approaching those expected of normal single-stranded RNA.     

Measurement of the Sequence Complexity of Cloned Moloney Murine Leukemia Virus 60 to 70S RNA: Evidence for a Haploid Genome

The sequence complexity of the 60-70S RNA complex from Moloney murine leukemia virus (M-MuLV) was determined by measuring the annealing rate of radioactively labeled virus-specific DNA with M-MuLV 60-70S RNA in conditions of vast RNA excess. The M-MuLV RNA annealing rate, characterized by the quantity C(r)t((1/2)), was compared with the C(r)t((1/2)) values for annealing of poliovirus 35S RNA (2.6 x 10(6) molecular weight) with poliovirus-specific DNA and Sindbis virus 42S RNA (4.3 x 10(6) molecular weight) with Sindbis-specific DNA. M-MuLV-specific DNA was prepared in vitro by the endogenous DNA polymerase reaction of M-MuLV virions, and poliovirus and Sindbis virus DNAs were prepared by incubation of viral RNA and DNA polymerase purified from avian myeloblastosis virus and an oligo deoxynucleotide primer. The poliovirus and Sindbis virus DNAs were sedimented through alkaline sucrose gradients, and those portions of the DNA with sizes similar to the M-MuLV DNA were selected out for the annealing measurements. M-MuLV was cloned on NIH-3T3 cells because it appeared possible that the standard source of M-MuLV for these experiments was a mixture of viruses. The annealing measurements indicated a sequence complexity of approximately 9 x 10(6) daltons for the cloned M-MuLV 60-70S RNA when standardized to poliovirus and Sindbis virus RNAs. This value supports the hypothesis that each of the 35S RNA subunits of M-MuLV 60-70S RNA has a different base sequence.     

Heteroduplex analysis of the RNA of clone 3 Moloney murine sarcoma virus.

Heteroduplex analysis of the RNA isolated from purified virions of clone 3 Moloney murine sarcoma virus (M-MSV) hybridized to cDNA's from Moloney murine leukemia virus (M-MLV) and clone 124 M-MSV shows that the main physical component of clone 3 RNA is missing all or most of the 1.5-kilobase (kb) clone 124 M-MSV specific sequence denoted beta s (S. Hu et al. Cell 10:469--477, 1977). This sequence is either deleted in clone 3 RNA or substituted by a very short (0.3-kilobase) sequence. In other respects, clone 3 and clone 124 RNAs show the same heteroduplex structure relative to M-MLV. Since beta s is believed to contain the src gene(s) of clone 124 RNA, this result leaves as an unresolved question the nature of the src gene(s) of the clone 3 M-MSV RNA complex.     

Low-molecular-weight RNAs of Moloney murine leukemia virus: identification of the primer for RNA-directed DNA synthesis.

The small RNAs of Moloney murine leukemia virus (M-MuLV) were fractionated into at least 15 species by two-dimensional polyacrylamide gel electrophoresis. The pattern of small RNAs is significantly different from that of Rous sarcoma virus. A subset of the virion small RNAs is associated with the genome RNA in the 70S complex. One of the associated molecules, a cellular tRNA, is tightly bound to the genome RNA and serves as the major primer for M-MuLV RNA-directed DNA synthesis in vitro.     

Highly inducible cell lines derived from mice genetically transmitting the Moloney murine leukemia virus genome.

Permanent, non-virus-producing cell lines have been established from a mouse embryo carrying an endogenous, genetically transmitted Moloney murine leukemia virus (M-MuLV) genome. These cells carry the M-MuLV genome, as demonstrated by hybridization of cellular DNA to M-MuLV complementary DNA, but do not express it at the levels of virus production, accumulation of intracellular viral p30, or M-MuLV-specific RNA. Treatment with bromodeoxyuridine (50 microgram/ml for 24 h) resulted in induction of XC-positive NB-tropic virus, although only a small fraction of the cells released virus (less than 0.1% after 48 h). Immunofluorescent staining and flow microfluorometry indicated that a wave of p30 accumulation occurs in the induced cells, with a maximum at 24 to 48 h after the addition of bromodeoxyuridine. Furthermore, most, if not all, cells were induced to produce p30 protein. Similar kinetics were found for the accumulation of M-MuLV-specific RNA in the cytoplasm of induced cells. This rapid induction of virus expression in a majority of cells was dependent on the presence of the M-MuLV genome and probably represents primarily the expression of this endogenous virus since induction was not observed in cells similarly derived from a sibling embryo lacking the M-MuLV genome.     

Rate of divergence of cellular sequences homologous to segments of Moloney sarcoma virus.

The RNA genome of the Moloney isolate of murine sarcoma virus (M-MSV) consists of two parts--a sarcoma-specific region with no homology to known leukemia viral RNAs, and a shared region present also in Moloney murine leukemia virus RNA. Complementary DNA was isolated which was specific for each part of the M-MSV genome. The DNA of a number of mammalian species was examined for the presence of nucleotide sequences homologous with the two M-MSV regions. Both sets of viral sequences had homologous nucleotide sequences present in normal mouse cellular DNA. MSV-specific sequences found in mouse cellular DNA closely matched those nucleotide sequences found in M-MSV as seen by comparisons of thermal denaturation profiles. In all normal mouse cells tested, the cellular set of M-MSV-specific nucleotide sequences was present in DNA as one to a few copies per cell. The rate of base substitution of M-MSV nucleotide sequences was compared with the rate of evolution of both unique sequences and the hemoglobin gene of various species. Conservation of MSV-specific nucleotide sequences among species was similar to that of mouse globin gene(s) and greater than that of average unique cellular sequences. In contrast, cellular nucleotide sequences that are homologous to the M-MSV-murine leukemia virus "common" nucleotide region were present in multiple copies in mouse cells and were less well matched, as seen by reduced melting profiles of the hybrids. The cellular common nucleotide sequences diverged very rapidly during evolution, with a base substitution rate similar to that reported for some primate and avian endogenous virogenes. The observation that two sets of covalently linked viral sequences evolved at very different rates suggests that the origin of M-MSV may be different from endogenous helper viruses and that cellular sequences homologous to MSV-specific nucleotide sequences may be important to survival.     

Moloney murine leukemia virus tolerance in anti-CD4 monoclonal antibody-treated adult mice.

Adult mice injected with Moloney murine leukemia virus (M-MuLV) 1 day after a short term treatment with anti-CD4 mAb developed T cell lymphomas, or sarcomas when rechallenged with Moloney murine sarcoma virus (M-MSV). Neoplastic development was correlated with virus spread, as thymic and peripheral T and B lymphocytes promptly expressed M-MuLV-induced Ag after virus introduction; no virus-specific CTL generation was detected in MLTC. This failure, which was selective for M-MuLV-induced Ag, persisted throughout the life span of the mice, and was not sustained by suppressor cell activity. The frequencies of splenic virus-specific CTL precursor varied in relation to time after virus injection; in the first postinjection month, frequencies were similar to those in nonimmune control mice, while at 4 mo post-virus exposure, they showed a striking reduction. These findings indicate that a transient functional impairment of CD4+ cells at the time of retrovirus injection provided the appropriate milieu for tolerance induction in both the peripheral mature and intrathymic T cell compartments.     

Methylation pattern of genomic RNA from Moloney murine leukemia virus.

32P- and methyl-3H-labeled 70S Moloney murine leukemia virus RNA was purified from virions produced in Moloney murine leukemia virus-infected mouse embryo cells. Primer-free RNA subunits obtained by heat treatment and zonal centrifugation were digested with RNase T2, and methylated oligonucleotides were chromatographed on DEAE-Sephadex in 7 M urea. Approximately one molecule of RNase T2-stable oligonucleotide (-5 charge) was isolated per subunit. Structural analysis indicated that the sequence of the oligonucleotide is m7GpppGmpCp. Analysis of the mononucleotide fraction isolated by DEAE-Sephadex chromatography of the RNase T2 digest identified 15 to 23 internal N6-methyladenylic acid molecules per subunit.     

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.     

Characterization of Gazdar murine sarcoma virus by nucleic acid hybridization and analysis of viral expression in cells.

Gazdar murine sarcoma virus (Gz-MSV) and Moloney murine sarcoma virus (M-MSV) are closely related. The complete M-MSV-specific nucleic acid sequences constituted a major portion of Gz-MSV-specific sequences. The MSV-specific sequences in both Gz-MSV and M-MSV genomes shared homology with hamster leukemia virus nucleic acid sequences. Both rat cells (S+L+) and hamster (S+L-) cells expressed two viral proteins of 68,000 and 70,000 daltons. These proteins were immunologically related to p60 purified from m1 virions of M-MSV.     

Integrated Moloney murine leukemia virus DNA studied by using complementary DNA which does not recognize endogenous related sequences

By preannealing a radioactive, representative Moloney murine leukemia virus (M-MuLV) cDNA with large excesses of AKR 70S viral RNA, an M-MuLV-specific cDNA has been prepared. When hybridized to restriction enzyme fragments of M-MuLV-infected mouse cell DNA, the preannealed probe recognizes integrated M-MuLV DNA and does not recognize endogenous related DNA sequences found in uninfected mouse cells. The viral DNA sequences recognized by the preannealed probe are spread throughout the viral genome, although some sequences are recognized less efficiently. By using this preannealed probe, multiple integrations of M-MuLV DNA have been detected in infected fibroblasts and in an M-MuLV-induced tumor. Integrated viral DNA fragments smaller than the complete viral genome have also been detected. By using this preannealed probe to examine a mass-infected culture of mouse fibroblasts, no evidence for a strongly preferred site for M-MuLV integration could be found.     

The integrated genome of murine leukemia virus

The Southern gel filter transfer technique has been used to characterize the integrated genome of Moloney murine leukemia virus (M-MuLV) and the genomes of the endogenous viruses of the mouse. Study of 10 clones of rat cell independently infected by M-MuLV indicates a minimum of 15 integration sites into which the M-MuLV provirus can be inserted. No common integration site is observed among these clones. Clones productively infected by M-MuLV acquire multiple proviruses, whereas infected cells unable to produce virus contain only one M-MuLV provirus. Once established, the integrated genomes are stable for at least two years after initial infection.The use of M-MuLV probe allows detection of a spectrum of Eco RI-cleaved mouse DNA fragments containing endogenous MuLV genomes. DNAs of different inbred laboratory mouse strains yield similar patterns of provirus with each strain showing minor characteristic differences. In some instances, mouse cells infected by M-MuLV reveal additional proviruses beyond those seen in the uninfected cell. DNAs from three different M-MuLV-induced thymomas indicate, as in rat cells, multiple possible integration sites.     

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.