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.     

Size analysis and relationship of murine leukemia virus-specific mRNA''s: evidence for transposition of sequences during synthesis and processing of subgenomic mRNA.

Virus-specific mRNA from purified polyribosomes of mouse cells infected with Moloney murine leukemia virus (M-MuLV) was analyzed by electrophoresis in agarose gels, followed by hybridization of gel slices with M-MuLV-specific complementary DNA (cDNA). The size resolution of the gels was better than that of sucrose gradients used in previous analyses, and two virus-specific mRNA's of 38S and 24S were detected. The 24S virus-specific mRNA is predominantly derived from the 3' half of the M-MuLV genome, since cDNAgag(pol) (complementary to the 5' half of the M-MuLV genome) could not efficiently anneal with this mRNA. However, sequences complementary to cDNA synthesized from the extreme 5' end of M-MuLV 38S RNA (cDNA 5') are present in the 24S virus-specific mRNA, since cDNA 5' (130 nucleotides) efficiently annealed with this mRNA. The annealing of cDNA 5' was not due to repetition of 5' terminal nucleotide sequences at the 3' end of M-MuLV 38S RNA, since smaller cDNA 5' molecules (60 to 70 nucleotides), which likely lack the terminal repetition, also efficiently annealed with the 24S mRNA. The sequences in 24S virus-specific mRNA recognized by cDNA 5' are not present in 3' fragments of virion RNA that are the same length. Therefore, it appears that RNA sequences from the extreme 5' end of the M-MuLV genome may be transposed to sequences from the 3' half of the M-MuLV 38S RNA during synthesis and processing of the 24S virus-specific mRNA. These results may indicate a phenomenon similar to the RNA splicing processes that occur during synthesis of adenovirus and papovavirus mRNA's.     

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.     

Low-multiplicity infection of Moloney murine leukemia virus in mouse cells: effect on number of viral DNA copies and virus production in producer cells.

Mouse cells infected with Moloney murine leukemia virus (M-MuLV) were prepared by two methods, and the number of M-MuLV-specific DNA copies in the infected cells was measured. The number of M-MuLV-specific DNA copies detected varied from one to eight per infected cell in different cell lines. Cells in which multiple rounds of viral infection occurred during establishment had on the average more viral DNA copies than cells in which infection at low multiplicity was performed, followed by cloning of the cells. However, even in cells derived by the low multiplicity of infection method, most cell lines carried more than one copy of M-MuLV-specific DNA. Virus production per cell was also measured, and no strict correlation was observed between the number of M-MuLV DNA copies present and the amount of virus produced.     

Methylation state and DNase I sensitivity of chromatin containing Moloney murine leukemia virus DNA in exogenously infected mouse cells

The nature of Moloney murine leukemia virus (M-MuLV)-specific proviral DNA in exogenously infected mouse cells was studied. M-MuLV clone A9 cells, NIH-3T3 fibroblasts productively infected with M-MuLV, were used. These cells contain 10 to 15 copies of M-MuLV proviral DNA. The state of methylation of M-MuLV proviral DNA was examined by cleaving A9 cell DNA with restriction endonucleases which have the dinucleotide CpG in their cleavage sequences. Analysis with such enzymes, which recognized nine different sites in M-MuLV DNA, indicated that most if not all of the M-MuLV proviruses in A9 cells were completely unmethylated. An individual proviral integration was examined, using as probe adjacent single-copy cellular sequences. These sequences were obtained from a lambda phage recombinant clone containing an M-MuLV provirus from the A9 cells. This individual integration also showed no detectable methylation. In contrast, endogenous MuLV-related sequences present in NIH-3T3 cells before infection were largely methylated. The configuration chromatin containing M-MuLV proviruses was also investigated by digesting A9 nuclei with DNase I, followed by restriction analysis of the remaining DNA. Endogenous MuLV-related DNA was in chromatin relatively resistant to DNase I digestion, whereas the majority of M-MuLV-specific proviruses were in domains of intermediate DNase I sensitivity. Two proviral copies hypersensitive to DNase I digestion were identified. Analogy to the DNase I sensitivity of expressed and nonexpressed globin genes suggested that the proviral copies containing DNase I-hypersensitive sites were transcribed.     

Retroviruses and embryogenesis: Microinjection of Moloney leukemia virus into midgestation mouse embryos

The interaction of Moloney leukemia virus (M-MuLV) with developing post-implantation mouse embryos was studied. First, the frequency at which embryos in utero are infected by transplacental transmission with maternal virus was explored. To exclude milk transmission from the viremic mother, embryos were delivered by cesarean section prior to birth and given to normal foster mothers. None of 72 mice raised this way developed viremia. This indicates that the placenta is an efficient barrier protecting the developing embryo against infection with exogenous retroviruses. To overcome the placental barrier and to introduce virus into embryos at defined stages of differentiation, Moloney leukemia virus was microinjected directly into embryos in utero at day 8 or 9 of gestation. Between 60 and 70% of the injected embryos survived to birth and were tested for viremia at 4 weeks of age. M-MuLVspecific sequences were quantitated in organs of viremic animals derived from midgestation embryos microinjected with virus. Molecular hybridization experiments with nucleic acids extracted from different organs of these animals indicated that every cell type carried M-MuLV-specific DNA sequences and that high concentrations of M-MuLV-specific RNA sequences were present in every organ. In contrast, M-MuLV infection and expression is restricted to lymphatic tissues when animals are exposed to virus after birth or in BALB/Mo mice. These results indicate that the most important parameter determining the “target tropism” of Moloney leukemia virus infection and expression is the stage of embryogenesis and cellular differentiation at which virus infection takes place. In viremic C57BL animals derived from microinoculated embryos, the hair color changed beginning at age 6 weeks. This was not observed in animals exposed to virus after birth. All animals succumbed to MMuLV-induced leukemia at a later age. The results suggest that expression of M-MuLV may also lead to cellular dysfunctions other than leukemic transformation.     

Virus-Like 30S RNA in Mouse Cells

Uninfected JLS-V9 mouse cells are known to express high levels of viral sequences that hybridize to complementary DNA made by the BrdU-induced virus of JLS-V9 cells. The genome in the BrdU-induced virus has been found to consist mainly of an RNA species that migrates as 30S RNA material during electrophoresis through agarose gels. This virus-like 30S RNA, designated VL30 RNA, apparently represents a new class of endogenous defective retroviruses that are not generally evident because of their defectiveness and lack of biological function. Fingerprint analysis and hybridization studies show that VL30 RNA does not have homology with the standard nondefective murine leukemia viruses. Upon superinfection with a nondefective murine leukemia virus, or upon induction of endogenous virus with BrdU, VL30 RNA is rescued into virions by phenotypic mixing. When VL30 RNA is rescued by BrdU induction, the VL30 RNA is mainly organized as a 50S complex, but when VL30 is rescued by superinfection, VL30 is also found in 70S RNA. Rescued VL30 RNA sequences can be reverse transcribed by the virion-associated DNA polymerase in an endogenous reaction. Many mouse cells express the sequences, whereas heterologous cells such as rat or rabbit cells do not contain them. By using hybridization of a complementary DNA probe to cellular RNA immobilized on paper, no subgenomic RNA related to the VL30 RNA could be found in cells expressing the VL30 sequences. From 20 to 50 copies of these sequences were found to be contained in the mouse genome. VL30 RNA is probably present in most stocks of leukemia and sarcoma viruses made in mouse cells.     

Activation of a functional idiotype network response by monoclonal antibody specific for a virus (M-MuLV)-induced tumor antigen

BALB/c mice were injected with IgM mAb specific for Moloney murine leukemia virus (M-MuLV)-determined cell surface Ag in an attempt to inhibit Moloney sarcoma growth. The monoclonal IgM significantly inhibited sarcoma growth when given to the mice after inoculation with Moloney murine sarcoma/leukemia virus, and also potentiated the in vivo antibody response specific for M-MuLV Ag. These responses were significantly greater than the primary response to the virus alone in age- and sex-matched control mice, and were also seen in mice which were injected with the IgM antibody only and not with virus, suggesting that an Ag-independent mechanism may be involved. The M-MuLV-specific serum antibody responses induced by the monoclonal IgM, with or without prior virus inoculation, were predominantly of the IgG1 isotype, with some IgG2a; no other isotypes were found to have titers significantly higher than in the normal response to virus alone. M-MuLV-specific IgG1 was detected only in mice injected with monoclonal IgM, and not in the response to virus alone. The same sera also had high titers of anti-idiotypic antibodies, (Ab2), as well as anti-anti-idiotypic antibodies (Ab3). It appears, therefore, that passive immunization with M-MuLV-specific IgM mAb activates an idiotypic network, which results in both Ab2 and Ab3 responses; the M-MuLV-specific response may be considered a subset of Ab3.     

M-MuLV-induced leukemogenesis: Integration and structure of recombinant proviruses in tumors

M-MuLV-specific DNA probes were used to establish the state of integration and amplification of recombinant proviral sequences in Moloney virus-induced tumors of Balb/Mo, Balb/c and 129 mice. The somatically acquired viral sequences contain both authentic M-MuLV genomes and recombinants of M-MuLV with endogenous viral sequences. All reintegrated genomes carry long terminal repeat (LTR) sequences at both termini of their genome. In the preleukemic stage a large population of cells exhibiting a random distribution of reintegrated M-MuLV genomes are seen, but during outgrowth of the tumor, selection of cells occurs leaving one or a few clonal descendants in the outgrown tumor. In this latter stage recombinant genomes can be detected. Although these recombinants constitute a heterogeneous group of proviruses, characteristic molecular markers are conserved among many individual proviral recombinants, lending credence to the notion that a certain recombinant structure is a prerequisite for the onset of neoplasia. The structure of these recombinants shows close structural similarities to the previously described mink cell focus-inducing (MCF)-type viruses.     

Generation and characterization of a recombinant Moloney murine leukemia virus containing the v-myc oncogene of avian MC29 virus: in vitro transformation and in vivo pathogenesis.

A new retrovirus consisting of the v-myc oncogene sequences of avian MC29 virus inserted into the genome of Moloney murine leukemia virus (M-MuLV) was generated. This was accomplished by constructing a recombinant DNA clone containing the desired organization, introducing the recombinant DNA into mouse NIH 3T3 cells, and superinfecting the cells with replication-competent M-MuLV. The construction was designed so that an M-MuLV gag-myc fusion protein would be produced. The resulting virus, M-MuLV(myc), morphologically transformed uninfected NIH 3T3 cells. Stocks of M-MuLV(myc)-M-MuLV were infected into secondary mouse embryo cultures. M-MuLV(myc) induced striking growth and proliferation of hematopoietic cells. These cells were of the myeloid lineage by morphology, phagocytic properties, and surface staining with Mac-1 and Mac-2 monoclonal antibodies. They resembled mature macrophages, although they displayed minor properties of immaturity. The myeloid cells were transformed in comparison with uninfected myeloid cells since they were less adherent and had unlimited proliferative capacity and reduced growth factor requirements. The transformed myeloid cells with proliferative potential were actually myeloid progenitors which apparently underwent terminal differentiation to macrophages. It was possible to derive a permanent line of factor-independent macrophages from M-MuLV(myc)-transformed myeloid cells. M-MuLV(myc) also immortalized and morphologically transformed mouse embryo fibroblasts. These in vitro properties closely resembled the biological activity of MC29 virus in avian cells and suggested that the nature of the v-myc oncogene was an important determinant in transformation specificity. Neonatal NIH Swiss mice inoculated intraperitoneally with M-MuLV(myc)-M-MuLV only developed lymphoblastic lymphoma characteristic of the M-MuLV helper alone, and no acute fibrosarcomas or myeloid tumors resulted. In light of the strong myeloid transformation observed in vitro, the absence of acute in vivo myeloid disease was noteworthy. Interestingly, when a derivative of M-MuLV(myc) carried by a nonpathogenic amphotropic MuLV helper was inoculated, T lymphomas developed with long latency. Molecular hybridization confirmed that these tumors contained M-MuLV(myc).     

Structure of the Abelson murine leukemia virus genome.

Virions produced from cells transformed by A-MuLV contain a 30S, 5.6 kb RNA that can be translated in a cell-free system to form the characteristic A-MuLV protein. This RNA was mapped by heteroduplex methods using DNA probes from M-MuLV, the presumed parent of A-MuLV. The overall organization of the RNA was determined by using full-length M-MuLV reverse transcribed DNA and visualizing the heteroduplexes in the electron microscope. This showed that A-MuLV and M-MuLV have homologous sequences at both ends of their RNAs but that the central portion of the A-MuLV genome is not homologous to sequences in M-MuLV RNA. A precise measure of the lengths of the shared regions was obtained by using S1 nuclease to digest hybrids between 32P-labeled M-MuLV DNA and A-MuLV RNA; the resulting fragments were analyzed for their length by electrophoresis. The regions of homology were shown to be 1320 nucleotides long at the 5' end and 730 nucleotides long at the 3' end. Thus approximately 6200 nucleotides of the approximately 8300 in M-MuLV RNA were deleted when the A-MuLV genome was formed, but an insert of 3600 nucleotides, presumably derived from the normal murine genome, was inserted in place of the deleted region.     

RNA metabolism of murine leukemia virus. III. Identification and quantitation of endogenous virus-specific mRNA in the uninfected BALB/c cell line JLS-V9.

mRNA containing type C endogenous virus-specific sequences was indentified in JLS-V9 cells (an uninfected BALB/c-derived cell line) by annealing extracted RNA with 3H-labeled virus-specific DNA. The criterion for virus-specific RNA being mRNA was that it co-sedimented with polyribosomes in a sucrose gradient and that it changed to lower sedimentation value if polyribosomes were disagregated prior to centrifugation. It was not possible to identify virus-specific mRNA in unfractionated cytoplasm from JLS-V9 cells since large amounts of virus-specific ribonucleoprotein which was not mRNA had sedimentation values similar to polyribosomes and obscured the analysis. Virus-specific mRNA could be readily identified in polyribosomes which had been purified through a step gradient of 1 and 2 M sucrose, and consisted of two species with sedimentation values of 38S and 27S. The amount of virus-specific RNA in different JLS-V9 cell fractions was quantitated in comparison to cell fractions obtained from M-MuLV clone no. 1 cells (a line of NIH 3T3 cells producing Moloney murine leukemia virus). Approximately 40% of the total virus-specific mRNA was recovered in the purified polyribosomes in M-MuLV no. 1 cells. The amount of virus-specific RNA on polyribosomes appeared to be quite similar for JLS-V9 cells and M-MuLV clone no.1 cells .In contrast, the level of virus-specific protein in JLS-V9 cells (as monitored by radioimmunoassay of the internal structural protein p30) was less than 2% the level in the M-MuLV clone no. 1 cells.     

Cloning of Two Genetically Transmitted Moloney Leukemia Proviral Genomes: Correlation Between Biological Activity of the Cloned DNA and Viral Genome Activation in the Animal

The Mov-7 and Mov-9 substrains of mice, carrying Moloney murine leukemia virus (M-MuLV) in their germ line at the Mov-7 locus and Mov-9 locus, respectively, are different with respect to virus activation. Infectious virus appears in all mice carrying the Mov-9 locus but is not activated in animals carrying the Mov-7 locus. Consequently, only Mov-9 mice develop viremia and subsequent leukemia. The endogenous M-MuLV provirus with flanking mouse sequences corresponding to the Mov-7 and Mov-9 loci was molecularly cloned. Detailed restriction maps obtained from the cloned DNAs revealed no detectable differences in the proviral genomes. The flanking mouse sequences, however, were different, confirming that the Mov-7 and Mov-9 loci represent different integration sites of M-MuLV. Both clones induced XC plaques in a transfection assay. The specific infectivity of the clones, however, was different. A total of 10⁻⁵ XC plaques per genome equivalent were induced by the Mov-9 clone, whereas only 10⁻⁹ XC plaques per genome equivalent were induced by the Mov-7 clone. Moreover, NIH 3T3 cells transfected with the Mov-9 clone produced NB-tropic M-MuLV, whereas cells transfected with the Mov-7 clone did not produce infectious virus. The results suggest that M-MuLV integrated at the Mov-7 locus carries a mutation which prevents synthesis of infectious virus but permits XC plaque induction by partial genome expression or synthesis of noninfectious particles. Thus, the pattern of virus expression in Mov-7 and Mov-9 mice correlates with the biological properties of the respective clones. Genomic DNA from Mov-9 mice was not infectious in the transfection assay (specific infectivity < 10⁻⁷ PFU per genome equivalent). As the only difference between the genomic and the cloned Mov-9 DNA appears to be the presence of 5-methylcytosine in CpG sequences, our results suggest that removal of methyl groups by molecular cloning in procaryotes permits genome expression in transfected eucaryotic cells. Our results support the hypothesis that DNA methylation is relevant not only in genome expression in the animal but also in expression of genes transfected into eucaryotic cells.     

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.     

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.     

Germ line integration of moloney leukemia virus: Effect of homozygosity at the M-MuLV locus

Mice genetically transmitting the exogenous Moloney leukemia virus (M-MuLV) have been previously derived. These animals carried one copy of M-MuLV DNA in their germ line and were heterozygous for the M-MuLV locus (Jaenisch, 1976).Experiments were performed to investigate whether homozygosity at the M-MuLV locus would be compatible with normal development. Animals heterozygous for the M-MuLV locus were mated [♀ (+?) × ♂(+?)] and the genotype of the off-spring was analyzed. Molecular hybridization experiments revealed three classes of offspring carrying two copies (++), one copy (+?) and no (??) M-MuLV-specific DNA sequences, respectively, in their liver DNA. Genetic experiments indicated that males of the first class transmitted the virus to 100% of their offspring, males of the second class to 50% and males of the third class not at all when mated with normal females. These results demonstrated that homozygosity at the M-MuLV locus has no detectable effect on normal development of the animals and that the M-MuLV gene is transmitted from one generation to the next strictly according to Mendelian expectations. Development of M-MuLV-induced leukemia is not influenced by the genotype of these animals-that is, animals carrying two or one copies of M-MuLV in their germ line or animals congenitally infected from the mother developed disease at similar rates.