Infectious viral DNA of murine leukemia virus

Silencing of Unintegrated Retroviral DNAs

Retroviral infection delivers an RNA genome into the cytoplasm that serves as the template for the synthesis of a linear double-stranded DNA copy by the viral reverse transcriptase. Within the nucleus this linear DNA gives rise to extrachromosomal circular forms, and in a key step of the life cycle is inserted into the host genome to form the integrated provirus. The unintegrated DNA forms, like those of DNAs entering cells by other means, are rapidly loaded with nucleosomes and heavily silenced by epigenetic histone modifications. This review summarizes our present understanding of the silencing machinery for the DNAs of the mouse leukemia viruses and human immunodeficiency virus type 1. We consider the potential impact of the silencing on virus replication, on the sensing of the virus by the innate immune system, and on the formation of latent proviruses. We also speculate on the changeover to high expression from the integrated proviruses in permissive cell types, and briefly consider the silencing of proviruses even after integration in embryonic stem cells and other developmentally primitive cell types.

Coming full circle-from endless complexity to simplicity and back again

Cell has celebrated the powers of reductionist molecular biology and its major successes for four decades. Those who have participated in cancer research during this period have witnessed wild fluctuations from times where endless inexplicable phenomenology reigned supreme to periods of reductionist triumphalism and, in recent years, to a move back to confronting the endless complexity of this disease.

Basic fibroblast growth factor is an extracellular matrix component required for supporting the proliferation of vascular endothelial cells and the differentiation of PC12 cells

Vascular endothelial cells (ECs) seeded sparsely on extracellular matrix (ECM) will proliferate in the absence of exogenous basic fibroblast growth factor (bFGF). This ECM will also stimulate neurite outgrowth in PC12 cells in the absence of exogenous growth factors. We have previously shown that bFGF is found in subendothelial ECM (Vlodavsky, I., J. Folkman, R. Sullivan, R. Fridman, R. Ishai-Michaeli, J. Sasse, and M. Klagsburn. 1987. Proc. Natl. Acad. Sci. USA. 84:2292-2296) and in basement membranes (Folkman, J., M. Klagsburn, J. Sasse, M. Wadzinski, D. Ingber, and I. Vlodavsky. 1988. Am. J. Pathol. 130:393-400). The actual requirement of ECM-associated bFGF for the growth of ECs and differentiation of PC12 cells was shown in two ways. First, polyclonal anti-bFGF antibodies added to subendothelial ECM inhibited both EC proliferation and PC12 neurite outgrowth. Secondly, PF-HR-9 cells, which do not synthesize bFGF and which produce an ECM not permissive for EC proliferation and PC12 neurite outgrowth, were transfected with bFGF cDNA. PF-HR-9 cells transfected with bFGF, but not with the dominant selectable marker SV2-neomycin, were found to express bFGF and to produce an ECM which did support both EC proliferation and PC12 differentiation. The ECM-mediated stimulatory effects were inhibited by anti-bFGF antibodies but not by anti-nerve growth factor antibodies or nonimmune rabbit IgG. These results indicate that bFGF associated with ECM is a required ECM component for ECM-mediated cell proliferation and differentiation.

A nucleoprotein complex mediates the integration of retroviral DNA

The integration of viral DNA into the host genome is an essential step in the retrovirus life cycle. To understand this process better, we have examined the native state of viral DNA in cells acutely infected by murine leukemia virus (MLV), using both a physical assay for viral DNA and a functional assay for integration activity (Brown et al. 1987). The viral DNA and integration activity copurify during velocity sedimentation, gel filtration, and density equilibrium centrifugation, indicating that viral DNA is in a large (approximately 160S) nucleoprotein complex that includes all functions required for integration activity in vitro. Analysis by immunoprecipitation shows that the viral capsid protein is part of the active nucleoprotein complex, but recognition of the complex by only a subset of anti-capsid sera implies that the protein is constrained conformationally. The viral DNA within this structure is accessible to nucleases; the effects of nucleases on the integrity of the complex suggest that the integration-competent particle is derived from and similar to the core of extracellular virions.

Basic fibroblast growth factor fused to a signal peptide transforms cells

Basic fibroblast growth factor (bFGF) is a potent growth and angiogenic factor that is found in abundance in tissues such as brain, hypothalamus, kidney and cartilage. Despite this copious production of bFGF, most of these tissues are not undergoing either active growth or angiogenesis, suggesting that bFGF activity must be regulated so as to prevent autostimulation of cell growth. In cultured cells, bFGF is associated mainly with cells and basement membranes and is not released into the medium. Prevention of release could be a mechanism for regulation of bFGF activity and may be a consequence of the apparent absence of a secretory-signal sequence in the bFGF protein. Here we investigate whether this regulation can be overridden through the forced secretion of bFGF. Such secretion might provide the bFGF access to its receptor and in turn lead to autocrine transformation of the cell. We report that bFGF, as specified by a recombinant plasmid, is itself unable to induce such transformation, but acquires this ability after fusion with a secretory-signal sequence. The resulting transformants undergo unusual morphological alteration and display tumorigenicity.

Tumorigenic and metastatic properties of "normal" and ras-transfected NIH/3T3 cells

To investigate the role of oncogene activation in the pathogenesis of malignant tumors, we have studied the tumorigenic and metastatic properties of NIH/3T3 secondary transfectants (designated A51) containing an activated c-Ha-ras-1 gene derived from the human T24 bladder carcinoma cell line and compared them with untransfected NIH/3T3 cells. Whereas subcutaneous implantation of NIH/3T3 cells in the supraclavicular region produced palpable tumors that failed to metastasize, NIH/3T3 cells inoculated in the footpad gave rise to malignant tumors that metastasized to the lung. Under identical conditions and irrespective of the site of implantation, A51 cells formed rapidly growing primary tumors that produced pulmonary metastases. In an assay for experimental metastasis, intravenously injected NIH/3T3 cells gave rise to pulmonary nodules only at high cell inocula and in long-term survivors (90 days after injection). In contrast, A51 cells formed multiple lung tumor colonies detectable 14 days after injection. These results indicate that "normal" untransfected NIH/3T3 cultures contain subpopulations of cells that express malignant properties and that transfection of NIH/3T3 cells with activated c-Ha-ras-1 accelerates formation of metastases.

Expression of the metastatic phenotype in cells transfected with human metastatic tumor DNA

NIH 3T3 mouse fibroblasts form nonmetastasizing fibrosarcomas upon transformation by the Ha-ras oncogene isolated from the EJ human bladder carcinoma cell line and subcutaneous inoculation into immunocompetent NFS/NCr mice. DNA from a human metastatic tumor was transfected into these Ha-ras transformants, and one of the resulting colonies yielded a lung metastasis after subcutaneous inoculation. DNA was isolated from this metastasis and subjected to a second round of transfer into Ha-ras-transformed NIH 3T3 cells. Inoculation of these transfected cultures into mice led once again to formation of metastases, this time at a higher frequency. Examination of four of the resulting metastases revealed discrete human DNA fragments that were common to all four. These findings demonstrate that the metastatic phenotype can be transferred via DNA from cell to cell and is associated with the presence of a discrete DNA segment. This segment is not identical to the myc oncogene or to any of the frequently detected ras tumor oncogenes.

Increase of cellular murine leukemia virus reverse transcriptase in interferon-treated cells

The addition of mouse interferon (IFN) to AKR murine leukemia virus (MuLV)-producing NIH3T3 cells inhibited the extracellular appearance of AKR MuLV when assayed for reverse transcriptase activity or infectious virus production. IFN treatment had no detectable effect on proviral DNA formation during infection nor on the level of viral RNA in virus-producing cells. However, addition of IFN did alter the level of cellular viral reverse transcriptase activity. Chromatography of extracts from virus-producing cells on poly(G)-Sepharose columns revealed two peaks of reverse transcriptase activity. Peaks I and II eluted at 0.45 M and 0.65 M NaCl, respectively, while the cellular DNA polymerase beta eluted earlier at 0.3 M NaCl. IFN treatment of these chronic virus producer cells resulted in a 5-fold increase in peak I whereas peak II and polymerase beta remained essentially unchanged. When reverse transcriptase from purified virions was similarly chromatographed on poly(G)-Sepharose, all of the enzymatic activity eluted as peak I. Thus, the reverse transcriptase in peak I from cell extracts appears to be the form which is present in mature virions. Contrary to the results with chronic virus-producing cells, IFN treatment prior to exogenous infection with MuLV did not alter levels of reverse transcriptase peaks I and II or polymerase beta. These results provide further evidence that the major effect of IFN occurs at the level of MuLV maturation and assembly.

Fv-1 host cell restriction of friend leukemia virus: microinjection of unintegrated viral DNA

The murine gene Fv-1 has been shown to exert a major influence over the replication of ecotropic murine leukemia viruses. Studies of the replication of Friend murine leukemia virus have shown that the restriction of viral replication occurs intracellularly after the initiation of viral DNA synthesis. The precise mechanism of the block imposed by the Fv-1 gene product is not completely understood. Our studies of Fv-1 restrictive infection have shown a variable decrease in the accumulation of intracellular unintegrated form I viral DNA. Analysis by microinjection of the viral DNA formed in nonpermissively infected BALB/c cells indicates that this DNA is infectious. These studies indicate that the form I DNA accumulated in nonpermissively infected BALB/c cells contains the complete viral sequences necessary for the production of viral progeny, and therefore, they suggest that the Fv-1 host restrictive mechanism recognizes viral factors other than form I DNA alone. These results support the possibility that Fv-1 host restriction occurs after formation of infectious viral DNA, perhaps at the integration step itself.

Mutations in the gag gene of Moloney murine leukemia virus: effects on production of virions and reverse transcriptase

We have constructed a series of deletion mutations in the p30 and p10 domains of the gag gene of Moloney murine leukemia virus. Mutants with deletions in P30 were completely defective in virion particle production even though an altered gag precursor protein is synthesized. This domain is apparently critical for particle formation. A mutant in P10 was able to release virion particles into the medium, and low levels of reverse transcriptase activity could be detected in these virions. To explore the effects of these mutations on the utilization of the gag-pol precursor, we have introduced these mutants into cells already releasing defective particles from an endogenous provirus which directs the synthesis of gag gene products and not pol gene products. The P10 mutant was capable of providing pol function as judged by the incorporation of high levels of reverse transcriptase into the particles and complete complementation for XC plaque formation. In contrast, the mutants in P30 were negative in this complementation test. Thus, those gag mutants which were unable on their own to assemble virion particles were also unable to contribute the gag-pol precursor to these particles. These mutations are the first to be mapped to the gag region which affect pol function, suggesting that the gag-pol precursor must be assembled before pol is functionally separated from the gag domain. The concordance of the effects of different mutations on both particle formation and gag-pol utilization suggests that similar domains of gag (namely, domains in the P30 region) are needed for these two processes.

Cellular oncogenes and multistep carcinogenesis

Two dozen cellular proto-oncogenes have been discovered to date through the study of retroviruses and the use of gene transfer. They form a structurally and functionally heterogeneous group. At least five distinct mechanisms are responsible for their conversion to active oncogenes. Recent work provides experimental strategies by which many of these oncogenes, as well as oncogenes of DNA tumor viruses, may be placed into functional categories. These procedures may lead to definition of a small number of common pathways through which the various oncogenes act to transform cells.

Effect of interferon on the penetration of murine leukemia virus and the binding of its genome RNA to polyribosomes at the early stage of infection

The effect of interferon (IFN) on the adsorption, penetration and subsequent binding of the incoming genome RNA of Moloney murine leukemia virus (MLV) to polyribosomes, was studied in NIH/3T3 mouse fibroblasts. Virus adsorption was assayed by determining reverse transcriptase activity in the inoculating virus stock and in the cell membrane fraction before and after 45 minutes of infection. Both measurements suggested that IFN had no effect on virus adsorption. Virus penetration was determined by measuring the amount of viral RNA in the cell cytoplasm at 45 minutes after infection. This amount was remarkably lower in IFN-treated than in untreated cells. This reduction was not due to inhibition of a possible induction of endogenous viral genetic information by the penetrating virions, but was proved to be a direct effect of IFN on virus penetration, which was related to the IFN-induced antiviral state. The effect of IFN on binding of parental genome RNA to polyribosomes was then investigated by analysing Crt hybridization kinetics of polyribosomal viral RNA at different time intervals after infection. While in untreated control cells maximal binding occurred at 3 hours postinfection, this maximal binding was observed in IFN-treated cells at 5 hours postinfection. The distribution of viral RNA molecules between sub-cytoplasmic fractions at 3 hours after infection was, in IFN-treated cells, significantly different from that observed in the untreated cells.

Tumorigenic conversion of primary embryo fibroblasts requires at least two cooperating oncogenes

Transfection of embryo fibroblasts by a human ras oncogene does not convert them into tumour cells unless the fibroblasts are established and immortalized before transfection. The embryo fibroblasts become tumorigenic if a second oncogene such as a viral or cellular myc gene or the gene for the polyoma large-T antigen is introduced together with the ras gene.

Deletion mutants of Moloney murine leukemia virus which lack glycosylated gag protein are replication competent

A series of deletion mutations localized near the 5' end of the Moloney murine leukemia virus genome was generated by site-specific mutagenesis of cloned viral DNA. The mutants recovered from such deleted DNAs failed to synthesize the normal glycosylated gag protein gPr80gag. Two of the mutants made no detectable protein, and a third mutant, containing a 66-base pair deletion, synthesized an altered gag protein which was not glycosylated. All the mutants made normal amounts of the internal Pr65gag protein. The viruses were XC positive and replicated normally in NIH/3T3 cells as well as in lymphoid cell lines. These results indicate that the additional peptides of the glycosylated gag protein are encoded near the 5' end, that the glycosylated and internal gag proteins are synthesized independently, and that the glycosylated gag protein is not required during the normal replication cycle. In addition, the region deleted in these mutants apparently encodes no cis-acting function needed for replication. Thus, all essential sequences, including those for packaging viral RNA, must lie outside this area.

DNA methylation affecting the expression of murine leukemia proviruses

The endogenous, vertically transmitted proviral DNAs of the ecotropic murine leukemia virus in AKR embryo fibroblasts were found to be hypermethylated relative to exogenous AKR murine leukemia virus proviral DNAs acquired by infection of the same cells. The hypermethylated state of the endogenous AKR murine leukemia virus proviruses in these cells correlated with the failure to express AKR murine leukemia virus and the lack of infectivity of cellular DNA. Induction of the endogenous AKR murine leukemia virus proviruses with the methylation antagonist 5-azacytidine suggested a causal connection between DNA methylation and provirus expression. Also found to be relatively hypermethylated and noninfectious were three of six Moloney murine leukemia virus proviral DNAs in an unusual clone of infected rat cells. Recombinant DNA clones which derived from a methylated, noninfectious Moloney provirus of this cell line were found to be highly active upon transfection, suggesting that a potentially active proviral genome can be rendered inactive by cellular DNA methylation. In contrast, in vitro methylation with the bacterial methylases MHpaII and MHhaI only slightly reduced the infectivity of the biologically active cloned proviral DNA. Recombinant DNA clones which derived from a second Moloney provirus of this cell line were noninfectious. An in vitro recombination method was utilized in mapping studies to show that this lack of infectivity was governed by mechanisms other than methylation.

Fv-1 host restriction of Friend leukemia virus: analysis of unintegrated proviral DNA

The murine gene Fv-1 predominantly controls the outcome of infection by murine ecotropic retroviruses. The inhibition of virus replication by the Fv-1 gene product has been determined to be at an early stage in virus replication. Mechanistically, its effect appears to be on the accumulation of unintegrated proviral DNA or its integration or both. We investigated the synthesis of unintegrated proviral DNA, using several clones of B-, N-, or NB-tropic Friend murine leukemia virus. Our results indicate that the accumulation of B-tropic proviral DNA in NIH cells may be inhibited at either the level of linear (form III) or covalently closed circular DNA (form I), depending upon the degree of restriction of the clone of virus used. We confirmed that there is an effect of the Fv-1 gene on the accumulation of form I DNA of either B- or N-tropic Friend murine leukemia virus. However, the decrease in infectious centers effected by the Fv-1 gene did not correlate quantitatively with the effect on form I proviral DNA produced by N-tropic Friend murine leukemia virus in nonpermissive cells. Lastly, we demonstrated in nonpermissively infected NIH cells that a rapidly migrating doublet of viral DNA is formed.

Efficient production of xenotropic murine leukemia virus unintegrated proviral DNA by cocultivation

Cocultivation of virus-producing cells and homologous uninfected cells yielded greater than a 10-fold increase in linear and superhelical proviral DNAs as compared with previously published techniques.

Structure of the provirus within NIH 3T3 cells transfected with Harvey sarcoma virus DNA

NIH 3T3 cells transformed with unintegrated Harvey sarcoma virus (HSV) linear DNA generally acquired a complete HSV provirus. Infection of these transformed cells with Moloney murine leukemia helper virus was followed by release of infectious particles. The HSV provirus within these transfected cells was convalently joined to nonviral DNA sequences and was termed "cell-linked" HSV DNA. The association of this cell-virus DNA sequence with the chromosomal DNA of a transfected cell was unclear. NIH 3T3 cells could also become transformed by transfection with this cell-linked HSV DNA. In this case, the recipient cells generally acquired a donor DNA fragment containing both the HSV provirus and its flanking nonviral sequences. After cells acquired either unintegrated or cell-linked HSV DNA, the newly established provirus and flanking cellular sequences underwent amplifications to between 5 and 100 copies per diploid cell. NIH 3T3 cells transfected with HSV DNA may acquire deleted proviral DNA lacking at least 1.3 kilobase pairs from the right end of full-length HSV 6-kilobase-pair DNA (corresponding to the 3'-proximal portion of wild-type HSV RNA). Cells bearing such deleted HSV genomes were transformed, indicating that the viral transformation gene lies in the middle or 5'-proximal portion of the HSV RNA genome. However, when these cells were infected with Moloney murine leukemia helper virus, only low levels of biologically active sarcoma virus particles were released. Therefore, the 3' end of full-length HSV RNA was required for efficient transmission of the viral genome.

Physical map of infectious baboon type C viral DNA and sites of integration in infected cells

Three species of unintegrated viral DNAs were found in permissive cells infected with baboon type C virus. The major species was a 9.0-kilobase (kb) linear DNA that was infectious. A restriction endonuclease map of this DNA was constructed and oriented with respect to the viral RNA. The linear DNA had a 0.6-kb sequence repeated at each terminus. These terminal repeat sequences were required for infectivity of the viral DNA. The minor species of the unintegrated viral DNAs were covalently closed circles of 9.0 and 8.4 kb. The smaller circle was in two- to threefold excess over the larger circle. The difference appeared to be that the smaller circle lacked one of the two 0.6-kb repeat sequences found in the larger circle. Restriction endonuclease maps of the integrated viral DNAs were constructed, and the sequences on both viral DNA and cellular DNA that are involved in integration were determined. The integrated viral DNA map was identical to that of the unintegrated infectious 9.0-kb linear DNA. Therefore, a specific site in the terminal repeat sequence of the viral DNA was used to integrate with the host cell DNA. The sizes of the cellular DNA fragments were different from clone to clone but stable with cell passage. Therefore, many sites in the cell DNA can recombine with the viral DNA.

Molecular cloning of unintegrated and a portion of integrated moloney murine leukemia viral DNA in bacteriophage lambda

A covalently closed circular form of unintegrated viral DNA obtained from NIH 3T3 cells freshly infected with Moloney murine leukemia virus (M-MLV) and a port of the endogenous M-MLV from the BALB/Mo mouse strain have been cloned in bacteriophage lambda. The unintegrated viral DNA was cleaved with restriction endonuclease HindIII and inserted into the single HindIII site of lambda phage Charon 21A. Similarly high-molecular-weight DNA from BALB/Mo mice ws cleaved sequentially with restriction endonucleases EcoRI and HindIII and separated on the basis of size, and one of the two fractions which reacted with an M-MLV-specific complementary DNA was inserted into the HindIII site of Charon 21A. Recombinant clones containing M-MLV-reacting DNA were analyzed by restriction endonuclease mapping, heteroduplexing, and infectivity assays. The restriction endonuclease map of the insert derived from unintegrated viral DNA, lambda x MLV-1, was comparable to published maps. Electron microscope analysis of the hybrid formed between lambda x MLV-1 DNA and 35S genomic M-MLV RNA showed a duplex structure. The molecularly cloned lambda x MLV-1 DNA contained only one copy of the long terminal repeat and was not infectious even after end-to-end ligation of the insert DNA. The insert DNA derived from endogenous M-MLV, lambda x MLVint-1, contained a DNA stretch measuring 5.4 kilobase pairs in length, corresponding to the 5' part of the genomic viral RNA, and cellular mouse DNA sequences measuring 3.5 kilobase pairs in length. The viral part of the insert showed the typical restriction pattern of M-MLV DNA except that a single restriction site, PvuII, in the 5' long terminal repeat was missing. Reconstructed genomes containing the 5' half derived from the integrated viral DNA and the 3' half derived from the unintegrated viral DNA were able to induce XC plaques after transfection in uninfected mouse fibroblasts.

Molecular cloning and characterization of avian sarcoma virus circular DNA molecules

Supercoiled DNA molecules were used for the molecular cloning of full-length avian sarcoma virus (ASV) DNA. Viral DNA produced by the Schmidt-Ruppin A (SR-A) strain of ASV was isolated from acutely infected transformed quail cells. Supercoiled DNA was separated from linear and open circular DNA by acid phenol extraction, opened into a full-length linear form by cleavage with the restriction endonuclease SacI, and cloned into lambda gtWES x lambda B. Four different cloned viral DNA molecules were isolated: SRA-1 contains two copies of the 330-base pair terminal redundancy normally found at each end of the linear DNA molecules, but harbors a 63-base pair deletion that spans the site at which the two copies of the terminal redundancy are joined in circular DNA molecules; SRA-2 contains two complete copies of the terminal redundancy; SRA-3 probably contains only one copy of the terminal redundancy but in all other respects appears to be similar to SRA-2; SRA-4 contains a 2,500-base pair deletion that removes all of the src gene (the gene responsible for transformation by ASVs) plus additional nucleotides adjacent to the src gene whose precise locations have not been determined. Transfection of chicken embryo fibroblasts by either SRA-1 or SRA-2 resulted both in the appearance of transformed cells and in the production of infectious virus. These results demonstrate that the cloned DNA molecules are functionally identical to viral DNA produced in vivo; therefore, molecular cloning did not cause any major alterations of the DNA. The infectivity of SRA-1 DNA indicates that the 63 base pairs missing from that molecule are not required for the initiation of viral RNA synthesis, even though the deletion is located in a copy of the terminal redundancy thought to carry a promoter for RNA synthesis. This suggests that the deletion does not remove any sequences required for the initiation of transcription.

Structure of murine sarcoma virus DNA replicative intermediates synthesized in vitro

Moloney murine sarcoma virions synthesize discrete DNA products in vitro which closely resemble those found in vivo shortly after infection. These in vitro products have been isolated by electrophoresis and mapped with restriction endonucleases. In addition to the full-genome-length 6-kilobase pair linear DNA, a 5.4-kilobase pair circular DNA molecule, an incomplete linear DNA molecule, and a 600-base pair molecule were detected. The 6-kilobase pair DNA contained a 600-base pair direct terminal repeat which was missing from the circular form and was partially represented on the incomplete linear DNA molecule. The 600-base pair DNA contained sequences which were present in the 600-base pair direct repeat on the 6-kilobase pair DNA. The order of synthesis and the structure of these molecules detected in the in vitro reaction suggest that they are crucial intermediates in the formation of the final product of in vitro reverse transcription. A model which accounts for the synthesis of all of these molecules during the initial stages of viral replication is suggested.

Molecular cloning of infectious integrated murine leukemia virus DNA from infected mouse cells

The lack of an endonuclease EcoRI site in the AKR murine leukemia virus (MuLV) DNA genome was utilized to molecularly clone, in Charon 4A lambda DNA, integrated infectious AKR MuLV DNA isolated from productively infected mouse cells. Three lambda-mouse recombinants (clones 614, 621, and 623) were selected by virtue of their reactivity with AKR MuLV [32P]cDNA. Clones 614 and 623 contained the complete AKR MuLV DNA flanked by nonviral cell sequences of which no more than 100 base pairs beyond the viral DNA appear to be shared. DNAs from both clones 614 and 623 were highly infectious for mouse cells and yielded N-tropic ecotropic MuLV; the specific infectivity of the DNA and the titer of the derived virus was more than 10-fold higher with 623. Clone 621 contained only some viral DNA and was not infectious under similar conditions.

Transfection of molecularly cloned Friend murine leukemia virus DNA yields a highly leukemogenic helper-independent type C virus

Unintegrated viral DNA was isolated via the Hirt procedure from mouse fibroblasts newly infected with Friend murine leukemia virus (F-MuLV) clone 201, a biologically cloned helper virus isolated from stocks of F-MuLV complex. A physical map of the unintegrated in vivo linear viral DNA was generated for several restriction endonucleases. The supercoiled viral DNA was digested with EcoRI, which cleaved the viral DNA at a unique site. The linearized viral DNA was then inserted into lambda gtWES.lambda B at the EcoRI site and cloned in an approved EK2 host. Eight independent lambda-mouse recombinants were identified as containing F-MuLV DNA inserts by hybridization with F-MuLV 32P-labeled complementary DNA. One of the F-MuLV DNA inserts was 9.1 kilobases (kb) and had the same restriction enzyme sites as the unintegrated linear F-MuLV DNA. Six inserts were 8.5 kb; each lacked a single copy of the terminally redundant sequences of the unintegrated linear viral DNA. One insert was 8.2 kb and contained a 0.9-kb deletion. After digestion with EcoRI, one recombinant DNA preparation containing an 8.5-kb insert was infectious for NIH 3T3 cells. Undigested recombinant DNA was not infectious. The infectivity of the EcoRI-digested DNA followed multihit kinetics, indicating that more than one molecule was required to register as an infectious unit. The virus isolated from this transfection (F-MuLV-57) was NB-ecotropic, helper-independent, and formed XC plaques. Inoculation of this virus into newborn NIH Swiss mice induced leukemia and splenomegaly in greater than 90% of animals within 3 to 4 weeks. The gross and microscopic abnormalities induced by F-MuLV clone 57 were identical to those seen with the original parent stocks of F-MuLV clone 201. These results indicate that this helper-independent F-MuLV can induce a rapid nonthymic leukemia in the absence of the spleen focus-forming virus.

The transforming gene of Moloney murine sarcoma virus

A cleavage map of the Moloney murine sarcoma viral DNA was constructed and compared with that of a spontaneously occurring deletion mutant. By restriction enzyme analysis, it was shown that a region encompassing over 40% of the viral information was not essential for transformation or rescue of the deletion mutant. The transforming region was further localised by analysis of the transforming activity in tissue culture of isolated restriction fragments of linear duoble-stranded sarcoma viral DNA. In each case, DNA fragments that retained transforming activity preserved the cell-derived insertion sequences of the viral genome. Moreover, such transformants invariably expressed RNA specific to this region. By these two approaches, it was possible to demonstrate that the transforming region of the viral genome begins very near or within the cell-derived insertion sequences. Thus, the transforming gene of this mammalian sarcoma virus originates from within the mouse cell genome.

Passage of phenotypes of chemically transformed cells via transfection of DNA and chromatin

DNA was prepared from 15 different mouse and rat cell lines transformed by chemical carcinogens in vitro and in vivo. These DNAs were applied to NIH3T3 mouse fibroblast cultures by using the calcium phosphate transfection technique. DNAs of five donor lines were able to induce foci on the recipient monolayers. Ten other donor DNAs yielded few or no foci. DNAs from control, nontransformed parental cell lines induced few or no foci. Chromosomes were transfected from one donor whose naked DNA was unable to induce foci, and morphologic transformation of recipients was observed. These experiments prove that in five of these cell lines the chemically induced phenotype is encoded in DNA, and the sequences specifying the transformed phenotype behave as a dominant allele in the NIH3T3 recipient cells. The sequences encoding the transformation are likely found on a single fragment of DNA.

Physical map of biologically active Harvey sarcoma virus unintegrated linear DNA

BALB/c JLS V9 cells recently infected with Harvey sarcoma virus-murine leukemia virus (HSV-MuLV) complex contained unintegrated HSV linear DNA of 6.0-kilobase pair mass. The cells also contained two HSV closed circular DNA species along with MuLV-encoded linear and closed circular DNA species. HSV 6.0-kilobase pair linear DNA induced focal transformation upon transfection of NIH 3T3 mouse fibroblasts, and the biological activity of HSV DNA did not require helper MuLV functions. A physical map of restriction endonuclease cleavage sites along HSV 6.0-kilobase pair linear DNA was derived. Comparison of this map with one for Moloney MuLV DNA showed that the HSV and Moloney MuLV genomes are identical near their viral RNA 3' ends.

Molecular cloning of the Harvey sarcoma virus closed circular DNA intermediates: initial structural and biological characterization

Supercoiled Harvey sarcoma virus (Ha-SV) DNA was extracted from newly infected cells by the Hirt procedure, enriched by preparative agarose gel electrophoresis, and digested with EcoRI, which cleaved the viral DNA at a unique site. The linearized Ha-SV DNA was then inserted into lambda gtWESlambda B at the EcoRI site and cloned in an approved EK2 host. Ha-SV DNA inserts from six independently derived recombinant clones have been analyzed by restriction endonuclease digestion, molecular hybridization, electron microscopy, and infectivity. Four of the Ha-SV DNA inserts were identical, contained about 6.0 kilobase pairs (kbp), and comigrated in agarose gels with the infectious, unintegrated, linear Ha-SV DNA. One insert was approximately 0.65 kbp smaller (5.35 kbp) and one was approximately 0.65 kpb larger (6.65 kpb) than the 6.0 kpb inserts. R-looping with Ha-SV RNA revealed that the small (5.35 kbp) insert contained one copy of the Ha-SV RNA. Preliminary restriction endonuclease digestion of the recombinant DNAs suggested that the middle-size inserts contained a 0.65-kbp tandem duplication of sequences present only one in the small-size insert; this duplication corresponded to the 0.65-kpb terminal duplication of the unintegrated linear Ha-SV DNA. The large-size insert apparently contained a tandem triplication of these terminally located sequences. DNA of all three sized inserts induced foci in NIH 3T3 cells, and focus-forming activity could be rescued from the transformed cells by superinfection with helper virus. Infectivity followed single-hit kinetics, suggesting that the foci were induced by a single molecule.

Cloning of integrated Moloney sarcoma proviral DNA sequences in bacteriophage lambda

We have identified integrated proviral DNA sequences of m1 and HT-1 isolates of Moloney sarcoma virus (MuSV) in EcoRI digests of transformed mink cell genomic DNA and have cloned these fragments in bacteriophage lambda. Both the lambda-HT1 phage recombinant, containing a 12.3-kilobase MuSV pair (kb) fragment, and the lambda-m1 phage recombinant, containing a 7.0-kb fragment, possess full copies of the sarcoma viruses along with 5' and 3' host flanking sequences. The MuSV proviral DNA sequences, 6.7 kb for HT-1 and 5.2 kb for m1, are colinear by heteroduplex microscopy with the 1.5-kb difference in size accounted for by two approximately equal to 0.8-kb deleted regions in m1. Both integrated viral genomes are terminally redundant and have integrated at the same site in the provirus but at different sites on the host chromosome. The host sequence flanking integrated HT-1 MuSV have been identified as a single EcoRI restriction fragment of 5.6 kb in normal mink cells.

Infectious murine leukemia virus from DNA of virus-negative AKR mouse embryo cells

DNA from virus-negative AKR mouse embryo cells is infectious for NIH 3T3 cells if the transfected cells are treated with 5-iododeoxyuridine (IdUrd) either before or after addition of the DNA. The virus isolated after transfection of the AKR DNA is an ecotropic murine leukemia virus (MuLV) indistinguishable from endogenous AKR MuLV. The AKR DNA is not infectious in the absence of IdUrd treatment of the recipient cells. DNA from AKR cells treated with IdUrd before DNA isolation is not infectious unless the recipient cells have been treated with IdUrd. Transfected DNA from NIH mouse cells is not infectious even when the recipient cells have been treated with IdUrd. DNA from cells chronically infected with AKR MuLV or Rauscher MuLV is infectious with or without IdUrd treatment of the recipient cells, but the infectivity is not enhanced by IdUrd. The results indicate that the endogenous AKR MuLV DNA genome is potentially infectious. The data are consistent with an IdUrd-sensitive restriction in the recipient NIH 3T3 cells that prevents viral replication from endogenous AKR MuLV DNA but does not prevent viral replication from MuLV DNA of productively infected cells.

Mechanism of transfection of chicken embryo fibroblasts by Rous sarcoma virus DNA

The mechanism of transfection by Rous sarcoma virus DNA was investigated by assaying DNA-mediated transformation under conditions which restricted secondary virus infection. Chicken embryo fibroblasts which were genetically resistant to virus infection as a result of the absence of receptors for virus penetration were also resistant to transformation by integrated or unintegrated Rous sarcoma virus DNA. In addition, DNA of replication-defective Bryan hightiter Rous sarcoma virus was noninfectious, and transformation by DNA of a temperature-sensitive DNA polymerase mutant was temperature sensitive. These results indicated that secondary virus infection was necessary for transformation by Rous sarcoma virus DNA. Since transformation was assayed by colony formation in soft agar, as well as by focus formation, the requirement for secondary virus infection was not an artifact of potential difficulty in detection of foci formed by division of single transformed cells. Therefore, it appeared that donor DNA did not stably transform recipient cells by direct integration. Instead, the results were consistent with the hypothesis that transfection of chicken embryo fibroblasts by Rous sarcoma virus DNA proceeded by transcription of donor DNA, formation of extracellular progeny virus, and secondary virus infection of sensitive cells.

Transfer of Fv-1 locus-specific resistance to murine N-tropic and B-tropic retroviruses by cytoplasmic RNA

A standardized bioassay for transfer of Fv-1 gene-specific resistance to N-tropic and B-tropic murine retroviruses was developed using X plaque reduction in SC-1 (Fv-1-) cells inoculated with virus. Testing of subcellular fractions of restrictive cells showed that the resistance transfer activity was present in the cytoplasmic (microsomal and cytosol) fractions. The activity of the cytoplasmic extract was destroyed by treatment with ribonuclease, but not with deoxyribonuclease or proteases. RNA prepared by phenol-chloroform extraction of mouse tissues, including embryos and livers of weanling mice, transferred Fv-1 locus-specific resistance into DEAE-dextran-treated SC-1 cells. The activity of isolated RNA preparations against virus of the appropriate host-range type has been demonstrated to correspond to the Fv-1 genotypes of the cell sources. The specific transfer of resistance with cellular RNA was effective within a 5- to 6-h period from 2 h before to 4 to 5 after virus infection. Sucrose gradient centrifugation of the RNA showed that the activity sedimented as a broad peak, with an apparent maximum in the 22S region. Affinity chromatography of whole-cell RNA on polyuridylic acid-Sepharose tended to separate more activity into the polyadenylic acid RNA fraction than the non-polyadenylic acid RNA fraction. Except for the reciprocal inhibitory activity for the two host-range virus types, the RNAs of Fv-1n and Fv-1b specificities showed similar properties in all aspects studied.

Helper-independent transformation by unintegrated Harvey sarcoma virus DNA

We have studied the unintegrated infectious DNA of Harvey sarcoma virus (Ha-SV) and Moloney leukemia virus (Mo-MuLV). The source of infectious viral DNA was the Hirt supernatant fraction from cells acutely infected with Ha-SV and Mo-MuLV. To obtain a direct quantitative assay for infectious viral DNA, recipient mouse cells were first exposed to calcium phosphate-precipitated viral DNA and then treated with dimethyl sulfoxide. Infectivity was monitored by focus formation for Ha-SV and XC plaque formation for Mo-MuLV. The viral DNA titration pattern followed single-hit kinetics for both foci and plaques, indicating that a single molecule carried information for each function. Focus-forming and plaque-forming activity were present in different molecules, since these two biological activities could be separated from each other by agarose gel electrophoresis. The focus-forming molecule was linear DNA with a molecular weight of about 4 x 10(6) daltons. The focus-forming activity of the viral DNA was sensitive to EcoRI and resistant to XhoI restriction endonucleases, whereas the plaque-forming activity was resistant to EcoRI and sensitive to XhoI. The generation of helper-independent foci indicates that Ha-SV DNA can transform mouse cells in the absence of helper virus or its proteins.

Transfection of Enterobacteriaceae and its applications

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Infectious primate type C virus proviral DNA in productively infected cells

Cell lines competent to infection by DNA from cultures chronically infected by type C viruses of the simian sarcoma virus and baboon endogenous virus groups were identified. Significant differences were observed in the relative susceptibility of some cell lines to infection by a given proviral DNA. Practical applications of transfection techniques for the separation of viruses from dually infected cultures and to free virus stocks from mycoplasmal contamination are described.

Transfection of Fv-1 permissive and restrictive mouse cells with integrated DNA of murine leukemia viruses

Whole-cell DNA preparations isolated from SC-1 cells chronically infected with N- or B-tropic murine leukemia viruses (MuLV) were tested for infectious activity in an Fv-1n (NIH-3T3) and two Fv-Ib (C57BL/6 and SV-A31) cell cultures. Efficiency of transfection for all DNAs was better in the NIH-3T3 cells than in C57BL/6 or SV-A31 cells; and an [N-tropic MuLV]SC-1 cell DNA preparation was slightly more infectious than a [B-tropic MuLV]SC-1 cell DNA preparation in all three cell cultures, regardless of their Fv-1 genotypes. Progeny viruses from the transfection showed N- or B-tropism corresponding to that of the parent viruses produced by the infected SC-1 cells that were used for the DNA preparation. DNA dose-response studies in NIH-3T3 cells revealed a one-hit mechanism for both the [B-tropic MuLV]SC-1 cell DNA and the [N-tropic MuLV]SC-1 cell DNA preparation. These results demonstrate that, in contrast to virion infection, transfection of N- and B-tropic MuLV with DNA preparations from chronically infected cells is not affected by the Fv-1 gene.

[Molecular biology of tumor viruses]

All classes of vertebrates harbor tumor viruses that are capable of inducing either tumors or leukemias. After infection, their genomes become integral parts of the host cell's genetic material (DNA). Many biological functions such as the capacity to code for the synthesis of new proteins and, in particular, the oncogenic property (oncogen) have already been assigned to specific regions (on physical maps) of their DNA.

In vitro synthesis of infectious DNA of murine leukaemia virus

DNA synthesised in vitro by purified virions of murine leukaemia virus is infectious. Neither RNA nor protein is required for infectivity. Transfection with reverse trancriptase product shows a single-hit dose response and results in the production of complete, infectious virus.

Assay of noninfectious fragments of DNA of avian leukosis virus-infected cells by marker rescue

A marker rescue assay of noninfectious fragments of avian leukosis virus DNAs is describe. DNA fragments were prepared either by sonication of EcoRI-digestion of DNAs of chicken cells infected with wild-type Rous sarcoma virus, with a nontransforming avian leukosis virus, and with a mutant of Rous sarcoma virus temperature sensitive for transformation. Recipient cultures of chicken embryo fibroblasts were treated with noninfectious DNA fragments and infected with temperature-sensitive mutants of Rous sarcoma virus defective in DNA polymerase or in an internal virion structural protein. Wild-type progeny viruses which replicated at the nonpermissive temperature were isolated. Some of the wild-type progeny acquired both the wild-type DNA polymerase and the subgroup specificity of the Rous sarcona virus strain used for preparation of sonicated or EcoRI-digested DNA fragments. Therefore the genetic markers for DNA polymerase and envelope were linked and appeared to be located on the same EcoRi fragment of the DNA of Rous sarcoma virus-infected cells.

Formation and structure of infectious DNA of spleen necrosis virus

The kinetics of formation and the structure of infectious DNA of spleen necrosis virus were determined. Nonintegrated infectious viral DNA first appeared 18 to 24 h after infection of dividing cells and persisted for more than 14 days. The nonintegrated infectious viral DNA was in the form of either a double-stranded linear DNA with a molecular weight of 6 X 10(6), detected in both the cytoplasm and nucleus, or a closed circular DNA of the same molecular weight, detected primarily in the nucleus. Integrated infectious viral DNA appeared soon after the nonintegrated infectious viral DNA and was the predominant form of infectious viral DNA late after infection. Integration of the spleen necrosis virus DNA into the chicken cell genome was demonstrated by three independent criteria. Nucleic acid hybridization indicated that the linear infectious viral DNA had a 5- to 10-fold higher specific infectivity than either the closed circular or integrated infectious viral DNA. Infectious viral DNA did not appear in infected stationary cells, indicating some cellular influence on the formation of infectious viral DNA.

Cleavage map of linear mouse sarcoma virus DNA

Proviral DNA transcribed from the RNA of Moloney murine sarcoma virus was isolated from newly infected cells. Three forms of viral DNA were observed: (i) a linear double-stranded form of 3.4 X 10(6) daltons which constituted the major viral DNA species in the cell, and is thought to be a complete transcript (monomer) of viral RNA; (ii) a fast-sedimenting viral DNA bigger than the monomeric unit which can be either integrated provirls or concatamers; and (iii) covalently closed circles of monomer size representing 5% or less of the total viral DNA in the cell. The linear viral DNA was tested for its susceptibility to restriction endonucleases by electrophoretic analysis of the digestion products and their identification by hybridization with viral RNA or cDNA probes. The linear DNA is not cleaved by endonucleases EcoRI and BamHI. It is cleaved into two fragments by endonucleases HindIII and Hae II, and into three fragments by restriction endonuclease HincII. The fragments of the viral DNA added up to approximately 3.4 X 10(6) daltons; this and the uniform size of the linear DNA indicated that the viral DNA has unique ends and a complexity of 3.4 X 10(6) daltons. The different cleavage fragments were ordered with respect to each other and the 3' end of the viral RNA. It was observed that fragments from both ends of the linear DNA can be hybridized to sequence(s) at the 3' end of murine sarcoma virus RNA; this result suggested the possibility that a short redundant sequence exists at both termini of the genome.

Increased length of DNA made by virions of murine leukemia virus at limiting magnesium ion concentration

Conditions have been developed for reverse transcription by detergent-disrupted virions of Moloney murine leukemia virus which permit synthesis of molecules that appear to be complete transcripts of the 35S RNA subunits. At limiting Mg2+ concentration, DNA is synthesized in good yield, up to a maximum size of about 2.4 X 10(6) daltons. DNA larger than 2 X 10(6) daltons, taken from alkaline sucrose gradients, has no detectable self-complementarity and was protected from digestion by S1 nuclease to an extent of 90% by annealing to 70S RNA. All size classes of DNA made in these reactions are primed with RNA, because all are initiated with a pApdAjunction. To produce such long molecules, it is necessary to keep the concentration of Mg2+ in the reaction mixture below the total concentration of deoxyribonucleoside triphosphates. Under these conditions, degradation of the RNA template is minimized. The rate of DNA synthesis is also slowed by 30 to 50%, but products longer than 5,000 nucleotides, which are not found otherwise, are completed between 3 and 6h of reaction.

Infectious, linear, unintegrated DNA of Moloney murine leukemia virus

A closed circular, double-stranded infectious DNA of Moloney leukemia virus has been described previously. The present report characterizes a second type of infectious, unintegrated viral DNA which is linear, largely double stranded, and of mass comparable to that of the closed circular viral DNA. The linear form is of nonpermuted sequence, and SalI endonuclease cleaves at one site 45% from one end.