Multiple integration sites for Moloney murine leukemia virus in productively infected mouse fibroblasts

Sites of retroviral DNA integration: From basic research to clinical applications

One of the most crucial steps in the life cycle of a retrovirus is the integration of the viral DNA (vDNA) copy of the RNA genome into the genome of an infected host cell. Integration provides for efficient viral gene expression as well as for the segregation of viral genomes to daughter cells upon cell division. Some integrated viruses are not well expressed, and cells latently infected with human immunodeficiency virus type 1 (HIV-1) can resist the action of potent antiretroviral drugs and remain dormant for decades. Intensive research has been dedicated to understanding the catalytic mechanism of integration, as well as the viral and cellular determinants that influence integration site distribution throughout the host genome. In this review, we summarize the evolution of techniques that have been used to recover and map retroviral integration sites, from the early days that first indicated that integration could occur in multiple cellular DNA locations, to current technologies that map upwards of millions of unique integration sites from single in vitro integration reactions or cell culture infections. We further review important insights gained from the use of such mapping techniques, including the monitoring of cell clonal expansion in patients treated with retrovirus-based gene therapy vectors, or patients with acquired immune deficiency syndrome (AIDS) on suppressive antiretroviral therapy (ART). These insights span from integrase (IN) enzyme sequence preferences within target DNA (tDNA) at the sites of integration, to the roles of host cellular proteins in mediating global integration distribution, to the potential relationship between genomic location of vDNA integration site and retroviral latency.

The long terminal repeat of Jaagsiekte sheep retrovirus is preferentially active in differentiated epithelial cells of the lungs

Jaagsiekte sheep retrovirus (JSRV) is the etiologic agent of a contagious bronchioloalveolar carcinoma of sheep known as sheep pulmonary adenomatosis (SPA; ovine pulmonary carcinoma). JSRV is unique among retroviruses because it transforms the alveolar type II cells and the nonciliated bronchiolar cells (Clara cells) of the lungs; these cells are where JSRV is specifically expressed in both naturally and experimentally SPA-affected sheep. In this study, we investigated the cell specificity of JSRV expression. By transient-transfection assays of 23 different cell lines with a reporter plasmid driven by the JSRV long terminal repeat (LTR), pJS21-luc, we found that the JSRV LTR is preferentially active in cell lines derived from type II pneumocytes and Clara cells (MLE-15 and mtCC1-2 mouse cell lines). Reporter assays using progressive 5' deletions of pJS21-luc allowed us to establish that the JSRV enhancers are able to activate the JSRV proximal promoter in MLE-15 and mtCC1-2 cells, but they have very low activity in mouse cells of other lineages (e.g., NIH 3T3). The JSRV enhancers are able to activate heterologous promoters in both MLE-15 and 3T3 cells, although optimal activity is achieved in MLE-15 cells only with the homologous JSRV promoter. Thus, JSRV cell-specific LTR activity appears to result from an interaction between the enhancer elements and the JSRV proximal promoter elements. By mutation analysis, we established that an upstream NF-kappaB-like element appears to be responsible for approximately 50% of the JSRV LTR transcriptional activity in MLE-15 cells. Electrophoretic mobility shift assays showed evidence of a factor(s) that binds to this sequence. Antibody supershift experiments indicated that the factor(s) is not related to NF-kappaB component p50 or p52. This factor also appeared to be present in cells that do not support a high level of JSRV expression. Finally the JSRV(21) LTR contains putative enhancer binding motifs for transcription factors such as hepatocyte nuclear factor 3 (HNF-3) that are involved in lung-specific gene expression. Cotransfection experiments demonstrated that exogenous HNF-3 is able to enhance the expression of pJS21-luc in NIH 3T3 cells, which normally show minimal enhancer activity for the JSRV LTR.

Chromatin structure of recombinant Moloney murine leukemia virus proviral DNAs that contain tax-responsive sequences from human T-cell lymphotropic virus type II in the presence and absence of tax

Human T-cell lymphotropic virus types I and II (HTLV-I and HTLV-II) are replication-competent retroviruses which contain two additional regulatory proteins, tax and rex. tax is a transcriptional transactivator of the HTLV-I or HTLV-II long terminal repeat (LTR) and also of some heterologous promoters. To investigate the mechanism of tax transactivation, we used chimeric Moloney murine leukemia viruses (M-MuLVs) with LTRs containing tax-responsive sequences from the HTLV-II LTR (nucleotides -273 to -32). Mo+HTLV-II+ M-MuLV contained the HTLV II sequences inserted into the wild-type M-MuLV LTR at nucleotide -150, whereas delta Mo+HTLV-II+ M-MuLV contained the same sequences inserted into an M-MuLV LTR lacking its own enhancer region. HTLV-II tax (tax II)-positive mouse cells (15S-5a) infected with Mo+HTLV-II+ M-MuLV or delta Mo+HTLV-II+ M-MuLV showed higher rates of viral transcription in nuclear run-on assays than did infected tax-negative NIH 3T3 cells. The chromatin structure of these viruses was investigated by high-resolution mapping of DNase I-hypersensitive (HS) sites. Three prominent HS sites were associated with HTLV-II sequences in proviral chromatin both in tax-positive and in tax-negative cells. The spacing resembled that of the 21-base-pair (bp) repeats, but the HS sites were displaced approximately 50 bp upstream of the 21-bp repeats. This suggested that cellular proteins bound to the HTLV-II sequences in the presence or absence of tax. No direct effect of tax on chromatin structure was found. These in vivo results were consistent with results of in vitro DNase footprinting studies performed by other investigators.

Intracisternal A-particle genes in Mus musculus: a conserved family of retrovirus-like elements

The structural organization of intracisternal A-particle genes has been studied, using isolates from a mouse gene library in lambda phage Charon 4A. The predominant gene form among the isolates was 7.3 kilobases (kb) in length. R-loops between the 7-kb (35S) A-particle genomic ribonucleic acid and several of these genes were colinear, with no visible evidence of intervening deoxyribonucleic acid sequences. One recombinant was found with an A-particle gene that contained a 1.7-kb deletion. Using the deletion as a reference, the deoxyribonucleic acid and ribonucleic acid homology regions were localized with respect to one another and to the restriction map: the 5' terminus of the ribonucleic acid was several hundred base pairs within the 5' end of the deoxyribonucleic acid homology region. Restriction endonuclease fragments encompassing the 5' and 3' regions of one 7.3-kb gene were separately subcloned into pBR322. Heteroduplexes between the two subclones revealed an approximately 300-base pair segment of terminally redundant sequences. The cloned 3' fragment hybridized with restriction fragments from the 5' end of several other A-particle genes, demonstrating the presence of common (though not necessarily identical) terminally repeated sequences. A-particle genes varied in the occurrence of specific restriction sites at characteristic internal loci. However, heteroduplexes between several variant 7.3-kb genes showed continuous homology regions even when spread under stringent hybridization conditions. The relative abundance of restriction site variants was highly conserved in 12 laboratory strains of Mus musculus, in embryonic and adult tissues of a single inbred strain, and in the SC-1 cell line of feral mouse origin, but appeared to differ in a feral Japanese substrain, Mus musculus molossinus. Some evidence suggests that subsets of A-particle genes may have similar flanking sequences. The results are discussed in terms of the evolution of this multigene family.

Significance of DNase I-hypersensitive sites in the long terminal repeats of a Moloney murine leukemia virus vector

A Moloney murine leukemia virus-derived retroviral vector (N4) carrying the bacterial neomycin resistance gene (neo) was used to study the chromatin configuration of integrated proviral DNA in NIH 3T3-derived cell lines containing one copy of the vector DNA per cell. Three independently obtained cell lines were examined. In two of these cell lines, the vector was introduced by viral infection, while in the third the construct was introduced by DNA transfection. Such transfected cell lines (including the one examined) usually express 10- to 50-fold less virus-specific RNA than do cell lines obtained by viral infection. All three cell lines exhibited similar patterns of DNase I-hypersensitive (HS) sites. Two strong DNase I HS sites were detected in the 5' long terminal repeat, which contains signals required for proper and efficient initiation of viral transcription. One of these sites was found to overlap the viral enhancer sequences, while the other site mapped very close to the start site for viral transcription. A third HS site was detected in nearby internal viral sequences. Only one HS site was found in the 3' long terminal repeat, which contains the signal(s) required for proper addition of a poly(A) tail to viral transcripts. This HS site was located in the region of the viral enhancer. Several weak DNase I HS sites were also found in the cellular sequences adjacent to the integration sites, at different locations in each cell line analyzed. No common pattern of cellular DNase I HS sites was found. These observations suggest that the 5' and 3' long terminal repeats of integrated retroviral proviruses exhibit different chromatin conformations, possibly reflecting the different functions encoded by the otherwise identical sequences, and the DNase I HS sites detected in these studies reflect only a potential for transcription and are not a reflection of the high transcriptional activity characteristic of retroviruses.

Dsi-1, a region with frequent proviral insertions in Moloney murine leukemia virus-induced rat thymomas

Dsi-1 is a region of chromosomal DNA that underwent proviral insertion in 3 of 24 Moloney murine leukemia virus-induced rat thymomas. In one of these tumors, a provirus is also integrated adjacent to the proto-oncogene c-myc. The proviruses in Dsi-1 have been characterized and appear to be complete. The proviruses were located within a 2-kilobase region that contained four prominent DNase I-hypersensitive sites. These hypersensitive sites were observed in Moloney murine leukemia virus-induced thymomas but not in NRK cells. The region of Dsi-1 immediately 3' to the insertions cross-hybridized with human and chicken DNA, indicating that it contains highly conserved sequences. No evidence could be found for the expression of this highly conserved region. Dsi-1 was mapped to mouse chromosome 4. This location demonstrates that Dsi-1 is different from 16 of the known proto-oncogenes (c-abl, c-erbA c-erbB, c-ets-1, c-ets-2, c-fes, c-fos, c-myb, c-myc, c-raf, A-raf, c-Ha-ras, c-Ki-ras, N-ras, c-sis, and c-src) and 12 cellular regions of tumor-associated integrations in retrovirus-induced tumors (c-erbB, Fis-1, int-1, int-2, Mis-1/pvt-1, Mlvi-1, Mlvi-2, c-mos, c-myb, c-myc, Pim-1, and c-Ha-ras). Hybridization experiments indicated that Dsi-1 is probably different from five additional proto-oncogenes (c-fgr, c-fms, c-mos, neu, and c-yes) and from two additional frequent integration regions (lck and Mlvi-3).

The pathophysiology of murine retrovirus-induced leukemias

Murine leukemia viruses (MuLVs) are retroviruses which induce a broad spectrum of hematopoietic malignancies. In contrast to the acutely transforming retroviruses, MuLVs do not contain transduced cellular genes, or oncogenes. Nonetheless, MuLVs can cause leukemias quickly (4 to 6 weeks) and efficiently (up to 100% incidence) in susceptible strains of mice. The molecular basis of MuLV-induced leukemia is not clear. However, the contribution of individual viral genes to leukemogenesis can be assayed by creating novel viruses in vitro using recombinant DNA techniques. These genetically engineered viruses are tested in vivo for their ability to cause leukemia. Leukemogenic MuLVs possess genetic sequences which are not found in nonleukemogenic viruses. These sequences control the histologic type, incidence, and latency of disease induced by individual MuL Vs.

Suppression of leukaemia virus pathogenicity by polyoma virus enhancers

The long terminal repeats (LTRs) of retroviruses contain sequences necessary for the initiation and termination of retroviral transcription. These sequences include promoter elements, transcriptional termination signals and transcriptional enhancer elements. The enhancer elements of Moloney murine leukaemia virus (M-MuLV) are localized in a tandemly repeated region (approximately 75 base pairs (bp) long), which lies 5' to the CAT and TATA promoter elements in the U3 region of the LTR (see Fig. 1). We have shown that the tandem repeats are required both for LTR promoter activity, as measured by transient expression assays, and for biological activity, as measured by production of infectious virus. Furthermore, they can be replaced by transcriptional enhancers from the F101 host-range mutant of polyoma virus without loss of function. We report here that the addition of the polyoma (PyF101) enhancers to the M-MuLV LTRs (either with or without the M-MuLV tandem repeats) results in complete loss of viral leukaemogenicity, even though the virus can replicate to high titres in tissue culture fibroblasts and can establish infection in animals.

Mapping of DNase I-hypersensitive sites in the 5' and 3' long terminal repeats of integrated moloney murine leukemia virus proviral DNA

The chromatin state of integrated Moloney murine leukemia virus (M-MuLV) proviral DNA was investigated. Nuclei from M-MuLV-infected mouse NIH 3T3 cells were digested with limited amounts of DNase I, and hypersensitive (HS) sites were mapped by the indirect end labeling technique. Particular emphasis was placed on the 5' long terminal repeat (LTR), since viral transcription initiates there. M-MuLV proviral DNA showed two strong DNase I-HS sites in the 5' LTR, one coincident with the transcription initiation (cap) site and the other with the transcriptional enhancers. Two weaker DNase I-HS sites were also detected in internal proviral DNA. The 3' LTR also showed a strong HS site in the region of the enhancers, but an HS site at the cap site of the 3' LTR was not detected. Thus, the chromatin configurations of the 5' and 3' LTRs of integrated M-MuLV proviruses appear to be different. The chromatin configuration of M-MuLV proviruses which contain LTR insertions of polyomavirus enhancer sequences was also studied. The 5' LTR of M-MuLV proviruses containing polyoma enhancer sequences substituted for the M-MuLV enhancers showed two strong HS sites, one in the polyoma sequences and one at the cap site. The 5' LTR of M-MuLV proviruses containing polyoma enhancer sequences inserted into the wild-type M-MuLV LTR between the cap site and the M-MuLV enhancers showed three HS sites. Two HS sites corresponded to those of the wild-type M-MuLV LTR, whereas the third mapped to the inserted polyoma sequences. The HS site associated with the inserted polyoma sequences was considerably stronger than the M-MuLV-associated HS sites.

Molecular clones of endogenous murine leukemia virus-related DNA sequences from Balb/c mice: characterization of integration sites

Eight recombinant DNA clones of endogenous murine leukemia virus (MuLV)-related DNA sequences have been isolated from a lambdaphage genomic library of Balb/c mouse DNA. Each clone contains LTR (long terminal repeat) and gag-related sequences, as well as 5' cellular DNA sequences. The virus-related sequences in each clone show an organization similar to that of integrated proviruses; those clones with the greatest length of MuLV-related sequences also contain pol and env gene-related sequences. One clone appears to contain an intact endogenous provirus. Unique cellular DNA segments from three of these clones were subcloned and used as specific "integration site" hybridization probes. Restriction fragment-length polymorphisms (RFLPs) were observed for these integration sites in the DNA of a number of different inbred mouse strains. One provirus-containing fragment was observed only in Balb/c mice while two others were observed in some but not all of the inbred mouse strains tested. Further restriction enzyme mapping of these three loci in the genomic DNA of Balb/c and C3H/HeJ or C57BL/6 mice indicated that the observed RFLPs were due to the presence of proviral DNA sequences in the Balb/c strain at these three integration sites which were lacking in the other mouse strains. The strain distribution of these three provirus insertions suggests that the BE 1 and 7 proviruses were widely, although not universally, present among the progenitors of modern inbred mouse strains, while the BE 16 provirus may be a recent addition to the genome of Balb/c mice.

Construction and characterization of Moloney murine leukemia virus mutants unable to synthesize glycosylated gag polyprotein

Murine leukemia virus (MuLV) encodes two independent pathways for expression of the gag gene. One pathway results in processing and cleavage of the precursor Pr65gag to yield the internal capsid proteins of the virion and is analogous to gag polyprotein precursors for all classes of retroviruses. The other pathway, which is not encoded by several other classes of retroviruses, begins with a glycosylated polyprotein gPr80gag . gPr80gag is synthesized independently of Pr65gag; it contains Pr65gag peptides and additional amino-terminal protein. It is modified by further addition of carbohydrate, exported to the cell surface, and released from the cell but does not appear in virus particles. To investigate the role of glycosylated gag in MuLV infection, two mutants of Moloney MuLV (M-MuLV) deficient for synthesis of gPr80gag but able to synthesize Pr65gag were constructed. The mutants were obtained by substitution into a molecular clone of M-MuLV DNA by DNA from two acutely transforming viruses, Ableson MuLV (Ab-MuLV) and Moloney murine sarcoma virus (M-MSV). Both Ab-MuLV and M-MSV are derived from M-MuLV and they express M-MuLV gag sequences, but some strains do not synthesize glycosylated gag protein. For Ab-MuLV, a 177-base-pair Pst I fragment from the P90 strain containing the initiation codon for Pr65gag was substituted for the equivalent fragment in M-MuLV DNA. For M-MSV, 1.5 kilobases at the 5' end of the genome was substituted. Transfection of the recombined DNAs onto NIH-3T3 cells produced infectious M-MuLV, although the infected cells did not produce gPr80gag. Therefore glycosylated gag is not absolutely required for MuLV replication. Deletion of the glycosylated gag pathway did not significantly reduce the level of virus production, although a minor difference in XC plaque morphology was observed.

Targeted integration of baboon endogenous virus in the BEVI locus on human chromosome 6

The infection of cultured human cells with baboon endogenous virus (BEV) frequently leads to an association of viral DNA with a specific genetic locus (termed BEVI, for baboon endogenous virus infection) on chromosome 6. Restriction endonuclease digestion of DNA from BEV-infected human cells and their derived somatic cell clones frequently revealed a common cellular DNA sequence in the proximity of one of the junctions between cellular DNA and the integrated virus. We propose that a short cellular DNA sequence, repeated on chromosome 6 and separated by unique DNA sequences, presents a high-affinity target for the integration of BEV in human cells.

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.

Cloning of endogenous murine leukemia virus-related sequences from chromosomal DNA of BALB/c and AKR/J mice: identification of an env progenitor of AKR-247 mink cell focus-forming proviral DNA

Recombinant phages containing murine leukemia virus (MuLV)-reactive DNA sequences were isolated after screening of a BALB/c mouse embryo DNA library and from shotgun cloning of EcoRI-restricted AKR/J mouse liver DNA. Twelve different clones were isolated which contained incomplete MuLV proviral DNA sequences extending various distances from either the 5' or 3' long terminal repeat (LTR) into the viral genome. Restriction maps indicated that the endogenous MuLV DNAs were related to xenotropic MuLVs, but they shared several unique restriction sites among themselves which were not present in known MuLV proviral DNAs. Analyses of internal restriction fragments of the endogenous LTRs suggested the existence of at least two size classes, both of which were larger than the LTRs of known ecotropic, xenotropic, or mink cell focus-forming (MCF) MuLV proviruses. Five of the six cloned endogenous MuLV proviral DNAs which contained envelope (env) DNA sequences annealed to a xenotropic MuLV env-specific DNA probe; in addition, four of these five also hybridized to an ecotropic MuLV-specific env DNA probe. Cloned MCF 247 proviral DNA also contained such dual-reactive env sequences. One of the dual-reactive cloned endogenous MuLV DNAs contained an env region that was indistinguishable by AluI and HpaII digestion from the analogous segment in MCF 247 proviral DNA and may therefore represent a progenitor for the env gene of this recombinant MuLV. In addition, the endogenous MuLV DNAs were highly related by AluI cleavage to the Moloney MuLV provirus in the gag and pol regions.

Rauscher murine leukemia virus: molecular cloning of infectious integrated proviral DNA

The integrated proviral genome of Rauscher murine leukemia virus was molecularly cloned in a bacteriophage Charon 4A vector after the proviral sequences were enriched by sequential RPC-5 column chromatography and sucrose gradient centrifugation. A recombinant DNA clone, lambda-RV-1, possessing a 12-kilobase-pair EcoRI insert, was shown to contain the entire 8.8-kilobase-pair leukemia virus genome flanked by rat cellular sequences at the 5' and 3' ends. This DNA fragment was biologically active, inducing the release of virion-associated reverse transcriptase activity with as little as 10 ng of DNA insert. The virus induced XC plaque formation at high titers on NIH/3T3 and BALB/3T3 cells and demonstrated identity with the parental virus in radioimmunoassays for the highly type-specific gag gene-coded p12 protein. The molecularly cloned Rauscher murine leukemia virus should be useful in studying the molecular mechanisms involved in the transformation of specific lymphoid target cells by chronic mouse leukemia viruses.

Molecular cloning of retrovirus-like genes present in multiple copies in the Syrian hamster genome

Endogenous retrovirus-like sequences homologous to intracisternal type-A particle (IAP) genes, which are present in the inbred mouse (Mus musculus) genome, were cloned from a Syrian hamster gene library. A typical hamster IAP gene was 7 kb long and segments homologous to long terminal repeat (IAP) sequences present in Mus musculus IAP genes were located at both ends of the gene. Contrary to the pattern found in the Mus musculus IAP genes, the organization of the cloned hamster IAP genes was not markedly polymorphic and deletion was not observed among these cloned genes. A sequence about 0.8 kb long and located close to the 3' end of the hamster IAP gene was well conserved in both IAP gene families, although they showed less overall homology with one another. The reiteration frequency of the hamster IAP genes was calculated to be 950 copies per haploid genome. Since such IAP genes with the above properties were not found in the genome of the Chinese hamster, whose progenitors diverged from those of the Syrian hamster about 7.5 Myr ago, the integration of a huge number of Syrian hamster IAP genes must have occurred subsequent to such divergence.

Integration of Rous sarcoma virus DNA into chicken embryo fibroblasts: no preferred proviral acceptor site in the DNA of clones of singly infected transformed chicken cells

We analyzed retroviral integration into a host genome by using avian sarcoma virus infection of natural target cells under conditions where secondary integration via virus spread was inhibited. This was accomplished by using the noninfectious pol- env- alpha variant of the Bryan high-titer strain of Rous sarcoma virus. A total of 12 independent Bryan high-titer Rous sarcoma virus-transformed chicken embryo fibroblast clones were obtained and mapped by using restriction endonucleases. Provirus-cell junction fragments were identified with appropriate hybridization probes. We found that expression of the viral genes could occur after proviral integration at many sites on the chicken genome and that there was no apparent preference for specific integration sites.

Endogenous type C retroviral sequences of mice are organized in a small number of virus-like classes and have been acquired recently

We studied endogenous type C virus-related sequences of mice by annealing Moloney murine leukemia virus DNA to agarose gel blot transfers of uninfected mouse cell DNA which had been cleaved with restriction enzymes. We found that many of the endogenous murine leukemia virus-related sequences in mice consist of two organizational classes that are integrated into many different loci. Both of these classes resemble standard murine leukemia virus proviral DNA in both size and sequence organization. All lines of inbred mice examined contained both organizational classes, as did feral isolates of Mus musculus domesticus. However, a related Asian subspecies, Mus musculus molossinus, contained different organizational classes of endogenous murine leukemia virus-related sequences. Among inbred strains and feral isolates of M. musculus domesticus, the murine leukemia virus-related sequences were present at different loci. This suggested that most of these sequences were acquired relatively recently during subspeciation and inbreeding.

Detection and cloning of murine leukemia virus-related sequences from African green monkey liver DNA

By using low-stringency nucleic acid hybridization conditions and specific subgenomic segments of the AKR ecotropic provirus as probes, murine leukemia virus (MuLV)-related sequences were detected in African green monkey (AGM) liver DNA. The MuLV-reactive segments present in restricted AGM DNA ranged from 1.9 kilobases (kb) to greater than 10 kb in size. On the basis of this finding, a 17-kb segment was cloned from a partial EcoRI AGM library in lambda Charon 4A which shared nearly 5 kb of homology with AKR ecotropic MuLV DNA. The MuLV-related sequences detected in restricted preparations of AGM DNA or present in the cloned monkey DNA reacted with probes mapping 2.0 to 7.0 kb from the 5' terminus of the AKR ecotropic provirus. The AGM clone also contained repeated sequences that flanked the MuLV-related segment. Labeled, subgenomic, MuLV-reactive segments of the monkey clone hybridized to multiple restriction fragments of AGM liver DNA, indicating the presence of several copies of the MuLV-related sequences.

Identification and cloning of endogenous retroviral sequences present in human DNA

Using nonstringent annealing conditions and a 2.75-kilobase segment of cloned African green monkey DNA that specifically hybridizes to the proviruses of AKR ecotropic murine leukemia virus (MuLV) and baboon endogenous virus (BaEV) as a probe, we detected related sequences in three different preparations of human brain DNA fragments. The blot-hybridization pattern obtained with cleaved human DNA was similar to that previously reported for the interaction of MuLV cDNA and cleaved mouse DNA and suggested the presence of numerous copies of retrovirus-related sequences in the human genome. The labeled 2.75-kilobase fragment derived from cloned monkey DNA was used to screen a human DNA library in Charon 4A. One clone obtained hybridized to three contiguous MuLV-and BaEV-reactive fragments of the cloned monkey DNA and to multiple fragments of human DNA including a prominent 1.0-kilobase EcoRI fragment also present in the clone.

Intracisternal A-particle genes in Mus musculus: a conserved family of retrovirus-like elements

The structural organization of intracisternal A-particle genes has been studied, using isolates from a mouse gene library in lambda phage Charon 4A. The predominant gene form among the isolates was 7.3 kilobases (kb) in length. R-loops between the 7-kb (35S) A-particle genomic ribonucleic acid and several of these genes were colinear, with no visible evidence of intervening deoxyribonucleic acid sequences. One recombinant was found with an A-particle gene that contained a 1.7-kb deletion. Using the deletion as a reference, the deoxyribonucleic acid and ribonucleic acid homology regions were localized with respect to one another and to the restriction map: the 5' terminus of the ribonucleic acid was several hundred base pairs within the 5' end of the deoxyribonucleic acid homology region. Restriction endonuclease fragments encompassing the 5' and 3' regions of one 7.3-kb gene were separately subcloned into pBR322. Heteroduplexes between the two subclones revealed an approximately 300-base pair segment of terminally redundant sequences. The cloned 3' fragment hybridized with restriction fragments from the 5' end of several other A-particle genes, demonstrating the presence of common (though not necessarily identical) terminally repeated sequences. A-particle genes varied in the occurrence of specific restriction sites at characteristic internal loci. However, heteroduplexes between several variant 7.3-kb genes showed continuous homology regions even when spread under stringent hybridization conditions. The relative abundance of restriction site variants was highly conserved in 12 laboratory strains of Mus musculus, in embryonic and adult tissues of a single inbred strain, and in the SC-1 cell line of feral mouse origin, but appeared to differ in a feral Japanese substrain, Mus musculus molossinus. Some evidence suggests that subsets of A-particle genes may have similar flanking sequences. The results are discussed in terms of the evolution of this multigene family.

Analysis of avian leukosis virus DNA and RNA in bursal tumours: viral gene expression is not required for maintenance of the tumor state

Each of twelve tumors induced by either Rous-associated virus-1 or -2 (RAV-1 or RAV-2) contained a predominant population of cells with ALV proviruses integrated at common sites, consistent with a clonal origin. Seven of nine RAV-2-induced bursal tumors contained single proviruses, and all seven solitary proviruses had suffered deletions. The detailed structures of four of these proviruses show that major deletions had occurred near or at the 5' ends, spanning sequences potentially important in the production of viral RNA. One provirus also lacked most of the information coding for the replicative functions of the virus. Restriction maps suggest that these four proviruses were inserted in similar regions of the host genome. We have studied virus-specific RNA in four bursal tumors and four cell lines derived from bursal tumors. No normal viral RNA species were detectable in three tumors containing single aberrant proviruses. However, transcripts of 2.2. kb which reacted only with a hybridization probe specific for the 5' end of viral RNA were observed in one of these three tumors. Analogous species, varying in length from 1.5 to 6.0 kb, were observed in a fourth bursal tumor with multiple proviruses and in all four cell lines. (This tumor and the cell lines also contained normal species of ALV mRNA and apparently normal proviral DNA). The structures of the aberrant proviruses and the absence of normal viral RNA in some tumors indicate that expression of viral genes is not required for maintenance of the tumor phenotype. In at least some cases, the mechanism of oncogenesis may involve stimulation of transcription of flanking cellular sequences by a viral promoter.

Avian leukosis virus-induced tumors have common proviral integration sites and synthesize discrete new RNAs: oncogenesis by promoter insertion

Unlike other RNA tumor viruses, avian leukosis viruses (which cause lymphomas and occasionally other neoplasms) lack discrete "transforming genes". We have analyzed the virus-related DNA and RNA of avian leukosis virus (ALV)-induced tumors in an attempt to gain insight into the mechanism of ALV oncogenesis. Our results show that viral gene products are not required for maintenance of neoplastic transformation. Primary and metastatic tumors are clonal and thus presumably derived from a single infected cell. Most importantly, tumors from different birds have integration sites in common. Tumor cells synthesize discrete new poly(A) RNAs consisting of viral sequences covalently linked to cellular sequences. These RNA species are expressed at high levels in tumor cells. Our results suggest that in lymphoid tumors, an ALV provirus is integrated adjacent to a specific cellular gene, and the insertion of the viral promoter adjacent to this gene results in its enhanced expression, leading to neoplasia. These results have potentially important implications for the mechanism of non-viral carcinogenesis.

Fate of unintegrated viral DNA in Fv-1 permissive and resistant mouse cells infected with murine leukemia virus

We have found that levels of unintegrated linear viral DNA were nearly identical in several Fv-1 resistant cell lines, whereas levels of closed circular viral DNA are markedly reduced in these resistant cells, to the same extent as virus production (P. Jolicoeur and E. Rassart, J. Virol. 33:183-195, 1980). To determine the fate of linear viral DNA made in resistant cells we performed pulse-chase experiments, labeling viral DNA with 5-bromodeoxyuridine and following it with a thymidine chase. 5-Bromodeoxyuridine-labeled viral DNA (HH) recovered by banding on cesium chloride gradients was sedimented on neutral sucrose density gradients or separated by the agarose gel-DNA transfer procedure and detected by hybridization with complementary DNA. Levels of linear viral DNA made in Fv-1(b/b) (JLS-V9 and SIM.R) and Fv-1(n/n) (NIH/3T3 and SIM) cells were found to decrease during the chase period at about the same rate in permissive and nonpermissive conditions, indicating that linear viral DNA is not specifically degraded in Fv-1 resistant cells. Levels of the two species of closed circular viral DNA made in Fv-1 permissive cells increased relative to the levels of linear DNA during the chase period. This confirmed the precursor-product relationship between linear DNA and the two species of circular DNA. In Fv-1 resistant cells, this apparent conversion of linear viral DNA into circular forms was not seen, and no supercoiled viral DNA could be detected. To determine whether the transport of linear viral DNA from the cytoplasm into the nucleus was prevented by the Fv-1 gene product, SIM.R cells were fractionated into cytoplasmic and nuclear fractions, and viral DNA was detected in each fraction by the agarose gel-DNA transfer procedure. Levels of linear viral DNA were nearly identical in both cytoplasmic and nuclear fractions of permissive or resistant cells. Circular viral DNA could be detected in the nuclear fraction of permissive cells, but not in that of resistant cells. A pulse-chase experiment was also performed with SIM.R cells. During the thymidine chase period, linear viral DNA was seen to accumulate in nuclei of both permissive and resistant cells, whereas supercoiled viral DNA accumulated only in nuclei of permissive cells. These results indicate that the Fv-1 gene product does not interfere with the transport of linear viral DNA into the nucleus. Our data also suggest that the Fv-1 restriction does not operate through a degradation process. Therefore, the Fv-1 gene product could either block the circularization of linear viral DNA directly or promote the synthesis of a faulty linear viral DNA whose defect (yet undetected) would prevent its circularization.

Isolation of recombinant DNA clones carrying complete integrated proviruses of Moloney murine leukemia virus

EcoRI DNA fragments from a Moloney murine leukemia virus (M-MuLV)-infected mouse fibroblast line (M-MuLV clone A9) were cloned in lambda phage Charon 4A cloning vector to derive clones containing integrated M-MuLV proviral DNA. A 10- to 16-megadalton class of EcoRI fragments was chosen for cloning, based on (i) its ability to induce XC-positive virus upon transfection of NIH/3T3 cells, and (ii) its content of a 0.8-megadalton viral KpnI fragment diagnostic for M-MuLV. Six recombinant DNA clones were isolated which contain a complete M-MuLV provirus, as judged by (i) restriction endonuclease mapping and (ii) the fact that all of the clones gave rise to XC-positive, NB-tropic virus upon DNA infection in NIH/3T3 cells. The sizes of the inserts were 12.0 (for three clones) or 12.5 megadaltons (for three clones). Restriction mapping indicated that these six clones represent five different M-MuLV proviral integrations into different cellular DNA sites.

Identification of ecotropic proviral sequences in inbred mouse strains with a cloned subgenomic DNA fragment

A specific probe for detecting ecotropic murine leukemia virus sequences was constructed by cloning a 500-base-pair DNA segment, corresponding to a portion of the env region of the AKR ecotropic virus, in a pBR322/Escherichia coli K-12 host/vector system. This probe was used to screen the cellular DNAs of six inbred strains of mice for the presence of ecotropic retroviral DNA sequences by the Southern blot hybridization procedure. Three copies of ecotropic viral DNA were detected in AKR/N (a high-ecotropic virus strain) and two were found in BALB/c (a low-ecotropic virus strain) DNAs. As expected, no sequences reactive with this probe were found in NFS mouse DNA (a virus-negative strain). However, cellular DNA sequences that reacted strongly with the ecotropic-specific DNA probe were detected in certain NZB, C57L, and 129 mice (all virus-negative strains). In contrast to the reactive sequences in AKR and BALB/c, the reactions were chiefly associated with EcoRI segments that were subgenomic in size.

DNA of avian myeloblastosis-associated virus type 2 integrates at multiple sites in the chicken genome

The cellular sites of integration of the avian myeloblastosis-associated virus type 2 (MAV-2) DNA have been examined by Southern blot analysis of cellular DNA from infected cloned and uncloned chicken embryonic fibroblasts. Provirus-cell juncture fragments were not detected in restriction enzyme digests of DNA from MAV-2-infected uncloned cells. However, each MAV-2-infected cell clone examined produced a unique set of junctive bands. Thse findings indicate that multiple sites of integration exists for MAV-2 proviruses in cellular DNA.

Structure of Moloney murine leukemia viral DNA: nucleotide sequence of the 5' long terminal repeat and adjacent cellular sequences

Some unintegrated and all integrated forms of murine leukemia viral DNA contain long terminal repeats (LTRs). The entire nucleotide sequence of the LTR and adjacent cellular sequences at the 5' end of a cloned integrated proviral DNA obtained from BALB/Mo mouse has been determined. It was compared to the nucleotide sequence of the LTR at the 3' end. The results indicate: (i) a direct 517-nucleotide repeat at the 5' and 3' termini; (ii) 145 nucleotides out of 517 nucleotides represent sequences between the 5'-CAP nucleotide and 3' end of the primer tRNA (strong-stop DNA); (iii) an 11-nucleotide inverted repeat is present at the ends of the 5'-LTR and a total of 17 out of 21 nucleotides at the termini are inverted repeats; (iv) sequences CAATAAAAG (at positions -24 to -31) and CAATAAAC (at positions +46 to +53) resembling the hypothetical DNA-dependent RNA polymerase II promoter site can be identified in the 5'-LTR; (v) the sequence GAAA appears to be repeated on both sides of the junction of viral and cellular sequences; and (vi) in analogy with the bacterial transposons, the presence of an inverted repeat sequence at the termini of 5'-LTR suggests that M-MLV also has the integration properties of a transposon.

Chromatin conformation of integrated Moloney leukemia virus DNA sequences in tissues of BALB/Mo mice and in virus-infected cell lines

The technique of preferential DNase I digestion of transcriptionally active chromatin regions was used to study the structural organization of integrated Moloney murine leukemia virus (M-MuLV) proviral sequences in various cells carrying integrated viral genomes. BALB/Mo mice, which carry M-MuLV as an endogenous virus at a single Mendelian locus, were used to examine the genetically transmitted viral genome copy and additional M-MuLV sequences acquired somatically during leukemogenesis. It has been shown previously that M-MuLV genome expression in these mice is restricted to lymphatic target tissues. In young homozygous BALB/Mo mice carrying one M-MuLV genome copy per haploid mouse genome in all cells we found that the genetically transmitted viral genome copy was in a preferentially DNase I-sensitive conformation in lymphatic target tissues, whereas in nontarget tissues the same sequence was not preferentially DNase I sensitive. This suggests that the chromatin conformation and the transcriptional activity of the integrated proviral genome are related to and probably determined by the state of cellular differentiation. In target tissues from BALB/Mo mice examined at different ages and in different stages of leukemogenesis the majority of the new somatically acquired M-MuLV sequences were preferentially DNase I digestible. A very similar pattern of DNase I digestibility was observed in target tissues from BALB/c mice exogenously infected with M-MuLV. This shows that in these tissues somatically acquired proviral sequences integrate preferentially or exclusively at sites of the host genome in which they are in a transcriptionally active chromatin conformation. Alternatively, the chromatin structure of the respective host genome region may be changed after the integration of viral DNA. In nontarget tissues from BALB/Mo mice the M-MuLV-specific sequences remained DNase I resistant throughout the lives of the animals. A different pattern of DNase I digestibility was observed in virus-infected cell lines which had been produced by low-multiplicity infection, cloned, and selected for virus production. When cell lines harboring different numbers of M-MuLV proviral copies were examined, it was found that a minority of the proviral sequences (on the average only one M-MuLV genome copy per haploid mouse genome) were preferentially digestible by DNase I, independent of the total number of proviral genome copies present. This suggests that the chromatin conformation of newly acquired proviral sequences is influenced by the state of differentiation of the infected cell or the way infected cells are selected or both.

Characterization of avian myeloblastosis-associated virus DNA intermediates

The major species of unintegrated linear viral DNA identified in chicken embryonic fibroblasts infected with either the avian myeloblastosis-associated viruses (MAV-1, MAV-2) or the standard avian myeloblastosis virus complex (AMV-S) has a mass of 5.3 X 10(6) daltons. An additional minor DNA component observed only in AMV-S-infected cells has a mass of 4.9 X 10(6) daltons. The unintegrated linear viral DNAs and integrated proviruses of MAV-1 and MAV-2 have been analyzed by digestion with the restriction endonucleases EcoRI and HindIII. MAV-2 lacks a HindIII site present in MAV-1. These fragments have been compared to those generated by EcoRI and HindIII digestion of linear viral DNAs of AMV-S. Restriction enzyme digestion of AMV-S viral DNA produced unique fragments not found with either MAV-1 or MAV-2 viral DNAs. The major viral component present in AMV-S stocks has the HindIII restriction pattern of MAV-1. Restriction enzyme analysis of the 5.3 X 10(6)-dalton unintegrated MAV viral DNAs and their integrated proviruses suggests that the DNAs have a direct terminal redundancy of approximately 0.3 megadaltons and integrate colinearly with respect to the unintegrated linear DNA.

Distribution of endogenous murine leukemia virus DNA sequences among mouse chromosomes

We used mouse-Chinese hamster somatic cell hybrids which lose mouse chromosomes to examine the distribution of murine leukemia virus DNA sequences in the genome of A/HeJ mice. We analyzed total cellular DNA from various hybrid clones for the presence of viral sequences by molecular hybridization and used the Southern blot hybridization procedure to identify viral DNA in cellular restriction endonuclease fragments. Our results show that murine leukemia virus DNA sequences are distributed among many mouse chromosomes in this strain. Chromosome 4 was shown to contain murine leukemia virus DNA sequences.

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.

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.