Genetic determinants of feline leukemia virus-induced lymphoid tumors: patterns of proviral insertion and gene rearrangement.

The genetic basis of feline leukemia virus (FeLV)-induced lymphoma was investigated in a series of 63 lymphoid tumors and tumor cell lines of presumptive T-cell origin. These were examined for virus-induced rearrangements of the c-myc, flvi-2 (bmi-1), fit-1, and pim-1 loci, for T-cell receptor (TCR) gene rearrangements, and for the presence of env recombinant FeLV (FeLV-B). The myc locus was most frequently affected in naturally occurring lymphomas (32%; n = 38) either by transduction (21%) or by proviral insertion (11%). Proviral insertions were also common at flvi-2 (24%). The two other loci were occupied in a smaller number of the naturally occurring tumors (fit-1, 8%; pim-1, 5%). Examination of the entire set of tumors showed that significant numbers were affected at two (19%) or three (5%) of the loci. Occupation of the fit-1 locus was observed most frequently in tumors induced by FeLV-myc strains, while flvi-2 insertions occurred with similar frequency in the presence or absence of obvious c-myc activation. These results suggest a hierarchy of mutational events in the genesis of feline T-cell lymphomas by FeLV and implicate insertion at fit-1 as a late progression step. The strongest links observed were with T-cell development, as monitored by rearrangement status of the TCR beta-chain gene, which was positively associated with activation of myc (P < 0.001), and with proviral insertion at flvi-2 (P = 0.02). This analysis also revealed a genetically distinct subset of thymic lymphomas with unrearranged TCR beta-chain genes in which the known target loci were involved very infrequently. The presence of env recombinant FeLV (FeLV-B) showed a negative correlation with proviral insertion at fit-1, possibly due to the rapid onset of these tumors. These results shed further light on the multistep process of FeLV leukemogenesis and the relationships between lymphoid cell maturation and susceptibility to FeLV transformation.     

Integration of New Endogenous Mouse Mammary Tumor Virus Proviral DNA at Common Sites in the DNA of Mammary Tumors of C3Hf Mice and Hypomethylation of the Endogenous Mouse Mammary Tumor Virus Proviral DNA in C3Hf Mammary Tumors and Spleens

To understand the molecular mechanisms by which the endogenous murine mammary tumor virus (MuMTV) proviruses are expressed and produce late-occurring mammary tumors in C3Hf mice, we analyzed, by the use of restriction enzymes and the Southern transfer procedure, genomic DNA from normal organs of mammary tumor-bearing and tumor-free mice and from 12 late-occurring C3Hf mammary tumors. We found, by using the restriction enzymes EcoRI and HindIII, that in addition to the preexisting endogenous MuMTV proviruses, new MuMTV-specific proviral DNA was integrated into new sites in the host genome in all 12 of the tumors that we examined. PstI digests of C3Hf tumor DNA revealed that the new proviral DNA found in C3Hf tumors was of endogenous origin. Moreover, the respective sizes of at least one of the new DNA fragments generated by EcoRI or HindIII digestion were the same in at least 50% of the C3Hf tumors analyzed, suggesting that the integration site of this new proviral DNA could be at the same location in the host genome of these tumors. Our results may imply that mammary tumorigenesis in C3Hf mice results from activation of cellular oncogenes by an MuMTV proviral DNA promoter. Specific hypomethylation of MuMTV proviral DNA was detected in the mammary tumors and spleens of C3Hf tumor-bearing mice. Our results indicated that most, if not all, of the hypomethylated MuMTV proviral DNA sequences were derived from the endogenous MuMTV provirus located at the MTV-1 locus, a locus responsible for the production of MuMTV antigens and increased incidence of mammary carcinoma in C3Hf mice. In spleens of non-tumor-bearing mice of ages 3, 6, 9, and 12 months, there was progressive hypomethylation of proviral DNA with increasing age, suggesting a possible correlation between demethylation of MuMTV proviral DNA in the spleens of C3Hf mice and the expression of endogenous MuMTV.     

Comparison of endogenous murine leukemia virus proviral organization and RNA expression in 3-methylcholanthrene-induced and spontaneous thymic lymphomas in RF and AKR mice.

3-Methylcholanthrene-induced T-cell thymic lymphomas in RF mice were examined for involvement of murine leukemia virus (MuLV)-related sequences in leukemogenesis. Both the expression of MuLV-related RNA species and the organization of endogenous MuLV proviral DNA were analyzed. Of 27 primary tumors examined, only 5 exhibited elevated MuLV-related RNA species homologous to xenotropic specific env DNA. None of these RNA species hybridized with ecotropic p15E DNA sequences. Only two of these five tumors contained MuLV-like RNA species that hybridized with ecotropic MuLV long terminal repeat sequences, despite the probe's ability to detect both ecotropic MuLV and mink cell focus-inducing viral RNA. No muLV resembling mink cell focus-inducing virus whose expression could be correlated with lymphomagenesis was detected in either preleukemic thymocytes, primary 3-methylcholanthrene-induced thymic tumors, tumors passaged in vivo, or cell lines derived from tumors. Restriction endonuclease analysis of DNA from both primary tumors and cell lines failed to reveal either proviral DNA with recombinant env genes or rearrangement of endogenous MuLV proviruses. Therefore, chemically induced lymphomagenesis in RF mice appears different from the spontaneous lymphomagenic process in AKR mice with respect to the involvement of endogenous MuLV sequences.     

Analysis of wild-type and mutant SL3-3 murine leukemia virus insertions in the c-myc promoter during lymphomagenesis reveals target site hot spots, virus-dependent patterns, and frequent error-prone gap repair

The murine leukemia retrovirus SL3-3 induces lymphomas in the T-cell compartment of the hematopoetic system when it is injected into newborn mice of susceptible strains. Previously, our laboratory reported on a deletion mutant of SL3-3 that induces T-cell tumors faster than the wild-type virus (S. Ethelberg, A. B. Sorensen, J. Schmidt, A. Luz, and F. S. Pedersen, J. Virol. 71:9796-9799, 1997). PCR analyses of proviral integrations in the promoter region of the c-myc proto-oncogene in lymphomas induced by wild-type SL3-3 [SL3-3(wt)] and the enhancer deletion mutant displayed a difference in targeting frequency into this locus. We here report on patterns of proviral insertions into the c-myc promoter region from SL3-3(wt), the faster variant, as well as other enhancer variants from a total of approximately 250 tumors. The analysis reveals (i) several integration site hot spots in the c-myc promoter region, (ii) differences in integration patterns between SL3-3(wt) and enhancer deletion mutant viruses, (iii) a correlation between tumor latency and the number of proviral insertions into the c-myc promoter, and (iv) a [5'-(A/C/G)TA(C/G/T)-3'] integration site consensus sequence. Unexpectedly, about 12% of the sequenced insertions were associated with point mutations in the direct repeat flanking the provirus. Based on these results, we propose a model for error-prone gap repair of host-provirus junctions.     

Induction of clonal monocyte-macrophage tumors in vivo by a mouse c-myc retrovirus: rearrangement of the CSF-1 gene as a secondary transforming event.

A mouse retrovirus containing the c-myc oncogene was found to induce tumors of mononuclear phagocytic cells in vivo. All tumors expressed the c-myc retroviral gene but not the endogenous c-myc gene (with one exception), and virtually all tumors were clonal with a unique proviral integration. This observation, coupled with a lag time in tumor formation, suggests that a second event, in addition to c-myc proviral integration, is necessary for the generation of neoplastic cells in vivo. All of the tumor cells expressed high levels of mRNA for both the putative colony-stimulating factor 1 (CSF-1) receptor (c-fms proto-oncogene product), as well as the c-fos proto-oncogene. Although all of the tumor cells proliferated in culture without the addition of exogenous CSF-1, which is required for the proliferation of primary macrophages partially transformed by the same c-myc retrovirus, several phenotypes were observed with respect to the expression of CSF-1 and granulocyte-macrophage CSF and to their growth factor responsiveness. The proliferation of one tumor, which secreted high levels of CSF-1, was blocked by specific anti-CSF-1 serum. This tumor was found to express altered CSF-1 mRNA and to have a DNA rearrangement at the CSF-1 locus. In this particular case, the data indicate that a CSF-1 gene rearrangement was the secondary event in development of the tumor. The pleiotropy of phenotypes among the other tumors indicated that there are a variety of other mechanisms for such secondary events which can be investigated with this system.     

Genetic background affects integration frequency of ecotropic proviral sequences into the mouse germ line.

Germ line acquisition of ecotropic proviruses occurs at a high frequency in the progeny of SWR/J-RF/J hybrid mice carrying two genetically linked RF/J ecotropic proviral loci, Emv-16 and Emv-17 (N. A. Jenkins and N. G. Copeland, Cell 43:811-819, 1985). To determine if genetic background affects proviral integration frequency, I analyzed a series of crosses in which the two RF/J proviral loci were transferred onto different provirus-negative background strains. Unlike SWR/J-RF/J hybrid progeny, few CBA/CaJ-RF/J hybrid mice were identified that carried new germ line proviral loci. These results indicate that genetic factors other than the linked RF/J proviral loci contribute to the increased frequency of germ line provirus integration seen in the SWR/J-RF/J hybrids. The frequency of proviral acquisition appeared to increase when females carrying Emv-16, Emv-17, and at least one new proviral locus were further backcrossed, suggesting that integration frequency can be increased by genetic manipulation. The breeding data are consistent with the hypothesis that virus from the mother infects the egg or the early embryo. Analysis of the transmission frequency and cosegregation patterns of new proviral loci indicated that viral integration occurs after the first round of DNA replication and before the germ line is set aside during embryogenesis, with a majority of viral integrations occurring at the two-cell stage of development, and independent viral integrations can occur in the same or in different cells of the embryo.     

DNA repair in the c-myc proto-oncogene locus: possible involvement in susceptibility or resistance to plasmacytoma induction in BALB/c mice.

This report describes an unexpected difference in the efficiency of removal of UV-induced DNA damage in the c-myc locus in splenic B lymphoblasts from two inbred strains of mice. In cells from plasmacytoma-resistant DBA/2N mice, 35% of UV-induced damage in the regulatory and 5' flank of c-myc is removed by 12 h. However, in cells from plasmacytoma-susceptible BALB/cAn mice, damage is not removed from this region. In the protein-encoding region and 3' flank of c-myc as well as in two dihydrofolate reductase gene fragments, UV damage is repaired with similar efficiency in B lymphoblasts from both strains of mice. Furthermore, in the protein-encoding portion and 3' flank of c-myc, damage is selectively removed from only the transcribed strand. No repair is detected in the nontranscribed strand. In contrast, DNA repair in the 5' flank of c-myc is not strand specific; in DNA from DBA/2N cells, UV damage is rapidly removed from both the transcribed and nontranscribed strands. In BALB/cAn cells no repair was detected in either strand in the 5'flank, consistent with the results with double-stranded, nick-translated probes to this region of c-myc. In addition to the repair studies, we have detected post-UV-damage formation: in most of the genes studied, we find that additional T4 endonuclease-sensitive sites are formed in the DNA 2 h after irradiation. Our findings provide new insights into the details of gene-specific and strand-specific DNA repair and suggest that there may be close links between DNA repair and B-cell neoplastic development.     

MoMuLV proviral integrations identified by Sup-F selection in tumors from infected myc/pim bitransgenic mice correlate with activation of the gfi-1 gene.

Infecting mice with a mutant Moloney murine leukemia virus which contains the bacterial suppressor tRNA supF in its LTR allows rapid cloning of proviral integration sites from genomic tumour DNA. In a previous study Emu pim-1/Emu L-myc bitransgenic mice had been inoculated neonatally with MoMuLV supF virus. The retroviral infection led to acceleration of lymphomagenesis indicating the proviral activation of further oncogenes cooperating with myc and pim-1 in tumour development. Using a functional supF screen for analysis of genomic mouse tumour DNA libraries which had been constructed in the phage vector EMBL3A, a common proviral integration site on mouse chromosome 5 was cloned and found to be identical to the proviral integration site evi-5 which has recently been identified in an AKXD T-cell lymphoma and which is located 18 kb upstream of the gfi-1 gene. Tumours bearing evi-5 integrations showed an enhanced gfi-1 expression level suggesting that gfi-1 is the target gene for insertions at the evi-5 locus. Together with three other previously described Moloney integration clusters all responsible for enhanced gfi-1 expression the number of tumours from infected double transgenic Emu L-myc/Emu pim-1 transgenic mice with retrovirally activated gfi-1 added up to 53% underscoring the role of GFI-1 as an effective collaborator for MYC and PIM-1 in the process of lymphomagenesis.     

Methylation and amplification of mouse mammary tumor virus DNA in normal, premalignant, and malignant cells of GR/A mice.

The methylation and amplification of mouse mammary tumor virus (MuMTV) proviral DNA was investigated in normal, premalignant, and malignant tissues of GR/A mice. The proviral methylation pattern was examined with the restriction enzyme HhaI, which fails to cleave methylated DNA. MuMTV proviral DNA from liver, kidney, and heart was highly methylated. Proviral DNA was somewhat undermethylated in mammary gland cells from virgin and lactating mice and extensively undermethylated in cells from premalignant outgrowths, pregnancy-dependent tumors, and pregnancy-independent tumors. The restriction enzyme SacI was used to detect additional proviruses in the same cells. No additional proviral copies of MuMTV were detected in liver, kidney, or heart cells or in mammary gland cells from virgin mice. Some mammary gland cells from lactating mice appeared to contain additional copies of the endogenous, highly oncogenic GT-MTV-2 provirus. Premalignant outgrowth, pregnancy-dependent tumor, and pregnancy-independent tumor cells contained an average of two to three additional copies per cell of the GT-MTV-2 provirus. Thus, neoplasia in GR/A mice was directly associated with quantized increases in MuMTV proviral DNA undermethylation and GR-MTV-2 proviral DNA amplification. Restriction enzyme analysis suggested that premalignant outgrowths and pregnancy-dependent tumors both consisted largely of heterogenous cell populations, although some evidence of clonal dominance was detected.     

Spontaneous germ line virus infection and retroviral insertional mutagenesis in eighteen transgenic Srev lines of mice.

SWR/J-RF/J hybrid mice spontaneously acquire new germ line ecotropic proviruses at high frequency. In the studies described here, we used these hybrids to produce 18 transgenic mouse lines, each carrying a single newly acquired Srev locus (SWR/J-RF/J ecotropic proviral locus). All of the newly acquired proviruses identified in mosaic founder SWR/J-RF/J mice that could be transmitted through the germ line were also present in somatic tissues, demonstrating that viral integration occurred before the germ line was set aside from the somatic lineages. Quantitative analysis of proviral DNA copy numbers in somatic and germinal tissues of mosaic founder parents combined with structural analysis of Srev loci indicated that these proviruses are acquired after multiple rounds of somatic viral reinfection and that most of these viral integration events occurred after DNA replication in the zygote and before DNA replication in the four-cell embryo. The frequency of provirus acquisition in Srev lines that expressed the infectious ecotropic virus was similar to that in SWR.RF mice carrying Emv-16 and Emv-17, suggesting that the chromosomal integration site of the parental locus is not an important determinant for high-frequency provirus acquisition. The frequency of recessive lethal mutations induced by spontaneous viral integration was 5%, which was similar to that induced by preimplantation embryo infection. This approach represents a simple and viable strategy for inducing and studying mutations that affect mammalian development.     

Changes in thymocyte proliferation at different stages of viral leukemogenesis in AKR mice

Proliferation in total populations of thymocytes from control AKR mice or AKR mice injected intrathymically with MCF 69L1 virus was measured by flow cytometry of acridine orange-stained cells. Cell sorting experiments showed that the majority subpopulations of small cortical and medullary thymocytes in control mice were noncycling and were predominantly in the Go phase of the cell cycle. Of the 15 to 20% cycling thymic lymphoblasts, approximately 50% were in the G1 phase, 35% were in the S phase, and 15% were in the G2 + M phases of the cell cycle. Cycling cells appeared to consist of a major subpopulation with low RNA content and a minority subpopulation with high RNA content. In virus-injected mice, no changes in cell cycling were observed at stage I of leukemogenesis (30 to 40 days postinjection), at which time infection of thymocytes by MCF virus is maximum and constant but no clonality is evident. Thus, MCF virus infection of thymocytes per se does not appear to alter cell proliferation. Increased cell cycling and a shift in cell cycle distribution to more cells in G1 was observed at stage II of leukemogenesis (50 to 60 days postinjection), at which time a clonally expanded cell population is known to emerge in thymuses of injected mice. Acridine orange staining resolved these novel cycling cells from subpopulations of normal thymic lymphoblasts on the basis of intermediate RNA content. The transition from stage II to stage III (50 to 60 days postinjection) was accompanied by the outgrowth of a major cycling population with a distinct, often increased, RNA content. As a result, the residual "normal" background of cycling cells often observed in stage II was markedly reduced or completely absent by stage III. Populations of cycling blasts from mice with frank leukemia differed from those at stage III by a variability in mean RNA content and in cell cycle distribution indicative of individual tumor heterogeneity. In addition, thymomas often contained multiple populations of cycling blasts that could be resolved by their discrete RNA distributions. Simultaneous staining of DNA and RNA by acridine orange appears particularly well-suited for studying a heterogeneous population of cycling and noncycling cells represented by mouse thymus. This method has permitted a rapid and quantitative analysis of cell cycle parameters at progressive stages of viral leukemogenesis in AKR mice.