Molecular cloning and characterization of a leukemia-inducing myeloproliferative sarcoma virus and two of its temperature-sensitive mutants.

The myeloproliferative sarcoma virus (MPSV) induces extensive hematopoietic changes, including spleen foci in adult mice, and transforms fibroblasts in vitro. NRK nonproducer cell lines of MPSV and ts temperature-sensitive mutants were analyzed by restriction enzyme digestion and Southern blotting. EcoRI fragments containing the proviral DNAs of MPSV and two temperature-sensitive mutants and rat cellular sequences homologous to c-mos were molecularly cloned. By comparing restriction enzyme cleavage sites, it was shown that the MPSV genome consists only of sequences related either to Moloney murine leukemia virus or to the c-mos mouse oncogenic sequences. Two regions of fragment heterogeneity were observed: (i) in the defective pol gene, where MPSV and the two cloned temperature-sensitive mutants were different from Moloney murine sarcoma virus and from each other, although MPSV wild-type retained more of the pol gene than any of the Moloney murine sarcoma virus isolates; (ii) in the area 3' to the mos gene, which was identical in MPSV and its temperature-sensitive mutants but different from other Moloney murine sarcoma virus variants. Transfection of cloned MPSV DNA in RAT4 cells and virus rescue on infection with Friend murine leukemia virus yielded MPSV which transformed fibroblasts in vitro and also induced spleen foci in adult mice, thus proving that both properties are coded by the same viral genome.     

Temperature-sensitive viral RNA expression in Moloney murine sarcoma virus ts110-infected cells.

We examined the mos-specific intracellular RNA species in 6m2 cells, an NRK cell line nonproductively infected with the ts110 mutant of Moloney murine sarcoma virus. These cells present a normal phenotype at 39 degrees C and a transformed phenotype at 28 or 33 degrees C, expressing two viral proteins, termed P85gag-mos and P58gag, at 28 to 33 degrees C, whereas only P58gag is expressed at 39 degrees C. It has been previously shown that 6m2 cells contain two virus-specific RNA species, a 4.0-kilobase (kb) RNA coding for P58gag and a 3.5-kb RNA coding for P85gag-mos. Using both Northern blot and S1 nuclease analyses, we show here that the 3.5-kb RNA is the predominant viral RNA species in 6m2 cells grown at 28 degrees C, whereas only the 4.0-kb RNA is detected at 39 degrees C. During temperature shift experiments, the 3.5-kb RNA species disappears after a shift from 28 to 39 degrees C and is detected again after a shift back from 39 to 28 degrees C. By Southern blot analysis, we have detected only one ts110 proviral DNA in the 6m2 genome. This observation, as well as previously published heteroduplex and S1 nuclease analyses which showed that the 3.5-kb RNA species lacks about 430 bases found at the gag gene-mos gene junction in the 4.0-kb RNA, suggests that the 3.5-kb RNA is a splicing product of the 4.0-kb RNA. The absence of the 3.5-kb RNA when 6m2 cells are grown at 39 degrees C indicates that the splicing reaction is thermosensitive. The splicing defect of the ts110 Moloney murine sarcoma virus viral RNA in 6m2 cells cannot be complemented by acute Moloney murine leukemia virus superinfection, since no 3.5-kb ts110 RNA was detected in acutely superinfected 6m2 cells maintained at 39 degrees C. The spliced Moloney murine leukemia virus env mRNA, however, is found in acutely infected cells maintained at 39 degrees C, suggesting that the lack of ts110 viral RNA splicing at 39 degrees C is not due to an obvious host defect. In sharp contrast, however, 6m2 cells chronically superinfected with Moloney murine leukemia virus produce a 3.5-kb RNA species at 39 degrees C as well as at 28 degrees C and contain proviral DNAs corresponding to the two viral RNA species.(ABSTRACT TRUNCATED AT 400 WORDS)     

Genomic complexities of murine leukemia and sarcoma, reticuloendotheliosis, and visna viruses.

The genetic complexities of several ribodeoxyviruses were measured by quantitative analysis of unique RNase T1-resistant oligonucleotides from 60-70S viral RNAs. Moloney murine leukemia virus was found to have an RNA complexity of 3.5 x 10(6) daltons, whereas Moloney murine sarcoma virus had a significantly smaller genome size of 2.3 x 10(6). Reticuleondotheliosis and visna virus RNAs had complexities of 3.9 x 10(6), respectively. Analysis of RNase A-resistant oligonucleotides of Rous sarcoma virus RNA gave a complexity of 3.6 x 10(6), similar to that previously obtained with RNase T1-resistant oligonucleotides. Since each of these viruses was found to have a unique sequence genomic complexity near the molecular weight of a single 30-40S viral RNA subunit, it was concluded that ribodeoxyvirus genomes are at least largely polyploid.     

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

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

Glucocorticoids enhance viral transformation of mammalian cells

The effect of glucocorticoids on the replication of murine sarcoma virus (MSV) in mammalian cells were examined. Glucocorticoids, hydrocortisone (1 to 10 micrograms/ml) and dexamethasone (5 micrograms/ml), enhance transformation induced by the Kirsten strain of MSV (Ki-MSV) in normal rat kidney and human cells 10- to 30-fold. The enhancing effect was much more pronounced in normal human colonic mucosal epithelial-like cells. On the other hand, the hormones estradiol, testosterone, and progesterone had no effect (5 micrograms/ml). Individual foci appeared earlier and were larger in hydrocortisone-treated cells compared with untreated cells. This enhancing effect is further evidenced by the increased virus yield and murine leukemia virus complement-fixing antigen production in the test system. However, such enhancement of hydrocortisone on the Ki-MSV-induced transformation was not observed in mouse embryo cells as previously reported.     

Glucocorticoid-receptor interaction and induction of murine mammary tumor virus.

The relationship between the cellular uptake of glucocorticoid hormones, the binding of these hormones to specific in vitro receptors, and the induction of mouse mammary tumor viruses in an established mouse mammary tumor cell line was highly correlated. These results suggest that the induction of mouse mammary tumor virus by glucocorticoid hormones is a physiological process acting through a mechanism of high affinity, saturable steroid-receptors. A temperature-sensitive or salt-dependent step following glucocorticoid-receptor interaction was required for nuclear uptake of the steroid. Induction studies with different adrenocorticoids indicate that the synthetic glucocorticoid, dexamethasone (1,4-pregnadiene-9-fluor-16alpha-methyl-11beta,17alpha,21-triol-3,20-dione), is the most potent inducer of mouse mammary tumor viruses and all steroids which caused significant induction were glucocorticoids. Other glucocorticoids appear to stimulate murine mammary tumor virus production by a mechanism similar to that of dexamethasone; for example, corticosterone competes with dexamethasone for binding to the glucocorticoid receptor and blocks the uptake of dexamethasone into cells. Progesterone also blocks the cellular uptake of dexamethasone and can bind to the glucocorticoid receptor at low concentrations (10-7 to 10-8 M) but progesterone does not consistently induce virus at hormone concentrations even as high as 10-4 M. Thus, in this system, binding to a cytoplasmic receptor is necessary but not sufficient for induction by glucocorticoids. Estrogens and androgens interfere with receptor binding and cellular uptake of dexamethasone but only at much higher concentration (10-4 M) than progesterone, and do not induce mammary tumor virus production. Although there was a positive correlation between steroid structure, binding, and biologic induction, other factors clearly affect the physiological manifestations of steroid actions. Mouse cells with comparable cytoplasmic receptor levels and comparable nuclear uptake differed absolutely in their degree of murine mammary tumor virus induction following hormone treatment. Although all mouse cells examined contain comparable levels of murine mammary tumor virus DNA, only cells producing constitutive levels of murine mammary tumor virus RNA could be induced to higher levels by a variety of glucocorticoids.     

Mammary tumor virus induction by glucocorticoids. Characterization of specific transcriptional regulation.

Dexamethasone (1,4-pregnadiene-9-fluor-16alpha-methyl-11beta,17alpha,21-triol-3,20-dione), a potent synthetic glucocorticoid, stimulates mouse mammary tumor virus expression 10- to 20-fold in tissue culture cells. This hormone effect was observed at concentrations as low as 1 times 10-10 M and was maximal at 10-7 to 10-8 M. The time course of induction indicated that detectable increases in extracellular viral DNA polymerase were first noted 18 to 24 hours following the addition of dexamethasone, and cells produced the highest polymerase levels at the time monolayers approached confluence. Steroid responsiveness was associated with specific increases in type B murine mammary tumor virus structural polypeptide (gp52(sl) expression and murine mammary tumor virus RNA that quantitatively paralleled the increase in extracellular virus production as measured by electron microscopy and supernatant RNA-dependent DNA polymerase activity. Another virally transformed murine cell line, KA 31, did not contain detectable levels of murine mammary tumor virus gp52(sl) or RNA before or after dexamethasone stimulation; thus induction was noted only in murine cells with pre-existing murine mammary tumor virus expression. No increase in basal levels of type C murine leukemia viral proteins or RNA was detected in dexamethasone-treated mammary cell lines which were producing increased levels of murine mammary tumor virus. Therefore, increases in murine mammary tumor virus gene products are specific for murine mammary tumor virus DNA sequences under these conditions.     

Dual regulation of protein maturation in viral infected rat HTC hepatoma cells by glucocorticoids and progesterone

Dexamethasone, a synthetic glucocorticoid, is required for full posttranslational maturation of mouse mammary tumor virus (MMTV) phosphoproteins and glycoproteins in M1.54 cells, a viral infected rat hepatoma (HTC) cell line. Pulse-chase radiolabeling with [35S]methionine revealed that steroids with known glucocorticoid activity (such as dexamethasone and hydrocortisone) regulated the maturation of both MMTV polyproteins in a manner proportional to their occupancy for glucocorticoid receptors and their biological potency. In contrast, progesterone selectively induced the proteolytic processing of MMTV phosphoproteins but simultaneously antagonized the dexamethasone-regulated maturation of MMTV glycoproteins and all other tested glucocorticoid responses. Exposure to suboptimal concentrations of both progesterone and dexamethasone fully stimulated the processing of MMTV phosphoproteins, suggesting that steroid receptors occupied with combinations of either steroid functionally interact at the putative maturation gene. Moreover, treatment with either actinomycin D, a potent inhibitor of de novo RNA synthesis, or RU38486, a synthetic antagonist of glucocorticoid and progesterone action, prevented both the dexamethasone and progesterone-regulated induction of MMTV phosphoprotein maturation. Sedimentation velocity and saturation binding analysis revealed that the sizes and concentrations of hepatoma cell progesterone and dexamethasone binding activities are similar while specific binding of the active progestin R5020 was not detected in either M1.54 cells or the glucocorticoid receptor deficient HTC cell line MSN6.10.2. Taken together, our results demonstrate that two distinct classes of steroid hormones can uniquely alter the posttranslational maturation of a specific subset of phosphoprotein substrates by a common glucocorticoid receptor-dependent process.     

S1 nuclease mapping of viral RNAs from a temperature-sensitive transformation mutant of murine sarcoma virus

The structures of murine sarcoma virus (MuSV) ts110 viral RNA and intracellular RNA present in MuSV ts110-infected cells (6m2 cells) have been examined by S1 nuclease analysis. A previous study involving heteroduplex analysis of MuSV ts110 viral RNAs hybridized to wild-type DNA revealed the presence of two MuSV ts110 RNAs, 4.0 and 3.5 kilobases (kb) in length, containing overlapping central deletions relative to wild-type MuSV 124 viral RNA (Junghans et al., J. Mol. Biol. 161:229-255, 1982). Here we show that the deletion (termed delta 1) in the 4.0-kb RNA has a 5' border located at about nucleotide 2409 (using the numbering system of Van Beveren et al., Cell 27:97-108, 1981), a position 63 bases upstream of the junction of the p30 and p10 coding sequences. The 3' border of the delta 1 deletion is found 1,473 bases downstream at approximately nucleotide 3883, 10 nucleotides downstream of the first mos gene initiation codon. In the 3.5-kb MuSV ts110 RNA, the 5' border of the deleted central region (termed delta 2) is located in a splice consensus donor site at approximately nucleotide 2017, 330 bases downstream from the junction of the p12 and p30 coding sequences, and extends about 1,915 bases in the downstream direction to nucleotide 3935, found in a splice consensus acceptor site about 55 nucleotides downstream of the first mos gene initiation codon and 30 bases upstream of the second initiation codon. No alteration of polyadenylate addition sites was observed in either MuSV ts110 RNA species, as compared with MuSV 349 RNA. The observation that the 5' and 3' borders of the deletion in the 3.5-kb RNA are within in-frame splice donor and acceptor sites suggests strongly that the 3.5-kb RNA is derived from the 4.0-kb RNA by a temperature-sensitive splice mechanism. Data presented here show unequivocally that formation of the 3.5-kb MuSV ts110 RNA from which the P85gag-mos polypeptide is translated is temperature sensitive. At 33 degrees C, with S1 analysis, the 3.5-kb RNA is found readily in 6m2 cells. Within 4 h of a shift to 39 degrees C, however, only trace amounts of this RNA can be found. Moreover, reshifting 6m2 cells to 33 degrees C permits the reappearance of the 3.5-kb RNA at its original level.     

Effects of steroid hormones on replication of murine sarcoma virus in mouse embryo cultures.

The androgenic steroid hormone, testosterone, inhibited focus formation by the murine Moloney sarcoma virus in mouse embryo cells. The inhibition of focus formation was enhanced by cyclic AMP. Although focus formation was inhibited, there was no inhibition of viral replication. The glucogenic adrenal corticosteroids, cortisol and dexamethasone, and 17-beta-estradiol and progesterone did not affect focus formation by MuSV(M).     

Synthesis of type C virus particles from murine-cultured cells induced by iododeoxyuridine. V. Effect of interferon and its interaction with dexamethasone.

Previous studies have shown that in certain cell systems dexamethasone may enhance the production of type C viruses. Conversely, interferon has been shown to inhibit their production. Both appear to exert their influence late in the viral replication cycle rather than on the synthesis of viral-specific RNA. In this report dexamethasone and interferon have been used to study some aspects of the mechanisms involved in the synthesis of type C viruses in murine K-BALB cells following induction of virus production by iododeoxyuridine. Interferon inhibited production of xenotropic type C virus induced by iododeoxyuridine from K-BALB cells both in the absence and presence of dexamethasone, but it did not affect production of N-tropic type C virus. Exposure of the cells to interferon for longer than 12 h was required for maximum effect. Two types of inhibitory effects were observed: one diminished by dexamethasone when the steroid was added 24 h after interferon removal, and the second resistant to dexamethasone. The concentration of intracellular group-specific antigen was diminshed after interferon and increased after dexamethasone exposure. When induced cells were treated with both interferon and dexamethasone, the intracellular group-specific protein concentration was slightly increased, but virus production was reduced 10-fold compared with induced cells treated with dexamethasone alone. We conclude that interferon and dexamethasone may affect both the synthesis of viral proteins and the assembly or release of virus particles and that dexamethasone can partially nullify the inhibitory activity of interferon. The results also support previous conclusions that the regulatory mechanisms for synthesis of viral proteins and for the release of viral particles may differ and that controls for xenotropic and ecotropic virus formation may not be identical.     

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

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

Glucocorticoids stimulate the release of a viral tumor marker (MMTV gp52) while inhibiting tumor cell growth

The influence of glucocorticoid treatments on the release of mouse mammary tumor virus (MMTV) envelope antigen (gp52) has been studied in C3H mammary tumor cell cultures and compared to treatment-mediated effects on tumor cell growth. Simultaneous assessment of extracellular viral antigen levels and tumor cell growth has indicated that both are coordinately affected by glucocorticoid treatment. While gp52 release is stimulated by treatment, this effect is accompanied by an inhibition of tumor cell growth. These stimulatory and inhibitory effects are mediated by dexamethasone (DEX) in a dose-dependent fashion, and both effects are more pronounced with the synthetic glucocorticoids DEX or triamcinolone acetonide (TA). Quantitation of media gp52 levels by RIA revealed the following hierarchy of glucocorticoid enhancement: TA greater than DEX greater than prednisolone greater than hydrocortisone greater than triamcinolone. A similar order of activity was observed in terms of inhibition of cell growth. The ability of TA to enhance gp52 release was 2.4-2.7 times greater than DEX, a previously proven stimulator of MMTV expression. Cell density of B9 mammary tumor cells was reduced 73% following 72 h of 10(-8) MTA treatment while C3H Mm5mt/cl mammary tumor cells were reduced by 53%. Hormone-mediated changes in in vitro gp52 release suggest that hormones might also influence plasma levels of MMTV gp52 as a systemic marker for the presence and status of murine mammary tumors. Coordinate stimulatory and inhibitory effects suggest that glucocorticoids may play a complex role in murine mammary tumorigenesis and subsequent mammary disease.     

Molecular cloning of Snyder-Theilen feline leukemia and sarcoma viruses: comparative studies of feline sarcoma virus with its natural helper virus and with Moloney murine sarcoma virus

Extrachromosomal DNA obtained from mink cells acutely infected with the Snyder-Theilen (ST) strain of feline sarcoma virus (feline leukemia virus) [FeSV(FeLV)] was fractionated electrophoretically, and samples enriched for FeLV and FeSV linear intermediates were digested with EcoRI and cloned in lambda phage. Hybrid phages were isolated containing either FeSV or FeLV DNA "inserts" and were characterized by restriction enzyme analysis, R-looping with purified 26 to 32S viral RNA, and heteroduplex formation. The recombinant phages (designated lambda FeSV and lambda FeLV) contain all of the genetic information represented in FeSV and FeLV RNA genomes but lack one extended terminally redundant sequence of 750 bases which appears once at each end of parental linear DNA intermediates. Restriction enzyme and heteroduplex analyses confirmed that sequences unique to FeSV (src sequences) are located at the center of the FeSV genome and are approximately 1.5 kilobase pairs in length. With respect to the 5'-3' orientation of genes in viral RNA, the order of genes in the FeSV genome is 5'-gag-src-env-c region-3'; only 0.9 kilobase pairs of gag and 0.6 kilobase pairs of env-derived FeLV sequences are represented in ST FeSV. Heteroduplex analyses between lambda FeSV or lambda FeLV DNA and Moloney murine sarcoma virus DNA (strain m1) were performed under conditions of reduced stringency to demonstrate limited regions of base pair homology. Two such regions were identified: the first occurs at the extreme 5' end of the leukemia and both sarcoma viral genomes, whereas the second corresponds to a 5' segment of leukemia virus "env" sequences conserved in both sarcoma viruses. The latter sequences are localized at the 3' end of FeSV src and at the 5' end of murine sarcoma virus src and could possibly correspond to regions of helper virus genomes that are required for retroviral transforming functions.