Transcription of mouse mammary tumor virus genes in tissues from high and low tumor incidence mouse strains

Presence of a mouse mammary tumour virus-like in feline lymphomas: a preliminary study

The mouse mammary tumour virus (MMTV) is implicated in the aetiology of murine mammary carcinomas and a variant of it, the type B leukemogenic virus, can cause murine thymic lymphomas. Interestingly, a MMTV-like virus is suspected to be involved in human breast cancer and feline mammary carcinomas. However, to date, no cases of MMTV-like sequence amplifications have been described in lymphoid neoplasms in veterinary literature. The aim of this study was to investigate the presence of env nucleotide sequences and protein 14 (p14) of a MMTV-like virus in fifty-three feline lymphoma samples. Our results show that MMTV-like sequences were detected in 5/53 tumours (9.4%): three gastrointestinal lymphomas (one B-type diffuse large, one B-type small non-cleaved, and one T-type diffuse mixed lymphoma); and two nasal lymphomas (one B-type diffuse small cleaved lymphoma and one B-type diffuse mixed lymphoma). P14 expression was detected in the cytoplasm, and rarely in nuclei, exclusively of neoplastic cells from PCR-positive tumours. The correlation between the presence of the MMTV-env like sequences (MMTVels) and p14 antigen was statistically significant in nasal lymphomas. All cats with MMTVels-positive lymphoma had a history of contact with the outdoor environment and/or catteries, and two deceased subjects shared their environment with cats that also died of lymphoma. In conclusion, this study succeeds in demonstrating the presence of MMTVels and p14 in feline lymphomas. The characterization of the immunophenotype of MMTVels-positive lymphomas could contribute to the understanding of a possible role of a MMTV-like virus in feline tumour aetiology. The significant association between the presence of the viral sequences in lymphoid tumours and their nasal localization, together with the data collected through supplementary anamnesis, should be further analysed in order to understand the epidemiology of the virus.

Determining epithelial contribution to in vivo mesenchymal tumour expression signature using species-specific microarray profiling analysis of xenografts

Gene expression profiling using microarrays and xenograft transplants of human cancer cell lines are both popular tools to investigate human cancer. However, the undefined degree of cross hybridization between the mouse and human genomes hinders the use of microarrays to characterize gene expression of both the host and the cancer cell within the xenograft. Since an increasingly recognized aspect of cancer is the host response (or cancer-stroma interaction), we describe here a bioinformatic manipulation of the Affymetrix profiling that allows interrogation of the gene expression of both the mouse host and the human tumour. Evidence of microenvironmental regulation of epithelial mesenchymal transition of the tumour component in vivo is resolved against a background of mesenchymal gene expression. This tool could allow deeper insight to the mechanism of action of anti-cancer drugs, as typically novel drug efficacy is being tested in xenograft systems.

Chromatin structure modulates transcription factor binding to the mouse mammary tumor virus (MMTV) promoter

The MMTV promoter contains a complex hormone responsive region (HRR) upstream of a binding site for the transcription factor nuclear factor I (NFI). Hormonal induction of MMTV expression requires the integrity of both the HRR and the NFI binding site. However, in vitro NFI acts as a basal transcription factor on the MMTV promoter that does not cooperate but rather competes with the hormone receptors in terms of binding to MMTV-DNA. Fragments that contain the HRR and the NFI binding site have been reconstituted into mononucleosomes. Steroid hormone receptors bind efficiently to these nucleosomes, NFI does not. Therefore it has been postulated that the chromatin structure may be responsible for the inability of NFI to bind to the chromosomally organized inactive MMTV promoter. In vivo DNaseI and methidium-propyl-EDTA-Fe(II) (MPE) digestion pattern indicate the presence of a nucleosome covering the HRR and the NFI binding site. Genomic footprinting shows that in vivo the rotational setting of the MMTV promoter DNA in this nucleosome is identical to that previously reported for reconstituted nucleosomes in which the major grooves of the NFI half palindromes are facing towards the histone octamer and appear not to be accessible to NFI. These results indicate that MMTV promoter sequences are determining nucleosome positioning in vivo and supports the concept that rotational positioning of DNA in this nucleosome constitutively represses the MMTV promoter.

Transgenic mouse mammary tumor virus superantigen expression prevents viral infection

Endogenous mouse mammary tumor virus (MMTV) proviruses have recently been shown to cosegregate genetically with the minor lymphocyte-stimulating loci, also termed self-superantigens. The antigenic activity has been localized to the open reading frame (ORF) protein encoded in the long terminal repeat of MMTV. We show here that unlike their nontransgenic littermates, transgenic mice expressing high levels of an ORF protein derived from the C3H exogenous MMTV specifically delete their V beta 14+ T cells and do not become infected with this virus when it is present in their mother's milk. Thus, it appears that MMTV utilizes cells of the immune system in its infection pathway, and mice that retain endogenous MMTVs should be immune to infection by exogenous virus. These results offer possible new approaches to anti-viral therapy or immunization.

Methylation of HSV-1 DNA as a mechanism of viral inhibition: studies of an analogue of methyldeoxycytidine: trifluoromethyldeoxycytidine (F3mdCyd)

Although several hypomethylating agents such as 5-azadeoxycytidine and 5-fluorodeoxycytidine have been shown to activate transcription after incorporation into viral or cellular DNA, agents which selectively affect the methylation status of virus-infected cells have not been described. Studies on the antiviral effect of the methyldeoxycytidine (mdCyd) analogue trifluoromethyldeoxycytidine (F3mdCyd) showed significant antiviral activity against herpes simplex virus type 1 (HSV-1). This analogue of both dCyd and dThd is selectively incorporated into the DNA of herpesvirus infected cells due to the unique specificity of the herpesvirus thymidine kinase (TK) because the HSV-1 TK is both a dCyd and dThd kinase. In contrast, the deoxycytidine kinase of uninfected cells preferentially phosphorylates dCyd and has a poor affinity for F3mdCyd. F3mdCyd hemisubstituted M13 DNA displayed the same properties as mdCyd-substituted M13 DNA with respect to cleavage by restriction enzymes, and acted as an efficient template for eukaryotic DNA methyltransferase (S-adenosyl-L-methionine DNA (cytosine-5) methyltransferase: EC 2.1.1.37). Using the persistently infected CEM cell model system, the extent of DNA methylation was shown to increase in a dose-related manner when HSV-1-infected CEM cells were treated with increasing concentrations of F3mdCyd. Higher levels of methylation correlated with significant decreases in HSV-1 titers. Isoschizomer analyses followed by Southern blotting and hybridization with genomic HSV-1 DNA showed that DNA from HSV-1-infected, analogue-treated Vero cells was resistant to cleavage by restriction enzymes at a time when productive virus was not present in culture. We infer from these results that the methylation-like properties of the incorporated F3mdCyd occur concomitantly with, and appear to be involved in, the mechanisms of the analogue's antiviral effect towards HSV-1.

Mouse mammary tumor virus (MMTV) infection in SWISS and RIII mice. Correlation between resistance to exogenous infection and anti-MMTV serum response

Host-virus relationships were examined in mice from the two mouse mammary tumor virus (MMTV)-infected strains SWISS MB+ and RIII, which harbour the same MMTV variant, and from the derived sublines Swiss MB- and RIIIf, which were freed of milk-borne MMTV by foster-nursing. These two strains are not phylogenetically related, the SWISS strain bearing the endogenous Mtv-3 locus in its DNA. In RIII and SWISS MB+ mice, the incidence of early mammary tumors, which was of 96% and 8%, respectively, was correlated to the level of MMTV expression in milk. In the SWISS MB-line, a non-coordinate expression of the provirus associated with the Mtv-3 locus was observed in the mammary glands, the salivary glands and the spleen. This expression was not tumorigenic and was characterized by the presence of the p28 gag antigen and the absence of the gp52 env antigen, except, however, in mammary glands of elder mice where traces of gp52 were found. In the mammary glands of SWISS MB+ mice, the expression of the Mtv-3 locus was masked by large amounts of antigens resulting from exogenous virus expression. RIIIf mice were MMTV-negative. Viral antigens coexisted with anti-MMTV antibodies in the serum of infected and tumor-bearing mice, but not in the form of immune complexes as verified by a method that allowed to detect specific antigen-containing-soluble immune complexes. An anti-MMTV serum reactivity was also detected in SWISS MB- and RIIIf mice. However, the serum response was higher in the two SWISS lines than in the two RIII lines. Except in tumor-bearing mice, the anti-MMTV response was not significantly modified by the presence of exogenous virus and thus resulted essentially from exposure to endogenous MMTV expression. In experimental infection studies, RIII mice were more susceptible to MMTV infection than SWISS mice. The correlation between resistance to MMTV infection and serum response to endogenous MMTV expression, suggests that the non-tumorigenic expression of an endogenous provirus can protect at least partially, against exogenous MMTV infection.

Mutations in the hormone regulatory element of mouse mammary tumor virus differentially affect the response to progestins, androgens, and glucocorticoids

Transcription of the mouse mammary tumor virus DNA is known to be induced by several steroid hormones. Using chimeric MMTV plasmids containing mutations within the hormone regulatory element, we have previously studied the regions required for the glucocorticoid response in mouse fibroblasts. Here we report the characterization of elements essential for the stimulation by progestins and androgens as compared with glucocorticoids. The same set of mutant plasmids was transfected into the human mammary tumor cell line T47D, and the specific transcripts were analyzed by an S1 nuclease protection assay. Androgen-mediated stimulation, although weak, showed an extended sensitivity to mutations, with a slight preference for the proximal region. The results with progestin suggest that sequences within all the described sites protected by the receptor in vitro are required and that the promoter-proximal region (-128 to -78 from the RNA start site) is more important than the distal one (-190 to -160). Moreover, a binding site for nuclear factor I was not required for the progestin response, whereas it was required for glucocorticoids. Thus, the various steroid receptors play a role in the differential regulation of mouse mammary tumor virus transcription by recognizing distinct sequence differences in the hormone regulatory element and interacting with different factors bound to the promoter.

Mutations in the hormone regulatory element of mouse mammary tumor virus differentially affect the response to progestins, androgens, and glucocorticoids

Transcription of the mouse mammary tumor virus DNA is known to be induced by several steroid hormones. Using chimeric MMTV plasmids containing mutations within the hormone regulatory element, we have previously studied the regions required for the glucocorticoid response in mouse fibroblasts. Here we report the characterization of elements essential for the stimulation by progestins and androgens as compared with glucocorticoids. The same set of mutant plasmids was transfected into the human mammary tumor cell line T47D, and the specific transcripts were analyzed by an S1 nuclease protection assay. Androgen-mediated stimulation, although weak, showed an extended sensitivity to mutations, with a slight preference for the proximal region. The results with progestin suggest that sequences within all the described sites protected by the receptor in vitro are required and that the promoter-proximal region (-128 to -78 from the RNA start site) is more important than the distal one (-190 to -160). Moreover, a binding site for nuclear factor I was not required for the progestin response, whereas it was required for glucocorticoids. Thus, the various steroid receptors play a role in the differential regulation of mouse mammary tumor virus transcription by recognizing distinct sequence differences in the hormone regulatory element and interacting with different factors bound to the promoter.

Endogenous mouse mammary tumor virus is expressed in several organs in addition to the lactating mammary gland

We studied the transcription of endogenous mouse mammary tumor virus (MMTV) in transgenic and normal strains of mice of different genetic backgrounds. Although the lactating mammary gland in all strains showed the highest level of MMTV expression, detectable levels of viral RNA were also found in the lungs, kidneys, salivary glands, seminal vesicles and/or prostate gland, testes, and lymphoid tissue in mice which contain different endogenous proviruses. Transcription in transgenic mice containing the MMTV long terminal repeat linked to the simian virus 40 early region also occurred in these same organs. These results indicate that the MMTV long terminal repeat functions in several organs in addition to the lactating mammary gland.

A transcriptionally defective long terminal repeat within an endogenous copy of mouse mammary tumor virus proviral DNA

Mouse mammary tumor virus proviral DNA is endogenous to most inbred strains of mice but in many strains is not transcriptionally active. This inactivity may be due to defects in the proviruses themselves or to position effects mediated by DNA sequences flanking the proviral units. The transcriptional competence of long terminal repeats (LTRs) derived from endogenous proviral DNA at genetic loci Mtv-8, Mtv-9, and Mtv-17 of the C57BL/6 mouse strain was examined with a transient transfection assay in which gene expression was monitored by expression of chloramphenicol acetyltransferase. LTRs from Mtv-8 and Mtv-9 were able to direct glucocorticoid-induced chloramphenicol acetyltransferase expression in this assay, while the LTR from Mtv-17 was only about 5% as effective. Analysis of chimeric LTRs indicated that the glucocorticoid-inducible transcriptional enhancer element within the Mtv-17 LTR is active when linked to a functional promoter from Mtv-8, whereas the promoter from Mtv-17 is defective in directing hormone-induced gene expression, even when linked to the Mtv-8 glucocorticoid-responsive enhancer. The DNA sequence of transcriptional control regions of the LTRs of all three endogenous proviral units was determined; this analysis revealed that the source of the defect in Mtv-17 is a single G-to-A transition at position-75 with respect to the site of transcription initiation that resides within the previously defined binding site for the transcription factor nuclear factor 1. Competition experiments with a gel electrophoresis mobility shift assay indicated that the affinity of nuclear factor 1 for DNA derived from Mtv-17 is significantly less than for comparable sequences derived from Mtv-8.

Mineralocorticoid regulation of transcription of transfected mouse mammary tumor virus DNA in cultured kidney cells

Renal cells contain two corticosteroid-binding entities defined on the basis of hormone-binding selectivity as type I (mineralocorticoid) and type II (glucocorticoid). The mineralocorticoid, aldosterone can bind to both type I and type II receptors. This poses problems in defining the characteristics of a true mineralocorticoid regulated expression of specific genes. We have used chimaeric constructs bearing the mouse mammary tumor virus (MMTV) promoter to study aldosterone action in the feline renal cell line CRFK. We have shown that in these cells aldosterone induces MMTV transcription through its own receptor (type I). This induction of MMTV transcription by aldosterone is a primary response to the hormone. We have shown that the DNA sequences that mediate the aldosterone response overlap the hormone response element (HRE) required for the glucocorticoid, progestin, and androgen induction of transcription at the MMTV long terminal repeat region. Thus the aldosterone regulation of MMTV long terminal repeat transcription is identical to the mode of action of the other steroid hormones at this promoter.

The mouse mammary tumor virus long terminal repeat directs expression in epithelial and lymphoid cells of different tissues in transgenic mice

A series of transgenic mice was developed that contained the simian virus 40 early region genes under the transcriptional control of the mouse mammary tumor virus long terminal repeat, including the promoter and glucocorticoid response elements. These mice all expressed the transgene in the epithelial cells of a number of different organs, such as lungs, kidneys, and prostate, salivary, and mammary glands, and in Leydig and lymphoid cells. Transcription of the chimeric gene was inducible by glucocorticoids, either after transfection into tissue culture cells or in cells cultured from animals carrying the transgene. Many, but not all, tissues which expressed the simian virus 40 sequences, as determined immunologically and by RNA analysis, developed into tumors, although they showed premalignant features. Since the mouse mammary tumor virus long terminal repeat is expressed in a number of different cell types when inherited through the germ line, the lactating mammary gland-specific transcription of endogenous proviruses must require other factors or sequences to achieve this specificity.

Spleen specific expression of an MMTV related transcript associated with the Mtv-6 locus in BALB/c mice

We have detected an MMTV related transcript which is expressed in a spleen specific manner in BALB/cHeA mice. Using a recombinant inbred series between BALB/cHeA and STS/A mice (C X S RI series) we have identified RNA associated with the Mtv-3 locus of the STS/A strain. This transcript initiates at the same site in the MMTV LTR as already reported for Mtv-2 and Mtv-8. The novel spleen specific MMTV transcript in the BALB/cHeA strain has a different structure as compared to the transcripts associated with the Mtv-2, Mtv-3, or Mtv-8 loci. We have tentatively identified the Mtv-6 locus as the source of these unique transcripts.

Differential expression of endogenous mouse mammary tumor virus genes during development of the BALB/c mammary gland

Expression of endogenous mouse mammary tumor virus sequences varied over the course of development of the mammary gland during primary pregnancy and lactation in virus-free BALB/c mice. Although RNA from all regions of the genome was detected, both the level and temporal regulation of expression were different for long terminal repeat-, env-, and gag-pol-specific RNAs. Analysis of the methylation status of proviral DNA indicated differential accessibility of the three endogenous units during development. The results demonstrated noncoordinate regulation of mouse mammary tumor virus expression with respect to provirus template utilized and specific transcripts accumulated.

Restriction endonuclease map of endogenous mouse mammary tumor virus loci in GR, DBA, and NFS mice

Mouse mammary tumor virus (MMTV) is integrated in the genome of most mice as an endogenous provirus. Two of these MMTV proviral loci (Mtv-1 and Mtv-2) are associated with virus expression and tumorigenicity. We prepared restriction endonuclease maps of the endogenous MMTV proviruses in two strains, DBA and GR, which contain the Mtv-1 and Mtv-2 loci, plus a third strain, NFS, which has a low mammary tumor incidence. We find that all these mouse strains have certain MMTV loci in common even though their origins are widely divergent. We also find that some integrated MMTV proviruses appear to have undergone alterations or deletions when compared with MMTV exogenous proviral DNA. We have thus made a comprehensive characterization of MMTV loci in these mouse strains which could serve as a basis for the study of their differences in expression.

Mouse mammary tumor virus gene expression regulated in trans by Lps locus

Expression of mouse mammary tumor virus (MMTV) in the lactating mammary glands of uninfected mice varies between strains of mice in a manner largely independent of the proviral content. Previous linkage analysis in the mouse suggested that the Lps locus was associated with steady-state levels of MMTV RNA. The Lps locus mediates the mouse's response to the injection of lipopolysaccharide (LPS) in the responder mouse while mice with the deficient allele are incapable of responding. Injecting LPS-responder mice, C3HfB/HeN, and nonresponder mice, C3Hf/HeJ, with LPS resulted in a threefold increase in the level of MMTV RNA in responder mice but had no effect on nonresponders. The increased level was due to only one of the possible MMTV transcripts: the 1.7-kb transcript containing the open reading frame (orf) of the long terminal repeat (LTR). The level of MMTV-specific transcripts, then, is regulated by the Lps locus, a cellular gene which is not linked to any viral coding sequences and therefore must act in trans.

Slow, persistent replication of lentiviruses: role of tissue macrophages and macrophage precursors in bone marrow

Lentiviruses, as exemplified by visna virus of sheep, are nononcogenic retroviruses that cause slowly progressive diseases after prolonged periods of incubation. Earlier studies on visna have shown that the long incubation period of the disease is associated with constant production of minimal quantities of virus in tissues, whereas virus could be obtained by culturing monocytes and macrophages from explants of lymphatic tissues and inflamed organs. In this study the role of macrophages in lentivirus infection was explored using two sheep that were intrabronchially inoculated with virus. When sections of paraffin-embedded tissue, processed by a recently described technique which combines immunocytochemistry for the identification of macrophages and in situ hybridization for identification of viral nucleic acid, were examined, we found that virus replication is associated almost exclusively with infection in selected populations of macrophages in the interalveolar region of the alveoli, in inflammatory exudate cells in the lung, in lymph nodes, and in the spleen. Although large numbers of alveolar macrophages had viral RNA, few of these cells produced virus. While this minimally productive type of viral replication provides an explanation for the slow pace of the infection, restricted replication in terminally differentiated, short-lived macrophages does not explain persistent virus replication in the animal. With the discovery of clusters of infected macrophage precursors in the bone marrow, a mechanism for persistence was found. The macrophage precursor cells provide an important missing link in the virus-target-cell circuit and may be the reservoir of latently infected cells which perpetuate lentivirus infections in both animals and humans.

Glucocorticoid regulation of mouse mammary tumor virus sequences in transgenic mice

We have introduced a chimeric plasmid, pLTR2TK, containing the mouse mammary tumor virus (MTV) long terminal repeat (LTR) linked to the herpes simplex virus type 1 thymidine kinase gene into the mouse germ line by microinjection. In one mouse line, the thymidine kinase gene is appropriately expressed in the lactating mammary glands of heterozygous females; expression also occurs in the ovaries of these mice. In heterozygous males of this line, and in a male derived from another microinjection, transcription of these new germ line genes occurs in the testes and is specifically stimulated by glucocorticoid hormones. Thus, the MTV LTR may contain elements that allow its expression both in lactating mammary glands and in testicular tissue.

Alterations in chromatin structure associated with glucocorticoid-induced expression of endogenous mouse mammary tumor virus genes

Alterations in the chromatin structure of endogenous mouse mammary tumor virus genes accompany glucocorticoid induction of viral RNA synthesis in the C57BL/6 T lymphoma cell line T1M1. These alterations are defined by the appearance of sites of DNase I hypersensitivity within proviral DNA in isolated nuclei, as well as by changes in the moderate nuclease sensitivity of entire proviral transcription units. Induced hypersensitive sites, termed type I, appear with a time course comparable to that required for induction of the rate of viral RNA synthesis and are maintained only in the continuous presence of hormone. Two such sites map to analogous positions in the 5' and 3' long terminal repeats of proviral DNA within, or very near, sequences that have been shown to comprise positions of specific binding of the glucocorticoid receptor in vitro and that are required for hormone-inducible transcription in vivo. A third type I site maps to another position of in vitro receptor binding near the 3' long terminal repeat. Some sites of DNase I hypersensitivity, termed type II, appear not to be markedly hormone dependent; two such sites are present in corresponding positions in each long terminal repeat. Comparison of the moderate DNase I sensitivity of mouse mammary tumor virus proviral DNA suggests that the three different endogenous units in T1M1 cells can be maintained in distinct chromatin conformations that are determined by factors related to the site of provirus insertion. It seems possible that altered chromatin conformations may reflect, or actually encode, important mechanistic features of these hormone-responsive genes.

Proviral unit II of endogenous mouse mammary tumour virus is selectively amplified and expressed in C57B1/10 mammary tumours induced by non-viral carcinogens

Restriction enzyme analysis and molecular hybridization assay of DNA isolated from C57B1/10 mammary adenocarcinomas induced by a combination of dimethylbenzanthracene, oestrogen, and prolactin, revealed the presence of four extra copies of endogenous mouse mammary tumour virus (MMTV). PstI restriction pattern of the amplified proviral sequences indicated their identity with the proviral Unit II of endogenous MMTV. The amplified proviruses are hypomethylated and expressed in a hormone-dependent fashion. Their internal structure is slightly modified, since an additional EcoRI recognition site is present within the proviral genomic DNA. Selective amplification of Unit II MMTV provirus in the course of mammary tumourigenesis initiated by chemical carcinogens and hormones is compatible with the accepted multifactorial nature of this process, and is interpreted in terms of the insertional mutagenesis model for MMTV-induced oncogenesis. However, sequences of cellular DNA, adjacent to the amplified Unit II proviruses, show no homology to the integration domains int-1 and int-2 common to exogenous MMTV.

Analysis of tissue-specific methylation patterns of mouse mammary tumor virus DNA by two-dimensional Southern blotting

We used a two-dimensional Southern blotting procedure to analyze the tissue-specific methylation patterns of the five endogenous mouse mammary tumor viruses in the GR/A mouse strain. Our findings suggest that in certain tissues (brain, kidney, and liver) all proviruses are extensively methylated. In other tissues (spleen, placenta, and testes) all proviruses are hypomethylated to some degree. In these tissues individual proviruses display both quantitative and qualitative differences in methylation. We interpret the general patterns of tissue-specific hypomethylation in terms of a "hitch-hiker" model: mouse mammary tumor virus proviral methylation patterns reflect the tissue-specific activity of neighboring sequences. The observation that certain sites on particular proviruses are differentially methylated in a tissue-specific fashion may reflect tissue-specific differences in the makeup or conformation, or both, of proviral-containing chromatin.

Alterations in chromatin structure associated with glucocorticoid-induced expression of endogenous mouse mammary tumor virus genes

Alterations in the chromatin structure of endogenous mouse mammary tumor virus genes accompany glucocorticoid induction of viral RNA synthesis in the C57BL/6 T lymphoma cell line T1M1. These alterations are defined by the appearance of sites of DNase I hypersensitivity within proviral DNA in isolated nuclei, as well as by changes in the moderate nuclease sensitivity of entire proviral transcription units. Induced hypersensitive sites, termed type I, appear with a time course comparable to that required for induction of the rate of viral RNA synthesis and are maintained only in the continuous presence of hormone. Two such sites map to analogous positions in the 5' and 3' long terminal repeats of proviral DNA within, or very near, sequences that have been shown to comprise positions of specific binding of the glucocorticoid receptor in vitro and that are required for hormone-inducible transcription in vivo. A third type I site maps to another position of in vitro receptor binding near the 3' long terminal repeat. Some sites of DNase I hypersensitivity, termed type II, appear not to be markedly hormone dependent; two such sites are present in corresponding positions in each long terminal repeat. Comparison of the moderate DNase I sensitivity of mouse mammary tumor virus proviral DNA suggests that the three different endogenous units in T1M1 cells can be maintained in distinct chromatin conformations that are determined by factors related to the site of provirus insertion. It seems possible that altered chromatin conformations may reflect, or actually encode, important mechanistic features of these hormone-responsive genes.

Sequence organization and molecular cloning of mouse mammary tumor virus DNA endogenous to C57BL/6 mice

The sequence organization of mouse mammary tumor virus DNA endogenous to the C57BL/6 inbred mouse strain was characterized by Southern blot analysis, utilizing probes specific for particular regions of the mouse mammary tumor virus provirus and by molecular cloning of endogenous mouse mammary tumor virus DNA. The genome of C57BL/6 mice contains three apparently intact, endogenous proviral units; two of these units comprise the Mtv-8 (unit II) and Mtv-9 (unit III) genetic loci that are also present in the DNA of BALB/c mice. The third unit is defined by EcoRI restriction fragments of 10.0 and 8.4 kilobases that contain the 5' and 3' portions of the provirus, respectively. This unit, termed unit XI and encoded by the genetic locus Mtv-17, has not been previously recognized in C57BL/6 DNA, but it can be clearly distinguished from the proviral units at Mtv-8 and Mtv-9 by Southern blot analysis under appropriate conditions. The proviral unit at Mtv-17 is not present in BALB/c DNA. DNAs comprising the entire Mtv-8 locus and the 3' portions of Mtv-9 and Mtv-17 were cloned. Analysis of the cloned DNA revealed no obvious deletions or rearrangements that would render proviral DNA defective; however, these endogenous genes are normally not transcriptionally active.

Molecular basis of altered mouse mammary tumor virus expression in the D-2 hyperplastic alveolar nodule line of BALB/c mice

The preneoplastic D-2 hyperplastic outgrowth line, which was derived from a hormone-induced hyperplastic alveolar nodule (HAN) of a BALB/c mouse, was used for a detailed analysis of mouse mammary tumor virus (MMTV) expression. The D-2 HAN line has previously been shown to express viral RNA representative of the entire genome, although viral particles have been noted only rarely. The MMTV-specific mRNA, protein, and DNA content of the D-2 tissues was defined in an effort to better understand the molecular basis of the aberrant virus expression. Northern blotting techniques demonstrated the presence of properly processed 8.9 kb (genomic) and 3.6 kb (envelope) mRNA. Protein electroblotting procedures established the presence of properly processed viral core protein p28. In contrast, the envelope precursor polyprotein was not processed into detectable levels of gp52. Analysis of MMTV proviral content by Southern blot methodology revealed the presence of a newly acquired provirus which serves as a marker for the clonal nature of the D-2 line. The origin of the new provirus is unknown. Methylation studies established that the new proviral insert is hypomethylated and, therefore, is likely serving as the template for the MMTV expression observed in the D-2 HAN line. These characteristics of the D-2 line make it an excellent system in which to study the role, if any, of MMTV in the progression of D-2 preneoplastic tissues to the tumor phenotype.

Characterization of an endogenous retrovirus-repetitive DNA chimera in the mouse genome

We found that an endogenous mouse mammary tumor provirus, GR-MTV-8, is embedded within a member of the BAM HI family of long interspersed repetitive mouse DNAs. GR-MTV-8 appears to be transcriptionally silent at its normal chromosomal position in the mouse genome. The provirus is transcriptionally active, however, when cloned and transfected into mouse cells (Kennedy et al., Nature (London) 295:622-624, 1982). We propose that the transcriptional inactivity of GR-MTV-8 in situ is due to an inhibitory effect, possibly involving DNA methylation, attributable to the flanking BAM HI element.

The methylation pattern of endogenous mouse mammary tumor virus proviral genes is tissue specific and stably inherited

The methylation pattern of mouse mammary tumor virus (MMTV) proviral genes endogenous to the mouse strains C3H, 020, FM/JmsA, C57BL6, and BALB/c were investigated in various organs and mammary tumor tissue. Digestion of DNA with EcoRI or with EcoRI and HpaII followed by Southern blotting analysis and hybridization to a nick-translated MMTV DNA, allowed the distinction between the fully methylated and hypomethylated gene copies. MMTV proviral gene methylation was found to be organ specific, and the methylation pattern is stably inherited. The same proviral units present in different strains of mice exhibit the same organ-specific methylation patterns. Although proviral genes are normally heavily methylated in all tissues, hypomethylation of endogenous proviral genes was found in organs not known to express MMTV.

Mouse mammary tumor virus DNA methylation: tissue-specific variation

Mouse mammary tumor virus-specific DNA sequences endogenous to the BALB/c mouse are shown to exhibit variable levels of methylation in a tissue-specific manner. In DNA from both lactating mammary gland and spleen, MMTV-specific sequences were hypomethylated at specific HpaII and HhaI sites. These variably methylated sites were found in the terminal repetitive sequences of the endogenous viral genomes. The specific hypomethylation of a HpaII site in Mtv-9 is associated with expression of a 1.6 kb transcript in the lactating mammary gland.

Characterization and chromosomal location of endogenous mouse mammary tumor virus loci in GR, NFS, and DBA mice

Endogenous mouse mammary tumor virus (MMTV) proviral copies were characterized in three genetically dissimilar mouse strains: GR, a high-tumor-incidence strain bred in Europe that carries an MMTV proviral copy associated with early mammary tumors; DBA, a high-tumor-incidence laboratory strain bred in the USA with an endogenous copy that is associated with MMTV antigen expression in the milk; and NFS, a recently inbred line of the low-tumor-incidence NIH Swiss mouse. MMTV proviral loci were studied using restriction endonuclease analysis and the Southern transfer procedure in genetic crosses and in somatic cell hybrids. By studying the segregation of MMTV-specific EcoRI, BamHI, and PstI fragments, the organization of these fragments into MMTV proviral loci was determined and it was shown that (1) many homologous proviral loci are present in these three mouse strains, (2) these MMTV proviruses differ in their pattern of internal restriction sites, and (3) the MMTV loci are distributed on multiple chromosomes including 1 and 7.

Mouse mammary tumor virus: specific methylation patterns of proviral DNA in normal mouse tissues

The methylation state of endogenous mouse mammary tumor virus (MuMTV) proviral DNA was examined in normal mouse tissues. DNAs from various tissues were cleaved with the methylation-sensitive enzymes HhaI and HpaII and analyzed by Southern blotting. Tissue-specific MuMTV proviral DNA methylation patterns were found in the BALB/c, C3H, C57BL, GR/A, and GR-Mtv-2- mouse strains. MuMTV proviral DNA was hypomethylated in DNAs from the spleens and testes of all strains examined. The GR/A mouse strain, which was most thoroughly studied, also showed hypomethylation of MuMTV proviral DNA in bone marrow and placental tissues. Analysis of RNAs extracted from GR/A liver, mammary tumor, testes, placenta, and spleen tissues demonstrated that MuMTV proviral hypomethylation need not reflect significant proviral transcription.

Immunological selection of variant mouse lymphoid cells with altered glucocorticoid responsiveness

We have devised an immunological procedure to separate cells on the basis of expression of mouse mammary tumor virus (MMTV) gene products. Plastic petri dishes coated with specific antibodies against MMTV proteins bind cells with an efficiency that correlates with the level of MMTV gene expression. Glucocorticoid-sensitive mouse thymoma cell line W7 was infected with MMTV. Clones from the infected population retain the relatively slow cytolytic glucocorticoid response and, in addition, exhibit a rapid induction of MMTV-specific RNA and proteins. By combining our immunological selection with the selection for resistance to hormone-mediated cytolysis, we have isolated variant cells which are resistant to the cytotoxic effect of glucocorticoids but which retain the induction of viral gene products and must therefore have a functional glucocorticoid receptor protein.

Immunological selection of variant mouse lymphoid cells with altered glucocorticoid responsiveness

We have devised an immunological procedure to separate cells on the basis of expression of mouse mammary tumor virus (MMTV) gene products. Plastic petri dishes coated with specific antibodies against MMTV proteins bind cells with an efficiency that correlates with the level of MMTV gene expression. Glucocorticoid-sensitive mouse thymoma cell line W7 was infected with MMTV. Clones from the infected population retain the relatively slow cytolytic glucocorticoid response and, in addition, exhibit a rapid induction of MMTV-specific RNA and proteins. By combining our immunological selection with the selection for resistance to hormone-mediated cytolysis, we have isolated variant cells which are resistant to the cytotoxic effect of glucocorticoids but which retain the induction of viral gene products and must therefore have a functional glucocorticoid receptor protein.

Regulation of endogenous murine mammary tumor virus expression in C57BL mouse lactating mammary glands: transcription of functional mRNA with a block at the translational level

Expression of endogenous murine mammary tumor viruses (MuMTVs) in various mouse strains is regulated in different ways, and in the absence of exogenous MuMTV, this regulation influences the incidence of spontaneous mammary tumors. Two mouse strains with low mammary tumor incidence, BALB/c and C57BL, control endogenous MuMTV expression at different stages. Neither of the strains had any detectable MuMTV polypeptides in its lactating mammary glands (LMG). However, in C57BL LMG, substantial amounts of MuMTV RNA were present, whereas very little viral RNA was detected in BALB/c LMG. By determining MuMTV RNA levels in LMG of hybrids and backcrosses of BALB/c and C57BL mice, we found that there are three unlinked, independently segregating genetic loci in C57BL mice that are responsible for the presence of moderately high amounts of MuMTV RNA in LMG. The viral RNA in C57BL LMG was processed and transported to the cytoplasm where it was found to cosediment with EDTA-sensitive polysomes. No viral proteins were detected in run-off reactions that permit completion of nascent polypeptide synthesis with polysomes from C57BL LMG, and sensitive radioimmunoassays failed to detect any MuMTV proteins in these tissues. In contrast, MuMTV mRNA purified from C57BL LMG did direct the synthesis of both gag and env MuMTV polypeptides when added to a heterologous rabbit reticulocyte lysate cell-free translation system. We propose that MuMTV mRNA in C57BL LMG, for unknown reasons, is blocked at the translational level.

Two classes of mutant mammary tumor virus-infected HTC cell with defects in glucocorticoid-regulated gene expression

We have isolated mutant derivatives of M1.54 (a mammary tumor virus [MTV]-infected rat hepatoma [HTC] cell line containing multiple integrated proviruses) that fail to express hormone-inducible cell surface viral glycoproteins. In wild-type M1.54, the synthetic glucocorticoid dexamethasone selectively stimulates the rate of synthesis of MTV RNA. In addition, dexamethasone is essential for posttranslational maturation of three of the four cell surface viral glycoproteins processed from the MTV glycosylated precursor polyprotein; the fourth mature species is produced constitutively. Two mutant phenotypes are described; each contains glucocorticoid receptors that are indistinguishable from the wild-type receptor with respect to hormone affinity, intracellular concentration, nuclear translocation efficiency, DNA-cellulose chromatography, and sedimentation rate. In one class, represented by the mutant line CR1, dexamethasone fails to stimulate the low basal rate of MTV gene transcription; surprisingly, hormonal regulation of tyrosine aminotransferase activity is also defective in CR1, whereas several other cellular responses to dexamethasone are normal. In the second class of mutants, represented by CR4, dexamethasone stimulates synthesis of MTV transcripts indistinguishable from those produced in M1.54, but only the constitutive cell surface viral glycoprotein is expressed. Thus, these mutants define two distinct and novel aspects of glucocorticoid regulated gene expression in HTC cells: CR4 contains a defect in a hormone inducible protein maturation pathway that acts on specific viral (and presumably cellular) precursor polypeptides, whereas the lesion in CR1 appears to affect the expression of a subset of the gene products normally under glucocorticoid control in M1.54.

Genetic control of the organ specificity of lymphoproliferative disease virus (LPDV) of turkeys

In a previous study based on the kinetics of virus replication and tumor formation (Gazit et al., 1982), it was shown that the organotropism of lymphoproliferative disease virus (LPDV) is confined to lymphoid tissues. The present paper demonstrates that this organ specificity is controlled at the level of infection and integration, that is, the lymphoid organs, which are the only organs sustaining virus replication, and also the only organs in whose cells integrated LPDV proviruses are detectable. At the same time, the efficiency of virus replication within the various target organs is regulated both at the level of infection and integration and at the level of viral gene transcription.

Two classes of mutant mammary tumor virus-infected HTC cell with defects in glucocorticoid-regulated gene expression

We have isolated mutant derivatives of M1.54 (a mammary tumor virus [MTV]-infected rat hepatoma [HTC] cell line containing multiple integrated proviruses) that fail to express hormone-inducible cell surface viral glycoproteins. In wild-type M1.54, the synthetic glucocorticoid dexamethasone selectively stimulates the rate of synthesis of MTV RNA. In addition, dexamethasone is essential for posttranslational maturation of three of the four cell surface viral glycoproteins processed from the MTV glycosylated precursor polyprotein; the fourth mature species is produced constitutively. Two mutant phenotypes are described; each contains glucocorticoid receptors that are indistinguishable from the wild-type receptor with respect to hormone affinity, intracellular concentration, nuclear translocation efficiency, DNA-cellulose chromatography, and sedimentation rate. In one class, represented by the mutant line CR1, dexamethasone fails to stimulate the low basal rate of MTV gene transcription; surprisingly, hormonal regulation of tyrosine aminotransferase activity is also defective in CR1, whereas several other cellular responses to dexamethasone are normal. In the second class of mutants, represented by CR4, dexamethasone stimulates synthesis of MTV transcripts indistinguishable from those produced in M1.54, but only the constitutive cell surface viral glycoprotein is expressed. Thus, these mutants define two distinct and novel aspects of glucocorticoid regulated gene expression in HTC cells: CR4 contains a defect in a hormone inducible protein maturation pathway that acts on specific viral (and presumably cellular) precursor polypeptides, whereas the lesion in CR1 appears to affect the expression of a subset of the gene products normally under glucocorticoid control in M1.54.

Acquisition of proviral DNA of mouse mammary tumor virus in thymic leukemia cells from GR mice

Male mice of strain GR develop T-cell leukemia at a low frequency late in life. These leukemia cells contain large amounts of mouse mammary tumor virus (MMTV) RNA and MMTV proteins in a precursor form (Nusse et al., J. Virol. 32:251-258, 1979). We used restriction enzyme analysis and molecular hybridization to identify MMTV proviruses in the DNA of these leukemia cells. GR leukemia cells contained additional integrated MMTV proviruses at various sites in the genome. This amplification of MMTV proviruses in GR leukemia cells is not restricted to one particular endogenous MMTV provirus of strain GR. The number and location of the extra MMTV proviruses present in transplants of GR leukemia cells did not change upon serial transplantation of the leukemia cells. Acquisition of MMTV proviruses was also found in a similar leukemia, L1210 of the DBA/2 mouse strain, but not in three other leukemias, SL2 of DBA/2, BW5147 of AKR, and a spontaneous thymoma of BALB/c. The two main classes of MMTV RNA, 35S and 24S, were present in the cytoplasmic RNA of GR leukemia cells, indicating that the aberrant processing of MMTV precursor proteins is not due to anomolously sized RNAs. We could not detect extra RNAs in GR leukemia cells which would represent read-through transcripts of cellular genes adjacent to the extra MMTV proviruses, initiated by a promoter signal in the right MMTV long terminal repeat sequence. These data suggest that acquisition of MMTV proviruses may coincide with the onset of leukemogenesis in GR male mice.

RNA and polypeptide homology among murine coronaviruses

Using a ³²P complementary DNA (cDNA) prepared against the A59 nucleocapsid protein messenger RNA, we have investigated the extent of homology between A59 and four other strains of murine hepatitis virus (MHV). Analysis by hybridization kinetics of the annealing between A59 [³²P]cDNA and infected cell RNA from the other four MHV strains demonstrated 70–80% homology. By gel transfer analysis, the A59 [³²P]cDNA was able to detect subgenomic-size virus-specific RNAs in cells infected with all of the five MHV strains. A similar pattern of seven viral RNAs was detected in cells infected with A59, MHV-1, MHV-3, and JHM. In contrast, cells infected with MHV-S contained seven virus-specific RNAs, of which only the two smallest species comigrated with RNAs from the other four strains. The results suggest that as previously shown with A59 (S. Cheley, R. Anderson, M. J. Cupples, E. C. M. Lee Chan, and V. L. Morris (1981)Virology, 112, 596–604), all MHV strains tested encode a nested set of subgenomic RNAs. Analysis of [³⁵S]methionine-labeled viral proteins by SDS-polyacrylamide gel electrophoresis revealed that each strain of MHV specified four major viral polypeptides with apparent molecular weights very similar to those previously reported for the E2, N, El, and PEI polypeptides of A59. The strong degree of interstrain homology among the five MHV strains investigated was confirmed by comparative chymotryptic peptide mapping of the viral N proteins. A majority of the chymotryptic peptides from each of the [³⁵Sknethionine-labeled N proteins was found to coelute by high-performance liquid chromotography. Moreover, this technique of peptide mapping indicated a particularly strong relatedness between MHV-1 and MHV-S and among MHV-3, JHM, and A59.

Quantitative of murine mammary tumor virus-related RNA in mammary tissues of low- and high-mammary-tumor-incidence mouse strains

Lactating mammary glands and hormonally induced mammary tumors of BALB/c mice from three geographically separated breeding colonies were examined by molecular hybridization, using murine mammary tumor virus (MuMTV) cDNA representing the entire viral genome to determine the amount of MuMTV-related RNA expressed in these tissues. The RNA extracted from these tissues by the classical sodium dodecyl sulfate-pronase, phenol-chloroform procedure (method 1) contained barely detectable levels of MuMTV-related sequences. In contrast, both normal lactating mammary glands and hormonally induced mammary tumors of these mice were found to contain approximately one to two copies of the MuMTV genome per cell by using a new procedure in which the RNA was extracted with guanidine derivatives (method 2). No significant differences in the MuMTV-related RNA content of the BALB/c mammary tissues were observed regardless of their colony of origin. Our results suggest that expression of MuMTV RNA does not change in BALB/c mammary glands during transformation to a malignant state and that MuMTV expression does not play a role in tumorigenesis in these mice. In view of the increased recovery of MuMTV-related RNA from BALB/c mice with method 2, we compared the level of MuMTV RNA expression in lactating mammary glands and mammary tumors of other mouse strains, including C57BL/6 and RIII, using both extraction methods. Yields of MuMTV-related RNA from mammary tissues increased by as much as 35- to 40-fold, using method 2 as compared with method 1. Therefore method 2, involving guanidine derivatives, appears to be method of choice for MuMTV-related RNA extraction from the mammary tissues of certain strains of mice, particularly those expressing relatively low levels of MuMTV RNA.

Genetics of susceptibility for radiation-induced leukemia. Mapping of genes involved to chromosomes 1, 2, and 4, and implications for a viral etiology in the disease

Susceptibility to radiation-induced leukemia in (A/J x B10)F2 mice is encoded for by genes in chromosomes 1, 2, and 4. The loci involved in chromosomes 1 and 4 are close to or similar to xenotropic virus inducibility locus on chromosome 1 and a locus-affecting expression of xenotropic MuLV envelope-related cell surface antigens. Radiation-induced leukemia-1 (Ril-1) on chromosome 2 plays an overriding influence in susceptibility to the disease. This locus might encode ecotropic viral-associated genetic information or might contain cellular sequences with oncogenic potential. These findings are of interest in view of the importance of recombinant viruses to leukemogenesis. Furthermore, it is intriguing that Ril-1 is located in a chromosomal site rich in thymus differentiation-specific loci. An explanation for tissue-specific activation of endogenous viruses is that activation of the virus in question is dependent on differentiation-specific steps.

Intracellular murine hepatitis virus-specific RNAs contain common sequences

A major polyadenylated viral RNA of approximately 0.8 × 10⁶ daltons was isolated from murine hepatitis virus (A59)-infected cells by preparative polyacrylamide gel electrophoresis in formamide. This RNA was shown to encode the viral nucleocapsid protein by direct in vitro translation in a cell-free, reticulocyte-derived system. Single stranded ³²P-labeled complementary DNA was prepared from this RNA and was demonstrated to be virus specific. Using this complementary DNA in a Northern blotting procedure, we were able to identify six major virus-specific intracellular RNA species with estimated molecular weights of 0.8, 1.1, 1.4, 1.6, 3, and 4 × 10⁶ daltons. All of these RNA species were polyadenylated. Our results support the idea that coronavirus-infected cells contain multiple intracellular polyadenylated RNAs which share common sequences.

Partial expression of endogenous mouse mammary tumor virus in mammary tumors induced in BALB/c mice by chemical, hormonal, and physical agents

The possible interaction of environmental factors with the endogenous mouse mammary tumor virus (MMTV) genome in the development of mammary tumors in the low-tumor-incidence BALB/c mouse strain was examined. Tumors were induced in virgin female animals by treatment with chemical carcinogen 7,12- dimethylbenz[alpha]anthracene or urethan, with or without prolonged hormonal stimulation, or by X-irradiation. Concomitant hormonal stimulation resulted in increased tumor incidences compared with those induced by chemical carcinogen treatment alone. The frequency of tumor induction by irradiation alone or in combination with urethan or prolactin stimulation was very low. MMTV expression in the mammary tumors was assayed by nucleic acid hybridization and by immunohistochemical staining. Depending upon the treatment group, 0 to 89% of the tumors contained detectable levels of MMTV RNA (>/=0.0005% of the total cellular RNA). Tumors which contained detectable viral transcripts exhibited only low levels of MMTV RNA, which did not appear to represent the accumulation of RNA sequences homologous to the entire MMTV genome; synthesis of MMTV structural proteins was detected in only one tumor. Viral RNA-positive tumors were generally associated with a longer latent period. MMTV RNA expression occurred in tumors classified histologically as adenoacanthomas, as well as in mammary adenocarcinomas, although the cell types in the adenoacanthomas expressing viral RNA were not identified. It does not appear that expression of the endogenous MMTV genome is required for maintenance of all mammary tumors in BALB/c mice, although partial genome expression undetectable by the methods employed cannot be ruled out. Linear regression analyses were performed. The mean time to tumor appearance and the percentage of tumors which were MMTV RNA positive were found to vary linearly as a function of the total dose of 7,12-dimethylbenz[alpha]anthracene administered. The percentage of tumors which were MMTV RNA positive was also shown to be linearly related to the mean time to tumor appearance. These relationships provide a basis for predictions in the BALB/c system related to these parameters.

Proviruses of mouse mammary tumor virus in normal and neoplastic tissues from GR and C3Hf mouse strains

We analyzed two experimental situations to assess the role of endogenous mouse mammary tumor virus (MMTV) DNA in the genesis of mammary carcinomas. (i) GR mice carry in their germ line one or more proviruses indistinguishable by limited restriction mapping from the proviruses introduced into cells by experimental infection with the highly tumorigenic virus isolated from GR mouse milk, MMTV(GR). Most tumors arising in GR mice contain one or more proviruses at various sites in tumor DNA in addition to those present endogenously. Detection of these new proviruses is possible as a consequence of the clonal or quasiclonal character of the tumors. (ii) C3H/He mice carry three units of endogenous viral DNA, none of which resembles the DNA of the commonly encountered strains of milk-borne MMTV. Nevertheless, MMTV-associated tumors arise late in life when these animals are removed from the influence of milk-borne virus; the responsible agent, MMTV(C3Hf), can also produce tumors in BALB/c mice. We found that tumors arising in both C3Hf/He mice and BALB/c mice infected with MMTV(C3Hf) were clonal or quasiclonal and contained one or more new copies of proviral DNA at various sites in the host genome. These new proviruses were readily distinguished from the proviruses of the common milk-borne virus strains and closely resembled unit II of endogenous MMTV DNA (Cohen et al., J. Virol., 32:483-496). Thus, in both experimental systems, we found evidence for new proviruses in mammary tumors, despite the preexistence of similar or identical proviruses in the germ line. The results suggest that the repositioning of MMTV proviruses may be required for the full expression of the oncogenic potential of endogenous MMTV DNA.