DNA methylation affecting the expression of murine leukemia proviruses

5-Azacytidine: A Promoter of Epigenetic Changes in the Quest to Improve Plant Somatic Embryogenesis

Somatic embryogenesis (SE) is a widely studied process due to its biotechnological potential to generate large quantities of plants in short time frames and from different sources of explants. The success of SE depends on many factors, such as the nature of the explant, the microenvironment generated by in vitro culture conditions, and the regulation of gene expression, among others. Epigenetics has recently been identified as an important factor influencing SE outcome. DNA methylation is one of the most studied epigenetic mechanisms due to its essential role in gene expression, and its participation in SE is crucial. DNA methylation levels can be modified through the use of drugs such as 5-Azacytidine (5-AzaC), an inhibitor of DNA methylation, which has been used during SE protocols. The balance between hypomethylation and hypermethylation seems to be the key to SE success. Here, we discuss the most prominent recent research on the role of 5-AzaC in the regulation of DNA methylation, highlighting its importance during the SE process. Also, the molecular implications that this inhibitor might have for the increase or decrease in the embryogenic potential of various explants are reviewed.

Epigenetic modification, dehydration, and molecular crowding effects on the thermodynamics of i-motif structure formation from C-rich DNA

DNA sequences with the potential to form secondary structures such as i-motifs (iMs) and G-quadruplexes (G4s) are abundant in the promoters of several oncogenes and, in some instances, are known to regulate gene expression. Recently, iM-forming DNA strands have also been employed as functional units in nanodevices, ranging from drug delivery systems to nanocircuitry. To understand both the mechanism of gene regulation by iMs and how to use them more efficiently in nanotechnological applications, it is essential to have a thorough knowledge of factors that govern their conformational states and stabilities. Most of the prior work to characterize the conformational dynamics of iMs have been done with iM-forming synthetic constructs like tandem (CCT)_n repeats and in standard dilute buffer systems. Here, we present a systematic study on the consequences of epigenetic modifications, molecular crowding, and degree of hydration on the stabilities of an iM-forming sequence from the promoter of the c-myc gene. Our results indicate that 5-hydroxymethylation of cytosines destabilized the iMs against thermal and pH-dependent melting; contrarily, 5-methylcytosine modification stabilized the iMs. Under molecular crowding conditions (PEG-300, 40% w/v), the thermal stability of iMs increased by ∼10 °C, and the pK_a was raised from 6.1 ± 0.1 to 7.0 ± 0.1. Lastly, the iM’s stability at varying degrees of hydration in 1,2-dimethoxyethane, 2-methoxyethanol, ethylene glycol, 1,3-propanediol, and glycerol cosolvents indicated that the iMs are stabilized by dehydration because of the release of water molecules when folded. Our results highlight the importance of considering the effects of epigenetic modifications, molecular crowding, and the degree of hydration on iM structural dynamics. For example, the incorporation of 5-methylycytosines and 5-hydroxymethlycytosines in iMs could be useful for fine-tuning the pH- or temperature-dependent folding/unfolding of an iM. Variations in the degree of hydration of iMs may also provide an additional control of the folded/unfolded state of iMs without having to change the pH of the surrounding matrix.

Epigenetic analysis of HIV-1 proviral genomes from infected individuals: predominance of unmethylated CpG's

Efforts to cure HIV-1 infections aim at eliminating proviral DNA. Integrated DNA from various viruses often becomes methylated de novo and transcriptionally inactivated. We therefore investigated CpG methylation profiles of 55 of 94 CpG's (58.5%) in HIV-1 proviral genomes including ten CpG's in each LTR and additional CpG's in portions of gag, env, nef, rev, and tat genes. We analyzed 33 DNA samples from PBMC's of 23 subjects representing a broad spectrum of HIV-1 disease. In 22 of 23 HIV-1-infected individuals, there were only unmethylated CpG's regardless of infection status. In one long term nonprogressor, however, methylation of proviral DNA varied between 0 and 75% over an 11-year period although the CD4+ counts remained stable. Hence levels of proviral DNA methylation can fluctuate. The preponderance of unmethylated CpG's suggests that proviral methylation is not a major factor in regulating HIV-1 proviral activity in PBMC's. Unmethylated CpG's may play a role in HIV-1 immunopathogenesis.

The human endogenous retrovirus link between genes and environment in multiple sclerosis and in multifactorial diseases associating neuroinflammation

Endogenous retroviruses represent about 8% of the human genome and belong to the superfamily of transposable and retrotransposable genetic elements. Altogether, these mobile genetic elements and their numerous inactivated "junk" sequences represent nearly one half of the human DNA. Nonetheless, a significant part of this "non-conventional" genome has retained potential activity. Epigenetic control is notably involved in silencing most of these genetic elements but certain environmental factors such as viruses are known to dysregulate their expression in susceptible cells. More particularly, embryonal cells with limited gene methylation are most susceptible to uncontrolled activation of these mobile genetic elements by, e.g., viral infections. In particular, certain viruses transactivate promoters from endogenous retroviral family type W (HERV-W). HERV-W RNA was first isolated in circulating viral particles (Multiple Sclerosis-associated RetroViral element, MSRV) that have been associated with the evolution and prognosis of multiple sclerosis. HERV-W elements encode a powerful immunopathogenic envelope protein (ENV) that activates a pro-inflammatory and autoimmune cascade through interaction with Toll-like receptor 4 on immune cells. This ENV protein has repeatedly been detected in MS brain lesions and may be involved in other diseases. Epigenetic factors controlling HERV-W ENV protein expression then reveal critical. This review addresses the gene-environment epigenetic interface of such HERV-W elements and its potential involvement in disease.

Specific in vivo expression in type II pneumocytes of the Jaagsiekte sheep retrovirus long terminal repeat in transgenic mice

Jaagsiekte sheep retrovirus (JSRV) is the causative agent of ovine pulmonary adenocarcinoma, a transmissible lung cancer in sheep. Previous experiments in differentiated murine tissue culture cell lines suggested that the disease specificity of JSRV for secretory lung epithelial cells (type II pneumocytes an Clara cells) reflects transcriptional specificity of the viral long terminal repeat (LTR) for these cells. To test this in vivo, transgenic mice carrying the bacterial beta-galactosidase (beta-Gal) gene driven by the JSRV LTR were generated. Two transgenic lines showed beta-Gal expression in the lungs but not other tissues of F1 animals, although transgene silencing in subsequent generations was a major problem. The cells expressing the transgene were identified by two- and three-color immunofluorescence for marker proteins of type II pneumocytes (surfactant protein C [SPC]) and Clara cells (CC10) as well as for a T7 gene 10 epitope present in the beta-Gal reporter. F1 animals from both lines showed transgene expression in type II pneumocytes, but somewhat surprisingly not in Clara cells. Expression was not detected in bronchiolo-alveolar stem cells (BASCs) either. These results indicate that the JSRV LTR is specifically active in type II pneumocytes in the mouse lung, which is consistent with the fact that JSRV-induced OPA tumors in sheep largely have phenotypic markers of type II pneumocytes.

Transcriptional regulation of early transposon elements, an active family of mouse long terminal repeat retrotransposons

While early transposon (ETn) endogenous retrovirus (ERV)-like elements are known to be active insertional mutagens in the mouse, little is known about their transcriptional regulation. ETns are transcribed during early mouse embryogenesis in embryonic stem (ES) and embryonic carcinoma (EC) cell lines. Despite their lack of coding potential, some ETns remain transposition competent through their use of reverse transcriptase encoded by a related group of ERVs-MusD elements. In this study, we have confirmed high expression levels of ETn and MusD elements in ES and EC cells and have demonstrated an increase in the copy number of ETnII elements in the EC P19 cell line. Using transient transfections, we have shown that ETnII and MusD LTRs are much more active as promoters in P19 cells than in NIH 3T3 cells, indicating that genomic context and methylation are not the only factors determining endogenous transcriptional activity of ETns. Three sites in the 5' part of the long terminal repeat (LTR) were demonstrated to bind Sp1 and Sp3 transcription factors and were found to be important for high LTR promoter activity in P19 cells, suggesting that as yet unidentified Sp binding partners are involved in the regulation of ETn activity in undifferentiated cells. Finally, we found multiple transcription start sites within the ETn LTR and have shown that the LTR retains significant promoter activity in the absence of its noncanonical TATA box. These findings lend insight into the transcriptional regulation of this family of mobile mouse retrotransposons.

Infection of central nervous system cells by ecotropic murine leukemia virus in C58 and AKR mice and in in utero-infected CE/J mice predisposes mice to paralytic infection by lactate dehydrogenase-elevating virus

Certain mouse strains, such as AKR and C58, which possess N-tropic, ecotropic murine leukemia virus (MuLV) proviruses and are homozygous at the Fv-1n locus are specifically susceptible to paralytic infection (age-dependent poliomyelitis [ADPM]) by lactate dehydrogenase-elevating virus (LDV). Our results provide an explanation for this genetic linkage and directly prove that ecotropic MuLV infection of spinal cord cells is responsible for rendering anterior horn neurons susceptible to cytocidal LDV infection, which is the cause of the paralytic disease. Northern (RNA) blot hybridization of total tissue RNA and in situ hybridization of tissue sections demonstrated that only mice harboring central nervous system (CNS) cells that expressed ecotropic MuLV were susceptible to ADPM. Our evidence indicates that the ecotropic MuLV RNA is transcribed in CNS cells from ecotropic MuLV proviruses that have been acquired by infection with exogenous ecotropic MuLV, probably during embryogenesis, the time when germ line proviruses in AKR and C58 mice first become activated. In young mice, MuLV RNA-containing cells were found exclusively in white-matter tracts and therefore were glial cells. An increase in the ADPM susceptibility of the mice with advancing age correlated with the presence of an increased number of ecotropic MuLV RNA-containing cells in the spinal cords which, in turn, correlated with an increase in the number of unmethylated proviruses in the DNA extracted from spinal cords. Studies with AKXD recombinant inbred strains showed that possession of a single replication-competent ecotropic MuLV provirus (emv-11) by Fv-1n/n mice was sufficient to result in ecotropic MuLV infection of CNS cells and ADPM susceptibility. In contrast, no ecotropic MuLV RNA-positive cells were present in the CNSs of mice carrying defective ecotropic MuLV proviruses (emv-3 or emv-13) or in which ecotropic MuLV replication was blocked by the Fv-1n/b or Fv-1b/b phenotype. Such mice were resistant to paralytic LDV infection. In utero infection of CE/J mice, which are devoid of any endogenous ecotropic MuLVs, with the infectious clone of emv-11 (AKR-623) resulted in the infection of CNS cells, and the mice became ADPM susceptible, whereas littermates that had not become infected with ecotropic MuLV remained ADPM resistant.

The v-sis oncoprotein loses transforming activity when targeted to the early Golgi complex

The location of autocrine interactions between the v-sis protein and PDGF receptors remains uncertain and controversial. To examine whether receptor-ligand interactions can occur intracellularly, we have constructed fusion proteins that anchor v-sis to specific intracellular membranes. Fusion of a cis-Golgi retention signal from a coronavirus E1 glycoprotein to v-sis protein completely abolished its transforming ability when transfected into NIH3T3 cells. Fusion proteins incorporating mutations in this retention signal were not retained within the Golgi complex but instead were transported to the cell surface, resulting in efficient transformation. All chimeric proteins were shown to dimerize properly. Derivatives of some of these constructs were also constructed bearing the cytoplasmic tail from the glycoprotein of vesicular stomatitis virus (VSV-G). These constructs allowed examination of subcellular localization by double-label immunofluorescence, using antibodies that distinguish between the extracellular PDGF-related domain and the VSV-G cytoplasmic tail. Colocalization of sis-E1-G with Golgi markers confirmed its targeting to the early Golgi complex. The sis-E1 constructs, targeted to the early Golgi complex, exhibited no proteolytic processing whereas the mutant forms of sis-E1 exhibited normal proteolytic processing. Treatment with suramin, a polyanionic compound that disrupts ligand/receptor interactions at the cell surface, was able to revert the transformed phenotype induced by the mutant sis-E1 constructs described here. Our results demonstrate that autocrine interactions between the v-sis oncoprotein and PDGF receptors within the early Golgi complex do not result in functional signal transduction. Another v-sis fusion protein was constructed by attaching the transmembrane domain and COOH-terminus of TGN38, a protein that localizes to the trans-Golgi network (TGN). This construct was primarily retained intracellularly, although some of the fusion protein reached the surface. Deletion of the COOH-terminal region of the TGN38 retention signal abrogated the TGN-localization, as evidenced by very prominent cell surface localization, and resulted in increased transforming activity. The behavior of the sis-TGN38 derivatives is discussed within the context of the properties of TGN38 itself, which is known to recycle from the cell surface to the TGN.

The v-sis protein retains biological activity as a type II membrane protein when anchored by various signal-anchor domains, including the hydrophobic domain of the bovine papilloma virus E5 oncoprotein

Membrane-anchored forms of the v-sis oncoprotein have been previously described which are oriented as type I transmembrane proteins and which efficiently induce autocrine transformation. Several examples of naturally occurring membrane-anchored growth factors have been identified, but all exhibit a type I orientation. In this work, we wished to construct and characterize membrane-anchored growth factors with a type II orientation. These experiments were designed to determine whether type II membrane-anchored growth factors would in fact exhibit biological activity. Additionally, we wished to determine whether the hydrophobic domain of the E5 oncoprotein of bovine papilloma virus (BPV) can function as a signal-anchor domain to direct type II membrane insertion. Type II derivatives of the v-sis oncoprotein were constructed, with the NH2 terminus intracellular and the COOH terminus extracellular, by substituting the NH2 terminal signal sequence with the signal-anchor domain of a known type II membrane protein. The signal-anchor domains of neuraminidase (NA), asialoglycoprotein receptor (ASGPR) and transferrin receptor (TR) all yielded biologically active type II derivatives of the v-sis oncoprotein. Although transforming all of the type II signal/anchor-sis proteins exhibited a very short half-life. The short half-life exhibited by the signal/anchor-sis constructs suggests that, in some cases, cellular transformation may result from the synthesis of growth factors so labile that they activate undetectable autocrine loops. The E5 oncoprotein encoded by BPV exhibits amino acid sequence similarity with PDGF, activates the PDGF beta-receptor, and thus resembles a miniature membrane-anchored growth factor with a putative type II orientation. The hydrophobic domain of the E5 oncoprotein, when substituted in place of the signal sequence of v-sis, was indistinguishable compared with the signal-anchor domains of NA, TR, and ASGPR, demonstrating its ability to function as a signal-anchor domain. NIH 3T3 cells transformed by the signal/anchor-sis constructs exhibited morphological reversion upon treatment with suramin, indicating a requirement for ligand/receptor interactions in a suramin-sensitive compartment, most likely the cell surface. In contrast, NIH 3T3 cells transformed by the E5 oncoprotein did not exhibit morphological reversion in response to suramin.

Minus-strand DNA is present within murine type C ecotropic retroviruses prior to infection

Viral minus-strand DNA has been identified within ecotropic murine retroviruses prior to infection. The abundance of minus-strand DNA is inversely proportional to the distance from the primer binding site, suggesting that viral DNA is synthesized by reverse transcriptase with the genomic RNA as template. These findings demonstrate that replication of the retroviral genome is not initiated by infection and may begin after activation of reverse transcriptase by gag-pol cleavage during virus assembly.

Intracellular retention of membrane-anchored v-sis protein abrogates autocrine signal transduction

An important question regarding autocrine transformation by v-sis is whether intracellularly activated PDGF receptors are sufficient to transform cells or whether activated receptor-ligand complexes are required at the cell surface. We have addressed this question by inhibiting cell surface transport of a membrane-anchored v-sis protein utilizing the ER retention signal of the adenoviral transmembrane protein E3/19K. A v-sis fusion protein containing this signal was retained within the cell and not transported to the cell surface as confirmed by immunofluorescent localization experiments. Also, proteolytic maturation of this protein was suppressed, indicating inefficient transport to post-Golgi compartments of the secretory pathway. When compared with v-sis proteins lacking a functional retention signal, the ER-retained protein showed a diminished ability to transform NIH 3T3 cells, as measured by the number and size of foci formed. In newly established cell lines, the ER-retained protein did not down-regulate PDGF receptors. However, continued passage of these cells selected for a fully transformed phenotype exhibiting downregulated PDGF receptors and proteolytically processed v-sis protein. These results indicate that productive autocrine interactions occur in a post-ER compartment of the secretory pathway. Transport of v-sis protein beyond the Golgi correlated with acquisition of the transformed phenotype. Furthermore, suramin treatment reversed transformation and upregulated the expression of cell surface PDGF receptors, suggesting an important role for receptor-ligand complexes localized to the cell surface.

Lactate dehydrogenase-elevating virus, equine arteritis virus, and simian hemorrhagic fever virus: a new group of positive-strand RNA viruses

The last comprehensive reviews of nonarbotogaviruses included discussions on pestiviruses, rubella virus, lactate dehydrogenase-elevating virus (LDV), equine arteritis virus (EAV), simian hemorrhagic fever virus (SHFV), cell fusion agent, and nonarboflaviviruses. The inclusion of all these viruses in the family Togaviridae was largely based on the similarities in morphological and physical–chemical properties of these viruses, and in the sizes and polarities of their genomes. In the intervening years, considerable new information on the replication strategies of these viruses and the structure and organization of their genomes has become available that has led to the reclassification or suggestions for reclassification of some of them. The replication strategy of EAV resembles that of the coronaviruses, involving a 3'-coterminal nested set of mRNAs. Therefore, EAV has been suggested to be included in a virus superfamily, along with coronaviruses and toroviruses. Recent evidence indicates that LDV not only resembles EAV in morphology, virion and genome size, and number and size of their structural proteins, but also in genome organization and replication via a 3'-coterminal set of mRNAs. SHFV, although not fully characterized, exhibits properties resembling those of LDV and EAV, and the recent evidence suggest that it may possess the same genome organization as these viruses. The three viruses may, therefore, represent a new family of positive-strand RNA viruses and are reviewed together in this chapter. In this chapter, emphasis is on the recent information concerning their molecular properties and pathogenesis in vitro and in vivo and on the host immune responses to infections by these viruses.

Induction of CAT gene expression on a plasmid vector (L factor) by retinoic acid in mouse embryonal carcinoma (F9) cells

We reported previously that composite DNA constructed from a mammalian plasmid (L factor) and foreign gene can be reestablished as a plasmid in mouse embryonal carcinoma (F9) cells after transfection and the plasmid-bearing F9 cells undergo normal in vitro differentiation in response to retinoic acid, an inducer for F9 cell differentiation. We constructed F9 cells bearing plasmidal L factor DNA in which a reporter (chloramphenicol acetyltransferase; CAT) gene was placed under the control of a differentiation-responsive viral (Moloney murine leukemia virus or simian virus 40) enhancer-promoter. When such plasmid-bearing cells were treated with retinoic acid, the CAT gene was inducibly expressed. These results indicate that mammalian gene expression can be studied with the plasmidal expression vector which is structurally dissociated from complex chromosomes.

Gene expression from heterologous promoters in a replication-defective avian retrovirus vector in quail cells

Avian retrovirus vectors, with potential for use in avian transformation, were constructed to evaluate the relative efficiency of promoters placed internal to the viral long terminal repeats (LTR). The vectors are replication-defective reticuloendotheliosis plasmids that contain the neomycin phosphotransferase gene under control of the 5' LTR and an internal promoter that directs expression of the chloramphenicol acetyltransferase gene. The internal promoters were the SV40 early, the mouse metallothionein I, and the human cytomegalovirus immediate early (HCMV-IE) promoters. Under transient conditions in QT6 cells, the HCMV-IE promoter construct was by far the strongest. However, expression dropped greatly from the HCMV-IE promoter after integration into the quail cell genome. Evidence suggests that the HCMV-IE promoter is selectively suppressed by methylation after stable transfection but not after infection.

Selection against CpG dinucleotides in lentiviral genes: a possible role of methylation in regulation of viral expression

Extremely low frequencies of CpG dinucleotides are found in the genomes of the lentivirus subfamily of retroviruses, including the human, simian and feline immunodeficiency viruses (HIV1, HIV2, SIV, and FIV, respectively), equine infectious anemia virus (EIAV), and the ovine lentivirus, Visna. The occurrence of CpG dinucleotides is greater in the 2-3 (NCG) than in the 1-2 (CGN) codon-defined frame, as well as in the gag and env genes, compared to the more conserved pol gene. These differences suggest that CpG depletion in lentiviruses occurs as a result of selection against CpG rather than due to mutational bias, the latter is responsible for low CpG frequencies in vertebrate genomes. CpG levels in the onco-retrovirus subfamily are reduced to a lesser extent, principally due to mutational bias. The difference between the retrovirus subfamilies appears to reflect their evolutionary origin, that is, lentiviruses have no known endogenous counterparts whereas most oncoviruses have endogenous cellular counterparts with which they can undergo recombination. Furthermore, we suggest that the number of CpG dinucleotides in a lentiviral genome determines the maximum potential DNA methylation level of the provirus, which in turn affects viral transcription in host cells.

Human cells infected with retrovirus vectors acquire an endogenous murine provirus

A 5.2-kilobase mouse RNA is expressed in human cells following infection with recombinant retroviruses propagated in mouse NIH 3T3 cells as psi-2 pseudotypes. This RNA is transcribed from a defective mink cell focus-forming provirus and copackaged into virions and integrated into human target cell DNA at a frequency comparable to that of the recombinant retrovirus genome.

Age-dependent poliomyelitis of mice: expression of endogenous retrovirus correlates with cytocidal replication of lactate dehydrogenase-elevating virus in motor neurons

The widespread presence of endogenous retroviruses in the genomes of animals and humans has suggested that these viruses may be involved in both normal and abnormal developmental processes. Previous studies have indicated the involvement of endogenous ecotropic murine leukemia virus (MuLV) in the development of age-dependent poliomyelitis caused by infection of old C58 or AKR mice by lactate dehydrogenase-elevating virus (LDV). The only genetic components which segregate with susceptibility to LDV-induced paralytic disease are multiple proviral copies of ecotropic MuLV and the permissive allele, at the Fv-1 locus, for N-tropic, ecotropic virus replication (Fv-1n/n). Using in situ hybridization and Northern (RNA) blot hybridization, we have correlated the expression of the endogenous MuLV, both temporally and spatially, with LDV infection of anterior horn motor neurons and the development of paralysis. Our data indicate that treatment of 6- to 7-month-old C58/M mice with cyclophosphamide, which renders these mice susceptible to LDV-induced paralytic disease, results in transient increases in ecotropic MuLV RNA levels in motor neurons throughout the spinal cord. Peripheral inoculation of C58/M mice with LDV, at the time of elevated MuLV RNA levels, results in a rapid spread of LDV to some spinal cord motor neurons. LDV infections then spread slowly but progressively throughout the spinal cord, involving an increasing number of motor neurons. LDV replication is cytocidal and results in neuron destruction and paralysis of the infected animals 2 to 3 weeks postinfection. The slow replication of LDV in the spinal cord contrasts sharply with the rapid replication of LDV in macrophages, the normal host cells for LDV, during the acute phase of infection. The data indicate that the interaction between the endogenous MuLV with the generally nonpathogenic murine togavirus LDV occurs at the level of the motor neuron. We discuss potential mechanisms for the novel dual-virus etiology of age-dependent poliomyelitis of mice.

Endogenous virus genomes become hypomethylated tissue--specifically during aging process of C57BL mice

In an attempt to find out a cause for age-dependent derepression of endogenous viruses, extents of DNA methylation at the endogenous B- and C-type ecotropic viruses in brain, liver and spleen of C57BL/6NJc1 were examined at three ages, newborn, young adult and old. Both endogenous viruses showed a slight but significant tissue-specific either hypo- or hypermethylation during post-natal developmental phase in the three tissues. After maturation, however, no such change was detectable at most of the sites examined. The exceptions were C-type ecotropic virus in brain and B-type virus in spleen, where the age-dependent decreases of methylation were observed. The changes seemed to be continuations of preceding developmental hypomethylation. They indicated that the hypomethylation could be one of the causes for the age-dependent derepression of endogenous virus. It was further suggested that a mechanism to stop the developmental changes of DNA methylation at the maturation of individuals would be important in considering the reasons for the changes in senescent phase.

DNA methylation and differentiation

The methylation of specific cytosine residues in DNA has been implicated in regulating gene expression and facilitating functional specialization of cellular phenotypes. Generally, the demethylation of certain CpG sites correlates with transcriptional activation of genes. 5-Azacytidine is an inhibitor of DNA methylation and has been widely used as a potent activator of suppressed genetic information. Treatment of cells with 5-azacytidine results in profound phenotypic alterations. The drug-induced hypomethylation of DNA apparently perturbs DNA-protein interactions that may consequently alter transcriptional activity and cell determination. The inhibitory effect of cytosine methylation may be exerted via altered DNA-protein interactions specifically or may be transduced by a change in the conformation of chromatin. Recent studies have demonstrated that cytosine methylation also plays a central role in parental imprinting, which in turn determines the differential expression of maternal and paternal genomes during embryogenesis. In other words, methylation is the mechanism whereby the embryo retains memory of the gametic origin of each component of genetic information. A memory of this type would probably persist during DNA replication and cell division as methylation patterns are stable and heritable.

Analysis of mutant Moloney murine leukemia viruses containing linker insertion mutations in the 3' region of pol

Twelve linker insertion mutations have been constructed in the 3' part of the pol gene of Moloney murine leukemia virus. This region of the Moloney murine leukemia virus genome encodes IN or p46pol, which is required for integration of the retroviral DNA into the host cell chromosome. Viral proteins synthesized by these mutants were used to pseudotype a neo-containing retroviral vector. Ten of twelve linker insertion mutant pseudotypes were unable to generate stable proviruses in infected mouse cells, as measured by the formation of G418-resistant colonies. Two mutants mapping at the 3' terminus of the IN-encoding region were competent for the formation of stable vector proviruses (hundreds of G418-resistant colonies per mutant pseudotype-infected plate). Representative linker insertion mutants were also tested for the ability to synthesize viral unintegrated DNA in newly infected cells. All assayed mutants were capable of synthesizing all normal forms of viral unintegrated DNA. The structure of integrated vector proviruses generated by defective and nondefective linker insertion mutants was also analyzed. All replication-competent mutants generated normal proviruses, while the few obtainable proviruses generated by replication-defective mutants were sometimes aberrant in structure. These results argue strongly (and confirm previous data) that the IN-encoding region of pol does not play a significant role in DNA synthesis, but is absolutely required for the formation of normal proviral DNA.

Rapid induction of IgM-secreting murine plasmacytomas by pristane and an immunoglobulin heavy-chain promoter/enhancer-driven c-myc/v-Ha-ras retrovirus

A retroviral vector, RIM, containing murine c-myc under the control of immunoglobulin heavy-chain gene promoter and enhancer elements and v-Ha-ras driven by a Moloney murine leukemia virus long terminal repeat induced IgM-secreting plasmacytomas in 28% of adult and 83% of 3-week-old pristane-conditioned mice with mean latency periods of 60-70 days. In contrast, the same vector only harboring c-myc or v-Ha-ras was virtually ineffective. RIM-induced plasmacytomas expressed retroviral myc and ras genes while their endogenous c-myc alleles were unrearranged and transcriptionally inactive. These plasmacytomas were clonal as each possessed a unique immunoglobulin heavy-chain joining region rearrangement and a single recombinant provirus. Moloney murine leukemia helper virus did not play an obligatory role in tumorigenesis since insertions of Moloney murine leukemia proviruses were found in only 6 of 24 plasmacytomas induced in adult mice. Taken together, these findings support the view that the v-Ha-ras oncogene can cooperate with an activated myc gene in pristane plasmacytomagenesis.

Identification of nonessential disulfide bonds and altered conformations in the v-sis protein, a homolog of the B chain of platelet-derived growth factor

The protein encoded by v-sis, the oncogene of simian sarcoma virus, is homologous to the B chain of platelet-derived growth factor (PDGF). There are eight conserved Cys residues between PDGF-B and the v-sis protein. Both native PDGF and the v-sis protein occur as disulfide-bonded dimers, probably containing both intramolecular and intermolecular disulfide bonds. Oligonucleotide-directed mutagenesis was used to change the Cys codons to Ser codons in the v-sis gene. Four single mutants lacked detectable biological activity, indicating that Cys-127, Cys-160, Cys-171, and Cys-208 are required for formation of a biologically active v-sis protein. The other four single mutants retained biological activity as determined in transformation assays, indicating that Cys-154, Cys-163, Cys-164, and Cys-210 are dispensable for biological activity. Double and triple mutants containing three of these altered sites were constructed, some of which were transforming as well. The v-sis proteins encoded by biologically active mutants displayed significantly reduced levels of dimeric protein compared with the wild-type v-sis protein, which dimerized very efficiently. Furthermore, a mutant with a termination codon at residue 209 exhibited partial transforming activity. This study thus suggests that the minimal region required for transformation consists of residues 127 to 208. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis indicated that the v-sis proteins encoded by some of the biologically active mutants exhibited an altered conformation when compared with the wild-type v-sis protein, and suggested that Cys-154 and Cys-163 participate in a nonessential disulfide bond.

The histidine-221 to tyrosine substitution in v-mos abolishes its biological function and its protein kinase activity

The viral mos gene encodes a cytoplasmic transforming protein termed p37mos. Evidence gathered from a number of experimental approaches is consistent with p37mos having a serine/threonine protein kinase activity. To gain further understanding of the p37mos-associated biochemical activity, we constructed a mutation in the v-mos gene by oligonucleotide-directed mutagenesis yielding a histidine to tyrosine substitution at residue 221 in p37mos. Based upon nucleotide sequences, the histidine residue at the corresponding position is conserved in all the serine/threonine protein kinases from yeast to man, and is absent in protein-tyrosine kinases. The mutant p37mos (Tyr-221) was expressed in yeast and assayed for kinase activity. The mutant protein was inactive as judged by a loss of autophosphorylation activity in vitro, thus providing further support for the conclusion that p37mos is a protein kinase. When the mutant v-mos gene was introduced into a retroviral vector, pDD102, and assayed for focus-forming ability on NIH/3T3 cells, it was found to be inactive at both 37 and 30 degrees. In contrast, the wild-type v-mos had transforming activity at both temperatures. These results extend our earlier findings on the correlation between transforming ability and protein kinase activity. A histidine to tyrosine substitution at the corresponding position of the v-mos protein and the yeast CDC28 gene product causes a similar effect on the kinase activity. Therefore, this residue and/or the sequence near the N-terminal side of the conserved predicted phosphate transfer domain, near the middle of the complete catalytic domain, might be specifically involved in the catalytic activity of serine/threonine protein kinases in general.

Identification of nonessential disulfide bonds and altered conformations in the v-sis protein, a homolog of the B chain of platelet-derived growth factor

The protein encoded by v-sis, the oncogene of simian sarcoma virus, is homologous to the B chain of platelet-derived growth factor (PDGF). There are eight conserved Cys residues between PDGF-B and the v-sis protein. Both native PDGF and the v-sis protein occur as disulfide-bonded dimers, probably containing both intramolecular and intermolecular disulfide bonds. Oligonucleotide-directed mutagenesis was used to change the Cys codons to Ser codons in the v-sis gene. Four single mutants lacked detectable biological activity, indicating that Cys-127, Cys-160, Cys-171, and Cys-208 are required for formation of a biologically active v-sis protein. The other four single mutants retained biological activity as determined in transformation assays, indicating that Cys-154, Cys-163, Cys-164, and Cys-210 are dispensable for biological activity. Double and triple mutants containing three of these altered sites were constructed, some of which were transforming as well. The v-sis proteins encoded by biologically active mutants displayed significantly reduced levels of dimeric protein compared with the wild-type v-sis protein, which dimerized very efficiently. Furthermore, a mutant with a termination codon at residue 209 exhibited partial transforming activity. This study thus suggests that the minimal region required for transformation consists of residues 127 to 208. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis indicated that the v-sis proteins encoded by some of the biologically active mutants exhibited an altered conformation when compared with the wild-type v-sis protein, and suggested that Cys-154 and Cys-163 participate in a nonessential disulfide bond.

A single point mutation in the envelope gene is responsible for replication and XC fusion deficiency of the endogenous ecotropic C3H/He murine leukemia virus and for its repair in culture

The molecular basis has been determined for differences in infectivity and XC phenotype of endogenous ecotropic murine leukemia virus of the low-leukemia mouse strain C3H/He, its relative in the high-leukemia mouse strain AKR, and highly infectious, XC-positive C3H virus variants selected in vitro. Endogenous ecotropic type C virus induced by iododeoxyuridine from the nontransformed C3H/10T1/2 cell line is XC negative and replication deficient. In contrast, viruses produced late after iododeoxyuridine induction in chemically transformed C3H/10T1/2 cells (MCA5) are XC positive and infectious. XC-negative viruses can be converted to XC-positive viruses by being grown in certain transformed cell lines. We have cloned the endogenous ecotropic provirus of C3H/He from MCA5 cells, which is XC negative and replication deficient, as well as two XC-positive C3H proviruses derived by in vitro conversion. Fragment exchange between the XC-negative molecular clone p110 and the XC-positive AKR virus clone p623 revealed that the defect in p110 lies 3' of the SalI site located in the pol region. Nucleotide sequencing established that the C3H p110 provirus was integrated within the R region of an endogenous VL30 long terminal repeat (LTR) in reverse orientation and that the virus differed from the infectious AKR p623 provirus by a point mutation, substituting Lys for Arg at the potential precursor cleavage site for gp70 and p15E. In vitro-converted XC-positive C3H proviral clones 3211 and 4211 are identical to XC-negative C3H p110, except that they have Arg at this site and the normal cleavage site is thus regenerated in these clones. The XC-negative C3H p110 was blocked in processing of Pr85env, whereas clones 3211 and 4211 had normal cleavage of the env precursor into gp70. Both the XC-negative C3H provirus and the in vitro-converted XC-positive C3H proviruses had a single copy of a 99-base-pair enhancer element in the LTR, whereas two copies of this sequence are present in the AKR proviral LTR. Substitution of Arg for Lys at the envelope precursor processing site of C3H p110 by site-directed mutagenesis is sufficient by itself to convert the virus to the XC-positive replication-competent phenotype. Thus, we have established that a single point mutation at the processing site of the envelope precursor protein Pr85 is responsible for the difference in the infectivity and XC phenotype of endogenous ecotropic murine leukemia virus from C3H/He and AKR mice and that the basis for in vitro conversion is a mutation at this site.

Rearrangement of exogenous immunoglobulin VH and DJH gene segments after retroviral transduction into immature lymphoid cell lines

A model substrate for the joining of Ig VH and DJH elements has been constructed in a retroviral vector carrying a selectable marker whose expression is independent of the arrangement of the resident Ig gene segments. The substrate was introduced into lymphoid and nonlymphoid cells, and site-specific recombination between the VH and DJH elements was monitored by a direct hybridization assay. Joining of the exogenous gene segments was observed in cell lines representative of three distinct stages in early B cell differentiation. Rearrangement was not observed in three cell lines derived from mature B cells, or in a fibroblastoid cell line. The VH and DJH elements were initially arranged so that the VH-DJH junction and the recombined flanking sequences could be recovered after rearrangement. By molecular cloning and nucleotide sequence determination, VH-DJH junctions formed upon rearrangement of the substrate were found to resemble closely similar junctions in functional H chain genes. The joining of VH and DJH elements was observed to be asymmetric; loss of nucleotides occurred at the coding joints, but not at the junctions between flanking sequences. Our results suggest that Ig H and L chain gene segments are joined by a common mechanism that is more active in B cell precursors than in mature B cells. These observations provide further evidence that the rearrangement of Ig gene segments occurs by a nonreciprocal recombinational mechanism. The model substrate described here is likely to be of use in defining the nucleotide sequences that mediate rearrangement and in examining the developmental specificity of this process.

Poorly expressed endogenous ecotropic provirus of DBA/2 mice encodes a mutant Pr65gag protein that is not myristylated

DBA/2 mice carry a single endogenous ecotropic murine leukemia provirus designated Emv-3. Although this provirus appears to be nondefective by genomic restriction enzyme mapping, weanling mice do not produce virus and only about one-third of adult mice ever express virus. 5-Iododeoxyuridine and 5-azacytidine, two potent inducers of ecotropic virus expression, are relatively ineffective at inducing Emv-3 expression. However, the chemical carcinogen 7,12-dimethylbenz(a)anthracene can induce ecotropic virus expression in approximately 95% of treated DBA/2 mice. Previous experiments involving DNA transfection and marker rescue analysis of molecularly cloned Emv-3 DNA suggested that Emv-3 carries a small defect(s) in the gag gene, not detectable by restriction enzyme mapping, that inhibits virus expression in vivo and in vitro. Using a combination of approaches, including DNA sequencing, peptide mapping, and metabolic labeling of cells with [3H]myristate, we have demonstrated that the defect in Emv-3 most likely results from a single nucleotide substitution within the gene for p15gag that inhibits myristylation of the Pr65gag N terminus. Myristylation of Pr65gag is thought to be required for this protein to associate with the plasma membrane and is essential for virus particle formation. These results provide a conceptual framework for understanding how Emv-3 expression is regulated during development and after chemical induction.

Sequence and spacing requirements of a retrovirus integration site

Following infection, retroviruses insert a DNA copy of their RNA genome into the host cell genome. This integrative recombination reaction occurs at specific sites on the viral DNA: inverted repeat sequences near the termini of the linear DNA form of the viral genome. We have described elsewhere the generation and analysis of deletion mutations at one of the inverted repeat sequences in Moloney murine leukemia virus. We describe here the effects of insertion mutations made at this locus. Our results show that substantial sequence changes at the site of recombination can be tolerated, and that the spacing between the cleavage sites on the viral DNA can be expanded as well as contracted while still allowing efficient viral integration. After several rounds of virus replication, each of the insertion mutants gave rise to pseudorevertants with new alterations at the integration site.

Mechanism of interaction between endogenous ecotropic murine leukemia viruses in (BALB/c X C57BL/6) hybrid cells

The germline ecotropic murine leukemia (MuLV) proviruses of BALB/c and C57BL/6 (B6) mice were analyzed to determine the molecular basis of low virus expression in these mouse strains and to determine the mechanism of interaction of these two proviruses. Previous work had demonstrated that the BALB/c endogenous ecotropic provirus was infectious but unable to induce XC cell syncytia formation, and that induced (BALB/c X B6) hybrid cells expressed 10- to 50-fold more XC syncytia than induced parental cells. Two independently isolated DNA clones of the B6 endogenous ecotropic provirus were noninfectious following transfection into cells, and cell lines that expressed this viral genome produced noninfectious MuLV. Nucleotide sequencing of the mutant region of the B6 provirus indicated that the defective nature of this provirus resulted from an amino acid substitution of proline for alanine in the central portion of reverse transcriptase. From the analysis of the virus produced by induced hybrid cells, and the patterns of steady-state viral RNA in induced cells, we propose that the enhanced XC cell syncytia formation observed in hybrid cells is due to trans-complementation of viral proteins and not viral recombination or trans-activation of viral genome expression.

Human beta-globin gene expression after gene transfer using retroviral vectors

A retroviral vector containing a 4.4-kb Pst I human beta S-globin gene and a neomycin resistance gene was used to infect NIH-3T3 and mouse erythroleukemia cells (MELC). In MELC, human beta-globin mRNA transcripts are transcribed and properly initiated and spliced. In some cases, there is an appropriate increase in beta-globin mRNA on addition of dimethylsulfoxide (DMSO), an inducer of hemoglobin synthesis and erythroid differentiation in these cells. When NIH-3T3 cells are infected with the same retroviral vector, there is less globin mRNA accumulation and no evidence for appropriate regulation. Human beta-globin gene expression in MELC clones induced with DMSO is 2-3% that of endogenous mouse beta-globin gene expression. These results indicate that retroviral vectors can be used to transfer and appropriately express human beta-globin genes in erythroid cells.

Activation of endogeneous retroviruses in mouse cells by thermal neutrons

The effect of thermal neutrons on the induction of murine endogenous viruses from a mouse fibroblast cell line was investigated. Thermal neutrons were more effective than X-rays in induction of endogenous virus as well as in killing of the cells. However, when measured as a function of cell killing, both radiations had similar efficiency of induction. The RBEs of thermal neutrons alone were calculated on the assumption that the contribution of contaminating gamma-rays was additive. It was 4.2 for the killing effect and 4-5 for virus induction.

Sequences responsible for erythroid and lymphoid leukemia in the long terminal repeats of Friend-mink cell focus-forming and Moloney murine leukemia viruses

Despite the high degree of homology (91%) between the nucleotide sequences of the Friend-mink cell focus-forming (MCF) and the Moloney murine leukemia virus (MuLV) genomic long terminal repeats (LTRs), the pathogenicities determined by the LTR sequences of the two viruses are quite different. Friend-MCF MuLV is an erythroid leukemia virus, and Moloney MuLV is a lymphoid leukemia virus. To map the LTR sequences responsible for the different disease specificities, we constructed nine viruses with LTRs recombinant between the Friend-MCF and Moloney MuLVs. Analysis of the leukemia induced with the recombinant viruses showed that a 195-base-pair nucleotide sequence, including a 75-base-pair nucleotide Moloney enhancer, is responsible for the tissue-specific leukemogenicity of Moloney MuLV. However, not only the enhancer but also its downstream sequences appear to be necessary. The Moloney virus enhancer and its downstream sequence exerted a dominant effect over that of the Friend-MCF virus, but the enhancer sequence alone did not. The results that three of the nine recombinant viruses induced both erythroid and lymphoid leukemias supported the hypothesis that multiple viral genetic determinants control both the ability to cause leukemia and the type of leukemia induced.

Germ line integration of a murine leukemia provirus into a retroviruslike sequence

Nucleotide sequence analysis of the cellular sequences flanking the integrated ecotropic (mouse-infectious) murine leukemia provirus of BALB/c mice indicated that the murine leukemia provirus is integrated in opposing transcriptional orientation within a solo long terminal repeat (LTR) of the VL30 family of endogenous retrovirus-related sequences. To quantify the effect of this integration event on the ability of the ecotropic provirus to be expressed, we constructed recombinant molecules that carried the chloramphenicol acetyltransferase (cat) gene and various viral LTRs and determined the CAT activity induced by these constructs after transfection of NIH 3T3 cells. Our results indicate that the BALB/c ecotropic LTR is about 10-fold more active than the VL30 LTR. The presence of the VL30 LTR did not affect the transcriptional activity of the ecotropic LTR in the context of the integration event. Our results also indicate that the LTRs of the BALB/c provirus are less transcriptionally active than are the proviral LTRs of AKR murine leukemia virus and the Harvey murine sarcoma virus.

Biosynthesis of the v-sis gene product: signal sequence cleavage, glycosylation, and proteolytic processing

The v-sis oncogene and its cellular homolog c-sis encode chain B of platelet-derived growth factor. Cells transformed by v-sis produce a platelet-derived growth factor-related molecule which is able to stimulate the platelet-derived growth factor receptor in an autocrine fashion. Site-directed mutagenesis was used to construct several mutations which substitute charged residues for hydrophobic residues in the proposed signal sequence of the v-sis gene product. Two of these mutations resulted in the synthesis of altered v-sis gene products with an unexpected nuclear location and a loss of biological activity. We also report here the intracellular localization of the v-sis gene product to the endoplasmic reticulum-Golgi compartment, where signal sequence cleavage and N-linked glycosylation occur. The v-sis gene product contains no transmembrane regions, as it is completely protected within isolated microsomes from trypsin proteolysis. Site-directed mutagenesis was also used to alter a proposed proteolytic processing site in the v-sis gene product. This mutant v-sis gene, which encodes Asn-Ser in place of Lys-Arg at residues 110 to 111, was found to retain full biological activity.

Deletions in the C-terminal coding region of the v-sis gene: dimerization is required for transformation

The v-sis gene encodes chain B of platelet-derived growth factor. However, this gene codes for additional amino acids at both the N terminus and the C terminus of its gene product which are not present in the amino acid sequence of platelet-derived growth factor. We constructed a series of deletion mutants with deletions in the v-sis gene in order to define the C-terminal limit of the v-sis gene product which is required for transformation. Deletion mutants of the v-sis gene which encoded truncated gene products up to 57 residues shorter than the v-siswt gene product were still able to transform cells. The minimal transforming region of the v-sis gene product contained six residues fewer than were present in chain B of platelet-derived growth factor. Only 10 residues, including the sequence Cys-Lys-Cys, separated the smallest transforming gene product from the largest nontransforming gene product. These cysteine residues were also important for dimerization of the v-sis gene product, since all of the nontransforming v-sis deletions were unable to form dimers when they were analyzed under nonreducing conditions. Our results suggest that there is a strong connection between transformation and dimerization.

Cell surface expression of membrane-anchored v-sis gene products: glycosylation is not required for cell surface transport

The v-sis gene is able to transform cells by production of a growth factor that is structurally related to platelet-derived growth factor. This growth factor has been detected in the conditioned media of v-sis transformed cells, and is able to stimulate the autophosphorylation of the platelet-derived growth factor receptor. We have used the v-sis gene product to analyze the role of protein-encoded signals in cell surface transport. We constructed several gene fusions that encode transmembrane forms of the v-sis gene product. These membrane-anchored forms of the v-sis gene product are properly folded into a native structure, as indicated by their dimerization, glycosylation, and NH2-terminal proteolytic processing. Indirect immunofluorescence demonstrated that several of these membrane-anchored gene products are transported to the cell surface. Removal of the N-linked glycosylation site from the v-sis gene product did not prevent cell surface transport. Several of these mutant genes are able to induce focus formation in NIH3T3 cells, providing further evidence that the membrane-anchored proteins are properly folded. These results demonstrate that N-linked glycosylation is not required for the cell surface transport of a protein that is in a native, biologically active conformation. These results provide a correlation between cell surface expression of the membrane-anchored v-sis gene products and transformation.

Acceptor sites for retroviral integrations map near DNase I-hypersensitive sites in chromatin

Seven cellular loci with acceptor sites for retroviral integrations have been mapped for the presence of DNase I-hypersensitive sites in chromatin. Integrations in three of these loci, chicken c-erbB, rat c-myc, and a rat locus, dsi-1, had been selected for in retrovirus-induced tumors. Of the remaining four, two, designated dsi-3 and dsi-4, harbored acceptor sites for apparently unselected integrations of Moloney murine leukemia virus in a Moloney murine leukemia virus-induced thymoma, and two, designated C and F, harbored unselected acceptor sites for Moloney murine leukemia virus integrations in a rat fibroblast cell line. Each acceptor site mapped to within 500 base pairs of a DNase I-hypersensitive site. In the analyses of the unselected integrations, six hypersensitive sites were observed in 39 kilobases of DNA. The four acceptor sites in this DNA were localized between 0.05 and 0.43 kilobases of a hypersensitive site. The probability of this close association occurring by chance was calculated to be extremely low. Hypersensitive sites were mapped in cells representing the lineage in which integration had occurred as well as in an unrelated lineage. In six of the seven acceptor loci hypersensitive sites could not be detected in the unrelated lineage. Our results indicate that retroviruses preferentially integrate close to DNase I-hypersensitive sites and that many of these sites are expressed in some but not all cells.

Biologically active mutants with deletions in the v-mos oncogene assayed with retroviral vectors

We have constructed retroviral expression vectors by manipulation of the Moloney murine leukemia virus genome such that an exogenous DNA sequence may be inserted and subsequently expressed when introduced into mammalian cells. A series of N-terminal deletions of the v-mos oncogene was constructed and assayed for biological activity with these retroviral expression vectors. The results of the deletion analysis demonstrate that the region of p37mos coding region upstream of the third methionine codon is dispensable with respect to transformation. However, deletion mutants of v-mos which allow initiation of translation at the fourth methionine codon have lost the biological activity of the parental v-mos gene. Furthermore, experiments were also carried out to define the C-terminal limit of the active region of p37mos by the construction of premature termination mutants by the insertion of a termination oligonucleotide. Insertion of the oligonucleotide just 69 base pairs upstream from the wild-type termination site abolished the focus-forming ability of v-mos. Thus, we have shown the N-terminal limit of the active region of p37mos to be between the third and fourth methionines, while the C-terminal limit is within the last 23 amino acids of the protein.

A retrovirus vector expressing the putative mammary oncogene int-1 causes partial transformation of a mammary epithelial cell line

In mammary tumors induced by the mouse mammary tumor virus (MMTV), the int-1 gene is frequently activated by adjacent proviral insertions and is thereby strongly implicated in tumorigenesis. To seek a direct biological effect of int-1 that would validate its proposed role as an oncogene, we constructed a retrovirus vector containing the gene and examined its effects on tissue culture cells. Expression of int-1 in a mammary epithelial cell line caused striking morphological changes, unrestricted growth at high cell density, and focus formation on a monolayer, although the cells were not tumorigenic in vivo. This partial transformation induced by int-1 was not observed in cells infected by an otherwise identical virus bearing a frameshift mutation in the gene. These findings strongly support the hypothesis that int-1 plays a functional role in MMTV-induced mammary tumorigenesis.

Suppression of the hypomethylated Moloney leukemia virus genome in undifferentiated teratocarcinoma cells and inefficiency of transformation by a bacterial gene under control of the long terminal repeat

The Moloney leukemia virus (M-MuLV) genome was introduced into undifferentiated teratocarcinoma cells by transfection of a plasmid with the virus genome linked to pSV2neo, which carries a bacterial drug resistance gene, neo, or by cotransfection with pSV2neo. In the resulting cells, the M-MuLV genome remained hypomethylated, but its expression was suppressed in cells in an undifferentiated state. The pattern of DNA methylation of the viral genome remained unchanged when the cells were induced to differentiate into epithelial tissues. However, spontaneous M-MuLV expression was detected with differentiation of the cells. To determine to what extent the viral long terminal repeat (LTR) was responsible for this suppression in undifferentiated cells, I constructed plasmids in which neo was placed under the control of the promoter sequence of the dihydrofolate reductase gene or the M-MuLV LTR, and compared the biological activities of the plasmids in Ltk- cells and in undifferentiated teratocarcinoma cells. In Ltk- cells, these plasmids were highly efficient in making the cells resistant to selection by G418. However, in undifferentiated teratocarcinoma cells, the M-MuLV LTR promoted neo gene expression at only 10% of the expected efficiency, as compared with the expression of the neo gene under the control of the simian virus to or dihydrofolate reductase promoter. Thus, the mechanisms of gene regulation are not the same in undifferentiated and differentiated teratocarcinoma cells.

Chromosomal position and specific demethylation in enhancer sequences of germ line-transmitted retroviral genomes during mouse development

The methylation pattern of the germ line-transmitted Moloney leukemia proviral genome was analyzed in DNA of sperm, of day-12 and day-17 embryos, and of adult mice from six different Mov substrains. At day 12 of gestation, all 50 testable CpG sites in the individual viral genomes as well as sites in flanking host sequences were highly methylated. Some sites were unmethylated in sperm, indicating de novo methylation of unique DNA sequences during normal mouse development. At subsequent stages of development, specific CpG sites which were localized exclusively in the 5' and 3' enhancer regions of the long terminal repeat became progressively demethylated in all six proviruses. The extent of enhancer demethylation, however, was tissue specific and strongly affected by the chromosomal position of the respective proviral genome. This position-dependent demethylation of enhancer sequences was not accompanied by a similar change within the flanking host sequences, which remained virtually unchanged. Our results indicate that viral enhancer sequences, but not other sequences in the M-MuLV genome, may have an intrinsic ability to interact with cellular proteins, which can perturb the interaction of the methylase with DNA. Demethylation of enhancer sequences is not sufficient for gene expression but may be a necessary event which enables the enhancer to respond to developmental signals which ultimately lead to gene activation.

Deletions in the N-terminal coding region of the v-sis gene: determination of the minimal transforming region

The gene product of the v-sis gene is closely related to the B chain of platelet-derived growth factor (PDGF). However, v-sis also encodes additional amino acids at its N and C termini, which are not represented in the sequence data of PDGF. We have constructed a series of N-terminal deletion mutants in the v-sis gene to define the minimum region required for transformation. These mutants were assayed for biological activity by using retroviral expression vectors which donate a signal sequence, required for translocation across the rough endoplasmic reticulum, to the mutant gene product. The minimal transforming region of the v-sis gene product defined by this analysis has 15 residues missing at the N terminus when compared with the PDGF-B chain. There are only two residues separating the closest transforming and nontransforming gene products. Mutant gene products lacking both the basic dipeptide processing site and the N-linked glycosylation site were found to be biologically active, indicating the dispensability of those processing steps. These results delimit the minimal transforming region of the v-sis gene product to residues 127 through 214, a total of 21 residues smaller than the PDGF-B chain.

Deletions in the C-terminal coding region of the v-sis gene: dimerization is required for transformation

The v-sis gene encodes chain B of platelet-derived growth factor. However, this gene codes for additional amino acids at both the N terminus and the C terminus of its gene product which are not present in the amino acid sequence of platelet-derived growth factor. We constructed a series of deletion mutants with deletions in the v-sis gene in order to define the C-terminal limit of the v-sis gene product which is required for transformation. Deletion mutants of the v-sis gene which encoded truncated gene products up to 57 residues shorter than the v-siswt gene product were still able to transform cells. The minimal transforming region of the v-sis gene product contained six residues fewer than were present in chain B of platelet-derived growth factor. Only 10 residues, including the sequence Cys-Lys-Cys, separated the smallest transforming gene product from the largest nontransforming gene product. These cysteine residues were also important for dimerization of the v-sis gene product, since all of the nontransforming v-sis deletions were unable to form dimers when they were analyzed under nonreducing conditions. Our results suggest that there is a strong connection between transformation and dimerization.

Biosynthesis of the v-sis gene product: signal sequence cleavage, glycosylation, and proteolytic processing

The v-sis oncogene and its cellular homolog c-sis encode chain B of platelet-derived growth factor. Cells transformed by v-sis produce a platelet-derived growth factor-related molecule which is able to stimulate the platelet-derived growth factor receptor in an autocrine fashion. Site-directed mutagenesis was used to construct several mutations which substitute charged residues for hydrophobic residues in the proposed signal sequence of the v-sis gene product. Two of these mutations resulted in the synthesis of altered v-sis gene products with an unexpected nuclear location and a loss of biological activity. We also report here the intracellular localization of the v-sis gene product to the endoplasmic reticulum-Golgi compartment, where signal sequence cleavage and N-linked glycosylation occur. The v-sis gene product contains no transmembrane regions, as it is completely protected within isolated microsomes from trypsin proteolysis. Site-directed mutagenesis was also used to alter a proposed proteolytic processing site in the v-sis gene product. This mutant v-sis gene, which encodes Asn-Ser in place of Lys-Arg at residues 110 to 111, was found to retain full biological activity.

DNA methylation and transcriptional controls of proviral DNA in avian sarcoma virus-transformed mammalian cells

Restriction mapping has been used to study the integration state of the single provirus present in the DNA of two subclones, RS2/3 and RS2/6, of hamster cells transformed in vitro by Rous sarcoma virus, but differing markedly in their level of proviral transcription which was higher in RS2/3 cells. It was observed that both proviruses are complete and located at the same integration site in each DNA. However, the RS2/6 provirus and its flanking cellular sequences were found to be hypermethylated, although a very short region was hypomethylated at about 1 kb upstream of the src gene. A low level of methylation was observed in RS2/3 cells, in the proviral region. Northern analysis of viral RNA detected only the src mRNA in RS2/6 cells, whereas the two other viral mRNA were found in RS2/3 cells, however their levels were very low compared to that of the src mRNA. These findings suggest a correlation between the methylation state and the transcriptional control of the proviral genes. Sequences responsible for such a control by methylation should lie within both the provirus and its 5' flanking cellular sequences.

Isolation of a recombinant murine leukemia virus utilizing a new primer tRNA

We have previously described the construction of a mutant of Moloney murine leukemia virus bearing a deletion at the normal site of integration of the viral DNA. We have now recovered a revertant of the virus after abortive infection of mouse cells and have determined the structure of the new virus. The revertant is a recombinant virus containing a 500-base-pair patch of new sequences derived from the mouse genome. The integration site was perfectly restored to the wild-type sequence, although the patch of DNA was overall only 80% homologous to Moloney murine leukemia virus. Surprisingly, the tRNA primer binding site was no longer homologous to the usual proline tRNAs, but was a perfect match for glutamine tRNA. This result suggests that the Moloney murine leukemia virus reverse transcriptase is not specific to one tRNA, but can utilize different tRNAs to prime the synthesis of viral DNA. Comparisons with published reports allowed the identification of sequences that are 94% homologous to the patch sequence, present in one of the endogenous retroviral sequences of the mouse. No replication-competent members of this family, utilizing the glutamine tRNA primer, have been previously isolated.