Formation and structure of infectious DNA of spleen necrosis virus

Identification of conserved, primary sequence motifs that direct retrovirus RNA fate

Precise stoichiometry of genome-length transcripts and alternatively spliced mRNAs is a hallmark of retroviruses. We discovered short, guanosine and adenosine sequence motifs in the 5'untranslated region of several retroviruses and ascertained the reasons for their conservation using a representative lentivirus and genetically simpler retrovirus. We conducted site-directed mutagenesis of the GA-motifs in HIV molecular clones and observed steep replication delays in T-cells. Quantitative RNA analyses demonstrate the GA-motifs are necessary to retain unspliced viral transcripts from alternative splicing. Mutagenesis of the GA-motifs in a C-type retrovirus validate the similar downregulation of unspliced transcripts and virion structural protein. The evidence from cell-based co-precipitation studies shows the GA-motifs in the 5'untranslated region confer binding by SFPQ/PSF, a protein co-regulated with T-cell activation. Diminished SFPQ/PSF or mutation of either GA-motif attenuates the replication of HIV. The interaction of SFPQ/PSF with both GA-motifs is crucial for maintaining the stoichiometry of the viral transcripts and does not affect packaging of HIV RNA. Our results demonstrate the conserved GA-motifs direct the fate of retrovirus RNA. These findings have exposed an RNA-based molecular target to attenuate retrovirus replication.

HIV-1 and two avian retroviral 5' untranslated regions bind orthologous human and chicken RNA binding proteins

Essential host cofactors in retrovirus replication bind cis-acting sequences in the 5'untranslated region (UTR). Although host RBPs are crucial to all aspects of virus biology, elucidating their roles in replication remains a challenge to the field. Here RNA affinity-coupled-proteomics generated a comprehensive, unbiased inventory of human and avian RNA binding proteins (RBPs) co-isolating with 5'UTRs of HIV-1, spleen necrosis virus and Rous sarcoma virus. Applying stringent biochemical and statistical criteria, we identified 185 RBP; 122 were previously implicated in retrovirus biology and 63 are new to the 5'UTR proteome. RNA electrophoretic mobility assays investigated paralogs present in the common ancestor of vertebrates and one hnRNP was identified as a central node to the biological process-anchored networks of HIV-1, SNV, and RSV 5' UTR-proteomes. This comprehensive view of the host constituents of retroviral RNPs is broadly applicable to investigation of viral replication and antiviral response in both human and avian cell lineages.

Intracellular partitioning of cell organelles and extraneous nanoparticles during mitosis

The nucleocytoplasmic partitioning of nanoparticles as a result of cell division is highly relevant to the field of nonviral gene delivery. We reviewed the literature on the intracellular distribution of cell organelles (the endosomal vesicles, Golgi apparatus, endoplasmic reticulum and nucleus), foreign macromolecules (dextrans and plasmid DNA) and inorganic nanoparticles (gold, quantum dot and iron oxide) during mitosis. For nonviral gene delivery particles (lipid- or polymer-based), indirect proof of nuclear entry during mitosis is provided. We also describe how retroviruses and latent DNA viruses take advantage of mitosis to transfer their viral genome and segregate their episomes into the host daughter nuclei. Based on this knowledge, we propose strategies to improve nonviral gene delivery in dividing cells with the ultimate goal of designing nonviral gene delivery systems that are as efficient as their viral counterparts but non-immunogenic, non-oncogenic and easy and inexpensive to prepare.

Designed zinc finger protein interacting with the HIV-1 integrase recognition sequence at 2-LTR-circle junctions

Integration of HIV-1 cDNA into the host genome is a crucial step for viral propagation. Two nucleotides, cytosine and adenine (CA), conserved at the 3' end of the viral cDNA genome, are cleaved by the viral integrase (IN) enzyme. As IN plays a crucial role in the early stages of the HIV-1 life cycle, substrate blockage of IN is an attractive strategy for therapeutic interference. In this study, we used the 2-LTR-circle junctions of HIV-1 DNA as a model to design zinc finger protein (ZFP) targeting at the end terminal portion of HIV-1 LTR. A six-contiguous ZFP, namely 2LTRZFP was designed using zinc finger tools. The designed motif was expressed and purified from E. coli to determine its binding properties. Surface plasmon resonance (SPR) was used to determine the binding affinity of 2LTRZFP to its target DNA. The level of dissociation constant (K(d)) was 12.0 nM. The competitive SPR confirmed that 2LTRZFP specifically interacted with its target DNA. The qualitative binding activity was subsequently determined by EMSA and demonstrated the aforementioned correlation. In addition, molecular modeling and binding energy analyses were carried out to provide structural insight into the binding of 2LTRZFP to the specific and nonspecific DNA target. It is suggested that hydrogen-bonding interactions play a key role in the DNA recognition mechanisms of the designed ZFP. Our study suggested an alternative HIV therapeutic strategy using ZFP interference of the HIV integration process.

Cyclophilin A levels dictate infection efficiency of human immunodeficiency virus type 1 capsid escape mutants A92E and G94D

Cyclophilin A (CypA) is an important human immunodeficiency virus type 1 (HIV-1) cofactor in human cells. HIV-1 A92E and G94D capsid escape mutants arise during CypA inhibition and in certain cell lines are dependent on CypA inhibition. Here we show that dependence on CypA inhibition is due to high CypA levels. Restricted HIV-1 is stable, and remarkably, restriction is augmented by arresting cell division. Nuclear entry is not inhibited. We propose that high CypA levels and capsid mutations combine to disturb uncoating, leading to poor infectivity, particularly in arrested cells. Our data suggest a role for CypA in uncoating the core of HIV-1 to facilitate integration.

A phenotypic recessive, post-entry block in rabbit cells that results in aberrant trafficking of HIV-1

Rabbit cells are poorly permissive to HIV-1 infection, but little is known about the nature of this block. Here, we show that the block to infection is mainly at the level of reverse transcription (RT), is independent of the cell receptor used by the virus for entry, cannot be effectively saturated with high doses of virus or virus-like particles, and has a recessive phenotype in human-rabbit heterokaryons. RT complexes (RTCs) extracted from human and rabbit cells have different densities but are both competent for RT in an in vitro endogenous assay. Cell fractionation showed that HIV-1 is trafficked in a different way in human and rabbit cells and that correct intracellular trafficking is linked to efficient RT and high infectivity in vivo. Viral DNA accumulated in rabbit cell nuclei only at a later stage and failed to associate with chromatin, suggesting a further block prior to integration. Our data point to the existence of cellular factors regulating the early stages of intracytoplasmic and possibly intranuclear HIV-1 trafficking.

Insertion of a classical nuclear import signal into the matrix domain of the Rous sarcoma virus Gag protein interferes with virus replication

The Rous sarcoma virus Gag protein undergoes transient nuclear trafficking during virus assembly. Nuclear import is mediated by a nuclear targeting sequence within the MA domain. To gain insight into the role of nuclear transport in replication, we investigated whether addition of a "classical " nuclear localization signal (NLS) in Gag would affect virus assembly or infectivity. A bipartite NLS derived from nucleoplasmin was inserted into a region of the MA domain of Gag that is dispensable for budding and infectivity. Gag proteins bearing the nucleoplasmin NLS insertion displayed an assembly defect. Mutant virus particles (RC.V8.NLS) were not infectious, although they were indistinguishable from wild-type virions in Gag, Gag-Pol, Env, and genomic RNA incorporation and Gag protein processing. Unexpectedly, postinfection viral DNA synthesis was also normal, as similar amounts of two-long-terminal-repeat junction molecules were detected for RC.V8.NLS and wild type, suggesting that the replication block occurred after nuclear entry of proviral DNA. Phenotypically revertant viruses arose after continued passage in culture, and sequence analysis revealed that the nucleoplasmin NLS coding sequence was deleted from the gag gene. To determine whether the nuclear targeting activity of the nucleoplasmin sequence was responsible for the infectivity defect, two critical basic amino acids in the NLS were altered. This virus (RC.V8.KR/AA) had restored infectivity, and the MA.KR/AA protein showed reduced nuclear localization, comparable to the wild-type MA protein. These data demonstrate that addition of a second NLS, which might direct MA and/or Gag into the nucleus by an alternate import pathway, is not compatible with productive virus infection.

Host factors that affect Ty3 retrotransposition in Saccharomyces cerevisiae

The retrovirus-like element Ty3 of Saccharomyces cerevisiae integrates at the transcription initiation region of RNA polymerase III. To identify host genes that affect transposition, a collection of insertion mutants was screened using a genetic assay in which insertion of Ty3 activates expression of a tRNA suppressor. Fifty-three loci were identified in this screen. Corresponding knockout mutants were tested for the ability to mobilize a galactose-inducible Ty3, marked with the HIS3 gene. Of 42 mutants tested, 22 had phenotypes similar to those displayed in the original assay. The proteins encoded by the defective genes are involved in chromatin dynamics, transcription, RNA processing, protein modification, cell cycle regulation, nuclear import, and unknown functions. These mutants were induced for Ty3 expression and assayed for Gag3p protein, integrase, cDNA, and Ty3 integration upstream of chromosomal tDNA(Val(AAC)) genes. Most mutants displayed differences from the wild type in one or more intermediates, although these were typically not as severe as the genetic defect. Because a relatively large number of genes affecting retrotransposition can be identified in yeast and because the majority of these genes have mammalian homologs, this approach provides an avenue for the identification of potential antiviral targets.

Phosphorylated serine residues and an arginine-rich domain of the moloney murine leukemia virus p12 protein are required for early events of viral infection

Mutational analyses of the p12 Gag phosphoprotein of Moloney murine leukemia virus have demonstrated its participation in both virus assembly and the early stages of infection. The molecular mechanisms by which p12 functions in these events are still poorly understood. We performed studies to examine the significance of p12 phosphorylation in the viral life cycle. Alanine substitutions were introduced at the potential phosphorylation sites in p12, and the resulting mutants were tested for replication. Mutant viruses with changes at S61 and S78 were severely impaired, whereas the other mutant viruses were viable. S61 was shown to be required for normal levels of phosphorylation of p12 in vivo. These defective mutant viruses showed no apparent alteration to Gag protein processing or reduction in the yield of virions after transient transfection, but the mutants failed to form circular viral DNAs in acutely infected cells. Sequence analysis of revertant clones derived from S(61,65)A mutant virus revealed two classes: one group with a single mutation at a residue adjacent to S61 and another group with mutations introducing new positive charges surrounding S61. In vivo [32P]orthophosphate labeling indicated that the rescue of the S(61,65)A mutant virus did not result in a significant increase in the phosphorylation level of p12. Alanine substitutions of an arginine-rich stretch near S61 (at R-66, -68, -70, and -71) resulted in the same phenotype as the S(61,65)A mutant virus. The restored function of S(61,65)A mutant virus by second or third site mutations may result from a structural change or the addition of positively charged residues in the arginine-rich region.

Cell cycle control of reverse transcriptase activity for the yeast retrotransposon Ty3

Retroviruses and retrotransposons depend on their host cells to complete their replication cycles. In many cases, the viral step of reverse transcription is blocked when host cells are arrested in their cell cycle and this block is only released when the host cell resumes division. It has previously been shown that a retrotransposon found in Saccharomyces cerevisiae, Ty3, is unable to produce full-length double-stranded DNA, the product of reverse transcription, when the host cells are arrested in G1. In this study we show that, although Ty3 viruslike particles are produced at equivalent levels in arrested and nonarrested cells, the reverse transcriptase enzyme is inactive in arrested cells. The enzyme activity is restored when the arrested cells are permitted to resume cell division. These data suggest that a host factor regulates the activity of Ty3 reverse transcriptase in the cell cycle, which represents a novel cellular control of retroelements.

Preactivation of B lymphocytes does not enhance mouse mammary tumor virus infection

We investigated whether mouse mammary tumor virus (MMTV) favors preactivated or naive B cells as targets for efficient infection. We have demonstrated previously that MMTV activates B cells upon infection. Here, we show that polyclonal activation of B cells leads instead to lower infection levels and attenuated superantigen-specific T-cell responses in vivo. This indicates that naive small resting B cells are the major targets of MMTV infection and that the activation induced by MMTV is sufficient to allow efficient infection.

Unintegrated circular HIV-1 DNA in the peripheral mononuclear cells of HIV-1-infected subjects: association with high levels of plasma HIV-1 RNA, rapid decline in CD4 count, and clinical progression to AIDS

We observed 36 HIV-infected patients to evaluate whether the presence of tandem 2-long terminal repeat circular unintegrated HIV-1 DNA (2-LTR) in peripheral blood mononuclear cells (PBMC) at baseline was associated with acceleration of HIV disease. Detection of 2-LTR at baseline correlated with high plasma HIV-1 RNA levels (p < .01), recovery of culturable HIV-1 from plasma (p = .02), and progression to AIDS during follow-up (p = .01). More patients with 2-LTR (68%) than without 2-LTR (31%) had a decline in CD4 levels of >50 cells/mm3 over the first 18 months of follow-up (p = .04), and the average annual CD4 decline was 35% in patients with 2-LTR compared with 16% in those without 2-LTR (p = 0.06). Detection of 2-LTR in PBMC at baseline was an independent predictor of high plasma HIV-1 RNA levels and subsequent CD4 cell decline in this cohort of patients with predominantly nonsyncytium-inducing (NSI) isolates at baseline. The presence of 2-LTR in PBMC appears to be reflective of ongoing HIV-1 replication, as measured by plasma HIV-1 RNA levels, and identifies persons at risk for immunologic and clinical decline.

Transposition of the yeast retroviruslike element Ty3 is dependent on the cell cycle

Host cell cycle genes provide important functions to retroviruses and retroviruslike elements. To define some of these functions, the cell cycle dependence of transposition of the yeast retroviruslike element Ty3 was examined. Ty3 is unique among retroviruslike elements because of the specificity of its integration, which occurs upstream of genes transcribed by RNA polymerase III. A physical assay for Ty3 transposition which takes advantage of this position-specific integration was developed. The assay uses PCR to amplify a product of Ty3 integration into a target plasmid that carries a modified tRNA gene. By using the GAL1 upstream activating sequence to regulate expression of Ty3, transposition was detected within one generation of cell growth after Ty3 transcription was initiated. This physical assay was used to show that Ty3 did not transpose when yeast cells were arrested in G1 during treatment with the mating pheromone alpha-factor. The restriction of transposition was not due to changes in transcription of either Ty3 or tRNA genes or to aspects of the mating pheromone response unrelated to cell cycle arrest. The block of the Ty3 life cycle was reversed when cells were released from G1 arrest. Examination of Ty3 intermediates during G1 arrest indicated that Ty3 viruslike particles were present but that reverse transcription of the Ty3 genomic RNA into double-stranded DNA had not occurred. In G1, the Ty3 life cycle is blocked after particle assembly but before the completion of reverse transcription.

Transposition of the yeast retroviruslike element Ty3 is dependent on the cell cycle

Host cell cycle genes provide important functions to retroviruses and retroviruslike elements. To define some of these functions, the cell cycle dependence of transposition of the yeast retroviruslike element Ty3 was examined. Ty3 is unique among retroviruslike elements because of the specificity of its integration, which occurs upstream of genes transcribed by RNA polymerase III. A physical assay for Ty3 transposition which takes advantage of this position-specific integration was developed. The assay uses PCR to amplify a product of Ty3 integration into a target plasmid that carries a modified tRNA gene. By using the GAL1 upstream activating sequence to regulate expression of Ty3, transposition was detected within one generation of cell growth after Ty3 transcription was initiated. This physical assay was used to show that Ty3 did not transpose when yeast cells were arrested in G1 during treatment with the mating pheromone alpha-factor. The restriction of transposition was not due to changes in transcription of either Ty3 or tRNA genes or to aspects of the mating pheromone response unrelated to cell cycle arrest. The block of the Ty3 life cycle was reversed when cells were released from G1 arrest. Examination of Ty3 intermediates during G1 arrest indicated that Ty3 viruslike particles were present but that reverse transcription of the Ty3 genomic RNA into double-stranded DNA had not occurred. In G1, the Ty3 life cycle is blocked after particle assembly but before the completion of reverse transcription.

Efficient insertion from an internal long terminal repeat (LTR)-LTR sequence on a reticuloendotheliosis virus vector is imprecise and cell specific

To examine the fidelity and efficiency of integration from a covalently closed long terminal repeat (LTR)-LTR sequence in vivo, we isolated individual spleen necrosis virus proviruses that arose following infection of chicken embryo fibroblasts (CEFs) and sequenced the provirus-cell DNA junctions. Some but not all CEF preparations allowed efficient insertion from the internal sequence. Moreover, in contrast to integration from the normal ends of the viral DNA, which occurs with precision with respect to the viral DNA, insertion from the internal sequence was not precise. In particular, there were short deletions of variable size from the viral DNA and these proviruses were not flanked by short direct repeats. Although this imprecise insertion can be efficient in CEFs, such integration is very inefficient in two other cell types (D17 and QT47) that support the replication of reticuloendotheliosis viruses. Thus, it is possible that there is a cell-specific factor(s) in CEFs required for efficient but imprecise insertion or, alternatively, D17 and QT47 cells contain a factor that abrogates integration from an internal LTR-LTR junction. Virus particles released from CEFs do not efficiently use the LTR-LTR junction following infection of D17 cells. Therefore, if there is a CEF-specific factor required for insertion, it does not appear to be transferred through particles.

Gene transfer by retrovirus vectors occurs only in cells that are actively replicating at the time of infection

Previous reports have shown that retrovirus infection is inhibited in nonreplicating (stationary-phase [hereafter called stationary]) cells. Infection of stationary cells was shown to occur when the cells were allowed to replicate at times up to a week after infection, suggesting that an unintegrated retrovirus could persist in a form that was competent to integrate after release of the block to replication. However, those studies were complicated by the use of replication-competent virus, which can spread in the infected cells. We have used a replication-defective retrovirus vector to compare the efficiency of gene transfer in stationary and replicating rat embryo fibroblasts. In agreement with previous results, gene transfer was inhibited 100-fold in stationary versus replicating cells. In contrast to previously reported results, the block to infection could not be relieved by stimulating stationary cells to divide at times from 6 h to 10 days after infection. Thus, for successful retroviral infection, the infected cells must be replicating at the time of infection. These results have important implications for the use of retroviral vectors for gene transfer.

Gene transfer by retrovirus vectors occurs only in cells that are actively replicating at the time of infection

Previous reports have shown that retrovirus infection is inhibited in nonreplicating (stationary-phase [hereafter called stationary]) cells. Infection of stationary cells was shown to occur when the cells were allowed to replicate at times up to a week after infection, suggesting that an unintegrated retrovirus could persist in a form that was competent to integrate after release of the block to replication. However, those studies were complicated by the use of replication-competent virus, which can spread in the infected cells. We have used a replication-defective retrovirus vector to compare the efficiency of gene transfer in stationary and replicating rat embryo fibroblasts. In agreement with previous results, gene transfer was inhibited 100-fold in stationary versus replicating cells. In contrast to previously reported results, the block to infection could not be relieved by stimulating stationary cells to divide at times from 6 h to 10 days after infection. Thus, for successful retroviral infection, the infected cells must be replicating at the time of infection. These results have important implications for the use of retroviral vectors for gene transfer.

The pathophysiology of murine retrovirus-induced leukemias

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

The retrovirus pol gene encodes a product required for DNA integration: identification of a retrovirus int locus

We mutagenized cloned spleen necrosis virus DNA to identify a region of the retrovirus genome encoding a polypeptide required for integration of viral DNA. Five plasmids bearing different lesions in the 3' end of the pol gene were examined for the ability to integrate or replicate following transfection of chicken embryo fibroblasts. Transfection with one of these DNAs resulted in the generation of mutant virus incapable of integrating but able to replicate at low levels; this phenotype is identical to that of mutants bearing alterations in the cis-acting region, att. To determine whether the 3' end of the pol gene encodes a protein that interacts with att, we did a complementation experiment. Cells were first infected with an att- virus and then superinfected with the integration-deficient virus containing a lesion in the pol gene and a wild-type att site. The results showed that the att- virus provided a transacting function allowing integration of viral DNA derived from the mutant bearing a wild-type att site. Thus, the 3' end of the pol gene serves as an "int" locus and encodes a protein mediating integration of retrovirus DNA through interaction with att.

An X-linked gene affecting mouse cell DNA synthesis also affects production of unintegrated linear and supercoiled DNA of murine leukemia virus

To identify specific cellular factors which could be required during the synthesis of retroviral DNA, we have studied the replication of murine leukemia virus in mouse cells temperature sensitive for cell DNA synthesis (M. L. Slater and H. L. Ozer, Cell 7:289-295, 1976) and in several of their revertants. This mutation has previously been mapped on the X chromosome. We found that a short incubation of mutant cells at a nonpermissive temperature (39 degrees C) during the early part of the virus cycle (between 0- to 20-h postinfection) greatly inhibited virus production. This effect was not observed in revertant or wild-type cells. Molecular studies by the Southern transfer procedure of the unintegrated viral DNA synthesized in these cells at a permissive (33 degrees C) or nonpermissive temperature revealed that the levels of linear double-stranded viral DNA (8.8 kilobase pairs) were nearly identical in mutant or revertant cells incubated at 33 or 39 degrees C. However, the levels of two species of supercoiled viral DNA (with one or two long terminal repeats) were significantly lower in mutant cells incubated at 39 degrees C than in mutant cells incubated at 33 degrees C or in revertant cells incubated at 39 degrees C. Pulse-chase experiments showed that linear viral DNA made at 39 degrees C could not be converted into supercoiled viral DNA in mutant cells after a shift down to 33 degrees C. In contrast, such conversion was observed in revertant cells. Restriction endonuclease analysis did not detect differences in the structure of linear viral DNA made at 39 degrees C in mutant cells as compared to linear viral DNA isolated from the same cells at 33 degrees C. However, linear viral DNA made at 39 degrees C in mutant cells was poorly infectious in transfection assays. Taken together, these results strongly suggest that this X-linked gene, affecting mouse cell DNA synthesis, is operating in the early phase of murine leukemia virus replication. It seems to affect the level of production of unintegrated linear viral DNA only slightly while greatly reducing the infectivity of these molecules. In contrast, the accumulation of supercoiled viral DNA and subsequent progeny virus production are greatly reduced. Our pulse-chase experiments suggest that the apparent, but not yet identified, defect in linear viral DNA molecules might be responsible for their subsequent impaired circularization.

Circles with two tandem LTRs are precursors to integrated retrovirus DNA

Infection of susceptible cells by retroviruses results in the synthesis of linear DNA with two long terminal repeats (LTRs), circular DNA with a single LTR, and circular DNA with two tandem LTRs. To determine which of these unintegrated molecules serves as the precursor to the provirus, we inserted into a retrovirus vector a 49 bp fragment containing the junction formed by in vivo blunt-end ligation of two LTRs. Infection of chicken embryo fibroblasts with virus recovered from this vector and subsequent characterization of the proviral DNA revealed that efficient integration can occur from this introduced junction sequence. Therefore, circular DNA with two tandem LTRs is a precursor to the provirus.

Structure and dimorphism of c-rel (turkey), the cellular homolog to the oncogene of reticuloendotheliosis virus strain T

A locus has been identified in turkey DNA that contains nucleotide sequences homologous to the oncogene (v-rel) in the avian retrovirus, reticuloendotheliosis virus strain T. This locus, c-rel, has been molecularly cloned from an apparently heterozygous turkey. c-rel is approximately 23 kilobase pairs in length, with at least seven apparent introns, and contains sequences sufficient to account for all of v-rel. Nucleic acid sequence differences exist between v-rel and homologous regions of c-rel. We examined a population of turkeys to determine whether these sequence differences are the result of polymorphism in the population. Within the turkey population, c-rel is dimorphic in apparent introns and 3' flanking sequences, but polymorphism has not been detected within the regions of the c-rel locus that are homologous to v-rel. Additionally, no nucleic acid sequence differences have been detected between the regions of c-rel in turkeys that are homologous to v-rel and the sequences related to v-rel of a homologous locus in chickens (Chen et al., J. Virol. 245:104-113, 1983). The general organization of introns and flanking sequences is conserved for both c-rel in turkeys and this locus in chickens, indicating that c-rel, like other proto-oncogenes, may have an important development or metabolic function.

An X-linked gene affecting mouse cell DNA synthesis also affects production of unintegrated linear and supercoiled DNA of murine leukemia virus

To identify specific cellular factors which could be required during the synthesis of retroviral DNA, we have studied the replication of murine leukemia virus in mouse cells temperature sensitive for cell DNA synthesis (M. L. Slater and H. L. Ozer, Cell 7:289-295, 1976) and in several of their revertants. This mutation has previously been mapped on the X chromosome. We found that a short incubation of mutant cells at a nonpermissive temperature (39 degrees C) during the early part of the virus cycle (between 0- to 20-h postinfection) greatly inhibited virus production. This effect was not observed in revertant or wild-type cells. Molecular studies by the Southern transfer procedure of the unintegrated viral DNA synthesized in these cells at a permissive (33 degrees C) or nonpermissive temperature revealed that the levels of linear double-stranded viral DNA (8.8 kilobase pairs) were nearly identical in mutant or revertant cells incubated at 33 or 39 degrees C. However, the levels of two species of supercoiled viral DNA (with one or two long terminal repeats) were significantly lower in mutant cells incubated at 39 degrees C than in mutant cells incubated at 33 degrees C or in revertant cells incubated at 39 degrees C. Pulse-chase experiments showed that linear viral DNA made at 39 degrees C could not be converted into supercoiled viral DNA in mutant cells after a shift down to 33 degrees C. In contrast, such conversion was observed in revertant cells. Restriction endonuclease analysis did not detect differences in the structure of linear viral DNA made at 39 degrees C in mutant cells as compared to linear viral DNA isolated from the same cells at 33 degrees C. However, linear viral DNA made at 39 degrees C in mutant cells was poorly infectious in transfection assays. Taken together, these results strongly suggest that this X-linked gene, affecting mouse cell DNA synthesis, is operating in the early phase of murine leukemia virus replication. It seems to affect the level of production of unintegrated linear viral DNA only slightly while greatly reducing the infectivity of these molecules. In contrast, the accumulation of supercoiled viral DNA and subsequent progeny virus production are greatly reduced. Our pulse-chase experiments suggest that the apparent, but not yet identified, defect in linear viral DNA molecules might be responsible for their subsequent impaired circularization.

The terminal nucleotides of retrovirus DNA are required for integration but not virus production

Deletion of specific nucleotides at either end of the long terminal repeat of the avian retrovirus, spleen necrosis virus, results in replication-competent but integration-defective virus. This result supports two conclusions: (1) the 5-base pair terminal inverted repeats and three to seven adjacent nucleotides are required for integration; (2) integration of retrovirus DNA is not required for retrovirus gene expression.

Structure and expression of c-rel, the cellular homolog to the oncogene of reticuloendotheliosis virus strain T

The cellular homolog of the onc sequences in the avian retrovirus reticuloendotheliosis virus strain T (v-rel) was studied by molecular cloning and nucleic acid hybridization. In contrast to v-rel sequences, which are 1.4 kilobase pairs long, the cellular homolog, c-rel, from line 15B chickens is at least 25 kilobase pairs long, with multiple apparent introns. A 4.0-kilobase polyadenylic acid-containing RNA transcript is the primary species of c-rel RNA present in uninfected chicken cells. Sequences at the 3' end of this c-rel RNA are not present in v-rel.

Substitution of 5' helper virus sequences into non-rel portion of reticuloendotheliosis virus strain T suppresses transformation of chicken spleen cells

The genome of the highly oncogenic avian retrovirus reticuloendotheliosis virus strain T (REV-T) differs from that of the helper virus reticuloendotheliosis virus strain A by a substitution (rel and a large deletion. Further deletions, constructed in vitro, within the helper-virus-related sequences of REV-T have little effect on the ability of the virus to transform chicken spleen cells in vitro. However, deletions that extend into rel abolish transformation. Substitution of helper-virus-related sequences for the deleted region in the non-rel portion of REV-T also abolishes transformation. Viruses with revertant phenotype were obtained both spontaneously and by construction in vitro from these substituted recombinants. The revertant viruses have various mutations, including deletions and insertions, in the helper-virus-related sequences. Thus the additional helper-virus-related sequences suppress expression of transformation in cis, and the deletion in REV-T seems necessary for expression of the transforming properties of the virus.

Establishment of infection by spleen necrosis virus: inhibition in stationary cells and the role of secondary infection

The relationship of two early events in the establishment of infection by avian retroviruses, the inhibition of viral DNA synthesis in stationary avian cells and the secondary infection which occurs after infection of replicating cells, was investigated. When neutralizing antibody to spleen necrosis virus was used to prevent secondary infection, the amount of unintegrated linear spleen necrosis virus DNA detected was much lower in infected stationary cells than in infected replicating cells. The amount of unintegrated linear spleen necrosis virus DNA in stationary cells was less than one copy per cell even at high multiplicities of infection. Viral DNA synthesis resumed after stimulation of the cells to replicate. The time of this viral DNA synthesis was closely correlated with renewed cellular DNA synthesis. In addition, blocking secondary infection of replicating cells prevented the rate of virus production from reaching the high levels usually associated with a normal productive infection by SNV. Virus production increased if secondary infection was allowed. However, this rise in virus production was not proportional to the amounts of viral DNA integrated after secondary infection.

Characterization of reticuloendotheliosis virus strain T DNA and isolation of a novel variant of reticuloendotheliosis virus strain T by molecular cloning

Reticuloendotheliosis virus strain T (REV-T) is a highly oncogenic avian retrovirus which causes a rapid neoplastic disease of the lymphoreticular system. Upon infection, this virus gives rise to two species of unintegrated linear viral DNA, which are 8.3 and 5.5 kilobase pairs long and represent the helper virus (REV-A) and the oncogenic component (REV-T), respectively. Restriction endonuclease cleavage maps of these two DNA components indicate that REV-T DNA has a large portion of the genome deleted with respect to REV-A DNA and a substitution about 0.8 to 1.5 kilobase pairs long that is unrelated to REV-A DNA. These additional sequences comprise the putative transforming region of REV-T (rel). A chicken spleen cell line transformed by REV-T produced virus which upon infection gives rise to three species of unintegrated linear viral DNA (8.3, 5.5, and 3,3 kilobase pairs). We isolated the proviruses of the 8.3- and 3.3-kilobase pair species from this cell line by cloning in the phage vector Charon 4A. Restriction enzyme mapping showed that the two proviral clones are proviruses of REV-A and a variant of REV-T, respectively. A subclone of the variant REV-T provirus specific for the rel sequences of REV-T was used as a hybridization probe to demonstrate that the rel sequences are different from the putative transforming sequences of Schmidt-Ruppin Rous sarcoma virus strain A, avain myelocytomatosis virus, avian myeloblastosis virus, avian erythroblastosis virus, Abelson murine leukemia virus, and Friend erythroleukemia virus. In addition, the rel-specific hybridization probe was used to identify a specific set of sequences which are present in uninfected avian DNAs digested with several restriction enzymes. The corresponding cell sequences are not arranged like rel in REV-T.

Clonal analysis of the integration and expression of endogenous avian retroviral DNA acquired by exogenous viral infection

Rous-associated virus-0 is one of several endogenous avian retroviruses that are transmitted vertically and that can be isolated from different inbred lines of chickens. These viruses, referred to here as induced-leukosis viruses bearing a subgroup E glycoprotein (ILV-E), are all closely related. Clonal populations of fibroblasts from line 15B and line 100 inbred chickens have been examined for the presence and expression of exogenously acquired ILV-E sequences. Restriction enzyme analysis of uniform populations of line 15B fibroblasts, prepared by cloning cells either before or after infection with ILV-E, indicates that viral sequences were inserted at multiple sites within the cell genome. Analysis of 49 clonal populations of line 100 fibroblasts containing between one and five copies of exogenous ILV-E sequences demonstrated that each clone was characterized by a unique set of viral DNA insertions within the cell genome. The expression of the exogenous ILV-E sequences within these fibroblast clones was examined by using reverse transcriptase activity as a measure of virus production. Some clones produced an amount of virus equivalent to that produced by an equal number of the uncloned ILV-E-infected parental fibroblasts. Other clones produced 5- to 10-fold less virus. Still other clones produced no detectable virus at all. Among nine clones derived from cells containing a single copy of the ILV-E provirus, the level of virus production differed more than 100-fold. DNA from these clones was analyzed with several different restriction endonucleases to characterize the location and arrangement of the ILV-E sequences. All nine clones consisted of cells that appeared to contain a complete provirus inserted (i) in a different site within the cellular DNA and (ii) in an orientation that was colinear with the viral genomic RNA. It was observed that several cleavage sites potentially affected by methylation were equally available for cleavage in all clones regardless of the level of viral production.

Analysis of avian myeloblastosis viral RNA and in vitro synthesis of proviral DNA

Two virus-specific RNA species of 7.5 and 7.0 kilobases have been identified in avian myeloblastosis virus (AMV) by denaturing gel electrophoresis and blot hybridization analysis, and they were found to be in a 10:1 ratio. The individual RNAs direccted the cell-free synthesis of the 76,000-dalton "gag" protein and the 180,000-dalton "gal-pol" protein, thereby demonstrating 5' sequence homology of approximately 4.9 kilobases between the two species. Synthesis of these two precursor proteins by the AMV genome indicates structural differences between AMV and other avian acute leukemia viruses. The two viral RNAs were transcribed into complete cDNA copies with AMV DNA polymerase. Linear proviruses were found to be 90--100% resistant to S1 nuclease. Analysis of single-stranded transcripts demonstrated two distinct species of 2.6 and 2.3 x 10(6) daltons, and analysis of duplexes formed from the single-stranded transcripts demonstrated species of 5.2 and 4.0 x 10(6) daltons.

Covalently closed circular DNAs of murine type C retrovirus: depressed formation in cells treated with cycloheximide early after infection

Formation of viral closed circular supercoiled DNA duplexes and production of progeny virus were both inhibited in cultured mouse cells treated with cycloheximide in the first 4 h of type C retrovirus infection. With different doses of cycloheximide to cause different degrees of inhibition, the number of viral supercoiled DNA duplexes detected in the cells at 11 h showed an apparent correlation with the amount of progeny virus produced in the 12- to 22-h period of infection. A slight accumulation of the full-genome linear duplex and an open circular duplex of viral DNA intermediate was observed in the cycloheximide-treated cells. Cycloheximide given to the cells during the time of conversion of viral DNA from linear to supercoiled duplex forms (6 to 11 h after virus inoculation) did not inhibit the conversion. These kinetic data suggest that a cycloheximide-sensitive metabolic process, probably early viral protein synthesis, is required for retrovirus replication and supercoiled viral DNA formation in the cell.

Spontaneous conversion of nontransformed avian sarcoma virus-infected rat cells to the transformed phenotype

Normal rat kidney (NRK) fibroblasts were infected with the Schmidt-Ruppin strain (SR-D) of avian sarcoma virus (ASV) and cloned 20 h after infection without selection for the transformed phenotype. Most infected clones initially exhibited the flat, nontransformed morphology that is characteristic of uninfected NRK cells. In long-term culture, however, the majority of the SR-D NRK clones began segregating typical ASV-transformed cells. Transforming ASV could be rescued by fusion with chicken embryo fibroblasts from most of the infected clones tested. Three predominantly flat, independently infected clones were further analyzed by subcloning 8 to 10 weeks after infection. Most flat progeny subclones derived at random from two of these "parental" SR-D NRK clonal lines did not yield virus upon fusion with chicken embryo fibroblasts, although a nondefective transforming ASV was repeatedly recovered from the parental clones. This observation suggested that most, but not all, daughter cells in these SR-D NRK clones lost the ASV provirus after cloning. The progeny of the third independent parental cell clone, c17, gave rise to both flat and transformed subclones that carried ASV. In this case, ASV recovery by fusion and transfection from the progeny subclones was equally efficient regardless of the transformation phenotype of the cells. The 60,000-dalton phosphoprotein product of the ASV src gene was, however, expressed at high level only in the transformed variants. The results of a Luria-Delbruck fluctuation analysis and of Newcombe's respreading test indicated that the event leading to the spontaneous conversion to the transformed state occurred at random in dividing cultures of these flat ASV NRK cells at a rate predicted for somatic mutation.

Ribonucleotides in unintegrated linear spleen necrosis virus DNA

The structure of unintegrated spleen necrosis virus DNA was characterized by using various chemical and enzymatic treatments in conjunction with denaturing gels and nucleic acid hybridization probes. Throughout the course of the viral infection, the predominant species of viral DNA was that of a linear double-stranded molecule containing ribonucleotides covalently joined to the DNA. The majority of both - and + strands were continuous. The ribonucleotide linkages appeared to be relatively short, and the base composition and distribution of the ribonucleotide linkages were heterogeneous. On the average, the - strand had fewer of the ribonucleotide linkages than did the strand. Viral DNA containing ribonucleotide linkages was infectious in DNA transfection assays. The structure of spleen necrosis virus DNA was different from that of Schmidt-Ruppin Rous sarcoma virus-D, and mixed infections demonstrated that the observed differences are a result of cis-acting functions.

Low-molecular-weight RNAs and initiation of RNA-directed DNA synthesis in avian reticuloendotheliosis virus

The small RNAs of avian reticuloendotheliosis virus (REV) were analyzed by two-dimensional polyacrylamide gel electrophoresis and compared with those of murine leukemia virus and avian sarcoma virus. Although there were some similarities among the three virus types, the patterns of small RNAs were distinct. By characterizing the small RNA which is most tightly associated with REV genome RNA and which can be labeled in limited DNA synthesis reactions, the primer for REV reverse transcription was identified as tRNAPro. This is consistent with previous reports that REV is more closely related to retroviruses of mammalian origin than to other avian viruses. In contrast, REV strong-stop complementary DNA is longer than any previously characterized strong-stop products of avian or mammalian retroviruses. The REV group may, therefore, have been derived from an as yet unidentified mammalian type C virus.

Structure of murine sarcoma virus DNA replicative intermediates synthesized in vitro

Moloney murine sarcoma virions synthesize discrete DNA products in vitro which closely resemble those found in vivo shortly after infection. These in vitro products have been isolated by electrophoresis and mapped with restriction endonucleases. In addition to the full-genome-length 6-kilobase pair linear DNA, a 5.4-kilobase pair circular DNA molecule, an incomplete linear DNA molecule, and a 600-base pair molecule were detected. The 6-kilobase pair DNA contained a 600-base pair direct terminal repeat which was missing from the circular form and was partially represented on the incomplete linear DNA molecule. The 600-base pair DNA contained sequences which were present in the 600-base pair direct repeat on the 6-kilobase pair DNA. The order of synthesis and the structure of these molecules detected in the in vitro reaction suggest that they are crucial intermediates in the formation of the final product of in vitro reverse transcription. A model which accounts for the synthesis of all of these molecules during the initial stages of viral replication is suggested.

Molecular cloning of infectious integrated murine leukemia virus DNA from infected mouse cells

The lack of an endonuclease EcoRI site in the AKR murine leukemia virus (MuLV) DNA genome was utilized to molecularly clone, in Charon 4A lambda DNA, integrated infectious AKR MuLV DNA isolated from productively infected mouse cells. Three lambda-mouse recombinants (clones 614, 621, and 623) were selected by virtue of their reactivity with AKR MuLV [32P]cDNA. Clones 614 and 623 contained the complete AKR MuLV DNA flanked by nonviral cell sequences of which no more than 100 base pairs beyond the viral DNA appear to be shared. DNAs from both clones 614 and 623 were highly infectious for mouse cells and yielded N-tropic ecotropic MuLV; the specific infectivity of the DNA and the titer of the derived virus was more than 10-fold higher with 623. Clone 621 contained only some viral DNA and was not infectious under similar conditions.

Correlation between cell killing and massive second-round superinfection by members of some subgroups of avian leukosis virus

Avian leukosis viruses of subgroups B, D, and F are cytopathic for chicken cells, whereas viruses of subgroups A, C, and E are not. The amounts of unintegrated linear viral DNA in cells at different times after infection with cytopathic or noncytopathic viruses were determined by hybridization and transfection assays. Shortly after infection, there is a transient accumulation of unintegrated linear viral DNA in cells infected with cytopathic avian leukosis viruses. By 10 days after infection, the majority of this unintegrated viral DNA is not present in the infected cells. The transient cytopathic effect seen in these infected cells also disappears by this time. Low amounts of unintegrated linear viral DNA persist in these cells. Cells infected with noncytopathic viruses do not show this transient accumulation of unintegrated viral DNA. Cells infected with cytopathic viruses and subsequently grown in the presence of neutralizing antibody do not show the transient accumulation of unintegrated viral DNA or cytopathic effects. These results demonstrate a correlation between envelope subgroup, transient accumulation of unintegrated linear viral DNA, and transient cell killing by avian leukosis viruses. The cell killing appears to be the result of massive second-round superinfection by the cytopathic avian leukosis viruses.

The transforming gene of Moloney murine sarcoma virus

A cleavage map of the Moloney murine sarcoma viral DNA was constructed and compared with that of a spontaneously occurring deletion mutant. By restriction enzyme analysis, it was shown that a region encompassing over 40% of the viral information was not essential for transformation or rescue of the deletion mutant. The transforming region was further localised by analysis of the transforming activity in tissue culture of isolated restriction fragments of linear duoble-stranded sarcoma viral DNA. In each case, DNA fragments that retained transforming activity preserved the cell-derived insertion sequences of the viral genome. Moreover, such transformants invariably expressed RNA specific to this region. By these two approaches, it was possible to demonstrate that the transforming region of the viral genome begins very near or within the cell-derived insertion sequences. Thus, the transforming gene of this mammalian sarcoma virus originates from within the mouse cell genome.

Differences between the endogenous and exogenous DNA sequences of Rous-associated virus-O

DNA sequences related to the endogenous retrovirus of chickens, Rous-associated virus-O (RAV-O), have been examined using site-specific DNA endonuclease analysis of cellular DNA derived from line 15 and line 100 chickens. Individual embryos from both inbred lines were used as a source of embryonic fibroblasts from which cellular DNA was isolated. Analysis of DNA containing either endogenous RAV-O sequences alone or both endogenous and exogenous RAV-O sequences produced identical patterns of RAV-O-specific DNA fragments after digestion with the endonucleases Eco RI, Hind III, BgI II, Bam HI or Xho I. Similar analysis with endonucleases Hinc II or Hha I, however, produced several RAV-O-specific DNA fragments which were derived from cellular DNA containing both endogenous and exogenous RAV-O sequences but not from cellular DNA containing only endogenous sequences. Although some differences exist between the DNA fragments specific for the endogenous viral sequences of line 15 and line 100 cellular DNA, the DNA fragments specific for the exogenous viral sequences were identical between the two inbred lines. Cleavage of an unintegrated linear RAV-O DNA molecule with Hinc II or Hha I produced DNA fragments identical to those specific for the exogenously acquired RAV-O provirus. This suggests that these characteristic fragments contain no cellular DNA. The potential DNA junction fragments containing both viral and cellular DNA, identified after analysis of DNA that contains both endogenous and exogenous viral sequences, were identical to those observed after analysis of DNA containing only endogenous viral sequences. These results support the following conclusions. First, exogenous proviral sequences are integrated into chicken cell DNA following an interaction between viral and cellular DNA that is specific with respect to the virus and nonspecific with respect to the cell. Second, both the free linear RAV-O DNA intermediate and the newly integrated exogenous provirus contain specific endonuclease sites that are not found in endogenous RAV-O DNA sequences. These results suggest that the formation of the exogenous DNA provirus involves specific alteration of the endogenous viral DNA sequences before reinsertion of the sequences as the exogenous RAV-O DNA provirus. It is possible that newly integrated exogenous RAV-O sequences are characterized by specific differences in the pattern of base methylation and a limited sequence arrangement.

Physical map of biologically active Harvey sarcoma virus unintegrated linear DNA

BALB/c JLS V9 cells recently infected with Harvey sarcoma virus-murine leukemia virus (HSV-MuLV) complex contained unintegrated HSV linear DNA of 6.0-kilobase pair mass. The cells also contained two HSV closed circular DNA species along with MuLV-encoded linear and closed circular DNA species. HSV 6.0-kilobase pair linear DNA induced focal transformation upon transfection of NIH 3T3 mouse fibroblasts, and the biological activity of HSV DNA did not require helper MuLV functions. A physical map of restriction endonuclease cleavage sites along HSV 6.0-kilobase pair linear DNA was derived. Comparison of this map with one for Moloney MuLV DNA showed that the HSV and Moloney MuLV genomes are identical near their viral RNA 3' ends.

Molecular cloning of the Harvey sarcoma virus closed circular DNA intermediates: initial structural and biological characterization

Supercoiled Harvey sarcoma virus (Ha-SV) DNA was extracted from newly infected cells by the Hirt procedure, enriched by preparative agarose gel electrophoresis, and digested with EcoRI, which cleaved the viral DNA at a unique site. The linearized Ha-SV DNA was then inserted into lambda gtWESlambda B at the EcoRI site and cloned in an approved EK2 host. Ha-SV DNA inserts from six independently derived recombinant clones have been analyzed by restriction endonuclease digestion, molecular hybridization, electron microscopy, and infectivity. Four of the Ha-SV DNA inserts were identical, contained about 6.0 kilobase pairs (kbp), and comigrated in agarose gels with the infectious, unintegrated, linear Ha-SV DNA. One insert was approximately 0.65 kbp smaller (5.35 kbp) and one was approximately 0.65 kpb larger (6.65 kpb) than the 6.0 kpb inserts. R-looping with Ha-SV RNA revealed that the small (5.35 kbp) insert contained one copy of the Ha-SV RNA. Preliminary restriction endonuclease digestion of the recombinant DNAs suggested that the middle-size inserts contained a 0.65-kbp tandem duplication of sequences present only one in the small-size insert; this duplication corresponded to the 0.65-kpb terminal duplication of the unintegrated linear Ha-SV DNA. The large-size insert apparently contained a tandem triplication of these terminally located sequences. DNA of all three sized inserts induced foci in NIH 3T3 cells, and focus-forming activity could be rescued from the transformed cells by superinfection with helper virus. Infectivity followed single-hit kinetics, suggesting that the foci were induced by a single molecule.

Carcinogenic chemicals enhance mouse leukemia virus infection in contact-inhibited culture: a new simple method of screening carcinogens

Carcinogenic chemicals enhanced infection in contact-inhibited cells with mouse leukemia virus. A correlation was found between the enhancing effects and the carcinogenicities of the 40 chemicals tested. The tumor promoter 12-O-tetradecanoylphorbol-13-acetate did not enhance viral infection.

Suppression of multiplication of avian sarcoma virus by rapid spread of transformation-defective virus of the same subgroup

We have tested the hypothesis that some transformation-defective (td) viruses grow faster than the avian sarcoma viruses (ASV) from which they are derived, resulting in establishment of interference by the td virus and suppression of the ASV multiplication. Using an ASV of subgroup A (ASV-A) that does not contain td virus and an independently isolated tdASV-A, we performed separate and mixed infections to test this hypothesis. At multiplicities of 1 or less, tdASV alone grew to higher titers and more rapidly than ASV alone. In mixed infections at low multiplicities that allowed spread of progeny virus, when as little as 10% of the virus inoculum was td virus, there was an excess of td virus by 2 days after infection and a decrease in the titer of ASV relative to a control infection with no td virus. In mixed infections at high multiplicities which minimized spread of progeny virus, there was no excess of td virus and the titer of ASV was not decreased relative to the control infection with no td virus. These data support the hypothesis that we proposed and indicate that deletions in the ASV src gene may not be a high-frequency event. We also present data concerning the amounts of unintegrated viral DNA found after the separare and mixed infections. There was no simple correlation between the amounts of unintegrated viral DNA early after infection and the titers of virus produced, indicating perhaps that virus production was determined by integrated viral DNA.