Involvement of directly repeated sequences in the generation of deletions of the avian sarcoma virus src gene

Retroviral vectors for analysis of viral mutagenesis and recombination

Retrovirus population diversity within infected hosts is commonly high due in part to elevated rates of replication, mutation, and recombination. This high genetic diversity often complicates the development of effective diagnostics, vaccines, and antiviral drugs. This review highlights the diverse vectors and approaches that have been used to examine mutation and recombination in retroviruses. Retroviral vectors for these purposes can broadly be divided into two categories: those that utilize reporter genes as mutation or recombination targets and those that utilize viral genes as targets of mutation or recombination. Reporter gene vectors greatly facilitate the detection, quantification, and characterization of mutants and/or recombinants, but may not fully recapitulate the patterns of mutagenesis or recombination observed in native viral gene sequences. In contrast, the detection of mutations or recombination events directly in viral genes is more biologically relevant but also typically more challenging and inefficient. We will highlight the advantages and disadvantages of the various vectors and approaches used as well as propose ways in which they could be improved.

Nuclear trafficking of retroviral RNAs and Gag proteins during late steps of replication

Retroviruses exploit nuclear trafficking machinery at several distinct stages in their replication cycles. In this review, we will focus primarily on nucleocytoplasmic trafficking events that occur after the completion of reverse transcription and proviral integration. First, we will discuss nuclear export of unspliced viral RNA transcripts, which serves two essential roles: as the mRNA template for the translation of viral structural proteins and as the genome for encapsidation into virions. These full-length viral RNAs must overcome the cell's quality control measures to leave the nucleus by co-opting host factors or encoding viral proteins to mediate nuclear export of unspliced viral RNAs. Next, we will summarize the most recent findings on the mechanisms of Gag nuclear trafficking and discuss potential roles for nuclear localization of Gag proteins in retrovirus replication.

Mechanisms and factors that influence high frequency retroviral recombination

With constantly changing environmental selection pressures, retroviruses rely upon recombination to reassort polymorphisms in their genomes and increase genetic diversity, which improves the chances for the survival of their population. Recombination occurs during DNA synthesis, whereby reverse transcriptase undergoes template switching events between the two copackaged RNAs, resulting in a viral recombinant with portions of the genetic information from each parental RNA. This review summarizes our current understanding of the factors and mechanisms influencing retroviral recombination, fidelity of the recombination process, and evaluates the subsequent viral diversity and fitness of the progeny recombinant. Specifically, the high mutation rates and high recombination frequencies of HIV-1 will be analyzed for their roles in influencing HIV-1 global diversity, as well as HIV-1 diagnosis, drug treatment, and vaccine development.

Truncated forms of human and simian immunodeficiency virus in infected individuals and rhesus macaques are unique or rare quasispecies

Truncated proviruses of variable sizes are present in peripheral blood mononuclear cells (PBMC) of human immunodeficiency virus type 1 (HIV-1)-infected persons and simian immunodeficiency virus (SIV)-infected rhesus macaques. Here, we investigated whether the highly deleted HIV and SIV proviruses are present in infected organisms as multiple copies or whether each truncated provirus is unique. Using end-point dilution, multiple long-distance (LD) DNA PCR assays were run in parallel using DNA extracted from PBMC of seropositive, treatment-naive persons and from lymph nodes of a rhesus monkey inoculated with cloned, full-length SIVmac239 DNA. The PCR products were titrated and mapped. Most truncated proviruses were present in the DNA samples tested as single, nonintegrated molecules that differed from one another in size and/or nucleotide sequence. These results indicate that truncated primate lentiviral sequences found in infected tissues are unique or rare quasispecies that do not replicate significantly.

A novel hybrid open reading frame formed by multiple cellular gene transductions by a plant long terminal repeat retroelement

The discovery that vertebrate retroviruses could transduce cellular sequences was central to cancer etiology and research. Although not well documented, transduction of cellular sequences by retroelements has been suggested to modify cellular functions. The maize Bs1 transposon was the first non-vertebrate retroelement reported to have transduced a portion of a cellular gene (c-pma). We show that Bs1 has, in addition, transduced portions of at least two more maize cellular genes, namely for 1,3-beta-glucanase (c-bg) and 1,4-beta-xylan endohydrolase (c-xe). We also show that Bs1 has maintained a truncated gag domain with similarity to the magellan gypsy-like long terminal repeat retrotransposon and a region that may correspond to an env-like domain. Our findings suggest that, like oncogenic retroviruses, the three transduced gene fragments and the Bs1 gag domain encode a fusion protein that has the potential to be expressed. We suggest that transduction by retroelements may facilitate the formation of novel hybrid genes in plants.

Genomic stability of murine leukemia viruses containing insertions at the Env-3' untranslated region boundary

Retroviruses containing inserts of exogenous sequences frequently eliminate the inserted sequences upon spread in susceptible cells. We have constructed replication-competent murine leukemia virus (MLV) vectors containing internal ribosome entry site (IRES)-transgene cassettes at the env-3' untranslated region boundary in order to examine the effects of insert sequence and size on the loss of inserts during viral replication. A virus containing an insertion of 1.6 kb replicated with greatly attenuated kinetics relative to wild-type virus and lost the inserted sequences in a single infection cycle. In contrast, MLVs containing inserts of 1.15 to 1.30 kb replicated with kinetics only slightly attenuated compared to wild-type MLV and exhibited much greater stability, maintaining their genomic integrity over multiple serial infection cycles. Eventually, multiple species of deletion mutants were detected simultaneously in later infection cycles; once detected, these variants rapidly dominated the population and thereafter appeared to be maintained at a relative equilibrium. Sequence analysis of these variants identified preferred sites of recombination in the parental viruses, including both short direct repeats and inverted repeats. One instance of insert deletion through recombination with an endogenous retrovirus was also observed. When specific sequences involved in these recombination events were eliminated, deletion variants still arose with the same kinetics upon virus passage and by apparently similar mechanisms, although at different locations in the vectors. Our results suggest that while lengthened, insert-containing genomes can be maintained over multiple replication cycles, preferential deletions resulting in loss of the inserted sequences confer a strong selective advantage.

Structural determinants of murine leukemia virus reverse transcriptase that affect the frequency of template switching

Retroviral reverse transcriptases (RTs) frequently switch templates within the same RNA or between copackaged viral RNAs to generate mutations and recombination. To identify structural elements of murine leukemia virus RT important for template switching, we developed an in vivo assay in which RT template switching within direct repeats functionally reconstituted the green fluorescent protein gene. We quantified the effect of mutations in the YXDD motif, the deoxynucleoside triphosphate binding site, the thumb domain, and the RNase H domain of RT and hydroxyurea treatment on the frequencies of template switching. Hydroxyurea treatment and some mutations in RT increased the frequency of RT template switching up to fivefold, while all of the mutations tested in the RNase H domain decreased the frequency of template switching by twofold. Based on these results, we propose a dynamic copy choice model in which both the rate of DNA polymerization and the rate of RNA degradation influence the frequency of RT template switching.

Development of murine leukemia virus-based self-activating vectors that efficiently delete the selectable drug resistance gene during reverse transcription

Expression of the selectable drug resistance gene in retroviral vectors used for gene therapy can lead to a decreased expression of the gene of interest and may induce a host immune response, resulting in a decreased efficiency of gene therapy. In this study, we demonstrate that high-frequency deletion of direct repeats, an inherent property of reverse transcriptases, can be used to efficiently excise the drug resistance gene during reverse transcription. One retroviral vector containing a direct repeat deleted the neomycin resistance expression cassette during a single replication cycle at >99% efficiency.

Effect of distance between homologous sequences and 3' homology on the frequency of retroviral reverse transcriptase template switching

Deletion of direct repeats in retroviral genomes provides an in vivo system for analysis of reverse transcriptase (RT) template switching. The effect of distance between direct repeats on the rate of deletion was determined for 16 murine leukemia virus (MLV)-based vectors containing a 701-bp direct repeat of overlapping fragments of the herpes simplex virus thymidine kinase gene (HTK). The direct repeats were separated by spacer fragments of various lengths (0.1 to 3.5 kb). Southern analysis of infected cells after one replication cycle indicated that all vectors in which the distance between homologous sequences was >1,500 bp deleted at very high rates (>90%). In contrast, vectors containing <1,500 bp between homologous sequences exhibited lower frequencies of deletion (37 to 82%). To analyze the pattern of locations at which RT switched templates, restriction site markers were introduced to divide the downstream direct repeat into five regions. RT switched templates within all five regions of the 701-bp direct repeat and the frequency of template switching was greater within the 5' regions in comparison to the 3' regions. The probability of RT switching templates within the 5' regions doubled when the MLV packaging sequence (Psi) was placed between the 701-bp direct repeats. However, Psi did not increase the rate of template switching for shorter direct repeats. These results indicate that linear distance between homologous sequences increases the rate of template switching and suggest that duplex formation between nascent DNA and homologous template sequences 3' of RT promote template switching.

Relative rates of retroviral reverse transcriptase template switching during RNA- and DNA-dependent DNA synthesis

Retroviral reverse transcriptases (RTs) frequently switch templates during DNA synthesis, which can result in mutations and recombination. The relative rates of in vivo RT template switching during RNA- and DNA-dependent DNA synthesis are unknown. To determine the relative rates of RT template switching during copying of RNA and DNA templates, we constructed spleen necrosis virus-based retroviral vectors containing a 400-bp direct repeat. The directly repeated sequences were upstream of the polypurine tract (PPT) in the RB-LLP vector; the same direct repeats flanked the PPT and attachment site (att) in the RB-LPL vector. RT template switching events could occur during either RNA- or DNA-dependent DNA synthesis and delete one copy of the direct repeat plus the intervening sequences. RB-LLP vectors that underwent direct repeat deletions during RNA- and DNA-dependent DNA synthesis generated viral DNA that could integrate into the host genome. However, any deletion of the direct repeats in the RB-LPL vector that occurred during RNA-dependent DNA synthesis resulted in deletion of the essential PPT and att site and generated a dead-end viral DNA product. Thus, only RB-LPL vectors that underwent direct repeat deletions during DNA-dependent DNA synthesis could integrate to form proviruses. The RB-LLP and RB-LPL vectors were permitted to undergo a single replication cycle, and the frequencies of direct repeat deletions were determined by PCR and Southern analysis of the resulting proviruses. A comparison of the frequency of direct repeat deletions in the RB-LLP and RB-LPL vectors indicated that the in vivo rates of RT template switching during RNA- and DNA-dependent DNA synthesis are nearly identical.

An array of novel murine spleen focus-forming viruses that activate the erythropoietin receptor

The Friend spleen focus-forming virus (SFFV) env gene encodes a 409-amino-acid glycoprotein with an apparent Mr of 55,000 (gp55) that binds to erythropoietin receptors (EpoR) to stimulate erythroblastosis. We reported previously the in vivo selection during serial passages in mice of several evolutionary intermediates that culminated in the formation of a novel SFFV (M. E. Hoatlin, E. Gomez-Lucia, F. Lilly, J. H. Beckstead, and D. Kabat, J. Virol. 72:3602-3609, 1998). A mouse injected with a retroviral vector in the presence of a nonpathogenic helper virus developed long-latency erythroblastosis, and subsequent viral passages resulted in more pathogenic isolates. The viruses taken from these mice converted an erythropoietin-dependent cell line (BaF3/EpoR) into factor-independent derivatives. Western blot analysis of cell extracts with an antiserum that broadly reacts with murine retroviral envelope glycoproteins suggested that the spleen from the initial mouse with mild erythoblastosis contained an array of viral components that were capable of activating EpoR. DNA sequence analysis of the viral genomes cloned from different factor-independent cell clones revealed env genes with open reading frames encoding 644, 449, and 187 amino acids. All three env genes contained 3' regions identical to that of SFFV, including a 6-bp duplication and a single-base insertion that have been shown previously to be critical for pathogenesis. However, the three env gene sequences did not contain any polytropic sequences and were divergent in their 5' regions, suggesting that they had originated by recombination and partial deletions of endogenously inherited MuLV env sequences. These results suggest that the requirements for EpoR activation by SFFV-related viruses are dependent on sequences at the 3' end of the env gene and not on the polytropic regions or on the 585-base deletions that are common among the classical strains of SFFV. Moreover, sequence analysis of the different recombinants and deletion mutants revealed that short direct and indirect repeat sequences frequently flanked the deletions that had occurred, suggesting a reverse transcriptase template jumping mechanism for this rapid retroviral diversification.

Homologous recombination occurs in a distinct retroviral subpopulation and exhibits high negative interference

Homologous recombination and deletions occur during retroviral replication when reverse transcriptase switches templates. While recombination occurs solely by intermolecular template switching (between copackaged RNAs), deletions can occur by an intermolecular or an intramolecular template switch (within the same RNA). To directly compare the rates of intramolecular and intermolecular template switching, two spleen necrosis virus-based vectors were constructed. Each vector contained a 110-bp direct repeat that was previously shown to delete at a high rate. The 110-bp direct repeat was flanked by two different sets of restriction site markers. These vectors were used to form heterozygotic virions containing RNAs of each parental vector, from which recombinant viruses were generated. By analyses of the markers flanking the direct repeats in recombinant and nonrecombinant proviruses, the rates of intramolecular and intermolecular template switching were determined. The results of these analyses indicate that intramolecular template switching is much more efficient than intermolecular template switching and that direct repeat deletions occur primarily through intramolecular template switching events. These studies also indicate that retroviral recombination occurs within a distinct viral subpopulation and exhibits high negative interference, whereby the selection of one recombination event increases the probability that a second recombination event will be observed.

Long terminal repeat U3 length polymorphism of human foamy virus

Size determination of the long terminal repeat (LTR) of an early (1985) and a more recent (1993) passage of wild-type human foamy virus (HFV) revealed that the virus has undergone substantial deletions in the U3 region upon replication in tissue culture. Two LTR deletion variants (HSRV1 and 2) have been characterized in the past and used to construct molecular clones which are replication competent in cell culture. We now report the molecular cloning, sequencing, and biological characterization of an HFV genome with full-length LTR (pHFV2). Sequence analysis revealed that the deletions in HSRV1 and 2 are nonrandom and probably occurred by misalignment during reverse transcription. The comparative analysis of HFV2 and the variant with the largest U3 deletion, HSRV2, revealed a differential ability to replicate in human cell cultures. While HSRV2 replicated faster in diploid human fibroblasts, cells which have been used extensively for amplification of HFV in the past, replication of HFV2 was faster in a lymphoblastoid cell line. Reporter gene assays indicated that the cell-type specific ability of the LTRs to respond to the viral transcriptional transactivator may be a likely, reason for the different growth properties of both viruses and for the occurrence of the HFV U3 deletions. In foamy virus-infected chimpanzees only the full-length type of LTR was observed; however, the HSRV1 deletion variant was detected as the dominating virus in an accidentally HFV-infected human.

Accumulation of defective viral genomes in peripheral blood mononuclear cells of human immunodeficiency virus type 1-infected individuals

Human immunodeficiency virus type 1 (HIV-1) genomes present in peripheral blood mononuclear cells (PBMCs) of infected persons or in lymphocytes infected in vitro were studied by long-distance PCR (LD-PCR) using primers localized in the HIV-1 long terminal repeats. The full-length 9-kb DNA was the only LD-PCR product obtained in peripheral and cord blood lymphocytes from seronegative donors infected in vitro. However, a high proportion (27% to 66%) of distinct populations of extensively deleted HIV-1 genomes of variable size was detected in PBMCs of 15 of 16 HIV-1-infected persons. Physical mapping of defective genomes showed that the frequency of deletions is proportional to their proximity to the central part of HIV-1 genome, which is consistent with a deletion mechanism involving a single polymerase jump during reverse transcription. Sequencing of deletion junctions revealed the presence of short direct repeats of three or four nucleotides. The number of defective HIV-1 genomes decreased after in vitro activation of PBMCs. Persistence of full-length and deleted genomes in in vitro activated PBMCs correlated with isolation of an infectious virus. Our results represent the first quantitative assessment of intragenomic rearrangements in HIV-1 genomes in PBMCs of infected persons and demonstrate that, in contrast to in vitro infection, defective genomes accumulate in PBMCs of infected persons.

Selection and characterization of replication-competent revertants of a Rous sarcoma virus src gene oversplicing mutant

All retroviruses require both unspliced and spliced RNA for a productive infection. One mechanism by which Rous sarcoma virus achieves incomplete splicing involves suboptimal env and src 3' splice sites. We have previously shown that mutagenesis of the nonconsensus src polypyrimidine tract to a 14-nucleotide uninterrupted polypyrimidine tract results in an oversplicing phenotype and a concomitant defective replication in permissive chicken embryo fibroblasts. In this report, we show that splicing at the src 3' splice site (3'ss) is further negatively regulated by the suppressor of src splicing cis element which is located approximately 100 nucleotides upstream of the src 3'ss. The increase in splicing at the src 3'ss results in a corresponding increase in splicing at a cryptic 5'ss within the env gene. Two classes of replication-competent revertants of the src oversplicing mutant (pSAP1) were produced after infection, and these mutants were characterized by molecular cloning and sequence analysis. Class I revertants are transformation-defective revertants in which the src 3'ss and the src gene are deleted by homologous recombination at several different sites within the imperfect direct repeat sequences that flank the src gene. Cells infected with these transformation-defective revertants produce lower levels of virus particles than cells infected with the wild-type virus. Class II revertants bear small deletions in the region containing the branchpoint sequence or polypyrimidine tract of the src 3'ss. Insertion of these mutated sequences into pSAP1 restored inefficient splicing at the src 3'ss and efficient replication in chicken embryo fibroblasts. All of these mutations caused reduced splicing at the src 3'ss when they were tested in an in vitro splicing system. These results indicate that maintenance of a weak src 3'ss is necessary for efficient Rous sarcoma virus replication.

Genetic rearrangements occurring during a single cycle of murine leukemia virus vector replication: characterization and implications

Retroviruses evolve at rapid rates, which is presumably advantageous for responding to selective pressures. Understanding the basic mutational processes involved during retroviral replication is important for comprehending the ability of retroviruses to escape immunosurveillance and antiviral drug treatment. Moreover, since retroviral vectors are important vehicles for somatic cell gene therapy, knowledge of the mechanism of retroviral variation is critical for anticipating untoward mutational events occurring during retrovirus-medicated gene transfer. The focus of this report is to examine the spectrum of genomic rearrangements arising during a single cycle of Moloney murine leukemia virus (MoMLV) vector virus replication. An MoMLV vector containing the herpes simplex virus thymidine kinase (tk) gene was constructed. MoMLV vector virus was produced in packaging lines, and target cells were infected. From a total of 224 mutant proviruses analyzed, 114 had gross rearrangements readily detectable by Southern blotting. The remaining proviruses were of parental size. PCR and DNA sequence analysis of 73 of the grossly rearranged mutant proviruses indicated they resulted from deletions, combined with insertions, duplications, and complex mutations that were a result of multiple genomic alterations in the same provirus. Complex hypermutations distinct from those previously described for spleen necrosis virus and human immunodeficiency virus were detected. There was a correlation between the mutation breakpoints and single-stranded regions in the predicted viral RNA secondary structure. The results also confirmed that the tk gene is inactivated at an average rate of about 8.8% per cycle of retroviral replication, which corresponds to a rate of mutation of 3%/kbp.

E- vectors: development of novel self-inactivating and self-activating retroviral vectors for safer gene therapy

We have developed novel self-inactivating and self-activating retroviral vectors based on the previously observed high-frequency deletion of direct repeats. We constructed spleen necrosis virus (SNV)-based viral vectors that contained large direct repeats flanking the viral encapsidation sequence (E). A large proportion of the proviruses in the target cells had E and one copy of the direct repeat deleted. Direct repeats of 1,333 and 788 bp were deleted at frequencies of 93 and 85%, respectively. To achieve a 100% deletion efficiency in target cells after ex vivo infection and drug selection, we constructed a self-activating vector that simultaneously deleted E and reconstituted the neomycin phosphotransferase gene. Selection of the target cells for resistance to G418 (a neomycin analog) ensured that all integrated proviruses had E deleted. The proviruses with E deleted were mobilized by a replication-competent virus 267,000-fold less efficiently than proviruses with E. We named these self-inactivating vectors E- (E-minus) vectors. These vectors should increase the safety of retroviral vector-mediated gene therapy by preventing the spread of vector sequences to nontarget cells in the event of coinfection with helper virus. We propose that direct-repeat deletions occur during RNA-dependent DNA synthesis and suggest that template switches occur without a requirement for RNA breaks. The minimum template dissociation frequency was estimated as 8%/100 bp per replication cycle. These vectors demonstrate that large direct repeats and template-switching properties of reverse transcriptase can be utilized to delete any sequence or reconstitute genes during retroviral replication.

Long terminal repeat enhancer core sequences in proviruses adjacent to c-myc in T-cell lymphomas induced by a murine retrovirus

The transcriptional enhancer in the long terminal repeat (LTR) of the T-lymphomagenic retrovirus SL3-3 differs from that of the nonleukemogenic virus Akv at several sites, including a single base pair difference in an element termed the enhancer core. Mutation of this T-A base pair to the C-G C-G sequence found in Akv significantly attenuated the leukemogenicity of SL3-3. Thus, this difference is important for viral leukemogenicity. Since Akv is an endogenous virus, this suggests that the C-G in its core is an adaptation to being minimally pathogenic. Most tumors that occurred in mice inoculated with the mutant virus, called SAA, contained proviruses with reversion or potential suppressor mutations in the enhancer core. We also found that the 72-bp tandem repeats constituting the viral enhancer could vary in number. Most tumors contained mixtures of proviruses with various numbers of 72-bp units, usually between one and four. Variation in repeat number was most likely due to recombination events involving template misalignment during viral replication. Thus, two processes during viral replication, misincorporation and recombination, combined to alter LTR enhancer structure and generate more pathogenic variants from the mutant virus. In SAA-induced tumors, enhancers of proviruses adjacent to c-myc had the largest number of core reversion or suppressor mutations of all of the viral enhancers in those tumors. This observation was consistent with the hypothesis that one function of the LTR enhancers in leukemogenesis is to activate proto-oncogenes such as c-myc.

High rate of genetic rearrangement during replication of a Moloney murine leukemia virus-based vector

A protocol was designed to measure the forward mutation rate over an entire gene replicated as part of a Moloney murine leukemia virus-based vector. For these studies, the herpes simplex virus thymidine kinase (tk) gene under the control of the spleen necrosis virus U3 promoter was used as target sequence since it allows selection for either the functional or the inactivated gene. Our results indicate that after one round of retroviral replication, the tk gene is inactivated at an average rate of 0.08 per cycle of replication. Southern blotting revealed that the majority of the mutant proviruses resulted from gross rearrangements and that deletions of spleen necrosis virus and tk sequences were the most frequent cause of the gene inactivation. Sequence analysis of the mutant proviruses suggested that homologous as well as nonhomologous recombination was involved in the observed rearrangements. Some mutations consisted of simple deletions, and others consisted of deletions combined with insertions. The frequency at which these mutations occurred during one cycle of retroviral replication provides evidence indicating that Moloney murine leukemia virus-based vectors may undergo genetic rearrangement at high rates. The high rate of rearrangement and its relevance for retrovirus-mediated gene transfer are discussed.

Small deletion in v-src SH3 domain of a transformation defective mutant of Rous sarcoma virus restores wild type transforming properties

RSV mutant virus PA101T was obtained while assaying the tumorigenicity of parental PA101 virus in chickens. PA101 is a transformation defective mutant of RSV which has a low src kinase activity. However, PA101 retained a temperature-sensitive ability to induce sustained proliferation of neuroretina cells. PA101T appeared as a wild-type phenotype revertant of PA101. Molecular cloning and sequencing of PA101T showed that this reversion is due to additional mutations in PA101 src gene. These mutations are a deletion eliminating three amino acids in the N-terminal region of SH3 domain and mutation of Ala 426 to Val. Analysis of the properties of chimeric src genes associating either half of PA101T with the complementary regions of PA101 or wild-type virus showed that the N-terminal moiety of PA101T src, which contains the deletion, confers wild-type transforming properties, whereas its C-terminal moiety, which contains single amino acid mutation, confers a partially temperature-sensitive phenotype. These results are consistent with other reports showing that mutations or deletions in this region of SH3 activate the transforming potential of c-src. They support the hypothesis that the N-terminal region of SH3 interacts with a cellular negative regulator of src activity.

Rearrangements in unintegrated retroviral DNA are complex and are the result of multiple genetic determinants

We used a replication-competent retrovirus shuttle vector based on a DNA clone of the Schmidt-Ruppin A strain of Rous sarcoma virus to characterize rearrangements in circular viral DNA. In this system, circular molecules of viral DNA present after acute infection of cultured cells were cloned as plasmids directly into bacteria. The use of a replication-competent shuttle vector permitted convenient isolation of a large number of viral DNA clones; in this study, over 1,000 clones were analyzed. The circular DNA molecules could be placed into a limited number of categories. Approximately one-third of the rescued molecules had deletions in which one boundary was very near the edge of a long terminal repeat (LTR) unit. Subtle differences in the patterns of deletions in circular DNAs with one versus two copies of the LTR sequence were observed, and differences between deletions emanating from the right and left boundaries of the LTR were seen. A virus with a missense mutation in the region of the pol gene responsible for integration and exhibiting a temperature sensitivity phenotype for replication had a marked decrease in the number of rescued molecules with LTR-associated deletions when infection was performed at the nonpermissive temperature. This result suggests that determinants in the pol gene, possibly in the integration protein, play a role in the generation of LTR-associated deletions. Sequences in a second region of the genome, probably within the viral gag gene, were also found to affect the types of circular viral DNA molecules present after infection. Sequences in this region from different strains of avian sarcoma-leukosis viruses influenced the fraction of circular molecules with LTR-associated deletions, as well as the relative proportion of circular molecules with either one or two copies of the LTR. Thus, the profile of rearrangements in unintegrated viral DNA is complex and dependent upon the nature of sequences in the gag and pol regions.

Transformation-defective mutants with 5' deletions of the src gene are frequently generated during replication of Rous sarcoma virus in established quail fibroblasts

Replication of Rous sarcoma virus (RSV) in avian fibroblasts leads to the generation of replication-competent variants that are defective for cell transformation (td virus). These td variants contain deletions affecting various portions of the v-src gene. We compared the rate of td virus production in Q3B cells, a quail cell line established by mutagen treatment, and in normal quail fibroblasts. Twenty-five days after infection with an RSV stock containing only transforming virions, Q3B cells harbor similar amounts of v-src-containing and v-src-deleted proviruses. However, these cells synthesize very low levels of p60v-src and generate large excess of td variants, as determined by biological assays. Unlike Q3B cells, normal quail fibroblasts infected with the same virus stock produce td variants only after multiple passages of undiluted virus on fresh cells. Restriction analysis showed that the td virus produced by Q3B cells is composed of two types of genomes: one lacking the entire v-src gene and the other carrying partial deletions of this gene predominantly located in the amino-terminal portion of the coding region of v-src. To study the mechanisms of these partial deletions, we molecularly cloned and sequenced the v-src genes of several td proviruses. We show that these mutants carry single or multiple v-src deletions of limited size, presumably generated by multiple mechanisms. Two deletions of 170 and 112 bp located in the 5' portion of v-src are frequently generated during RSV replication in Q3B cells and may represent preferential sites for v-src deletion in these cells.

Duck hepatitis B virus can tolerate insertion, deletion, and partial frameshift mutation in the distal pre-S region

In-frame and frameshift mutations were introduced into the pre-S region (1,212 base pairs) of duck hepatitis B virus. The in-frame mutants retained the inserted 12 nucleotides, while the frameshift mutants either reverted to wild type or exhibited a 10-nucleotide compensatory deletion downstream of the original mutation site. Thus, although duck hepatitis B virus has a compact and highly economical genome organization, it can replicate despite alterations of up to 9 amino acid codons in the pre-S and P open reading frames.

Specific sequence deletions in two classes of murine leukemia virus-related proviruses in the mouse genome

Characteristic long terminal repeats (LTR) of approximately 700 and 750 bp were found, respectively, in the two classes (polytropic and modified polytropic) of murine leukemia virus (MuLV)-related nonecotropic nonxenotropic proviral sequences in eight individual molecular clones of RFM/Un mouse chromosomal DNA fragments. Three proviral clones, two polytropic and one modified polytropic, contained sequence deletions in the viral structural genes. Nucleotide sequence analysis revealed that 7-bp direct repeats occur at both ends of deleted sequences in intact structures and one of the repeats remains in genomes with the deletion. Specifically, the deleted sequences were a 1487-bp gag-pol sequence with ACTGCCC repeat, a 113-bp mid-pol sequence with CAGGCAA repeat, and a 1811-bp env sequence with GGTCCAG repeat. The same specific sequence deletions were found in both classes of MuLV-related proviral structures. Examination of chromosomal DNA from eight inbred laboratory mouse strains and six wild mouse species showed that a minor population of proviruses with these specific deletions were present in Mus musculus and Mus spretus, all of which contain prominent 700-bp LTR polytropic proviral structures. The 750-bp LTR modified polytropic proviral structures were phylogenetically more restricted, being equally predominant in Mus musculus domesticus mice, but minor to undetectable in Mus spretus subspecies, and absent in other wild mouse populations.

Identification of putative endogenous proviral templates for progenitor mink cell focus-forming (MCF) MuLV-related RNAs

Murine leukemia virus (MuLV)-related RNAs exhibiting different env deletions are believed to participate in the generation of leukemogenic mink cell focus-forming (MCF) viruses. We have cloned an endogenous MuLV provirus from AKR/J mouse DNA, designated as A-2, which may serve as template for the env-deleted E2 MuLV RNA, expressed in GIX+ mice (D.E. Levy et al., J. Virol. 56, 691-700 (1985]. We have also isolated an endogenous MCF-related DNA, A-1, which shared close sequence homology with the 7.2-kb RNA expressed in AKR mice (F. Laigret et al., J. Virol. 62, 376-386 (1988] and sustained an identical env deletion. The data indicate that putative precursor MCF-related RNAs are transcribed from a heterogenous family of env-deleted endogenous MuLV DNAs.

An enhancer sequence instability that diversifies the cell repertoire for expression of a murine leukemia virus

Studies of recombinants between murine leukemia viruses (MuLVs) that cause thymic or erythroid leukemias have shown that enhancer sequences in the long-terminal repeats (LTRs) can determine the target tissues for pathogenesis. It has been inferred that the enhancers may specifically target viral expression into the cells that then become neoplastic. However, the neoplasms in those studies formed after latencies and contained ultimate viruses (called MCFs) that differed from the injected viruses in their enhancer sequences and envelope (env) genes. Transcriptional activities of LTRs from these proximal and ultimate viruses have not been thoroughly analyzed in different hematopoietic lineages. We present evidence that the enhancer of Friend spleen focus-forming virus (SFFV), an ultimate erythroleukemogenic retrovirus, contains an unstable 42-nucleotide direct repeat. Other ultimate erythroleukemogenic MuLVs (Friend MCFs) contain an enhancer nearly identical to that of SFFV both in its sequence and in its specific instability. The instability occurs in sequences that contain inverted repeats and we propose that it occurs by a simple reverse transcriptase hop mechanism. We constructed plasmids that contain the two forms of the SFFV LTR linked to the bacterial chloramphenicol acetyltransferase (CAT) gene, and we compared these in transient transfection assays with LTR-CAT plasmids constructed from Friend and Moloney MuLVs. The assays employed erythroleukemia cells, thymic lymphoma cells, and fibroblasts. The tropisms of expression correlated only weakly with tissue specificities of pathogenesis and each LTR was active in all cells. The SFFV 42-nucleotide duplication reduced expression in erythroid cells and increased expression in fibroblasts. We conclude that retroviral enhancers do not stringently direct gene expression into specific cell lineages, but on the contrary they are leaky and contain replicative instabilities that also may facilitate viral entrenchment throughout the host. These results have important implications for understanding murine retroviral evolution and the multi-step process of leukemogenesis.

Avian sarcoma viruses

Twelve independent isolates of avian sarcoma viruses (ASVs) can be divided into four groups according to the transforming genes harbored in the viral genomes. The first group is represented by viruses containing the transforming sequence, src, inserted in the viral genome as an independent gene; the other three groups of viruses contain transforming genes fps, yes or ros fused to various length of the truncated structural gene gag. These transforming sequences have been obtained by avian retroviruses from chicken cellular DNA by recombination. The src-containing viruses code for an independent polypeptide, p60src; and the representative fps, yes and ros-containing ASVs code for P140/130gag-fps, P90gag-yes and P68gag-ros fusion polypeptides respectively. All of these transforming proteins are associated with the tyrosine-specific protein kinase activity capable of autophosphorylation and phosphorylating certain foreign substrates. p60src and P68gag-ros are integral cellular membrane proteins and P140/130gag-fps and P90gag-yes are only loosely associated with the plasma membrane. Cells transformed by ASVs contain many newly phosphorylated proteins and in most cases have an elevated level of total phosphotyrosine. However, no definitive correlation between phosphorylation of a particular substrate and transformation has been established except that a marked increase of the tyrosine phosphorylation of a 34,000 to 37,000 dalton protein is observed in most ASV transformed cells. The kinase activity of ASV transforming proteins appears to be essential, but not sufficient for transformation. The N-terminal domain of p60src required for myristylation and membrane binding is also crucial for transformation. By contrast, the gag portion of the FSV P130gag-fps is dispensable for in vitro transformation and removal of it has only an attenuating effect on in vivo tumorigenicity. The products of cellular src, fps and yes proto-oncogenes have been identified and shown to also have tyrosine-specific protein kinase activity. The transforming potential of c-src and c-fps has been studied and shown that certain structural changes are necessary to convert them into transforming genes. Among the cellular proto-oncogenes related to the four ASV transforming genes, c-ros most likely codes for a growth factor receptor-like molecule. It is possible that the oncogene products of ASVs act through certain membrane receptor(s) or enzyme(s), such as protein kinase C, in the process of cell transformation.

Potential progenitor sequences of mink cell focus-forming (MCF) murine leukemia viruses: ecotropic, xenotropic, and MCF-related viral RNAs are detected concurrently in thymus tissues of AKR mice

Leukemogenic mink cell focus-forming (MCF) viruses of AKR mice are believed to originate in thymic tissue via recombination between ecotropic, xenotropiclike, and endogenous MCF-related murine leukemia virus (MuLV) sequences. We have previously used a synthetic 16-base-pair MCF env-specific oligomer probe to identify subgenomic MCF-related mRNAs present in the thymus tissues of AKR mice prior to the appearance of full-length (8.4-kilobase [kb]) recombinant MCF viral RNAs (A. S. Khan, F. Laigret, and C. P. Rodi, J. Virol. 61:876-882, 1987). These potential MCF env precursors consisted of 7.2-, 3.0-, and 1.8-kb RNA species. In this study, we have determined the structure of the MCF-related mRNAs on the basis of Northern (RNA) blot hybridization analyses by using 10 different MuLV subgenomic DNA probes, determined the nucleotide sequence of a cloned cDNA segment representing the 3' portion of the 7.2-kb mRNA, and studied the expression of ecotropic and xenotropic MuLV sequences by using env-specific DNA probes. The results indicated that ecotropic, xenotropic, and MCF-related transcripts were constitutively and concurrently expressed exclusively in thymus tissue of 2-month-old AKR mice prior to detection of MCF viral RNAs. We have molecularly characterized these thymic MuLV RNAs, which may participate in formation of recombinant MCF viruses; a novel recombinant ecotropic viral RNA was identified as a putative intermediate in the stepwise generation of leukemogenic MCF MuLVs. We have also described the unique structure of the 6.0-kb MCF-related RNAs which were expressed specifically in liver and kidney tissues of AKR mice; these RNAs contained an upstream non-MuLV transcriptional regulatory element.

The mechanism of transduction of proto-oncogene c-src by avian retroviruses

Chicken c-src sequences have been transduced by avian leukosis viruses (ALV) and by partial src-deletion (td) mutants of Rous sarcoma virus in several independent events. Analyses of the recombination junctions in the genomes of src-containing viruses and the c-src DNA have shed light on the mechanism of transduction, which involves at least two steps of recombination. The initial recombination between a viral genome and the 5' region of c-src appears to occur at the DNA level. This step does not require extensive homology and can be mediated by stretches of sequences with only partial homology. The 5' recombination junction can also be formed by splicing between viral and c-src sequences. The second recombination is presumed to occur between the transducing ALV or td viral RNA and the viral-c-src hybrid RNA molecule generated from the initial recombination. This step involving recombination at the 3' ends of those molecules restores the 3' viral sequences essential for replication to the viral-c-src hybrid molecule. High frequency of c-src transduction by partial td mutants suggests that the second recombination is greatly enhanced when there is sequence homology between the transducing virus and the 3' region of c-src. Incorporation of the c-src sequences into an ALV genome results in greatly elevated expression of the gene. However, increased expression of c-src alone is insufficient to activate its transforming potential. Structural changes in c-src are necessary to convert it into a transforming gene. The changes can be as small as single nucleotide changes resulting in single amino aid substitutions at certain positions. Mutations can occur rapidly during viral replication after c-src is incorporated into the viral genome. Therefore, it is most likely that transduction of c-src by ALV is followed by subsequent mutation and selection for the sarcomagenic virus. In the case of transduction by td viruses that retain certain src sequences, joining of these sequences with the transduced c-src apparently is sufficient to activate its transforming potential.

Instability of large direct repeats in retrovirus vectors

Retrovirus vectors were constructed with large (0.85- to 1.3-kilobase-pair) direct repeats in their genomes. Deletions involving the direct repeats occurred at a high frequency. Deletions occurred both when the direct repeats were in tandem and when they were separated by additional sequences. These deletions occurred during virus replication.

Age-related RNA polymerase I activity in isolated nuclei of PHA stimulated human lymphocytes

In order to extend to the immune system previous findings that there is an age-related loss of hybridizability of the genes for ribosomal RNA (rRNA) in several tissues of mice, dogs and humans, we have investigated the function of the genes for rRNA in human T lymphocytes. These cells were chosen because they show a substantial decline in function with age, greater than that of other components of the immune system. rRNA synthesis was determined by measuring tritiated-UTP incorporation into acid precipitable counts as a result of the action of RNA polymerase I in nuclei isolated from phytohemagglutinin (PHA) stimulated peripheral-blood lymphocytes from 24 young adult and old human donors. The number of PHA-responsive cells from each donor was determined by counting grains in autoradiographs after a pulse of tritiated-uridine had been administered to them. The aggregate PHA induced synthesis of rRNA in the cultures decreased as a function of the age of the donor. However, the number of PHA-responsive cells also dropped with age. When the data are normalized for the number of PHA-responsive cells in each culture, it appears that rRNA synthesis per PHA-responding cell does not significantly decline with age, even though there is a suggestion of a decrease after corrections are made. On the average, differences between individuals of the same age group were as great or greater than age-related differences.

Nucleotide sequence comparison of the 3' regions of avian retroviruses NY203 and NTRE-2

We have been characterizing molecular clones of two subgroup E avian retroviruses (NTRE-2 and NY203RAV-60) that produce different proliferative diseases after inoculation into susceptable K28 chickens. Both viruses arose by recombination between exogenous and endogenous viral genomes. To further characterize regions of these viruses that are important for the production of disease, we have determined the nucleotide sequence of a 1.2-kb EcoRI fragment extending from the carboxyl end of gp85 through 150 bases of the U3 region of the LTR. From the sequence data it is possible to precisely define one point where recombination occurred between PrRSV-B and RAV-0 to produce NTRE-2. We suggest a hypothesis, based on the core enhancer consensus sequence, for the higher incidence of disease when chickens are infected with viruses bearing the LTR of NY203RAV-60.

Partial nucleotide sequence of Rous sarcoma virus-29 provides evidence that the original Rous sarcoma virus was replication defective

Rous sarcoma virus-29 (RSV-29) is the strain of RSV that has the least number of passages beyond its isolation from chicken tumor no. 1 among all current strains of RSV. Biological characterization indicated that it was replication defective. RNA analysis of nonproducer clones of RSV-29-infected chicken embryonic fibroblasts showed the presence of a subgenomic message of 2.6 kilobases containing src and a genomic RNA of 7.7 kilobases that contains gag, pol, and src, but not env. The src-containing EcoRI fragment of RSV-29 proviral DNA was molecularly cloned. Sequence analysis of the regions flanking src revealed that the env gene was completely deleted in RSV-29 and that the sequence across the deletion was exactly the same as the Bryan high-titer strain of RSV. The sequence immediately 3' to src in RSV-29 was closely related to that of the Prague strain of RSV. The fact that the strain of RSV which has the minimal number of passages beyond its isolation is replication defective supports the hypothesis of Lerner and Hanafusa (J. Virol. 49:549-556, 1984) that the original RSV is a defective transforming virus. This defective transforming virus is postulated to be the precursor to other defective RSVs like the Bryan high-titer strain and to nondefective RSVs like the Prague strain. The particular clone of RSV-29 that we studied also had a short stretch of sequence duplication at the 3' end of the pol gene, which was presumably created by an error of reverse transcription.

Unusual features of the leader sequence of Rous sarcoma virus packaging mutant TK15

TK15, a mutant derived from a temperature-sensitive mutant of Rous sarcoma virus (tsNY68), has extremely low infectivity although it has intact viral genes. Biological and biochemical analyses of the virus and virus-induced transformants showed that the mutant has a defect in the packaging of its own genomic RNA possibly owing to a deletion near the 5' end (S. Kawai and T. Koyama, J. Virol. 51:147-153, 1984; T. Koyama, F. Harada, and S. Kawai, J. Virol. 51:154-162, 1984). Nucleotide sequence analysis of the provirus DNA of the mutant revealed that the deletion extends from the 3' end of the primer binding site to 22 bases upstream of the gag initiation codon and also suggested that possible binding between an extra region of the primer molecule and the viral genome resulting from the deletion causes another defect in the replication of the TK15 genome. It was suggested that the deletion of 237 bases in TK15 was generated during reverse transcription of the genome by the skipping of a sequence between identical 13-base sequences present in the primer binding site and 35 to 22 bases upstream of the gag initiation codon of the parental virus.

Evolutionary variants of Rous sarcoma virus: large deletion mutants do not result from homologous recombination

Large deletion (LD) mutants of Prague strain Rous sarcoma virus, subgroup B (PrB), derived by serial undiluted passage through chicken (C/E) cells, were isolated and characterized. Individual LD viruses were initially isolated by cloning in soft agar of infected, chemically transformed quail (QT6) cells. Two regions of the PrB genome were deleted in the formation of the LD virus. This resulted in the junction of gag sequences in p12 to env sequences in gp37, and in the loss of the src gene. DNA restriction analysis of biologically active lambda Charon 27-LD recombinant clones indicated that individual LD viruses contained similar but not identical deletion endpoints. Two LD isolates, LD25 and LD85, were further subcloned into pBR322, and the deletion junctions were examined by DNA sequencing. Although the gag-env deletion endpoints were identical in the two subclones, heterogeneity was observed across the src deletion in that both mutants analyzed had the same 5' endpoint but slightly different 3' endpoints. In all cases, only a single homologous base (always an A residue) was found at the deletion endpoint. S1 nuclease analysis of the RNA from a number of QT6-LD clones gave similar results, indicating that the LD population was composed of viruses with similar but not identical deletion endpoints. Such viruses may have been generated from errors during reverse transcription of the virion RNA with subsequent selection assuring their dominance in the population.

The Gv-1 locus coordinately regulates the expression of multiple endogenous murine retroviruses

The analysis of the normal expression of endogenous retroviral sequences in congenic 129 GIX+ and GIX- mouse strains suggests the action of a regulatory element, encoded by Gv-1, functioning in trans to control the expression of these sequences. At steady state, the abundance of polyadenylated retroviral transcripts of different length cosegregates with the Gv-1 genotype. The presence of low but detectable quantities of these transcripts in antigen-negative mice indicates however, that Gv-1 may be distinct from the structural genes encoding retroviral proteins. We report here that retroviral transcripts, derived from distinct proviruses, are expressed in a tissue-specific manner and are coordinately regulated by the Gv-1 locus. The structure of several of the abundant transcripts demonstrates further that they are transcribed from independent defective endogenous proviral genomes exhibiting extensive deletions of env coding regions as well as modified U3 regions distinct from those found in exogenous retroviral transcripts.

Mechanisms for the generation of src-deletion mutants and recovered sarcoma viruses: identification of viral sequences involved in src deletions and in recombination with c-src sequences

The precise src deletions in six transformation-defective (td) deletion mutants derived from the Schmidt-Ruppin strain of Rous sarcoma virus were determined by sequence analysis. Examination of the parental viral sequences neighboring the junctions of deletions in these td mutants revealed that these regions contained either directly repeated or inverted complementary sequences ranging from 9 to 28 nucleotides. Five td mutants were found to contain deletions flanked by directly repeated sequences, of which the 3' direct repeat was retained whereas the 5' direct repeat was deleted in the resulting td viral RNA. In the deletions of two td mutants where inverted complementary sequences were present at junctions of the deletions, both copies of the inverted complementary sequence were deleted in the td viral RNA. It is proposed from these observations that deletions of these mutants have been generated during the synthesis of minus-strand viral DNA by reverse transcriptase by jumping over a sequence flanked by direct repeats or by skipping a stem-and-loop structure formed via inverted complementary sequences on the viral RNA template. Data provide further information on the sequences in the td viral genome that are required for the generation of recovered sarcoma viruses (rASVs) by recombination with c-src. Sequence data of td viruses revealed that retaining as few as 82 nucleotides of the 3' src coding sequence is sufficient, whereas retaining as much as one-third of the 5' src but none of the 3' src coding sequences is not sufficient, for the generation of rASVs. Those that generate replication-competent rASVs retain, in addition to the 3' src region, a portion of the 5' src and/or its immediate upstream sequence that is homologous to exon 1 of the c-src DNA. These two sequence domains apparently provided 5' and 3' homologous regions for recombination between td viral genome and c-src DNA resulting in nondefective rASVs. Td109, which was shown previously to generate only replication-defective rASVs, retains 296 nucleotides of the 3' src sequence but lacks all the 5' src and 316 nucleotides of its immediate upstream region. It is concluded that the 5' src coding sequence and its immediate upstream region are not essential for the generation of rASVs. However, retaining a portion of those sequences is required for the generation of replication-competent rASVs.

Simian virus 40 illegitimate recombination occurs near short direct repeats

We have analysed nucleotide sequences at the junction between simian virus 40 (SV40) and cellular DNA in the Fisher rat transformed line tsA30-N2. This line contains a single insertion of one complete SV40 genome with a terminal duplication of 267 nucleotides, the recombination sites being located at nucleotides 439 and 705 in the late region of SV40. These two positions are located within short direct repeats in the virus genome. In order to test the significance of such repeats with respect to illegitimate recombination events, we analysed two series of published sequences of SV40 recombination sites: the first one consists of eight SV40 insertion endpoints derived from four SV40-transformed cell lines; the second one consists of 18 junction points from SV40 evolutionary variants. Our analysis demonstrates that in both cases, recombination preferentially takes place near short direct repeats in the virus genome. A model involving a "slipped mispairing" mechanism is proposed in order to account for this finding.

Induction of tumors and generation of recovered sarcoma viruses by, and mapping of deletions in, two molecularly cloned src deletion mutants

td108 , a transformation-defective (td) deletion mutant of the Schmidt-Ruppin strain of Rous sarcoma virus of subgroup A (SR-A), was molecularly cloned. Two isolates of td viruses, td108 -3b and td108 -4a, obtained by transfection of the molecularly cloned td108 DNAs into chicken embryo fibroblasts, were tested for their ability to induce tumors and generate recovered avian sarcoma viruses ( rASVs ) in chickens. Both td viruses were able to induce tumors with a latency and frequency similar to those observed previously with biologically purified td mutants of SR-A. rASVs were isolated from most of the tumors examined. The genomic RNAs of those newly obtained rASVs were analyzed by RNase T1 oligonucleotide fingerprinting. The results showed that they had regained the deleted src sequences and contained the same set of marker src oligonucleotides as those of rASVs analyzed previously. The src oligonucleotides of rASVs are distinguishable from those present in SR-A. We conclude that those rASVs must have been generated by recombination between the molecularly cloned td mutants and the c-src sequence. The deletions in the td mutants were mapped by restriction enzyme analysis and nucleotide sequencing. td108 -3b was found to contain an internal src deletion of 1,416 nucleotides and to retain 57 and 105 nucleotides of the 5' and 3' src coding sequences, respectively. td108 -4a contained a src deletion of 1,174 nucleotides and retained 180 and 225 nucleotides of the 5' and 3' src sequences, respectively. Comparison of sequences in the 5' src and its upstream region of td108 -3b with those of SR-A, rASV1441 (a td108 -derived rASV analyzed previously), and c-src suggested that the 5' recombination between td108 and c-src occurred from 7 to 20 nucleotides upstream from the beginning of the src coding sequence.

The avian sarcoma virus PRCII lacks 1020 nucleotides of the fps transforming gene

Fujinami sarcoma virus (FSV) and PRCII avian sarcoma virus both encode gag-fps transforming proteins associated with tyrosine-specific protein kinase activity; however, PRCII has a lower oncogenic potential than does FSV. In this study, the genomes of PRCII and FSV have been compared. By hybridization of PRCII [32P]RNA to FSV DNA on Southern blots, a large internal deletion in the 5' half of the fps gene in PRCII has been mapped. To determine the exact size and location of the deletion in PRCII, dideoxy sequencing of PRCII RNA with FSV DNA fragments as primers was used. The FSV sequence corresponding to the deletion in PRCII was flanked by 6-base direct repeats ( AGCTGG ) at 1614-1619 and 2634-2639 nucleotides. One copy of the direct repeat was retained in the PRCII genome. The length of the deleted region was 1020 nucleotides. The deletion in fps did not alter the kinase domain or ATP-binding site of the P105 transforming protein of PRCII. It was shown that the specific kinase activity of P105 was as high as that of FSV P130 . The sequence deleted from PRCII was found to encode part of a large hydrophilic domain. In the accompanying paper [J. Woolford and K. Beemon (1984) Virology 135, 168-180], evidence that the PRCII and FSV proteins have different subcellular locations and solubility properties, possibly due to the loss of this domain, is presented. These alterations in the structure and location of the PRCII protein may prevent it from phosphorylating certain substrates involved in oncogenic transformation.

High-frequency deletion in recovered retrovirus vectors containing exogenous DNA with promoters

We previously described infectious retrovirus vectors constructed from spleen necrosis virus which contain the herpes simplex virus thymidine kinase gene and the mouse alpha-globin gene (K. Shimotohno and H. M. Temin, Nature [London] 299:255-268, 1982). In the present study we report that when TK- chicken cells infected with a virus containing the mouse alpha-globin promoter and other 5' noncoding sequences in addition to the alpha-globin coding sequences were selected for thymidine kinase (TK) activity, all virus-producing TK+ cell clones shed virus with a deletion. These deletions were of different sizes and included the mouse alpha-globin coding sequences and the mouse alpha-globin transcriptional promoter. One of the deleted viruses was molecularly cloned. DNA sequencing showed that the deleted sequences are flanked by a short direct repeat. This deleted virus was also shown to have an advantage over the nondeleted parent both in multiplication and in its specific TK-transforming unit titer. In contrast to the results described above, TK+ cell clones established with viruses that contained only the coding sequences from the mouse alpha-globin gene did not delete and were stable over many cell passages. The implications of the high-frequency deletion of the viruses with internal promoters are discussed in terms of the evolution of retroviruses and the construction of retrovirus vectors.

Replication origins and a sequence involved in coordinate induction of the immediate-early gene family are conserved in an intergenic region of herpes simplex virus

We have determined the structure of the 5' portion of herpes simplex virus type 2 (HSF-2) immediate-early (IE) mRNA-3 and have obtained the DNA sequence specifying the N terminus of its encoded polypeptide, Vmw182, its untranslated leader and the intergenic region between IEmRNAs-3 & 4/5. Comparison of the HSV-2 intergenic sequences with the HSV-1 equivalent region identifies several conserved regions: (1) an AT-rich element with core consensus TAATGARAT which is likely to be the 'activator' sequence through which coordinate induction of the IE gene family is mediated. (2) GC-rich and GA-rich tracts, found in a wide variety of eukaryotic promoters, which vary in position and orientation between HSV-2 and HSV-1 and which represent modulators of transcription. (3) TATA homologies present 15-25 base pairs (bp) upstream of mRNA 5' termini. (4) a 137bp direct repeat in HSV-2 which contains sequence almost identical to the HSV-1 replication origin.

cis-Acting RNA packaging locus in the 115-nucleotide direct repeat of Rous sarcoma virus

The v-src gene of Schmidt-Ruppin strain A of Rous sarcoma virus is flanked by a 115-nucleotide direct repeat. Mutants that lack either the upstream or downstream copy replicate normally. However, mutants that lack both copies do not replicate. Cloned viral DNA lacking both copies of the 115-nucleotide sequence is capable of directing the transcription of viral RNA posttransfection. This viral RNA is polyadenylated, spliced, exported from the nucleus, and translated into protein normally. However, virions isolated from the culture medium 48 h posttransfection lack viral RNA. When mutant DNA is contransfected with wild-type DNA, the virions produced 48 h later contain wild-type RNA but not mutant RNA, even though both RNAs are present in the cytoplasm. We propose that the 115-nucleotide element of Rous sarcoma-avian leukosis virus encodes a cis-acting sequence that is necessary for the proper incorporation of viral RNA into virions.