Retroviral splicing suppressor requires three nonconsensus uridines in a 5' splice site-like sequence.

Rous sarcoma virus RNA contains a negative regulator of splicing (NRS) element that aids in maintenance of unspliced RNA. The NRS binds U1 snRNA at a sequence that deviates from the 5' splice site consensus by substitution of U's for A's at three positions: -2, +3, and +4. All three of these U's are important for NRS-mediated splicing suppression. Substitution of a single nonconsensus C or G at any of these sites diminished NRS activity, whereas substitution of a single A generated a preferred 5' splice site within the NRS.

Rous sarcoma virus DR posttranscriptional elements use a novel RNA export pathway.

Rous sarcoma virus (RSV), a simple retrovirus, needs to export unspliced viral RNA from the nucleus to the cytoplasm, circumventing the host cell restriction on cytoplasmic expression of intron-containing RNA. The cytoplasmic accumulation of full-length viral RNA is promoted by two cis-acting direct repeat (DR) elements that flank the src gene; at least one copy of the DR sequence is necessary for viral replication. We show here that the DR mediates export of a reporter construct from the nucleus, suggesting it is a constitutive transport element (CTE). In contrast, human immunodeficiency virus type 1 (HIV-1) and other complex retroviruses encode accessory proteins, Rev or Rex, which promote export of incompletely spliced viral transcripts. This RNA export pathway is CRM1 dependent and can be blocked by the cytotoxic agent leptomycin B. We show here that DR-mediated export is CRM1 independent, suggesting that RSV uses a different export pathway from that of HIV-1 and other complex retroviruses. The simian retroviruses have a CTE which interacts with the cellular Tap export protein. However, we were unable to detect binding of the RSV DR RNA to Tap, suggesting it may use a different export pathway from that of the simian retroviruses. These data suggest that the RSV DR element uses a novel nucleocytoplasmic export pathway.

The role of overlapping U1 and U11 5' splice site sequences in a negative regulator of splicing.

Splicing of Rous sarcoma virus RNA is regulated in part by a cis-acting intronic RNA element called the negative regulator of splicing (NRS). An NRS mutant affecting nt 916-923 disrupts U11 snRNP binding and reduces NRS activity (Gontarek et al., 1993, Genes & Dev 7:1926-1936). However, we observed that a U15' splice site-like sequence, which overlapped the U11 site, was also disrupted by this mutation. To determine whether the U1 or the U11 site was essential for NRS activity, we analyzed twelve additional mutants involving nt 915-926. All mutations that disrupted the potential base pairing between U1 snRNA and the NRS reduced NRS activity, including single point mutations at nt 915, 916, and 919. The point mutation at nt 919 was partially suppressed by a compensatory base change mutation in U1 snRNA. In contrast, a mutation which strengthened the potential base pairing between the U1 site and the NRS increased NRS activity. Surprisingly, mutations that specifically targeted the U115' splice site consensus sequence increased the levels of unspliced RNA, suggesting U11 binding plays an antagonistic role to NRS activity. We propose that U1 snRNP binding to the NRS inhibits splicing and is regulated by U11 snRNP binding to the overlapping sequence. Competition between U1 and U11 snRNPs would result in the appropriate balance of spliced to unspliced RNAs for optimal viral replication. Further, a virus mutated in the U1/U11 region of the NRS was found to have delayed replication.

Mutational analysis of the rous sarcoma virus DR posttranscriptional control element.

The direct repeat (DR) sequences flanking the src gene in Rous sarcoma virus are essential posttranscriptional control elements; at least one copy of this sequence is necessary for cytoplasmic accumulation of unspliced viral RNA. These sequences promote Rev-independent human immunodeficiency virus type 1 expression, suggesting they act as constitutive transport elements (CTEs). To determine which regions of this sequence are critical for CTE function, mutations in the downstream DR were generated and tested in a viral deletion construct lacking src and the upstream DR. Two single-point mutations and three different clustered mutations caused substantial reductions in reverse transcriptase activity, Gag protein levels, and unspliced viral RNA in the cytoplasm. Three conserved regions of the CTE, including nucleotides 8844 to 8847, 8862 to 8864, and 8868 to 8870, were most sensitive to inactivation by mutagenesis.

Minimal truncation of the c-myb gene product in rapid-onset B-cell lymphoma.

Oncogenic activation of c-myb by insertional mutagenesis has been implicated in rapid-onset B-cell lymphomas induced by the nonacute avian leukosis virus EU-8. In these tumors, proviruses are integrated either upstream of the c-myb coding region or within the first intron of c-myb. Tumors with either type of integration contained identical chimeric mRNAs in which the viral 5' splice site was juxtaposed to the 3' splice site of c-myb exon 2 and myb exon 1 was eliminated. Both classes of integrations generated truncated Myb proteins that were indistinguishable by Western analysis. In contrast to most other examples of c-myb activation, the truncation consisted of only 20 N-terminal amino acids and did not disrupt either the DNA binding domain near the N terminus or the negative regulatory domain near the C terminus of Myb. The significance of the 20-amino-acid Myb truncation to tumorigenesis was tested by infection of chicken embryos with retroviral vectors expressing different myb gene products. While virus expressing either wild-type c-myb or c-myb mutated at the N-terminal casein kinase II sites was only weakly oncogenic at 10 weeks, the minimally truncated myb virus induced a high incidence of rapid-onset tumors, including B-cell lymphomas, sarcomas, and adenocarcinomas.

Genetic determinant of rapid-onset B-cell lymphoma by avian leukosis virus.

Infection of 10 day-old chicken embryos with the recombinant avian leukosis virus (ALV) EU-8 induces a high incidence of rapid-onset B-cell lymphoma by insertional activation of the c-myb gene. LR-9, a related ALV with differences from EU-8 in the gag and pol genes, induces rapid-onset lymphoma at only a low incidence. To localize the viral determinant(s) responsible for this biologic difference, we constructed and tested a series of reciprocal chimeras between EU-8 and LR-9 ALVs. The ability to induce rapid-onset lymphoma efficiently was localized to a 925-nucleotide (nt) region of the EU-8 gag gene. Sequence analysis of the region revealed a 42-nt deletion in EU-8 relative to LR-9, as well as some single-nucleotide changes. A mutant virus, delta LR-9, constructed by deleting these 42 nt from LR-9, also induced rapid-onset lymphoma at a high frequency, confirming the biologic significance of this deletion. This deletion removed nt 735 to 776, which lies within a cis-acting RNA element that negatively regulates splicing (NRS). The deletion was shown to cause an increase in splicing efficiency, which may lead to increased production of a truncated myb gene product from an ALV-myb readthrough RNA.

Rapid induction of B-cell lymphomas by avian leukosis virus.

Avian leukosis viruses (ALVs) that induce rapid B-cell lymphomas integrate into the c-myb gene and produce an ALV-myb read-through RNA, which is spliced to produce a truncated Myb protein. The genetic determinants of such recombinant ALVs have been mapped to a 42-nt deletion within the gag gene. This deletion increases splicing efficiency since it is located within a negative regulator of splicing. We propose that the deletion leads to increased production of Myb protein by increasing splicing of an ALV-myb pre-mRNA.

Avian retroviral RNA element promotes unspliced RNA accumulation in the cytoplasm.

All retroviruses need mechanisms for nucleocytoplasmic export of their unspliced RNA and for maintenance of this RNA in the cytoplasm, where it is either translated to produce Gag and Pol proteins or packaged into viral particles. The complex retroviruses encode Rev or Rex regulatory proteins, which interact with cis-acting viral sequences to promote cytoplasmic expression of incompletely spliced viral RNAs. Since the simple retroviruses do not encode regulatory proteins, we proposed that they might contain cis-acting sequences that could interact with cellular Rev-like proteins. To test this possibility, we initially looked for a cis-acting sequence in avian retroviruses that could substitute for Rev and the Rev response element in human immunodeficiency virus type 1 expression constructs. A cis-acting element in the 3' untranslated region of Rous sarcoma virus (RSV) RNA was found to promote Rev-independent expression of human immunodeficiency virus type 1 Gag proteins. This element was mapped between RSV nucleotides 8770 and 8925 and includes one copy of the direct repeat (DR) sequences flanking the RSV src gene; similar activity was observed for the upstream DR. To address the function of this element in RSV, both copies of the DR sequence were deleted. Subsequently, each DR sequence was inserted separately back into this deleted construct. While the viral construct lacking both DR sequences failed to replicate, constructs containing either the upstream or downstream DR replicated well. In the absence of both DRs, Gag protein levels were severely diminished and cytoplasmic levels of unspliced viral RNA were significantly reduced; replacement of either DR sequence led to normal levels of Gag protein and cytoplasmic unspliced RNA.

Two strong 5' splice sites and competing, suboptimal 3' splice sites involved in alternative splicing of human immunodeficiency virus type 1 RNA.

The human immunodeficiency virus type 1 (HIV-1) genome contains 20 exons that are alternatively spliced from 16 splice sites to generate more than 40 different mRNAs, including incompletely spliced and unspliced mRNAs. In contrast to avian retroviral RNA, which has a cis-acting element in gag that negatively regulates splicing (NRS), HIV-1 RNA did not have any NRS sequences in the gag or pol genes detectable by a splicing inhibition assay. However, this assay demonstrated that the HIV-1 first 5' splice site competed with a cellular 5' splice site, suggesting that HIV-1 may have some strong splice sites. To extend this observation, we used a splice site swapping strategy to determine the efficiency of 14 HIV-1 splice sites in human beta globin chimeras tested in transient transfection experiments. While the 1st HIV-1 5' splice site used in all spliced transcripts and the 4th 5' splice site used in most of the 2-kb transcripts were efficient, the other splice sites, including all the 3' splice sites, were less efficient, ranging in use from 25 to 60%. We propose that this range of splice site efficiencies contributes to the regulation of alternative splicing of HIV-1 mRNAs.

Rous sarcoma virus RNA stability requires an open reading frame in the gag gene and sequences downstream of the gag-pol junction.

The intracellular accumulation of the unspliced RNA of Rous sarcoma virus was decreased when translation was prematurely terminated by the introduction of nonsense codons within its 5' proximal gene, the gag gene. Subcellular fractionation of transfected cells suggested that nonsense codon-mediated instability occurred in the cytoplasm. Analysis of constructs containing an in-frame deletion in the nucleocapsid domain of gag, which prevents interaction between the Gag protein and viral RNA, showed that an open reading frame extending to approximately 30 nucleotides from the natural gag termination codon was needed for RNA stability. Sequences at the gag-pol junction necessary for ribosomal frameshifting were not required for RNA stability; however, sequences located 100 to 200 nucleotides downstream of the natural gag termination codon were found to be necessary for stable RNA. The stability of RNAs lacking this downstream sequence was not markedly affected by premature termination codons. We propose that this downstream RNA sequence may interact with ribosomes translating gag to stabilize the RNA.

Mutation of an RSV intronic element abolishes both U11/U12 snRNP binding and negative regulation of splicing.

A cis-acting negative regulator of splicing (NRS) within the gag gene of RSV is involved in control of the relative levels of spliced and unspliced viral mRNAs. Insertion of the NRS into the intron of an adenovirus pre-mRNA resulted in inhibition of splicing in vitro before the first cleavage step. Analyses of spliceosome assembly with this substrate showed that it formed large RNP complexes that did not migrate like mature spliceosomes on native gels. Affinity selection of the RNP complexes formed on NRS-containing pre-mRNAs showed an association with U11 and U12 snRNPs, as well as with the spliceosomal snRNPs. Immunoprecipitation with antisera specific for U1 and U2 snRNPS showed binding of both snRNPs to NRS RNA. A 7-nucleotide missense mutation in the NRS that prevented binding of U11 and U12 snRNPs impaired NRS activity in vivo, suggesting a functional role for U11 and U12 snRNPs in the inhibition of splicing mediated by the RSV NRS RNA.

Mutation of the C/EBP binding sites in the Rous sarcoma virus long terminal repeat and gag enhancers.

Several C/EBP binding sites within the Rous sarcoma virus (RSV) long terminal repeat (LTR) and gag enhancers were mutated, and the effect of these mutations on viral gene expression was assessed. Minimal site-specific mutations in each of three adjacent C/EBP binding sites in the LTR reduced steady-state viral RNA levels. Double mutation of the two 5' proximal LTR binding sites resulted in production of 30% of wild-type levels of virus. DNase I footprinting analysis of mutant DNAs indicated that the mutations blocked C/EBP binding at the affected sites. Additional C/EBP binding sites were identified upstream of the 3' LTR and within the 5' end of the LTRs. Point mutations in the RSV gag intragenic enhancer region, which blocked binding of C/EBP at two of three adjacent C/EBP sites, also reduced virus production significantly. Nuclear extracts prepared from both chicken embryo fibroblasts (CEFs) and chicken muscle contained proteins binding to the same RSV DNA sites as did C/EBP, and mutations that prevented C/EBP binding also blocked binding of these chicken proteins. It appears that CEFs and chicken muscle contain distinct proteins binding to these RSV DNA sites; the CEF binding protein was heat stable, as is C/EBP, while the chicken muscle protein was heat sensitive.

Intronic sequences and 3' splice sites control Rous sarcoma virus RNA splicing.

cis-acting sequences of Rous sarcoma virus (RSV) RNA involved in control of the incomplete splicing that is part of the retroviral life cycle have been studied. The 5' and two alternative 3' splice sites, as well as negative regulator of splicing element in the intron, have been introduced into chimeric constructs, and their responsive roles in splicing inhibition have been evaluated by transient transfection experiments. Although the RSV 5' splice site was used efficiently in these assays, substrates containing either the RSV env or the RSV src 3' splice site were not spliced completely, resulting in 40 to 50% unspliced RNA. Addition of the negative regulator of splicing element to substrates containing RSV 3' splice sites resulted in greater inhibition of splicing (70 to 80% unspliced RNA), suggesting that the two elements function independently and additively. Deletion of sequences more than 70 nucleotides upstream of the src 3' splice site resulted in efficient splicing at this site, suggesting that inefficient usage is not inherent in this splice site but is instead due to to sequences upstream of it. Insertion of these upstream sequences into the intron of a heterologous pre-mRNA resulted in partial inhibition of its splicing. In addition, secondary structure interactions were predicted to occur between the src 3' splice site and the inhibitory sequences upstream of it. Thus, RSV splicing control involves both intronic sequences and 3' splice sites, with different mechanisms involved in the underutilization of the env and src splice acceptor sites.

Characterization of Rous sarcoma virus intronic sequences that negatively regulate splicing.

Retroviruses splice only a fraction of their primary RNA transcripts to subgenomic mRNA. The unspliced RNA is transported to the cytoplasm, where it serves as genomic RNA as well as mRNA for the gag and pol genes. Deletion of sequences from the Rous sarcoma virus gag gene, which is part of the intron of the subgenomic mRNAs, was previously observed to result in an increase in the ratio of spliced to unspliced RNA. These sequences, which we termed a negative regulator of splicing (NRS), can be moved to the intron of a heterologous gene resulting in an accumulation of unspliced RNA in the nucleus. We have used such constructs, assayed by transient expression in chicken embryo fibroblasts, to define the minimal sequences necessary to inhibit splicing. Maximal NRS activity was observed with a 300-nt fragment containing RSV nts 707-1006; two noncontiguous domains within this fragment, one of which contains a polypyrimidine tract, were both found to be essential. The NRS element was active exclusively in the sense orientation in two heterologous introns tested and in both avian and mammalian cells. Position dependence was also observed, with highest activity when the NRS was inserted in the intron near the 5' splice site. The NRS element was also active at an exon position 136 nts upstream of the 5' splice site but not at sites further upstream. In addition, it did not affect the splicing of a downstream intron.

Nonsense codons within the Rous sarcoma virus gag gene decrease the stability of unspliced viral RNA.

The intracellular accumulation of the unspliced RNA of Rous sarcoma virus was decreased when translation was prematurely terminated by the introduction of nonsense codons within its 5' proximal gene, the gag gene. In contrast, the levels of spliced viral RNAs were not affected in our transient expression assays in chicken cells. Experiments using the transcription inhibitor dactinomycin showed that mutant unspliced RNAs were degraded more rapidly than wild-type RNA. Furthermore, mutant RNAs could be partially stabilized by coexpression of wild-type gag proteins in trans; however, intact gag proteins were not required to maintain the stability of RNAs which did not contain premature termination codons. Thus, termination codons seemed to destabilize the RNA not because of their effect on gag protein function but instead because they disrupted the process of translating the gag region of the RNA. Analysis of double-mutant constructs containing both deletions and termination codons within the gag gene also suggested that the stability of the unspliced RNA was affected by a cis-acting interaction between the RNA and ribosomes.

Sequence specificity of mRNA N6-adenosine methyltransferase.

The sequence specificity of chicken mRNA N6-adenosine methyltransferase has been investigated in vivo. Localization of six new N6-methyladenosine sites on Rous sarcoma virus (RSV) virion RNA has confirmed our extended consensus sequence for methylation: RGACU, where R is usually a G (7/12). We have also observed A (2/12) and U (3/12) at the -2 position (relative to m6A at +1) but never a C. At the +3 position, the U was observed 10/12 times; an A and a C were observed once each in weakly methylated sequences. The extent of methylation varied between the different sites up to a maximum of about 90%. To test the significance of this consensus sequence, it was altered by site-specific mutagenesis, and methylation was assayed after transfection of mutated RSV DNA into chicken embryo fibroblasts. We found that changing the G at -1 or the U at +3 to any other residue inhibited methylation. However, inhibition of methylation at all four of the major sites in the RSV src gene did not detectably alter the steady-state levels of the three viral RNA species or viral infectivity. Additional mutants that inactivated the src protein kinase activity produced less virus and exhibited relatively less src mRNA in infected cells.

BK virus T antigens induce kidney carcinomas and thymoproliferative disorders in transgenic mice.

Renal adenocarcinomas and/or extremely enlarged thymuses (up to 250 times normal size) were observed in 60 of 78 mice in a transgenic line containing a single copy of the BK virus (BKV) early region. Enlarged thymuses from different mice displayed thymoproliferative disorders of varying severity, ranging from extreme hyperplasia to thymomas and lymphomas. All kidney tumor DNAs analyzed contained highly amplified BKV sequences with multiple rearrangements in cellular DNA flanking the transgene, whereas amplification and rearrangement were observed only in some enlarged thymus DNAs. Expression of BKV T antigens was restricted to epithelial cells of kidney tumors and enlarged thymuses and was not detected in any normal tissues. Although thymocytes proliferated to numbers much greater than normal in the enlarged thymuses, no T antigen expression was detected in thymocytes.

Avian retroviral long terminal repeats bind CCAAT/enhancer-binding protein.

DNA-protein interactions involving enhancer and promoter sequences within the U3 regions of several avian retroviral long terminal repeats (LTRs) were studied by DNase I footprinting. The rat CCAAT/enhancer-binding protein, C/EBP, bound to all four viral LTRs examined. The Rous sarcoma virus binding site corresponded closely to the 5' limit of the LTR enhancer; nucleotides -225 to -188 were protected as a pair of adjacent binding domains. The Fujinami sarcoma virus LTR bound C/EBP at a single site at nucleotides -213 to -195. C/EBP also bound to the promoter region of the enhancerless Rous-associated virus-0 LTR at nucleotides -77 to -57. The avian myeloblastosis virus LTR bound C/EBP at three sites: nucleotides -262 to -246, -154 to -134, and -55 to -39. We have previously observed binding of C/EBP to an enhancer in the gag gene of avian retroviruses. A heat-treated nuclear extract from chicken liver bound to all of the same retroviral sequences as did C/EBP. Alignment of the avian retroviral binding sequences with the published binding sites for C/EBP in two CCAAT boxes and in the simian virus 40, polyoma, and murine sarcoma virus enhancers suggested TTGNNGCTAATG as a consensus sequence for binding of C/EBP. When two bases of this consensus sequence were altered by site-specific mutagenesis of the Rous sarcoma virus LTR, binding of the heat-stable chicken protein was eliminated.

Proposed gag-encoded transcriptional activator is not necessary for Rous sarcoma virus replication or transformation.

It has been reported that gene expression directed by the long terminal repeat of Rous sarcoma virus (RSV) is trans activated by a protein encoded in an alternate reading frame within the RSV gag gene (S. Broome and W. Gilbert, Cell 40:537-546, 1985). We have made specific mutations to test the role of the putative transcriptional activator in RSV replication. Termination codons were created within the alternate reading frame coding for the trans activator, and the mutations were introduced into an infectious RSV plasmid. We were unable to demonstrate specific trans activation of the RSV long terminal repeat by either wild-type or mutant RSV plasmids in transient cotransfection assays. Experiments using mutant or wild-type RSV-infected chick embryo fibroblasts indicated that the proposed RSV transcriptional activator was not required for viral replication or transformation and did not increase steady-state levels of viral RNA.

Regulation of Rous sarcoma virus RNA splicing and stability.

Only a fraction of retroviral primary transcripts are spliced to subgenomic mRNAs; the unspliced transcripts are transported to the cytoplasm for packaging into virions and for translation of the gag and pol genes. We identified cis-acting sequences within the gag gene of Rous sarcoma virus (RSV) which negatively regulate splicing in vivo. Mutations were generated downstream of the splice donor (base 397) in the intron of a proviral clone of RSV. Deletion of bases 708 to 800 or 874 to 987 resulted in a large increase in the level of spliced RSV RNA relative to unspliced RSV RNA. This negative regulator of splicing (nrs) also inhibited splicing of a heterologous splice donor and acceptor pair when inserted into the intron. The nrs element did not affect the level of spliced RNA by increasing the rate of transport of the unspliced RNA to the cytoplasm but interfered more directly with splicing. To investigate the possible role of gag proteins in splicing, we studied constructs carrying frameshift mutations in the gag gene. While these mutations, which caused premature termination of gag translation, did not affect the level of spliced RSV RNA, they resulted in a large decrease in the accumulation of unspliced RNA in the cytoplasm.