A suboptimal src 3' splice site is necessary for efficient replication of Rous sarcoma virus

Encoded Conformational Dynamics of the HIV Splice Site A3 Regulatory Locus: Implications for Differential Binding of hnRNP Splicing Auxiliary Factors

Alternative splicing of the HIV transcriptome is controlled through cis regulatory elements functioning as enhancers or silencers depending on their context and the type of host RNA binding proteins they recruit. Splice site acceptor A3 (ssA3) is one of the least used acceptor sites in the HIV transcriptome and its activity determines the levels of tat mRNA. Splice acceptor 3 is regulated by a combination of cis regulatory sequences, auxiliary splicing factors, and presumably RNA structure. The mechanisms by which these multiple regulatory components coordinate to determine the frequency in which ssA3 is utilized is poorly understood. By NMR spectroscopy and phylogenetic analysis, we show that the ssA3 regulatory locus is conformationally heterogeneous and that the sequences that encompass the locus are conserved across most HIV isolates. Despite the conformational heterogeneity, the major stem loop (A3SL1) observed in vitro folds to base pair the Polypyrimdine Tract (PPyT) to the Exon Splicing Silencer 2p (ESS2p) element and to a conserved downstream linker. The 3D structure as determined by NMR spectroscopy further reveals that the A3 consensus cleavage site is embedded within a unique stereochemical environment within the apical loop, where it is surrounded by alternating base-base interactions. Despite being described as a receptor for hnRNP H, the ESS2p element is sequestered by base pairing to the 3' end of the PPyT and within this context it cannot form a stable complex with hnRNP H. By comparison, hnRNP A1 directly binds to the A3 consensus cleavage site located within the apical loop, suggesting that it can directly modulate U2AF assembly. Sequence mutations designed to destabilize the PPyT:ESS2p helix results in an increase usage of ssA3 within HIV-infected cells, consistent with the PPyT becoming more accessible for U2AF recognition. Additional mutations introduced into the downstream ESS2 element synergize with ESS2p to cause further increases in ssA3 usage. When taken together, our work provides a unifying picture by which cis regulatory sequences, splicing auxiliary factors and RNA structure cooperate to provide stringent control over ssA3. We describe this as the pair-and-lock mechanism to restrict access of the PPyT, and posit that it operates to regulate a subset of the heterogenous structures encompassing the ssA3 regulatory locus.

Evidence that a threshold of serine/arginine-rich (SR) proteins recruits CFIm to promote rous sarcoma virus mRNA 3' end formation

The weak polyadenylation site (PAS) of Rous sarcoma virus (RSV) is activated by the juxtaposition of SR protein binding sites within the spatially separate negative regulator of splicing (NRS) element and the env RNA splicing enhancer (Env enhancer), which are far upstream of the PAS. Juxtaposition occurs by formation of the NRS - 3' ss splicing regulatory complex and is thought to provide a threshold of SR proteins that facilitate long-range stimulation of the PAS. We provide evidence for the threshold model by showing that greater than three synthetic SR protein binding sites are needed to substitute for the Env enhancer, that either the NRS or Env enhancer alone promotes polyadenylation when the distance to the PAS is decreased, and that SR protein binding sites promote binding of the polyadenylation factor cleavage factor I (CFIm) to the weak PAS. These observations may be relevant for cellular PASs.

Comparative Transcriptome Analysis of Bombyx mori (Lepidoptera) Larval Midgut Response to BmNPV in Susceptible and Near-Isogenic Resistant Strains

Bombyx mori nucleopolyhedrovirus (BmNPV) is one of the primary pathogens causing severe economic losses in sericulture. However, the molecular mechanism of silkworm resistance to BmNPV remains largely unknown. Here, the recurrent parent P50 (susceptible strain) and the near-isogenic line BC9 (resistance strain) were used in a comparative transcriptome study examining the response to infection with BmNPV. A total of 14,300 unigenes were obtained from two different resistant strains; of these, 869 differentially expressed genes (DEGs) were identified after comparing the four transcriptomes. Many DEGs associated with protein metabolism, cytoskeleton, and apoptosis may be involved in the host response to BmNPV infection. Moreover, some immunity related genes were also altered following BmNPV infection. Specifically, after removing genetic background and individual immune stress response genes, 22 genes were found to be potentially involved in repressing BmNPV infection. These genes were related to transport, virus replication, intracellular innate immune, and apoptosis. Our study provided an overview of the molecular mechanism of silkworm resistance to BmNPV infection and laid a foundation for controlling BmNPV in the future.

Posttranscriptional regulation of retroviral gene expression: primary RNA transcripts play three roles as pre-mRNA, mRNA, and genomic RNA

After reverse transcription of the retroviral RNA genome and integration of the DNA provirus into the host genome, host machinery is used for viral gene expression along with viral proteins and RNA regulatory elements. Here, we discuss co-transcriptional and posttranscriptional regulation of retroviral gene expression, comparing simple and complex retroviruses. Cellular RNA polymerase II synthesizes full-length viral primary RNA transcripts that are capped and polyadenylated. All retroviruses generate a singly spliced env mRNA from this primary transcript, which encodes the viral glycoproteins. In addition, complex viral RNAs are alternatively spliced to generate accessory proteins, such as Rev, which is involved in posttranscriptional regulation of HIV-1 RNA. Importantly, the splicing of all retroviruses is incomplete; they must maintain and export a fraction of their primary RNA transcripts. This unspliced RNA functions both as the major mRNA for Gag and Pol proteins and as the packaged genomic RNA. Different retroviruses export their unspliced viral RNA from the nucleus to the cytoplasm by either Tap-dependent or Rev/CRM1-dependent routes. Translation of the unspliced mRNA involves frame-shifting or termination codon suppression so that the Gag proteins, which make up the capsid, are expressed more abundantly than the Pol proteins, which are the viral enzymes. After the viral polyproteins assemble into viral particles and bud from the cell membrane, a viral encoded protease cleaves them. Some retroviruses have evolved mechanisms to protect their unspliced RNA from decay by nonsense-mediated RNA decay and to prevent genome editing by the cellular APOBEC deaminases.

Juxtaposition of two distant, serine-arginine-rich protein-binding elements is required for optimal polyadenylation in Rous sarcoma virus

The Rous sarcoma virus (RSV) polyadenylation site (PAS) is very poorly used in vitro due to suboptimal upstream and downstream elements, and yet ∼85% of viral transcripts are polyadenylated in vivo. The mechanisms that orchestrate polyadenylation at the weak PAS are not completely understood. It was previously shown that serine-arginine (SR)-rich proteins stimulate RSV PAS use in vitro and in vivo. It has been proposed that viral RNA polyadenylation is stimulated through a nonproductive splice complex that forms between a pseudo 5' splice site (5'ss) within the negative regulator of splicing (NRS) and a downstream 3'ss, which repositions NRS-bound SR proteins closer to the viral PAS. This repositioning is thought to be important for long-distance poly(A) stimulation by the NRS. We report here that a 308-nucleotide deletion downstream of the env 3'ss decreased polyadenylation efficiency, suggesting the presence of an additional element required for optimal RSV polyadenylation. Mapping studies localized the poly(A) stimulating element to a region coincident with the Env splicing enhancer, which binds SR proteins, and inactivation of the enhancer and SR protein binding decreased polyadenylation efficiency. The positive effect of the Env enhancer on polyadenylation could be uncoupled from its role in splicing. As with the NRS, the Env enhancer also stimulated use of the viral PAS in vitro. These results suggest that a critical threshold of SR proteins, achieved by juxtaposition of SR protein binding sites within the NRS and Env enhancer, is required for long-range polyadenylation stimulation.

Structural and functional analysis of the Rous Sarcoma virus negative regulator of splicing and demonstration of its activation by the 9G8 SR protein

Retroviruses require both spliced and unspliced RNAs for replication. Accumulation of Rous Sarcoma virus (RSV) unspliced RNA depends upon the negative regulator of splicing (NRS). Its 5′-part is considered as an ESE binding SR proteins. Its 3′-part contains a decoy 5′-splice site (ss), which inhibits splicing at the bona fide 5′-ss. Only the 3D structure of a small NRS fragment had been experimentally studied. Here, by chemical and enzymatic probing, we determine the 2D structure of the entire RSV NRS. Structural analysis of other avian NRSs and comparison with all sequenced avian NRSs is in favour of a phylogenetic conservation of the NRS 2D structure. By combination of approaches: (i) in vitro and in cellulo splicing assays, (ii) footprinting assays and (iii) purification and analysis of reconstituted RNP complex, we define a small NRS element retaining splicing inhibitory property. We also demonstrate the capability of the SR protein 9G8 to increase NRS activity in vitro and in cellulo. Altogether these data bring new insights on how NRS fine tune splicing activity.

RNA processing control in avian retroviruses

Upon integration into the host chromosome, retroviral gene expression requires transcription by the host RNA polymerase II, and viral messages are subject RNA processing events including 5'-end capping, pre-mRNA splicing, and polyadenylation. At a minimum, RNA splicing is required to generate the env mRNA, but viral replication requires substantial amounts of unspliced RNA to serve as mRNA and for incorporation into progeny virions as genomic RNA. Therefore, splicing has to be controlled to preserve the large unspliced RNA pool. Considering the current view that splicing and polyadenylation are coupled, the question arises as to how genome-length viral RNA is efficiently polyadenylated in the absence of splicing. Polyadenylation of many retroviral mRNAs is inefficient; in avian retroviruses, approximately 15 percent of viral transcripts extend into and are polyadenylated at downstream host genes, which often has profound biological consequences. Retroviruses have served as important models to study RNA processing and this review summarizes a body of work using avian retroviruses that has led to the discovery of novel RNA splicing and polyadenylation control mechanisms.

A premature termination codon mutation at the C terminus of foamy virus Gag downregulates the levels of spliced pol mRNA

Foamy viruses (FV) comprise a subfamily of retroviruses. Orthoretroviruses, such as human immunodeficiency virus type 1, synthesize Gag and Pol from unspliced genomic RNA. However, FV Pol is expressed from a spliced mRNA independently of Gag. FV pol splicing uses a 3' splice site located at the 3' end of gag, resulting in a shared exon between gag and pol. Previously, our laboratory showed that C-terminal Gag premature termination codon (PTC) mutations in the 3' shared exon led to greatly decreased levels of Pol protein (C. R. Stenbak and M. L. Linial, J. Virol. 78:9423-9430, 2004). To further characterize these mutants, we quantitated the levels of unspliced gag and spliced pol mRNAs using a real-time PCR assay. In some of the PTC mutants, the levels of spliced pol mRNA were reduced as much as 30-fold, whereas levels of unspliced gag RNA were not affected. Substitutions of a missense codon in place of a PTC restored normal levels of spliced pol mRNA. Disrupting Upf proteins involved in nonsense-mediated mRNA decay (NMD) did not affect Pol protein expression. Introduction of an exonic splicing enhancer downstream of the PTC mutation restored pol splicing to the wild-type level. Taken together, our results show that the PTC mutation itself is responsible for decreased levels of pol mRNA but that mechanisms other than NMD might be involved in downregulating Pol expression. The results also suggest that normal pol splicing utilizes a suboptimal splice site seen for other spliced mRNAs in most retroviruses, in that introduced exonic enhancer elements can increase splicing efficiency.

Serine/arginine-rich proteins contribute to negative regulator of splicing element-stimulated polyadenylation in rous sarcoma virus

Rous sarcoma virus (RSV) requires large amounts of unspliced RNA for replication. Splicing and polyadenylation are coupled in the cells they infect, which raises the question of how viral RNA is efficiently polyadenylated in the absence of splicing. Optimal RSV polyadenylation requires a far-upstream splicing control element, the negative regulator of splicing (NRS), that binds SR proteins and U1/U11 snRNPs and functions as a pseudo-5' splice site that interacts with and sequesters 3' splice sites. We investigated a link between NRS-mediated splicing inhibition and efficient polyadenylation. In vitro, the NRS alone activated a model RSV polyadenylation substrate, and while the effect did not require the snRNP-binding sites or a downstream 3' splice site, SR proteins were sufficient to stimulate polyadenylation. Consistent with this, SELEX-binding sites for the SR proteins ASF/SF2, 9G8, and SRp20 were able to stimulate polyadenylation when placed upstream of the RSV poly(A) site. In vivo, however, the SELEX sites improved polyadenylation in proviral clones only when the NRS-3' splice site complex could form. Deletions that positioned the SR protein-binding sites closer to the poly(A) site eliminated the requirement for the NRS-3' splice site interaction. This indicates a novel role for SR proteins in promoting RSV polyadenylation in the context of the NRS-3' splice site complex, which is thought to bridge the long distance between the NRS and poly(A) site. The results further suggest a more general role for SR proteins in polyadenylation of cellular mRNAs.

Murine leukemia virus regulates alternative splicing through sequences upstream of the 5' splice site

Alternative splicing of the primary transcript plays a key role in retroviral gene expression. In contrast to all known mechanisms that mediate alternative splicing in retroviruses, we found that in murine leukemia virus, distinct elements located upstream of the 5' splice site either inhibited or activated splicing of the genomic RNA. Detailed analysis of the first untranslated exon showed that the primer binding site (PBS) activates splicing, whereas flanking sequences either downstream or upstream of the PBS are inhibitory. This new function of the PBS was independent of its orientation and primer binding but associated with a particular destabilizing role in a proposed secondary structure. On the contrary, all sequences surrounding the PBS that are involved in stem formation of the first exon were found to suppress splicing. Targeted mutations that destabilized the central stem and compensatory mutations of the counter strand clearly validated the concept that murine leukemia virus attenuates its 5' splice site by forming an inhibitory stem-loop in its first exon. Importantly, this mode of splice regulation was conserved in a complete proviral clone. Some of the mutants that increase splicing revealed an opposite effect on translation, implying that the first exon also regulates this process. Together, these findings suggest that sequences upstream of the 5' splice site play an important role in splice regulation of simple retroviruses, directly or indirectly attenuating the efficiency of splicing.

The retrovirus RNA trafficking granule: from birth to maturity

Post-transcriptional events in the life of an RNA including RNA processing, transport, translation and metabolism are characterized by the regulated assembly of multiple ribonucleoprotein (RNP) complexes. At each of these steps, there is the engagement and disengagement of RNA-binding proteins until the RNA reaches its final destination. For retroviral genomic RNA, the final destination is the capsid. Numerous studies have provided crucial information about these processes and serve as the basis for studies on the intracellular fate of retroviral RNA. Retroviral RNAs are like cellular mRNAs but their processing is more tightly regulated by multiple cis-acting sequences and the activities of many trans-acting proteins. This review describes the viral and cellular partners that retroviral RNA encounters during its maturation that begins in the nucleus, focusing on important events including splicing, 3' end-processing, RNA trafficking from the nucleus to the cytoplasm and finally, mechanisms that lead to its compartmentalization into progeny virions.

An exonic splicing silencer downstream of the 3' splice site A2 is required for efficient human immunodeficiency virus type 1 replication

Alternative splicing of the human immunodeficiency virus type 1 (HIV-1) genomic mRNA produces more than 40 unique viral mRNA species, of which more than half remain incompletely spliced within an HIV-1-infected cell. Regulation of splicing at HIV-1 3' splice sites (3'ss) requires suboptimal polypyrimidine tracts, and positive or negative regulation of splicing occurs through binding of cellular factors to cis-acting splicing regulatory elements. We have previously shown that splicing at HIV-1 3'ss A2, which produces vpr mRNA and promotes inclusion of HIV-1 exon 3, is repressed by the hnRNP A/B-dependent exonic splicing silencer ESSV. Here we show that ESSV activity downstream of 3'ss A2 is localized to a 16-nucleotide element within HIV-1 exon 3. HIV-1 replication was reduced by 95% when ESSV was inactivated by mutagenesis. Reduced replication was concomitant with increased inclusion of exon 3 within spliced viral mRNA and decreased accumulation of unspliced viral mRNA, resulting in decreased cell-associated p55 Gag. Prolonged culture of ESSV mutant viruses resulted in two independent second-site reversions disrupting the splice sites that define exon 3, 3'ss A2 and 5' splice site D3. Either of these changes restored both HIV-1 replication and regulated viral splicing. Therefore, inhibition of HIV-1 3'ss A2 splicing is necessary for HIV-1 replication.

Position dependence of the Rous sarcoma virus negative regulator of splicing element reflects proximity to a 5' splice site

Rous sarcoma virus (RSV) requires incomplete splicing of its viral transcripts to maintain efficient replication. A splicing inhibitor element, the negative regulator of splicing (NRS), is located near the 5' end of the RNA but the significance of this positioning is not known. In a heterologous intron the NRS functions optimally when positioned close to the authentic 5' splice site. This observation led us to investigate the basis of the position dependence. Four explanations were put forth and stressed the role of three major elements involved in splicing, the 3' splice site, the 5' splice site, and the 5' end cap structure. NRS function was unrelated to its position relative to the 3' splice site or the cap structure and appeared to depend on its position relative to the authentic 5' splice site. We conclude that position dependence may reflect distance constraints necessary for competition of the NRS with the authentic 5' splice site for pairing with the 3' splice sites.

Rous sarcoma virus negative regulator of splicing selectively suppresses SRC mRNA splicing and promotes polyadenylation

Retroviruses require a balance of spliced and unspliced RNA for efficient replication. Here, we examined the effect of mutations in a splicing suppressor sequence called the negative regulator of splicing (NRS), located within the gag gene of Rous sarcoma virus. While the NRS mutant viruses showed only small changes in the levels of spliced env mRNAs, they had significant increases in src mRNA levels and transformed cells more efficiently than wild-type virus. None of these mutations prevented viral replication; however, some of the mutant viruses replicated more slowly than wild-type virus. In addition, increased transcriptional readthrough of the poly(A) site in the 3' LTR was observed with the NRS mutant viruses, suggesting that the wild-type NRS sequence promotes polyadenylation.

Efficient polyadenylation of Rous sarcoma virus RNA requires the negative regulator of splicing element

Rous sarcoma virus pre-mRNA contains an element known as the negative regulator of splicing (NRS) that acts to inhibit viral RNA splicing. The NRS binds serine/arginine-rich (SR) proteins, hnRNP H and the U1/U11 snRNPs, and appears to inhibit splicing by acting as a decoy 5' splice site. Deletions within the gag gene that encompass the NRS also lead to increased read-through past the viral polyadenylation site, suggesting a role for the NRS in promoting polyadenylation. Using NRS-specific deletions and mutations, we show here that a polyadenylation stimulatory activity maps directly to the NRS and is most likely dependent upon SR proteins and U1 and/or U11 snRNP. hnRNP H does not appear to mediate splicing control or stimulate RSV polyadenylation, since viral RNAs containing hnRNP H-specific mutations were spliced and polyadenylated normally. However, the ability of hnRNP H mutations to suppress the read-through caused by an SR protein mutation suggests the potential for hnRNP H to antagonize polyadenylation. Interestingly, disruption of splicing control closely correlated with increased read-through, indicating that a functional NRS is necessary for efficient RSV polyadenylation rather than binding of an individual factor. We propose a model in which the NRS serves to enhance polyadenylation of RSV unspliced RNA in a process analogous to the stimulation of cellular pre-mRNA polyadenylation by splicing complexes.

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.

Repair of a Rev-minus human immunodeficiency virus type 1 mutant by activation of a cryptic splice site

We isolated a revertant virus after prolonged culturing of a replication-impaired human immunodeficiency virus type 1 (HIV-1) mutant of which the Rev open reading frame was inactivated by mutation of the AUG translation initiation codon. Sequencing of the tat-rev region of this revertant virus identified a second-site mutation in tat that restored virus replication in the mutant background. This mutation activated a cryptic 5' splice site (ss) that, when used in conjunction with the regular HIV 3' ss #5, fuses the tat and rev reading frames to encode a novel T-Rev fusion protein that rescues Rev function. We also demonstrate an alternative route to indirectly activate this cryptic 5' ss by mutational inactivation of an adjacent exon splicing silencer element.

Selective inhibition of splicing at the avian sarcoma virus src 3' splice site by direct-repeat posttranscriptional cis elements

The direct-repeat elements (dr1) of avian sarcoma virus (ASV) and leukosis virus have the properties of constitutive transport elements (CTEs), which facilitate cytoplasmic accumulation of unspliced RNA. It is thought that these elements represent binding sites for cellular factors. Previous studies have indicated that in the context of the avian sarcoma virus genome, precise deletion of both ASV dr1 elements results in a very low level of virus replication. This is characterized by a decreased cytoplasmic accumulation of unspliced RNA and a selective increase in spliced src mRNA. Deletion of either the upstream or downstream dr1 results in a delayed-replication phenotype. To determine if the same regions of the dr1 mediate inhibition of src splicing and unspliced RNA transport, point mutations in the upstream and downstream elements were studied. In the context of viral genomes with single dr1 elements, the effects of the mutations on virus replication and increases in src splicing closely paralleled the effects of the mutations on CTE activity. For mutants strongly affecting CTE activity and splicing, unspliced RNA but not spliced RNA turned over in the nucleus more rapidly than wild-type RNA. In the context of wild-type virus containing two dr1 elements, mutations of either element that strongly affect CTE activity caused a marked delay of virus replication and a selective increase in src splicing. However, the turnover of the mutant unspliced RNA as well as the spliced mRNA species did not differ significantly from that of the wild type. These results suggest the dr1 elements in ASV act to selectively inhibit src splicing and that both elements contribute to the fitness of the wild-type virus. However, a single dr1 element is sufficient to stabilize unspliced RNA.

Optimization of a weak 3' splice site counteracts the function of a bovine papillomavirus type 1 exonic splicing suppressor in vitro and in vivo

Alternative splicing is a critical component of the early to late switch in papillomavirus gene expression. In bovine papillomavirus type 1 (BPV-1), a switch in 3' splice site utilization from an early 3' splice site at nucleotide (nt) 3225 to a late-specific 3' splice site at nt 3605 is essential for expression of the major capsid (L1) mRNA. Three viral splicing elements have recently been identified between the two alternative 3' splice sites and have been shown to play an important role in this regulation. A bipartite element lies approximately 30 nt downstream of the nt 3225 3' splice site and consists of an exonic splicing enhancer (ESE), SE1, followed immediately by a pyrimidine-rich exonic splicing suppressor (ESS). A second ESE (SE2) is located approximately 125 nt downstream of the ESS. We have previously demonstrated that the ESS inhibits use of the suboptimal nt 3225 3' splice site in vitro through binding of cellular splicing factors. However, these in vitro studies did not address the role of the ESS in the regulation of alternative splicing. In the present study, we have analyzed the role of the ESS in the alternative splicing of a BPV-1 late pre-mRNA in vivo. Mutation or deletion of just the ESS did not significantly change the normal splicing pattern where the nt 3225 3' splice site is already used predominantly. However, a pre-mRNA containing mutations in SE2 is spliced predominantly using the nt 3605 3' splice site. In this context, mutation of the ESS restored preferential use of the nt 3225 3' splice site, indicating that the ESS also functions as a splicing suppressor in vivo. Moreover, optimization of the suboptimal nt 3225 3' splice site counteracted the in vivo function of the ESS and led to preferential selection of the nt 3225 3' splice site even in pre-mRNAs with SE2 mutations. In vitro splicing assays also showed that the ESS is unable to suppress splicing of a pre-mRNA with an optimized nt 3225 3' splice site. These data confirm that the function of the ESS requires a suboptimal upstream 3' splice site. A surprising finding of our study is the observation that SE1 can stimulate both the first and the second steps of splicing.

R region sequences in the long terminal repeat of a murine retrovirus specifically increase expression of unspliced RNAs

A stem-loop structure at the 5' end of the R region of the long terminal repeat (LTR) of the murine leukemia virus SL3 and other type C mammalian retroviruses is important for maximum levels of expression of a reporter gene under the control of the viral LTR. This element, termed the R region stem-loop (RSL), has a small effect on transcriptional initiation and no effect on RNA polymerase processivity. Its major effect is on posttranscriptional processing of LTR-driven transcripts. Here we tested whether the RSL affected the production of RNAs from a full-length SL3 genome. Mutation of the RSL in the 5' LTR of SL3 reduced the cytoplasmic levels of full-length viral transcripts but not those of spliced, env mRNA transcripts. Thus, the RSL specifically affected the cytoplasmic levels of the unspliced viral RNA. To test further whether the effect was specific for unspliced transcripts, a system was devised in which the expression of a reporter gene under the control of the viral LTR was tested in the presence or absence of an intron. Mutation of the RSL resulted in only about a twofold decline in the level of reporter gene expression when the transcripts contained an intron. However, when the intron was removed, mutation of the RSL reduced expression of the reporter gene about 10- to 60-fold in various cell lines. The secondary structure of the RSL was essential for its activity on the intronless transcript. Thus, the RSL appears to be important for the cytoplasmic accumulation of unspliced viral RNA and unspliced RNA from chimeric transcription units under the control of the viral LTR.

U1 small nuclear ribonucleoprotein and splicing inhibition by the rous sarcoma virus negative regulator of splicing element

Retroviruses require both spliced and unspliced RNA for replication. Accumulation of unspliced Rous sarcoma virus RNA is facilitated in part by a negative cis element in the gag region, termed the negative regulator of splicing (NRS), which serves to repress splicing of viral RNA but can also block splicing of heterologous introns. The NRS binds components of the splicing machinery including SR proteins, U1 and U2, small nuclear ribonucleoproteins (snRNPs) of the major splicing pathway, and U11 snRNP of the minor pathway, yet splicing does not normally occur from the NRS. A mutation that abolishes U11 binding (RG11) also abrogates NRS splicing inhibition, indicating that U11 is functionally important for NRS activity and suggesting that the NRS is recognized as a minor-class 5' splice site (5' ss). We show here, using specific NRS mutations to disrupt U11 binding and coexpression of U11 snRNA genes harboring compensatory mutations, that the NRS U11 site is functional when paired with a minor-class 3' ss from the human P120 gene. Surprisingly, the expectation that the same NRS mutants would be defective for splicing inhibition proved false; splicing inhibition was as good as, if not better than, that for the wild-type NRS. Comparison of these new mutations with RG11 indicated that the latter may disrupt binding of a factor(s) other than U11. Our data suggest that this factor is U1 snRNP and that a U1 binding site that overlaps the U11 site is also disrupted by RG11. Analysis of mutations which selectively disrupted U1 or U11 binding indicated that splicing inhibition by the NRS correlates most strongly with U1 snRNP. Additionally, we show that U1 binding is facilitated by SR proteins that bind to the 5' half of the NRS, confirming an earlier proposal that this region is involved in recruiting snRNPs to the NRS. These data indicate a functional role for U1 in NRS-mediated splicing inhibition.

Function of a bovine papillomavirus type 1 exonic splicing suppressor requires a suboptimal upstream 3' splice site

Alternative splicing is an important mechanism for the regulation of bovine papillomavirus type 1 (BPV-1) gene expression during the virus life cycle. Previous studies in our laboratory have identified two purine-rich exonic splicing enhancers (ESEs), SE1 and SE2, located between two alternative 3' splice sites at nucleotide (nt) 3225 and nt 3605. Further analysis of BPV-1 late-pre-mRNA splicing in vitro revealed a 48-nt pyrimidine-rich region immediately downstream of SE1 that inhibits utilization of the nt 3225 3' splice site. This inhibitory element, which we named an exonic splicing suppressor (ESS), has a U-rich 5' end, a C-rich central part, and an AG-rich 3' end (Z. M. Zheng, P. He, and C. C. Baker, J. Virol. 70:4691-4699, 1996). The present study utilized in vitro splicing of both homologous and heterologous pre-mRNAs to further characterize the ESS. The BPV-1 ESS was inserted downstream of the 3' splice site in the BPV-1 late pre-mRNA, Rous sarcoma virus src pre-mRNA, human immunodeficiency virus tat-rev pre-mRNA, and Drosophila dsx pre-mRNA, all containing a suboptimal 3' splice site, and in the human beta-globin pre-mRNA, which contains a constitutive 3' splice site. These studies demonstrated that suppression of splicing by the BPV-1 ESS requires an upstream suboptimal 3' splice site but not an upstream ESE. Furthermore, the ESS functions when located either upstream or downstream of BPV-1 SE1. Mutational analyses demonstrated that the function of the ESS is sequence dependent and that only the C-rich region of the ESS is essential for suppression of splicing in all the pre-mRNAs tested.

The exon splicing silencer in human immunodeficiency virus type 1 Tat exon 3 is bipartite and acts early in spliceosome assembly

Inefficient splicing of human immunodeficiency virus type 1 (HIV-1) RNA is necessary to preserve unspliced and singly spliced viral RNAs for transport to the cytoplasm by the Rev-dependent pathway. Signals within the HIV-1 genome that control the rate of splicing include weak 3' splice sites, exon splicing enhancers (ESE), and exon splicing silencers (ESS). We have previously shown that an ESS present within tat exon 2 (ESS2) and a suboptimal 3' splice site together act to inhibit splicing at the 3' splice site flanking tat exon 2. This occurs at an early step in spliceosome assembly. Splicing at the 3' splice site flanking tat exon 3 is regulated by a bipartite element composed of an ESE and an ESS (ESS3). Here we show that ESS3 is composed of two smaller elements (AGAUCC and UUAG) that can inhibit splicing independently. We also show that ESS3 is more active in the context of a heterologous suboptimal splice site than of an optimal 3' splice site. ESS3 inhibits splicing by blocking the formation of a functional spliceosome at an early step, since A complexes are not detected in the presence of ESS3. Competitor RNAs containing either ESS2 or ESS3 relieve inhibition of splicing of substrates containing ESS3 or ESS2. This suggests that a common cellular factor(s) may be required for the inhibition of tat mRNA splicing mediated by ESS2 and ESS3.

The upstream, direct repeat sequence of Prague A Rous sarcoma virus is deficient in mediating efficient Gag assembly and particle release

Rous sarcoma virus (RSV) contains two approximately 135-nt imperfect direct repeats composed of smaller repeats, dr1 (approximately 100 nt) and dr2 (approximately 36 nt), that are between the env and src genes and downstream of src in the 3' untranslated region, respectively. It has previously been shown that a Prague A RSV mutant in which both dr1 sequences are deleted is defective at several points in the virus life cycle, including unspliced RNA and env mRNA stability, unspliced RNA transport, and virus particle assembly. A defect in unspliced RNA transport occurs because a cytoplasmic transport element is present within the dr1. We have suggested that the defect of particle production may arise from the failure of the unspliced RNA to be targeted to sites in the cytoplasm where its translation is favorable for Gag protein assembly. In this report, we have further investigated the function of the direct repeats by comparing virus mutants containing either a single upstream or downstream dr1 sequence. Both mutants were delayed in replication compared to the wild-type; the mutant with a single upstream dr1 (delta DDR) is significantly more defective than the mutant with a single downstream dr1 (delta UDR). While both mutants appear capable of efficiently transporting unspliced RNA to the cytoplasm, the delta DDR mutant with only the upstream dr1 is defective in its ability to support Gag assembly and particle release. The replication defect cannot be repaired by placing the upstream dr1 at the location of the downstream dr1 in the 3' untranslated region. A single point mutation in the upstream dr1 (U to C) restored replication and particle production to near normal levels. The results suggest that unspliced RNA transport and Gag assembly functions may be mediated by different elements within the dr1 and that the Prague A upstream dr1 is defective in the latter but not the former function.

An RNA splicing enhancer-like sequence is a component of a splicing inhibitor element from Rous sarcoma virus

The accumulation in infected cells of large amounts of unspliced viral RNA for use as mRNA and genomic RNA is a hallmark of retrovirus replication. The negative regulator of splicing (NRS) is a long cis-acting RNA element in Rous sarcoma virus that contributes to unspliced RNA accumulation through splicing inhibition. One of two critical sequences located in the NRS 3' region resembles a minor class 5' splice site and is required for U11 small nuclear ribonucleoprotein (snRNP) binding to the NRS. The second is a purine-rich region in the 5' half that interacts with the splicing factor SF2/ASF. In this study we investigated the possibility that this purine-rich region provides an RNA splicing enhancer function required for splicing inhibition. In vitro, the NRS acted as a potent, orientation-dependent enhancer of Drosophila doublesex pre-mRNA splicing, and enhancer activity mapped to the purine-rich domain. Analysis of a number of site-directed and deletion mutants indicated that enhancer activity was diffusely located throughout a 60-nucleotide area but only the activity associated with a short region previously shown to bind SF2/ASF correlated with efficient splicing inhibition. The significance of the enhancer activity to splicing inhibition was demonstrated by using chimeras in which two authentic enhancers (ASLV and FP) were substituted for the native NRS purine region. In each case, splicing inhibition in transfected cells was restored to levels approaching that observed for the NRS. The observation that a nonfunctional version of the FP enhancer (FPD) that does not bind SF2/ASF also fails to block splicing when paired with the NRS 3' region supports the notion that SF2/ASF binding to the NRS is relevant, but other SR proteins may substitute if an appropriate binding site is supplied. Our results are consistent with a role for the purine region in facilitated snRNP binding to the NRS via SF2/ASF.

SR protein and snRNP requirements for assembly of the Rous sarcoma virus negative regulator of splicing complex in vitro

Retroviruses use unspliced RNA as mRNA for expression of virion structural proteins and as genomic RNA; the full-length RNA often constitutes the majority of the viral RNA in an infected cell. Maintenance of this large pool of unspliced RNA is crucial since even a modest increase in splicing efficiency can lead to impaired replication. In Rous sarcoma virus, the negative regulator of splicing (NRS) was identified as a cis element that negatively impacts splicing of viral RNA. Components of the splicing apparatus appear to be involved in splicing inhibition since binding of a number of splicing factors (snRNPs and SR proteins) and assembly of a large complex (NRS-C) in nuclear extracts correlate with NRS-mediated splicing inhibition. In determining the requirements for NRS complex assembly, we show that NRS-C assembly can be reconstituted by addition of total SR proteins to an S100 extract that lacks these factors. Of the purified SR proteins tested, SF2/ASF was functional in NRS-C assembly, whereas SC35 and SRp40 were not. The participation of snRNPs in NRS-C assembly was addressed by selectively depleting individual snRNPs with oligonucleotides and RNase H or by sequestering critical snRNA domains with 2'-O-methyl RNA oligonucleotides. The results indicate that in addition to U11 snRNP, U1 snRNP and SR proteins, but not U2 snRNP, are involved in NRS-C assembly.

Transformation of primary chick embryo fibroblasts by Marek's disease virus

Marek's disease virus (MDV) is an alphaherpesvirus, which can mediate the malignant transformation of lymphocytes to form lymphomas in chickens. In this study, we demonstrate that MDV can transform primary chick embryo fibroblasts (CEF). The cell line derived from primary CEF infected with the GA strain of MDV was called CEM(MDV). The fibroblast nature of CEM(MDV) was verified by absence of cytokeratin type II. The CEM(MDV) phenotype differed from either primary CEF or MDV-infected CEF. CEM(MDV) were extensively vacuolated, with unusual multilamellar structures in the cytoplasm, The nuclei were considerably larger than those in primary CEF and were uniformly positive for proliferating cell nuclear antigen. The cell line was subcultured for more than 10 generations; however, CEM(MDV) did not support a fully productive MDV infection, because complete nucleocapsids were not detected and infectivity assays showed that cell line produced no infectious virus. PCR analyses demonstrated that this cell line carried both polypeptide 38 (pp38) and Meq DNA, MDV-specific genes associated with transformation. In addition, examination by laser scanning confocal microscopy revealed that CEM(MDV) constitutively produced MDV MEQ protein in nuclei and pp38 as well as glycoprotein B in the cytoplasm and on the plasma membrane. Growth in soft agar assay demonstrated that CEM(MDV) formed colonies, similar to HeLa and human melanoma cells. Retroviral insertion was not detected in DNA from the CEM(MDV) line.

Rous sarcoma virus direct repeat cis elements exert effects at several points in the virus life cycle

Two approximately 135-nucleotide (nt) direct repeats flank the Rous sarcoma virus (RSV) oncogene src and are composed of two smaller repeats, dr1 (approximately 100 nt) and dr2 (approximately 36 nt). These sequences have been reported to contain cis-acting signals necessary for RNA packaging and elements that allow cytoplasmic accumulation of unspliced RNA (cytoplasmic transport elements). In this report, we show that avian fibroblasts infected with the Prague A strain of RSV with precise deletions of both dr1 elements express src and are transformed by this mutant virus but production of virus particles is very low and virus spread throughout the culture requires several weeks. We show that the replication defect is due to complex effects on viral RNA transport, viral RNA half-life, and virus particle assembly. The dr1 elements may contain binding sites for a permissive cell-specific factor(s) that facilitates efficient nuclear-cytoplasmic transport, RNA stability, and cytoplasmic utilization of unspliced viral RNA. The implications of these results for understanding the defects of nonpermissive virus infections in mammalian cells are discussed.

High-level expression of exogenous genes by replication-competent retrovirus vectors with an internal ribosomal entry site

We report the construction of two types of Rous sarcoma virus (RSV)-based replication-competent avian retrovirus vectors, IR1 and IR2 to express an exogenous gene at a very high level. In these vectors, the internal ribosomal entry site (IRES) derived from encephalomyocarditis virus (EMCV) was inserted between the env gene and an exogenous gene. The IR1 vector retains the splicing acceptor site that is present in the downstream of the env gene while the IR2 vector lacks it. Using a v-fos mutant (v-fos-CD3) as an example of exogenous genes, we show here that both IR1 and IR2 vectors expressed the gene product, CD3, at expression levels 5- and 8-fold higher than that of their parental vector without IRES, respectively. These vectors were moderately stable and kept a high-level expression of CD3 for at least three passages through the cells. Analysis of viral transcripts indicate that exogenous genes carried by both IR vectors were translated exclusively from the IRES that is present in all the species of the viral transcripts. High-level expression of exogenous genes was also observed in the case of the Hoxa-13 gene in the IR1 vector or the fra-2 gene in the IR2 vector, indicating that the extremely high-level expression characteristic of these vectors is applicable to several exogenous genes.

A naturally arising mutation of a potential silencer of exon splicing in human immunodeficiency virus type 1 induces dominant aberrant splicing and arrests virus production

We have isolated a naturally arising human immunodeficiency type 1 (HIV-1) mutant containing a point mutation within the env gene. The point mutation resulted in complete loss of balanced splicing, with dominant production of aberrant mRNAs. The aberrant RNAs arose via activation of normally cryptic splice sites flanking the mutation within the env terminal exon to create exon 6D, which was subsequently incorporated in aberrant env, tat, rev, and nef mRNAs. Aberrant multiply spliced messages contributed to reduced virus replication as a result of a reduction in wild-type Rev protein. The point mutation within exon 6D activated exon 6D inclusion when the exon and its flanking splice sites were transferred to a heterologous minigene. Introduction of the point mutation into an otherwise wild-type HIV-1 proviral clone resulted in virus that was severely inhibited for replication in T cells and displayed elevated usage of exon 6D. Exon 6D contains a bipartite element similar to that seen in tat exon 3 of HIV-1, consisting of a potential exon splicing silencer (ESS) juxtaposed to a purine-rich sequence similar to known exon splicing enhancers. In the absence of a flanking 5' splice site, the point mutation within the exon 6D ESS-like element strongly activated env splicing, suggesting that the putative ESS plays a natural role in limiting the level of env splicing. We propose, therefore, that exon silencers may be a common element in the HIV-1 genome used to create balanced splicing of multiple products from a single precursor RNA.

Splicing efficiency of human immunodeficiency virus type 1 tat RNA is determined by both a suboptimal 3' splice site and a 10 nucleotide exon splicing silencer element located within tat exon 2

We have previously demonstrated that an exon splicing silencer (ESS) is present within human immunodeficiency virus type 1 (HIV-1)tat exon 2. This 20 nucleotide (nt) RNA element acts selectively to inhibit splicing at the upstream 3'splice site (3'ss #3) flanking this exon. In this report, we have used in vitro splicing of mutated RNA substrates to determine the sequences necessary and sufficient for the activity of the ESS. The activity of the ESS within tat exon 2 maps to a 10 nt core sequence CUAGACUAGA. This core sequence was sufficient to inhibit splicing when inserted downstream from the 3'ss of the heterologous Rous sarcoma virus src gene. Mutagenesis of the interspersed purines in the polypyrimidine tract of the tat exon 2 3'ss to pyrimidines resulted in a significant increase in splicing efficiency indicating that 3'ss#3 is suboptimal. The ESS acts to inhibit splicing at the optimized 3'splice sites of both the HIV-1 tat and RSV src constructs but with a reduced efficiency compared to its effect on suboptimal 3'splice sites. The results indicate that both the ESS and a suboptimal 3'splice site act together to control splicing at the 3'splice site flanking at exon 2.

Pararetro- and retrovirus RNA: splicing and the control of nuclear export

Splicing and nuclear export of RNA are obligatory steps in gene expression by eukaryotic cells. Not only have novel splicing events been identified during the replication cycle of retro- and pararetroviruses, but the resulting combination of spliced and unspliced products requires specialized mechanisms for nuclear export, which in turn is a key regulatory step for virus replication.

The Moloney murine sarcoma virus ts110 5' splice site signal contributes to the regulation of splicing efficiency and thermosensitivity

The 5' splice site signal (5'ss) in Moloney murine sarcoma virus ts110 (MuSVts110) RNA was found to participate in the regulation of its splicing phenotype. This 5'ss (CAG/GUAGGA) departs from the mammalian consensus (CAG/GURAGU) at positions +4 and +6, both of which base pair with U1 and U6 small nuclear RNAs during splicing. A doubling in splicing efficiency and near elimination of the splicing thermosensitivity characteristic of MuSVts110 were observed in 5'ss mutants containing a U at position +6 (termed 5' A6U), even in those in which U1-5'ss complementarity had been reduced. At the permissive temperature (28 degrees C), the 5' A6U mutation increased the efficiency of the second splicing reaction, while at the nonpermissive temperature (39 degrees C), both splicing reactions were positively affected.

Human T-cell leukemia virus type 2 Rex inhibits pre-mRNA splicing in vitro at an early stage of spliceosome formation

The Rex protein is an essential regulator of RNA expression in human T-cell leukemia virus types 1 and 2 (HTLV-1 and HTLV-2) that promotes the accumulation of full-length and partially spliced viral transcripts in the cytoplasm. Rex-mediated regulation correlates with specific binding to a cognate RNA recognition element which overlaps the 5' splice site in the viral long terminal repeat. It has been unclear whether Rex directly affects splicing or only nuclear-to-cytoplasmic transport of viral mRNA. We demonstrate that HTLV-2 Rex is a potent inhibitor of splicing in vitro at an early step in spliceosome assembly. Inhibition requires phosphorylation of Rex and the ability of Rex to bind to the Rex response element. Direct inhibition of early spliceosome assembly by Rex may account for differential accumulation of unspliced transcripts and represents a novel mechanism of retroviral gene regulation.

Selection of the bovine papillomavirus type 1 nucleotide 3225 3' splice site is regulated through an exonic splicing enhancer and its juxtaposed exonic splicing suppressor

Alternative splicing is an important mechanism for the regulation of bovine papillomavirus type 1 (BPV-1) gene expression during the virus life cycle. However, one 3' splice site, located at nucleotide (nt) 3225, is used for the processing of most BPV-1 pre-mRNAs in BPV-1-transformed C127 cells and at early to intermediate times in productively infected warts. At late stages of the viral life cycle, an alternative 3' splice site at nt 3605 is used for the processing of the late pre-mRNA. In this study, we used in vitro splicing in HeLa cell nuclear extracts to identify cis elements which regulate BPV-1 3' splice site selection. Two purine-rich exonic splicing enhancers were identified downstream of nt 3225. These sequences, designated SE1 (nt 3256 to 3305) and SE2 (nt 3477 to 3526), were shown to strongly stimulate the splicing of a chimeric Drosophila doublesex pre-mRNA, which contains a weak 3' splice site. A BPV-1 late pre-mRNA containing the nt 3225 3' splice site but lacking both SE1 and SE2 was spliced poorly, indicating that this 3' splice site is inherently weak. Analysis of the 3' splice site suggested that this feature is due to both a nonconsensus branch point sequence and a suboptimal polypyrimidine tract. Addition of SE1 to the late pre-mRNA dramatically stimulated splicing, indicating that SE1 also functions as an exonic splicing enhancer in its normal context. However, a late pre-mRNA containing both SE1 and SE2 as well as the sequence in between was spliced inefficiently. Further mapping studies demonstrated that a 48-nt pyrimidine-rich region immediately downstream of SE1 was responsible for this suppression of splicing. Thus, these data suggest that selection of the BPV-1 nt 3225 3' splice site is regulated by both positive and negative exonic sequences.

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.

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.

SR protein splicing factors interact with the Rous sarcoma virus negative regulator of splicing element

Retroviral replication requires that a portion of the primary transcripts generated from proviral DNA be spliced to serve as mRNA for the envelope protein and in Rous sarcoma virus as src mRNA. However, a substantial amount of full-length RNA must be maintained in an unspliced form, as the unspliced RNA serves both as mRNA for structural proteins and virion-associated enzymatic proteins and as genomic RNA for progeny virions. The extent of viral RNA splicing must be finely controlled, since only a narrow range in the ratio of unspliced RNA to spliced RNA is tolerated for optimal replication. A number of cis-acting sequences within the RNA of Rous sarcoma virus play a role in preserving a large pool of unspliced RNA. One such sequence, the negative regulator of splicing (NRS), is of interest because it blocks splicing but is not located near any of the splice junctions. To better understand how this novel element blocks splicing at a distance, we set out to identify host cell factors that interact specifically with this inhibitory sequence. In this study, proteins from nuclear extracts with molecular masses of 26, 36, 44, and 55 kDa were shown by UV cross-linking assays to bind the NRS preferentially. One of them, p55, was also detected in a specific complex with SR protein electrophoretic mobility shift assay. All but p55 have biochemical properties consistent with SR protein splicing factors, and some, but not all, of the total SR proteins purified from HeLa cells cross-link specifically to the NRS. The strongest cross-linking SR protein is SRp30a/b, which is composed of the splicing factors SF2/ASF and SC35. The NRS specifically binds bacterially expressed SF2/ASF, whereas nonfunctional mutants do not. Data indicating that the 36-kDa protein which cross-links in nuclear extracts is SF2/ASF are presented. The data indicate that factors normally required for RNA splicing may be exploited by retroviruses to block splicing.

Branchpoint and polypyrimidine tract mutations mediating the loss and partial recovery of the Moloney murine sarcoma virus MuSVts110 thermosensitive splicing phenotype

Balanced splicing of retroviral RNAs is mediated by weak signals at the 3' splice site (ss) acting in concert with other cis elements. Moloney murine sarcoma virus MuSVts110 shows a similar balance between unspliced and spliced RNAs, differing only in that the splicing of its RNA is, in addition, growth temperature sensitive. We have generated N-nitroso-N-methylurea (NMU)-treated MuSVts110 revertants in which splicing was virtually complete at all temperatures and have investigated the molecular basis of this reversion on the assumption that the findings would reveal cis-acting elements controlling MuSVts110 splicing thermosensitivity. In a representative revertant (NMU-20), we found that complete splicing was conferred by a G-to-A substitution generating a consensus branchpoint (BP) signal (-CCCUGGC- to -CCCUGAC- [termed G(-25)A]) at -25 relative to the 3' ss. Weakening this BP to -CCCGAC- [G(-25)A,U(-27)C] moderately reduced splicing at the permissive temperature and sharply inhibited splicing at the originally nonpermissive temperature, arguing that MuSVts110 splicing thermosensitivity depends on a suboptimal BP-U2 small nuclear RNA interaction. This conclusion was supported by results indicating that lengthening the short MuSVts110 polypyrimidine tract and altering its uridine content doubled splicing efficiency at permissive temperatures and nearly abrogated splicing thermosensitivity. In vitro splicing experiments showed that MuSVts110 G(-25)A RNA intermediates were far more efficiently ligated than RNAs carrying the wild-type BP, the G(-25)A,U (-27)C BP, or the extended polypyrimidine tract. The efficiency of ligation in vitro roughly paralleled splicing efficiency in vivo [G(-25)A BP > extended polypyrimidine tract > G(-25)A,U(-27)C BP > wild-type BP]. These results suggest that MuSVts110 RNA splicing is balanced by cis elements similar to those operating in other retroviruses and, in addition, that its splicing thermosensitivity is a response to the presence of multiple suboptimal splicing signals.

Inhibition of RNA splicing at the Rous sarcoma virus src 3' splice site is mediated by an interaction between a negative cis element and a chicken embryo fibroblast nuclear factor

In permissive Rous sarcoma virus-infected chicken embryo fibroblasts (CEF), approximately equimolar amounts of env and src mRNAs are present. In nonpermissive mammalian cells, the src mRNA level is elevated and env mRNA level is reduced. A cis element in the region between the env gene and the src 3' splice site, which we have termed the suppressor of src splicing (SSS), acts specifically in CEF but not in human cells to reduce src mRNA levels. The splicing inhibition in CEF is not caused by a base-paired structure which is predicted to form between the SSS and the src 3' splice site. To further investigate the mechanism of the inhibition, we have used human HeLa cell nuclear extracts to compare in vitro the rates of splicing of RNA substrates containing the Rous sarcoma virus major 5' splice site and either the env or src 3' splice sites. We show that the src 3' splice site is used approximately fivefold more efficiently than the env 3' splice site. The efficiency of in vitro splicing at the src 3' splice site is specifically reduced by addition of CEF nuclear extract. The inhibition is dependent on the presence of the SSS element and can be abrogated by addition of competitor RNA. We propose that the SSS region represents a binding site for a negative-acting CEF splicing factor(s).

Presence of exon splicing silencers within human immunodeficiency virus type 1 tat exon 2 and tat-rev exon 3: evidence for inhibition mediated by cellular factors

Human immunodeficiency virus type 1 (HIV-1) pre-mRNA splicing is regulated in order to maintain pools of unspliced and partially spliced viral RNAs as well as the appropriate levels of multiply spliced mRNAs during virus infection. We have previously described an element in tat exon 2 that negatively regulates splicing at the upstream tat 3' splice site 3 (B. A. Amendt, D. Hesslein, L.-J. Chang, and C. M. Stoltzfus, Mol. Cell. Biol. 14:3960-3970, 1994). In this study, we further defined the element to a 20-nucleotide (nt) region which spans the C-terminal vpr and N-terminal tat coding sequences. By analogy with exon splicing enhancer (ESE) elements, we have termed this element an exon splicing silencer (ESS). We show evidence for another negative cis-acting region within tat-rev exon 3 of HIV-1 RNA that has sequence motifs in common with a 20-nt ESS element in tat exon 2. This sequence is juxtaposed to a purine-rich ESE element to form a bipartite element regulating splicing at the upstream tat-rev 3' splice site. Inhibition of the splicing of substrates containing the ESS element in tat exon 2 occurs at an early stage of spliceosome assembly. The inhibition of splicing mediated by the ESS can be specifically abrogated by the addition of competitor RNA. Our results suggest that HIV-1 RNA splicing is regulated by cellular factors that bind to positive and negative cis elements in tat exon 2 and tat-rev exon 3.