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.     

Two regions promote U11 small nuclear ribonucleoprotein particle binding to a retroviral splicing inhibitor element (negative regulator of splicing)

The Rous sarcoma virus (RSV) negative regulator of splicing (NRS) is an RNA element that represses splicing and promotes polyadenylation of viral RNA. The NRS acts as a pseudo 5' splice site (ss), and serine-arginine (SR) proteins, U1snRNP, and U6 small nuclear ribonucleoproteins (snRNPs) are implicated in its function. The NRS also efficiently binds U11 snRNP of the U12-dependent splicing pathway, which is interesting, because U11 binds only poorly to authentic substrates that lack a U12-type 3' splice site. It is of considerable interest to understand how the low abundance U11 snRNP binds the NRS so well. Here we show that U11 can bind the NRS as a mono-snRNP in vitro and that a G-rich element located downstream of the U11 site is required for efficient binding. Mutational analyses indicated that two of four G tracts in this region were important for optimal U11 binding and that the G-rich region did not function indirectly by promoting U1 snRNP binding to an overlapping site. Surprisingly, inactivation of U2 snRNP also decreased U11 binding to the NRS. The NRS harbors a branch point-like/pyrimidine tract sequence (BP/Py) just upstream of the U1/U11 site that is characteristic of 3' splice sites. Deletion of this region decreased U2 and U11 binding, and deletion of the G-rich region also reduced U2 binding. The G element, but not the BP/Py sequence, was also required for U11 binding to the NRS in vivo as assessed by minor class splicing from the NRS to a minor class 3'ss from the P120 gene. These results indicate that efficient U11 binding to the isolated NRS involves at least two elements in addition to the U11 consensus sequence and may have implications for U11 binding to authentic splicing substrates.     

The role of U2AF35 and U2AF65 in enhancer-dependent splicing.

Splicing enhancers are RNA sequence elements that promote the splicing of nearby introns. The mechanism by which these elements act is still unclear. Some experiments support a model in which serine-arginine (SR)-rich proteins function as splicing activators by binding to enhancers and recruiting the splicing factor U2AF to an adjacent weak 3' splice site. In this model, recruitment requires interactions between the SR proteins and the 35-kDa subunit of U2AF (U2AF35). However, more recent experiments have not supported the U2AF recruitment model. Here we provide additional evidence for the recruitment model. First, we confirm that base substitutions that convert weak 3' splice sites to a consensus sequence, and therefore increase U2AF binding, relieve the requirement for a splicing activator. Second, we confirm that splicing activators are required for the formation of early spliceosomal complexes on substrates containing weak 3' splice sites. Most importantly, we find that splicing activators promote the binding of both U2AF65 and U2AF35 to weak 3' splice sites under splicing conditions. Finally, we show that U2AF35 is required for maximum levels of activator-dependent splicing. We conclude that a critical function of splicing activators is to recruit U2AF to the weak 3' splice sites of enhancer-dependent introns, and that efficient enhancer-dependent splicing requires U2AF35.     

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.     

Interactions of SR45, an SR-like protein, with spliceosomal proteins and an intronic sequence: insights into regulated splicing

SR45 is a serine/arginine-rich (SR)-like protein with two arginine/serine-rich (RS) domains. We have previously shown that SR45 regulates alternative splicing (AS) by differential selection of 5' and 3' splice sites. However, it is unknown how SR45 regulates AS. To gain mechanistic insights into the roles of SR45 in splicing, we screened a yeast two-hybrid library with SR45. This screening resulted in the isolation of two spliceosomal proteins, U1-70K and U2AF(35) b that are known to function in 5' and 3' splice site selection, respectively. This screen not only confirmed our prior observation that U1-70K and SR45 interact, but also helped to identify an additional interacting partner (U2AF(35) ). In vitro and in vivo analyses revealed an interaction of SR45 with both paralogs of U2AF(35) . Furthermore, we show that the RS1 and RS2 domains of SR45, and not the RNA recognition motif (RRM) domain, associate independently with both U2AF(35) proteins. Interaction studies among U2AF(35) paralogs and between U2AF(35) and U1-70K revealed that U2AF(35) can form homo- or heterodimers and that U2AF(35) proteins can associate with U1-70K. Using RNA probes from SR30 intron 10, whose splicing is altered in the sr45 mutant, we show that SR45 and U2AF(35) b bind to different parts of the intron, with a binding site for SR45 in the 5' region and two binding regions, each ending with a known 3' splice site, for U2AF(35) b. These results suggest that SR45 recruits U1snRNP and U2AF to 5' and 3' splice sites, respectively, by interacting with pre-mRNA, U1-70K and U2AF(35) and modulates AS.     

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.     

Enhancer elements activate the weak 3' splice site of alpha-tropomyosin exon 2.

We have identified four purine-rich sequences that act as splicing enhancer elements to activate the weak 3' splice site of alpha-tropomyosin exon 2. These elements also activate the splicing of heterologous substrates containing weak 3' splice sites or mutated 5' splice sites. However, they are unique in that they can activate splicing whether they are placed in an upstream or downstream exon, and the two central elements can function regardless of their position relative to one another. The presence of excess RNAs containing these enhancers could effectively inhibit in vitro pre-mRNA splicing reactions in a substrate-dependent manner and, at lower concentrations of competitor RNA, the addition of SR proteins could relieve the inhibition. However, when extracts were depleted by incubation with biotinylated exon 2 RNAs followed by passage over streptavidin agarose, SR proteins were not sufficient to restore splicing. Instead, both SR proteins and fractions containing a 110-kD protein were necessary to rescue splicing. Using gel mobility shift assays, we show that formation of stable enhancer-specific complexes on alpha-tropomyosin exon 2 requires the presence of both SR proteins and the 110-kD protein. By analogy to the doublesex exon enhancer elements in Drosophila, our results suggest that assembly of mammalian exon enhancer complexes requires both SR and non-SR proteins to activate selection of weak splice sites.     

Exonic splicing enhancer-dependent selection of the bovine papillomavirus type 1 nucleotide 3225 3' splice site can be rescued in a cell lacking splicing factor ASF/SF2 through activation of the phosphatidylinositol 3-kinase/Akt pathway

Bovine papillomavirus type 1 (BPV-1) late pre-mRNAs are spliced in keratinocytes in a differentiation-specific manner: the late leader 5' splice site alternatively splices to a proximal 3' splice site (at nucleotide 3225) to express L2 or to a distal 3' splice site (at nucleotide 3605) to express L1. Two exonic splicing enhancers, each containing two ASF/SF2 (alternative splicing factor/splicing factor 2) binding sites, are located between the two 3' splice sites and have been identified as regulating alternative 3' splice site usage. The present report demonstrates for the first time that ASF/SF2 is required under physiological conditions for the expression of BPV-1 late RNAs and for selection of the proximal 3' splice site for BPV-1 RNA splicing in DT40-ASF cells, a genetically engineered chicken B-cell line that expresses only human ASF/SF2 controlled by a tetracycline-repressible promoter. Depletion of ASF/SF2 from the cells by tetracycline greatly decreased viral RNA expression and RNA splicing at the proximal 3' splice site while increasing use of the distal 3' splice site in the remaining viral RNAs. Activation of cells lacking ASF/SF2 through anti-immunoglobulin M-B-cell receptor cross-linking rescued viral RNA expression and splicing at the proximal 3' splice site and enhanced Akt phosphorylation and expression of the phosphorylated serine/arginine-rich (SR) proteins SRp30s (especially SC35) and SRp40. Treatment with wortmannin, a specific phosphatidylinositol 3-kinase/Akt kinase inhibitor, completely blocked the activation-induced activities. ASF/SF2 thus plays an important role in viral RNA expression and splicing at the proximal 3' splice site, but activation-rescued viral RNA expression and splicing in ASF/SF2-depleted cells is mediated through the phosphatidylinositol 3-kinase/Akt pathway and is associated with the enhanced expression of other SR proteins.     

A cellular protein, hnRNP H, binds to the negative regulator of splicing element from Rous sarcoma virus

Incomplete RNA splicing is a key feature of the retroviral life cycle. This is in contrast to the processing of most cellular pre-mRNAs, which are usually spliced to completion. In Rous sarcoma virus, splicing control is achieved in part through a cis-acting RNA element termed the negative regulator of splicing (NRS). The NRS is functionally divided into two parts termed NRS5' and NRS3', which bind a number of splicing factors. The U1 and U11 small nuclear ribonucleoproteins interact with sequences in NRS3', whereas NRS5' binds several proteins including members of the SR [corrected] family of proteins. Among the proteins that specifically bind NRS5' is a previously unidentified 55-kDa protein (p55). In this report we describe the isolation and identification of p55. The p55 binding site was localized by UV cross-linking to a 31-nucleotide segment, and a protein that binds specifically to it was isolated by RNA affinity selection and identified by mass spectrometry as hnRNP H. Antibodies against hnRNP H immunoprecipitated cross-linked p55 and induced a supershift of a p55-containing complex formed in HeLa nuclear extract. Furthermore, UV cross-linking and electrophoretic mobility shift assays indicated that recombinant hnRNP H specifically interacts with the p55 binding site, confirming that hnRNP H is p55. The possible roles of hnRNP H in NRS function are discussed.     

SR proteins promote the first specific recognition of Pre-mRNA and are present together with the U1 small nuclear ribonucleoprotein particle in a general splicing enhancer complex.

We show that addition of SR proteins to in vitro splicing extracts results in a significant increase in assembly of the earliest prespliceosomal complex E and a corresponding decrease in assembly of the heterogeneous nuclear ribonucleoprotein (hnRNP) complex H. In addition, SR proteins promote formation of the E5' and E3' complexes that assemble on RNAs containing only 5' and 3' splice sites, respectively. We conclude that SR proteins promote the earliest specific recognition of both the 5' and 3' splice sites and are limiting for this function in HeLa nuclear extracts. Using UV cross-linking, we demonstrate specific, splice site-dependent RNA-protein interactions of SR proteins in the E, E5', and E3' complexes. SR proteins do not UV cross-link in the H complex, and conversely, hnRNP cross-linking is largely excluded from the E-type complexes. We also show that a discrete complex resembling the E5' complex assembles on both purine-rich and non-purine-rich exonic splicing enhancers. This complex, which we have designated the Enhancer complex, contains U1 small nuclear RNP (snRNP) and is associated with different SR protein family members, depending on the sequence of the enhancer. We propose that both downstream 5' splice site enhancers and exonic enhancers function by establishing a network of pre-mRNA-protein and protein-protein interactions involving U1 snRNP, SR proteins, and U2AF that is similar to the interactions that bring the 5' and 3' splice sites together in the E complex.     

The cap and the 3' splice site similarly affect polyadenylation efficiency.

The 5' cap of a mammalian pre-mRNA has been shown to interact with splicing components at the adjacent 5' splice site for processing of the first exon and the removal of the first intron (E. Izaurralde, J. Lewis, C. McGuigan, M. Jankowska, E. Darzynkiewicz, and I.W. Mattaj, Cell 78:657-668, 1994). Likewise, it has been shown that processing of the last exon and removal of the last intron involve interaction between splicing components at the 3' splice site and the polyadenylation complex at the polyadenylation signal (M. Niwa, S. D. Rose, and S.M. Berget, Genes Dev. 4:1552-1559, 1990; M. Niwa and S. M. Berget, Genes Dev. 5:2086-2095, 1991). These findings suggest that the cap provides a function in first exon processing which is similar to the function of the 3' splice site at last exon processing. To determine whether caps and 3' splice sites function similarly, we compared the effects of the cap and the 3' splice site on the in vitro utilization of the simian virus 40 late polyadenylation signal. We show that the presence of a m7GpppG cap, but not a cap analog, can positively affect the efficiency of polyadenylation of a polyadenylation-only substrate. Cap analogs do not stimulate polyadenylation because they fail to bind titratable cap-binding factors. The failure of cap analogs to stimulate polyadenylation can be overcome if a 3' splice site is present upstream of the polyadenylation signal. These data indicate that factors interacting with the cap or the 3' splice site function similarly to affect polyadenylation signal, along with m7GpppG cap, is inhibitory to polyadenylation. This finding suggests that the interaction between the cap-binding complexes and splicing components at the 5' splice site may form a complex which is inhibitory to further processing if splicing of an adjacent intron is not achieved.     

An element in the 5' common exon of the NCAM alternative splicing unit interacts with SR proteins and modulates 5' splice site selection.

The neural cell adhesion molecule (NCAM) gene contains an 801 nt exon that is included preferentially in neuronal cells. We have set up an in vitro splicing system that mimics the neuro-specific alternative splicing profile of NCAM exon 18. Splicing regulation is observed using model pre-mRNAs that contain competing 5' or 3' splice sites, suggesting that distinct pathways regulate NCAM 5' and 3' splice site selection. While inclusion of exon 18 is the predom-inant choice in neuronal cells, an element in the 5' common exon 17 improves exon 17/exon 19 splicing in a neuronal cell line. A similar behavior is observed in vitro as the element can stimulate the 5' splice site of exon 17 or a heterologous 5' splice site. The minimal 32 nt sequence of the exon 17 enhancer consists of purine stretches and A/C motifs. Mutations in the purine stretches compromise the binding of SR proteins and decreases splicing stimulation in vitro. Mutations in the A/C motifs do not affect SR protein binding but reduce enhancing activity. Our results suggest that the assembly of an enhancer complex containing SR proteins in a 5' common exon ensures that NCAM mRNAs lacking exon 18 are made in neuronal cells.     

Ser/Arg-rich protein-mediated communication between U1 and U2 small nuclear ribonucleoprotein particles

Previous work demonstrated that U1 small nuclear ribonucleoprotein particle (snRNP), bound to a downstream 5' splice site, can positively influence utilization of an upstream 3' splice site via exon definition in both trans- and cis-splicing systems. Although exon definition results in the enhancement of splicing of an upstream intron, the nature of the factors involved has remained elusive. We assayed the interaction of U1 snRNP as well as the positive effect of a downstream 5' splice site on trans-splicing in nematode extracts containing either inactive (early in development) or active (later in development) serine/arginine-rich splicing factors (SR proteins). We have determined that U1 snRNP interacts with the 5' splice site in the downstream exon even in the absence of active SR proteins. In addition, we determined that U1 snRNP-directed loading of U2 snRNP onto the branch site as well as efficient trans-splicing in these inactive extracts could be rescued upon the addition of active SR proteins. Identical results were obtained when we examined the interaction of U1 snRNP as well as the requirement for SR proteins in communication across a cis-spliced intron. Weakening of the 3' splice site uncovered distinct differences, however, in the ability of U1 snRNP to promote U2 addition, dependent upon its position relative to the branch site. These results demonstrate that SR proteins are required for communication between U1 and U2 snRNPs whether this interaction is across introns or exons.     

Human immunodeficiency virus type 1 hnRNP A/B-dependent exonic splicing silencer ESSV antagonizes binding of U2AF65 to viral polypyrimidine tracts

Human immunodeficiency virus type 1 (HIV-1) exonic splicing silencers (ESSs) inhibit production of certain spliced viral RNAs by repressing alternative splicing of the viral precursor RNA. Several HIV-1 ESSs interfere with spliceosome assembly by binding cellular hnRNP A/B proteins. Here, we have further characterized the mechanism of splicing repression using a representative HIV-1 hnRNP A/B-dependent ESS, ESSV, which regulates splicing at the vpr 3' splice site. We show that hnRNP A/B proteins bound to ESSV are necessary to inhibit E complex assembly by competing with the binding of U2AF65 to the polypyrimidine tracts of repressed 3' splice sites. We further show evidence suggesting that U1 snRNP binds the 5' splice site despite an almost complete block of splicing by ESSV. Possible splicing-independent functions of U1 snRNP-5' splice site interactions during virus replication are discussed.