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.     

Splicing regulatory elements within tat exon 2 of human immunodeficiency virus type 1 (HIV-1) are characteristic of group M but not group O HIV-1 strains

In the NL4-3 strain of human immunodeficiency virus type 1 (HIV-1), regulatory elements responsible for the relative efficiencies of alternative splicing at the tat, rev, and the env/nef 3' splice sites (A3 through A5) are contained within the region of tat exon 2 and its flanking sequences. Two elements affecting splicing of tat, rev, and env/nef mRNAs have been localized to this region. First, an exon splicing silencer (ESS2) in NL4-3, located approximately 70 nucleotides downstream from the 3' splice site used to generate tat mRNA, acts specifically to inhibit splicing at this splice site. Second, the A4b 3' splice site, which is the most downstream of the three rev 3' splice sites, also serves as an element inhibiting splicing at the env/nef 3' splice site A5. These elements are conserved in some but not all HIV-1 strains, and the effects of these sequence changes on splicing have been investigated in cell transfection and in vitro splicing assays. SF2, another clade B virus and member of the major (group M) viruses, has several sequence changes within ESS2 and uses a different rev 3' splice site. However, splicing is inhibited by the two elements similarly to NL4-3. As with the NL4-3 strain, the SF2 A4b AG dinucleotide overlaps an A5 branchpoint, and thus the inhibitory effect may result from competition of the same site for two different splicing factors. The sequence changes in ANT70C, a member of the highly divergent outlier (group O) viruses, are more extensive, and ESS2 activity in tat exon 2 is not present. Group O viruses also lack the rev 3' splice site A4b, which is conserved in all group M viruses. Mutagenesis of the most downstream rev 3' splice site of ANT70C does not increase splicing at A5, and all of the branchpoints are upstream of the two rev 3' splice sites. Thus, splicing regulatory elements in tat exon 2 which are characteristic of most group M HIV-1 strains are not present in group O HIV-1 strains.     

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.     

SR proteins and hnRNP H regulate the splicing of the HIV-1 tev-specific exon 6D

A naturally arising point mutation in the env gene of HIV-1 activates the aberrant inclusion of the cryptic exon 6D into most viral messages, leading to inefficient viral replication. We set out to understand how a single nucleotide substitution could cause such a dramatic change in splicing. We have determined that the exon 6D mutation promotes binding of the SR protein SC35 to the exon. Mutant exon 6D sequences function as a splicing enhancer when inserted into an enhancer-dependent splicing construct. hnRNP H family proteins bind to the enhancer as well; their binding is dependent on the sequence GGGA located just downstream of the point mutation and depletion-- reconstitution studies show that hnRNP H is essential for enhancer activity. A polypurine sequence located further downstream in exon 6D binds SR proteins but acts as an exonic splicing silencer. hnRNP H is required for interaction of U1 snRNP with the enhancer, independent of the point mutation. We propose that SC35 binding to the point mutation region may convert the hnRNP H-U1 snRNP complex into a splicing enhancer.     

hnRNP A1 controls HIV-1 mRNA splicing through cooperative binding to intron and exon splicing silencers in the context of a conserved secondary structure

The removal of the second intron in the HIV-1 rev/tat pre-mRNAs, which involves the joining of splice site SD4 to SA7, is inhibited by hnRNP A1 by a mechanism that requires the intronic splicing silencer (ISS) and the exon splicing silencer (ESS3). In this study, we have determined the RNA secondary structure and the hnRNP A1 binding sites within the 3' splice site region by phylogenetic comparison and chemical/enzymatic probing. A biochemical characterization of the RNA/protein complexes demonstrates that hnRNP A1 binds specifically to primarily three sites, the ISS, a novel UAG motif in the exon splicing enhancer (ESE) and the ESS3 element, which are all situated in experimentally supported stem loop structures. A mutational analysis of the ISS region revealed that the core hnRNP A1 binding site directly overlaps with a major branchpoint used in splicing to SA7, thereby providing a direct explanation for the inhibition of U2 snRNP association with the pre-mRNA by hnRNP A1. Binding of hnRNP A1 to the ISS core site is inhibited by RNA structure but strongly stimulated by the exonic silencer, ESS3. Moreover, the ISS also stimulate binding of hnRNP A1 to the exonic splicing regulators ESS3 and the ESE. Our results suggest a model where a network is formed between hnRNP A1 molecules situated at discrete sites in the intron and exon and that these interactions preclude the recognition of essential splicing signals including the branch point.     

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.     

Simian immunodeficiency virus displays complex patterns of RNA splicing.

The human and simian immunodeficiency viruses encode at least six gene products that apparently serve regulatory functions. To evaluate the regulation of simian immunodeficiency virus gene expression at the level of RNA splicing, we used the polymerase chain reaction to amplify and clone cDNAs corresponding to a large array of mRNAs from infected cells. We identified mRNAs that used splice acceptor sites upstream of the initiator codons for tat, rev, vpr, nef, vif, and vpx, suggesting that these proteins may be expressed from different mRNAs. We also provide hybridization data suggesting that the same splice acceptor site may be used for both rev and env mRNAs. Furthermore, we isolated both tat and rev cDNAs that utilized three alternative splice acceptor sites at the start of coding exon 2, indicating that different versions of these proteins may be encoded. Finally, approximately 10 to 20% of simian immunodeficiency virus mRNAs spliced an intron from their untranslated 5' ends, and sequences contained within this intron constituted a portion of the tat-responsive TAR element. Thus, alternative pre-mRNA splicing adds a level of complexity to simian immunodeficiency virus expression, which may affect several levels of gene regulation.     

Alternative splicing of human immunodeficiency virus type 1 mRNA modulates viral protein expression, replication, and infectivity.

Multiple RNA splicing sites exist within human immunodeficiency virus type 1 (HIV-1) genomic RNA, and these sites enable the synthesis of many mRNAs for each of several viral proteins. We evaluated the biological significance of the alternatively spliced mRNA species during productive HIV-1 infections of peripheral blood lymphocytes and human T-cell lines to determine the potential role of alternative RNA splicing in the regulation of HIV-1 replication and infection. First, we used a semiquantitative polymerase chain reaction of cDNAs that were radiolabeled for gel analysis to determine the relative abundance of the diverse array of alternatively spliced HIV-1 mRNAs. The predominant rev, tat, vpr, and env RNAs contained a minimum of noncoding sequence, but the predominant nef mRNAs were incompletely spliced and invariably included noncoding exons. Second, the effect of altered RNA processing was measured following mutagenesis of the major 5' splice donor and several cryptic, constitutive, and competing 3' splice acceptor motifs of HIV-1NL4-3. Mutations that ablated constitutive splice sites led to the activation of new cryptic sites; some of these preserved biological function. Mutations that ablated competing splice acceptor sites caused marked alterations in the pool of virus-derived mRNAs and, in some instances, in virus infectivity and/or the profile of virus proteins. The redundant RNA splicing signals in the HIV-1 genome and alternatively spliced mRNAs provides a mechanism for regulating the relative proportions of HIV-1 proteins and, in some cases, viral infectivity.     

hnRNP A/B proteins are required for inhibition of HIV-1 pre-mRNA splicing.

Splicing of the human immunodeficiency virus type 1 (HIV-1) pre-mRNA must be inefficient to provide a pool of unspliced messages which encode viral proteins and serve as genomes for new virions. Negative cis-regulatory elements (exonic splicing silencers or ESSs) are necessary for HIV-1 splicing inhibition. We demonstrate that heterogeneous nuclear ribonucleoproteins (hnRNPs) of the A and B group are trans-acting factors required for the function of the tat exon 2 ESS. Depletion of hnRNP A/B proteins from HeLa cell nuclear extract activates splicing of tat exon 2 pre-mRNA substrate. Splicing inhibition is restored by addition of recombinant hnRNP A/B proteins to the depleted extract. A high-affinity hnRNP A1-binding sequence can substitute functionally for the ESS in tat exon 2. These results demonstrate that hnRNP A/B proteins are required for repression of HIV-1 splicing.     

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.     

Functional comparison of transactivation by simian immunodeficiency virus from rhesus macaques and human immunodeficiency virus type 1.

Simian immunodeficiency virus from rhesus macaques (SIVmac), like human immunodeficiency virus type 1 (HIV-1), encodes a transactivator (tat) which stimulates long terminal repeat (LTR)-directed gene expression. We performed cotransfection assays of SIVmac and HIV-1 tat constructs with LTR-CAT reporter plasmids. The primary effect of transactivation for both SIVmac and HIV-1 is an increase in LTR-directed mRNA accumulation. The SIVmac tat gene product partially transactivates an HIV-1 LTR, whereas the HIV-1 tat gene product fully transactivates an SIVmac LTR. Significant transactivation is achieved by the product of coding exon 1 of the HIV-1 tat gene; however, inclusion of coding exon 2 results in a further increase in mRNA accumulation. In contrast, coding exon 2 of the SIVmac tat gene is required for significant transactivation. These results imply that the tat proteins of SIVmac and HIV-1 are functionally similar but not interchangeable. In addition, an in vitro-generated mutation in SIVmac tat disrupts splicing at the normal splice acceptor site at the beginning of coding exon 2 and activates a site approximately 15 nucleotides downstream. The product of this splice variant stimulates LTR-directed gene expression. This alternative splice acceptor site is also used by a biologically active provirus with an efficiency of approximately 5% compared with the upstream site. These data suggest that a novel tat protein is encoded during the course of viral infection.     

Binding of equine infectious anemia virus rev to an exon splicing enhancer mediates alternative splicing and nuclear export of viral mRNAs

In addition to facilitating the nuclear export of incompletely spliced viral mRNAs, equine infectious anemia virus (EIAV) Rev regulates alternative splicing of the third exon of the tat/rev mRNA. In the presence of Rev, this exon of the bicistronic RNA is skipped in a fraction of the spliced mRNAs. In this report, the cis-acting requirements for exon 3 usage were correlated with sequences necessary for Rev binding and transport of incompletely spliced RNA. The presence of a purine-rich exon splicing enhancer (ESE) was required for exon 3 recognition, and the addition of Rev inhibited exon 3 splicing. Glutathione-S-transferase (GST)-Rev bound to probes containing the ESE, and mutation of GAA repeats to GCA within the ESE inhibited both exon 3 recognition in RNA splicing experiments and GST-Rev binding in vitro. These results suggest that Rev regulates alternative splicing by binding at or near the ESE to block SR protein-ESE interactions. A 57-nucleotide sequence containing the ESE was sufficient to mediate Rev-dependent nuclear export of incompletely spliced RNAs. Rev export activity was significantly inhibited by mutation of the ESE or by trans-complementation with SF2/ASF. These results indicate that the ESE functions as a Rev-responsive element and demonstrate that EIAV Rev mediates exon 3 exclusion through protein-RNA interactions required for efficient export of incompletely spliced viral RNAs.