Long- and Short-Range Electrostatic Fields in GFP Mutants: Implications for Spectral Tuning.

The majority of protein functions are governed by their internal local electrostatics. Quantitative information about these interactions can shed light on how proteins work and allow for improving/altering their performance. Green fluorescent protein (GFP) and its mutation variants provide unique optical windows for interrogation of internal electric fields, thanks to the intrinsic fluorophore group formed inside them. Here we use an all-optical method, based on the independent measurements of transition frequency and one- and two-photon absorption cross sections in a number of GFP mutants to evaluate these internal electric fields. Two physical models based on the quadratic Stark effect, either with or without taking into account structural (bond-length) changes of the chromophore in varying field, allow us to separately evaluate the long-range and the total effective (short- and long-range) fields. Both types of the field quantitatively agree with the results of independent molecular dynamic simulations, justifying our method of measurement.

Transcriptional and posttranscriptional regulation of HIV-1 gene expression.

Control of HIV-1 gene expression depends on two viral regulatory proteins, Tat and Rev. Tat stimulates transcription elongation by directing the cellular transcriptional elongation factor P-TEFb to nascent RNA polymerases. Rev is required for the transport from the nucleus to the cytoplasm of the unspliced and incompletely spliced mRNAs that encode the structural proteins of the virus. Molecular studies of both proteins have revealed how they interact with the cellular machinery to control transcription from the viral LTR and regulate the levels of spliced and unspliced mRNAs. The regulatory feedback mechanisms driven by HIV-1 Tat and Rev ensure that HIV-1 transcription proceeds through distinct phases. In cells that are not fully activated, limiting levels of Tat and Rev act as potent blocks to premature virus production.

Excessive RNA splicing and inhibition of HIV-1 replication induced by modified U1 small nuclear RNAs.

HIV-1 RNA undergoes a complex splicing process whereby over 40 different mRNA species are produced by alternative splicing. In addition, approximately half of the RNA transcripts remain unspliced and either are used to encode Gag and Gag-Pol proteins or are packaged into virions as genomic RNA. It has previously been shown that HIV-1 splicing is regulated by cis elements that bind to cellular factors. These factors either enhance or repress definition of exons that are flanked by the HIV-1 3' splice sites. Here we report that expression of modified U1 snRNPs with increased affinity to HIV-1 downstream 5' splice sites and to sequences within the first tat coding exon act to selectively increase splicing at the upstream 3' splice sites in cotransfected 293T cells. This results in a decrease of unspliced viral RNA levels and an approximately 10-fold decrease in virus production. In addition, excessive splicing of viral RNA is concomitant with a striking reduction in the relative amounts of Gag processing intermediates and products. We also show that T cell lines expressing modified U1 snRNAs exhibit reduced HIV-1 replication. Our results suggest that induction of excessive HIV-1 RNA splicing may be a novel strategy to inhibit virus replication in human patients.

Chapter 1. Regulation of HIV-1 alternative RNA splicing and its role in virus replication.

Over 40 different human immunodeficiency virus type 1 (HIV-1) mRNA species, both completely and incompletely spliced, are produced by alternative splicing of the primary viral RNA transcript. In addition, about half of the viral RNA remains unspliced and is transported to the cytoplasm where it is used both as mRNA and as genomic RNA. In general, the identities of the completely and incompletely spliced HIV-1 mRNA species are determined by the proximity of the open reading frames to the 5'-end of the mRNAs. The relative abundance of the mRNAs encoding the HIV-1 gene products is determined by the frequency of splicing at the different alternative 3'-splice sites. This chapter will highlight studies showing how HIV-1 uses exon definition to control the level of splicing at each of its 3'-splice sites through a combination of positively acting exonic splicing enhancer (ESE) elements, negatively acting exonic and intronic splicing silencer elements (ESS and ISS elements, respectively), and the 5'-splice sites of the regulated exons. Each of these splicing elements represent binding sites for cellular factors whose levels in the infected cell can determine the dominance of the positive or negative elements on HIV-1 alternative splicing. Both mutations of HIV-1 splicing elements and overexpression or inhibition of cellular splicing factors that bind to these elements have been used to show that disruption of regulated splicing inhibits HIV-1 replication. These studies have provided strong rationale for the investigation and development of antiviral drugs that specifically inhibit HIV-1 RNA splicing.

Regulation of Vif mRNA splicing by human immunodeficiency virus type 1 requires 5' splice site D2 and an exonic splicing enhancer to counteract cellular restriction factor APOBEC3G.

The human immunodeficiency virus type 1 (HIV-1) accessory protein Vif is encoded by an incompletely spliced mRNA resulting from splicing of the major splice donor in the HIV-1 genome, 5' splice site (5'ss) D1, to the first splice acceptor, 3'ss A1. We have shown previously that splicing of HIV-1 vif mRNA is tightly regulated by suboptimal 5'ss D2, which is 50 nucleotides downstream of 3'ss A1; a GGGG silencer motif proximal to 5'ss D2; and an SRp75-dependent exonic splicing enhancer (ESEVif). In agreement with the exon definition hypothesis, mutations within 5'ss D2 that are predicted to increase or decrease U1 snRNP binding affinity increase or decrease the usage of 3'ss A1 (D2-up and D2-down mutants, respectively). In this report, the importance of 5'ss D2 and ESEVif for avoiding restriction of HIV-1 by APOBEC3G (A3G) was determined by testing the infectivities of a panel of mutant viruses expressing different levels of Vif. The replication of D2-down and ESEVif mutants in permissive CEM-SS cells was not significantly different from that of wild-type HIV-1. Mutants that expressed Vif in 293T cells at levels greater than 10% of that of the wild type replicated similarly to the wild type in H9 cells, and Vif levels as low as 4% were affected only modestly in H9 cells. This is in contrast to Vif-deleted HIV-1, whose replication in H9 cells was completely inhibited. To test whether elevated levels of A3G inhibit replication of D2-down and ESEVif mutants relative to wild-type virus replication, a Tet-off Jurkat T-cell line that expressed approximately 15-fold-higher levels of A3G than control Tet-off cells was generated. Under these conditions, the fitness of all D2-down mutant viruses was reduced relative to that of wild-type HIV-1, and the extent of inhibition was correlated with the level of Vif expression. The replication of an ESEVif mutant was also inhibited only at higher levels of A3G. Thus, wild-type 5'ss D2 and ESEVif are required for production of sufficient Vif to allow efficient HIV-1 replication in cells expressing relatively high levels of A3G.

HIV-1 infection induces changes in expression of cellular splicing factors that regulate alternative viral splicing and virus production in macrophages.

BACKGROUND: Macrophages are important targets and long-lived reservoirs of HIV-1, which are not cleared of infection by currently available treatments. In the primary monocyte-derived macrophage model of infection, replication is initially productive followed by a decline in virion output over ensuing weeks, coincident with a decrease in the levels of the essential viral transactivator protein Tat. We investigated two possible mechanisms in macrophages for regulation of viral replication, which appears to be primarily regulated at the level of tat mRNA: 1) differential mRNA stability, used by cells and some viruses for the rapid regulation of gene expression and 2) control of HIV-1 alternative splicing, which is essential for optimal viral replication. RESULTS: Following termination of transcription at increasing times after infection in macrophages, we found that tat mRNA did indeed decay more rapidly than rev or nef mRNA, but with similar kinetics throughout infection. In addition, tat mRNA decayed at least as rapidly in peripheral blood lymphocytes. Expression of cellular splicing factors in uninfected and infected macrophage cultures from the same donor showed an inverse pattern over time between enhancing factors (members of the SR family of RNA binding proteins) and inhibitory factors (members of the hnRNP family). While levels of the SR protein SC35 were greatly up-regulated in the first week or two after infection, hnRNPs of the A/B and H groups were down-regulated. Around the peak of virus production in each culture, SC35 expression declined to levels in uninfected cells or lower, while the hnRNPs increased to control levels or above. We also found evidence for increased cytoplasmic expression of SC35 following long-term infection. CONCLUSION: While no evidence of differential regulation of tat mRNA decay was found in macrophages following HIV-1 infection, changes in the balance of cellular splicing factors which regulate alternative viral pre-mRNA splicing were observed. These changes correlated with changes in Tat expression and virus production and could play an important role in viral persistence in macrophages. This mechanism could provide a novel target for control of infection in this critical cell type, which would be necessary for eventual eradication of the virus from infected individuals.

Negative and positive mRNA splicing elements act competitively to regulate human immunodeficiency virus type 1 vif gene expression.

Over 40 different human immunodeficiency virus type 1 (HIV-1) mRNAs are produced by alternative splicing of the primary HIV-1 RNA transcripts. In addition, approximately half of the viral RNA remains unspliced and is used as genomic RNA and as mRNA for the Gag and Pol gene products. Regulation of splicing at the HIV-1 3' splice sites (3'ss) requires suboptimal polypyrimidine tracts, and positive or negative regulation occurs through the binding of cellular factors to cis-acting splicing regulatory elements. We have previously shown that splicing at HIV-1 3'ss A1, which produces single-spliced vif mRNA and promotes the inclusion of HIV exon 2 into both completely and incompletely spliced viral mRNAs, is increased by optimizing the 5' splice site (5'ss) downstream of exon 2 (5'ss D2). Here we show that the mutations within 5'ss D2 that are predicted to lower or increase the affinity of the 5'ss for U1 snRNP result in reduced or increased Vif expression, respectively. Splicing at 5'ss D2 was not necessary for the effect of 5'ss D2 on Vif expression. In addition, we have found that mutations of the GGGG motif proximal to the 5'ss D2 increase exon 2 inclusion and Vif expression. Finally, we report the presence of a novel exonic splicing enhancer (ESE) element within the 5'-proximal region of exon 2 that facilitates both exon inclusion and Vif expression. This ESE binds specifically to the cellular SR protein SRp75. Our results suggest that the 5'ss D2, the proximal GGGG silencer, and the ESE act competitively to determine the level of vif mRNA splicing and Vif expression. We propose that these positive and negative splicing elements act together to allow the accumulation of vif mRNA and unspliced HIV-1 mRNA, compatible with optimal virus replication.

Gag-processing defect of human immunodeficiency virus type 1 integrase E246 and G247 mutants is caused by activation of an overlapping 5' splice site.

We have previously described several human immunodeficiency virus type 1 (HIV-1) mutants that are characterized by an excessive-RNA-splicing phenotype and reduced virus particle production. In one of these mutants (NLD2up), the sequence of 5' splice site D2 was changed to a consensus splice donor site. This splice site overlaps the HIV-1 integrase reading frame, and thus, the NLD2up mutant also bears a G-to-W change at amino acid 247 of the integrase. A previously described E-to-K mutant at position 246 of the C-terminal domain of the integrase, which resulted in a G-to-A mutation at the +3 position of overlapping splice donor D2 (NLD2A3), was also shown to affect virus particle production and Gag protein processing. By using second-site mutations to revert the excessive-splicing phenotype, we show that the effects on Gag protein processing and virus particle production of both the NLD2up and NLD2A3 mutants are caused by excessive viral RNA splicing due to the activation of the overlapping 5' splice site and not to the changes in the integrase protein. Both integrase protein mutations, however, are lethal for virus infectivity. These studies suggest that changes in the usage of overlapping splice sites may be a possible alternative explanation for a defective virus phenotype resulting from changes in protein-coding sequences or in the nucleotide sequence during codon optimization.

A suboptimal 5' splice site downstream of HIV-1 splice site A1 is required for unspliced viral mRNA accumulation and efficient virus replication.

BACKGROUND: Inefficient alternative splicing of the human immunodeficiency virus type 1(HIV-1) primary RNA transcript results in greater than half of all viral mRNA remaining unspliced. Regulation of HIV-1 alternative splicing occurs through the presence of suboptimal viral 5' and 3' splice sites (5' and 3'ss), which are positively regulated by exonic splicing enhancers (ESE) and negatively regulated by exonic splicing silencers (ESS) and intronic splicing silencers (ISS). We previously showed that splicing at HIV-1 3'ss A2 is repressed by ESSV and enhanced by the downstream 5'ss D3 signal. Disruption of ESSV results in increased vpr mRNA accumulation and exon 3 inclusion, decreased accumulation of unspliced viral mRNA, and decreased virus production. RESULTS: Here we show that optimization of the 5'ss D2 signal results in increased splicing at the upstream 3'ss A1, increased inclusion of exon 2 into viral mRNA, decreased accumulation of unspliced viral mRNA, and decreased virus production. Virus production from the 5'ss D2 and ESSV mutants was rescued by transient expression of HIV-1 Gag and Pol. We further show that the increased inclusion of either exon 2 or 3 does not significantly affect the stability of viral mRNA but does result in an increase and decrease, respectively, in HIV-1 mRNA levels. The changes in viral mRNA levels directly correlate with changes in tat mRNA levels observed upon increased inclusion of exon 2 or 3. CONCLUSION: These results demonstrate that splicing at HIV-1 3'ss A1 is regulated by the strength of the downstream 5'ss signal and that suboptimal splicing at 3'ss A1 is necessary for virus replication. Furthermore, the replication defective phenotype resulting from increased splicing at 3'ss A1 is similar to the phenotype observed upon increased splicing at 3'ss A2. Further examination of the role of 5'ss D2 and D3 in the alternative splicing of 3'ss A1 and A2, respectively, is necessary to delineate a role for non-coding exon inclusion in HIV-1 replication.

Role of viral splicing elements and cellular RNA binding proteins in regulation of HIV-1 alternative RNA splicing.

In HIV-1 infected cells, over 40 different mRNA species are produced by alternative splicing of the single HIV-1 primary RNA transcript. In addition, approximately half of the HIV-1 primary RNA transcripts are not spliced and are exported to the cytoplasm where they serve as mRNA and as genomic RNA. In this article, we will review current knowledge of the mechanisms by which the HIV-1 alternative splicing is regulated. Several negatively and positively-acting cis-acting elements have been detected within the viral genome that repress or facilitate viral RNA splicing by binding to cellular proteins. These include exonic splicing silencers (ESS) and an intronic splicing silencer (ISS) that are selectively bound either by members of the hnRNP A/B family (hnRNPs A1, A1(B), A2, and B1) or by hnRNP H. Exonic splicing enhancers (ESE) are also present within the HIV-1 genome and are selectively bound by members of the SR protein family. ESS and ISS repression mediated by hnRNP A/B proteins occurs at early steps of splicing, prior to formation of pre-spliceosome complexes. Current models propose that ESS elements promote cooperative binding of hnRNP A/B proteins to the exon and prevent efficient binding of essential cellular splicing factors to the 3' splice site. SR proteins bound to ESE elements that are juxtaposed or overlapping ESS elements may counteract this inhibition. We will review data indicating the importance of the HIV-1 splicing elements and their cognate binding proteins for efficient virus replication. Differences in cis-acting splicing elements between the group M (major) and group O (outlier) HIV-1 strains will also be discussed. Finally we will review evidence suggesting the possibility that there may be changes in regulation of HIV-1 alternative splicing in infected human T cells, human macrophages and rodent cells.

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.

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.

RNA splicing at human immunodeficiency virus type 1 3' splice site A2 is regulated by binding of hnRNP A/B proteins to an exonic splicing silencer element.

The synthesis of human immunodeficiency virus type 1 (HIV-1) mRNAs is a complex process by which more than 30 different mRNA species are produced by alternative splicing of a single primary RNA transcript. HIV-1 splice sites are used with significantly different efficiencies, resulting in different levels of mRNA species in infected cells. Splicing of Tat mRNA, which is present at relatively low levels in infected cells, is repressed by the presence of exonic splicing silencers (ESS) within the two tat coding exons (ESS2 and ESS3). These ESS elements contain the consensus sequence PyUAG. Here we show that the efficiency of splicing at 3' splice site A2, which is used to generate Vpr mRNA, is also regulated by the presence of an ESS (ESSV), which has sequence homology to ESS2 and ESS3. Mutagenesis of the three PyUAG motifs within ESSV increases splicing at splice site A2, resulting in increased Vpr mRNA levels and reduced skipping of the noncoding exon flanked by A2 and D3. The increase in Vpr mRNA levels and the reduced skipping also occur when splice site D3 is mutated toward the consensus sequence. By in vitro splicing assays, we show that ESSV represses splicing when placed downstream of a heterologous splice site. A1, A1(B), A2, and B1 hnRNPs preferentially bind to ESSV RNA compared to ESSV mutant RNA. Each of these proteins, when added back to HeLa cell nuclear extracts depleted of ESSV-binding factors, is able to restore splicing repression. The results suggest that coordinate repression of HIV-1 RNA splicing is mediated by members of the hnRNP A/B protein family.

A second exon splicing silencer within human immunodeficiency virus type 1 tat exon 2 represses splicing of Tat mRNA and binds protein hnRNP H.

An equilibrium between spliced and unspliced primary transcripts is essential for retrovirus multiplication. This equilibrium is maintained by the presence of inefficient splice sites. The A3 3'-splice site of human immunodeficiency virus type I (HIV-1) is required for Tat mRNA production. The infrequent utilization of this splice site has been attributed to the presence of a suboptimal polypyrimidine tract and an exonic splicing silencer (ESS2) in tat exon 2 approximately 60 nucleotides downstream of 3'-splice site A3. Here, using site-directed mutagenesis followed by analysis of splicing in vitro and in HeLa cells, we show that the 5' extremity of tat exon 2 contains a second exonic splicing silencer (ESS2p), which acts to repress splice site A3. The inhibitory property of this exonic silencer was active when inserted downstream of another HIV-1 3'-splice site (A2). Protein hnRNP H binds to this inhibitory element, and two U-to-C substitutions within the ESS2p element cause a decreased hnRNP H affinity with a concomitant increase in splicing efficiency at 3'-splice site A3. This suggests that hnRNP H is directly involved in splicing inhibition. We propose that hnRNP H binds to the HIV-1 ESS2p element and competes with U2AF(35) for binding to the exon sequence flanking 3'-splice site A3. This binding results in the inhibition of splicing at 3'-splice site A3.

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.

Conserved stem-loop structures in the HIV-1 RNA region containing the A3 3' splice site and its cis-regulatory element: possible involvement in RNA splicing.

The HIV-1 transcript is alternatively spliced to over 30 different mRNAs. Whether RNA secondary structure can influence HIV-1 RNA alternative splicing has not previously been examined. Here we have determined the secondary structure of the HIV-1/BRU RNA segment, containing the alternative A3, A4a, A4b, A4c and A5 3' splice sites. Site A3, required for tat mRNA production, is contained in the terminal loop of a stem-loop structure (SLS2), which is highly conserved in HIV-1 and related SIVcpz strains. The exon splicing silencer (ESS2) acting on site A3 is located in a long irregular stem-loop structure (SLS3). Two SLS3 domains were protected by nuclear components under splicing condition assays. One contains the A4c branch points and a putative SR protein binding site. The other one is adjacent to ESS2. Unexpectedly, only the 3' A residue of ESS2 was protected. The suboptimal A3 polypyrimidine tract (PPT) is base paired. Using site-directed mutagenesis and transfection of a mini-HIV-1 cDNA into HeLa cells, we found that, in a wild-type PPT context, a mutation of the A3 downstream sequence that reinforced SLS2 stability decreased site A3 utilization. This was not the case with an optimized PPT. Hence, sequence and secondary structure of the PPT may cooperate in limiting site A3 utilization.

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.

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.

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.

Overlapping cis sites used for splicing of HIV-1 env/nef and rev mRNAs.

Alternative splicing is used to generate more than 30 human immunodeficiency virus type 1 (HIV-1) spliced and unspliced mRNAs from a single primary transcript. The abundance of HIV-1 mRNAs is determined by the efficiencies with which its different 5' and 3' splice sites are used. Three splice sites (A4c, A4a, and A4b) are upstream of the rev initiator AUG. RNAs spliced at A4c, A4a, and A4b are used as mRNAs for Rev. Another 3' splice site (A5) is immediately downstream of the rev initiator. RNAs spliced at A5 are used as mRNAs for Env and Nef. In this report, primer extension analysis of splicing intermediates was used to show that there are eight branch points in this region, all of which map to adenosine residues. In addition, cis elements recognized by the cellular splicing machinery overlap; the two most 3' branch points overlap with the AG dinucleotides at rev 3' splice sites A4a and A4b. Competition of the overlapping cis sites for different splicing factors may play a role in maintaining the appropriate balance of mRNAs in HIV-1-infected cells. In support of this possibility, mutations at rev 3' splice site A4b AG dinucleotide dramatically increased splicing of the env/nef 3' splice site A5. This correlated with increased usage of the four most 3' branch points, which include those within the rev 3' splice site AG dinucleotides. Consistent with these results, analysis of a mutant in which three of the four env/nef branch points were inactivated indicated that use of splice site A5 was inhibited and splicing was shifted predominantly to the most 5' rev 3' splice site A4c with preferential use of the two most 5' branch points. Our results suggest that spliceosomes formed at rev A4a-4b, rev A4c, and env/nef A5 3' splice sites each recognize different subsets of the eight branch point sequences.