Distribution of SR protein exonic splicing enhancer motifs in human protein-coding genes

Exonic splicing enhancers (ESEs) are pre-mRNA cis-acting elements required for splice-site recognition. We previously developed a web-based program called ESEfinder that scores any sequence for the presence of ESE motifs recognized by the human SR proteins SF2/ASF, SRp40, SRp55 and SC35 (http://rulai.cshl.edu/tools/ESE/). Using ESEfinder, we have undertaken a large-scale analysis of ESE motif distribution in human protein-coding genes. Significantly higher frequencies of ESE motifs were observed in constitutive internal protein-coding exons, compared with both their flanking intronic regions and with pseudo exons. Statistical analysis of ESE motif frequency distributions revealed a complex relationship between splice-site strength and increased or decreased frequencies of particular SR protein motifs. Comparison of constitutively and alternatively spliced exons demonstrated slightly weaker splice-site scores, as well as significantly fewer ESE motifs, in the alternatively spliced group. Our results underline the importance of ESE-mediated SR protein function in the process of exon definition, in the context of both constitutive splicing and regulated alternative splicing.     

SR proteins Asf/SF2 and 9G8 interact to activate enhancer-dependent intron D splicing of bovine growth hormone pre-mRNA in vitro

The alternative splicing of the last intron (intron D) of bovine growth hormone (bGH) pre-mRNA requires a down-stream exonic splicing enhancer (FP/ESE). The presence of at least one SR protein has been shown to be essential for FP/ESE function and splicing of intron D in in vitro splicing assays. However, in vitro reconstitution of splicing using individual purified SR proteins may not accurately reflect the true complexity of alternative splicing in an intact nucleus, where multiple SR proteins in varying amounts are likely to be available simultaneously. Here, a panel of recombinant baculovirus-expressed SR proteins was produced and tested for the ability to activate FP/ESE-dependent splicing. Individual recombinant SR proteins differed significantly in their activity in promoting intron D splicing. Among the recombinant SR proteins tested, SRp55 was the most active, SC35 showed very little activity, and ASF/SF2 and 9G8 individually had intermediate activity. At least one SR protein (ASF/SF2) bound to the FP/ESE with characteristics of a cooperative interaction. Most interestingly, low concentrations of ASF/SF2 and 9G8 acted synergistically to activate intron D splicing. This was due in part to synergistic binding to the FP/ESE. Splicing of bGH intron D is inherently complex, and is likely controlled by an interaction of the FP/ESE with several trans-acting protein factors acting both independently and cooperatively. This level of complexity may be required for precise control of alternative splicing by an exon sequence, which simultaneously is constrained to maintain translational integrity of the mature mRNA.     

Interactions among SR proteins, an exonic splicing enhancer, and a lentivirus Rev protein regulate alternative splicing.

We examine here the roles of cellular splicing factors and virus regulatory proteins in coordinately regulating alternative splicing of the tat/rev mRNA of equine infectious anemia virus (EIAV). This bicistronic mRNA contains four exons; exons 1 and 2 encode Tat, and exons 3 and 4 encode Rev. In the absence of Rev expression, the four-exon mRNA is synthesized exclusively, but when Rev is expressed, exon 3 is skipped to produce an mRNA that contains only exons 1, 2, and 4. We identify a purine-rich exonic splicing enhancer (ESE) in exon 3 that promotes exon inclusion. Similar to other cellular ESEs that have been identified by other laboratories, the EIAV ESE interacted specifically with SR proteins, a group of serine/arginine-rich splicing factors that function in constitutive and alternative mRNA splicing. Substitution of purines with pyrimidines in the ESE resulted in a switch from exon inclusion to exon skipping in vivo and abolished binding of SR proteins in vitro. Exon skipping was also induced by expression of EIAV Rev. We show that Rev binds to exon 3 RNA in vitro, and while the precise determinants have not been mapped, Rev function in vivo and RNA binding in vitro indicate that the RNA element necessary for Rev responsiveness overlaps or is adjacent to the ESE. We suggest that EIAV Rev promotes exon skipping by interfering with SR protein interactions with RNA or with other splicing factors.     

Multiple interactions between SRm160 and SR family proteins in enhancer-dependent splicing and development of C. elegans

BACKGROUND: SR family and SR-related proteins assemble on exonic splicing enhancer (ESE) sequences to promote both constitutive and regulated splicing. The SRm160 splicing coactivator, an SR-related nuclear matrix protein of 160 kDa, is important for the splicing of specific constitutive and ESE-dependent pre-mRNAs. RESULTS: In the present study, we show that SRm160 is required to promote pre-mRNA splicing mediated by a large population of functional ESE sequences within a randomized 18 nucleotide sequence. This suggests that it functions as a general coactivator by interacting with different SR family/SR-related proteins bound to different ESE sequences. Consistent with this, several SR family and SR-related proteins coimmunoprecipitated specifically with SRm160 in the presence of low salt. We used RNA interference (RNAi) in Caenorhabditis elegans to determine whether interactions between CeSRm160 and different CeSR family proteins are important in a whole-organism context. Previously we showed that RNAi of CeSRm160 and individual CeSR family genes other than CeSF2/ASF results in no obvious phenotype, which is indicative of gene redundancy. In the present study, we demonstrate that RNAi of CeSRm160 in combination with any CeSR family gene results in the production of unfertilized oocytes by the injected mother. CONCLUSIONS: The observation that simultaneous suppression of CeSRm160 and individual CeSR family proteins results in a distinct phenotype is indicative of critical functional interactions between these factors. Our results provide biochemical and genetic evidence indicating that interactions between SRm160 and multiple SR family proteins are important for both optimal splicing activity and for proper development.     

Factors associated with a purine-rich exonic splicing enhancer sequence in Xenopus oocyte nucleus

Purine-rich exonic splicing enhancers (ESEs) stimulate splicing of the adjacent introns with suboptimal splice sites. To elucidate the mechanism regarding ESEs, factors specifically associated with ESEs in HeLa cell nuclear extracts were previously investigated, and shown to include SR (serine/arginine-rich) proteins. However, factors associated with ESEs in vivo have not yet been explored. Here we show that a GAA repeat RNA sequence, a typical ESE, is associated in Xenopus oocyte nuclei with at least one SR protein, SF2/ASF, as was expected. Moreover, components of SF3a/b complexes, U2 snRNA, and U2AF(65) were also found to be associated with the ESE in the nucleus. Since SF3a/b complexes are the constituents of the 17S U2 snRNP, these results suggest that the 17S U2 snRNP is associated with the ESE in the nucleus, probably through bridging interactions of U2AF and SR proteins. The identified factors may represent a functional splicing enhancer complex in vivo.     

TIA proteins are necessary but not sufficient for the tissue-specific splicing of the myosin phosphatase targeting subunit 1

We are using the tissue-specific splicing of myosin phosphatase targeting subunit (MYPT1) as a model to investigate smooth muscle phenotypic diversity. We previously identified a U-rich intronic enhancer flanking the 5' splice site (IE1), and a bipartite exonic enhancer/suppressor, that regulate splicing of the MYPT1 central alternative exon. Here we show that T-cell inhibitor of apoptosis (TIA-1) and T-cell inhibitor of apoptosis-related (TIAR) proteins bind to the IE1. Co-transfection of TIA expression vectors with a MYPT1 mini-gene construct increase splicing of the central alternative exon. TIA proteins do not enhance splicing when the palindromic exonic splicing enhancer (ESE) is mutated, indicating that TIAs are necessary but not sufficient for splicing. The ESE specifically binds SRp55 and SRp20 proteins, supporting a model in which both SR and TIA proteins binding to their cis-elements are required for the recruitment of the splicing complex to a weak 5' splice site. Inactivation of TIA proteins in the DT40 cell line (TIA-1(-/-)TIAR(+/-)) reduced the splicing of the central alternative exon of the endogenous MYPT1 as well as stably transfected MYPT1 minigene constructs. Splicing of the MYPT1 3' alternative exon and the MLC(17) alternative exon were unaffected, suggesting that TIA proteins regulate a subset of smooth muscle/nonmuscle alternative splicing reactions. Finally, reduced RNA binding and reduced expression of the TIA and SR proteins in phasic (gizzard) smooth muscle around hatching coincided with the switch from exon inclusion to exon skipping, suggesting that loss of TIA and SR enhancer activity may play a role in the developmental switch in MYPT1 splicing.     

Distinct factor requirements for exonic splicing enhancer function and binding of U2AF to the polypyrimidine tract

Exonic splicing enhancer (ESE) sequences are important for the recognition of adjacent splice sites in pre-mRNA and for the regulation of splice site selection. It has been proposed that ESEs function by associating with one or more serine/arginine-repeat (SR) proteins which stabilize the binding of the U2 small nuclear ribonucleoprotein particle (snRNP) auxiliary factor (U2AF) to the polypyrimidine tract upstream of the 3' splice site. We have tested this model by analyzing the composition of splicing complexes assembled on an ESE-dependent pre-mRNA derived from the doublesex gene of Drosophila. Several SR proteins and hTra2beta, a human homolog of the Drosophila alternative splicing regulator Transformer-2, associate with this pre-mRNA in the presence, but not in the absence, of a purine-rich ESE. By contrast, the 65-kDa subunit of U2AF (U2AF-65 kDa) bound equally to the pre-mRNA in the presence and absence of the ESE. Time course experiments revealed differences in the levels and kinetics of association of individual SR proteins with the ESE-containing pre-mRNA, whereas U2AF-65 kDa bound prior to most SR proteins and hTra2beta and its level of binding did not change significantly during the course of the splicing reaction. Binding of U2AF-65 kDa to the ESE-dependent pre-mRNA was, however, dependent on U1 snRNP. The results indicate that an ESE promotes spliceosome formation through interactions that are distinct from those required for the binding of U2AF-65 kDa to the polypyrimidine tract.     

ESEfinder: A web resource to identify exonic splicing enhancers

Point mutations frequently cause genetic diseases by disrupting the correct pattern of pre-mRNA splicing. The effect of a point mutation within a coding sequence is traditionally attributed to the deduced change in the corresponding amino acid. However, some point mutations can have much more severe effects on the structure of the encoded protein, for example when they inactivate an exonic splicing enhancer (ESE), thereby resulting in exon skipping. ESEs also appear to be especially important in exons that normally undergo alternative splicing. Different classes of ESE consensus motifs have been described, but they are not always easily identified. ESEfinder (http://exon.cshl.edu/ESE/) is a web-based resource that facilitates rapid analysis of exon sequences to identify putative ESEs responsive to the human SR proteins SF2/ASF, SC35, SRp40 and SRp55, and to predict whether exonic mutations disrupt such elements.     

A pathway of sequential arginine-serine-rich domain-splicing signal interactions during mammalian spliceosome assembly

Serine-arginine (SR) proteins are general splicing factors and can function through binding to exonic splicing enhancers (ESEs). SR proteins and several other mammalian splicing factors contain an arginine-serine-rich (RS) domain required to promote splicing. We have recently found that the ESE bound RS domain functions by contacting the branchpoint. Here, we perform RNA-protein crosslinking experiments to show that the branchpoint is sequentially contacted first in complex E by the RS domain of the essential splicing factor U2AF(65) and then in the prespliceosome by the ESE bound RS domain. Although the ESE bound RS domain can promote formation of the prespliceosome, at least one additional SR protein is required for complete spliceosome assembly. We show that the RS domain of this additional SR protein contacts the 5' splice site specifically in the mature spliceosome. We propose that direct contact with splicing signals is a general mechanism by which RS domains promote splicing.     

Distribution of exonic splicing enhancer elements in human genes

Ab initio prediction of functional exon splicing enhancer (ESE) elements based on RNA sequences present a challenge in the evaluation of the functional impacts of human genetic polymorphisms on splicing. To better understand the behavior of ESEs, we studied their distribution in human exons and introns for four known SR protein-binding motifs: SF2/SAF, SC35, SRp40, and SRp55. ESEs are enriched in regions in exons that are close to the splice sites, especially in the region 80 to 120 bases away from the ends of splice acceptor sites. Significant enrichment of ESEs is associated with weak splice acceptor sites but not weak donor sites. ESE density decreases at the 3 ends of long exons. ESEs are also enriched in introns with weak donor or acceptor sites. These characteristics of ESEs may help to predict functional ESE sites in RNA sequences.     

Exon identity established through differential antagonism between exonic splicing silencer-bound hnRNP A1 and enhancer-bound SR proteins.

SR proteins recognize exonic splicing enhancer (ESE) elements and promote exon use, whereas certain hnRNP proteins bind to exonic splicing silencer (ESS) elements and block exon recognition. We investigated how ESS3 in HIV-1 tat exon 3 blocks splicing promoted by one SR protein (SC35) but not another (SF2/ASF). hnRNP A1 mediates silencing by binding initially to a required high-affinity site in ESS3, which then promotes further hnRNP A1 association with the upstream region of the exon. Both SC35 and SF2/ASF recognize upstream ESE motifs, but only SF2/ASF prevents secondary hnRNP A1 binding, presumably by blocking its cooperative propagation along the exon. The differential antagonism between a negative and two positive regulators exemplifies how inclusion of an alternative exon can be modulated.     

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.