Prp16p, Slu7p, and Prp8p interact with the 3' splice site in two distinct stages during the second catalytic step of pre-mRNA splicing.

For the second catalytic step of pre-mRNA splicing to occur, a 3' splice site must be selected and juxtaposed with the 5' exon. Four proteins, Prp16p, Slu7p, Prp17p, Prp18p, and an integral spliceosomal protein, Prp8p, are known to be required for the second catalytic step. prp8-101, an allele of PRP8 defective in 3' splice site recognition, exhibits specific genetic interactions with mutant alleles of the other second step splicing factors. The prp8-101 mutation also results in decreased crosslinking of Prp8p to the 3' splice site. To determine the role of the step-two-specific proteins in 3' splice site recognition and in binding of Prp8p to the 3' splice site, we performed crosslinking studies in mutant and immunodepleted extracts. Our results suggest an ordered pathway in which, after the first catalytic step, Prp16p crosslinks strongly to the 3' splice site and Prp8p and Slu7p crosslink weakly. ATP hydrolysis by Prp16p affects a conformational change that reduces the crosslinking of Prp16p with the 3' splice site and allows stronger crosslinking of Prp8p and Slu7p. Thus, the 3' splice site appears to be recognized in two stages during the second step of splicing. Strong 3' splice site crosslinking of Prp8p and Slu7p also requires the functions of Prp17p and Prp18p. Therefore, Prp8p and Slu7p interact with the 3' splice site at the latest stage of splicing prior to the second catalytic step that can currently be defined, and may be at the active site.     

Secondary structure is required for 3' splice site recognition in yeast

Higher order RNA structures can mask splicing signals, loop out exons, or constitute riboswitches all of which contributes to the complexity of splicing regulation. We identified a G to A substitution between branch point (BP) and 3' splice site (3'ss) of Saccharomyces cerevisiae COF1 intron, which dramatically impaired its splicing. RNA structure prediction and in-line probing showed that this mutation disrupted a stem in the BP-3'ss region. Analyses of various COF1 intron modifications revealed that the secondary structure brought about the reduction of BP to 3'ss distance and masked potential 3'ss. We demonstrated the same structural requisite for the splicing of UBC13 intron. Moreover, RNAfold predicted stable structures for almost all distant BP introns in S. cerevisiae and for selected examples in several other Saccharomycotina species. The employment of intramolecular structure to localize 3'ss for the second splicing step suggests the existence of pre-mRNA structure-based mechanism of 3'ss recognition.     

Molecular recognition in a trans excision-splicing ribozyme: non-Watson-Crick base pairs at the 5' splice site and omegaG at the 3' splice site can play a role in determining the binding register of reaction substrates

Trans excision-splicing (TES) ribozymes, derived from a Pneumocystis carinii group I intron, can catalyze the excision of targeted sequences from within RNAs. In this report, the sequence requirements of the splice sites are analyzed. These conserved sequences include a u-G wobble pair at the 5' splice site and a guanosine in the omega position at the 3' splice site (in the substrate). We report that 7 out of 16 base pair combinations at the 5' splice site produce appreciable TES product. This promiscuity is in contrast to results reported for analogous self-splicing reactions using a Tetrahymena ribozyme. At long reaction times TES products dissociate and rebind free ribozyme, at which point product degradation occurs via the 5' cleavage reaction. Unexpectedly, only in cases where Watson-Crick base pairs form at the 5'splice site do we see degradation of TES products at cryptic sites, suggesting that non-Watson-Crick base pairs at the 5' splice site are acting in concert with other factors to precisely determine the binding register of TES reaction substrates within the ribozyme. Moreover, cryptic site degradation does not occur with the corresponding reaction substrates, which additionally contain omegaG, suggesting that omegaG can play a similar role. We report that omegaG cannot be replaced by any other base, so TES substrates require a guanosine as the last (or only) base to be excised. Additionally, we demonstrate that P9.0 and P10 are expendable for TES reactions, suggesting that omegaG is sufficient as a 3' molecular recognition element.     

Identification of alternative 5'/3' splice sites based on the mechanism of splice site competition

Alternative splicing plays an important role in regulating gene expression. Currently, most efficient methods use expressed sequence tags or microarray analysis for large-scale detection of alternative splicing. However, it is difficult to detect all alternative splice events with them because of their inherent limitations. Previous computational methods for alternative splicing prediction could only predict particular kinds of alternative splice events. Thus, it would be highly desirable to predict alternative 5'/3' splice sites with various splicing levels using genomic sequences alone. Here, we introduce the competition mechanism of splice sites selection into alternative splice site prediction. This approach allows us to predict not only rarely used but also frequently used alternative splice sites. On a dataset extracted from the AltSplice database, our method correctly classified approximately 70% of the splice sites into alternative and constitutive, as well as approximately 80% of the locations of real competitors for alternative splice sites. It outperforms a method which only considers features extracted from the splice sites themselves. Furthermore, this approach can also predict the changes in activation level arising from mutations in flanking cryptic splice sites of a given splice site. Our approach might be useful for studying alternative splicing in both computational and molecular biology.     

Switch in 3' splice site recognition between exon definition and splicing catalysis is important for sex-lethal autoregulation

Maintenance of female sexual identity in Drosophila melanogaster involves an autoregulatory loop in which the protein Sex-lethal (SXL) promotes skipping of exon 3 from its own pre-mRNA. We have used transient transfection of Drosophila Schneider cells to analyze the role of exon 3 splice sites in regulation. Our results indicate that exon 3 repression requires competition between the 5' splice sites of exons 2 and 3 but is independent of their relative strength. Two 3' splice site AG's precede exon 3. We report here that, while the distal site plays a critical role in defining the exon, the proximal site is preferentially used for the actual splicing reaction, arguing for a switch in 3' splice site recognition between exon definition and splicing catalysis. Remarkably, the presence of the two 3' splice sites is important for the efficient regulation by SXL, suggesting that SXL interferes with molecular events occurring between initial splice site communication across the exon and the splice site pairing that leads to intron removal.     

3' splice site recognition in nematode trans-splicing involves enhancer-dependent recruitment of U2 snRNP.

Trans-splicing requires that 5' and 3' splice sites be independently recognized. Here, we have used mutational analyses and a sensitive nuclease protection assay to determine the mechanism of trans-3' splice site recognition in vitro. Efficient recognition of the 3' splice site is dependent upon both the sequence of the 3' splice site itself and enhancer elements located in the 3' exon. We show that the presence of three distinct classes of enhancers results in increased binding of U2 snRNP to the branchpoint region. Several lines of evidence strongly suggest that the increased binding of U2 snRNP is mediated by U2AF. These results expand the roles of enhancers in constitutive splicing and provide direct support for the recruitment model of enhancer function.     

Comprehensive in vivo RNA-binding site analyses reveal a role of Prp8 in spliceosomal assembly

Prp8 stands out among hundreds of splicing factors as a protein that is intimately involved in spliceosomal activation and the catalytic reaction. Here, we present the first comprehensive in vivo RNA footprints for Prp8 in budding yeast obtained using CLIP (cross-linking and immunoprecipitation)/CRAC (cross-linking and analyses of cDNAs) and next-generation DNA sequencing. These footprints encompass known direct Prp8-binding sites on U5, U6 snRNA and intron-containing pre-mRNAs identified using site-directed cross-linking with in vitro assembled small nuclear ribonucleoproteins (snRNPs) or spliceosome. Furthermore, our results revealed novel Prp8-binding sites on U1 and U2 snRNAs. We demonstrate that Prp8 directly cross-links with U2, U5 and U6 snRNAs and pre-mRNA in purified activated spliceosomes, placing Prp8 in position to bring the components of the active site together. In addition, disruption of the Prp8 and U1 snRNA interaction reduces tri-snRNP level in the spliceosome, suggesting a previously unknown role of Prp8 in spliceosomal assembly through its interaction with U1 snRNA.     

Exonic splicing enhancers contribute to the use of both 3' and 5' splice site usage of rat beta-tropomyosin pre-mRNA

The rat beta-tropomyosin gene encodes two tissue-specific isoforms that contain the internal, mutually exclusive exons 6 (nonmuscle/smooth muscle) and 7 (skeletal muscle). We previously demonstrated that the 3' splice site of exon 6 can be activated by introducing a 9-nt polyuridine tract at its 3' splice site, or by strengthening the 5' splice site to a U1 consensus binding site, or by joining exon 6 to the downstream common exon 8. Examination of sequences within exons 6 and 8 revealed the presence of two purine-rich motifs in exon 6 and three purine-rich motifs in exon 8 that could potentially represent exonic splicing enhancers (ESEs). In this report we carried out substitution mutagenesis of these elements and show that some of them play a critical role in the splice site usage of exon 6 in vitro and in vivo. Using UV crosslinking, we have identified SF2/ASF as one of the cellular factors that binds to these motifs. Furthermore, we show that substrates that have mutated ESEs are blocked prior to A-complex formation, supporting a role for SF2/ASF binding to the ESEs during the commitment step in splicing. Using pre-mRNA substrates containing exons 5 through 8, we show that the ESEs within exon 6 also play a role in cooperation between the 3' and 5' splice sites flanking this exon. The splicing of exon 6 to 8 (i.e., 5' splice site usage of exon 6) was enhanced with pre-mRNAs containing either the polyuridine tract in the 3' splice site or consensus sequence in the 5' splice site around exon 6. We show that the ESEs in exon 6 are required for this effect. However, the ESEs are not required when both the polyuridine and consensus splice site sequences around exon 6 were present in the same pre-mRNA. These results support and extend the exon-definition hypothesis and demonstrate that sequences at the 3' splice site can facilitate use of a downstream 5' splice site. In addition, the data support the hypothesis that ESEs can compensate for weak splice sites, such as those found in alternatively spliced exons, thereby providing a target for regulation.     

Evidence that U5 snRNP recognizes the 3' splice site for catalytic step II in mammals.

The first AG dinucleotide downstream from the branchpoint sequence (BPS) is chosen as the 3'' splice site during catalytic step II of the splicing reaction. The mechanism and factors involved in selection of this AG are not known. Early in mammalian spliceosome assembly, U2AF65 binds to the pyrimidine tract between the BPS and AG. Here we show that U2AF65 crosslinking is replaced by crosslinking of three proteins of 110, 116 and 220 kDa prior to catalytic step II, and we provide evidence that all three proteins are components of U5 snRNP. These proteins interact with pre-mRNA in the region spanning from immediately downstream of U2 snRNP''s binding site at the BPS to just beyond the 3'' splice site. We also demonstrate that there are strict constraints on both the sequence and the distance between the BPS and AG for catalytic step II. Together, these observations suggest that U5 snRNP is positioned on the 3'' splice site by an interaction (direct or indirect) with U2 snRNP bound at the BPS and by a direct interaction with the pyrimidine tract. The functional AG for catalytic step II may be specified, in turn, by its location with respect to the U5 snRNP binding site.     

Extended base pair complementarity between U1 snRNA and the 5' splice site does not inhibit splicing in higher eukaryotes, but rather increases 5' splice site recognition

Spliceosome formation is initiated by the recognition of the 5′ splice site through formation of an RNA duplex between the 5′ splice site and U1 snRNA. We have previously shown that RNA duplex formation between U1 snRNA and the 5′ splice site can protect pre-mRNAs from degradation prior to splicing. This initial RNA duplex must be disrupted to expose the 5′ splice site sequence for base pairing with U6 snRNA and to form the active spliceosome. Here, we investigated whether hyperstabilization of the U1 snRNA/5′ splice site duplex interferes with splicing efficiency in human cell lines or nuclear extracts. Unlike observations in Saccharomyces cerevisiae, we demonstrate that an extended U1 snRNA/5′ splice site interaction does not decrease splicing efficiency, but rather increases 5′ splice site recognition and exon inclusion. However, low complementarity of the 5′ splice site to U1 snRNA significantly increases exon skipping and RNA degradation. Although the splicing mechanisms are conserved between human and S.cerevisiae, these results demonstrate that distinct differences exist in the activation of the spliceosome.     

A role for U2/U6 helix Ib in 5' splice site selection.

Selection of pre-mRNA splice sites is a highly accurate process involving many trans-acting factors. Recently, we described a role for U6 snRNA position G52 in selection of the first intron nucleotide (+1G). Because some U2 alleles suppress U6-G52 mutations, we investigated whether the corresponding U2 snRNA region also influenced 5' splice site selection. Our results demonstrate that U2 snRNAs mutated at position U23, but not adjacent nucleotides, specifically affect 5' splice site cleavage. Furthermore, all U2 position U23 mutations are synthetic lethal with the thermosensitive U6-G52U allele. Interestingly, the U2-U23C substitution has an unprecedented hyperaccurate splicing phenotype in which cleavage of introns with a +1G substitution is reduced, whereas the strain grows with wild-type kinetics. U2 position U23 forms the first base pair with U6 position A59 in U2/U6 helix Ib. Restoration of the helical structure suppresses 5' splice site cleavage defects, showing an important role for the helix Ib structure in 5' splice site selection. U2/U6 helix Ib and helix II have recently been described as being functionally redundant. This report demonstrates a unique role for helix Ib in 5' splice site selection that is not shared with helix II.     

The role of overlapping U1 and U11 5' splice site sequences in a negative regulator of splicing

Splicing of Rous sarcoma virus RNA is regulated in part by a cis-acting intronic RNA element called the negative regulator of splicing (NRS). An NRS mutant affecting nt 916-923 disrupts U11 snRNP binding and reduces NRS activity (Gontarek et al., 1993, Genes & Dev 7:1926-1936). However, we observed that a U15' splice site-like sequence, which overlapped the U11 site, was also disrupted by this mutation. To determine whether the U1 or the U11 site was essential for NRS activity, we analyzed twelve additional mutants involving nt 915-926. All mutations that disrupted the potential base pairing between U1 snRNA and the NRS reduced NRS activity, including single point mutations at nt 915, 916, and 919. The point mutation at nt 919 was partially suppressed by a compensatory base change mutation in U1 snRNA. In contrast, a mutation which strengthened the potential base pairing between the U1 site and the NRS increased NRS activity. Surprisingly, mutations that specifically targeted the U115' splice site consensus sequence increased the levels of unspliced RNA, suggesting U11 binding plays an antagonistic role to NRS activity. We propose that U1 snRNP binding to the NRS inhibits splicing and is regulated by U11 snRNP binding to the overlapping sequence. Competition between U1 and U11 snRNPs would result in the appropriate balance of spliced to unspliced RNAs for optimal viral replication. Further, a virus mutated in the U1/U11 region of the NRS was found to have delayed replication.     

A role for the Psi-U mismatch in the recognition of the 5' splice site of yeast introns by the U1 small nuclear ribonucleoprotein particle

The U1 small nuclear ribonucleoprotein particle (snRNP)/5' splice site (5'SS) interaction in yeast is essential for the splicing process and depends on the formation of a short RNA duplex between the 5' arm of U1 snRNA and the 1st intronic nucleotides. This RNA/RNA interaction is characterized by the presence of a mismatch that occurs with almost all yeast introns and concerns nucleotides 4 on the pre-mRNA (a U) and 5 on U1 snRNA (a Psi). The latter nucleotide is well conserved from yeast to vertebrates, but its role in yeast and the significance of the associated mismatch in the U1 snRNA/5'SS interaction have never been fully explained. We report here that the presence of this mismatch is a determinant of stability that mainly affects the off rate of the interaction. To our knowledge this is the first report assigning a function to this noncanonical interaction. We also performed SELEX (systematic evolution of ligands by exponential enrichment) experiments by immunoprecipitating U1 snRNP and the associated RNA. The artificial phylogeny derived from these experiments allows the isolation of the selective pressure due to U1 snRNP binding on the 5'SS of yeast introns.     

Functional recognition of 5' splice site by U4/U6.U5 tri-snRNP defines a novel ATP-dependent step in early spliceosome assembly

A sensitive assay based on competition between cis-and trans-splicing suggested that factors in addition to U1 snRNP were important for early 5' splice site recognition. Cross-linking and physical protection experiments revealed a functionally important interaction between U4/U6.U5 tri-snRNP and the 5' splice site, which unexpectedly was not dependent upon prior binding of U2 snRNP to the branch point. The early 5' splice site/tri-snRNP interaction requires ATP, occurs in both nematode and HeLa cell extracts, and involves sequence-specific interactions between the highly conserved splicing factor Prp8 and the 5' splice site. We propose that U1 and U5 snRNPs functionally collaborate to recognize and define the 5' splice site prior to establishment of communication with the 3' splice site.     

FUBP1 is a general splicing factor facilitating 3′ splice site recognition and splicing of long introns

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