ATP-dependent interaction of yeast U5 snRNA loop 1 with the 5' splice site.

Pre-messenger RNA splicing is a two-step process by which introns are removed and exons joined together. In yeast, the U5 snRNA loop 1 interacts with the 5' exon before the first step of splicing and with the 5' and 3' exons before the second step. In vitro studies revealed that yeast U5 loop 1 is not required for the first step of splicing but is essential for holding the 5' and 3' exons for ligation during the second step. It is critical, therefore, that loop 1 contacts the 5' exon before the first step of splicing to hold this exon following cleavage from the pre-mRNA. At present it is not known how U5 loop 1 is positioned on the 5' exon prior to the first step of splicing. To address this question, we have used site-specific photoactivated crosslinking in yeast spliceosomes to investigate the interaction of U5 loop 1 with the pre-mRNA prior to the first step of splicing. We have found that the highly conserved uridines in loop 1 make ATP-dependent contacts with an approximately 8-nt region at the 5' splice site that includes the invariant GU. These interactions are dependent on functional U2 and U6 snRNAs. Our results support a model where U5 snRNA loop 1 interacts with the 5' exon in two steps during its targeting to the 5' splice site.     

Activation of a cryptic 5' splice site by U1 snRNA

In the course of analyzing 5' splice site mutations in the second intron of Schizosaccharomyces pombe cdc2, we identified a cryptic 5' junction containing a nonconsensus nucleotide at position +2. An even more unusual feature of this cryptic 5' junction was its pattern of activation. By analyzing the profile of splicing products for an extensive series of cdc2 mutants in the presence and absence of compensatory U1 alleles, we have obtained evidence that the natural 5' splice site participates in activation of the cryptic 5' splice site, and that it does so via base pairing to U1 snRNA. Furthermore, the results of follow-up experiments strongly suggest that base pairing between U1 snRNA and the cryptic 5' junction itself plays a dominant role in its activation. Most remarkably, a mutant U1 can activate the cryptic 5' splice site even in the presence of a wild-type sequence at the natural 5' junction, providing unambiguous evidence that this snRNA redirects splicing via base pairing. Although previous work has demonstrated that U5 and U6 snRNAs can activate cryptic 5' splice sites through base pairing interactions, this is the first example in which U1 snRNA has been implicated in the final selection of a cryptic 5' junction.     

Site-specific crosslinks of yeast U6 snRNA to the pre-mRNA near the 5' splice site.

We have introduced a single photochemical crosslinking reagent into specific sites in the central domain of U6 to identify the sites that are in close proximity to the pre-mRNA substrate. Four distinct U6 snRNAs were synthesized with a single 4-thiouridine (4-thioU) at positions 46, 51, 54, and 57, respectively. Synthetic U6 RNA containing the 4-thioU modifications can functionally reconstitute splicing activity in cell-free yeast splicing extracts depleted of endogenous U6 snRNA. Upon photoactivation with UV (>300 nm), 4-thioU at position 46 forms crosslinks to pre-mRNA near the 5' splice site at nt +4, +5, +6, and +7 in the intron, whereas 4-thioU at position 51 crosslinks to the pre-mRNA at positions -2, -1, +1, +2, +3, and at the invariant G in the lariat intermediate. All crosslinks are dependent on the presence of ATP and the splicing substrate. The two crosslinks to the pre-mRNA from position 46 and 51 of U6 can also occur in prp2 heat-inactivated yeast splicing extracts blocked immediately prior to the first chemical step. Significantly, the crosslink from position 51 can undergo subsequent splicing when the mutant extract is complemented with functional Prp2 protein in a chase experiment, indicating that the crosslink reflects a functional interaction that is maintained during the first step. The crosslink to lariat intermediate appears when the mutant spliceosomes are complemented with functional Prp2 protein added exogenously. This experiment is a paradigm for future studies in which different mutant extracts are used to establish the stage in assembly at which particular RNA-RNA interactions defined by unique crosslinks occur.     

snRNA interactions at 5' and 3' splice sites monitored by photoactivated crosslinking in yeast spliceosomes.

Splice site recognition and catalysis of the transesterification reactions in the spliceosome are accompanied by a dynamic series of interactions involving conserved or invariant sequences in the spliceosomal snRNAs. We have used site-specific photoactivated crosslinking in yeast spliceosomes to monitor interactions between snRNAs and exon sequences near the 5' and 3' splice sites. The last nucleotide of the 5' exon can be crosslinked to an invariant loop sequence in U5 SnRNA before and after 5' splice site cleavage. The first nucleotide of the 3' exon can also be crosslinked to the same U5 loop sequence, but this contact is only detectable after the first transesterification. These results are in close agreement with earlier data from mammalian splicing extracts, and they are consistent with a model in which U5 snRNA aligns the 5' and 3' exons for the second transesterification. After the first catalytic step of splicing, the first nucleotide of the 3' exon can also crosslink to nt U23 in U2 snRNA. This is one of a cluster of residues in U2-U6 helix I implicated by mutational analysis in the second catalytic step of splicing. The crosslinking data suggest that these residues in U2-U6 helix I are in close proximity to the scissile phosphodiester bond at the 3' splice site prior to the second transesterification. These results constitute the first biochemical evidence for a direct interaction between the 3' splice site and U2 snRNA.     

Exon mutations uncouple 5' splice site selection from U1 snRNA pairing

It has previously been shown that a mutation of yeast 5' splice junctions at position 5 (GUAUGU) causes aberrant pre-mRNA cleavages near the correct 5' splice site. We show here that the addition of exon mutations to an aberrant cleavage site region transforms it into a functional 5' splice site both in vivo and in vitro. The aberrant mRNAs are translated in vivo. The results suggest that the highly conserved G at the 5' end of introns is necessary for the second step of splicing. Further analyses indicate that the location of the U1 snRNA-pre-mRNA pairing is not affected by the exon mutations and that the precise 5' splice site is selected independent of this pairing.     

U5 snRNA interacts with exon sequences at 5' and 3' splice sites.

U5 snRNA is an essential pre-mRNA splicing factor whose function remains enigmatic. Specific mutations in a conserved single-stranded loop sequence in yeast U5 snRNA can activate cleavage of G1----A mutant pre-mRNAs at aberrant 5' splice sites and facilitate processing of dead-end lariat intermediates to mRNA. Activation of aberrant 5' cleavage sites involves base pairing between U5 snRNA and nucleotides upstream of the cleavage site. Processing of dead-end lariat intermediates to mRNA correlates with base pairing between U5 and the first two bases in exon 2. The loop sequence in U5 snRNA may therefore by intimately involved in the transesterification reactions at 5' and 3' splice sites. This pattern of interactions is strikingly reminiscent of exon recognition events in group II self-splicing introns and is consistent with the notion that U5 snRNA may be related to a specific functional domain from a group II-like self-splicing ancestral intron.     

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.     

Defining a 5' splice site by functional selection in the presence and absence of U1 snRNA 5' end

Pre-mRNA splicing in metazoans is mainly specified by sequences at the termini of introns. We have selected functional 5' splice sites from randomized intron sequences through repetitive rounds of in vitro splicing in HeLa cell nuclear extract. The consensus sequence obtained after one round of selection in normal extract closely resembled the consensus of natural occurring 5' splice sites, suggesting that the selection pressures in vitro and in vivo are similar. After three rounds of selection under competitive splicing conditions, the base pairing potential to the U1 snRNA increased, yielding a G100%U100%R94%A67%G89%U76%R83% intronic consensus sequence. Surprisingly, a nearly identical consensus sequence was obtained when the selection was performed in nuclear extract containing U1 snRNA with a deleted 5' end, suggesting that other factors than the U1 snRNA are involved in 5' splice site recognition. The importance of a consecutive complementarity between the 5' splice site and the U1 snRNA was analyzed systematically in the natural range for in vitro splicing efficiency and complex formation. Extended complementarity was inhibitory to splicing at a late step in spliceosome assembly when pre-mRNA substrates were incubated in normal extract, but favorable for splicing under competitive splicing conditions or in the presence of truncated U1 snRNA where transition from complex A to complex B occurred more rapidly. This suggests that stable U1 snRNA binding is advantageous for assembly of commitment complexes, but inhibitory for the entry of the U4/U6.U5 tri-snRNP, probably due to a delayed release of the U1 snRNP.     

Mutations in yeast U5 snRNA alter the specificity of 5' splice-site cleavage

Recognition of 5' splice sites in pre-mRNA splicing is achieved in part by base pairing with U1 snRNA. We have used interactive suppression in the yeast Saccharomyces cerevisiae to look for other factors involved in 5' splice-site recognition. This approach identified an extragenic suppressor that activates a cryptic 5' splice site. The suppressor is a gene for U5 snRNA (snR7) with a single base mutation in a strictly conserved 9 base sequence. This suggests that U5 snRNA can play a part in determining the position of 5' splice-site cleavage. Consistent with this, we have been able to isolate other mutations in the 9 base element in U5 snRNA that specifically activate a second cryptic 5' splice site nearby.     

hnRNP A1 proofreads 3' splice site recognition by U2AF

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Highlights? hnRNP A1 displaces U2AF from uridine-rich RNAs not followed by a 3′ splice site AG ? A 3′ splice site AG allows formation of a ternary complex with hnRNP A1 and U2AF ? AG proofreading requires U2AF35 and the glycine-rich domain of hnRNP A1 ? hnRNP A1-mediated proofreading influences U2 snRNP recruitment     

Structuring of the 3' splice site by U2AF65

Recognition of the 3' splice site in mammalian introns is accomplished by association of the splicing factor U2AF with the precursor mRNA (pre-mRNA) in a multiprotein splicing commitment complex. It is well established that this interaction involves binding of the large U2AF65 subunit to sequences upstream of the 3' splice site, but the orientation of the four domains of this protein with respect to the RNA and hence their role in structuring the commitment complex remain unclear and the basis of contradictory models. We have examined the interaction of U2AF65 with an RNA representing the 3' splice site using a series of U2AF deletion mutants modified at the N terminus with the directed hydroxyl radical probe iron-EDTA. These studies, combined with an analysis of extant high resolution x-ray structures of protein.RNA complexes, suggest a model whereby U2AF65 bends the pre-mRNA to juxtapose reactive functionalities of the pre-mRNA substrate and organize these structures for subsequent spliceosome assembly.     

U11 snRNA interacts in vivo with the 5' splice site of U12-dependent (AU-AC) pre-mRNA introns.

A notable feature of the newly described U12 snRNA-dependent class of eukaryotic nuclear pre-mRNA introns is the highly conserved 8-nt 5'' splice site sequence. This sequence is virtually invariant in all known members of this class from plants to mammals. Based on sequence complementarity between this sequence and the 5'' end of the U11 snRNA, we proposed that U11 snRNP may play a role in identifying and/or activating the 5'' splice site for splicing. Here we show that mutations of the conserved 5'' splice site sequence of a U12-dependent intron severely reduce correct splicing in vivo and that compensatory mutations in U11 snRNA can suppress the effects of the 5'' splice site mutations to varying extents. This provides evidence for a required interaction between U11 snRNA and the 5'' splice site sequence involving Watson-Crick base pairing. This data, in addition to a report that U11 snRNP is bound transiently to the U12-dependent spliceosome, suggests that U11 snRNP is the analogue of U1 snRNP in splicing this rare class of introns.     

Proximity of conserved U6 and U2 snRNA elements to the 5' splice site region in activated spliceosomes

Major structural changes occur in the spliceosome during its catalytic activation, which immediately precedes the splicing of pre-mRNA. Whereas changes in snRNA conformation are well documented at the level of secondary RNA-RNA interactions, little is known about the tertiary structure of this RNA-RNA network, which comprises the spliceosome's catalytic core. Here, we have used the hydroxyl-radical probe Fe-BABE, tethered to the tenth nucleotide (U(+10)) of the 5' end of a pre-mRNA intron, to map RNA-RNA proximities in spliceosomes. These studies revealed that several conserved snRNA regions are close to U(+10) in activated spliceosomes, namely (i) the U6 snRNA ACAGAG-box region, (ii) portions of the U6 intramolecular stem-loop (U6-ISL) including a nucleotide implicated in the first catalytic step (U74), and (iii) the region of U2 that interacts with the branch point. These data constrain the relative orientation of these structural elements with respect to U(+10) in the activated spliceosome. Upon conversion of the activated spliceosome to complex C, the accessibility of U6-ISL to hydroxyl-radical cleavage is altered, suggesting rearrangements after the first catalytic step.     

The U1 snRNP base pairs with the 5' splice site within a penta-snRNP complex

Recognition of the 5' splice site is an important step in mRNA splicing. To examine whether U1 approaches the 5' splice site as a solitary snRNP or as part of a multi-snRNP complex, we used a simplified in vitro system in which a short RNA containing the 5' splice site sequence served as a substrate in a binding reaction. This system allowed us to study the interactions of the snRNPs with the 5' splice site without the effect of other cis-regulatory elements of precursor mRNA. We found that in HeLa cell nuclear extracts, five spliceosomal snRNPs form a complex that specifically binds the 5' splice site through base pairing with the 5' end of U1. This system can accommodate RNA-RNA rearrangements in which U5 replaces U1 binding to the 5' splice site, a process that occurs naturally during the splicing reaction. The complex in which U1 and the 5' splice site are base paired sediments in the 200S fraction of a glycerol gradient together with all five spliceosomal snRNPs. This fraction is functional in mRNA spliceosome assembly when supplemented with soluble nuclear proteins. The results argue that U1 can bind the 5' splice site in a mammalian preassembled penta-snRNP complex.     

Both the polypyrimidine tract and the 3' splice site function prior to the first step of splicing in fission yeast.

While it is known that several trans -acting splicing factors are highly conserved between Schizosaccharomyces pombe and mammals, the roles of cis -acting signals have received comparatively little attention. In Saccharomyces cerevisiae, sequences downstream from the branch point are not required prior to the first transesterification reaction, whereas in mammals the polypyrimidine tract and, in some introns, the 3' AG dinucleotide are critical for initial recognition of an intron. We have investigated the contribution of these two sequence elements to splicing in S.pombe. To determine the stage at which the polypyrimidine tract functions, we analyzed the second intron of the cdc2 gene (cdc 2-Int2), in which pyrimidines span the entire interval between the branch point and 3' splice site. Our data indicate that substitution of a polypurine tract results in accumulation of linear pre-mRNA, while expanding the polypyrimidine tract enhances splicing efficiency, as in mammals. To examine the role of the AG dinucleotide in cdc 2-Int2 splicing, we mutated the 3' splice junction in both the wild-type and pyrimidine tract variant RNAs. These changes block the first transesterification reaction, as in a subset of mammalian introns. However, in contrast to the situation in mammals, we were unable to rescue the first step of splicing in a 3' splice site mutant by expanding the polypyrimidine tract. Mutating the terminal G in the third intron of the nda 3 gene (nda 3-Int3) also blocks the first transesterification reaction, suggesting that early recognition of the 3' splice site is a general property of fission yeast introns. Counter to earlier work with an artificial intron, it is not possible to restore the first step of splicing in cdc 2-Int2 and nda 3-Int3 3' splice site mutants by introducing compensatory changes in U1 snRNA. These results highlight the diversity and probable redundancy of mechanisms for identifying the 3' ends of introns.     

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.     

Genetic suppression of intronic +1G mutations by compensatory U1 snRNA changes in Caenorhabditis elegans

Mutations to the canonical +1G of introns, which are commonly found in many human inherited disease alleles, invariably result in aberrant splicing. Here we report genetic findings in C. elegans that aberrant splicing due to +1G mutations can be suppressed by U1 snRNA mutations. An intronic +1G-to-U mutation, e936, in the C. elegans unc-73 gene causes aberrant splicing and loss of gene function. We previously showed that mutation of the sup-39 gene promotes splicing at the mutant splice donor in e936 mutants. We demonstrate here that sup-39 is a U1 snRNA gene; suppressor mutations in sup-39 are compensatory substitutions in the 5' end, which enhance recognition of the mutant splice donor. sup-6(st19) is an allele-specific suppressor of unc-13(e309), which contains an intronic +1G-to-A transition. The e309 mutation activates a cryptic splice site, and sup-6(st19) restores splicing to the mutant splice donor. sup-6 also encodes a U1 snRNA and the mutant contains a compensatory substitution at its 5' end. This is the first demonstration that U1 snRNAs can act to suppress the effects of mutations to the invariant +1G of introns. These findings are suggestive of a potential treatment of certain alleles of inherited human genetic diseases.     

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.