Genetic interaction between U6 snRNA and the first intron nucleotide in Saccharomyces cerevisiae.

Nuclear pre-mRNA splicing necessitates specific recognition of the pre-mRNA splice sites. It is known that 5' splice site selection requires base pairing of U6 snRNA with intron positions 4-6. However, no factor recognizing the highly conserved 5' splice site GU has yet been identified. We have tested if the known U6 snRNA-pre-mRNA interaction could be extended to include the first intron nucleotides and the conserved 50GAG52 sequence of U6 snRNA. We observe that some combinations of 5' splice site and U6 snRNA mutations produce a specific synthetic block to the first splicing step. In addition, the U6-G52U allele can switch between two competing 5' splice sites harboring different nucleotides following the cleavage site. These results indicate that U6 snRNA position 52 interacts with the first nucleotide of the intron before 5' splice site cleavage. Some combinations of U6 snRNA and pre-mRNA mutations also blocked the second splicing step, suggesting a role for the corresponding nucleotides in a proofreading step before exon ligation. From studies in diverse organisms, various functions have been ascribed to the conserved U6 snRNA 47ACAGAG52 sequence. Our results suggest that these discrepancies might reflect variations between different experimental systems and point to an important conserved role of this sequence in the splicing reaction.     

Influences of separation and adjacent sequences on the use of alternative 5' splice sites.

Single nucleotide changes to the sequence between two alternative 5' splice sites, separated by 25 nucleotides in a beta-globin gene derivative, caused substantial shifts in pre-mRNA splicing preferences, both in vivo and in vitro. An activating sequence for splicing was located. Models for the recognition by U1 small nuclear ribonucleoproteins (snRNPs) of competing 5' splice sites were tested by altering the distance separating the two sites. Use of the upstream splice site declined sharply when it was separated from the downstream (natural) site by distances of 40 nucleotides or more. This effect was reversed in vivo, but not in vitro, by altering the upstream sequence to that of a consensus 5' splice site sequence. Dilution of an extract used for splicing in vitro shifted preferences when the sites were close towards the downstream site. We conclude that the mechanism of selection depends on the distance apart of the potential splice sites and that with close sites steric interference between factors bound to both sites may impede splicing and affect splicing preferences.     

Possible role of nucleotide correlations between human exon junctions

There is ample evidence that prediction of human splice sites can be refined by analyzing the nucleotides surrounding splice sites. This could mean that exon nucleotides over splice sites harbour information for the splicing process in addition to the coding information to specify aminoacids. We analyzed the correlations among the nucleotides lying at the end and at the beginning of all the consecutive human exons to seek relationships among the nucleotides. We have divided the sequences taking into account the phase of interruption. Even though exon sequences are involved in the coding function, we found phase-dependent, specific correlations in the area of exon junctions. These regularities do not give rise to specific motifs, but rather to a phase-specific nucleotide context that could contribute to define the splice site or aid the splicing machinery to join the exon ends. Results provide further evidence that accurate selection of human splice sites likely requires the contribution of exon regulatory sequences.     

Characterization of intronic structures and alternative splicing in Phytophthora sojae by comparative analysis of expressed sequence tags and genomic sequences

The oomycetes, a distinct phylogenetic lineage of fungus-like microorganisms, are heterokonts (stramenopiles) belonging to the supergroup Chromalveolata. Although the complete genomic sequences of a number of oomycetes have been reported, little information regarding the introns therein is available. Here, we investigated the introns of Phytophthora sojae, a pathogen that causes soybean root and stem rot, by a comparative analysis of genomic sequences and expressed sequence tags. A total of 4013 introns were identified, of which 96.6% contained canonical splice sites. The P. sojae genome possessed features distinct from other organisms at 5' splice sites, polypyrimidine tracts, branch sites, and 3' splice sites. Diverse repeating sequences, ranging from 2 to 10 nucleotides in length, were found at more than half of the intron-exon boundaries. Furthermore, 122 genes underwent alternative splicing. These data indicate that P. sojae has unique splicing mechanisms, and recognition of those mechanisms may lead to more accurate predictions of the location of introns in P. sojae and even other oomycete species.     

Deletion mutants that alter differential RNA processing in the E3 complex transcription unit of adenovirus

Region E3 of the adenovirus encodes about ten overlapping mRNAs (a to j) with different splicing patterns and with two RNA 3' end sites termed E3A and E3B. We have examined how deletions in 12 viable virus mutants affect differential RNA processing in E3. We assayed E3 mRNAs by the nuclease-gel and RNA blot procedures. Some deletions had no effect whereas others (e.g. deletion of a 3' splice or the E3A 3' end signal) had the anticipated effects on RNA processing. However, deletions in two regions had surprising effects. Deletions in one region (nucleotides 1691 to 2044) enhanced splicing at the upstream 951 5' splice site and the downstream 2157 and/or 2880 3' splice sites. Some of these deletions prevented RNA 3' end formation at the downstream E3A site. Deletion in the other region (nucleotides 2173 to 2237) enhanced an upstream splice site (951 to 2157) such that almost all pre-mRNA was processed into mRNA f. We suggest that these two regions contain cis-acting signals that regulate differential RNA processing. We discuss the results in terms of RNA folding and scanning models for splicing, as well as models for differential RNA 3' end formation at the E3A versus the E3B site.     

Comprehensive splice-site analysis using comparative genomics

We have collected over half a million splice sites from five species-Homo sapiens, Mus musculus, Drosophila melanogaster, Caenorhabditis elegans and Arabidopsis thaliana-and classified them into four subtypes: U2-type GT-AG and GC-AG and U12-type GT-AG and AT-AC. We have also found new examples of rare splice-site categories, such as U12-type introns without canonical borders, and U2-dependent AT-AC introns. The splice-site sequences and several tools to explore them are available on a public website (SpliceRack). For the U12-type introns, we find several features conserved across species, as well as a clustering of these introns on genes. Using the information content of the splice-site motifs, and the phylogenetic distance between them, we identify: (i) a higher degree of conservation in the exonic portion of the U2-type splice sites in more complex organisms; (ii) conservation of exonic nucleotides for U12-type splice sites; (iii) divergent evolution of C.elegans 3' splice sites (3'ss) and (iv) distinct evolutionary histories of 5' and 3'ss. Our study proves that the identification of broad patterns in naturally-occurring splice sites, through the analysis of genomic datasets, provides mechanistic and evolutionary insights into pre-mRNA splicing.     

Identification and characterization by antisense oligonucleotides of exon and intron sequences required for splicing.

Certain thalassemic human beta-globin pre-mRNAs carry mutations that generate aberrant splice sites and/or activate cryptic splice sites, providing a convenient and clinically relevant system to study splice site selection. Antisense 2'-O-methyl oligoribonucleotides were used to block a number of sequences in these pre-mRNAs and were tested for their ability to inhibit splicing in vitro or to affect the ratio between aberrantly and correctly spliced products. By this approach, it was found that (i) up to 19 nucleotides upstream from the branch point adenosine are involved in proper recognition and functioning of the branch point sequence; (ii) whereas at least 25 nucleotides of exon sequences at both 3' and 5' ends are required for splicing, this requirement does not extend past the 5' splice site sequence of the intron; and (iii) improving the 5' splice site of the internal exon to match the consensus sequence strongly decreases the accessibility of the upstream 3' splice site to antisense 2'-O-methyl oligoribonucleotides. This result most likely reflects changes in the strength of interactions near the 3' splice site in response to improvement of the 5' splice site and further supports the existence of communication between these sites across the exon.     

Extensive interactions of PRP8 protein with the 5'' and 3'' splice sites during splicing suggest a role in stabilization of exon alignment by U5 snRNA.

Precursor RNAs containing 4-thiouridine at specific sites were used with UV-crosslinking to map the binding sites of the yeast protein splicing factor PRP8. PRP8 protein interacts with a region of at least eight exon nucleotides at the 5' splice site and a minimum of 13 exon nucleotides and part of the polypyrimidine tract in the 3' splice site region. Crosslinking of PRP8 to mutant and duplicated 3' splice sites indicated that the interaction is not sequence specific, nor does it depend on the splice site being functional. Binding of PRP8 to the 5' exon was established before step 1 and to the 3' splice site region after step 1 of splicing. These interactions place PRP8 close to the proposed catalytic core of the spliceosome during both transesterification reactions. To date, this represents the most extensive mapping of the binding site(s) of a splicing factor on the substrate RNA. We propose that the large binding sites of PRP8 stabilize the intrinsically weaker interactions of U5 snRNA with both exons at the splice sites for exon alignment by the U5 snRNP.     

Intron sequences involved in lariat formation during pre-mRNA splicing

We have shown that lariat formation during in vitro splicing of several RNA precursors, from Drosophila to man, occurs at a unique and identifiable but weakly conserved site, 18 to 37 nucleotides proximal to the 3' splice site. Lariat formation within an artificial intron lacking a normal branch-point sequence occurs at a cryptic site a conserved distance (approximately 23 nucleotides) from the 3' splice site. Analysis of beta-thalassemia splicing mutations revealed that lariat formation in the first intron of the human beta-globin gene occurs at the same site in normal and mutant precursors, even though alternate 5' and 3' splice sites are utilized in the mutants. Remarkably, cleavage at the 5' splice site and lariat formation do not occur when the precursor contains a beta-thalassemia deletion removing the polypyrimidine stretch and AG dinucleotide at the 3' splice site. In contrast, a single base substitution in the AG dinucleotide blocks cleavage at the 3' splice site but not at the 5' site.     

Splicing signals in Drosophila: intron size, information content, and consensus sequences.

A database of 209 Drosophila introns was extracted from Genbank (release number 64.0) and examined by a number of methods in order to characterize features that might serve as signals for messenger RNA splicing. A tight distribution of sizes was observed: while the smallest introns in the database are 51 nucleotides, more than half are less than 80 nucleotides in length, and most of these have lengths in the range of 59-67 nucleotides. Drosophila splice sites found in large and small introns differ in only minor ways from each other and from those found in vertebrate introns. However, larger introns have greater pyrimidine-richness in the region between 11 and 21 nucleotides upstream of 3' splice sites. The Drosophila branchpoint consensus matrix resembles C T A A T (in which branch formation occurs at the underlined A), and differs from the corresponding mammalian signal in the absence of G at the position immediately preceding the branchpoint. The distribution of occurrences of this sequence suggests a minimum distance between 5' splice sites and branchpoints of about 38 nucleotides, and a minimum distance between 3' splice sites and branchpoints of 15 nucleotides. The methods we have used detect no information in exon sequences other than in the few nucleotides immediately adjacent to the splice sites. However, Drosophila resembles many other species in that there is a discontinuity in A + T content between exons and introns, which are A + T rich.     

A clean data set of EST-confirmed splice sites from Homo sapiens and standards for clean-up procedures.

A clean data set of verified splice sites from Homo sapiens are reported as well as the standards used for the clean-up procedure. The sites were validated by: (i) standard cleaning procedures such as requiring consistency in the annotation of the gene structural elements, completeness of the coding regions and elimination of redundant sequences; (ii) clustering by decision trees coupled with analysis of ClustalW alignments of the translated protein sequence with homologous proteins from SWISS-PROT; (iii) matching against human EST sequences. The sites are categorised as: (i) donor sites, a set of 619 EST-confirmed donor sites, for which 138 are either the sites or the regions around the sites involved in alternative splice events; (ii) acceptor sites, a set of 623 EST-confirmed acceptor sites, for which 144 are either the sites or the regions around the sites are involved in alternative splice events; (iii) genuine splice sites, a set of 392 splice sites wherein both the donor and acceptor sites had EST confirmation and were not involved in any alternative splicing; (iv) alternative splice sites, a set of 209 splice sites wherein both the donor and acceptor sites had EST confirmation and the sites or the regions around them were involved in alternative splicing. A set of nucleotide regions that can be used to generate a control set of false splice sites that have a high confidence of being non-functional are also reported.     

Does distance matter? Variations in alternative 3′ splicing regulation

Alternative splicing constitutes a major mechanism creating protein diversity in humans. This diversity can result from the alternative skipping of entire exons or by alternative selection of the 5′ or 3′ splice sites that define the exon boundaries. In this study, we analyze the sequence and evolutionary characteristics of alternative 3′ splice sites conserved between human and mouse genomes for distances ranging from 3 to 100 nucleotides. We show that alternative splicing events can be distinguished from constitutive splicing by a combination of properties which vary depending on the distance between the splice sites. Among the unique features of alternative 3′ splice sites, we observed an unexpectedly high occurrence of events in which a polypyrimidine tract was found to overlap the upstream splice site. By applying a machine-learning approach, we show that we can successfully discriminate true alternative 3′ splice sites from constitutive 3′ splice sites. Finally, we propose that the unique features of the intron flanking alternative splice sites are indicative of a regulatory mechanism that is involved in splice site selection. We postulate that the process of splice site selection is influenced by the distance between the competitive splice sites.     

Interactions between the terminal bases of mammalian introns are retained in inosine-containing pre-mRNAs.

Nuclear pre-mRNA splicing has a fundamentally similar two-step mechanism to that employed by group II self-splicing introns. It is believed that nuclear pre-mRNA splicing involves a network of RNA-RNA interactions which form the catalytic core of the active spliceosome. We show here a non-Watson-Crick interaction between the first and last guanosine residues of a mammalian intron. As in Saccharomyces cerevisiae, substitution of the conserved guanosines at the 5' and 3' splice sites by A and C respectively, specifically suppresses step 2 splicing defects resulting from the individual mutations. No other combination of terminal nucleotides was able to restore splicing. We additionally provide independent evidence for an indirect interaction between other nucleotides of the consensus splice sites during step 2 of splicing. Substitution of the nucleotide in the +3 position of the 5' splice site affects competition between closely spaced AG dinucleotides at the 3' splice site, although the interaction is not via direct differential base pairing. Finally, we show that complete substitution of guanosine residues by inosine in a pre-mRNA has only a modest effect upon step 2 of splicing, although earlier spliceosome assembly steps are impaired. Predictions can thus be made about the precise configuration of the non-Watson-Crick interaction between the terminal residues.