Identification of a specific exon sequence that is a major determinant in the selection between a natural and a cryptic 5'' splice site.

The first intron of the early region 3 from adenovirus type 2 contains a cryptic 5' splice site, Dcr1, 74 nucleotides downstream from the natural site D1. The cryptic site can be activated when the natural site is inactivated by mutagenesis. To investigate the basis for selection between a natural and a cryptic 5' splice site, we searched for cis-acting elements responsible for the exclusive selection of the natural site. We show that both the relative intrinsic strength of the sites and the sequence context affect the selection. A 120-nucleotide segment located at the 3' end of exon 1 enhances splicing at the proximal site D1; in its absence the two sites are used according to their strength. Thus, three cis-acting elements are involved in the silencing of the cryptic site: the sequence of D1, the sequence of Dcr1, and an upstream exonic sequence. We show that the exonic element folds, in solution, into a 113-nucleotide-long stem-loop structure. We propose that this potential stem-loop structure which is located 6 nucleotides upstream of the exon 1-intron junction is responsible for the preferential use of the natural 5' splice site.     

An alternative helix in the 26S rRNA promotes excision and integration of the Tetrahymena intervening sequence.

A highly conserved ribosomal stem-loop immediately upstream of the Tetrahymena splice junction can inhibit both forward and reverse self-splicing by competing with base pairing between the 5' exon and the guide sequence of the intervening sequence. Formation of this unproductive hairpin is preferred in precursor RNAs with short exons and results in a lower rate of splicing. Inhibition of self-splicing is not observed in longer precursors, suggesting that additional interactions in the extended exons can influence the equilibrium between the productive and unproductive hairpins at the 5' splice site. An alternative pairing upstream of the 5' splice site has been identified and is proposed to stabilize the active conformer of the pre-rRNA. Nucleotide changes that alter the ability to form this additional helix were made, and the self-splicing rates were compared. Precursors in which the proposed stem is stabilized splice more rapidly than the wild type, whereas RNAs that contain a base mismatch splice more slowly. The ability of DNA oligomers to bind the RNA, as detected by RNase H digestion, correlates with the predicted secondary structure of the RNA. We also show that a 236-nucleotide RNA containing the natural splice junction is a substrate for intervening sequence integration. As in the forward reaction, reverse splicing is enhanced in ligated exon substrates in which the alternative rRNA pairing is more stable.     

Mutational evidence for competition between the P1 and the P10 helices of a mitochondrial group I intron.

A guanosine to cytosine transversion at position 2 of the fifth intron of the mitochondrial gene COB blocks the ligation step of splicing. This mutation prevents the formation of a base pair within the P1 helix of this group I intron--the RNA duplex formed between the 3' end of the upstream exon and the internal guide sequence. The mutation also reduces the rate of the first step of splicing (guanosine addition at the 5' splice junction) while stimulating hydrolysis at the 3' intron-exon boundary. Consequently, the ligation of exons is blocked because the 3' exon is removed prior to cleavage at the 5' splice junction. The lesion can be suppressed by second-site mutations that preserve the potential for base-pairing at this position. Because the P1 duplex and the P10 duplex (between the guide sequence and the 3' exon) overlap at the affected pairings represent alternative structures that do not, indeed cannot, form simultaneously.     

Effect of 5'' splice site mutations on splicing of the preceding intron.

Three exon constructs containing identical intron and exon sequences were mutated at the 5' splice site beginning intron 2 and assayed for the effect of the mutation on splicing of the upstream intron in vitro. Alteration of two or six bases within the 5' splice site reduced removal of intron 1 at least 20-fold, as determined by quantitation of either spliced product or released lariat RNA. The prominent product was skip splicing of exon 1 to exon 3. Examination of complex formation indicated that mutation of the 5' splice site terminating exon 2 depressed the ability of precursor RNAs containing just the affected exon to direct assembly in vitro. These results suggest that mutation at the end of an internal exon inhibits the ability of the exon to be recognized by splicing factors. A comparison of the known vertebrate 5' splice site mutations in which the mutation resides at the end of an internal exon indicated that exon skipping is the preferred phenotype for this type of mutation, in agreement with the in vitro observation reported here. Inhibition of splicing by mutation at the distal and of the exon supports the suggestion that exons, rather than splice sites, are the recognition units for assembly of the spliceosome.     

Accurate selection of a 5' splice site requires sequences within fibronectin alternative exon B.

Inclusion of fibronectin alternative exon B in mRNA is developmentally regulated. Here we demonstrate that exon B contains two unique purine-rich sequence tracts, PRE1 and PRE2, that are important for proper 5' splice site selection both in vivo and in vitro. Targeted mutations of both PREs decreased the inclusion of exon B in the mRNA by 50% in vivo. Deletion or mutation of the PREs reduced removal of the downstream intron, but not the upstream intron, and induced the activation of cryptic 5' splice sites in vitro. PRE-mediated 5' splice selection activity appears sensitive to position and sequence context. A well characterized exon sequence enhancer that normally acts on the upstream 3' splice site can partially rescue proper exon B 5' splice site selection. In addition, we found that PRE 5' splice selection activity was preserved when exon B was inserted into a heterologous pre-mRNA substrate. Possible roles of these unique activities in modulating exon B splicing are considered.     

Donor site competition is involved in the regulation of alternative splicing of the rat beta-tropomyosin pre-mRNA

The rat beta-tropomyosin (beta-TM) gene encodes both skeletal muscle beta-TM mRNA and nonmuscle TM-1 mRNA via alternative RNA splicing. This gene contains eleven exons: exons 1-5, 8, and 9 are common to both mRNAs; exons 6 and 11 are used in fibroblasts as well as in smooth muscle, whereas exons 7 and 10 are used in skeletal muscle. Previously we demonstrated that utilization of the 3' splice site of exon 7 is blocked in nonmuscle cells. In this study, we use both in vitro and in vivo methods to investigate the regulation of the 5' splice site of exon 7 in nonmuscle cells. The 5' splice site of exon 7 is used efficiently in the absence of flanking sequences, but its utilization is suppressed almost completely when the upstream exon 6 and intron 6 are present. The suppression of the 5' splice site of exon 7 does not result from the sequences at the 3' end of intron 6 that block the use of the 3' splice site of exon 7. However, mutating two conserved nucleotides GU at the 5' splice site of exon 6 results in the efficient use of the 5' splice site of exon 7. In addition, a mutation that changes the 5' splice site of exon 7 to the consensus U1 snRNA binding site strongly stimulates the splicing of exon 7 to the downstream common exon 8. Collectively, these studies demonstrate that 5' splice site competition is responsible, in part, for the suppression of exon 7 usage in nonmuscle cells.     

Cryptic intron activation within the large exon of the mouse polymeric immunoglobulin receptor gene: cryptic splice sites correspond to protein domain boundaries.

The fourth exon of the mouse polymeric immuno-globulin receptor (pIgR) is 654 nt long and, despite being surrounded by large introns, is constitutively spliced into the mRNA. Deletion of an 84 nt sequence from this exon strongly activated both cryptic 5' and 3' splice sites surrounding a 78 nt cryptic intron. The 84 nt deletion is just upstream of the cryptic 3' splice site; the cryptic 3' splice site was likely activated because the deletion created a better 3' splice site. However, the cryptic 5' splice site was also required to activate the cryptic splice reaction; point mutations in either of the cryptic splice sites that decreased their match to the consensus splice site sequence inactivated the cryptic splice reaction. The activation and inactivation of these cryptic splice sites as a pair suggests that they are being co-recognized by the splicing machinery. Interestingly, the large fourth exon of the pIgR gene encodes two immunoglobulin-like extracellular protein domains; the cryptic 3' splice site coincides with the junction between these protein domains. The cryptic 5' splice site is located between protein subdomains where an intron is found in another gene of the immunoglobulin superfamily.     

In vivo recognition of a vertebrate mini-exon as an exon-intron-exon unit.

Very small vertebrate exons are problematic for RNA splicing because of the proximity of their 3' and 5' splice sites. In this study, we investigated the recognition of a constitutive 7-nucleotide mini-exon from the troponin I gene that resides quite close to the adjacent upstream exon. The mini-exon failed to be included in spliced RNA when placed in a heterologous gene unless accompanied by the upstream exon. The requirement for the upstream exon disappeared when the mini-exon was internally expanded, suggesting that the splice sites bordering the mini-exon are compatible with those of other constitutive vertebrate exons and that the small size of the exon impaired inclusion. Mutation of the 5' splice site of the natural upstream exon did not result in either exon skipping or activation of a cryptic 5' splice site, the normal vertebrate phenotypes for such mutants. Instead, a spliced RNA accumulated that still contained the upstream intron. In vitro, the mini-exon failed to assemble into spliceosome complexes unless either internally expanded or accompanied by the upstream exon. Thus, impaired usage of the mini-exon in vivo was accompanied by impaired recognition in vitro, and recognition of the mini-exon was facilitated by the presence of the upstream exon in vivo and in vitro. Cumulatively, the atypical in vivo and in vitro properties of the troponin exons suggest a mechanism for the recognition of this mini-exon in which initial recognition of an exon-intron-exon unit is followed by subsequent recognition of the intron.     

The length of the downstream exon and the substitution of specific sequences affect pre-mRNA splicing in vitro.

We have shown previously that truncation of the human beta-globin pre-mRNA in the second exon, 14 nucleotides downstream from the 3' splice site, leads to inhibition of splicing but not cleavage at the 5' splice site. We now show that several nonglobin sequences substituted at this site can restore splicing and that the efficiency of splicing depends on the length of the second (downstream) exon and not a specific sequence. Deletions in the first exon have no effect on the efficiency of in vitro splicing. Surprisingly, an intron fragment from the 5' region of the human or rabbit beta-globin intron 2, when placed 14 nucleotides downstream from the 3' splice site, inhibited all the steps in splicing beginning with cleavage at the 5' splice site. This result suggests that the intron 2 fragment carries a "poison" sequence that can inhibit the splicing of an upstream intron.     

Proximity of the U12 snRNA with both the 5' splice site and the branch point during early stages of spliceosome assembly

U12 snRNA is required for branch point recognition in the U12-dependent spliceosome. Using site-specific cross-linking, we have captured an unexpected interaction between the 5' end of the U12 snRNA and the -2 position upstream of the 5' splice site of P120 and SCN4a splicing substrates. The U12 snRNA nucleotides that contact the 5' exon are the same ones that form the catalytically important helix Ib with U6atac snRNA in the spliceosome catalytic core. However, the U12/5' exon interaction is transient, occurring prior to the entry of the U4atac/U6atac.U5 tri-snRNP to the spliceosome. This suggests that the helix Ib region of U12 snRNA is positioned near the 5' splice site early during spliceosome assembly and only later interacts with U6atac to form helix Ib. We also provide evidence that U12 snRNA can simultaneously interact with 5' exon sequences near 5' splice site and the branch point sequence, suggesting that the 5' splice site and branch point sequences are separated by <40 to 50 A in the complex A of the U12-dependent spliceosome. Thus, no major rearrangements are subsequently needed to position these sites for the first step of catalysis.     

The conserved U.G pair in the 5'' splice site duplex of a group I intron is required in the first but not the second step of self-splicing.

Group I self-splicing introns have a 5' splice site duplex (P1) that contains a single conserved base pair (U.G). The U is the last nucleotide of the 5' exon, and the G is part of the internal guide sequence within the intron. Using site-specific mutagenesis and analysis of the rate and accuracy of splicing of the Tetrahymena thermophila group I intron, we found that both the U and the G of the U.G pair are important for the first step of self-splicing (attack of GTP at the 5' splice site). Mutation of the U to a purine activated cryptic 5' splice sites in which a U.G pair was restored; this result emphasizes the preference for a U.G at the splice site. Nevertheless, some splicing persisted at the normal site after introduction of a purine, suggesting that position within the P1 helix is another determinant of 5' splice site choice. When the U was changed to a C, the accuracy of splicing was not affected, but the Km for GTP was increased by a factor of 15 and the catalytic rate constant was decreased by a factor of 7. Substitution of U.A, U.U, G.G, or A.G for the conserved U.G decreased the rate of splicing by an even greater amount. In contrast, mutation of the conserved G enhanced the second step of splicing, as evidenced by a trans-splicing assay. Furthermore, a free 5' exon ending in A or C instead of the conserved U underwent efficient ligation. Thus, unlike the remainder of the P1 helix, which functions in both the first and second steps of self-splicing, the conserved U.G appears to be important only for the first step.     

Polypyrimidine tract binding protein blocks the 5' splice site-dependent assembly of U2AF and the prespliceosomal E complex

Polypyrimidine tract binding protein (PTB) represses some alternatively spliced exons by direct occlusion of splice sites. In repressing the splicing of the c-src N1 exon, we find that PTB acts by a different mechanism. PTB does not interfere with U1 snRNP binding to the N1 5' splice site. Instead, PTB prevents formation of the prespliceosomal early (E) complex across the intervening intron by preventing the assembly of the splicing factor U2AF on the 3' splice site of exon 4. When the unregulated 5' splice site of the upstream exon 3 is present, U2AF binding is restored and splicing between exons 3 and 4 proceeds in spite of the N1 exon bound PTB. Thus, rather than directly blocking the N1 splice sites, PTB prevents the 5' splice site-dependent assembly of U2AF into the E complex. This mechanism likely occurs in many other alternative exons.     

Base pairing between the 3'' exon and an internal guide sequence increases 3'' splice site specificity in the Tetrahymena self-splicing rRNA intron.

It has been proposed that recognition of the 3' splice site in many group I introns involves base pairing between the start of the 3' exon and a region of the intron known as the internal guide sequence (R. W. Davies, R. B. Waring, J. Ray, T. A. Brown, and C. Scazzocchio, Nature [London] 300:719-724, 1982). We have examined this hypothesis, using the self-splicing rRNA intron from Tetrahymena thermophila. Mutations in the 3' exon that weaken this proposed pairing increased use of a downstream cryptic 3' splice site. Compensatory mutations in the guide sequence that restore this pairing resulted in even stronger selection of the normal 3' splice site. These changes in 3' splice site usage were more pronounced in the background of a mutation (414A) which resulted in an adenine instead of a guanine being the last base of the intron. These results show that the proposed pairing (P10) plays an important role in ensuring that cryptic 3' splice sites are selected against. Surprisingly, the 414A mutation alone did not result in activation of the cryptic 3' splice site.     

cis-acting sequences involved in exon selection in the chicken beta-tropomyosin gene.

The chicken beta-tropomyosin gene contains an internal pair of mutually exclusive exons (6A and 6B) that are selected in a tissue-specific manner. Exon 6A is incorporated in fibroblasts and smooth muscle cells, whereas exon 6B is skeletal muscle specific. In this study we show that two different regions in the intron between the two mutually exclusive exons are important for this specific selection in nonmuscle cells. Sequences in the 3' end of the intron have a negative effect in the recognition of the 3' splice site, while sequences in the 5' end of the intron have a positive effect in the recognition of the 5' splice site. First, sequences in exon 6B as well as in the intron upstream of exon 6B are both able to inhibit splicing when placed in a heterologous gene. The sequences in the polypyrimidine stretch region contribute to splicing inhibition of exons 5 or 6A to 6B through a mechanism independent of their implication in the previously described secondary structure around exon 6B. Second, we have identified a sequence of 30 nucleotides in the intron just downstream of exon 6A that is essential for the recognition of the 5' splice site of exon 6A. This is so even after introduction of a consensus sequence into the 5' splice site of this exon. Deletion of this sequence blocks splicing of exon 6A to 6B after formation of the presplicing complex. Taken together, these results suggest that both the mutually exclusive behavior and the choice between exons 6A and 6B of the chicken beta-tropomyosin gene are trans regulated.     

Regulation of Fas alternative splicing by antagonistic effects of TIA-1 and PTB on exon definition

Fas exon 6 can be included or skipped to generate mRNAs encoding, respectively, a membrane bound form of the receptor that promotes apoptosis or a soluble isoform that prevents programmed cell death. We report that the apoptosis-inducing protein TIA-1 promotes U1 snRNP binding to the 5' splice site of intron 6, which in turn facilitates exon definition by enhancing U2AF binding to the 3' splice site of intron 5. The polypyrimidine tract binding protein (PTB) promotes exon skipping by binding to an exonic splicing silencer and inhibiting the association of U2AF and U2 snRNP with the upstream 3' splice site, without affecting recognition of the downstream 5' splice site by U1. Remarkably, U1 snRNP-mediated recognition of the 5' splice site is required both for efficient U2AF binding and for U2AF inhibition by PTB. We propose that TIA-1 and PTB regulate Fas splicing and possibly Fas-mediated apoptosis by targeting molecular events that lead to exon definition.     

Combinatorial splicing of exon pairs by two-site binding of U1 small nuclear ribonucleoprotein particle.

A two-site model for the binding of U1 small nuclear ribonucleoprotein particle (U1 snRNP) was tested in order to understand how exon partners are selected in complex pre-mRNAs containing alternative exons. In this model, it is proposed that two U1 snRNPs define a functional unit of splicing by base pairing to the 3' boundary of the downstream exon as well as the 5' boundary of the intron to be spliced. Three-exon substrates contained the alternatively spliced exon 4 (E4) region of the preprotachykinin gene. Combined 5' splice site mutations at neighboring exons demonstrate that weakened binding of U1 snRNP at the downstream site and improved U1 snRNP binding at the upstream site result in the failure to rescue splicing of the intron between the mutations. These results indicate the stringency of the requirement for binding a second U1 snRNP to the downstream 5' splice site for these substrates as opposed to an alternative model in which a certain threshold level of U1 snRNP can be provided at either site. Further support for the two-site model is provided by single-site mutations in the 5' splice site of the third exon, E5, that weaken base complementarity to U1 RNA. These mutations block E5 branchpoint formation and, surprisingly, generate novel branchpoints that are specified chiefly by their proximity to a cryptic 5' splice site located at the 3' terminus of the pre-mRNA. The experiments shown here demonstrate a true stimulation of 3' splice site activity by the downstream binding of U1 snRNP and suggest a possible mechanism by which combinatorial patterns of exon selection are achieved for alternatively spliced pre-mRNAs.