Yeast mRNA splicing in vitro

Synthetic actin and CYH2 pre-mRNAs containing a single intron are accurately spliced in a soluble whole cell extract of yeast. Splicing in vitro requires ATP. The excised intron is released as a lariat in which an RNA branch connects the 5' end of the molecule to the last A in the "intron conserved sequence" UACUAAC. Two other discrete RNA species produced during splicing in vitro may represent reaction intermediates: free, linear exon 1 and a form of the intron lariat extending beyond the 3' splice site to include exon 2. Both lariat forms correspond to molecules previously shown to be produced during yeast pre-mRNA splicing in vivo.     

Specific accessory sequences in Saccharomyces cerevisiae introns control assembly of pre-mRNAs into spliceosomes.

In experiments involving deletion and rearrangement of intron sequences two small regions of the intron in the yeast CYH2 ribosomal protein gene were found to play important roles in splicing of the pre-mRNA. One element lies downstream of the 5' splice site, and the other is upstream of the branchpoint sequence UACUAAC. Deletion of the element upstream of the branchpoint prevents spliceosome formation and blocks splicing in vivo and in vitro. Deletion of the element downstream of the 5' splice site does not on its own block splicing but rescues spliceosome formation and splicing of pre-mRNA lacking the element upstream of the branchpoint. These elements correspond to two regions of sequence complementarity which are a conserved feature of the introns in yeast pre-mRNAs. Mixing and matching of the elements from the ACT1 and CYH2 gene introns showed that these elements can cooperate in an intron-specific fashion to control spliceosome assembly.     

Cryptic branch point activation allows accurate in vitro splicing of human beta-globin intron mutants

The excised introns of pre-mRNAs and intron-containing splicing intermediates are in a lariat configuration in which the 5' end of the intron is linked by a 2'-5' phosphodiester bond (RNA branch) to a single adenosine residue near the 3' end of the intron. To determine the role of the specific sequence surrounding the RNA branch, we have mutated the branch point sequence of the human beta-globin IVS1. Pre-mRNAs lacking the authentic branch point sequence are accurately spliced in vitro; processing of the mutant pre-mRNAs generates RNA lariats due to the activation of cryptic branch points within IVS1. The cryptic branch points always occur at adenosine residues, but the sequences surrounding the branched nucleotide vary. Regardless of the type of mutation or the sequences remaining within IVS1, the cryptic branch points are 22 to 37 nucleotides upstream of the 3' splice site. These results suggest that RNA branch point selection is primarily based on a mechanism that measures the distance from the 3' splice site.     

Natural base-pairing interactions between 5' splice site and branch site sequences affect mammalian 5' splice site selection.

In the murine gene encoding the neuronal cell adhesion molecule (NCAM), the integrity of the 5' splice site of exon 18 (E18) is essential for regulation of alternative splicing. To further study the contribution of 5' splice site sequences, we used a simple NCAM pre-mRNA containing a portion of E18 fused to E19 and separated by a shortened intron. This RNA is spliced in vitro to produce five sets of lariat intermediates and products, the most abundant set displaying aberrant migration in acrylamide/urea gels. Base pairing interactions between positions +5 and +8 of the intron and positions -3 and -6 from the branch point were responsible for the faster migration of this set of lariat molecules. To test whether the duplex structure forms earlier and contributes to 5' splice site selection, we used NCAM substrates carrying the 5' splice sites of E17 and E18 in competition for the 3' splice site of E19. Mutations upstream of the major branch site improve E18/E19 splicing in NIH3T3 extracts, whereas compensatory mutations at positions +7 and +8 neutralize the effect of branch site mutations and curtail E18/E19 splicing. Our data suggest that duplex formation occurs early and interferes with the assembly of complexes initiated on the 5' splice site of NCAM E18. This novel type of intron interaction may exist in the introns of other mammalian pre-mRNAs.     

Spatial organization of protein-RNA interactions in the branch site-3' splice site region during pre-mRNA splicing in yeast

A series of efficiently spliced pre-mRNA substrates containing single 4-thiouridine residues were used to monitor RNA-protein interactions involving the branch site-3' splice site-3' exon region during yeast pre-mRNA splicing through cross-linking analysis. Prior to the assembly of the prespliceosome, Mud2p and the branch point bridging protein cross-link to a portion of this region in an ATP-independent fashion. Assembly of the prespliceosome leads to extensive cross-linking of the U2-associated protein Hsh155p to this region. Following the first step of splicing and in a manner independent of Prp16p, the U5 small nuclear ribonucleoprotein particle-associated protein Prp8p also associates extensively with the branch site-3' splice site-3' exon region. The subsequent cross-linking of Prp16p to the lariat intermediate is restricted to the 3' splice site and the adjacent 3' exon sequence. Using modified substrates to either mutationally or chemically block the second step, we found that the association of Prp22p with the lariat intermediate represents an authentic transient intermediate and appears to be restricted to the last eight intron nucleotides. Completion of the second step leads to the cross-linking of an unidentified approximately 80-kDa protein near the branch site sequence, suggesting a potential role for this protein in a later step in intron metabolism. Taken together, these data provide a detailed portrayal of the dynamic associations of proteins with the branch site-3' splice site region during spliceosome assembly and catalysis.     

Specific and stable intron-factor interactions are established early during in vitro pre-mRNA splicing

Biochemical components (splicing factors) interact with specific intron regions during pre-mRNA splicing in vitro. The pre-mRNA specifically associates with factors at both the branch point and the 5' splice site and these RNA-factor interactions are maintained in the intron-containing RNA processing products. The first detectable event, the ATP-dependent association of a factor (or factors) with the branch point, is mediated by at least one factor containing an essential nucleic acid component. Mutant RNA substrates that lack either the 5' splice site or the vast majority of exon sequences can still associate with the branch point binding factor(s). However, this branch point-factor interaction does not occur with a mutant RNA substrate that contains the branch point but that lacks the 3' splice site consensus sequence. These results suggest that selection of the 3' splice site accompanied by the association of a factor with the branch point may be the initial step in mammalian pre-mRNA splicing.     

Ribonucleoprotein complex formation during pre-mRNA splicing in vitro.

The ribonucleoprotein (RNP) structures of the pre-mRNA and RNA processing products generated during in vitro splicing of an SP6/beta-globin pre-mRNA were characterized by sucrose gradient sedimentation analysis. Early, during the initial lag phase of the splicing reaction, the pre-mRNA sedimented heterogeneously but was detected in both 40S and 60S RNP complexes. An RNA substrate lacking a 3' splice site consensus sequence was not assembled into the 60S RNP complex. The two splicing intermediates, the first exon RNA species and an RNA species containing the intron and the second exon in a lariat configuration (IVS1-exon 2 RNA species), were found exclusively in a 60S RNP complex. These two splicing intermediates cosedimented under a variety of conditions, indicating that they are contained in the same RNP complex. The products of the splicing reaction, accurately spliced RNA and the excised IVS1 lariat RNA species, are released from the 60S RNP complex and detected in smaller RNP complexes. Sequence-specific RNA-factor interactions within these RNP complexes were evidenced by the preferential protection of the pre-mRNA branch point from RNase A digestion and protection of the 2'-5' phosphodiester bond of the lariat RNA species from enzymatic debranching. The various RNP complexes were further characterized and could be distinguished by immunoprecipitation with anti-Sm and anti-(U1)RNP antibodies.     

Short artificial hairpins sequester splicing signals and inhibit yeast pre-mRNA splicing.

To examine the stability of yeast (Saccharomyces cerevisiae) pre-mRNA structures, we inserted a series of small sequence elements that generated potential RNA hairpins at the 5' splice site and branch point regions. We analyzed spliceosome assembly and splicing in vitro as well as splicing and nuclear pre-mRNA retention in vivo. Surprisingly, the inhibition of in vivo splicing approximately paralleled that of in vitro splicing. Even a 6-nucleotide hairpin could be shown to inhibit splicing, and a 15-nucleotide hairpin gave rise to almost complete inhibition. The in vitro results indicate that hairpins that sequester the 5' splice site have a major effect on the early steps of spliceosome assembly, including U1 small nuclear ribonucleoprotein binding. The in vivo experiments lead to comparable conclusions as the sequestering hairpins apparently result in the transport of pre-mRNA to the cytoplasm. The observations are compared with previous data from both yeast and mammalian systems and suggest an important effect of pre-mRNA structure on in vivo splicing.     

Antisense-targeted immuno-EM localization of the pre-mRNA path in the spliceosomal C complex

A first step in understanding the architecture of the spliceosome is elucidating the positions of individual spliceosomal components and functional centers. Catalysis of the first step of pre-mRNA splicing leads to the formation of the spliceosomal C complex, which contains the pre-mRNA intermediates--the cleaved 5' exon and the intron-3' exon lariat. To topographically locate the catalytic center of the human C complex, we first determined, by DNA oligonucleotide-directed RNAse H digestions, accessible pre-mRNA regions closest to nucleotides of the cleaved 5' splice site (i.e., the 3' end of exon 1 and the 5' end of the intron) and the intron lariat branch point, which are expected to be at/near the catalytic center in complex C. For electron microscopy (EM) localization studies, C complexes were allowed to form, and biotinylated 2'-OMe RNA oligonucleotides were annealed to these accessible regions. To allow localization by EM of the bound oligonucleotide, first antibiotin antibodies and then protein A-coated colloidal gold were additionally bound. EM analyses allowed us to map the position of exon and intron nucleotides near the cleaved 5' splice site, as well as close to the anchoring site just upstream of the branch adenosine. The identified positions in the C complex EM map give first hints as to the path of the pre-mRNA splicing intermediates in an active spliceosomal C complex and further define a possible location for its catalytic center.     

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.     

Mapping of branchpoint nucleotides in mutant pre-mRNAs expressed in plant cells

Pre-mRNA encoding rubisco activase in the Arabidopsis thaliana mutant rca contains a GU to AU change at the 5' splice site of intron 3 and this mutation results in accumulation of splicing intermediates bearing an incompletely processed intron. It has been demonstrated that one of the intermediates contains intron 3 in the form of a lariat and the branchpoint nucleotide has been mapped to the A residue at position −32 forming part of the sequence UUG A U. Analysis of a similar GU to AU 5' splice site mutation, present in a synthetic pre-mRNA context expressed in transfected protoplasts of Nicotiana plumbaginifolia , also suggests formation of lariats with branching occurring at A₋₃₁. A small fraction (approximately 10%) of this mutant pre-mRNA also underwent the second step of splicing. In addition to the consensus AG, an AU dinucleotide was used as splicing acceptor.     

Inefficient in vitro splicing of the regulatory intron of the L1 ribosomal protein gene of X.laevis depends on suboptimal splice site sequences.

The splicing of the third intron of the L1 r-protein gene of X.laevis was studied in the heterologous in vitro HeLa nuclear system. Despite the evolutionary distance, the cis-elements responsible for the default process play a similar role in the two organisms. Analysis of the splicing of various mutant substrates showed that the 5' splice site is primarily responsible for the low efficiency of splicing of the third intron. The suboptimal 5' splice site sequence leads to the utilization of an upstream alternative site which corresponds to the one utilized in vivo. The accumulation of splicing intermediates in the in vitro system allowed the identification of the branch site and of the branch consensus sequence. In contrast, the in vivo regulatory mechanism involving cleavage of the pre-mRNA is not mimicked in the HeLa extract.     

Distribution and consensus of branch point signals in eukaryotic genes: a computerized statistical analysis.

An intermediate stage in the process of eukaryotic RNA splicing is the formation of a lariat structure. It is anchored at an adenosine residue in intron between 10 and 50 nucleotides upstream of the 3' splice site. A short conserved sequence (the branch point sequence) functions as the recognition signal for the site of lariat formation. It has been generally assumed that the branch point is recognized mainly by the presence of its unique sequence where the lariat is formed. However, the known branch point consensus sequence is found to be distributed nearly randomly throughout the gene sequence with only a slightly higher frequency in the expected lariat region. Further, the known consensus sequence is found to be clearly inadequate to specify branch points. These observations have implications for understanding the mechanism of branch point recognition in the process of splicing, and the possible evolution of the branch point signal.     

Splicing and spliceosome formation of the yeast MATa1 transcript require a minimum distance from the 5'' splice site to the internal branch acceptor site.

Small deletions of 6, 7, and 12 nucleotides introduced between the 5' splice site and the internal branch acceptor site of the first intron of the yeast MATa1 gene completely abolish accurate splicing in vitro in these constructs. Splicing only occurs at an alternative 5' splice site which was found in the first exon of the MATa1 gene and which is used both in vivo and in vitro. The splicing defect cannot be cured by expanding the distance from the branch point to the 3' splice site. If the alternative 5' splice site is deleted as well in these constructs, neither spliced products nor spliceosomes are formed. Our findings especially lead to the conclusion that a minimum distance between the 5' splice site and the internal branch acceptor site of the intron is required for the formation of splicing complexes and for accurate splicing.     

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.     

Self-splicing of group II introns in vitro: lariat formation and 3' splice site selection in mutant RNAs

Deletion or substitution of the branch A residue in group II intron bl1 significantly reduces splicing activity; yet, residual exon ligation is correct, and lariats have their branch points at the normal distance from the 3' end of the intron. Mutations in the sequence facing the branch point also allow residual lariat formation; however, free 3' exons are generated with false 5' termini, all of which are within a UCACA consensus sequence located upstream or downstream of the normal 3' splice site. These results indicate that both the conserved 3' splice site APy and the spatial arrangements in stem 6 are crucial for correct 3' splice site selection.     

An LKB1 AT-AC intron mutation causes Peutz-Jeghers syndrome via splicing at noncanonical cryptic splice sites

Peutz-Jeghers syndrome (PJS) is an autosomal dominant disorder associated with gastrointestinal polyposis and an increased cancer risk. PJS is caused by germline mutations in the tumor suppressor gene LKB1. One such mutation, IVS2+1A>G, alters the second intron 5' splice site, which has sequence features of a U12-type AT-AC intron. We report that in patients, LKB1 RNA splicing occurs from the mutated 5' splice site to several cryptic, noncanonical 3' splice sites immediately adjacent to the normal 3' splice site. In vitro splicing analysis demonstrates that this aberrant splicing is mediated by the U12-dependent spliceosome. The results indicate that the minor spliceosome can use a variety of 3' splice site sequences to pair to a given 5' splice site, albeit with tight constraints for maintaining the 3' splice site position. The unusual splicing defect associated with this PJS-causing mutation uncovers differences in splice-site recognition between the major and minor pre-mRNA splicing pathways.