Impairment of yeast pre-mRNA splicing by potential secondary structure-forming sequences near the conserved branchpoint sequence.

The absolutely conserved TACTAAC box within introns of RNA polymerase II-transcribed genes of the yeast Saccharomyces cerevisiae serves an indispensable role in lariat formation. We show in this report that rather short palindromic sequences inserted into the yeast actin gene intron immediately 3' to the TACTAAC box block the second but not the first splicing step. In contrast, a palindromic sequence inserted some 23 bp 3' of the TACTAAC box did not affect correct and efficient splicing. The data suggest that hairpin structures that might form adjacent to the branchsite sequence interfere with some necessary alteration of the spliceosome required for 3' intron cleavage and exon ligation.     

Recognition of the TACTAAC box during mRNA splicing in yeast involves base pairing to the U2-like snRNA

The U2 snRNP binds to the site of branch formation during splicing of mammalian pre-mRNA in vitro. In Saccharomyces cerevisiae the branch site is within the so-called TACTAAC box (UACUAAC box), an absolutely conserved intron sequence required for splicing. Based on the identification and sequence of a U2 analogue in yeast, a specific base pairing interaction between the UACUAAC box and a highly conserved region of this snRNA can be proposed. To test this hypothesis, we have taken advantage of two mutations constructed previously in the UACUAAC box of an actin-HIS4 fusion. These mutant strains were transformed with stable plasmids bearing U2-like snRNAs into which changes predicted to restore base pairing had been introduced. Allele-specific suppression of biological and biochemical phenotypes was observed in both cases. Recognition of the UACUAAC box thus relies, at least in part, on Watson-Crick base pairing with the yeast U2 analogue.     

In vivo commitment to splicing in yeast involves the nucleotide upstream from the branch site conserved sequence and the Mud2 protein.

Pre-mRNA splicing is a stepwise nuclear process involving intron recognition and the assembly of the spliceosome followed by intron excision. We previously developed a pre-mRNA export assay that allows the discrimination between early steps of spliceosome formation and splicing per se. Here we present evidence that these two assays detect different biochemical defects for point mutations. Mutations at the 5' splice site lead to pre-mRNA export, whereas 3' splice site mutations do not. A genetic screen applied to mutants in the branch site region shows that all positions in the conserved TACTAAC sequence are important for intron recognition. An exhaustive analysis of pre-mRNA export and splicing defects of these mutants shows that the in vivo recognition of the branch site region does not involve the base pairing of U2 snRNA with the pre-mRNA. In addition, the nucleotide preceding the conserved TACTAAC sequence contributes to the recognition process. We show that a T residue at this position allows for optimal intron recognition and that in natural introns, this nucleotide is also used preferentially. Moreover, the Mud2 protein is involved in the recognition of this nucleotide, thus establishing a role for this factor in the in vivo splicing pathway.     

Homologous mRNA 3'' end formation in fission and budding yeast.

Sequences resembling polyadenylation signals of higher eukaryotes are present downstream of the Schizosaccharomyces pombe ura4+ and cdc10+ coding regions and function in HeLa cells. However, these and other mammalian polyadenylation signals are inactive in S. pombe. Instead, we find that polyadenylation signals of the CYC1 gene of budding yeast Saccharomyces cerevisiae function accurately and efficiently in fission yeast. Furthermore, a 38 bp deletion which renders this RNA processing signal non-functional in S. cerevisiae has the equivalent effect in S. pombe. We demonstrate that synthetic pre-mRNAs encoding polyadenylation sites of S. pombe genes are accurately cleaved and polyadenylated in whole cell extracts of S. cerevisiae. Finally, as is the case in S. cerevisiae, DNA sequences encoding regions proximal to the S. pombe mRNA 3' ends are found to be extremely AT rich; however, no general sequence motif can be found. We conclude that although fission yeast has many genetic features in common with higher eukaryotes, mRNA 3' end formation is significantly different and appears to be formed by an RNA processing mechanism homologous to that of budding yeast. Since fission and budding yeast are evolutionarily divergent, this lower eukaryotic mechanism of mRNA 3' end formation may be generally conserved.     

Formation of the yeast splicing complex A1 and association of the splicing factor PRP19 with the pre-mRNA are independent of the 3' region of the intron.

Assembly of the spliceosome is a step-wise process and involves sequential binding of snRNAs to the pre-mRNA to form pre-splicing complex A2-1. Subsequent dissociation of U4 from the spliceosome is accompanied by formation of complex A1 (Genes Dev. 1, 1014-1027, 1987). We show that the 3' region of the intron sequence is not required for efficient assembly of the yeast spliceosome. Truncated precursor mRNA retaining only four or five nucleotides 3' to the TACTAAC box formed pre-splicing complex A1, kinetically the last pre-mRNA containing splicing complex identified. The subsequent cleavage--ligation reaction requires at least 23 nucleotides on the 3' side of the TACTAAC box in a sequence-independent manner. Immunoprecipitation with anti-PRP19 antibody showed that association of PRP19 with the spliceosome was also independent of the 3' region of the intron.     

Molecular consequences of specific intron mutations on yeast mRNA splicing in vivo and in vitro

We have altered the TACTAAC sequence in the yeast CYH2m gene intron to TACTACC. This mutation changes the nucleotide at the normal position of the branch in intron RNA lariats produced during pre-mRNA splicing, and it prevents splicing in vivo. In a yeast pre-mRNA splicing system, CYH2m pre-mRNA carrying the TACTACC mutation is not specifically cut or rearranged in any way. Substitution of an A for the first G of the CYH2m intron, converting the highly conserved GTATGT 5' splice site sequence to ATATGT, also blocks intron excision in vivo and in vitro: pre-mRNA carrying this mutation was still cut normally at the mutant 5' splice site in vitro, to give authentic exon 1 and an intron-exon 2 lariat RNA with an A-A 2'-5' phosphodiester linkage at the branch point. This lariat RNA is a dead-end product. The subsequent cleavage at the 3' splice site is therefore sensitive to the sequence of the 5' end of the intron attached at the branch point.     

Differential nuclease sensitivity identifies tight contacts between yeast pre-mRNA and spliceosomes.

The oligonucleotide-directed RNase H sensitivity of a yeast (Saccharomyces cerevisiae) pre-mRNA was determined in an in vitro splicing reaction. While most of the pre-mRNA was sensitive to cleavage, the regions of the 5' splice site and TACTAAC box were found to be highly resistant. The biochemical requirements for protection against nuclease attack parallel those of both spliceosome formation and splicing. Most of the uncleaved pre-mRNA remaining after RNase H challenge was found associated with two forms of the yeast spliceosome. Differences in the RNase H sensitivity of pre-mRNA found in the two spliceosome forms indicate an increased association of splicing factors with the 5' splice site during spliceosome assembly.     

Early commitment of yeast pre-mRNA to the spliceosome pathway.

Pre-mRNA splicing in vitro is preceded by complex formation (spliceosome assembly). U2 small nuclear RNA (snRNA) is found in the earliest form of the spliceosome detected by native gel electrophoresis, both in Saccharomyces cerevisiae and in metazoan extracts. To examine the requirements for the formation of this early complex (band III) in yeast extracts, we cleaved the U2 snRNA by oligonucleotide-directed RNase H digestion. U2 snRNA depletion by this means inhibits both splicing and band III formation. Using this depleted extract, we were able to design a chase experiment which shows that a pre-mRNA substrate is committed to the spliceosome assembly pathway in the absence of functional U2 snRNP. Interactions occurring during the commitment step are highly resistant to the addition of an excess of unlabeled substrate and require little or no ATP. Sequence requirements for this commitment step have been analyzed by competition experiments with deletion mutants: both the 5' splice site consensus sequence and the branch point TACTAAC box sequence are necessary. These experiments strongly suggest that the initial assembly process requires a trans-acting factor(s) (RNA and/or proteins) that recognizes and stably binds to the two consensus sequences of the pre-mRNA prior to U2 snRNP binding.     

Pre-spliceosome formation in S.pombe requires a stable complex of SF1-U2AF(59)-U2AF(23)

We have initiated a biochemical analysis of splicing complexes in extracts from the fission yeast Schizosaccharomyces pombe. Extracts of S.pombe contain high levels of the spliceosome-like U2/5/6 tri-snRNP, which dissociates into mono-snRNPs in the presence of ATP, and supports binding of U2 snRNP to the 3' end of introns, yielding a weak ATP-independent E complex and the stable ATP-dependent complex A. The requirements for S.pombe complex A formation (pre-mRNA sequence elements, protein splicing factors, SF1/BBP and both subunits of U2AF) are analogous to those of mammalian complex A. The S.pombe SF1/BBP, U2AF(59) and U2AF(23) are tightly associated in a novel complex that is required for complex A formation. This pre-formed SF1- U2AF(59)-U2AF(23) complex may represent a streamlined mechanism for recognition of the branch site, pyrimidine tract and 3' splice site at the 3' end of introns.     

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.     

Introns and splicing elements of five diverse fungi

Genomic sequences and expressed sequence tag data for a diverse group of fungi (Saccharomyces cerevisiae, Schizosaccharomyces pombe, Aspergillus nidulans, Neurospora crassa, and Cryptococcus neoformans) provided the opportunity to accurately characterize conserved intronic elements. An examination of large intron data sets revealed that fungal introns in general are short, that 98% or more of them belong to the canonical splice site (ss) class (5'GU...AG3'), and that they have polypyrimidine tracts predominantly in the region between the 5' ss and the branch point. Information content is high in the 5' ss, branch site, and 3' ss regions of the introns but low in the exon regions adjacent to the introns in the fungi examined. The two yeasts have broader intron length ranges and correspondingly higher intron information content than the other fungi. Generally, as intron length increases in the fungi, so does intron information content. Homologs of U2AF spliceosomal proteins were found in all species except for S. cerevisiae, suggesting a nonconventional role for U2AF in the absence of canonical polypyrimidine tracts in the majority of introns. Our observations imply that splicing in fungi may be different from that in vertebrates and may require additional proteins that interact with polypyrimidine tracts upstream of the branch point. Theoretical protein homologs for Nam8p and TIA-1, two proteins that require U-rich regions upstream of the branch point to function, were found. There appear to be sufficient differences between S. cerevisiae and S. pombe introns and the introns of two filamentous members of the Ascomycota and one member of the Basidiomycota to warrant the development of new model organisms for studying the splicing mechanisms of fungi.     

p68 RNA helicase: identification of a nucleolar form and cloning of related genes containing a conserved intron in yeasts.

The human p68 protein is an RNA-dependent ATPase and RNA helicase which was first identified because of its immunological cross-reaction with a viral RNA helicase, simian virus 40 large T antigen. It belongs to a recently discovered family of proteins (DEAD box proteins) that share extensive regions of amino acid sequence homology, are ubiquitous in living organisms, and are involved in many aspects of RNA metabolism, including splicing, translation, and ribosome assembly. We have shown by immunofluorescent microscopy that mammalian p68, which is excluded from the nucleoli during interphase, translocates to prenucleolar bodies during telophase. We have cloned 55% identical genes from both Schizosaccharomyces pombe and Saccharomyces cerevisiae and shown that they are essential in both yeasts. The human and yeast genes contain a large intron whose position has been precisely conserved. In S. cerevisiae, the intron is unusual both because of its size and because of its location near the 3' end of the gene. We discuss possible functional roles for such an unusual intron in an RNA helicase gene.     

FELINES: a utility for extracting and examining EST-defined introns and exons

FELINES (Finding and Examining Lots of Intron 'N' Exon Sequences) is a utility written to automate construction and analysis of high quality intron and exon sequence databases produced from EST (expressed sequence tag) to genomic sequence alignments. We demonstrated the various programs of the FELINES utility by creating intron and exon sequence databases for the fungal organism Schizosaccharomyces pombe from alignments of EST to genomic sequences. In addition, we analyzed our constructed S.pombe sequence databases and the well-established Saccharomyces cerevisiae intron database from Manuel Ares' Laboratory for conserved sequence motifs. FELINES was shown to be useful for characterizing branchsites, polypyrimidine tracts and 5' and 3' splice sites in the intron databases and exonic splicing enhancers (ESEs) in S.pombe exons. FELINES is available at http://www.genome.ou.edu/informatics.html.     

Sequence dependent conformation and local geometry of the conserved branch site sequence element d(TpApCpTpApApC), essential for yeast mRNA splicing, deduced from high resolution 1H-NMR

The conserved sequence element and branch site splice signal d(TpApCpTpApApC) has been synthesized by a solid phase procedure. All the non-exchangeable protons have been assigned using a combination of one-dimensional and two-dimensional 1H-NMR analytical procedures. On the basis of the low NOE intensities in the 1D-NOE and NOESY experiments, the heptamer exists in solution as a random coil. The deoxyribose rings towards the 5' terminus exist predominantly in the S form (2'-endo-3'-exo) while residues on or adjacent to the 2' branch site in the eventual lariat structure [A(6) of TACTAAC] show more N-character (3'endo-2'-exo). In addition unique propeller twisting at contiguous AT base pairs in the consensus 5'-splice site occurs in the region in which there is partial complementarity with the branch splice signal TACTAAC. These subtle structural features, if carried over to the corresponding RNA, may have significance either as a recognition signals or for stereochemical reasons in the formation of the lariat intermediate in the maturation process of mRNA.