Allele-specific genetic interactions between Prp8 and RNA active site residues suggest a function for Prp8 at the catalytic core of the spliceosome.
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The highly conserved spliceosomal protein Prp8 is known to cross-link the critical sequences at both the 5' (GU) and 3' (YAG) ends of the intron. We have identified prp8 mutants with the remarkable property of suppressing exon ligation defects due to mutations in position 2 of the 5' GU, and all positions of the 3' YAG. The prp8 mutants also suppress mutations in position A51 of the critical ACAGAG motif in U6 snRNA, which has been observed previously to cross-link position 2 of the 5' GU. Other mutations in the 5' splice site, branchpoint, and neighboring residues of the U6 ACAGAG motif are not suppressed. Notably, the suppressed residues are specifically conserved from yeast to man, and from U2- to U12-dependent spliceosomes. We propose that Prp8 participates in a previously unrecognized tertiary interaction between U6 snRNA and both the 5' and 3' ends of the intron. This model suggests a mechanism for positioning the 3' splice site for catalysis, and assigns a fundamental role for Prp8 in pre-mRNA splicing. (+info)
Functional interactions of Prp8 with both splice sites at the spliceosomal catalytic center.
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A U5 snRNP protein, hPrp8, interacts closely with the GU dinucleotide at the 5' splice site (5'SS), forming a specific UV-inducible cross-link. To test if this physical contact between the 5'SS and the carboxy-terminal region of Prp8 reflects a functional recognition of the 5'SS during spliceosome assembly, we mutagenized the corresponding region of yeast Prp8 and screened the resulting mutants for suppression of 5'SS mutations in vivo. All of the isolated prp8 alleles not only suppress 5'SS but also 3'SS mutations, affecting the second catalytic step. Suppression of the 5'SS mutations by prp8 alleles was also tested in the presence of U1-7U snRNA, a predicted suppressor of the U+2A mutation. As expected, U1-7U efficiently suppresses prespliceosome formation, and the first, but not the second, step of U+2A pre-mRNA splicing. Independently, Prp8 functionally interacts with both splice sites at the later stage of splicing, affecting the efficiency of the second catalytic step. The striking proximity of two of the prp8 suppressor mutations to the site of the 5'SS:hPrp8 cross-link suggests that some protein:5'SS contacts made before the first step may be subsequently extended to accommodate the 3'SS for the second catalytic step. Together, these results strongly implicate Prp8 in specific interactions at the catalytic center of the spliceosome. (+info)
Yeast ortholog of the Drosophila crooked neck protein promotes spliceosome assembly through stable U4/U6.U5 snRNP addition.
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Mutants in the Drosophila crooked neck (crn) gene show an embryonic lethal phenotype with severe developmental defects. The unusual crn protein consists of sixteen tandem repeats of the 34 amino acid tetratricopeptide (TPR) protein recognition domain. Crn-like TPR elements are found in several RNA processing proteins, although it is unknown how the TPR repeats or the crn protein contribute to Drosophila development. We have isolated a Saccharomyces cerevisiae gene, CLF1, that encodes a crooked neck-like factor. CLF1 is an essential gene but the lethal phenotype of a clf1::HIS3 chromosomal null mutant can be rescued by plasmid-based expression of CLF1 or the Drosophila crn open reading frame. Clf1p is required in vivo and in vitro for pre-mRNA 5' splice site cleavage. Extracts depleted of Clf1p arrest spliceosome assembly after U2 snRNP addition but prior to productive U4/U6.U5 association. Yeast two-hybrid analyses and in vitro binding studies show that Clf1p interacts specifically and differentially with the U1 snRNP-Prp40p protein and the yeast U2AF65 homolog, Mud2p. Intriguingly, Prp40p and Mud2p also bind the phylogenetically conserved branchpoint binding protein (BBP/SF1). Our results indicate that Clf1p acts as a scaffolding protein in spliceosome assembly and suggest that Clf1p may support the cross-intron bridge during the prespliceosome-to-spliceosome transition. (+info)
Identification by mass spectrometry and functional analysis of novel proteins of the yeast [U4/U6.U5] tri-snRNP.
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The 25S [U4/U6.U5] tri-snRNP (small nuclear ribonucleoprotein) is a central unit of the nuclear pre-mRNA splicing machinery. The U4, U5 and U6 snRNAs undergo numerous rearrangements in the spliceosome, and knowledge of all of the tri-snRNP proteins is crucial to the detailed investigation of the RNA dynamics during the spliceosomal cycle. Here we characterize by mass spectrometric methods the proteins of the purified [U4/U6.U5] tri-snRNP from the yeast Saccharomyces cerevisiae. In addition to the known tri-snRNP proteins (only one, Lsm3p, eluded detection), we identified eight previously uncharacterized proteins. These include four Sm-like proteins (Lsm2p, Lsm5p, Lsm6p and Lsm7p) and four specific proteins named Snu13p, Dib1p, Snu23p and Snu66p. Snu13p comprises a putative RNA-binding domain. Interestingly, the Schizosaccharomyces pombe orthologue of Dib1p, Dim1p, was previously assigned a role in cell cycle progression. The role of Snu23p, Snu66p and, additionally, Spp381p in pre-mRNA splicing was investigated in vitro and/or in vivo. Finally, we show that both tri-snRNPs and the U2 snRNP are co-precipitated with protein A-tagged versions of Snu23p, Snu66p and Spp381p from extracts fractionated by glycerol gradient centrifugation. This suggests that these proteins, at least in part, are also present in a [U2.U4/U6.U5] tetra-snRNP complex. (+info)
Phosphorylation of splicing factor SF1 on Ser20 by cGMP-dependent protein kinase regulates spliceosome assembly.
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Splicing factor 1 (SF1) functions at early stages of pre-mRNA splicing and contributes to splice site recognition by interacting with the essential splicing factor U2AF65 and binding to the intron branch site. We have identified an 80 kDa substrate of cGMP-dependent protein kinase-I (PKG-I) isolated from rat brain, which is identical to SF1. PKG phosphorylates SF1 at Ser20, which inhibits the SF1-U2AF65 interaction leading to a block of pre-spliceosome assembly. Mutation of Ser20 to Ala or Thr also inhibits the interaction with U2AF65, indicating that Ser20 is essential for binding. SF1 is phosphorylated in vitro by PKG, but not by cAMP-dependent protein kinase A (PKA). Phosphorylation of SF1 also occurs in cultured neuronal cells and is increased on Ser20 in response to a cGMP analogue. These results suggest a new role for PKG in mammalian pre-mRNA splicing by regulating in a phosphorylation-dependent manner the association of SF1 with U2AF65 and spliceosome assembly. (+info)
Late changes in spliceosomal introns define clades in vertebrate evolution.
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The evolutionary origin of spliceosomal introns has been the subject of much controversy. Introns are proposed to have been both lost and gained during evolution. If the gain or loss of introns are unique events in evolution, they can serve as markers for phylogenetic analysis. We have made an extensive survey of the phylogenetic distribution of seven spliceosomal introns that are present in Fugu genes, but not in their mammalian homologues; we show that these introns were acquired by actinopterygian (ray-finned) fishes at various stages of evolution. We have also investigated the intron pattern of the rhodopsin gene in fishes, and show that the four introns found in the ancestral chordate rhodopsin gene were simultaneously lost in a common ancestor of ray-finned fishes. These changes in introns serve as excellent markers for phylogenetic analysis because they reliably define clades. Our intron-based cladogram establishes the difficult-to-ascertain phylogenetic relationships of some ray-finned fishes. For example, it shows that bichirs (Polypterus) are the sister group of all other extant ray-finned fishes. (+info)
Spliceosomal U snRNP core assembly: Sm proteins assemble onto an Sm site RNA nonanucleotide in a specific and thermodynamically stable manner.
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The association of Sm proteins with U small nuclear RNA (snRNA) requires the single-stranded Sm site (PuAU(4-6)GPu) but also is influenced by nonconserved flanking RNA structural elements. Here we demonstrate that a nonameric Sm site RNA oligonucleotide sufficed for sequence-specific assembly of a minimal core ribonucleoprotein (RNP), which contained all seven Sm proteins. The minimal core RNP displayed several conserved biochemical features of native U snRNP core particles, including a similar morphology in electron micrographs. This minimal system allowed us to study in detail the RNA requirements for Sm protein-Sm site interactions as well as the kinetics of core RNP assembly. In addition to the uridine bases, the 2' hydroxyl moieties were important for stable RNP formation, indicating that both the sugar backbone and the bases are intimately involved in RNA-protein interactions. Moreover, our data imply that an initial phase of core RNP assembly is mediated by a high affinity of the Sm proteins for the single-stranded uridine tract but that the presence of the conserved adenosine (PuAU.) is essential to commit the RNP particle to thermodynamic stability. Comparison of intact U4 and U5 snRNAs with the Sm site oligonucleotide in core RNP assembly revealed that the regions flanking the Sm site within the U snRNAs facilitate the kinetics of core RNP assembly by increasing the rate of Sm protein association and by decreasing the activation energy. (+info)
Characterization of a protein complex containing spliceosomal proteins SAPs 49, 130, 145, and 155.
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SF3b is a U2 snRNP-associated protein complex essential for spliceosome assembly. Although evidence that SF3b contains the spliceosomal proteins SAPs 49, 130, 145, and 155 has accumulated, a protein-mediated association between all of these proteins has yet to be directly demonstrated. Here we report the isolation of a cDNA encoding SAP 130, which completes the cloning of the putative SF3b complex proteins. Using antibodies to SAP 130 and other putative SF3b components, we showed that SAPs 130, 145, and 155 are present in a protein complex in nuclear extracts and that these proteins associate with one another in purified U2 snRNP. Moreover, SAPs 155 and 130 interact with each other (directly or indirectly) within this complex, and SAPs 49 and 145 are known to interact directly with each other. Thus, together with prior work, our studies indicate that SAPs 49, 130, 145, and 155 are indeed components of SF3b. The Saccharomyces cerevisiae homologs of SAPs 49 and 145 are encoded by essential genes. We show here that the S. cerevisiae homologs of SAPs 130 and 155 (scSAP 130/RSE1 and scSAP 155, respectively) are also essential. Recently, the SF3b proteins were found in purified U12 snRNP, which functionally substitutes for U2 snRNP in the minor spliceosome. This high level of conservation, together with the prior observation that the SF3b proteins interact with pre-mRNA very close to the branch site, suggest that the SF3b complex plays a critical role near or at the spliceosome catalytic core. (+info)