Rds3p is required for stable U2 snRNP recruitment to the splicing apparatus

Rds3p is a well-conserved 12-kDa protein with five CxxC zinc fingers that has been implicated in the activation of certain drug transport genes and in the pre-mRNA splicing pathway. Here we show that Rds3p resides in the yeast spliceosome and is essential for splicing in vitro. Rds3p purified from yeast stably associates with at least five U2 snRNP proteins, Cus1p, Hsh49p, Hsh155p, Rse1p, and Ist3p/Snu17p, and with the Yra1p RNA export factor. A mutation upstream of the first Rds3p zinc finger causes the conditional release of the putative branchpoint nucleotide binding protein, Ist3p/Snu17p, and weakens Rse1p interaction with the Rds3p complex. The resultant U2 snRNP particle migrates exceptionally slowly in polyacrylamide gels, suggestive of a disorganized structure. U2 snRNPs depleted of Rds3p fail to form stable prespliceosomes, although U2 snRNA stability is not affected. Metabolic depletion of Yra1p blocks cell growth but not splicing, suggesting that Yra1p association with Rds3p relates to Yra1p's role in RNA trafficking. Together these data establish Rds3p as an essential component of the U2 snRNP SF3b complex and suggest a new link between the nuclear processes of pre-mRNA splicing and RNA export.     

Interactions of the yeast SF3b splicing factor

The U2 snRNP promotes prespliceosome assembly through interactions that minimally involve the branchpoint binding protein, Mud2p, and the pre-mRNA. We previously showed that seven proteins copurify with the yeast (Saccharomyces cerevisiae) SF3b U2 subcomplex that associates with the pre-mRNA branchpoint region: Rse1p, Hsh155p, Hsh49p, Cus1p, and Rds3p and unidentified subunits p10 and p17. Here proteomic and genetic studies identify Rcp10p as p10 and show that it contributes to SF3b stability and is necessary for normal cellular Cus1p accumulation and for U2 snRNP recruitment in splicing. Remarkably, only the final 53 amino acids of Rcp10p are essential. p17 is shown to be composed of two accessory splicing factors, Bud31p and Ist3p, the latter of which independently associates with the RES complex implicated in the nuclear pre-mRNA retention. A directed two-hybrid screen reveals a network of prospective interactions that includes previously unreported intra-SF3b contacts and SF3b interactions with the RES subunit Bud13p, the Prp5p DExD/H-box protein, Mud2p, and the late-acting nineteen complex. These data establish the concordance of yeast and mammalian SF3b complexes, implicate accessory splicing factors in U2 snRNP function, and support SF3b contribution from early pre-mRNP recognition to late steps in splicing.     

The Clf1p splicing factor promotes spliceosome assembly through N-terminal tetratricopeptide repeat contacts

Spliceosome assembly follows a well conserved pathway of subunit addition that includes both small nuclear ribonucleoprotein (snRNP) particles and non-snRNP splicing factors. Clf1p is an unusual splicing factor composed almost entirely of direct repeats of the tetratricopeptide repeat (TPR) protein-binding motif. Here we show that the Clf1p protein resides in at least two multisubunit protein complexes, a small nuclear RNA-free structure similar to what was reported as the Prp19p complex (nineteen complex; NTC) and an RNP structure that contains the U2, U5, and U6 small nuclear RNAs. Thirty Ccf (Clf1p complex factor) proteins have been identified by mass spectroscopy or immune detection as known or suspected components of the yeast spliceosome. Deletion of TPR1 or TPR2 from an epitope-tagged Clf1p protein (i.e. Clf1Delta2-TAP) destabilizes Clf1p complexes assembled in vivo, causing the release of the Cef1p and Prp19p NTC factors and decreased association of the Rse1p, Snu114p, and Hsh155p snRNP proteins. In vitro, temperature inactivation of Clf1Delta2p impairs the prespliceosome to spliceosome transition and prevents Prp19p recruitment to the splicing complex. These and related data support the view that the poly-TPR Clf1p splicing factor promotes the functional integration of the U4/U6.U5 tri-snRNP particle into the U1-, U2-dependent prespliceosome.     

The yeast U5 snRNP coisolated with the U1 snRNP has an unexpected protein composition and includes the splicing factor Aar2p.

We describe the purification and characterization of a 16S U5 snRNP from the yeast Saccharomyces cerevisiae and the identification of its proteins. In contrast to the human 20S U5 snRNP, it has a comparatively simple protein composition. In addition to the Sm core proteins, it contains only two of the U5 snRNP specific proteins, Prp8p and Snu114p. Interestingly, the 16S U5 snRNP contains also Aar2p, a protein that was previously implicated in splicing of the two introns of the MATa1 pre-mRNA. Here, we demonstrate that Aar2p is essential and required for in vivo splicing of U3 precursors. However, it is not required for splicing in vitro. Aar2p is associated exclusively with this simple form of the U5 snRNP (Aar2-U5), but not with the [U4/U6.U5] tri-snRNP or spliceosomal complexes. Consistent with this, we show that depletion of Aar2p interferes with later rounds of splicing, suggesting that it has an effect when splicing depends on snRNP recycling. Remarkably, the Aar2-U5 snRNP is invariably coisolated with the U1 snRNP regardless of the purification protocol used. This is consistent with the previously suggested cooperation between the U1 and U5 snRNPs prior to the catalytic steps of splicing. Electron microscopy of the Aar2-U5 snRNP revealed that, despite the comparatively simple protein composition, the yeast Aar2-U5 snRNP appears structurally similar to the human 20S U5 snRNP. Thus, the basic structural scaffold of the Aar2-U5 snRNP seems to be essentially determined by Prp8p, Snu114p, and the Sm proteins.     

Proteomic analysis identifies a new complex required for nuclear pre-mRNA retention and splicing

Using the proteomic tandem affinity purification (TAP) method, we have purified the Saccharomyces cerevisie U2 snRNP-associated splicing factors SF3a and SF3b. While SF3a purification revealed only the expected subunits Prp9p, Prp11p and Prp21p, yeast SF3b was found to contain only six subunits, including previously known components (Rse1p, Hsh155p, Cus1p, Hsh49p), the recently identified Rds3p factor and a new small essential protein (Ysf3p) encoded by an unpredicted split ORF in the yeast genome. Surprisingly, Snu17p, the proposed yeast orthologue of the seventh human SF3b subunit, p14, was not found in the yeast complex. TAP purification revealed that Snu17p, together with Bud13p and a newly identified factor, Pml1p/Ylr016c, form a novel trimeric complex. Subunits of this complex were not essential for viability. However, they are required for efficient splicing in vitro and in vivo. Furthermore, inactivation of this complex causes pre-mRNA leakage from the nucleus. The corresponding complex was named pre-mRNA REtention and Splicing (RES). The presence of RES subunit homologues in numerous eukaryotes suggests that its function is evolutionarily conserved.     

The first ATPase domain of the yeast 246-kDa protein is required for in vivo unwinding of the U4/U6 duplex.

The yeast PRP44 gene, alternatively named as BRR2, SLT22, RSS1, or SNU246, encodes a 246-kDa protein with putative RNA helicase function during pre-mRNA splicing. The protein is a typical DEAD/H family member, but unlike most other members of this family, it contains two putative RNA helicase domains, each with a highly conserved ATPase motif. Prior to this study little was known about functional roles for these two domains. We present genetic and biochemical evidence that ATPase motifs of only the first helicase domain are required for cell viability and pre-mRNA splicing. Overexpression of mutations in the first domain results in a dominant negative phenotype, and extracts from these mutant strains inhibit in vitro pre-mRNA splicing. In vitro analyses of affinity purified proteins revealed that only the first helicase domain possesses poly (U)-dependent ATPase activity. Overexpression of a dominant negative protein in vivo reduces the relative abundance of free U4 and U6 snRNA with a concomitant accumulation of the U4/U6 duplex. Accumulation of the U4/U6 duplex was relieved by overexpression of wild-type Prp44p. Three DEAD/H box proteins, Prp16p, Prp22p and Prp44p, have previously been shown to affect U4/U6 unwinding activity in vitro. The possible role of these proteins in mediating this reaction in vivo was explored following induced expression of ATPase domain mutants in each of these. Although overexpression of the mutant form of either Prp16p, Prp22p, or Prp44p was lethal, only expression of the mutant Prp44p resulted in accumulation of the U4/U6 helix. Our results, when combined with previously published in vitro results, support a direct role for Prp44p in unwinding of the U4/U6 helix.     

Functional contacts with a range of splicing proteins suggest a central role for Brr2p in the dynamic control of the order of events in spliceosomes of Saccharomyces cerevisiae

Mapping of functional protein interactions will help in understanding conformational rearrangements that occur within large complexes like spliceosomes. Because the U5 snRNP plays a central role in pre-mRNA splicing, we undertook exhaustive two-hybrid screening with Brr2p, Prp8p, and other U5 snRNP-associated proteins. DExH-box protein Brr2p interacted specifically with five splicing factors: Prp8p, DEAH-box protein Prp16p, U1 snRNP protein Snp1p, second-step factor Slu7p, and U4/U6.U5 tri-snRNP protein Snu66p, which is required for splicing at low temperatures. Co-immunoprecipitation experiments confirmed direct or indirect interactions of Prp16p, Prp8p, Snu66p, and Snp1p with Brr2p and led us to propose that Brr2p mediates the recruitment of Prp16p to the spliceosome. We provide evidence that the prp8-1 allele disrupts an interaction with Brr2p, and we propose that Prp8p modulates U4/U6 snRNA duplex unwinding through another interaction with Brr2p. The interactions of Brr2p with a wide range of proteins suggest a particular function for the C-terminal half, bringing forward the hypothesis that, apart from U4/U6 duplex unwinding, Brr2p promotes other RNA rearrangements, acting synergistically with other spliceosomal proteins, including the structurally related Prp2p and Prp16p. Overall, these protein interaction studies shed light on how splicing factors regulate the order of events in the large spliceosome complex.     

PUF60: a novel U2AF65-related splicing activity

We have identified a new pyrimidine-tract binding factor, PUF, that is required, together with U2AF, for efficient reconstitution of RNA splicing in vitro. The activity has been purified and consists of two proteins, PUF60 and the previously described splicing factor p54. p54 and PUF60 form a stable complex in vitro when cotranslated in a reaction mixture. PUF activity, in conjunction with U2AF, facilitates the association of U2 snRNP with the pre-mRNA. This reaction is dependent upon the presence of the large subunit of U2AF, U2AF65, but not the small subunit U2AF35. PUF60 is homologous to both U2AF65 and the yeast splicing factor Mud2p. The C-terminal domain of PUF60, the PUMP domain, is distantly related to the RNA-recognition motif domain, and is probably important in protein-protein interactions.     

The purified yeast pre-mRNA splicing factor PRP2 is an RNA-dependent NTPase.

Unlike autocatalyzed self-splicing reactions, nuclear pre-mRNA splicing requires transacting macromolecules and ATP. A protein encoded by the PRP2 gene of Saccharomyces cerevisiae is required, in conjunction with ATP, for the first cleavage-ligation reaction of pre-mRNA splicing. In this study, we have purified two forms of the PRP2 gene product with apparent molecular weights of 100 kDa and 92 kDa, from a yeast strain overproducing the protein. Both proteins were indistinguishable in their ability to complement extracts derived from a heat-sensitive prp2 mutant. Furthermore, we show that the PRP2 protein is capable of hydrolyzing nucleoside triphosphates in the presence of single-stranded RNAs such as poly(U). However, purified PRP2 by itself did not unwind double-stranded RNA substrates. The fact that an RNA-dependent NTPase activity is intrinsic to PRP2 may account for the ATP requirement in the first catalytic reaction of pre-mRNA splicing.     

In vitro reconstitution of mammalian U1 snRNPs active in splicing: the U1-C protein enhances the formation of early (E) spliceosomal complexes.

We have established an in vitro reconstitution/splicing complementation system which has allowed the investigation of the role of mammalian U1 snRNP components both in splicing and at the early stages of spliceosome formation. U1 snRNPs reconstituted from purified, native snRNP proteins and either authentic or in vitro transcribed U1 snRNA restored both early (E) splicing complex formation and splicing-activity to U1-depleted extracts. In vitro reconstituted U1 snRNPs possessing an m3G or ApppG cap were equally active in splicing, demonstrating that a physiological cap structure is not absolutely required for U1 function. However, the presence of an m7GpppG or GpppG cap was deleterious to splicing, most likely due to competition for the m7G cap binding proteins. No significant reduction in splicing or E complex formation was detected with U1 snRNPs reconstituted from U1 snRNA lacking the RNA binding sites of the U1-70K or U1-A protein (i.e., stem-loop I and II, respectively). Complementation studies with purified HeLa U1 snRNPs lacking subsets of the U1-specific proteins demonstrated a role for the U1-C, but not U1-A, protein in the formation and/or stabilization of early splicing complexes. Studies with recombinant U1-C protein mutants indicated that the N-terminal domain of U1-C is necessary and sufficient for the stimulation of E complex formation.     

A BBP-Mud2p heterodimer mediates branchpoint recognition and influences splicing substrate abundance in budding yeast

The 3' end of mammalian introns is marked by the branchpoint binding protein, SF1, and the U2AF65-U2AF35 heterodimer bound at an adjacent sequence. Baker's yeast has equivalent proteins, branchpoint binding protein (BBP) (SF1) and Mud2p (U2AF65), but lacks an obvious U2AF35 homolog, leaving open the question of whether another protein substitutes during spliceosome assembly. Gel filtration, affinity selection and mass spectrometry were used to show that rather than a U2AF65/U2AF35-like heterodimer, Mud2p forms a complex with BBP without a third (U2AF35-like) factor. Using mutants of MUD2 and BBP, we show that the BBP-Mud2p complex bridges partner-specific Prp39p, Mer1p, Clf1p and Smy2p two-hybrid interactions. In addition to inhibiting Mud2p association, the bbpDelta56 mutation impairs splicing, enhances pre-mRNA release from the nucleus, and similar to a mud2::KAN knockout, suppresses a lethal sub2::KAN mutation. Unexpectedly, rather than exacerbating bbpDelta56, the mud2::KAN mutation partially suppresses a pre-mRNA accumulation defect observed with bbpDelta56. We propose that a BBP-Mud2p heterodimer binds as a unit to the branchpoint in vivo and serves as a target for the Sub2p-DExD/H-box ATPase and for other splicing factors during spliceosome assembly. In addition, our results suggest the possibility that the Mud2p may enhance the turnover of pre-mRNA with impaired BBP-branchpoint association.     

Identification by mass spectrometry and functional analysis of novel proteins of the yeast [U4/U6.U5] tri-snRNP.

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.     

SLU7 and a novel activity, SSF1, act during the PRP16-dependent step of yeast pre-mRNA splicing.

Understanding the mechanism of pre-mRNA splicing requires the characterization of all components involved. In the present study, we used the genetically and biochemically defined yeast PRP16 protein as a point of departure for the identification of additional factors required for the second catalytic step in vitro. We isolated by glycerol gradient sedimentation spliceosomes that were formed in yeast extracts depleted of PRP16. This procedure separated the spliceosomal complexes containing lariat intermediate and exon 1 from free proteins present in the whole-cell yeast extract. We then supplemented these spliceosomes with purified proteins or yeast extract fractions as a functional assay for second-step splicing factors. We show that SLU7 protein and a novel activity that we named SSF1 (second-step factor 1) were required in concert with PRP16 to promote progression through the second catalytic step of splicing. Taking advantage of a differential ATP requirement for PRP16 and SLU7 function, we show that SLU7 can act after PRP16 in the splicing pathway.     

Structural requirements for the function of a yeast chromosomal replicator

We have investigated the role of small nuclear ribonucleoprotein particles (snRNPs) in the in vitro splicing of messenger RNA precursors by a variety of procedures. Removal of the U-type snRNPs from the nuclear extracts of HeLa cells with protein A-Sepharose-coupled human autoimmune antibodies leads to complete loss of splicing activity. The inhibition of splicing can be prevented by saturating the coupled antibodies with purified nucleoplasmic U snRNPs prior to incubation with nuclear extract. We further demonstrate that an intact 5' terminus of U1 snRNA is required for the functioning of U1 snRNP in the splicing reaction. Antibodies directed against the trimethylated cap structure of the U snRNAs inhibit splicing. Upon removal of the first eight nucleotides of the U1 snRNA in the particles by site-directed hydrolysis with ribonuclease H in the presence of a synthetic complementary oligodeoxynucleotide splicing is completely abolished. These results are in strong support of current models suggesting that a base-pairing interaction between the 5' terminus of the U1 snRNA and the 5' splice site of a mRNA precursor is a prerequisite for proper splicing.     

Systematic two-hybrid and comparative proteomic analyses reveal novel yeast pre-mRNA splicing factors connected to Prp19

Prp19 is the founding member of the NineTeen Complex, or NTC, which is a spliceosomal subcomplex essential for spliceosome activation. To define Prp19 connectivity and dynamic protein interactions within the spliceosome, we systematically queried the Saccharomyces cerevisiae proteome for Prp19 WD40 domain interaction partners by two-hybrid analysis. We report that in addition to S. cerevisiae Cwc2, the splicing factor Prp17 binds directly to the Prp19 WD40 domain in a 1:1 ratio. Prp17 binds simultaneously with Cwc2 indicating that it is part of the core NTC complex. We also find that the previously uncharacterized protein Urn1 (Dre4 in Schizosaccharomyces pombe) directly interacts with Prp19, and that Dre4 is conditionally required for pre-mRNA splicing in S. pombe. S. pombe Dre4 and S. cerevisiae Urn1 co-purify U2, U5, and U6 snRNAs and multiple splicing factors, and dre4Δ and urn1Δ strains display numerous negative genetic interactions with known splicing mutants. The S. pombe Prp19-containing Dre4 complex co-purifies three previously uncharacterized proteins that participate in pre-mRNA splicing, likely before spliceosome activation. Our multi-faceted approach has revealed new low abundance splicing factors connected to NTC function, provides evidence for distinct Prp19 containing complexes, and underscores the role of the Prp19 WD40 domain as a splicing scaffold.     

A novel SR-related protein is required for the second step of Pre-mRNA splicing

The SR family proteins and SR-related polypeptides are important regulators of pre-mRNA splicing. A novel SR-related protein of an apparent molecular mass of 53 kDa was isolated in a gene trap screen that identifies proteins which localize to the nuclear speckles. This novel protein possesses an arginine- and serine-rich domain and was termed SRrp53 (for SR-related protein of 53 kDa). In support for a role of this novel RS-containing protein in pre-mRNA splicing, we identified the mouse ortholog of the Saccharomyces cerevisiae U1 snRNP-specific protein Luc7p and the U2AF65-related factor HCC1 as interacting proteins. In addition, SRrp53 is able to interact with some members of the SR family of proteins and with U2AF35 in a yeast two-hybrid system and in cell extracts. We show that in HeLa nuclear extracts immunodepleted of SRrp53, the second step of pre-mRNA splicing is blocked, and recombinant SRrp53 is able to restore splicing activity. SRrp53 also regulates alternative splicing in a concentration-dependent manner. Taken together, these results suggest that SRrp53 is a novel SR-related protein that has a role both in constitutive and in alternative splicing.     

A comprehensive biochemical and genetic analysis of the yeast U1 snRNP reveals five novel proteins.

The U1 snRNP is essential for recognition of the pre-mRNA 5'-splice site and the subsequent assembly of the spliceosome. Yeast U1 snRNP is considerably more complex than its metazoan counterpart, which suggests possible differences between yeast and metazoa in early splicing events. We have comprehensively analyzed the composition of yeast U1 snRNPs using a combination of biochemical, mass spectrometric, and genetic methods. We demonstrate the specific association of four novel U1 snRNP proteins, Snu71p, Snu65p, Nam8p, and Snu56p, that have no known metazoan homologues. A fifth protein, Npl3p, is an abundant cellular component that reproducibly co-purifies with the U1 snRNP, but its association is salt-sensitive. Therefore, we are unable to establish conclusively whether it binds specifically to the U1 snRNP. Interestingly, Nam8p and Npl3p were previously assigned functions in (pre-m)RNA-metabolism; however, so far, no association with U1 snRNP has been demonstrated or proposed. We also show that the yeast SmB protein is a U1 snRNP component. Yeast U1 snRNP therefore contains 16 different proteins, including seven snRNP core proteins, three homologues of the metazoan U1 snRNP-specific proteins, and six yeast-specific U1 snRNP proteins. We have simultaneously continued the characterization of additional mutants isolated in a synthetic lethal (MUD) screen for genes that functionally cooperate with U1 snRNA. Consistent with the biochemical results, mud10, mud15, and mud16 are alleles of SNU56, NAM8, and SNU65, respectively. mud10 and mud15 affect the in vivo splicing efficiency of noncanonical introns. Moreover, mud10p strongly affects the in vitro formation of splicing complexes, and extracts from the mud15 strain contain a U1 snRNP that migrates aberrantly on native gels. Finally, we show that Nam8p/Mud15p contributes to the stability of U1 snRNP.