The mammalian homologue of Prp16p is overexpressed in a cell line tolerant to Leflunomide, a new immunoregulatory drug effective against rheumatoid arthritis.

Prp2p, Prp16p, Prp22p, and Prp43p are members of the DEAH-box family of ATP-dependent putative RNA helicases required for pre-mRNA splicing in Saccharomyces cerevisiae. Recently, mammalian homologues of Prp43p and Prp22p have been described, supporting the idea that splicing in yeast and man is phylogenetically conserved. In this study, we show that a murine cell line resistant to the novel immunoregulatory drug Leflunomide (Arava) overexpresses a 135-kDa protein that is a putative DEAH-box RNA helicase. We have cloned the human counterpart of this protein and show that it shares pronounced sequence homology with Prp16p. Apart from its N-terminal domain, which is rich in RS, RD, and RE dipeptides, this human homologue of Prp16p (designated hPrp16p) is 41% identical to Prp16p. Significantly, homology is not only observed within the phylogenetically conserved helicase domain, but also in Prp16p-specific sequences. Immunofluorescence microscopy studies demonstrated that hPrp16p co-localizes with snRNPs in subnuclear structures referred to as speckles. Antibodies specific for hPrp16p inhibited pre-mRNA splicing in vitro prior to the second step. Thus, like its yeast counterpart, hPrp16p also appears to be required for the second catalytic step of splicing. Taken together, our data indicate that the human 135-kDa protein identified here is the structural and functional homologue of the yeast putative RNA helicase, Prp16p.     

Brr2p carboxy-terminal Sec63 domain modulates Prp16 splicing RNA helicase

RNA helicases are essential for virtually all cellular processes, however, their regulation is poorly understood. The activities of eight RNA helicases are required for pre-mRNA splicing. Amongst these, Brr2p is unusual in having two helicase modules, of which only the amino-terminal helicase domain appears to be catalytically active. Using genetic and biochemical approaches, we investigated interaction of the carboxy-terminal helicase module, in particular the carboxy-terminal Sec63-2 domain, with the splicing RNA helicase Prp16p. Combining mutations in BRR2 and PRP16 suppresses or enhances physical interaction and growth defects in an allele-specific manner, signifying functional interactions. Notably, we show that Brr2p Sec63-2 domain can modulate the ATPase activity of Prp16p in vitro by interfering with its ability to bind RNA. We therefore propose that the carboxy-terminal helicase module of Brr2p acquired a regulatory function that allows Brr2p to modulate the ATPase activity of Prp16p in the spliceosome by controlling access to its RNA substrate/cofactor.     

Functional domains of the yeast splicing factor Prp22p

The essential Saccharomyces cerevisiae PRP22 gene encodes a 1145-amino acid DEXH box RNA helicase. Prp22p plays two roles during pre-mRNA splicing as follows: it is required for the second transesterification step and for the release of mature mRNA from the spliceosome. Whereas the step 2 function of Prp22p does not require ATP hydrolysis, spliceosome disassembly is dependent on the ATPase and helicase activities. Here we delineate a minimal functional domain, Prp22(262-1145), that suffices for the activity of Prp22p in vivo when expressed under the natural PRP22 promoter and for pre-mRNA splicing activity in vitro. The biologically active domain lacks an S1 motif (residues 177-256) that had been proposed to play a role in RNA binding by Prp22p. The deletion mutant Prp22(351-1145) can function in vivo when provided at a high gene dosage. We suggest that the segment from residues 262 to 350 enhances Prp22p function in vivo, presumably by targeting Prp22p to the spliceosome. We characterize an even smaller catalytic domain, Prp22(466-1145) that suffices for ATP hydrolysis, RNA binding, and RNA unwinding in vitro and for nuclear localization in vivo but cannot by itself support cell growth. However, the ATPase/helicase domain can function in vivo if the N-terminal region Prp22(1-480) is co-expressed in trans.     

Prp22, a DExH-box RNA helicase, plays two distinct roles in yeast pre-mRNA splicing.

In order to assess the role of Prp22 in yeast pre-mRNA splicing, we have purified the 130 kDa Prp22 protein and developed an in vitro depletion/reconstitution assay. We show that Prp22 is required for the second step of actin pre-mRNA splicing. Prp22 can act on pre-assembled spliceosomes that are arrested after step 1 in an ATP-independent fashion. The requirement for Prp22 during step 2 depends on the distance between the branchpoint and the 3' splice site, suggesting a previously unrecognized role for Prp22 in splice site selection. We characterize the biochemical activities of Prp22, a member of the DExH-box family of proteins, and we show that purified recombinant Prp22 protein is an RNA-dependent ATPase and an ATP-dependent RNA helicase. Prp22 uses the energy of ATP hydrolysis to effect the release of mRNA from the spliceosome. Thus, Prp22 has two distinct functions in yeast pre-mRNA splicing: an ATP-independent role during the second catalytic step and an ATP-requiring function in disassembly of the spliceosome.     

Interaction of the yeast DExH-box RNA helicase prp22p with the 3' splice site during the second step of nuclear pre-mRNA splicing

Using site-specific incorporation of the photochemical cross-linking reagent 4-thiouridine, we demonstrate the previously unknown association of two proteins with yeast 3′ splice sites. One of these is an unidentified ~122 kDa protein that cross-links to 3′ splice sites during formation of the pre-spliceosome. The other factor is the DExH-box RNA helicase, Prp22p. With substrates functional in the second step of splicing, only very weak cross-linking of Prp22p to intron sequences at the 3′ splice site is observed. In contrast, substrates blocked at the second step exhibit strong cross-linking of Prp22 to intron sequences at the 3′ splice site, but not to adjacent exon sequences. In vitro reconstitution experiments also show that the association of Prp22p with intron sequences at the 3′ splice site is dependent on Prp16p and does not persist when release of mature mRNA from the spliceosome is blocked. Taken together, these results suggest that the 3′ splice site of yeast introns is contacted much earlier than previously envisioned by a protein of ~120 kDa, and that a transient association of Prp22p with the 3′ splice site occurs between the first and second catalytic steps.     

Physical and genetic interactions of yeast Cwc21p,an ortholog of human SRm300/SRRM2, suggest a role at the catalytic center of the spliceosome

In Saccharomyces cerevisiae, Cwc21p is a protein of unknown function that is associated with the NineTeen Complex (NTC), a group of proteins involved in activating the spliceosome to promote the pre-mRNA splicing reaction. Here, we show that Cwc21p binds directly to two key splicing factors—namely, Prp8p and Snu114p—and becomes the first NTC-related protein known to dock directly to U5 snRNP proteins. Using a combination of proteomic techniques we show that the N-terminus of Prp8p contains an intramolecular fold that is a Snu114p and Cwc21p interacting domain (SCwid). Cwc21p also binds directly to the C-terminus of Snu114p. Complementary chemical cross-linking experiments reveal reciprocal protein footprints between the interacting Prp8 and Cwc21 proteins, identifying the conserved cwf21 domain in Cwc21p as a Prp8p binding site. Genetic and functional interactions between Cwc21p and Isy1p indicate that they have related functions at or prior to the first catalytic step of splicing, and suggest that Cwc21p functions at the catalytic center of the spliceosome, possibly in response to environmental or metabolic changes. We demonstrate that SRm300, the only SR-related protein known to be at the core of human catalytic spliceosomes, is a functional ortholog of Cwc21p, also interacting directly with Prp8p and Snu114p. Thus, the function of Cwc21p is likely conserved from yeast to humans.     

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.     

The splicing factor Prp17 interacts with the U2, U5 and U6 snRNPs and associates with the spliceosome pre- and post-catalysis

Saccharomyces cerevisiae PRP17-null mutants are temperature-sensitive for growth. In vitro splicing with extracts lacking Prp17 are kinetically slow for the first step of splicing and are arrested for the second step at temperatures greater than 34 degrees C. In the present study we show that these stalled spliceosomes are compromised for an essential conformational switch that is triggered by Prp16 helicase. These results suggest a plausible mechanistic basis for the second-step arrest in prp17Delta extracts and support a role for Prp17 in conjunction with Prp16. To understand the association of Prp17 with spliceosomes we used a functional epitope-tagged protein in co-immunoprecipitation experiments. Examination of co-precipitated snRNAs (small nuclear RNAs) show that Prp17 interacts with U2, U5 and U6 snRNPs (small nuclear ribonucleoproteins) but it is not a core component of any one snRNP. Prp17 association with in-vitro-assembled spliceosome complexes on actin pre-mRNAs was also investigated. Although the U5 snRNP proteins Prp8 and Snu114 are found in early pre-spliceosomes that contain all five snRNPs, Prp17 is not detectable at this step; however, Prp17 is present in the subsequent pre-catalytic A1 complex, containing unspliced pre-mRNA, formed after the dissociation of U4 snRNP. Thus Prp17 joins the spliceosome prior to both catalytic reactions. Our results indicate continued interactions in catalytic spliceosomes that contain reaction intermediates and in post-splicing complexes containing the lariat intron. These Prp17-spliceosome association analyses provide a biochemical basis for the delayed first step in prp17Delta and explain the previously known multiple genetic interactions between Prp17, factors of the Prp19-complex [NTC (nineteen complex)], functional elements in U2 and U5 snRNAs and other second-step splicing factors.     

Prp16p, Slu7p, and Prp8p interact with the 3' splice site in two distinct stages during the second catalytic step of pre-mRNA splicing.

For the second catalytic step of pre-mRNA splicing to occur, a 3' splice site must be selected and juxtaposed with the 5' exon. Four proteins, Prp16p, Slu7p, Prp17p, Prp18p, and an integral spliceosomal protein, Prp8p, are known to be required for the second catalytic step. prp8-101, an allele of PRP8 defective in 3' splice site recognition, exhibits specific genetic interactions with mutant alleles of the other second step splicing factors. The prp8-101 mutation also results in decreased crosslinking of Prp8p to the 3' splice site. To determine the role of the step-two-specific proteins in 3' splice site recognition and in binding of Prp8p to the 3' splice site, we performed crosslinking studies in mutant and immunodepleted extracts. Our results suggest an ordered pathway in which, after the first catalytic step, Prp16p crosslinks strongly to the 3' splice site and Prp8p and Slu7p crosslink weakly. ATP hydrolysis by Prp16p affects a conformational change that reduces the crosslinking of Prp16p with the 3' splice site and allows stronger crosslinking of Prp8p and Slu7p. Thus, the 3' splice site appears to be recognized in two stages during the second step of splicing. Strong 3' splice site crosslinking of Prp8p and Slu7p also requires the functions of Prp17p and Prp18p. Therefore, Prp8p and Slu7p interact with the 3' splice site at the latest stage of splicing prior to the second catalytic step that can currently be defined, and may be at the active site.     

Genetic interactions of conserved regions in the DEAD-box protein Prp28p.

The yeast PRP28 g ene has been implicated in nuclear precursor messenger RNA (pre-mRNA) splicing, a two-step reaction involved in a multitude of RNA structural alterations. Prp28p, the gene product of PRP28 , is a member of the evolutionarily conserved DEAD-box proteins (DBPs). Members of DBPs are involved in a variety of RNA-related biochemical processes, presumably by their putative RNA helicase activities. Prp28p has been speculated to play a role in melting the duplex between U4 and U6 small nuclear RNAs (snRNAs), leading to the formation of an active spliceosome. To study the function of Prp28p and its interactions with other components of the splicing machinery, we have isolated and characterized a large number of prp28 conditional mutants. Strikingly, many of these prp28 mutations are localized in the highly conserved motifs found in all the DBPs. Intragenic reversion analysis suggests that regions of motifs II, III and V, as well as of motifs I and IV, in Prp28p are likely to be in close proximity to each other. Our results thus provide the first hint of the local structural arrangement for Prp28p, and perhaps for other DBPs as well.     

Human homologs of yeast prp16 and prp17 reveal conservation of the mechanism for catalytic step II of pre-mRNA splicing.

Pre-mRNA splicing takes place in two catalytic steps. The second step is poorly understood, especially in mammals. In yeast, the splicing factors, Prps 16, 17, 18 and Slu7 function exclusively in step II. Here we report the isolation of cDNAs encoding human Prps 16 and 17 which are 41 and 36% identical to their yeast counterparts. The Prp16 gene is essential in yeast, and we show that a chimeric yeast-human Prp16 protein rescues a yeast Prp16 knockout strain. Immunodepletion of hPrp16 from splicing extracts specifically blocks step II, and the activity can be fully restored with recombinant hPrp16. Moreover, both hPrps 16 and 17 associate with the spliceosome late in the splicing pathway. Mutations at the 3' splice site that specifically block step II do not affect the association of hPrps 16 and 17 with the spliceosome, indicating that these factors may function at a stage of step II prior to recognition of the 3' splice site. Recently, the human homologs of Prp18 and Slu7 were identified. The observation that humans contain homologs of all four known step II proteins in yeast indicates that the mechanism for catalytic step II is highly conserved.     

Interaction between a G-patch protein and a spliceosomal DEXD/H-box ATPase that is critical for splicing

Prp2 is an RNA-dependent ATPase that activates the spliceosome before the first transesterification reaction of pre-mRNA splicing. Prp2 has extensive homology throughout the helicase domain characteristic of DEXD/H-box helicases and a conserved carboxyl-terminal domain also found in the spliceosomal helicases Prp16, Prp22, and Prp43. Despite the extensive homology shared by these helicases, each has a distinct, sequential role in splicing; thus, uncovering the determinants of specificity becomes crucial to the understanding of Prp2 and the other DEAH-splicing helicases. Mutations in an 11-mer near the C-terminal end of Prp2 eliminate its spliceosome binding and splicing activity. Here we show that a helicase-associated protein interacts with this domain and that this interaction contributes to the splicing process. First, a genome-wide yeast two-hybrid screen using Prp2 as bait identified Spp2, which contained a motif with glycine residues found in a number of RNA binding proteins. SPP2 was originally isolated as a genetic suppressor of a prp2 mutant. In a reciprocal screen, Spp2 specifically pulled out the C-terminal half of Prp2. Mutations in the Prp2 C-terminal 11-mer that disrupted function or spliceosome binding also disrupted Spp2 interaction. A screen of randomly mutagenized SPP2 clones identified an Spp2 protein with a mutation in the G patch that could restore interaction with Prp2 and enhanced splicing in a prp2 mutant strain. The study identifies a potential mechanism for Prp2 specificity mediated through a unique interaction with Spp2 and elucidates a role for a helicase-associated protein in the binding of a DEXD/H-box protein to the spliceosome.     

SNEV is an evolutionarily conserved splicing factor whose oligomerization is necessary for spliceosome assembly

We have isolated the human protein SNEV as downregulated in replicatively senescent cells. Sequence homology to the yeast splicing factor Prp19 suggested that SNEV might be the orthologue of Prp19 and therefore might also be involved in pre-mRNA splicing. We have used various approaches including gene complementation studies in yeast using a temperature sensitive mutant with a pleiotropic phenotype and SNEV immunodepletion from human HeLa nuclear extracts to determine its function. A human–yeast chimera was indeed capable of restoring the wild-type phenotype of the yeast mutant strain. In addition, immunodepletion of SNEV from human nuclear extracts resulted in a decrease of in vitro pre-mRNA splicing efficiency. Furthermore, as part of our analysis of protein–protein interactions within the CDC5L complex, we found that SNEV interacts with itself. The self-interaction domain was mapped to amino acids 56–74 in the protein's sequence and synthetic peptides derived from this region inhibit in vitro splicing by surprisingly interfering with spliceosome formation and stability. These results indicate that SNEV is the human orthologue of yeast PRP19, functions in splicing and that homo-oligomerization of SNEV in HeLa nuclear extract is essential for spliceosome assembly and that it might also be important for spliceosome stability.     

Snt309p, a Component of the Prp19p-Associated Complex That Interacts with Prp19p and Associates with the Spliceosome Simultaneously with or Immediately after Dissociation of U4 in the Same Manner as Prp19p

The yeast protein Prp19p is essential for pre-mRNA splicing and is associated with the spliceosome concurrently with or just after dissociation of U4 small nuclear RNA. In splicing extracts, Prp19p is associated with several other proteins in a large protein complex of unknown function, but at least one of these proteins is also essential for splicing (W.-Y. Tarn, C.-H. Hsu, K.-T. Huang, H.-R. Chen, H.-Y. Kao, K.-R. Lee, and S.-C. Cheng, EMBO J. 13:2421–2431, 1994). To identify proteins in the Prp19p-associated complex, we have isolated trans-acting mutations that exacerbate the phenotypes of conditional alleles of prp19, using the ade2-ade3 sectoring system. A novel splicing factor, Snt309p, was identified through such a screen. Although the SNT309 gene was not essential for growth of Saccharomyces cerevisiae under normal conditions, yeast cells containing a null allele of the SNT309 gene were temperature sensitive and accumulated pre-mRNA at the nonpermissive temperature. Far-Western blot analysis revealed direct interaction between Prp19p and Snt309p. Snt309p was shown to be a component of the Prp19p-associated complex by Western blot analysis. Immunoprecipitation studies demonstrated that Snt309p was also a spliceosomal component and associated with the spliceosome in the same manner as Prp19p during spliceosome assembly. These results suggest that the functions of Prp19p and Snt309p in splicing may require coordinate action of these two proteins.     

Comprehensive in vivo RNA-binding site analyses reveal a role of Prp8 in spliceosomal assembly

Prp8 stands out among hundreds of splicing factors as a protein that is intimately involved in spliceosomal activation and the catalytic reaction. Here, we present the first comprehensive in vivo RNA footprints for Prp8 in budding yeast obtained using CLIP (cross-linking and immunoprecipitation)/CRAC (cross-linking and analyses of cDNAs) and next-generation DNA sequencing. These footprints encompass known direct Prp8-binding sites on U5, U6 snRNA and intron-containing pre-mRNAs identified using site-directed cross-linking with in vitro assembled small nuclear ribonucleoproteins (snRNPs) or spliceosome. Furthermore, our results revealed novel Prp8-binding sites on U1 and U2 snRNAs. We demonstrate that Prp8 directly cross-links with U2, U5 and U6 snRNAs and pre-mRNA in purified activated spliceosomes, placing Prp8 in position to bring the components of the active site together. In addition, disruption of the Prp8 and U1 snRNA interaction reduces tri-snRNP level in the spliceosome, suggesting a previously unknown role of Prp8 in spliceosomal assembly through its interaction with U1 snRNA.     

Fission yeast Prp4p kinase regulates pre-mRNA splicing by phosphorylating a non-SR-splicing factor

We provide evidence that Prp4p kinase activity is required for pre-mRNA splicing in vivo and show that loss of activity impairs G₁–S and G₂–M progression in the cell cycle. Prp4p interacts genetically with the non-SR (serine/arginine) splicing factors Prp1p and Prp5p. Bacterially produced Prp1p is phosphorylated by Prp4p in vitro. Prp4p and Prp1p also interact in the yeast two-hybrid system. In vivo labelling studies using a strain with a mutant allele of the prp4 gene in the genetic background indicate a change in phosphorylation of the Prp1p protein. These results are consistent with the notion that Prp4p kinase is involved in the control of the formation of active spliceosomes, targeting non-SR splicing factors.     

Molecular dissection of step 2 catalysis of yeast pre-mRNA splicing investigated in a purified system

Step 2 catalysis of pre-mRNA splicing entails the excision of the intron and ligation of the 5′ and 3′ exons. The tasks of the splicing factors Prp16, Slu7, Prp18, and Prp22 in the formation of the step 2 active site of the spliceosome and in exon ligation, and the timing of their recruitment, remain poorly understood. Using a purified yeast in vitro splicing system, we show that only the DEAH-box ATPase Prp16 is required for formation of a functional step 2 active site and for exon ligation. Efficient docking of the 3′ splice site (3′SS) to the active site requires only Slu7/Prp18 but not Prp22. Spliceosome remodeling by Prp16 appears to be subtle as only the step 1 factor Cwc25 is dissociated prior to step 2 catalysis, with its release dependent on docking of the 3′SS to the active site and Prp16 action. We show by fluorescence cross-correlation spectroscopy that Slu7/Prp18 and Prp16 bind early to distinct, low-affinity binding sites on the step-1-activated B* spliceosome, which are subsequently converted into high-affinity sites. Our results shed new light on the factor requirements for step 2 catalysis and the dynamics of step 1 and 2 factors during the catalytic steps of splicing.     

Definition of a spliceosome interaction domain in yeast Prp2 ATPase

The Saccharomyces cerevisiae splicing factor Prp2 is an RNA-dependent ATPase required before the first transesterification reaction in pre-mRNA splicing. Prp2 binds to the spliceosome in the absence of ATP and is released following ATP hydrolysis. It contains three domains: a unique N-terminal domain, a helicase domain that is highly conserved in the DExD/H protein family, and a C-terminal domain that is conserved in spliceosomal DEAH proteins Prp2, Prp16, Prp22, and Prp43. We examined the role of each domain of Prp2 by deletion mutagenesis. Whereas deletions of either the helicase or C-terminal domain are lethal, deletions in the N-terminal domain have no detectable effect on Prp2 activity. Overexpression of the C-terminal domain of Prp2 exacerbates the temperature-sensitive phenotype of a prp2(Ts) strain, suggesting that the C-domain interferes with the activity of the Prp2(Ts) protein. A genetic approach was then taken to study interactions between Prp2 and the spliceosome. Previously, we isolated dominant negative mutants in the helicase domain of Prp2 that inhibit the activity of wild-type Prp2 when the mutant protein is overexpressed. We mutagenized one prp2 release mutant gene and screened for loss of dominant negative function. Several weak binding mutants were isolated and mapped to the C terminus of Prp2, further indicating the importance of the C terminus in spliceosome binding. This study is the first to indicate that amino acid substitutions outside the helicase domain can abolish spliceosome contact and splicing activity of a spliceosomal DEAH protein.