The structure of Prp40 FF1 domain and its interaction with the crn-TPR1 motif of Clf1 gives a new insight into the binding mode of FF domains

The yeast splicing factor Prp40 (pre-mRNA processing protein 40) consists of a pair of WW domains followed by several FF domains. The region comprising the FF domains has been shown to associate with the 5' end of U1 small nuclear RNA and to interact directly with two proteins, the Clf1 (Crooked neck-like factor 1) and the phosphorylated repeats of the C-terminal domain of RNA polymerase II (CTD-RNAPII). In this work we reported the solution structure of the first FF domain of Prp40 and the identification of a novel ligand-binding site in FF domains. By using chemical shift assays, we found a binding site for the N-terminal crooked neck tetratricopeptide repeat of Clf1 that is distinct and structurally separate from the previously identified CTD-RNAPII binding pocket of the FBP11 (formin-binding protein 11) FF1 domain. No interaction, however, was observed between the Prp40 FF1 domain and three different peptides derived from the CTD-RNAPII protein. Indeed, the equivalent CTD-RNAPII-binding site in the Prp40 FF1 domain is predominantly negatively charged and thus unfavorable for an interaction with phosphorylated peptide sequences. Sequence alignments and phylogenetic tree reconstructions using the FF domains of three functionally related proteins, Prp40, FBP11, and CA150, revealed that Prp40 and FBP11 are not orthologous proteins and supported the different ligand specificities shown by their respective FF1 domains. Our results also revealed that not all FF domains in Prp40 are functionally equivalent. We proposed that at least two different interaction surfaces exist in FF domains that have evolved to recognize distinct binding motifs.     

Multiple factors including the small nuclear ribonucleoproteins U1 and U2 are necessary for pre-mRNA splicing in vitro

We have identified six distinct factors necessary for pre-mRNA splicing in vitro by selective inactivation and complementation studies, and by fractionation procedures. Splicing factor 1 (SF1) is sensitive to micrococcal nuclease, and appears to consist of at least U1 and U2 snRNPs, since splicing is inhibited when the 5' termini of U1 and U2 snRNAs are removed by site-directed cleavage with RNAase H. SF2 is a micrococcal nuclease-resistant factor present in the nuclear extract but absent from an S100 extract. SF3 is a factor that can be preferentially inactivated by moderate heat treatment. Two additional factors (SF4A and SF4B) were identified by fractionation of the nuclear extract using spermine-agarose and CM-sepharose chromatography. SF1, SF2, and SF4B appear to be required for cleavage of the pre-mRNA at the 5' splice site and lariat formation, whereas SF3 and SF4A are only required for cleavage at the 3' splice site and exon ligation.     

Characterization of a U2AF-independent commitment complex (E') in the mammalian spliceosome assembly pathway

Early recognition of pre-mRNA during spliceosome assembly in mammals proceeds through the association of U1 small nuclear ribonucleoprotein particle (snRNP) with the 5' splice site as well as the interactions of the branch binding protein SF1 with the branch region and the U2 snRNP auxiliary factor U2AF with the polypyrimidine tract and 3' splice site. These factors, along with members of the SR protein family, direct the ATP-independent formation of the early (E) complex that commits the pre-mRNA to splicing. We report here the observation in U2AF-depleted HeLa nuclear extract of a distinct, ATP-independent complex designated E' which can be chased into E complex and itself commits a pre-mRNA to the splicing pathway. The E' complex is characterized by a U1 snRNA-5' splice site base pairing, which follows the actual commitment step, an interaction of SF1 with the branch region, and a close association of the 5' splice site with the branch region. These results demonstrate that both commitment to splicing and the early proximity of conserved sequences within pre-mRNA substrates can occur in a minimal complex lacking U2AF, which may function as a precursor to E complex in spliceosome assembly.     

Combined biochemical and electron microscopic analyses reveal the architecture of the mammalian U2 snRNP.

The 17S U2 small nuclear ribonucleoprotein particle (snRNP) represents the active form of U2 snRNP that binds to the pre-mRNA during spliceosome assembly. This particle forms by sequential interactions of splicing factors SF3b and SF3a with the 12S U2 snRNP. We have purified SF3b and the 15S U2 snRNP, an intermediate in the assembly pathway, from HeLa cell nuclear extracts and show that SF3b consists of four subunits of 49, 130, 145, and 155 kD. Biochemical analysis indicates that both SF3b and the 12S U2 snRNP are required for the incorporation of SF3a into the 17S U2 snRNP. Nuclease protection studies demonstrate interactions of SF3b with the 5' half of U2 small nuclear RNA, whereas SF3a associates with the 3' portion of the U2 snRNP and possibly also interacts with SF3b. Electron microscopy of the 15S U2 snRNP shows that it consists of two domains in which the characteristic features of isolated SF3b and the 12S U2 snRNP are conserved. Comparison to the two-domain structure of the 17S U2 snRNP corroborates the biochemical results in that binding of SF3a contributes to an increase in size of the 12S U2 domain and possibly induces a structural change in the SF3b domain.     

The splicing factor, Prp40, binds the phosphorylated carboxyl-terminal domain of RNA polymerase II

We showed previously that the WW domain of the prolyl isomerase, Ess1, can bind the phosphorylated carboxyl-terminal domain (phospho-CTD) of the largest subunit of RNA Polymerase II. Analysis of phospho-CTD binding by four other WW domain-containing Saccharomyces cerevisiae proteins indicates the splicing factor, Prp40, and the RNA polymerase II ubiquitin ligase, Rsp5, can also bind the phospho-CTD. The identification of Prp40 as a phospho-CTD binding protein represents the first demonstration of direct interaction between a documented splicing factor and the phospho-CTD. Domain dissection studies reveal that phospho-CTD binding occurs at multiple locations in Prp40, including sites in both the WW and FF domain regions. Because the conserved repeats of the CTD make it an ideal ligand for multi-site binding events, the implications of multi-site binding are discussed. Our data suggest a mechanism by which the phospho-CTD of elongating RNA polymerase II facilitates commitment complex formation by juxtaposing the 5' and 3' splice sites.     

Splicing factor SF4 is dispensable for the assembly of a functional splicing complex and participates in the subsequent steps of the splicing reaction.

The splicing of nuclear messenger RNA precursors (pre-mRNA) can be reconstituted in vitro with factors partially purified from HeLa cell nuclear extracts. Splicing complexes are assembled in the presence of the small nuclear ribonucleoprotein particles (snRNPs) U1, U2, U4, U5 and U6 and the protein factors SF1, SF2, SF3 and U2AF. However, the complexes thus formed are inactive, i.e. they only contain unprocessed pre-mRNA. The intermediates and products of the splicing reaction are generated after addition of SF4. This splicing factor is a heat-labile protein which requires sulfhydryl groups for its activity. SF4 appears to participate, directly or indirectly, in the conversion of a functional but inactive splicing complex to the active spliceosome.     

Selection of alternative 5' splice sites: role of U1 snRNP and models for the antagonistic effects of SF2/ASF and hnRNP A1

The first component known to recognize and discriminate among potential 5' splice sites (5'SSs) in pre-mRNA is the U1 snRNP. However, the relative levels of U1 snRNP binding to alternative 5'SSs do not necessarily determine the splicing outcome. Strikingly, SF2/ASF, one of the essential SR protein-splicing factors, causes a dose-dependent shift in splicing to a downstream (intron-proximal) site, and yet it increases U1 snRNP binding at upstream and downstream sites simultaneously. We show here that hnRNP A1, which shifts splicing towards an upstream 5'SS, causes reduced U1 snRNP binding at both sites. Nonetheless, the importance of U1 snRNP binding is shown by proportionality between the level of U1 snRNP binding to the downstream site and its use in splicing. With purified components, hnRNP A1 reduces U1 snRNP binding to 5'SSs by binding cooperatively and indiscriminately to the pre-mRNA. Mutations in hnRNP A1 and SF2/ASF show that the opposite effects of the proteins on 5'SS choice are correlated with their effects on U1 snRNP binding. Cross-linking experiments show that SF2/ASF and hnRNP A1 compete to bind pre-mRNA, and we conclude that this competition is the basis of their functional antagonism; SF2/ASF enhances U1 snRNP binding at all 5'SSs, the rise in simultaneous occupancy causing a shift in splicing towards the downstream site, whereas hnRNP A1 interferes with U1 snRNP binding such that 5'SS occupancy is lower and the affinities of U1 snRNP for the individual sites determine the site of splicing.