The carboxyl-terminal domain (CTD) of the largest subunit of eukaryotic RNA polymerase II (pol II) plays an important role in promoting steps of pre-mRNA processing. To identify proteins in human cells that bind to the CTD and that could mediate its functions in pre-mRNA processing, we used the mouse CTD expressed in bacterial cells in affinity chromatography experiments. Two proteins present in HeLa cell extract, the splicing and transcription-associated factors, PSF and p54nrb/NonO, bound specifically and could be purified to virtual homogeneity by chromatography on immobilized CTD matrices. Both hypo- and hyperphosphorylated CTD matrices bound these proteins with similar selectivity. PSF and p54nrb/NonO also copurified with a holoenzyme form of pol II containing hypophosphorylated CTD and could be coimmunoprecipitated with antibodies specific for this and the hyperphosphorylated form of pol II. That PSF and p54nrb/NonO promoted the binding of RNA to immobilized CTD matrices suggested these proteins can interact with the CTD and RNA simultaneously. PSF and p54nrb/NonO may therefore provide a direct physical link between the pol II CTD and pre-mRNA processing components, at both the initiation and elongation phases of transcription.

The poly(A)-limiting element (PLE) is a cis-acting sequence that acts to limit poly(A) tail length on pre-mRNA to <20 nt. Functional PLEs are present in a number of genes, underscoring the generality of this control mechanism. The current study sought to define further the position requirements for poly(A) length regulation and the core sequence that comprises a PLE. Increasing the spacing between the PLE and the upstream 3′ splice site or between the PLE and the downstream AAUAAA had no effect on poly(A) length control. However, moving the PLE from the terminal exon to either an upstream exon or intron eliminated poly(A) length control. Poly(A) length control was further evaluated using a battery of constructs in which the PLE was maintained in the terminal exon, but where upstream introns were either deleted, modified, or replaced with a polypyrimidine tract. Poly(A) length control was retained in all cases, indicating that the key feature is the presence of the PLE in the terminal exon. A battery of mutations demonstrated the importance of the 5′ pyrimidine-rich portion of the element. Finally, UV crosslinking experiments identified an ∼62-kDa protein in Hela nuclear extract that binds to a wild-type 23-nt PLE RNA oligonucleotides but not to a mutated nonfunctional form of the element.

In most species the 3′ splice site is recognized initially by an interaction between the two-subunit splicing factor U2AF with the polypyrimidine (poly(Y)) tract that results in recruitment of the U2 snRNP to the branch-point consensus just upstream. In contrast, in Caenorhabditis elegans, both the poly(Y) tract and the branch-point consensus sequences are missing, apparently replaced by the highly conserved U4CAG/R 3′ splice site consensus. Nevertheless C. elegans U2AF65 is very similar to its mammalian and fly counterparts and may recognize the 3′ splice site consensus. Here we report the cloning of the C. elegans U2AF35 gene, uaf-2. We show that it lacks an identifiable RS domain, which, in flies, has been shown to play a role in RNA binding, but it contains an extended glycine-rich stretch at its C-terminus. uaf-2 is in an operon with cyp-13, a gene that encodes a cyclophilin with an RRM domain at its N-terminus. We demonstrate by RNA interference that both U2AF genes, uaf-1 (which encodes U2AF65) and uaf-2, are required for viability, whereas cyp-13 is apparently not.

Selection of pre-mRNA splice sites is a highly accurate process involving many trans-acting factors. Recently, we described a role for U6 snRNA position G52 in selection of the first intron nucleotide (+1G). Because some U2 alleles suppress U6-G52 mutations, we investigated whether the corresponding U2 snRNA region also influenced 5′ splice site selection. Our results demonstrate that U2 snRNAs mutated at position U23, but not adjacent nucleotides, specifically affect 5′ splice site cleavage. Furthermore, all U2 position U23 mutations are synthetic lethal with the thermosensitive U6-G52U allele. Interestingly, the U2-U23C substitution has an unprecedented hyperaccurate splicing phenotype in which cleavage of introns with a +1G substitution is reduced, whereas the strain grows with wild-type kinetics. U2 position U23 forms the first base pair with U6 position A59 in U2/U6 helix Ib. Restoration of the helical structure suppresses 5′ splice site cleavage defects, showing an important role for the helix Ib structure in 5′ splice site selection. U2/U6 helix Ib and helix II have recently been described as being functionally redundant. This report demonstrates a unique role for helix Ib in 5′ splice site selection that is not shared with helix II.

Nuclear pre-mRNA splicing necessitates specific recognition of the pre-mRNA splice sites. It is known that 5′ splice site selection requires base pairing of U6 snRNA with intron positions 4–6. However, no factor recognizing the highly conserved 5′ splice site GU has yet been identified. We have tested if the known U6 snRNA–pre-mRNA interaction could be extended to include the first intron nucleotides and the conserved 50GAG52 sequence of U6 snRNA. We observe that some combinations of 5′ splice site and U6 snRNA mutations produce a specific synthetic block to the first splicing step. In addition, the U6-G52U allele can switch between two competing 5′ splice sites harboring different nucleotides following the cleavage site. These results indicate that U6 snRNA position 52 interacts with the first nucleotide of the intron before 5′ splice site cleavage. Some combinations of U6 snRNA and pre-mRNA mutations also blocked the second splicing step, suggesting a role for the corresponding nucleotides in a proofreading step before exon ligation. From studies in diverse organisms, various functions have been ascribed to the conserved U6 snRNA 47ACAGAG52 sequence. Our results suggest that these discrepancies might reflect variations between different experimental systems and point to an important conserved role of this sequence in the splicing reaction.