Different requirements of the kinase and UHM domains of KIS for its nuclear localization and binding to splicing factors

The protein kinase KIS is made by the juxtaposition of a unique kinase domain and a C-terminal domain with a U2AF homology motif (UHM), a sequence motif for protein interaction initially identified in the heterodimeric pre-mRNA splicing factor U2AF. This domain of KIS is closely related to the C-terminal UHM domain of the U2AF large subunit, U2AF⁶⁵. KIS phosphorylates the splicing factor SF1, which in turn enhances SF1 binding to U2AF⁶⁵ and the 3′ splice site, an event known to take place at an early step of spliceosome assembly. Here, the analysis of the subcellular localization of mutated forms of KIS indicates that the kinase domain of KIS is the necessary domain for its nuclear localization. As in the case of U2AF⁶⁵, the UHM-containing C-terminal domain of KIS is required for binding to the splicing factors SF1 and SF3b155. The efficiency of KIS binding to SF1 and SF3b155 is similar to that of U2AF⁶⁵ in pull-down assays. These results further support the functional link of KIS with splicing factors. Interestingly, when compared to other UHM-containing proteins, KIS presents a different specificity for the UHM docking sites that are present in the N-terminal region of SF3b155, thus providing a new insight into the variety of interactions mediated by UHM domains.     

Solution structure of the HIV-1 exon splicing silencer 3

Alternative splicing of the human immunodeficiency virus type 1 (HIV-1) genomic RNA is necessary to produce the complete viral protein complement, and aberrations in the splicing pattern impair HIV-1 replication. Genome splicing in HIV-1 is tightly regulated by the dynamic assembly/disassembly of trans host factors with cis RNA control elements. The host protein, heterogeneous nuclear ribonucleoprotein (hnRNP) A1, regulates splicing at several highly conserved HIV-1 3′ splice sites by binding 5′-UAG-3′ elements embedded within regions containing RNA structure. The physical determinants of hnRNP A1 splice site recognition remain poorly defined in HIV-1, thus precluding a detailed understanding of the molecular basis of the splicing pattern. Here, the three-dimensional structure of the exon splicing silencer 3 (ESS3) from HIV-1 has been determined using NMR spectroscopy. ESS3 adopts a 27-nucleotide hairpin with a 10-bp A-form stem that contains a pH-sensitive A⁺C wobble pair. The seven-nucleotide hairpin loop contains the high-affinity hnRNP-A1-responsive 5′-UAGU-3′ element and a proximal 5′-GAU-3′ motif. The NMR structure shows that the heptaloop adopts a well-organized conformation stabilized primarily by base stacking interactions reminiscent of a U-turn. The apex of the loop is quasi-symmetric with UA dinucleotide steps from the 5′-GAU-3′ and 5′-UAGU-3′ motifs stacking on opposite sides of the hairpin. As a step towards understanding the binding mechanism, we performed calorimetric and NMR titrations of several hnRNP A1 subdomains into ESS3. The data show that the UP1 domain forms a high-affinity (K_d = 37.8 ± 1.1 nM) complex with ESS3 via site-specific interactions with the loop.     

RNA induces conformational changes in the SF1/U2AF65 splicing factor complex

Spliceosomes assemble on pre-mRNA splice sites through a series of dynamic ribonucleoprotein complexes, yet the nature of the conformational changes remains unclear. Splicing factor 1 (SF1) and U2 auxiliary factor (U2AF⁶⁵) cooperatively recognize the 3′ splice site during the initial stages of pre-mRNA splicing. Here, we used small-angle X-ray scattering to compare the molecular dimensions and ab initio shape restorations of SF1 and U2AF⁶⁵ splicing factors, as well as the SF1/U2AF⁶⁵ complex in the absence and presence of AdML (adenovirus major late) splice site RNAs. The molecular dimensions of the SF1/U2AF⁶⁵/RNA complex substantially contracted by 15 Å in the maximum dimension, relative to the SF1/U2AF⁶⁵ complex in the absence of RNA ligand. In contrast, no detectable changes were observed for the isolated SF1 and U2AF⁶⁵ splicing factors or their individual complexes with RNA, although slight differences in the shapes of their molecular envelopes were apparent. We propose that the conformational changes that are induced by assembly of the SF1/U2AF⁶⁵/RNA complex serve to position the pre-mRNA splice site optimally for subsequent stages of splicing.     

Interactome for auxiliary splicing factor U2AF65 suggests diverse roles

U2 small nuclear ribonucleoprotein auxiliary factor (U2AF) is an essential component of the splicing machinery that is composed of two protein subunits, the 35 kDa U2AF³⁵ (U2AF1) and the 65 kDa U2AF⁶⁵ (U2AF2). U2AF interacts with various splicing factors within this machinery. Here we expand the list of mammalian splicing factors that are known to interact with U2AF⁶⁵ as well as the list of nuclear proteins not known to participate in splicing that interact with U2AF⁶⁵. Using a yeast two-hybrid system, we found fourteen U2AF⁶⁵-interacting proteins. The validity of the screen was confirmed by identification of five known U2AF⁶⁵-interacting proteins, including its heterodimeric partner, U2AF³⁵. In addition to binding these known partners, we found previously unrecognized U2AF⁶⁵ interactions with four splicing-related proteins (DDX39, SFRS3, SFRS18, SNRPA), two zinc finger proteins (ZFP809 and ZC3H11A), a U2AF⁶⁵ homolog (RBM39), and two other regulatory proteins (DAXX and SERBP1). We report which regions of U2AF⁶⁵ each of these proteins interacts with and we discuss their potential roles in regulation of pre-mRNA splicing, 3′-end mRNA processing, and U2AF⁶⁵ sub-nuclear localization. These findings suggest expanded roles for U2AF⁶⁵ in both splicing and non-splicing functions.     

Position-dependent effects of hnRNP A1/A2 in SMN1/2 exon7 splicing

Heterogeneous nuclear ribonucleoprotein A1 and A2 (hnRNP A1/2) is a ubiquitously expressed RNA binding protein known to bind intronic or exonic splicing silencer. Binding of hnRNP A1/2 to survival of motor neuron gene (SMN1/2) exon 7 and flanking sequences strongly inhibits the inclusion of exon 7, which causes spinal muscular atrophy, a common genetic disorder. However, the role of hnRNP A1/2 on the side away from exon 7 is unclear. Here using antisense oligonucleotides, we fished an intronic splicing enhancer (ISE) near the 3′-splice site (SS) of intron 7 of SMN1/2. Mutagenesis identified the efficient motif of the ISE as “UAGUAGG”, coupled with RNA pull down and protein overexpression, we proved that hnRNP A1/2 binding to the ISE promotes the inclusion of SMN1/2 exon 7. Using MS2-tethering array and “UAGGGU” motif walking, we further uncovered that effects of hnRNP A1/2 on SMN1/2 exon 7 splicing are position-dependent: exon 7 inclusion is inhibited when hnRNP A1/2 binds proximal to the 5′SS of intron 7, promoted when its binds proximal to the 3′SS. These data provide new insights into the splicing regulatory mechanism of SMN1/2.     

Backbone assignment of the UHM domain of Puf60 free and bound to five ligands

U2AF homology motifs (UHM) are protein domains that bind peptidic UHM ligand motifs (ULM) and thus form an intricate network of interactions involved in splicing regulation. Here, we report the backbone assignment of the UHM domain of the splicing factor Puf60 as well as ¹H, ¹⁵N chemical shifts upon binding of the ULM peptides U2AF⁶⁵ (85–112), SF1 (1–25), SF3b155 (194–229), SF3b155 (317–357), and Prp16 (201–238).     

Structure,phosphorylation and U2AF65 binding of the N-terminal domain of splicing factor 1 during 3′-splice site recognition

Recognition of the 3′-splice site is a key step in pre-mRNA splicing and accomplished by a dynamic complex comprising splicing factor 1 (SF1) and the U2 snRNP auxiliary factor 65-kDa subunit (U2AF65). Both proteins mediate protein–protein and protein–RNA interactions for cooperative RNA-binding during spliceosome assembly. Here, we report the solution structure of a novel helix-hairpin domain in the N-terminal region of SF1 (SF1^NTD). The nuclear magnetic resonance- and small-angle X-ray scattering-derived structure of a complex of the SF1^NTD with the C-terminal U2AF homology motif domain of U2AF65 (U2AF65^UHM) reveals that, in addition to the known U2AF65^UHM–SF1 interaction, the helix-hairpin domain forms a secondary, hydrophobic interface with U2AF65^UHM, which locks the orientation of the two subunits. Mutational analysis shows that the helix hairpin is essential for cooperative formation of the ternary SF1–U2AF65–RNA complex. We further show that tandem serine phosphorylation of a conserved Ser80-Pro81-Ser82-Pro83 motif rigidifies a long unstructured linker in the SF1 helix hairpin. Phosphorylation does not significantly alter the overall conformations of SF1, SF1–U2AF65 or the SF1–U2AF65–RNA complexes, but slightly enhances RNA binding. Our results indicate that the helix-hairpin domain of SF1 is required for cooperative 3′-splice site recognition presumably by stabilizing a unique quaternary arrangement of the SF1–U2AF65–RNA complex.     

Plant-specific SR-related protein atSR45a interacts with spliceosomal proteins in plant nucleus

Serine/arginine-rich (SR) protein and its homologues (SR-related proteins) are important regulators of constitutive and/or alternative splicing and other aspects of mRNA metabolism. To clarify the contribution of a plant-specific and stress-responsive SR-related protein, atSR45a, to splicing events, here we analyzed the interaction of atSR45a with the other splicing factors by conducting a yeast two-hybrid assay and a bimolecular fluorescence complementation analysis. The atSR45a-1a and -2 proteins, the presumed mature forms produced by alternative splicing of atSR45a, interacted with U1-70K and U2AF³⁵b, splicing factors for the initial definition of 5′ and 3′ splice sites, respectively, in the early stage of spliceosome assembly. Both proteins also interacted with themselves, other SR proteins (atSR45 and atSCL28), and PRP38-like protein, a homologue of the splicing factor essential for cleavage of the 5′ splice site. The mapping of deletion mutants of atSR45a proteins revealed that the C-terminal arginine/serine-rich (RS) domain of atSR45a proteins are required for the interaction with U1-70K, U2AF³⁵b, atSR45, atSCL28, PRP38-like protein, and themselves, and the N-terminal RS domain enhances the interaction efficiency. Interestingly, the distinctive N-terminal extension in atSR45a-1a protein, but not atSR45a-2 protein, inhibited the interaction with these splicing factors. These findings suggest that the atSR45a proteins help to form the bridge between 5′ and 3′ splice sites in the spliceosome assembly and the efficiency of spliceosome formation is affected by the expression ratio of atSR45a-1a and atSR45a-2.     

HMGA1a is involved in specific splice site regulation of human immunodeficiency virus type 1

Human immunodeficiency virus type 1 (HIV-1) utilizes a highly complex splice site regulation system, taking advantage of host proteins, to express its own viral protein in an orderly way. We show here that one of the host proteins, high mobility group A protein 1a (HMGA1a), is involved in splice site regulation of 3′ splice site 2 (A2) and 5′splice site 3 (D3) of HIV-1 genomic RNA. shRNA knockdown of HMGA1 in HeLa cells resulting in a decrease of HMGA1 showed a significant decrease of Vpr mRNA. RNA electophoretic mobility shift assays showed HMGA1a specifically binds to a sequence adjacently upstream D3. In vitro splicing using heterologous pre-mRNA with A2 and D3, showed HMGA1a induced a splicing intermediate which decreased when an RNA decoy of the HMGA1a binding site was added. RT-PCR of in vitro splicing products revealed that HMGA1a induced an incomplete splicing product resulting from usage of A2 but inhibition of D3, which is reminiscent of the splicing pattern necessary for Vpr mRNA formation. HMGA1a interacted with hnRNPA1 shown by coimmunoprecipitation and supershifted U1 snRNP in an RNA electophoretic mobility shift assay. We conclude that HMGA1a anchors U1 snRNP to inhibit D3 function, and that HMGA1a inhibits hnRNPA1 function on exon splicing silencer of Vpr (ESSV) to activate A2 function. We show here for the first time that HMGA1a is involved in specific splice site regulation of HIV-1.     

PACSIN 2 represses cellular migration through direct association with cyclin D1 but not its alternate splice form cyclin D1b

Cyclin D1 overexpression is a common feature of many human malignancies. Genomic deletion analysis has demonstrated a key role for cyclin D1 in cellular proliferation, angiogenesis and cellular migration. To investigate the mechanisms contributing to cyclin D1 functions, we purified cyclin D1a-associated complexes by affinity chromatography and identified the PACSIN 2 (protein kinase C and casein kinase substrate in neurons 2) protein by mass spectrometry. The PACSIN 2, but not the related PACSIN 1 and 3, directly bound wild-type cyclin D1 (cyclin D1a) at the carboxyl terminus and failed to bind cyclin D1b, the alternative splicing variant of cyclin D1. PACSIN 2 knockdown induced cellular migration and reduced cell spreading in LNCaP cells expressing cyclin D1a. In cyclin D1^−/− mouse embryonic fibroblasts (MEFs), cyclin D1a, but not cyclin D1b, reduced the cell spreading to a polarized morphology. siPACSIN 2 had no effect on cellular migration of cyclin D1^−/− MEFs. Cyclin D1a restored the migratory ability of cyclin D1^−/− MEFs, which was further enhanced by knocking down PACSIN 2 with siRNA. The cyclin D1-associated protein, PACSIN 2, regulates cell spreading and migration, which are dependent on cyclin D1 expression.Key words: PACSIN 2, cyclin D1, polymorphism, cellular migration, cell spreading, cancer     

The 1H, 13C and 15N backbone and side-chain assignment of the RRM domain of SC35, a regulator of pre-mRNA splicing

The serine-arginine rich family of proteins play important roles in the regulation of both constitutive and alternative splicing. SC35 (also known as SFRS2 and PR264) is a member of this family and contains one RNA recognition motif (RRM domain) and a RS domain at the C-terminus which is enriched with arginine and serine residues. SC35 is specifically involved in major regulatory pathways for cell proliferation and cell cycle progression. Determining the structure of SC35 would enable greater understanding of how its structure relates to its many functions. Complete ¹H, ¹³C and ¹⁵N assignments of the RRM domain of SC35 are presented. The assignments were obtained using 2D heteronuclear and 3D triple-resonance experiments with the uniformly [¹⁵N,¹³C]-labelled protein. The chemical shifts are used to predict the 3-dimensional structure of this RRM domain in the absence of RNA.     

Mer1p is a modular splicing factor whose function depends on the conserved U2 snRNP protein Snu17p

Mer1p activates the splicing of at least three pre-mRNAs (AMA1, MER2, MER3) during meiosis in the yeast Saccharomyces cerevisiae. We demonstrate that enhancer recognition by Mer1p is separable from Mer1p splicing activation. The C-terminal KH-type RNA-binding domain of Mer1p recognizes introns that contain the Mer1p splicing enhancer, while the N-terminal domain interacts with the spliceosome and activates splicing. Prior studies have implicated the U1 snRNP and recognition of the 5′ splice site as key elements in Mer1p-activated splicing. We provide new evidence that Mer1p may also function at later steps of spliceosome assembly. First, Mer1p can activate splicing of introns that have mutated branch point sequences. Secondly, Mer1p fails to activate splicing in the absence of the non-essential U2 snRNP protein Snu17p. Thirdly, Mer1p interacts with the branch point binding proteins Mud2p and Bbp1p and the U2 snRNP protein Prp11p by two-hybrid assays. We conclude that Mer1p is a modular splicing regulator that can activate splicing at several early steps of spliceosome assembly and depends on the activities of both U1 and U2 snRNP proteins to activate splicing.