Human Splicing Factor Research Articles

A complementation method for functional analysis of mammalian genes

Our progress in understanding mammalian gene function has lagged behind that of gene identification. New methods for mammalian gene functional analysis are needed to accelerate the process. In yeast, the powerful genetic shuffle system allows deletion of any chromosomal gene by homologous recombination and episomal expression of a mutant allele in the same cell. Here, we report a method for mammalian cells, which employs a helper-dependent adenoviral (HD-Ad) vector to synthesize small hairpin (sh) RNAs to knock-down the expression of an endogenous gene by targeting untranslated regions (UTRs). The vector simultaneously expresses an exogenous version of the same gene (wild-type or mutant allele) lacking the UTRs for functional analysis. We demonstrated the utility of the method by using PRPF3, which encodes the human RNA splicing factor Hprp3p. Recently, missense mutations in PRPF3 were found to cause autosomal-dominant Retinitis Pigmentosa, a form of genetic eye diseases affecting the retina. We knocked-down endogenous PRPF3 in multiple cell lines and rescued the phenotype (cell death) with exogenous PRPF3 cDNA, thereby creating a genetic complementation method. Because Ad vectors can efficiently transduce a wide variety of cell types, and many tissues in vivo, this method could have a wide application for gene function studies.

Structure–function analysis of the U2 snRNP-associated splicing factor SF3a

Human splicing factor SF3a is a part of the 17 S U2 snRNP (small nuclear ribonucleoprotein), which interacts with the pre-mRNA branch site early during spliceosome formation. The SF3a subunits of 60, 66 and 120 kDa are all required for SF3a function in vitro. Depletion of individual subunits from HeLa cells by RNA interference results in a global inhibition of splicing, indicating that SF3a is a constitutive splicing factor. Structure-function analyses have defined domains necessary for interactions within the SF3a heterotrimer, association with the U2 snRNP and spliceosome assembly. Studies aimed at the identification of regions in SF3a60 and SF3a66, required for proper intracellular localization, have led to a model for the final steps in U2 snRNP biogenesis and the proposal that SF3a is incorporated into the U2 snRNP in Cajal bodies.

A human splicing factor, SKIP, associates with P-TEFb and enhances transcription elongation by HIV-1 Tat

HIV-1 Tat binds human CyclinT1 and recruits the CDK9/P-TEFb complex to the viral TAR RNA in a step that links RNA polymerase II (RNAPII) C-terminal domain (CTD) Ser 2 phosphorylation with transcription elongation. Previous studies have suggested a connection between Tat and pre-mRNA splicing factors. Here we show that the splicing-associated c-Ski-interacting protein, SKIP, is required for Tat transactivation in vivo and stimulates HIV-1 transcription elongation, but not initiation, in vitro. SKIP associates with CycT1:CDK9/P-TEFb and Tat:P-TEFb complexes in nuclear extracts and interacts with recombinant Tat:P-TEFb:TAR RNA complexes in vitro, indicating that it may act through nascent RNA to overcome pausing by RNAPII. SKIP also associates with U5snRNP proteins and tri-snRNP110K in nuclear extracts, and facilitates recognition of an alternative Tat-specific splice site in vivo. The effects of SKIP on transcription elongation, binding to P-TEFb, and splicing are mediated through the SNW domain. HIV-1 Tat transactivation is accompanied by the recruitment of P-TEFb, SKIP, and tri-snRNP110K to the integrated HIV-1 promoter in vivo, whereas the U5snRNPs associate only with the transcribed coding region. These findings suggest that SKIP plays independent roles in transcription elongation and pre-mRNA splicing.

Human Splicing Factor SF3a, but Not SF1, Is Essential for Pre-mRNA Splicing In Vivo

The three subunits of human splicing factor SF3a are essential for the formation of the functional 17S U2 snRNP and prespliceosome assembly in vitro. RNAi-mediated depletion indicates that each subunit is essential for viability of human cells. Knockdown of single subunits results in a general block in splicing strongly suggesting that SF3a is a constitutive splicing factor in vivo. In contrast, splicing of several endogenous and reporter pre-mRNAs is not affected after knockdown of SF1, which functions at the onset of spliceosome assembly in vitro and is essential for cell viability. Thus, SF1 may only be required for the splicing of a subset of pre-mRNAs. We also observe a reorganization of U2 snRNP components in SF3a-depleted cells, where U2 snRNA and U2-B'' are significantly reduced in nuclear speckles and the nucleoplasm, but still present in Cajal bodies. Together with the observation that the 17S U2 snRNP cannot be detected in extracts from SF3a-depleted cells, our results provide further evidence for a function of Cajal bodies in U2 snRNP biogenesis.

Crystal structure of the human ATP-dependent splicing and export factor UAP56

Pre-mRNA splicing requires the function of a number of RNA-dependent ATPases/helicases, yet no three-dimensional structure of any spliceosomal ATPases/helicases is known. The highly conserved DECD-box protein UAP56/Sub2 is an essential splicing factor that is also important for mRNA export. The expected ATPase/helicase activity appears to be essential for the UAP56/Sub2 functions. Here, we show that purified human UAP56 is an active RNA-dependent ATPase, and we also report the crystal structures of UAP56 alone and in complex with ADP, as well as a DECD to DEAD mutant. The structures reveal a unique spatial arrangement of the two conserved helicase domains, and ADP-binding induces significant conformational changes of key residues in the ATP-binding pocket. Our structural analyses suggest a specific protein-RNA displacement model of UAP56/Sub2. The detailed structural information provides important mechanistic insights into the splicing function of UAP56/Sub2. The structures also will be useful for the analysis of other spliceosomal DExD-box ATPases/helicases.

Shape-specific Nucleotide Binding of Single-stranded RNA by the GLD-1 STAR Domain

Proteins containing the STAR RNA-binding domain fulfill vital roles in RNA biogenesis, yet a detailed understanding of STAR domain RNA binding specificity is lacking. In Caenorhabditis elegans, the STAR protein GLD-1 directly binds the 28 nucleotide recognition element TGE within the 3' untranslated region of tra-2 mRNA. The GLD-1:TGE interaction promotes translational silencing of tra-2 mRNA, marking a pivotal event in the spermatogenesis to oogenesis switch in C.elegans hermaphrodites. By measuring the binding affinities of both GLD-1 and TGE mutants, we have explored the molecular determinants of STAR domain specificity. Site-directed GLD-1 mutants were guided by sequence homology with human splicing factor 1 (SF1), for which an RNA:protein complex structure is available in the work done by Liu et al. The RNA binding affinity of 11 mutant GLD-1 proteins was measured, and their binding specificity was assessed with a series of TGE RNAs containing natural or modified nucleotides. This combinatorial analysis of both RNA and protein mutants revealed a diverse array of specificities of individual nucleotide-binding pockets along the interface. At nucleotide position 18, adenosine appears to be specified by the overall shape of a pocket lined with aliphatic side-chains. At position 19, the high preference for cytidine is dependent on both the length of an amino acid side-chain and the identity of terminal functional groups. The nucleotide 21 binding pocket exhibits low discrimination for cytidine, and accommodates most nucleobases. The highly hydrophobic binding interface and apparent small number of hydrogen bonding read-out interactions at these positions is consistent with our finding that few amino acids seem to function individually in establishing binding specificity. Rather, specificity is conferred by the shape of the nucleotide-binding pocket. Our data provide the first detailed, quantitative analysis of the STAR domain, and highlight features of STAR:RNA recognition that are distinct among single-stranded RNA-binding proteins.

A Novel Human Gene (WDR25) Encoding a 7-WD40-Containing Protein Maps on 14q32

Members of the large family of WD-repeat proteins are involved in diverse functions such as RNA-procession, signal transduction, vesicular trafficking, cytoskeletal assembly, and cell cycle control. By large-scale-sequencing analysis of a human fetal brain cDNA library, we isolated a novel human cDNA encoding a 7-WD40-repeat protein. This cDNA is 2004 bp in length and it codes for a 544-amino-acid protein. We term it human WD40-repeat-containing gene 25 (WDR25) and this gene shows significant similarity with human pre-mRNA splicing factor 17. The WDR25 gene is mapped to chromosome 14q32 and contains seven exons. RT-PCR analysis shows that the WDR25 gene is widely expressed in human tissues and the expression levers in heart, muscle, testis, ovary, uterus, and prostate are relatively high.

The second RNA-binding domain of the human splicing factor ASF/SF2 is the critical domain controlling adenovirus E1A alternative 5'-splice site selection.

The human splicing factor ASF/SF2 (alternative splicing factor/splicing factor 2) is modular in structure with two RNA-binding domains (RBD1 and RBD2) and a C-terminal domain rich in arginine-serine dipeptide repeats. ASF/SF2 is an essential splicing factor that also functions as an important regulator of alternative splicing. In adenovirus E1A (early region 1A) alternative pre-mRNA splicing, ASF/SF2 functions as a strong inducer of proximal 5'-splice-site selection, both in vitro and in vivo. In the present study, we tested the functional role of individual domains of ASF/SF2 in alternative splicing in vitro. We show that ASF/SF2-RBD2 is the critical domain controlling E1A alternative splicing. In fact, RBD2 alone is sufficient to mimic the activity of the full-length ASF/SF2 protein as an inducer of proximal 5'-splice-site selection in vitro. The RBD2 domain induces a switch to E1A-proximal 5'-splice-site usage by repressing distal 12 S splicing and simultaneously stimulates proximal 13 S splicing. In contrast, the ASF/SF2-RBD1 domain has a more general splicing enhancer phenotype and appears to stimulate preferentially cap-proximal 5'-splice-site selection. Furthermore, the SWQDLKD motif, which is conserved in all SR proteins (serine/arginine-rich proteins) containing two RBDs, and the ribonucleoprotein-1-type RNA recognition motif were both found to be necessary for the alternative splice-site-switching activity of ASF/SF2. The RNP-1 motif was necessary for efficient RNA binding, whereas the SWQDLKD motif most probably contributes by functioning as a surface-mediating critical protein-protein contact during spliceosome assembly.

SR-A1, a member of the human pre-mRNA splicing factor family, and its expression in colon cancer progression

SR (serine-arginine) proteins are essential pre-mRNA splicing factors. Several SR proteins have been characterized in humans, among them SR-A1. It has been demonstrated by members of our group that the SR-A1 gene is constitutively expressed in most of the human tissues, while its transcription is increased in breast carcinoma cell lines. Moreover, the SR-A1 gene is overexpressed in a set of ovarian tumors, suggesting that it may be involved in the pathogenesis and/or progression of ovarian cancer. Therefore, in the present study we examined the expression of the SR-A1 gene in colon cancer tissues by RT-PCR and found that it is overexpressed as compared to normal mucosa (p=0.01). The SR-A1 gene was expressed more frequently in well-differentiated tumors than those with poor differentiation. Survival curves determined by the Kaplan-Meier method and univariate analysis demonstrated that SR-A1-positivity is associated with a long survival (p=0.044). However, when entered into a Cox multivariate model adjusted for other clinicopathological features studied, SR-A1 expression status was not found to be of independent prognostic significance. To the best of our knowledge, this is the first study examining the expression of the novel gene SR-A1 in colon cancer progression.

Activation function-1 domain of androgen receptor contributes to the interaction between two distinct subnuclear compartments

The nucleus contains different sets of functional compartments often called “speckles”. The splicing factor compartment (SFC) has been speculated to consist of SFs and transcription factors, which thus make transcription-splicing coupling possible at the periphery of SFC. Androgen receptor (AR), as well as glucocorticoid receptor (GR), is unique since most, if not all, of its activities are mediated via the constitutive activity of the activation function-1 (AF-1) function. Transcriptionally active AR produces 250–400 subnuclear fine speckles11 shared with GR or estrogen receptor (ER), which colocalize with chiefly activation function-2 (AF-2)-interacting p160 family- or CBP-related speckles. We herein report the isolation of ANT-1 (AR N-terminal domain (NTD) transactivating protein-1) enhancing autonomous AF-1 transactivation function of AR or GR, but not of estrogen receptor α (ERα). The ANT-1 was identical to a binding protein of human splicing factor U5 snRNP (U5 snRNP-associated protein). ANT-1 was compartmentalized into 15–20 coarse SFC speckles which were spatially distinct from but surrounded by the AR compartments. Our results suggest that ANT-1 may play a key role in the molecular interaction between two spatially distinct subnuclear compartments in a receptor-specific fashion, and thereby induce the strong autonomous transactivation functions either of AR- or GR-AF-1.

The Structure of the Zinc Finger Domain from Human Splicing Factor ZNF265 Fold

Identification of the protein domains that are responsible for RNA recognition has lagged behind the characterization of protein-DNA interactions. However, it is now becoming clear that a range of structural motifs bind to RNA and their structures and molecular mechanisms of action are beginning to be elucidated. In this report, we have expressed and purified one of the two putative RNA-binding domains from ZNF265, a protein that has been shown to bind to the spliceosomal components U1-70K and U2AF35 and to direct alternative splicing. We show that this domain, which contains four highly conserved cysteine residues, forms a stable, monomeric structure upon the addition of 1 molar eq of Zn(II). Determination of the solution structure of this domain reveals a conformation comprising two stacked beta-hairpins oriented at approximately 80 degrees to each other and sandwiching the zinc ion; the fold resembles the zinc ribbon class of zinc-binding domains, although with one less beta-strand than most members of the class. Analysis of the structure reveals a striking resemblance to known RNA-binding motifs in terms of the distribution of key surface residues responsible for making RNA contacts, despite a complete lack of structural homology. Furthermore, we have used an RNA gel shift assay to demonstrate that a single crossed finger domain from ZNF265 is capable of binding to an RNA message. Taken together, these results define a new RNA-binding motif and should provide insight into the functions of the >100 uncharacterized proteins in the sequence data bases that contain this domain.

Structural Basis for the Molecular Recognition between Human Splicing Factors U2AF 65 and SF1/mBBP

The essential splicing factors SF1 and U2AF play an important role in the recognition of the pre-mRNA 3′ splice site during early spliceosome assembly. The structure of the C-terminal RRM (RRM3) of human U2AF 65 complexed to an N-terminal peptide of SF1 reveals an extended negatively charged helix A and an additional helix C. Helix C shields the potential RNA binding surface. SF1 binds to the opposite, helical face of RRM3. It inserts a conserved tryptophan into a hydrophobic pocket between helices A and B in a way that strikingly resembles part of the molecular interface in the U2AF heterodimer. This molecular recognition establishes a paradigm for protein binding by a subfamily of noncanonical RRMs.

YTH: a new domain in nuclear proteins.

A novel 100-150-residue domain has been identified in the human splicing factor YT521-B and its Drosophila and yeast homologues. Homology searches show that the domain is typical for the eukaryotes and is particularly abundant in plants. It is predicted to adopt a mixed alpha-helix-beta-sheet fold and to bind to RNA. We propose the name YTH (for YT521-B homology) for the domain.

Induced folding of the U2AF35 RRM upon binding to U2AF65

The human essential splicing factor U2AF (U2 auxiliary factor) consists of 35 and 65 kDa subunits which form a highly stable heterodimer in solution. Copurification of the recombinant U2AF35 RNA recognition motif (U2AF35 RRM) and full-length U2AF65 yields a soluble and functionally active minimal U2AF heterodimer. Recombinant U2AF35 RRM protein free and in complex with three different regions of U2AF65 was characterized by nuclear magnetic resonance spectroscopy. We found that the recombinant U2AF35 RRM is unstructured in solution but its tertiary structure is induced upon binding to U2AF65. This interaction is mediated by the N-terminal proline-rich region of U2AF65 and does not involve the U2AF65 RRMs.

P68 RNA helicase is an essential human splicing factor that acts at the U1 snRNA-5' splice site duplex.

Modulation of the interaction between U1 snRNP and the 5' splice site (5'ss) is a key event that governs 5'ss recognition and spliceosome assembly. Using the methylene blue-mediated cross-linking method (Z. R. Liu, A. M. Wilkie, M. J. Clemens, and C. W. Smith, RNA 2:611-621, 1996), a 65-kDa protein (p65) was shown to interact with the U1-5'ss duplex during spliceosome assembly (Z. R. Liu, B. Sargueil, and C. W. Smith, Mol. Cell. Biol. 18:6910-6920, 1998). In this report, p65 was identified as p68 RNA helicase and shown to be essential for in vitro pre-mRNA splicing. Depletion of endogenous p68 RNA helicase does not affect the loading of the U1 snRNP to the 5'ss during early stage of splicing. However, dissociation of the U1 from the 5'ss is largely inhibited. The data suggest that p68 RNA helicase functions in destabilizing the U1-5'ss interactions. Furthermore, depletion of p68 RNA helicase arrested spliceosome assembly at the prespliceosome stage, suggesting that p68 may play a role in the transition from prespliceosome to spliceosome.

Large-scale proteomic analysis of the human spliceosome.

In a previous proteomic study of the human spliceosome, we identified 42 spliceosome-associated factors, including 19 novel ones. Using enhanced mass spectrometric tools and improved databases, we now report identification of 311 proteins that copurify with splicing complexes assembled on two separate pre-mRNAs. All known essential human splicing factors were found, and 96 novel proteins were identified, of which 55 contain domains directly linking them to functions in splicing/RNA processing. We also detected 20 proteins related to transcription, which indicates a direct connection between this process and splicing. This investigation provides the most detailed inventory of human spliceosome-associated factors to date, and the data indicate a number of interesting links coordinating splicing with other steps in the gene expression pathway.

Central Region of the Human Splicing Factor Hprp3p Interacts with Hprp4p

Human splicing factors Hprp3p and Hprp4p are associated with the U4/U6 small nuclear ribonucleoprotein particle, which is essential for the assembly of an active spliceosome. Currently, little is known about the specific roles of these factors in splicing. In this study, we characterized the molecular interaction between Hprp3p and Hprp4p. Constructs were created for expression of Hprp3p or its mutants in bacterial or mammalian cells. We showed that antibodies against either Hprp3p or Hprp4p were able to pull-down the Hprp3p-Hprp4p complex formed in Escherichia coli lysates. By co-immunoprecipitation and isothermal titration calorimetry, we demonstrated that purified Hprp3p and its mutants containing the central region, but lacking either the N-terminal 194 amino acids or the C-terminal 240 amino acids, were able to interact with Hprp4p. Conversely, Hprp3p mutants containing only the N- or C-terminal region did not interact with Hprp4p. In addition, by co-immunoprecipitation, we showed that intact Hprp3p and its mutants containing the central region interacted with Hprp4p in HeLa cell nuclear extracts. Primer extension analysis illustrated that the central region of Hprp3p is required to maintain the association of Hprp3p-Hprp4p with U4/U6 small nuclear RNAs, suggesting that this Hprp3p/Hprp4p interaction allows the recruitment of Hprp4p, and perhaps other protein(s), to the U4/U6 small nuclear ribonucleoprotein particle.

Human Splicing Factor ASF/SF2 Encodes for a Repressor Domain Required for Its Inhibitory Activity on Pre-mRNA Splicing

The essential splicing factor ASF/SF2 activates or represses splicing depending on where on the pre-mRNA it binds. We have shown previously that ASF/SF2 inhibits adenovirus IIIa pre-mRNA splicing by binding to an intronic repressor element. Here we used MS2-ASF/SF2 fusion proteins to show that the second RNA binding domain (RBD2) is both necessary and sufficient for the splicing repressor function of ASF/SF2. Furthermore, we show that the completely conserved SWQDLKD motif in ASF/SF2-RBD2 is essential for splicing repression. Importantly, this heptapeptide motif is unlikely to be directly involved in RNA binding given its position within the predicted structure of RBD2. The activity of the ASF/SF2-RBD2 domain in splicing was position-dependent. Thus, tethering RBD2 to the IIIa intron resulted in splicing repression, whereas RBD2 binding at the second exon had no effect on IIIa splicing. The splicing repressor activity of RBD2 was not unique to the IIIa pre-mRNA, as binding of RBD2 at an intronic position in the rabbit beta-globin pre-mRNA also resulted in splicing inhibition. Taken together, our results suggest that ASF/SF2 encode distinct domains responsible for its function as a splicing enhancer or splicing repressor protein.

Mutations in HPRP3, a third member of pre-mRNA splicing factor genes, implicated in autosomal dominant retinitis pigmentosa.

Retinitis pigmentosa (RP), the commonest form of inherited retinal dystrophies is a clinically and genetically heterogeneous disorder. It is characterized by progressive degeneration of the peripheral retina leading to night blindness and loss of peripheral visual field. RP is inherited either in an autosomal dominant, autosomal recessive or X-linked mode. A locus (RP18) for autosomal dominant RP was previously mapped by linkage analysis in two large pedigrees to chromosome 1p13-q21. The human HPRP3 gene, the orthologue of the yeast pre-mRNA splicing factor (PRP3), localizes within the RP18 disease interval. The recent identification of mutations in human splicing factors, PRPF31 and PRPC8, led us to screen HPRP3 as a candidate in three chromosome 1q-linked families. So far, two different missense mutations in two English, a Danish family and in three RP individuals have been identified. Both mutations are clustered within a two-codon stretch in the 11th exon of the HPRP3 gene. Interestingly, one of the mutations (T494M) is seen repeatedly in apparently unlinked families raising the possibility of a mutation hot spot. This has been confirmed by haplotype analysis using SNPs spanning the HPRP3 gene region supporting multiple origins of the mutation. The altered HPRP3 amino acids, which are highly conserved in all known HPRP3 orthologues, indicate a major function of that domain in the splicing process. The identification of mutations in a third pre-mRNA splicing factor gene further highlights a novel mechanism of photoreceptor degeneration due to defects in the splicing process.

Domains in human splicing factors SF3a60 and SF3a66 required for binding to SF3a120, assembly of the 17S U2 snRNP, and prespliceosome formation.

The active 17S U2 small nuclear ribonucleoprotein particle (snRNP), which binds to the intron branch site during the formation of the prespliceosome, is assembled in vitro by sequential interactions of the essential splicing factors SF3b and SF3a with the 12S U2 snRNP. We have analyzed the function of individual subunits of human SF3a (SF3a60, SF3a66, and SF3a120) by testing recombinant proteins, expressed in insect cells, in various in vitro assays. The recombinant subunits readily form the SF3a heterotrimer, where SF3a60 and SF3a66 interact with SF3a120, but not with each other. All SF3a subunits are essential for the formation of the mature 17S U2 snRNP and the prespliceosome. Single subunits engage in interactions with the 15S U2 snRNP (consisting of the 12S U2 snRNP and SF3b), and SF3a60 appears to play a major role in recruiting SF3a120 into the U2 particle. Analysis of functional domains in SF3a60 and SF3a66 identified interaction sites for SF3a120 in their N-terminal portions. C(2)H(2)-type zinc finger domains mediate the integration of SF3a60 and SF3a66 into the U2 snRNP, and we propose a model in which protein-protein interactions between the zinc finger domains and the Sm proteins, common to all spliceosomal snRNPs, contribute to the assembly of the 17S U2 snRNP. Finally, we demonstrate that all domains required for interactions within the SF3a heterotrimer and the formation of the 17S U2 snRNP are also necessary to assemble the prespliceosome.