Purification and cDNA cloning of HeLa cell p54nrb, a nuclear protein with two RNA recognition motifs and extensive homology to human splicing factor PSF and Drosophila NONA/BJ6

While searching for a human homolog of the S.cerevisiae splicing factor PRP18, we found a polypeptide that reacted strongly with antibodies against PRP18. We purified this polypeptide from HeLa cells using a Western blot assay, and named it p54nrb (for nuclear RNA-binding protein, 54 kDa). cDNAs encoding p54nrb were cloned with probes derived from partial sequence of the purified protein. These cDNAs have identical coding sequences but differ as a result of alternative splicing in the 5' untranslated region. The cDNAs encode a 471 aa polypeptide that contains two RNA recognition motifs (RRMs). Human p54nrb has no homology to yeast PRP18, except for a common epitope, but is instead 71% identical to human splicing factor PSF within a 320 aa region that includes both RRMs. In addition, both p54nrb and PSF are rich in Pro and Gln residues outside the main homology region. The Drosophila puff-specific protein BJ6, one of three products encoded by the alternatively spliced no-on-transient A gene (nonA), which is required for normal vision and courtship song, is 42% identical to p54nrb in the same 320 aa region. The striking homology between p54nrb, PSF, and NONA/BJ6 defines a novel phylogenetically conserved protein segment, termed DBHS domain (for Drosophila behavior, human splicing), which may be involved in regulating diverse pathways at the level of pre-mRNA splicing.     

Multiple forms of the U2 small nuclear ribonucleoprotein auxiliary factor U2AF subunits expressed in higher plants

Requirements for intron recognition during pre-mRNA splicing in plants differ from those in vertebrates and yeast. Plant introns contain neither conserved branch points nor distinct 3' splice site-proximal polypyrimidine tracts characteristic of the yeast and vertebrate introns, respectively. However, they are strongly enriched in U residues throughout the intron, property essential for splicing. To understand the roles of different sequence elements in splicing, we are characterizing proteins involved in intron recognition in plants. In this work we show that Nicotiana plumbaginifolia, a dicotyledonous plant, contains two genes encoding different homologs of the large 50-65-kDa subunit of the polypyrimidine tract binding factor U2AF, characterized previously in animals and Schizosaccharomyces pombe. Both plant U2AF65 isoforms, referred to as NpU2AF65a and NpU2AF65b, support splicing of an adenovirus pre-mRNA in HeLa cell nuclear extracts depleted of the endogenous U2AF factor. Both proteins interact with RNA fragments containing plant introns and show affinity for poly(U) and, to a lesser extend, poly(C) and poly(G). The branch point or the 3' splice site regions do not contribute significantly to intron recognition by NpU2AF65. The existence of multiple isoforms of U2AF may be quite general in plants because two genes expressing U2AF65 have been identified in Arabidopsis, and different isoforms of the U2AF small subunit are expressed in rice.     

Mutation of PTB binding sites causes misregulation of alternative 3' splice site selection in vivo

Alternative splicing of pre-mRNA is a commonly used mechanism to regulate gene expression in higher eukaryotes. However, with the exception of regulated cascades in Drosophila, the cis-acting elements and the trans-acting factors that control tissue- and/or developmentally regulated splicing remain largely unidentified. Cis-acting elements that control smooth muscle-specific repression of exon 3 of alpha-tropomyosin (alpha-TM) have been identified recently and consist of two regions that flank this exon. Deletion of either element causes misregulated splicing of alpha-TM in transfected smooth muscle cells. In experiments designed to characterize essential sequences within each element and the factors that interact with these sequences, we have identified two overlapping sequences within the downstream regulatory element (DRE) that are identical to binding sites for polypyrimidine tract binding protein (PTB) that were identified using iterative selection techniques. Mutation of these sites caused aberrant splicing regulation in transfected smooth muscle cells. In addition, sequences identical to high-affinity PTB binding sites were also detected upstream of exon 3 and mutation of these sites also resulted in misregulation of splicing in vivo, suggesting that PTB binding to specific sequences flanking exon 3 is responsible, in part, for the repression of exon 3. Consistent with this hypothesis, UV crosslinking and equilibrium binding assays confirm that the same mutations that cause misregulated splicing also disrupt PTB binding to RNA.     

Oncoprotein TLS interacts with serine-arginine proteins involved in RNA splicing

The gene encoding the human TLS protein, also termed FUS, is located at the site of chromosomal translocations in human leukemias and sarcomas where it forms a chimeric fusion gene with one of several different genes. To identify interacting partners of TLS, we screened a yeast two-hybrid cDNA library constructed from mouse hematopoietic cells using the C-terminal region of TLS in the bait plasmid. Two cDNAs encoding members of the serine-arginine (SR) family of proteins were isolated. The first SR protein is the mouse homolog of human splicing factor SC35, and the second SR member is a novel 183-amino acid protein that we term TASR (TLS-associated serine-arginine protein). cDNA cloning of human TASR indicated that mouse and human TASR have identical amino acid sequences. The interactions between TLS and these two SR proteins were confirmed by co-transfection and immunoprecipitation studies. In vivo splicing assays indicated that SC35 and TASR influence splice site selection of adenovirus E1A pre-mRNA. TLS may recruit SR splicing factors to specific target genes through interaction with its C-terminal region, and chromosomal translocations that truncate the C-terminal region of TLS may prevent this interaction. Thus TLS translocations may alter RNA processing and play a role in malignant transformation.     

A T to G mutation in the polypyrimidine tract of the second intron of the human beta-globin gene reduces in vitro splicing efficiency: evidence for an increased hnRNP C interaction

In a patient with a beta-thalassemia intermedia, a mutation was identified in the second intron of the human beta-globin gene. The U-->G mutation is located within the polypyrimidine tract at position -8 upstream of the 3' splice site. In vivo, this mutation leads to decreased levels of the hemoglobin protein. Because of the location of the mutation and the role of the polypyrimidine tract in the splicing process, we performed in vitro splicing assays on the pre-messenger RNA (pre-mRNA). We found that the splicing efficiency of the mutant pre-mRNA is reduced compared to the wild type and that no cryptic splice sites are activated. Analysis of splicing complex formation shows that the U-->G mutation affects predominantly the progression of the H complex towards the pre-spliceosome complex. By cross-linking and immunoprecipitation assays, we show that the hnRNP C protein interacts more efficiently with the mutant precursor than with the wild-type. This stronger interaction could play a role, directly or indirectly, in the decreased splicing efficiency.     

A potential role for U2AF-SAP 155 interactions in recruiting U2 snRNP to the branch site

Base pairing between U2 snRNA and the branchpoint sequence (BPS) is essential for pre-mRNA splicing. Because the metazoan BPS is short and highly degenerate, this interaction alone is insufficient for specific binding of U2 snRNP. The splicing factor U2AF binds to the pyrimidine tract at the 3' splice site in the earliest spliceosomal complex, E, and is essential for U2 snRNP binding in the spliceosomal complex A. We show that the U2 snRNP protein SAP 155 UV cross-links to pre-mRNA on both sides of the BPS in the A complex. SAP 155's downstream cross-linking site is immediately adjacent to the U2AF binding site, and the two proteins interact directly in protein-protein interaction assays. Using UV cross-linking, together with functional analyses of pre-mRNAs containing duplicated BPSs, we show a direct correlation between BPS selection and UV cross-linking of SAP 155 on both sides of the BPS. Together, our data are consistent with a model in which U2AF binds to the pyrimidine tract in the E complex and then interacts with SAP 155 to recruit U2 snRNP to the BPS.     

The PRP31 gene encodes a novel protein required for pre-mRNA splicing in Saccharomyces cerevisiae

The pre-mRNA splicing factor Prp31p was identified in a screen of temperature-sensitive yeast strains for those exhibiting a splicing defect upon shift to the non- permissive temperature. The wild-type PRP31 gene was cloned and shown to be essential for cell viability. The PRP31 gene is predicted to encode a 60 kDa polypeptide. No similarities with other known splicing factors or motifs indicative of protein-protein or RNA-protein interaction domains are discernible in the predicted amino acid sequence. A PRP31 allele bearing a triple repeat of the hemagglutinin epitope has been generated. The tagged protein is functional in vivo and a single polypeptide species of the predicted size was detected by Western analysis with proteins from yeast cell extracts. Functional Prp31p is required for the processing of pre-mRNA species both in vivo and in vitro, indicating that the protein is directly involved in the splicing pathway.     

The role of branchpoint-3' splice site spacing and interaction between intron terminal nucleotides in 3' splice site selection in Saccharomyces cerevisiae

A conserved 3' splice site YAG is essential for the second step of pre-mRNA splicing but no trans-acting factor recognizing this sequence has been found. A direct, non-Watson-Crick interaction between the intron terminal nucleotides was suggested to affect YAG selection. The mechanism of YAG recognition was proposed to involve 5' to 3' scanning originating from the branchpoint or the polypyrimidine tract. We have constructed a yeast intron harbouring two closely spaced 3' splice sites. Preferential selection of a wild-type site over mutant ones indicated that the two sites are competing. For two identical sequences, the proximal site is selected. As previously observed, an A at the first intron nucleotide spliced most efficiently with a 3' splice site UAC. In this context, UAA or UAU were also more efficient 3' splice sites than UAG and competed more efficiently than the wild-type sequence with a 3' splice site UAC. We observed that a U at the first intron nucleotide is used for splicing in combination with 3' splice sites UAG, UAA or UAU. Our data indicate that the 3' splice site is not primarily selected through an interaction with the first intron nucleotide. Selection of the 3' splice site depends critically on its distance from the branchpoint but does not occur by a simple leaky scanning mechanism.     

A coactivator of pre-mRNA splicing

The nuclear matrix antigen recognized by the monoclonal antibody (mAb) B1C8 is a novel serine (S) and arginine (R)-rich protein associated with splicing complexes and is named here SRm160 (SR-related matrix protein of 160 kD). SRm160 contains multiple SR repeats, but unlike proteins of the SR family of splicing factors, lacks an RNA recognition motif. SRm160 and a related protein SRm300 (the 300-kD nuclear matrix antigen recognized by mAb B4A11) form a complex that is required for the splicing of specific pre-mRNAs. The SRm160/300 complex associates with splicing complexes and promotes splicing through interactions with SR family proteins. Binding of SRm160/300 to pre-mRNA is normally also dependent on U1 snRNP and is stabilized by U2 snRNP. Thus, SRm160/300 forms multiple interactions with components bound directly to important sites within pre-mRNA. The results suggest that a complex of the nuclear matrix proteins SRm160 and SRm300 functions as a coactivator of pre-mRNA splicing.     

Enhancer elements activate the weak 3' splice site of alpha-tropomyosin exon 2

We have identified four purine-rich sequences that act as splicing enhancer elements to activate the weak 3' splice site of alpha-tropomyosin exon 2. These elements also activate the splicing of heterologous substrates containing weak 3' splice sites or mutated 5' splice sites. However, they are unique in that they can activate splicing whether they are placed in an upstream or downstream exon, and the two central elements can function regardless of their position relative to one another. The presence of excess RNAs containing these enhancers could effectively inhibit in vitro pre-mRNA splicing reactions in a substrate-dependent manner and, at lower concentrations of competitor RNA, the addition of SR proteins could relieve the inhibition. However, when extracts were depleted by incubation with biotinylated exon 2 RNAs followed by passage over streptavidin agarose, SR proteins were not sufficient to restore splicing. Instead, both SR proteins and fractions containing a 110-kD protein were necessary to rescue splicing. Using gel mobility shift assays, we show that formation of stable enhancer-specific complexes on alpha-tropomyosin exon 2 requires the presence of both SR proteins and the 110-kD protein. By analogy to the doublesex exon enhancer elements in Drosophila, our results suggest that assembly of mammalian exon enhancer complexes requires both SR and non-SR proteins to activate selection of weak splice sites.     

The budding yeast U5 snRNP Prp8 is a highly conserved protein which links RNA splicing with cell cycle progression

The dbf3 mutation was originally obtained in a screen for DNA synthesis mutants with a cell cycle phenotype in the budding yeast Saccharomyces cerevisiae. We have now isolated the DBF3 gene and found it to be an essential gene with an ORF of 7239 nucleotides, potentially encoding a large protein of 268 kDa. We also obtained an allele-specific high copy number suppressor of the dbf3-1 allele, encoded by the known SSB1 gene, a member of the Hsp70 family of heat shock proteins. The sequence of the Dbf3 protein is 58% identical over 2300 amino acid residues to a predicted protein from Caenorhabditis elegans. Furthermore, partial sequences with 61% amino acid sequence identity were deduced from two files of human cDNA in the EST nucleotide database so that Dbf3 is a highly conserved protein. The nucleotide sequence of DBF3 turned out to be identical to the yeast gene PRP8, which encodes a U5 snRNP required for pre-mRNA splicing. This surprising result led us to further characterise the phenotype of dbf3 which confirmed its role in the cell cycle and showed it to function early, around the time of S phase. This data suggests a hitherto unexpected link between pre-mRNA splicing and the cell cycle.     

Modulation of E-cadherin expression in TPA-induced cell motility: well-differentiated human adenocarcinoma cells move as coherent sheets associated with phosphorylation of E-cadherin-catenin complex

We have identified a human splicing factor required for the second step of pre-mRNA splicing. This new protein, hPrp18, is 30% identical to the yeast splicing factor Prp18. In HeLa cell extracts immunodepleted of hPrp18, the second step of pre-mRNA splicing is abolished. Splicing activity is restored by the addition of recombinant hPrp18, demonstrating that hPrp18 is required for the second step. The hPrp18 protein is bound tightly to the spliceosome only during the second step of splicing. hPrp18 is required for the splicing of several pre-mRNAs, making it the first general second-step splicing factor found in humans. Splicing activity can be restored to hPrp18-depleted HeLa cell extracts by yeast Prp18, showing that important functional regions of the proteins have been conserved. A 90-amino-acid region near the carboxyl terminus of hPrp18 is strongly homologous to yeast Prp18 and is also conserved in rice and nematodes. The homology identifies one region important for the function of both proteins and may define a new protein motif. In contrast to yeast Prp18, hPrp18 is not stably associated with any of the snRNPs. A 55-kD protein that cross-reacts with antibodies against hPrp18 is a constituent of the U4/U6 and U4/U6 x U5 snRNP particles.     

Two independent internal ribosome entry sites are involved in translation initiation of vascular endothelial growth factor mRNA

The mRNA of vascular endothelial growth factor (VEGF), the major angiogenic growth factor, contains an unusually long (1,038 nucleotides) and structured 5' untranslated region (UTR). According to the classical translation initiation model of ribosome scanning, such a 5' UTR is expected to be a strong translation inhibitor. In vitro and bicistronic strategies were used to show that the VEGF mRNA translation was cap independent and occurred by an internal ribosome entry process. For the first time, we demonstrate that two independent internal ribosome entry sites (IRESs) are present in this 5' UTR. IRES A is located within the 300 nucleotides upstream from the AUG start codon. RNA secondary structure prediction and site-directed mutagenesis allowed the identification of a 49-nucleotide structural domain (D4) essential to IRES A activity. UV cross-linking experiments revealed that IRES A activity was correlated with binding of a 100-kDa protein to the D4 domain. IRES B is located in the first half of the 5' UTR. An element between nucleotides 379 and 483 is required for its activity. Immunoprecipitation experiments demonstrated that a main IRES B-bound protein was the polypyrimidine tract binding protein (PTB), a well-known regulator of picornavirus IRESs. However, we showed that binding of the PTB on IRES B does not seem to be correlated with its activity. Evidence is provided of an original cumulative effect of two IRESs, probably controlled by different factors, to promote an efficient initiation of translation at the same AUG codon.     

A pyrimidine-rich exonic splicing suppressor binds multiple RNA splicing factors and inhibits spliceosome assembly

The bovine papillomavirus type 1 (BPV-1) exonic splicing suppressor (ESS) is juxtaposed immediately downstream of BPV-1 splicing enhancer 1 and negatively modulates selection of a suboptimal 3' splice site at nucleotide 3225. The present study demonstrates that this pyrimidine-rich ESS inhibits utilization of upstream 3' splice sites by blocking early steps in spliceosome assembly. Analysis of the proteins that bind to the ESS showed that the U-rich 5' region binds U2AF65 and polypyrimidine tract binding protein, the C-rich central part binds 35- and 54-55-kDa serine/arginine-rich (SR) proteins, and the AG-rich 3' end binds alternative splicing factor/splicing factor 2. Mutational and functional studies indicated that the most critical region of the ESS maps to the central C-rich core (GGCUCCCCC). This core sequence, along with additional nonspecific downstream nucleotides, is sufficient for partial suppression of spliceosome assembly and splicing of BPV-1 pre-mRNAs. The inhibition of splicing by the ESS can be partially relieved by excess purified HeLa SR proteins, suggesting that the ESS suppresses pre-mRNA splicing by interfering with normal bridging and recruitment activities of SR proteins.     

Regulation of adenovirus alternative RNA splicing by dephosphorylation of SR proteins

SR proteins are a family of essential splicing factors required for early recognition of splice sites during spliceosome assembly. They also function as alternative RNA splicing factors when overexpressed in vivo or added in excess to extracts in vitro. SR proteins are highly phosphorylated in vivo, a modification that is required for their function in spliceosome assembly and splicing catalysis. Here we show that SR proteins purified from late adenovirus-infected cells are inactivated as splicing enhancer or splicing repressor proteins by virus-induced dephosphorylation. We further show that the virus-encoded protein E4-ORF4 activates dephosphorylation by protein phosphatase 2A of HeLa SR proteins and converts their splicing properties into that of SR proteins purified from late adenovirus-infected cells. Taken together, our results suggest that E4-ORF4 is an important factor controlling the temporal shift in adenovirus alternative RNA splicing. We conclude that alternative pre-mRNA splicing, like many other biological processes, is regulated by reversible protein phosphorylation.