The conserved pre-mRNA splicing factor U2AF from Drosophila: requirement for viability

Pyrimidine tracts between the 5' splice site and branch point facilitate splicing and recognition of a small Drosophila intron

The minimum size for splicing of a vertebrate intron is approximately 70 nucleotides. In Drosophila melanogaster, more than half of the introns are significantly below this minimum yet function well. Such short introns often lack the pyrimidine tract located between the branch point and 3' splice site common to metazoan introns. To investigate if small introns contain special sequences that facilitate their recognition, the sequences and factors required for the splicing of a 59-nucleotide intron from the D. melanogaster mle gene have been examined. This intron contains only a minimal region of interrupted pyrimidines downstream of the branch point. Instead, two longer, uninterrupted C-rich tracts are located between the 5' splice site and branch point. Both of these sequences are required for maximal in vivo and in vitro splicing. The upstream sequences are also required for maximal binding of factors to the 5' splice site, cross-linking of U2AF to precursor RNA, and assembly of the active spliceosome, suggesting that sequences upstream of the branch point influence events at both ends of the small mle intron. Thus, a very short intron lacking a classical pyrimidine tract between the branch point and 3' splice site requires accessory pyrimidine sequences in the short region between the 5' splice site and branch point.

Cloning of Caenorhabditis U2AF65: an alternatively spliced RNA containing a novel exon

The U2 small nuclear ribonucleoprotein particle (snRNP) auxiliary factor, U2AF, is an essential splicing factor required for recognition of the polypyrimidine tract and subsequent U2 snRNP assembly at the branch point. Because Caenorhabditis elegans introns lack both polypyrimidine tract and branch point consensus sequences but have a very highly conserved UUUUCAG/R consensus at their 3' splice sites, we hypothesized that U2AF might serve to recognize this sequence and thus promote intron recognition in C. elegans. Here we report the cloning of the gene for the large subunit of U2AF, uaf-1. Three classes of cDNA were identified. In the most abundant class the open reading frame is similar to that for the U2AF65 from mammals and flies. The remaining two classes result from an alternative splicing event in which an exon containing an in-frame stop codon is inserted near the beginning of the second RNA recognition motif. However, this alternative mRNA is apparently not translated. Interestingly, the inserted exon contains 10 matches to the 3' splice site consensus. To determine whether this feature is conserved, we sequenced uaf-1 from the related nematode Caenorhabditis briggsae. It is composed of six exons, including an alternatively spliced third exon interrupting the gene at the same location as in C. elegans. uaf-1 is contained in an operon with the rab-18 gene in both species. Although the alternative exons from the two species are not highly conserved and would not encode related polypeptides, the C. briggsae alternative exon has 18 matches to the 3' splice site consensus. We hypothesize that the array of 3' splice site-like sequences in the pre-mRNA and alternatively spliced exon may have a regulatory role. The alternatively spliced RNA accumulates at high levels following starvation, suggesting that this RNA may represent an adaption for reducing U2AF65 levels when pre-mRNA levels are low.

Targeted disruption of an essential vertebrate gene: ASF/SF2 is required for cell viability

Alternative splicing factor/splicing factor 2 (ASF/SF2) is the prototype of a family of nuclear proteins highly conserved throughout metazoa, the SR (serine/arginine) proteins. Based largely on in vitro studies, SR proteins have been suggested to play important roles in constitutive and alternative splicing of pre-mRNAs. Here we describe the development of a genetic system employing the chicken B-cell line DT40 to study the function of ASF/SF2 in vivo. The high level of homologous recombination and rapid growth rate of these cells allowed us to show first that ASF/SF2 is an essential gene, and then to perform targeted disruption of both ASF/SF2 alleles, by creating a cell line in which the only source of ASF/SF2 is a human cDNA controlled by a tetracycline (tet)-repressible promoter. We show that addition of tet to these cells results in rapid depletion of ASF/SF2, concomitant accumulation of incompletely processed pre-mRNA, and subsequent cell death. The tet-induced lethality could be rescued by plasmids expressing wild-type ASF/SF2, but not several mutant derivatives, or other SR proteins. Heterozygous cell lines overexpressing human ASF/SF2 displayed significant reductions of endogenous ASF/SF2 mRNA, suggesting that ASF/SF2 mRNA levels are controlled by an autoregulatory loop. This system provides a novel method for genetic analysis of factors that function in basic processes in vertebrate cells.

Functional properties of p54, a novel SR protein active in constitutive and alternative splicing

The p54 protein was previously identified by its reactivity with an autoantiserum. We report here that p54 is a new member of the SR family of splicing factors, as judged from its structural, antigenic, and functional characteristics. Consistent with its identification as an SR protein, p54 can function as a constitutive splicing factor in complementing splicing-deficient HeLa cell S100 extract. However, p54 also shows properties distinct from those of other SR family members, p54 can directly interact with the 65-kDa subunit of U2 auxiliary factor (U2AF65), a protein associated with the 3' splice site. In addition, p54 interacts with other SR proteins but does not interact with the U1 small nuclear ribonucleoprotein U1-70K or the 35-kDa subunit of U2 auxiliary factor (U2AF35). This protein-protein interaction profile is different from those of prototypical SR proteins SC35 and ASF/SF2, both of which interact with U1-70K and U2AF35 but not with U2AF65. p54 promotes the use of the distal 5' splice site in E1A pre-mRNA alternative splicing, while the same site is suppressed by ASF/SF2 and SC35. These findings and the differential tissue distribution of p54 suggest that this novel SR protein may participate in regulation of alternative splicing in a tissue- and substrate-dependent manner.

Mutations in the small subunit of the Drosophila U2AF splicing factor cause lethality and developmental defects

The essential eukaryotic pre-mRNA splicing factor U2AF (U2 small nuclear ribonucleoprotein auxiliary factor) is required to specify the 3' splice at an early step in spliceosome assembly. U2AF binds site-specifically to the intron polypyrimidine tract and recruits U2 small nuclear ribonucleoprotein to the branch site. Human U2AF (hU2AF) is a heterodimer composed of a large (hU2AF65) and small (hU2AF35) subunit. Although these proteins associate in a tight complex, the biochemical requirement for U2AF activity can be satisfied solely by the large subunit. The requirement for the small subunit in splicing has remained enigmatic. No biochemical activity has been found for hU2AF35 and it has been implicated in splicing only indirectly by its interaction with known splicing factors. In the absence of a biochemical assay, we have taken a genetic approach to investigate the function of the small subunit in the fruit fly Drosophila melanogaster. A cDNA clone encoding the small subunit of Drosophila U2AF (dU2AF38) has been isolated and sequenced. The dU2AF38 protein is highly homologous to hU2AF35 containing a conserved central arginine- and serine-rich (RS) domain. A recessive P-element insertion mutation affecting dU2AF38 causes a reduction in viability and fertility and morphological bristle defects. Consistent with a general role in splicing, a null allele of dU2AF38 is fully penetrant recessive lethal, like null alleles of the Drosophila U2AF large subunit.

Biochemistry and regulation of pre-mRNA splicing

During the past year, significant advances have been made in the field of pre-mRNA splicing. It is now clear that members of the serine-arginine-rich protein family are key players in exon definition and function at multiple steps in the spliceosome cycle. Novel findings have been made concerning the role of exon sequences, which function as both constitutive and regulated enhancers of splicing, in trans-splicing and as targets for tissue-specific control of splicing patterns. By combining biochemical approaches in human and yeast extracts with genetic analysis, much has been learned about the RNA-RNA and RNA-protein interactions that are necessary to assemble the various complexes that are found along the pathway to the catalytically active spliceosome.

The splicing factor U2AF35 mediates critical protein-protein interactions in constitutive and enhancer-dependent splicing

The splicing factor U2AF (U2 snRNP auxiliary factor) is a heterodimer with subunits of 65 and 35 kD (U2AF65 and U2AF35). U2AF65 binds specifically to 3' splice sites, but previous studies failed to demonstrate a function for U2AF35. Here, we report that U2AF35 is required for constitutive splicing and also functions as a mediator of enhancer-dependent splicing. Nuclear extracts deficient in U2AF35 were inactive; however, both constitutive and enhancer-dependent splicing could be restored by the addition of purified recombinant U2AF35. In vitro protein-RNA interaction studies with pre-mRNAs containing either a constitutive or regulated splicing enhancer revealed that U2AF35 directly mediates interactions between U2AF65 and proteins bound to the enhancers. Thus, U2AF35 functions as a bridge between U2AF65 and the enhancer complex to recruit U2AF65 to the adjacent intron.

The small subunit of the splicing factor U2AF is conserved in fission yeast

The human splicing factor U2 auxiliary factor (hsU2AF) is comprised of two interacting subunits of 65 and 35 kDa. Previously we identified the Schizosaccharomyces pombe homolog, spU2AF59, of the human large subunit. We have screened a fission yeast cDNA library in search of proteins that interact with spU2AF59 using the yeast two-hybrid system and have identified a homolog of the hsU2AF35 subunit. The S. pombe U2AF small subunit is a single copy gene that encodes a protein which shares 55% amino acid identity and 17% similarity with the human small subunit. Unlike the human protein, the yeast protein lacks an arginine/serine-rich region. The predicted molecular mass of the spU2AF small subunit is 23 kDa. The region of spU2AF59 that interacts with spU2AF23 is similar to the region in which the human small and large subunits interact.

Distinct binding specificities and functions of higher eukaryotic polypyrimidine tract-binding proteins

In higher eukaryotes, the polypyrimidine-tract (Py-tract) adjacent to the 3' splice site is recognized by several proteins, including the essential splicing factor U2AF65, the splicing regulator Sex-lethal (Sxl), and polypyrimidine tract-binding protein (PTB), whose function is unknown. Iterative in vitro genetic selection was used to show that these proteins have distinct sequence preferences. The uridine-rich degenerate sequences selected by U2AF65 are similar to those present in the diverse array of natural metazoan Py-tracts. In contrast, the Sxl-consensus is a highly specific sequence, which can help explain the ability of Sxl to regulate splicing of transformer pre-mRNA and autoregulate splicing of its own pre-mRNA. The PTB-consensus is not a typical Py-tract; it can be found in certain alternatively spliced pre-mRNAs that undergo negative regulation. Here it is shown that PTB can regulate alternative splicing by selectively repressing 3' splice sites that contain a PTB-binding site.

Soma-specific expression and cloning of PSI, a negative regulator of P element pre-mRNA splicing

PSI is an RNA-binding protein involved in repressing splicing of the P element third intron in Drosophila somatic cell extracts. PSI produced in bacteria restores splicing inhibition to an extract relieved of inhibitory activity, indicating that PSI plays a direct role in somatic inhibition. Sequence analysis of cDNAs encoding PSI reveals three KH RNA-binding domains, a conserved motif also found in the yeast splicing regulator MER1. Notably, PSI is expressed highly in somatic embryonic nuclei but is undetectable in germ-line cells. In contrast, hrp48, another protein implicated in somatic inhibition, is found in the nucleus and cytoplasm of both tissues. The splicing inhibitory properties and soma-specific expression of PSI may be sufficient to explain the germ-line-specific transposition of P elements.

The yeast MUD2 protein: an interaction with PRP11 defines a bridge between commitment complexes and U2 snRNP addition

In characterizing a series of yeast (Saccharomyces cerevisiae) mutants synthetic lethal with U1 RNA, we have identified a yeast gene (MUD2) with sequence similarity to the well-studied metazoan splicing factor U2AF65. The biochemical characterization indicates that the MUD2 gene product (MUD2P) contacts pre-mRNA directly and is a component of the pre-mRNA-U1 snRNP complex (commitment complex) that forms during early spliceosome assembly in yeast extracts. Unlike U1 snRNP itself, the association of MUD2P with pre-mRNA is dependent on a proper yeast branchpoint sequence. Genetic experiments indicate that MUD2P affects U2 snRNP addition. Moreover, experiments in the two-hybrid system show that PRP11P, a recently identified component of U2 snRNP, can interact directly with MUD2P. The experiments identify a specific inter-snRNP protein-protein contact that occurs during spliceosome assembly and more generally support substantial functional similarity between U2AF65 and MUD2P.

Pre-mRNA splicing

Information from yeast and mammalian pre-mRNA splicing systems has advanced our understanding of the roles of protein factors in the early steps of spliceosome assembly. New results on the stereochemistry of nuclear pre-mRNA splicing and data on the transposition of Group II self-splicing introns in vivo have fuelled the long-running debate on the evolution of introns and RNA splicing.