B-cell and plasma-cell splicing differences: a potential role in regulated immunoglobulin RNA processing

The immunoglobulin micro pre-mRNA is alternatively processed at its 3' end by competing splice and cleavage-polyadenylation reactions to generate mRNAs encoding the membrane-associated or secreted forms of the IgM protein, respectively. The relative use of the competing processing pathways varies during B-lymphocyte development, and it has been established previously that cleavage-polyadenylation activity is higher in plasma cells, which secrete IgM, than in B cells, which produce membrane-associated IgM. To determine whether RNA-splicing activity varies during B-lymphocyte development to contribute to micro RNA-processing regulation, we first demonstrate that micro pre-mRNA processing is sensitive to artificial changes in the splice environment by coexpressing SR proteins with the micro gene. To explore differences between the splice environments of B cells and plasma cells, we analyzed the splicing patterns from two different chimeric non-Ig genes that can be alternatively spliced but have no competing cleavage-polyadenylation reaction. The ratio of intact exon splicing to cryptic splice site use from one chimeric gene differs between several B-cell and several plasma-cell lines. Also, the amount of spliced RNA is higher in B-cell than plasma-cell lines from a set of genes whose splicing is dependent on a functional exonic splice enhancer. Thus, there is clear difference between the B-cell and plasma-cell splicing environments. We propose that both general cleavage-polyadenylation and general splice activities are modulated during B-lymphocyte development to ensure proper regulation of the alternative micro RNA processing pathways.     

The SR protein B52/SRp55 is essential for Drosophila development.

B52, also called SRp55, is a 52-kDa member of the Drosophila SR protein family of general splicing factors. Escherichia coli-produced B52 is capable of both activating splicing and affecting the alternative splice site choice in human in vitro splicing reactions. Here we report the isolation of a B52 null mutant generated by remobilizing a P element residing near the B52 gene. The resulting deletion, B52(28), is confined to the B52 gene and its neighbor the Hrb87F gene. Second-instar larvae homozygous for the deletion are deficient in both B52 mRNA and protein. The B52 null mutant is lethal at the first- and second-instar larval stages. Germ line transformation of Drosophila flies with B52 genomic DNA rescues this lethality. Thus, B52 is an essential gene and has a critical role in Drosophila development. Larvae deficient in B52 are still capable of splicing the five endogenous pre-mRNAs tested here, including both constitutively and alternatively spliced genes. Therefore, B52 is not required for all splicing in vivo. This is the first in vivo deficiency analysis of a member of the SR protein family.     

A role for U2/U6 helix Ib in 5' splice site selection.

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.     

Distinct factor requirements for exonic splicing enhancer function and binding of U2AF to the polypyrimidine tract

Exonic splicing enhancer (ESE) sequences are important for the recognition of adjacent splice sites in pre-mRNA and for the regulation of splice site selection. It has been proposed that ESEs function by associating with one or more serine/arginine-repeat (SR) proteins which stabilize the binding of the U2 small nuclear ribonucleoprotein particle (snRNP) auxiliary factor (U2AF) to the polypyrimidine tract upstream of the 3' splice site. We have tested this model by analyzing the composition of splicing complexes assembled on an ESE-dependent pre-mRNA derived from the doublesex gene of Drosophila. Several SR proteins and hTra2beta, a human homolog of the Drosophila alternative splicing regulator Transformer-2, associate with this pre-mRNA in the presence, but not in the absence, of a purine-rich ESE. By contrast, the 65-kDa subunit of U2AF (U2AF-65 kDa) bound equally to the pre-mRNA in the presence and absence of the ESE. Time course experiments revealed differences in the levels and kinetics of association of individual SR proteins with the ESE-containing pre-mRNA, whereas U2AF-65 kDa bound prior to most SR proteins and hTra2beta and its level of binding did not change significantly during the course of the splicing reaction. Binding of U2AF-65 kDa to the ESE-dependent pre-mRNA was, however, dependent on U1 snRNP. The results indicate that an ESE promotes spliceosome formation through interactions that are distinct from those required for the binding of U2AF-65 kDa to the polypyrimidine tract.     

Pre-mRNA splicing by the essential Drosophila protein B52: tissue and target specificity

B52, an essential SR protein of Drosophila melanogaster, stimulates pre-mRNA splicing in splicing-deficient mammalian S100 extracts. Surprisingly, mutant larvae depleted of B52 were found to be capable of splicing at least several pre-mRNAs tested (H. Z. Ring and J. T. Lis, Mol. Cell. Biol. 14:7499-7506, 1994). In a homologous in vitro system, we demonstrated that B52 complements a Drosophila S100 extract to allow splicing of a Drosophila fushi tarazu (ftz) mini-pre-mRNA. Moreover, Kc cell nuclear extracts that were immunodepleted of B52 lost their ability to splice this ftz pre-mRNA. In contrast, splicing of this same ftz pre-mRNA occurred in whole larvae homozygous for the B52 deletion. Other SR protein family members isolated from these larvae could substitute for B52 splicing activity in vitro. We also observed that SR proteins are expressed variably in different larval tissues. B52 is the predominant SR protein in specific tissues, including the brain. Tissues in which B52 is normally the major SR protein, such as larval brain tissue, failed to produce ftz mRNA in the B52 deletion line. These observations support a model in which the lethality of the B52 deletion strain is a consequence of splicing defects in tissues in which B52 is normally the major SR protein.     

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.     

Mutagenesis of the Yeast Gene Prp8 Reveals Domains Governing the Specificity and Fidelity of 3' Splice Site Selection

PRP8 encodes a highly conserved U5 snRNP protein required for spliceosome assembly and later steps of pre-mRNA splicing. We recently identified a novel allele, prp8-101, that specifically impairs recognition of the uridine tract that precedes most yeast 3'' slice sites. We carried out extensive mutagenesis of the gene and selected for new alleles that confer a phenotype similar to that of prp8-101. The strongest alleles cause changes in one of two amino acids in the C-terminal portion of the protein. We also identified a second class of PRP8 mutant that affects the fidelity of 3'' splice site utilization. These alleles suppress point mutations in the PyAG motif at the 3'' splice site and do not alter uridine tract recognition. The strongest of these alleles map to a region directly upstream of the prp8-101-like mutations. These new PRP8 alleles define two separable functions of Prp8p, required for specificity of 3'' splice site selection and fidelity of 3'' splice site utilization, respectively. Taken together with other recent biochemical and genetic data, our results suggest that Prp8p plays a functional role at the active site of the spliceosome during the second catalytic step of splicing.     

A downstream splicing enhancer is essential for in vitro pre-mRNA splicing.

Splicing enhancers have previously been shown to promote processing of introns containing weak splicing signals. Here, we extend these studies by showing that also 'strong' constitutively active introns are absolutely dependent on a downstream splicing enhancer for activity in vitro. SR protein binding to exonic enhancer elements or U1 snRNP binding to a downstream 5' splice site serve redundant functions as activators of splicing. We further show that a 5' splice site is most effective as an enhancer of splicing. Thus, a 5' splice site is functional in S100 extracts, under conditions where a SR enhancer is nonfunctional. Also, splice site pairing occurs efficiently in the absence of exonic SR enhancers, emphasizing the significance of a downstream 5' splice site as the enhancer element in vertebrate splicing.     

Genetic interaction between U6 snRNA and the first intron nucleotide in Saccharomyces cerevisiae.

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.     

The Drosophila SR protein RBP1 contributes to the regulation of doublesex alternative splicing by recognizing RBP1 RNA target sequences.

The SR proteins represent a family of splicing factors several of which have been implicated in the regulation of sex-specific alternative splicing of doublesex (dsx) pre-mRNA in Drosophila. The dsx gene is involved in Drosophila sex determination. We have identified two RNA target sequence motifs recognized by the SR protein RBP1 from Drosophila using an in vitro selection approach. Several copies of these RBP1 target sequences were found within two regions of the dsx pre-mRNA which are important for the regulation of dsx alternative splicing, the repeat region and the purine-rich polypyrimidine tract of the regulated female-specific 3' splice site. We show that RBP1 target sequences within the dsx repeat region are required for the efficient splicing of dsx pre-mRNA. Moreover, our studies reveal that RBP1 contributes to the activation of female-specific dsx splicing in vivo by recognizing the RBP1 target sequences within the purine-rich polypyrimidine tract of the female-specific 3' splice site.     

Binding of a candidate splice regulator to a calcitonin-specific splice enhancer regulates calcitonin/CGRP pre-mRNA splicing

The calcitonin/calcitonin gene-related peptide (CGRP) pre-mRNA is alternatively processed in a tissue-specific manner leading to the production of calcitonin mRNA in thyroid C cells and CGRP mRNA in neurons. A candidate calcitonin/CGRP splice regulator (CSR) isolated from rat brain was shown to inhibit calcitonin-specific splicing in vitro. CSR specifically binds to two regions in the calcitonin-specific exon 4 RNA previously demonstrated to function as a bipartate exonic splice enhancer (ESE). The two regions, A and B element, are necessary for inclusion of exon 4 into calcitonin mRNA. A novel RNA footprinting method based on the UV cross-linking assay was used to define the site of interaction between CSR and B element RNA. Base changes at the CSR binding site prevented CSR binding to B element RNA and CSR was unable to inhibit in vitro splicing of pre-mRNAs containing the mutated CSR binding site. When expressed in cells that normally produce predominantly CGRP mRNA, a calcitonin/CGRP gene containing the mutated CSR binding site expressed predominantly calcitonin mRNA. These observations demonstrate that CSR binding to the calcitonin-specific ESE regulates calcitonin/CGRP pre-mRNA splicing.     

Evidence for a role of Sky1p-mediated phosphorylation in 3' splice site recognition involving both Prp8 and Prp17/Slu4

The SRPK family of kinases is specific for RS domain-containing splicing factors and known to play a critical role in protein-protein interaction and intracellular distribution of their substrates in both yeast and mammalian cells. However, the function of these kinases in pre-mRNA splicing remains unclear. Here we report that SKY1, a SRPK family member in Saccharomyces cerevisiae, genetically interacts with PRP8 and PRP17/SLU4, both of which are involved in splice site selection during pre-mRNA splicing. Prp8 is essential for splicing and is known to interact with both 5' and 3' splice sites in the spliceosomal catalytic center, whereas Prp17/Slu4 is nonessential and is required only for efficient recognition of the 3' splice site. Interestingly, deletion of SKY1 was synthetically lethal with all prp17 mutants tested, but only with specific prp8 alleles in a domain implicated in governing fidelity of 3'AG recognition. Indeed, deletion of SKY1 specifically suppressed 3'AG mutations in ACT1-CUP1 splicing reporters. These results suggest for the first time that 3' AG recognition may be subject to phosphorylation regulation by Sky1p during pre-mRNA splicing.     

Selection of the bovine papillomavirus type 1 nucleotide 3225 3' splice site is regulated through an exonic splicing enhancer and its juxtaposed exonic splicing suppressor.

Alternative splicing is an important mechanism for the regulation of bovine papillomavirus type 1 (BPV-1) gene expression during the virus life cycle. However, one 3' splice site, located at nucleotide (nt) 3225, is used for the processing of most BPV-1 pre-mRNAs in BPV-1-transformed C127 cells and at early to intermediate times in productively infected warts. At late stages of the viral life cycle, an alternative 3' splice site at nt 3605 is used for the processing of the late pre-mRNA. In this study, we used in vitro splicing in HeLa cell nuclear extracts to identify cis elements which regulate BPV-1 3' splice site selection. Two purine-rich exonic splicing enhancers were identified downstream of nt 3225. These sequences, designated SE1 (nt 3256 to 3305) and SE2 (nt 3477 to 3526), were shown to strongly stimulate the splicing of a chimeric Drosophila doublesex pre-mRNA, which contains a weak 3' splice site. A BPV-1 late pre-mRNA containing the nt 3225 3' splice site but lacking both SE1 and SE2 was spliced poorly, indicating that this 3' splice site is inherently weak. Analysis of the 3' splice site suggested that this feature is due to both a nonconsensus branch point sequence and a suboptimal polypyrimidine tract. Addition of SE1 to the late pre-mRNA dramatically stimulated splicing, indicating that SE1 also functions as an exonic splicing enhancer in its normal context. However, a late pre-mRNA containing both SE1 and SE2 as well as the sequence in between was spliced inefficiently. Further mapping studies demonstrated that a 48-nt pyrimidine-rich region immediately downstream of SE1 was responsible for this suppression of splicing. Thus, these data suggest that selection of the BPV-1 nt 3225 3' splice site is regulated by both positive and negative exonic sequences.     

The serine/arginine-rich protein family in rice plays important roles in constitutive and alternative splicing of pre-mRNA

Ser/Arg-rich (SR) proteins play important roles in the constitutive and alternative splicing of pre-mRNA. We isolated 20 rice (Oryza sativa) genes encoding SR proteins, of which six contain plant-specific characteristics. To determine whether SR proteins modulate splicing efficiency and alternative splicing of pre-mRNA in rice, we used transient assays in rice protoplasts by cotransformation of SR protein genes with the rice Waxy(b) (Wx(b))-beta-glucuronidase fusion gene. The results showed that plant-specific RSp29 and RSZp23, an SR protein homologous to human 9G8, enhanced splicing and altered the alternative 5' splice sites of Wx(b) intron 1. The resulting splicing pattern was unique to each SR protein; RSp29 stimulated splicing at the distal site, and RSZp23 enhanced splicing at the proximal site. Results of domain-swapping experiments between plant-specific RSp29 and SCL26, which is a homolog of human SC35, showed the importance of RNA recognition motif 1 and the Arg/Ser-rich (RS) domain for the enhancement of splicing efficiencies. Overexpression of plant-specific RSZ36 and SRp33b, a homolog of human ASF/SF2, in transgenic rice changed the alternative splicing patterns of their own pre-mRNAs and those of other SR proteins. These results show that SR proteins play important roles in constitutive and alternative splicing of rice pre-mRNA.