Regulation of alternative polyadenylation by U1 snRNPs and SRp20

Although considerable information is currently available about the factors involved in constitutive vertebrate polyadenylation, the factors and mechanisms involved in facilitating communication between polyadenylation and splicing are largely unknown. Even less is known about the regulation of polyadenylation in genes in which 3'-terminal exons are alternatively recognized. Here we demonstrate that an SR protein, SRp20, affects recognition of an alternative 3'-terminal exon via an effect on the efficiency of binding of a polyadenylation factor to an alternative polyadenylation site. The gene under study codes for the peptides calcitonin and calcitonin gene-related peptide. Its pre-mRNA is alternatively processed by the tissue-specific inclusion or exclusion of an embedded 3'-terminal exon, exon 4, via factors binding to an intronic enhancer element that contains both 3' and 5' splice site consensus sequence elements. In cell types that preferentially exclude exon 4, addition of wild-type SRp20 enhances exon 4 inclusion via recognition of the intronic enhancer. In contrast, in cell types that preferentially include exon 4, addition of a mutant form of SRp20 containing the RNA-binding domain but missing the SR domain inhibits exon 4 inclusion. Inhibition is likely at the level of polyadenylation, because the mutant SRp20 inhibits binding of CstF to the exon 4 poly(A) site. This is the first demonstration that an SR protein can influence alternative polyadenylation and suggests that this family of proteins may play a role in recognition of 3'-terminal exons and perhaps in the communication between polyadenylation and splicing.     

Modulation of exon skipping and inclusion by heterogeneous nuclear ribonucleoprotein A1 and pre-mRNA splicing factor SF2/ASF

The essential splicing factor SF2/ASF and the heterogeneous nuclear ribonucleoprotein A1 (hnRNP A1) modulate alternative splicing in vitro of pre-mRNAs that contain 5' splice sites of comparable strengths competing for a common 3' splice site. Using natural and model pre-mRNAs, we have examined whether the ratio of SF2/ASF to hnRNP A1 also regulates other modes of alternative splicing in vitro. We found that an excess of SF2/ASF effectively prevents inappropriate exon skipping and also influences the selection of mutually exclusive tissue-specific exons in natural beta-tropomyosin pre-mRNA. In contrast, an excess of hnRNP A1 does not cause inappropriate exon skipping in natural constitutively or alternatively spliced pre-mRNAs. Although hnRNP A1 can promote alternative exon skipping, this effect is not universal and is dependent, e.g., on the size of the internal alternative exon and on the strength of the polypyrimidine tract in the preceding intron. With appropriate alternative exons, an excess of SF2/ASF promotes exon inclusion, whereas an excess of hnRNP A1 causes exon skipping. We propose that in some cases the ratio of SF2/ASF to hnRNP A1 may play a role in regulating alternative splicing by exon inclusion or skipping through the antagonistic effects of these proteins on alternative splice site selection.     

Cloning and structure of the gene encoding the human N-methyl-D-aspartate receptor (NMDAR1)

The complete gene encoding the human N-methyl-D-aspartate receptor subunit NR1 (NMDAR1) has been isolated on a single cosmid clone. The gene is composed of 21 exons distributed over a total length of about 31 kb. More than 24 kb were sequenced. Exons 4, 20 and 21 are identical in their amino-acid sequence to those exons that are subject to alternative splicing in rat, indicating that all eight NMDAR1 isoforms found in rat will also be expressed in the human brain. Computer analysis of the pre-mRNA sequence revealed no secondary structures stable enough to explain alternative splicing. We suggest that cell-specific factors control expression of different isoforms. The promoter region contains two perfect copies of the recognition sequence for the Drosophila even-skipped protein, indicating that the developmentally regulated expression of NMDAR1 is controlled by a homeobox protein. The complete cosmid clone covering NMDAR1 was mapped to chromosome 9q34.3-qter by fluorescent in situ hybridization (FISH). The telomeric location is supported by an imperfect (CA)n repeat homologous to a subtelomeric repeat on chromosome 16p.     

The human HNRPD locus maps to 4q21 and encodes a highly conserved protein

The hnRNP D protein interacts with nucleic acids both in vivo and in vitro. Like many other proteins that interact with RNA, it contains RBD (or "RRM") domains and arg-gly-gly (RGG) motifs. We have examined the organization and localization of the human and murine genes that encode the hnRNP D protein. Comparison of the predicted sequences of the hnRNP D proteins in human and mouse shows that they are 96.9% identical (98.9% similar). This very high level of conservation suggests a critical function for hnRNP D. Sequence analysis of the human HNRPD gene shows that the protein is encoded by eight exons and that two additional exons specify sequences in the 3' UTR. Use of two of the coding exons is determined by alternative splicing of the HNRPD mRNA. The human HNRPD gene maps to 4q21. The mouse Hnrpd gene maps to the F region of chromosome 3, which is syntenic with the human 4q21 region.     

Splicing of 5' introns dictates alternative splice selection of acetylcholinesterase pre-mRNA and specific expression during myogenesis

Splicing of alternative exon 6 to invariant exons 2, 3, and 4 in acetylcholinesterase (AChE) pre-mRNA results in expression of the prevailing enzyme species in the nervous system and at the neuromuscular junction of skeletal muscle. The structural determinants controlling splice selection are examined in differentiating C2-C12 muscle cells by selective intron deletion from and site-directed mutagenesis in the Ache gene. Transfection of a plasmid lacking two invariant introns (introns II and III) within the open reading frame of the Ache gene, located 5' of the alternative splice region, resulted in alternatively spliced mRNAs encoding enzyme forms not found endogenously in myotubes. Retention of either intron II or III is sufficient to control the tissue-specific pre-mRNA splicing pattern prevalent in situ. Further deletions and branch point mutations revealed that upstream splicing, but not the secondary structure of AChE pre-mRNA, is the determining factor in the splice selection. In addition, deletion of the alternative intron between the splice donor site and alternative acceptor sites resulted in aberrant upstream splicing. Thus, selective splicing of AChE pre-mRNA during myogenesis occurs in an ordered recognition sequence in which the alternative intron influences the fidelity of correct upstream splicing, which, in turn, determines the downstream splice selection of alternative exons.     

Mouse prolactin receptor gene: genomic organization reveals alternative promoter usage and generation of isoforms via alternative 3'-exon splicing

In rodents, the prolactin receptor is expressed as multiple isoforms with identical extracellular and membrane-proximal region sequences but with different 3' sequences, encoding different cytoplasmic regions, and different 5' untranslated region (UTR) sequences. These divergent sequences could be the result of multiple prolactin receptor genes or of a single gene which displays alternative promoter usage and 3'-exon splicing. To investigate the molecular basis for these observations, we have cloned and determined the organization of the mouse prolactin receptor gene. Genomic DNA cloning allowed the arrangement of promoters 1A, 1B, and 1C to be determined. 5'-RACE-PCR from mouse liver identified two novel 5' prolactin receptor sequences, indicating that the gene has at least five different promoters, four of which are active in liver. The remaining nonvariable 5' UTR is encoded by a separate exon (exon 2), while a further 11 coding exons follow, the last 4 of which are alternatively spliced to produce the four isoforms of the receptor. Functional units were found to be exon specific. Thus, the multiple prolactin receptor isoforms are the product of a single gene of >120 kb which displays multiple promoter usage and 3'-exon splicing.