An intron element modulating 5' splice site selection in the hnRNP A1 pre-mRNA interacts with hnRNP A1.

The hnRNP A1 pre-mRNA is alternatively spliced to yield the A1 and A1b mRNAs, which encode proteins differing in their ability to modulate 5' splice site selection. Sequencing a genomic portion of the murine A1 gene revealed that the intron separating exon 7 and the alternative exon 7B is highly conserved between mouse and human. In vitro splicing assays indicate that a conserved element (CE1) from the central portion of the intron shifts selection toward the distal donor site when positioned in between the 5' splice sites of exon 7 and 7B. In vivo, the CE1 element promotes exon 7B skipping. A 17-nucleotide sequence within CE1 (CE1a) is sufficient to activate the distal 5' splice site. RNase T1 protection/immunoprecipitation assays indicate that hnRNP A1 binds to CE1a, which contains the sequence UAGAGU, a close match to the reported optimal A1 binding site, UAGGGU. Replacing CE1a by different oligonucleotides carrying the sequence UAGAGU or UAGGGU maintains the preference for the distal 5' splice site. In contrast, mutations in the AUGAGU sequence activate the proximal 5' splice site. In support of a direct role of the A1-CE1 interaction in 5'-splice-site selection, we observed that the amplitude of the shift correlates with the efficiency of A1 binding. Whereas addition of SR proteins abrogates the effect of CE1, the presence of CE1 does not modify U1 snRNP binding to competing 5' splice sites, as judged by oligonucleotide-targeted RNase H protection assays. Our results suggest that hnRNP A1 modulates splice site selection on its own pre-mRNA without changing the binding of U1 snRNP to competing 5' splice sites.

A splicing enhancer in the human fibronectin alternate ED1 exon interacts with SR proteins and stimulates U2 snRNP binding.

The inclusion of the 270-nucleotide human fibronectin ED1 exon in HeLa cells requires the presence of a centrally located 81-nucleotide exon sequence. We have conducted a series of in vitro experiments aimed at understanding the structural and functional features associated with this splicing enhancer (SE). Using hybrid model pre-mRNA substrates, we show that the SE element markedly stimulates the use of the 3' splice site of ED1. Deletion and replacement analysis identifies the stimulating sequences as a purine-rich stretch of 9 nucleotides (GAAGAAGAC). The SE element stimulates splicing to the ED1 3' splice site from various positions within the exon except when placed beyond 293 nucleotides downstream from that 3' splice site. The action of the enhancer is not limited to the ED1 acceptor site because the SE element stimulates human beta-globin splicing and also induces the use of a 3' splice site in a prokaryotic sequence in vitro. We have explored the mechanism of action of the fibronectin splicing enhancer and found that the SE element is required for efficient assembly of early splicing complexes, allowing a more efficient interaction of the U2 snRNP with branch site sequences. In competition experiments, an RNA containing mainly SE sequences specifically abolished the action of the SE element, suggesting that factors bind the enhancer element to mediate stimulation of splicing. Using RNA mobility shift assays we show that SR proteins interact specifically with the SE element. Our results demonstrate that exon sequences lying in the SE element play a crucial role in specifying splice site recognition through interactions with factors binding to the 3' splice site.

Differential ASF/SF2 activity in extracts from normal WI38 and transformed WI38VA13 cells.

The normal human fibroblast cell line WI38 and a transformed derivative, WI38VA13, differentially splice fibronectin pre-mRNA in vivo. As a first step to understand the molecular basis for this regulation of splicing, we examined the ability of WI38 and WI38VA13 nuclear extracts to splice model adenovirus and globin pre-mRNAs. Adenovirus RNA splicing was detected in WI38VA13 but not in WI38 extracts. Likewise, when supplemented with a HeLa post-nuclear supernatant (S100), human beta-globin RNA splicing was detected in WI38VA13 but not in WI38 extracts. The splicing defect in WI38 extracts was associated with a reduced ability to form splicing complexes and with a corresponding decrease in the interaction of U2 small nuclear ribonucleoprotein (snRNP) with the branchsite. These defects did not correlate with a decrease in 65 kD U2AF binding since equivalent U2AF level and activity were detected in WI38 and WI38VA13 extracts. Rather, WI38 extracts displayed reduced ASF/SF2 activity and contained a low level of 30 and 40 kD SR phosphoproteins. Moreover, addition of purified ASF/SF2 dramatically increased splicing complex formation in WI38 extracts. These results raise the possibility that variations in the level and activity of ASF/SF2 and other SR proteins play a role in the regulation of fibronectin splicing.

Proteolysis of splicing factors during rat and monkey cell fractionation.

We have investigated the ability of various rat and monkey cell lines to yield nuclear extracts that would allow splicing of a model adenovirus pre-mRNA substrate. Extracts from normal FR3T3, rat-1 and CV-1 fibroblasts were unable to assemble splicing complexes and displayed a dramatic reduction in the binding activity of the splicing factor 65 kD U2AF. These results correlated with reduced levels of 65 kD U2AF and the snRNP-associated B protein. When a battery of protease inhibitors was used during cell fractionation, increased levels of 65 kD U2AF and B proteins were detected. Most importantly, U2AF binding and complex formation were dramatically improved in FR3T3, rat-1 and CV-1 extracts. Interestingly, transformation of rat and monkey cells with the SV40 large T antigen yielded extracts active in complex formation. Similar extracts were generated following transformation of rat-1 cells with the Py middle T antigen but not with the v-fos oncogene. Only SV40-transformed FR3T3 extracts displayed splicing activity. Our results indicate that proteolysis is a major obstacle encountered during the preparation of active extracts from normal rat and monkey cells and suggest that cells transformed with T antigens manifest reduced proteolysis during fractionation.