Regulation of alternative splicing in the IIICS region of human fibronectin pre-mRNA encoding cell binding sites CS1 and CS5

The cell binding sites CS1 and CS5 in the IIICS region of human fibronectin (FN) mediate the adhesion of specific cell types by interacting with the integrin alpha 4 beta 1. IIICS pre-mRNA is alternatively spliced via the use of three alternative splice acceptor sites and one alternative splice donor site. These alternative splicing pathways can potentially give rise to variant FN molecules which are CS1+,CS5+; CS1+,CS5-; CS1-,CS5+ or CS1-,CS5-. Here we show that selection of the acceptor site which incorporates mRNA encoding CS1 and CS5 is more frequent in foetal tissues compared to adult liver, whereas an alternative acceptor site and the alternative donor site, which exclude CS1 and CS5, are used at a higher level in adult liver compared to foetal tissue. All possible splice junctions were accurately processed, and selected at different levels in mRNA expressed from a IIICS minigene transiently transfected into a HeLa cell line which does not express FN, suggesting that all the cellular factors required for alternative processing of IIICS are present in this system. Furthermore, pre-mRNA expressed from a mutant construct lacking IIICS-1 intron sequence, was correctly processed in HeLa cells via selection of all possible splice sites. On the basis of our results we propose that regulation of splice site selection in IIICS and thus expression of CS1 and CS5 is achieved by subtle tuning of splicing systems involving the interaction of local cis elements and cellular factors which are not necessarily restricted developmentally or tissue-specifically, and that expression of CS1 and CS5 is independently regulated.

Specific binding of the human monocytic cell line U937 to the alternatively spliced connecting segment (IIICS) of fibronectin.

U937 cells attach to the RGDS-containing 80-kD fragment of fibronectin (Fn). The present report examined whether these cells recognize other domains of Fn. U937 cells attach to a 38-kD fragment derived from the A chain of Fn, which includes the Hep II domain and most of the alternatively spliced IIICS region. U937 did not bind to a 58-kD fragment derived from the B chain (which lacks IIICS) and has the Hep II site. They also did not bind to a 31-kD COOH-terminal fibrin-binding fragment or to a 29-kD fragment containing the Hep I domain. Cell adhesion to the 38-kD fragment was not inhibited by the 80-kD fragment, by GRGDSPC synthetic peptides, or by a mAb directed to the RGDS-containing domain of Fn. Attachment was completely inhibited by the 38-kD fragment and by the synthetic peptide CS-1, comprising the first 25 amino acid residues of IIICS. These results indicate that U937 cells interact with two sites of Fn, the RGDS-containing region, and the IIICS region.

Neurite extension of chicken peripheral nervous system neurons on fibronectin: relative importance of specific adhesion sites in the central cell-binding domain and the alternatively spliced type III connecting segment.

Fibronectin contains at least two domains that support cell adhesion. One is the central cell-binding domain that is recognized by a variety of cell types, including fibroblasts. The second, originally identified by its ability to support melanoma cell adhesion, is located in the alternatively spliced type III connecting segment (IIICS). Using specific adhesive ligands and inhibitory probes, we have examined the role of each of these domains in fibronectin-mediated neurite extension of neurons from chick embryo dorsal root and sympathetic ganglia. In studies using explanted ganglia, both fl3, a 75-kD tryptic fragment of human plasma fibronectin containing the central cell-binding domain, and CS1-IgG, a synthetic peptide-IgG conjugate containing the principal cell adhesion site from the IIICS, supported neurite outgrowth after adsorption onto the substrate. The maximal activities of fl3 and CSl-IgG were 45-55% and 25-30% that of intact fibronectin, respectively. Co-coating of the substrate with f13 and CS1-IgG produced an additive stimulation of neurite outgrowth, the extent of which approached that obtained with fibronectin. Similar results were obtained with purified neuronal cell preparations isolated by tryptic dissociation of dorsal root ganglia. In complementary studies, blockage of the adhesive function of either the central cell-binding domain (with mAb 333, an antiadhesive monoclonal antibody) or the IIICS (with CS1 peptide), resulted in approximately 60 or 30% reduction in fibronectin-mediated neurite outgrowth, respectively. When tested in combination, the inhibitory activities of mAb 333 and CSl were additive. From these results, we conclude that neurons from the peripheral nervous system can extend neurites on both the central cell-binding domain and the IIICS region of fibronectin, and that these cells are therefore the first normal, embryonic cell type shown to adhere to the IIICS. These results suggest that spatiotemporal fluctuations in the alternative mRNA splicing of the IIICS region of fibronectin may be important in regulation of cell adhesive events during development of the peripheral nervous system.