Faculty Bibliography

Fibronectin isolated from human plasma functions in vitro as a mediator of adhesion and spreading of trypsinized fibroblasts on native or denatured collagen. As a means of elucidating structural characteristics which might contribute to fibronectin's biological activity, we have modified and digested the protein with several chemicals. Following various treatments, the protein was utilized to mediate cell adhesion and spreading on collagen to determine which alteration disrupted its activity. Fibronectin remained functionally intact after partial or complete reduction and alkylation, oxidation of 59% of the carbohydrates with sodium periodate, citraconylation, carbodiimide-catalyzed amide formation, and oxidation of 35.2 residues of tryptophan/molecule with N-bromosuccinimide. Dinitrofluorobenzene treatment, which phenylated ten residues/molecule of fibronectin, successfully inactivated fibronectin's in vitro biological function. Effective modification of the protein was determined by appropriate analytical procedures. Since fibronectin retained its biological function after several treatments that presumably affected its molecular conformation, we concluded that its secondary or tertiary structure appears not to be essential for its in vitro activity, or alternatively that the protein possesses a biologically active domain relatively resistant to chemical modification

The gelatin-binding region of fibronectin has been obtained by subtilisin digestion and cyanogen bromide cleavage of the molecule. Enzymatic digestion yielded two fragments of molecular weights 50,000 (S50K) and 30,000 (S30K) which were isolated by elution from gelatin-Sepharose affinity columns. Because the S50K fragment also mediated the adhesion of fibroblasts to collagen, it contains both the collagen and cell binding sites on the fibronectin molecule. Both fragments had valine as the NH2-terminal residue, were enriched in half-cystine and methionine residues compared to the whole molecule, and were identical by immunodiffusion. The S50K fragment begins with the sequence Val-Tyr-Gln-Pro-Gln-Pro-His-Pro-Gln-Pro-(Pro)-(Gly)-Tyr-Gly-His-( )-Val, a region with an extended conformation which is susceptible to proteolysis and connects this domain to the remainder of the fibronectin molecule. The S50K fragment appears to be located in the COOH-terminal one-third of the fibronectin molecule but does not contain the interchain disulfide bridge(s); the S30K fragment is probably derived from the NH2-terminal region of S50K.