Human plasma fibronectin was denatured with 8 M urea and reduced with dithiothreitol. Dialysis or dilution of the solution led to formation of fibronectin dimers which migrated in non-reducing SDS/PAGE similarly to untreated control protein. When the redimerized fibronectin was reduced and re-electrophoresed it formed a doublet of alpha and beta chains of equal intensity indicating that it was a heterodimer. Low concentrations (less than 1 mM) of Fe3+ enhanced the redimerization of fibronectin, suggesting that metal ions may mediate oxidative reactions in the formation of the disulfides. Consequently, redimerization of fibronectin was completely prevented by deferoxamine, an iron chelator. Dimerization of fibronectin took place most effectively at pH greater than or equal to 8.8 but decreased strongly at lower pH, representing more unfavourable conditions for the action of the thiolate anion in the thiol/disulfide exchange reaction. Redimerized fibronectin, however, lost many of its binding properties to macromolecular ligands, suggesting that the disulfide bonding did not entirely regenerate the proper conformation of the protein. Pulse/chase experiments of fibroblast cultures showed that the initially monomeric fibronectin was rapidly and quantitatively dimerized under conditions representing natural pH and environment. SDS/PAGE analysis of the dialyzed urea-denatured/reduced thrombin and plasmin digests of fibronectin revealed that the NH2-terminal 30-kDa fragment and other fragments that contained intrachain disulfides quantitatively regained their non-reduced electrophoretic mobility. The results show that the dimerization and formation of intrachain disulfides of fibronectin may occur, in part, spontaneously, based on the amino acid sequence information of the protein. However, complete disulfide formation may also need other factors, present only in living cells, as suggested by pulse/chase experiments in fibroblasts.