Fibronectins are adhesive glycoproteins thought to mediate the attachment of cells to various substrates. Plasma fibronectin (PFN) is a dimer comprising subunits of molecular weight 220,000, connected by one or two disulphide bonds. Electron microscopy shows that PFN is a long, flexible strand, 2-3 nm in diameter and 140 nm long. Many cells in tissue culture elaborate an extracellular matrix of insoluble (highly cross-linked by disulphide bonds) fibronectin, and a variable amount of 'cell surface fibronectin' (CSFN) that can be extracted by mild urea treatment. This CSFN, soluble in 1 M urea and at high pH, is a mixture of dimers and disulphide-bonded oligomers. In the present study we have examined the structure of these molecules by electron microscopy. Oligomers were separated from dimers and contaminating proteins by zone sedimentation through glycerol gradients. We report that the CSFN dimers are identical in structure to PFN. In contrast, the oligomers have an elaborate and well defined structure that we call a 'hexabrachion': six arms emanating from a central globular particle. The arms are similar to PFN in being long, thin and flexible, but have several distinctly different features.