Molecular chaperones have evolved diverse tertiary and quaternary structures to stabilize non-native polypeptides and facilitate their transition to the native state. Indeed, different families of chaperones lack sequence similarity, and few are represented ubiquitously in all three domains of life. Despite their discrete evolutionary paths, recent crystal structures reveal that many chaperones use seemingly convergent strategies to bind non-native proteins. This crystallographic evidence shows, or strongly suggests, that chaperones including prefoldin, Skp, trigger factor, Hsp40 and Hsp90 have clamp-like structural features used to grip substrate proteins. We explore the notion that clamp-like structures are evolutionarily favored by both ATP-dependent and ATP-independent molecular chaperones. Presumably, clamps present a multivalent binding surface ideal for protecting unstable protein conformers until they reach the native state or are transferred to another component of the folding machinery.