Module-module interactions in the cell binding region of fibronectin: stability, flexibility and specificity.

The structure of mosaic proteins depends on the nature and strength of interactions between individual modules. Here we investigated the structural significance of module-module interactions in the RGD-dependent cell binding region of human fibronectin, comprising the ninth and tenth fibronectin type III. A combination of protein engineering, thermodynamics and nuclear magnetic resonance methods was employed to establish a relationship between intermodular protein-protein interactions and the structural properties of the module pair. A poly(glycine) peptide link connecting the C terminus of the ninth and the N terminus of the tenth module was introduced to probe the range of the interaction. NMR studies (Chemical shifts and 15N relaxation) together with equilibrium and kinetic unfolding experiments were carried out on five different single and double module constructs. The results show that non-specific protein-protein interactions provide the bulk of the thermodynamic stabilization and the motional constraint of the two modules. Specific interactions between the two modules are restricted to the wild-type module pair and decline very rapidly with the insertion of additional linker residues. This low level of specificity is nonetheless sufficient to fine-tune the precise module-module orientation and to provide the full biological activity of the wild-type pair. This suggests that individual modules in mosaic proteins can achieve a high degree of motional constraint and mutual stabilization without the requirement for intricate and specific interactions in the module-module interfaces.