A classical dogma of molecular biology dictates that the 3D structure of a protein is necessary for its function. However, a considerable fraction of the human proteome, although functional, does not adopt a defined folded state under physiological conditions. These intrinsically disordered proteins tend to fold upon binding to their partners with a molecular mechanism that is elusive to experimental characterization. Indeed, although many hypotheses have been put forward, the functional role (if any) of disorder in these intrinsically denatured systems is still shrouded in mystery. Here, we characterize the structure of the transition state of the binding-induced folding in the reaction between the KIX domain of the CREB-binding protein and the transactivation domain of c-Myb. The analysis, based on the characterization of a series of conservative site-directed mutants, reveals a very high content of native-like structure in the transition state and indicates that the recognition between KIX and c-Myb is geometrically precise. The implications of our results in the light of previous work on intrinsically unstructured systems are discussed.kinetics | mutagenesis | protein folding
In the past decade, a wealth of experimental data has demonstrated that a large fraction of proteins, while functional, are intrinsically disordered at physiological conditions. Many intrinsically disordered proteins (IDPs) undergo a disorder-to-order transition upon binding to their biological targets, a phenomenon known as induced folding. Induced folding may occur through two extreme mechanisms, namely conformational selection and folding after binding. Although the pre-existence of ordered structures in IDPs is a prerequisite for conformational selection, it does not necessarily commit to this latter mechanism, and kinetic studies are needed to discriminate between the two possible scenarios. So far, relatively few studies have addressed this issue from an experimental perspective. Here, we analyze the interaction kinetics between the intrinsically disordered C-terminal domain of the measles virus nucleoprotein (NTAIL) and the X domain (XD) of the viral phosphoprotein. Data reveal that NTAIL recognizes XD by first forming a weak encounter complex in a disordered conformation, which is subsequently locked-in by a folding step; i.e., binding precedes folding. The implications of our kinetic results, in the context of previously reported equilibrium data, are discussed. These results contribute to enhancing our understanding of the molecular mechanisms by which IDPs recognize their partners and represent a paradigmatic example of the need of kinetic methods to discriminate between reaction mechanisms.
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