When studying the effect of ions on the stability of proteins, simple inorganic cations follow an important rule of thumb: the higher the surface charge density of the cation the stronger the ion destabilizes proteins in solution. However, the rather bulky, organic guanidinium cation (Gdm+), having a low surface charge density, is amongst the most effective protein denaturants. Thus, Gdm+ is a prominent exception in the Hofmeister series. In recent years it became apparent that this exceptional effect of Gdm+ on proteins cannot be explained from bulk properties of aqueous guanidinium electrolytes, but must be related to the specific interaction of Gdm+ with proteins.Indeed, computer simulations suggest specific interaction of Gdm+ with model proteins. However, to date the exact mechanism how Gdm+ interacts with proteins is controversially discussed. It has been suggested that Gdm+ ions bind to the peptide backbone, interact with the positively or negatively charged protein side-chains, or cover hydrophobic fragments of the proteins. Each of these interaction mechanisms is claimed to lead to the unfolding of the protein.We will study the interaction of Gdm+ with small model proteins experimentally and test the different scenarios mentioned above. We will determine the binding strength of Gdm+ to hydrophobic moieties, charged side chains, and to the amide backbone. This will reveal the predominant unfolding mechanism and what makes the guanidinium cation such an efficient protein denaturant.

DFG Programme Research Grants