The high spatial resolution and the force sensitivity of the Atomic Force Microscope have made it possible to perform mechanical experiments with single molecules. These experiments give direct access to the forces that stabilize biomolecule structure. In a variety of examples we show how different molecular interactions determine the mechanical stability of polysaccharides, proteins, DNA and other biomolecules.
Under the influence of a stretching force of around 750 pN the polysaccharide dextran undergoes a transition into a stretched conformation during which bond angles flip into a new conformation. Molecular dynamics simulations corroborated this conformational change.
Proteins fold into compact domains. Especially for structural proteins the mechanical stability of these domains is of importance. We show that the immunoglobulin and fibronectin III domains of the muscle protein titin exhibit exceptionally high unfolding forces (150-250 pN) when stretched at speeds of normal muscle operation (Fig. 1).