Transforming de novo protein α3D into a mechanically stable protein by zinc binding

Abstract

α₃D is a de novo designed three-helix bundle protein. Like most naturally occurring helical proteins, it is mechanically labile with an unfolding force of <15 pN, revealed by atomic force microscopy-based single-molecule force spectroscopy (AFM-SMFS). This protein has been further designed with a tri-cysteine metal-binding site, named α₃DIV, which can bind heavy transition metals. Here, we demonstrate that incorporating such a metal-binding site can transform this mechanically labile protein into a stable one. We show that zinc binds to the tri-cysteine site and increases the unfolding force to ∼160 pN. This force is one order of magnitude higher than that of the apo-protein (<15 pN). Moreover, the unfolding mechanism of Zn-α₃DIV indicates the correct zinc binding with the tri-cysteine site, forming three mechanostable Zn–thiolate bonds. Thus, α₃DIV could be a potential α-helical structure-based building block for synthesizing biomaterials with tunable mechanical properties.