Abstract
The electrochemical potentials of redox-active proteins need to be tuned accurately to the correct values for proper biological function. Here, we describe a diheme cytochrome c with high heme redox potentials of about +350 mV, despite having a large overall negative charge, which typically reduces redox potentials. High-resolution crystal structures, spectroelectrochemical measurements, and high-end computational methods show how this is achieved: each heme iron has a calcium cation positioned next to it at a distance of only 6.9 Å, raising their redox potentials by several hundred millivolts through electrostatic interaction. We suggest that this has evolved to provide the protein with a high redox potential despite its large negative surface charge, which it likely requires for interactions with redox partners.