Heme Hopping Falls Short: What Explains Anti-Arrhenius Conductivity in a Multi-heme Cytochrome Nanowire?

Abstract: A helical homopolymer of the outer-membrane cytochrome type S (OmcS) was proposed to electrically connect a common soil bacterium, Geobacter sulfurreducens, with minerals and other microbes for biogeochemically important processes. OmcS exhibits a surprising rise in conductivity upon cooling from 300 to 270 K that has recently been attributed to a restructuring of H-bonds, which in turn modulates heme redox potentials. This proposal is more thoroughly examine herein by (1) analyzing H-bonding at 13 temperature… Show more

“…However, statistical convergence, not reachable for a large protein complex, is attained on the simulation time of 200–300 ns for small globular proteins, such as azurin considered here. Despite this convergence, the protein component of the thermal bath shows a strong separation between λ St and λ according to eq , suggesting that the jammed and frustrated protein interior promotes glassy dynamics with strong features of nonergodic sampling. − It is currently not clear if this is just the size of the protein complex or the membrane that acts to dehydrate a part of the protein to allow eq for large membrane-bound protein complexes. However, dehydration provides a natural control mechanism of protein’s activity: a small globular protein becomes redox-active when binding to a large protein complex partially eliminates its hydration shell.…”

Theory of Protein Charge Transfer: Electron Transfer between Tryptophan Residue and Active Site of Azurin

“…However, statistical convergence, not reachable for a large protein complex, is attained on the simulation time of 200–300 ns for small globular proteins, such as azurin considered here. Despite this convergence, the protein component of the thermal bath shows a strong separation between λ St and λ according to eq , suggesting that the jammed and frustrated protein interior promotes glassy dynamics with strong features of nonergodic sampling. − It is currently not clear if this is just the size of the protein complex or the membrane that acts to dehydrate a part of the protein to allow eq for large membrane-bound protein complexes. However, dehydration provides a natural control mechanism of protein’s activity: a small globular protein becomes redox-active when binding to a large protein complex partially eliminates its hydration shell.…”

Theory of Protein Charge Transfer: Electron Transfer between Tryptophan Residue and Active Site of Azurin