Litcius/Paper detail

Electron Tunneling in Biology: When Does it Matter?

Setare Mostajabi Sarhangi, Dmitry V. Matyushov

2023ACS Omega27 citationsDOIOpen Access PDF

Abstract

High Resolution Image Download MS PowerPoint Slide Electrons can tunnel between cofactor molecules positioned along biological electron transport chains up to a distance of ≃ 20 Å on the millisecond time scale of enzymatic turnover. This tunneling range determines the design of biological energy chains facilitating the cross-membrane transport of electrons. Tunneling distance and cofactors’ redox potentials become the main physical parameters affecting the rate of electron transport. In addition, universal charge-transport properties are assigned to all proteins, making protein identity, flexibility, and dynamics insignificant. This paradigm is challenged by dynamical models of electron transfer, showing that the electron hopping rate is constant within the crossover distance R * ≃ 12 Å, followed with an exponential falloff at longer distances. If this hypothesis is fully confirmed, natural and man-made energy chains for electron transport should be best designed by placing redox cofactors near the crossover distance R *. Protein flexibility and dynamics affect the magnitude of the maximum hopping rate within the crossover distance. Changes in protein flexibility between forward and backward transitions contribute to vectorial charge transport. For biological energy chains, charge transport through proteins is not defined by universal parameters, and protein identity matters.

Topics & Concepts

Electron transport chainElectronQuantum tunnellingElectron transferChemical physicsPhysicsMillisecondAtomic physicsChemistryCondensed matter physicsQuantum mechanicsPhysical chemistryBiochemistryPhotosynthetic Processes and MechanismsMolecular Junctions and NanostructuresPhotoreceptor and optogenetics research