Direct electrochemical detection of trans-plasma membrane electron transfer: A possible alternative pathway for cell respiration

Abstract

An electrochemical protocol was designed to enable Vero cells to transfer electrons to an electrode without any added redox mediator. The cells were cultured on the surface of electrodes polarized at the optimal potential of 400 mV/silver pseudo-reference. Gold, carbon, and CNT-coated carbon electrodes displayed similar current record patterns. Extracellular electron transfer was sustained for several days. Its intensity, up to 1.5 pA.cell−1, was in the range of the electron flows implemented by cell respiration. A large fraction of the current vanished as soon as anoxic conditions were established, which suggests a mitochondrial origin for a large proportion of the electrons. The current records always showed a two-phase pattern. The occurrence of the two phases was not due to an evolution of the cell mat structure, which was fully established during the first day of polarization and did not change significantly thereafter. Increasing the cell seeding density decreased the maximum current reached during the first phase and the duration of the phase. These observations put together lead us to propose a model, in which only the cells adhered on the electrode surface produced current by metabolizing glutamine during the first phase. The possible role of this extracellular electron transfer as an alternative cell respiration pathway is discussed. The key roles it could play in regulating pH and pO2 gradients are considered, specifically to explain the pH gradient reversal observed in cancer cells. These pioneering results pave the way for electrochemical sensors to directly address cellular metabolic pathways.