Histidine Reactive Chemicals Modify the Thermus thermophilus CuA Redox Center

Abstract

The electron transport chain is a series of redox protein complexes that couple the shuttling of electrons with the pumping of protons, in order to create the electrochemical gradient that drives ATP synthesis. The first redox center of the terminal complex from the Thermus thermophilus bacteria has been isolated as TtCuA and has a binuclear copper center bridged by two cysteines and ligated by two histidines and two weak axial ligands. H157 of TtCuA, a solvent exposed ligating histidine, has demonstrated modification by diethyl pyrocarbonate (DEPC), an exogenous chemical modifier, that is facilitated by the residue’s fast proton exchange with the solvent. The H157‐DEPC adduct is reversible over 48 hours at room temperature, as supported by mass spectrometry, electrochemistry, and visible CD spectroscopy. This is one of two modifications, out of 12, that becomes removed. Due to the lability of the H157‐DEPC bond, it is possible that the H157 Nɛ is primed for proton pumping in the electron transport chain.In order to model a possible in vivo modification, TtCuA was exposed to 4‐hydroxynonenal (HNE), an endogenous lipid peroxidation product associated with multiple metabolic and neurodegenerative diseases. Exposure of TtCuA to 20 equivalents of HNE appears to reduce the protein over 48 hours and four modifications are observed via mass spectrometry. Exposure of the Pseudomonas aeruginosa azurin protein, a mononuclear blue‐copper denitrification protein with similar ligand groups to TtCuA, is not reduced by HNE, despite modification. Azurin also lacks a ligating histidine that can be modified by DEPC. In conclusion, the binuclear copper center of TtCuA has hyperreactivity in comparison to a similarly ligated mononuclear copper center.Support or Funding InformationMurchison Undergraduate Research Fellowship, Trinity University Chemistry Department, Mach Research Fellowship, Welch Foundation