Control of mitochondrial superoxide production by reverse electron transport at complex I

Ellen L Robb,Andrew R Hall,Tracy A Prime,Simon Eaton,Marten Szibor,Carlo Viscomi,Andrew M James,Michael P Murphy

doi:10.1074/jbc.ra118.003647

Abstract

The generation of mitochondrial superoxide (O2˙̄) by reverse electron transport (RET) at complex I causes oxidative damage in pathologies such as ischemia reperfusion injury, but also provides the precursor to H2O2 production in physiological mitochondrial redox signaling. Here, we quantified the factors that determine mitochondrial O2˙̄ production by RET in isolated heart mitochondria. Measuring mitochondrial H2O2 production at a range of proton-motive force (Δp) values and for several coenzyme Q (CoQ) and NADH pool redox states obtained with the uncoupler p-trifluoromethoxyphenylhydrazone, we show that O2˙̄ production by RET responds to changes in O2 concentration, the magnitude of Δp, and the redox states of the CoQ and NADH pools. Moreover, we determined how expressing the alternative oxidase from the tunicate Ciona intestinalis to oxidize the CoQ pool affected RET-mediated O2˙̄ production at complex I, underscoring the importance of the CoQ pool for mitochondrial O2˙̄ production by RET. An analysis of O2˙̄ production at complex I as a function of the thermodynamic forces driving RET at complex I revealed that many molecules that affect mitochondrial reactive oxygen species production do so by altering the overall thermodynamic driving forces of RET, rather than by directly acting on complex I. These findings clarify the factors controlling RET-mediated mitochondrial O2˙̄ production in both pathological and physiological conditions. We conclude that O2˙̄ production by RET is highly responsive to small changes in Δp and the CoQ redox state, indicating that complex I RET represents a major mode of mitochondrial redox signaling.

Highlights

The generation of mitochondrial superoxide (O2.) by reverse electron transport (RET) at complex I causes oxidative damage in pathologies such as ischemia reperfusion injury, and provides the precursor to H2O2 production in physiological mitochondrial redox signaling
Measuring mitochondrial H2O2 production at a range of proton-motive force (⌬p) values and for several coenzyme Q (CoQ) and NADH pool redox states obtained with the uncoupler p-trifluoromethoxyphenylhydrazone, we show that O2. production by RET responds to changes in O2 concentration, the magnitude of ⌬p, and the redox states of the CoQ and NADH pools
We conclude that O2. production by RET is highly responsive to small changes in ⌬p and the CoQ redox state, indicating that complex I RET represents a major mode of mitochondrial redox signaling

Summary

The abbreviations used are

O2. , superoxide; ROS, reactive oxygen species; SOD, superoxide dismutase; RET, reverse electron transport; CoQ, coenzyme Q; ⌬p, proton-motive force; ⌬␺, membrane potential; FCCP, carbonyl rapidly converted to H2O2 by manganese superoxide dismutase (MnSOD) within the matrix [1, 2]. There is considerable evidence that RET at complex I is a physiological process that underlies mitochondrial redox signaling in a range of situations [11, 13] while leading to pathological oxidative damage during ischemia–reperfusion injury [1, 14, 15]. We measured H2O2 generation as a function of the membrane potential (⌬␺) and of the reduction state of the CoQ and NADH pools This was done by altering ⌬␺ with the uncoupler carbonyl cyanide p-trifluoromethoxyphenylhydrazone (FCCP) and oxidizing the CoQ pool by ectopic expression within heart mitochondria of the alternative oxidase (AOX) from Ciona intestinalis [16]. Production by RET and indicate how this process contributes to oxidative damage and redox signaling These data provide a complete description of mitochondrial O2. production by RET and indicate how this process contributes to oxidative damage and redox signaling

Results

Discussion

Experimental procedures