Protonophoric Activity of Fatty Acid Analogs and Derivatives in the Inner Mitochondrial Membrane: A Further Argument for the Fatty Acid Cycling Model

The protonophoric (uncoupling) action of various long-chain fatty acids and their derivatives in mitochondria was investigated as related to their ability for rapid transbilayer movement in the inner mitochondrial membrane (flip-flop) and interaction with the ADP/ATP carrier (AAC). Flip-flop was assessed from a rapid decrease of internal mitochondrial pH. It was found that long-chain unsubstituted fatty acids (with the exception of very-long-chain unbranched homologs) and their thia and oxa analogs performed a rapid flip-flop, inhibited AAC activity and increased proton permeability of the inner mitochondrial membrane, resulting in dissipation of mitochondrial membrane potential and increased resting state respiration. Bipolar fatty acid analogs, i.e., those containing a second carboxylic group or OH group(s) at the hydrocarbon tail, phenyl-substituted fatty acid derivatives, and fatty acid analogs containing strongly ionized sulfonyl or sulfate groups instead of the carboxylic group, did not flip-flop and were not uncoupling, although some of them were weak inhibitors of AAC. These results provide further confirmation of the fatty acid cycling model (V. P. Skulachev,FEBS Lett. 294,158–162, 1991) in which the protonophoric function of fatty acids is a result of the spontaneous transbilayer passage of undissociated (protonated) molecules of the fatty acid from the external side of the inner mitochondrial membrane to the matrix side and the AAC-mediated transport of the fatty acid anion in the opposite direction.