Abstract

The mitochondrial citrate transport protein (CTP) is critical to energy metabolism in eukaryotic cells. We demonstrate that 1,2,3-benzenetricarboxylate (BTC), the classic and defining inhibitor of the mitochondrial CTP, is a mixed inhibitor of the reconstituted Cys-less CTP, with a strong competitive component [i.e., a competitive inhibition constant (K_ic) of 0.12 ± 0.02 mM and an uncompetitive inhibition constant (K_iu) of 3.04 ± 0.74 mM]. Based on docking calculations, a model for BTC binding has been developed. We then determined the K_ic values for each of the eight substrate binding site cysteine substitution mutants and observed increases of 62- to 261-fold relative to the Cys-less control, thereby substantiating the importance of each of these residues in BTC binding. It is noteworthy that we observed parallel increases in the K_m for citrate transport with each of these binding site mutants, thereby confirming that with these CTP variants, K_m approximates the K_d (for citrate) and is therefore a measure of substrate affinity. To further substantiate the importance of these binding site residues, in silico screening of a database of commercially available compounds has led to discovery of the first purely competitive inhibitor of the CTP. Docking calculations indicate that this inhibitor spans and binds to both substrate sites simultaneously. Finally, we propose a kinetic model for citrate transport in which the citrate molecule sequentially binds to the external and internal binding sites (per CTP monomer) before transport.