Inhibition of cytochrome b563-oxidation by triorganotins in spinach chloroplasts

Abstract

The triorganotin compounds triphenyltin chloride and tributyltin chloride have been known as inhibitors of the transmembrane proton channel forming F0-domain of ATPases at micromolar concentrations. We show that these compounds at higher concentrations (10–100 µM) also inhibit uncoupled electron transport in chloroplasts within the low potential chain of the cytochrome bf complex. They cause high levels of transiently reduced cytochrome b563 as they decelerate the reoxidation process in flash illuminated chloroplasts. At the same time they slow down the flash induced slow electrogenic step generated at the cytochrome bf complex. The inhibitory effect of triphenyltin chloride on cytochrome b563 turnover in chloroplasts is comparable to that of the Qn-inhibitor MOA-stilbene, with even less side effects on the high potential chain. Studies on the isolated bf complex suggest different binding sites for triorganotins and the quinone analogue type Qn-inhibitors. The results are interpreted within the framework of the modified Q-cycle model by a putative organotin sensitive proton translocating site which enables proton transfer from the outer aqueous face of the membrane to the hydrophobic quinone reduction site within the complex. Hence, cytochrome b563 oxidation and plastoquinone reduction may be inhibited as a consequence of proton transfer being suppressed by triorganotins. In analogy, the previously described inhibitory effect of Val/K+ at the n-side of the cytochrome bf complex [Klughammer and Schreiber (1993) FEBS 336: 491–495] may be rationalised by binding of the cyclic depsipeptide at the entrance of the proton path to the Qn-site.