Mechanism of Proton Transfer Inhibition by Cd2+Binding to Bacterial Reaction Centers: Determination of the pKAof Functionally Important Histidine Residues
Citations Over TimeTop 19% of 2003 papers
Abstract
The bacterial photosynthetic reaction center (RC) uses light energy to catalyze the reduction of a bound quinone molecule Q(B) to quinol Q(B)H(2). In RCs from Rhodobacter sphaeroides the protons involved in this process come from the cytoplasm and travel through pathways that involve His-H126 and His-H128 located near the proton entry point. In this study, we measured the pH dependence from 4.5 to 8.5 of the binding of the proton transfer inhibitor Cd(2+), which ligates to these surface His in the RC and inhibits proton-coupled electron transfer. At pH 7, K(D) becomes essentially independent of pH. A theoretical fit to the data over the entire pH range required two protons with pK(A) values of 6.8 and 6.3 (+/-0.5). To assess the contribution of His-H126 and His-H128 to the observed pH dependence, K(D) was measured in mutant RCs that lack the imidazole group of His-H126 or His-H128 (His --> Ala). In both mutant RCs, K(D) was approximately pH independent, showing that Cd(2+) does not displace protons upon binding in the mutant RCs, in contrast to the native RC in which His-H126 and His-H128 are the predominant contributors to the observed pH dependence of K(D). Thus, Cd(2+) inhibits RC function by binding to functionally important histidines.
Related Papers
- → Ubiquinone reduction in the photosynthetic reaction centre of Rhodobacter sphaeroides: interplay between electron transfer, proton binding and flips of the quinone ring(2005)22 cited
- → Quinone (QB) Reduction by B-Branch Electron Transfer in Mutant Bacterial Reaction Centers fromRhodobacter sphaeroides: Quantum Efficiency and X-ray Structure,(2005)32 cited
- → Effects of Oxygen, Heavy Water, and Glycerol on Electron Transfer in the Acceptor Part of Rhodobacter sphaeroides Reaction Centers(2005)3 cited
- → Implications of spin dynamics for the charge recombination in iron-depleted and quinone-substituted reaction centers from Rhodobacter sphaeroides R-26(1987)5 cited
- → Effect of replacing the primary quinone by different species on the ultrafast photosynthetic electron transfer in bacterial reaction centres(1990)4 cited