On the electronic structure of the primary electron donor in bacterial photosynthesis – the bacteriochlorophyll dimer as viewed by EPR/ENDOR methods

Abstract

The primary electron donor (D) plays a prominent role in electron transfer reactions in the primary processes of photosynthesis. In purple photosynthetic bacteria D is a dimer of bacteriochlorophyll molecules. Investigations on its electronic structure using EPR and ENDOR (electron nuclear double resonance) methods are summarized, focussing on results obtained in the last six years. These encompass studies on the cation radical (D+·) of mutants in which the immediate environment of D is modified through mutagenesis, particularly hydrogen bond and heterodimer mutants. Models using these results to describe the electronic interaction of the dimer halves are discussed. Also, High-Field (95 GHz) EPR to obtain the G-tensor of D+· is addressed. Furthermore, ENDOR on the photoexcited triplet state of D (DT), which in some aspects could serve as a model for the excited singlet state, are discussed. Different approaches towards correlating the electronic structure with function, in particular with the rates of electron transfer reactions, are described.