Electric field dependence of recombination kinetics in reaction centers of photosynthetic bacteria

Time-resolved charge recombination has been measured by reflectance/absorption spectroscopic analysis of Langmuir-Blodgett films of reaction centers of the photosynthetic bacterium, Rhodopseudomonas sphaeroides over a wide range of applied electric field strengths. The field dependence of the recombination kinetics has been deduced from the time-course of the reduction of the flash-oxidized bacteriochlorophyll dimer [(BChl)+2] recorded at different applied field strengths. Measurements were performed under two different electric field biasing conditions: a constant bias and a high-frequency bipolar square-wave bias. The additional data obtained from bipolar biasing enabled the use of a new deconvolution method to obtain the field dependence of the rate constants from the experimental curves. The deconvolution shows that the rates for charge recombination from the flash-generated state back to the ground state (BChl)2QA approximate exponential functions of the applied electric field. Correlation of the recombination kinetics data with photoinduced electrical response measurements on films with asymmetric up and down populations of reaction centers reveals that fields opposing charge separation result in faster rates of recombination. Although other possibilities are considered, the main source of the effect is believed to be a result of field-induced changes in the free energy gap between and (BChl)2QA. The results presented here are compared to those obtained in experiments with solubilized reaction centers in which the free energy gap between and (BChl)2QA has been changed by quinone replacement.