Abstract
Photochemical reaction centers are the engines that drive photosynthesis. The reaction center from heliobacteria (HbRC) has been proposed to most closely resemble the common ancestor of photosynthetic reaction centers, motivating a detailed understanding of its structure-function relationship. The recent elucidation of the HbRC crystal structure motivates advanced spectroscopic studies of its excitonic structure and charge separation mechanism. We perform multispectral two-dimensional electronic spectroscopy of the HbRC and corresponding numerical simulations, resolving the electronic structure and testing and refining recent excitonic models. Through extensive examination of the kinetic data by lifetime density analysis and global target analysis, we reveal that charge separation proceeds via a single pathway in which the distinct A0 chlorophyll a pigment is the primary electron acceptor. In addition, we find strong delocalization of the charge separation intermediate. Our findings have general implications for the understanding of photosynthetic charge separation mechanisms, and how they might be tuned to achieve different functional goals.
Highlights
Photochemical reaction centers are the engines that drive photosynthesis
We find that charge separation (CS) in the heliobacterial RC (HbRC) proceeds via a two-step process in which A0 acts as the primary electron acceptor
The energy transfer and CS processes of the HbRC have been studied since the 1980s9–16,18,19,41,42
Summary
The reaction center from heliobacteria (HbRC) has been proposed to most closely resemble the common ancestor of photosynthetic reaction centers, motivating a detailed understanding of its structure-function relationship. The recent elucidation of the HbRC crystal structure motivates advanced spectroscopic studies of its excitonic structure and charge separation mechanism. The primary energy conversion step, charge separation (CS), takes place in the RC2, driving the subsequent chemical reactions for synthesizing high-energy chemical compounds. The. HbRC has been proposed to be the RC most similar to the common ancestor of all photosynthetic RCs4,5. HbRC has been proposed to be the RC most similar to the common ancestor of all photosynthetic RCs4,5 It is the simplest known RC and structural analog to the photosystem I RC7 (PSI RC), and possesses three chemically distinct pigments
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