The transport of electrons along photosynthetic and respiratory chains involves a series of enzymatic reactions that are coupled through redox mediators, including proteins and small molecules. The use of native and synthetic redox probes is key to understanding charge transport mechanisms and to the design of bioelectronic sensors and solar energy conversion devices. However, redox probes have limited tunability to exchange charge at the desired electrochemical potentials (energy levels) and at different protein sites. Herein, we take advantage of electrochemical scanning tunneling microscopy (ECSTM) to control the Fermi level and nanometric position of the ECSTM probe in order to study electron transport in individual photosystem I (PSI) complexes. Current–distance measurements at different potentiostatic conditions indicate that PSI supports long‐distance transport that is electrochemically gated near the redox potential of P700, with current extending farther under hole injection conditions.
Charge separation and transport through the reaction center of photosystem I (PSI) is an essential part of the photosynthetic electron transport chain. A strategy is developed to immobilize and orient PSI complexes on gold electrodes allowing to probe the complex's electron acceptor side, the chlorophyll special pair P700. Electrochemical scanning tunneling microscopy (ECSTM) imaging and current–distance spectroscopy of single protein complex shows lateral size in agreement with its known dimensions, and a PSI apparent height that depends on the probe potential revealing a gating effect in protein conductance. In current–distance spectroscopy, it is observed that the distance‐decay constant of the current between PSI and the ECSTM probe depends on the sample and probe electrode potentials. The longest charge exchange distance (lowest distance‐decay constant β) is observed at sample potential 0 mV/SSC (SSC: reference electrode silver/silver chloride) and probe potential 400 mV/SSC. These potentials correspond to hole injection into an electronic state that is available in the absence of illumination. It is proposed that a pair of tryptophan residues located at the interface between P700 and the solution and known to support the hydrophobic recognition of the PSI redox partner plastocyanin, may have an additional role as hole exchange mediator in charge transport through PSI.
Photosynthesis is a fundamental process that converts
photons into
chemical energy, driven by large protein complexes at the thylakoid
membranes of plants, cyanobacteria, and algae. In plants, water-soluble
plastocyanin (Pc) is responsible for shuttling electrons between cytochrome b6f complex and the photosystem I (PSI) complex in the photosynthetic
electron transport chain (PETC). For an efficient turnover, a transient
complex must form between PSI and Pc in the PETC, which implies a
balance between specificity and binding strength. Here, we studied
the binding frequency and the unbinding force between suitably oriented
plant PSI and Pc under redox control using single molecule force spectroscopy
(SMFS). The binding frequency (observation of binding-unbinding events)
between PSI and Pc depends on their respective redox states. The interaction
between PSI and Pc is independent of the redox state of PSI when Pc
is reduced, and it is disfavored in the dark (reduced P700) when Pc
is oxidized. The frequency of interaction between PSI and Pc is higher
when at least one of the partners is in a redox state ready for electron
transfer (ET), and the post-ET situation (PSIRed-PcOx) leads to lower binding. In addition, we show that the binding
of ET-ready PcRed to PSI can be regulated externally by
Mg2+ ions in solution.
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