Kai Stieger

Advanced unidirectional photocurrent generation via cytochrome c as reaction partner for directed assembly of photosystem I

Conversion of light into an electrical current based on biohybrid systems mimicking natural photosynthesis is becoming increasingly popular. Photosystem I (PSI) is particularly useful in such photo-bioelectrochemical devices. Herein, we report on a novel biomimetic approach for an effective assembly of photosystem I with the electron transfer carrier cytochrome c (cyt c), deposited on a thiol-modified gold-surface. Atomic force microscopy and surface plasmon resonance measurements have been used for characterization of the assembly process. Photoelectrochemical experiments demonstrate a cyt c mediated generation of an enhanced unidirectional cathodic photocurrent. Here, cyt c can act as a template for the assembly of an oriented and dense layer of PSI and as wiring agent to direct the electrons from the electrode towards the photosynthetic reaction center of PSI. Furthermore, three-dimensional protein architectures have been formed via the layer-by-layer deposition technique resulting in a successive increase in photocurrent densities. An intermittent cyt c layer is essential for an efficient connection of PSI layers with the electrode and for an improvement of photocurrent densities.

High photocurrent generation by photosystem I on artificial interfaces composed of π-system-modified graphene

Photosystem I (PSI) is a key component of the oxygenic photosynthetic electron transport chain because of its light-induced charge separation and electron transfer (ET) capabilities. We report the fabrication of an efficient graphene-biohybrid light-harvesting electrode consisting of cyanobacterial trimeric PSI complexes immobilized onto π-system-modified graphene electrodes. Based on the strong interaction between conjugated aromatic compounds and the graphene material via π–π-stacking, we have designed a simple but smart platform to fabricate light-driven photoelectrochemical devices. Due to the possibility of surface property adaptation and the excellent conductivity of graphene, the modified biohybrid electrodes exhibit a well-defined photoelectrochemical response. In particular, the PSI–graphene electrode applying pyrene butyric acid NHS ester displays a very high photocurrent output of 23 μA cm−2 already at the open circuit potential which can be further increased by an overpotential and the use of an electron acceptor (methyl viologen) under air saturation up to 135 μA cm−2. Comparing the graphene–PSI biohybrid systems based on different π-system-modifiers reveals that the pyrene derivatives result in higher current outputs compared to the anthracene derivatives and that the covalent fixation during immobilization appears more efficient compared to simple adsorption. Interestingly, the pyrene-based PSI electrodes also display a nearly unidirectional photocurrent generation, establishing the feasibility of conjoining these nanomaterials as potential constructs in next-generation photovoltaic devices.

Biohybrid architectures for efficient light-to-current conversion based on photosystem I within scalable 3D mesoporous electrodes

The combination of advanced materials and defined surface design with complex proteins from natural photosynthesis is currently one of the major topics in the development of biohybrid systems and biophotovoltaic devices. In this study transparent mesoporous indium tin oxide (μITO) electrodes have been used in combination with the trimeric supercomplex photosystem I (PSI) from Thermosynechococcus elongatus and the small redox protein cytochrome c (cyt c) from horse heart to fabricate advanced and efficient photobiocathodes. The preparation of the μITO via spin coating allows easy scalability and ensures a defined increase in the electrochemically active surface area with accessibility for both proteins. Using these 3D electrodes up to 40 μm thickness, the immobilization of cyt c and PSI with full monolayer coverage and their electrical communication to the electrode can be achieved. Significant improvement can be made when the heterogenous electron transfer rate constant of cyt c with the electrode is increased by an appropriate surface treatment. The photocurrent follows linearly the thickness of the μITO and current densities of up to 150 μA cm−2 can be obtained without indications of a limitation. The internal quantum efficiency is determined to be 39% which demonstrates that the wiring of PSI via cyt c can be advantageously used in a system with high protein loading and efficient electron pathways inside 3D transparent conducting oxides.

Insights into Interprotein Electron Transfer of Human Cytochrome c Variants Arranged in Multilayer Architectures by Means of an Artificial Silica Nanoparticle Matrix

The redox behavior of proteins plays a crucial part in the design of bioelectronic systems. We have demonstrated several functional systems exploiting the electron exchange properties of the redox protein cytochrome c (cyt c) in combination with enzymes and photoactive proteins. The operation is based on an effective reaction at modified electrodes but also to a large extent on the capability of self-exchange between cyt c molecules in a surface-fixed state. In this context, different variants of human cyt c have been examined here with respect to an altered heterogeneous electron transfer (ET) rate in a monolayer on electrodes as well as an enhanced self-exchange rate while being incorporated in multilayer architectures. For this purpose, mutants of the wild-type (WT) protein have been prepared to change the chemical nature of the surface contact area near the heme edge. The structural integrity of the variants has been verified by NMR and UV–vis measurements. It is shown that the single-point mutations can significantly influence the heterogeneous ET rate at thiol-modified gold electrodes and that electroactive protein/silica nanoparticle multilayers can be constructed with all forms of human cyt c prepared. The kinetic behavior of electron exchange for the mutant proteins in comparison with that of the WT has been found altered in some multilayer arrangements. Higher self-exchange rates have been found for K79A. The results demonstrate that the position of the introduced change in the charge situation of cyt c has a profound influence on the exchange behavior. In addition, the behavior of the cyt c variants in assembled multilayers is found to be rather similar to the situation of cyt c self-exchange in solution verified by NMR.

Bioelectronic Circuit on a 3D Electrode Architecture: Enzymatic Catalysis Interconnected with Photosystem I

Artificial light-driven signal chains are particularly important for the development of systems converting light into a current, into chemicals or for light-induced sensing. Here, we report on the construction of an all-protein, light-triggered, catalytic circuit based on photosystem I, cytochrome c (cyt c) and human sulfite oxidase (hSOX). The defined assembly of all components using a modular design results in an artificial biohybrid electrode architecture, combining the photophysical features of PSI with the biocatalytic properties of hSOX for advanced light-controlled bioelectronics. The working principle is based on a competitive switch between electron supply from the electrode or by enzymatic substrate conversion.