Geobacter bacteria produce multiheme c-type cytochrome nanowires that are involved in long-range extracellular electron transfer. The ability of these protein nanowires to conduct electrical current makes them promising candidates for electronic devices, offering several functional and sustainable advantages over traditional materials. Therefore, this study focused on synthesizing hybrid protein fibers that mimic the natural Geobacter extracellular nanowires. To achieve this, a mutated PpcA triheme protein variant was used as the building block, with thiol-ene coupling employed to bind the protein molecules. This engineered PpcA variant (PpcAK9CK22C) maintained a structure similar to that of the native protein. Thermal denaturation studies revealed a two-state process, with a melting temperature of 62 ± 1 °C and an enthalpy change of 61 ± 2 kcal/mol. The new protein nanowires showed a lower heme group content than the precursor protein and displayed distinct secondary structure features, with a slight reduction in helical content and an increase in β-sheet and unordered structures. Their thermal stability also differed, as it could not be described by the same model applied to the PpcA variant. Despite these differences, the nanowires retained their ability to undergo redox cycling. Morphologically, they consisted of linear single-protein filaments extending over 300 nm in length.

Previous studies with Geobacter sulfurreducens have demonstrated that OmcS, an abundant c-type cytochrome that is only loosely bound to the outer surface, plays an important role in electron transfer to Fe(III) oxides as well as other extracellular electron acceptors. In order to further investigate the function of OmcS, it was purified from a strain that overproduces the protein. Purified OmcS had a molecular mass of 47 015 Da, and six low-spin bis-histidinyl hexacoordinated heme groups. Its midpoint redox potential was −212 mV. A thermal stability analysis showed that the cooperative melting of purified OmcS occurs in the range of 65–82 °C. Far UV circular dichroism spectroscopy indicated that the secondary structure of purified OmcS consists of about 10% α-helix and abundant disordered structures. Dithionite-reduced OmcS was able to transfer electrons to a variety of substrates of environmental importance including insoluble Fe(III) oxide, Mn(IV) oxide and humic substances. Stopped flow analysis revealed that the reaction rate of OmcS oxidation has a hyperbolic dependence on the concentration of the studied substrates. A ten-fold faster reaction rate with anthraquinone-2,6-disulfonate (AQDS) (25.2 s− 1) was observed as compared to that with Fe(III) citrate (2.9 s− 1). The results, coupled with previous localization and gene deletion studies, suggest that OmcS is well-suited to play an important role in extracellular electron transfer.