Search for: All records

Abstract Microbial respiration via extracellular electron transfer (EET) drives several globally-important environmental processes and has applications in bioenergy, bioremediation, and bioelectronics.Geobacter sulfurreducensproduce micrometer-long cytochrome nanowires for long-range (>10 µm) EET, but also require transmembrane porin-cytochrome complexes (PCCs), which can only perform EET on the cell surface. It was unknown why cells performing long-range EET need both PCCs and nanowires. Using Om(abc)B and OmcS as a model PCC and nanowire, respectively, for EET to Fe(III), we show that PCCs and nanowires form sequential, independent EET pathways where PCCs first kickstart EET and provide energy crucial for nanowire synthesis, and then nanowires perform long-range EET. Our model explains why both PCCs and nanowires are necessary. To understand the underlying EET mechanism, we purified native Om(ab)B and OmcB and found high excitonic coupling among hemes. Their midpoint reduction potentials (-182, -167 mV, respectively) are tuned for efficient electron transport. Additionally, OmcB transfers electrons to Fe(III) ~5 times more efficiently than OmcS. Our work suggests that the metabolic trade-off between PCCs and nanowires results from efficient proteome allocation. Notably, PCCs are widespread in environmentally-important bacteria and co-evolved with OmcS nanowires. This previously-undescribed nanowire synthesis strategy could accelerate EET in diverse microbes and environments. 

Abstract Mixed electronic-ionic conductors are crucial for various technologies, including harvesting power from humidity in a durable, self-sustainable, manner unrestricted by location or environment^1,2. Biological proteins have been proposed as mixed conductors for 50 years^3,4. Recently,Geobacter sulfurreducenspili filaments have been claimed to act as nanowires to generate power^5,6. Here, we show that the power is generated byG. sulfurreducens-produced cytochrome OmcZ nanowires that show 20,000-fold higher electron conductivity than pili⁷. Remarkably, nanowires show ultrahigh electron and proton mobility (>0.25 cm2/Vs), owing to directional charge migration through seamlessly-stacked hemes and a charged, hydrogen-bonding surface, respectively. AC impedance spectroscopy and DC conductivity measurements using four-probe van der Pauw and back-gated field-effect-transistor devices reveal that humidity increases carrier mobility by 30,000-fold. Cooling halves the activation energy, thereby accelerating charge transport. Electrochemical measurements identify the voltage and mobilities required to switch pure electronic conduction to mixed conduction for power generation. The high aspect ratio (1:1000) and hydrophilic nanowire surface captures moisture efficiently to reduce oxygen reversibly, generating large potentials (>0.5 V) necessary to sustain high power. Our studies establish a new class of biologically-synthesized, low-cost and high-performance mixed-conductors and identify key design principles for improving power output using highly-tunable electronic and protein structures. 

Protein around hemes acts as a temperature sensor for environmental changes to control conductivity of cytochrome OmcS nanowires. 

Abstract Advances in synthetic biology permit the genetic encoding of synthetic chemistries at monomeric precision, enabling the synthesis of programmable proteins with tunable properties. Bacterial pili serve as an attractive biomaterial for the development of engineered protein materials due to their ability to self-assemble into mechanically robust filaments. However, most biomaterials lack electronic functionality and atomic structures of putative conductive proteins are not known. Here, we engineer high electronic conductivity in pili produced by a genomically-recodedE. colistrain. Incorporation of tryptophan into pili increased conductivity of individual filaments >80-fold. Computationally-guided ordering of the pili into nanostructures increased conductivity 5-fold compared to unordered pili networks. Site-specific conjugation of pili with gold nanoparticles, facilitated by incorporating the nonstandard amino acid propargyloxy-phenylalanine, increased filament conductivity ~170-fold. This work demonstrates the sequence-defined production of highly-conductive protein nanowires and hybrid organic-inorganic biomaterials with genetically-programmable electronic functionalities not accessible in nature or through chemical-based synthesis. 

Proteins are commonly known to transfer electrons over distances limited to a few nanometers. However, many biological processes require electron transport over far longer distances. For example, soil and sediment bacteria transport electrons, over hundreds of micrometers to even centimeters, via putative filamentous proteins rich in aromatic residues. However, measurements of true protein conductivity have been hampered by artifacts due to large contact resistances between proteins and electrodes. Using individual amyloid protein crystals with atomic-resolution structures as a model system, we perform contact-free measurements of intrinsic electronic conductivity using a four-electrode approach. We find hole transport through micrometer-long stacked tyrosines at physiologically relevant potentials. Notably, the transport rate through tyrosines (10⁵s⁻¹) is comparable to cytochromes. Our studies therefore show that amyloid proteins can efficiently transport charges, under ordinary thermal conditions, without any need for redox-active metal cofactors, large driving force, or photosensitizers to generate a high oxidation state for charge injection. By measuring conductivity as a function of molecular length, voltage, and temperature, while eliminating the dominant contribution of contact resistances, we show that a multistep hopping mechanism (composed of multiple tunneling steps), not single-step tunneling, explains the measured conductivity. Combined experimental and computational studies reveal that proton-coupled electron transfer confers conductivity; both the energetics of the proton acceptor, a neighboring glutamine, and its proximity to tyrosine influence the hole transport rate through a proton rocking mechanism. Surprisingly, conductivity increases 200-fold upon cooling due to higher availability of the proton acceptor by increased hydrogen bonding.