Structural Determination of a Filamentous Chaperone to Fabricate Electronically Conductive Metalloprotein Nanowires

Chen, Yun X.; Ing, Nicole L.; Wang, Fengbin; Xu, Dawei; Sloan, Nancy B.; Lam, Nga Tien; Winter, Daniel L.; Hochbaum, Allon I.; Clark, Douglas S.; Glover, Dominic J.

doi:10.1021/acsnano.9b09405

Cited by 24 publications

(32 citation statements)

References 48 publications

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“…The second important challenge to overcome is the material creation protocol, whereas most known conductive protein‐based polymers use genetically expressed proteins. [ 8,9,12,14–16 ] Although much progress has been made in producing mass amount of genetically expressed proteins, [ 17 ] this is still costly and time‐consuming, even upon upscaling, and cannot result in bulk quantities of highly affordable proteins needed for the large‐scale production of materials. Cost effectiveness is a key requisite of any application, and too often, applications validated at the proof‐of‐concept level in the lab do not undergo upscaling to reach the market, as they were not initially designed to meet the requirements of industrial upscaling through sustainable production (e.g., price of the single components and manufacturing costs).…”

Section: Introductionmentioning

confidence: 99%

A Protein‐Based Free‐Standing Proton‐Conducting Transparent Elastomer for Large‐Scale Sensing Applications

2021

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A most important endeavor in modern materials’ research is the current shift toward green environmental and sustainable materials. Natural resources are one of the attractive building blocks for making environmentally friendly materials. In most cases, however, the performance of nature‐derived materials is inferior to the performance of carefully designed synthetic materials. This is especially true for conductive polymers, which is the topic here. Inspired by the natural role of proteins in mediating protons, their utilization in the creation of a free‐standing transparent polymer with a highly elastic nature and proton conductivity comparable to that of synthetic polymers, is demonstrated. Importantly, the polymerization process relies on natural protein crosslinkers and is spontaneous and energy‐efficient. The protein used, bovine serum albumin, is one of the most affordable proteins, resulting in the ability to create large‐scale materials at a low cost. Due to the inherent biodegradability and biocompatibility of the elastomer, it is promising for biomedical applications. Here, its immediate utilization as a solid‐state interface for sensing of electrophysiological signals, is shown.

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Section: Introductionmentioning

confidence: 99%

A Protein‐Based Free‐Standing Proton‐Conducting Transparent Elastomer for Large‐Scale Sensing Applications

2021

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“…The Mavlankar team has recently demonstrated the control of biofilms of G. sulforreducens conductivity through electrode potential bias, this report demonstrates and emphasizes even further both the role of porphyrins in the electrochemical properties of biofilms as well as the ability to manipulate biofilms’ properties and specifically their electrochemical properties using electrodes [37] . Based on these findings in natural pili, artificial pili like structures were designed and have shown conductivity in‐vitro (Figure 1(B)) [38] …”

Section: Introductionmentioning

confidence: 62%

“…[37] Based on these findings in natural pili, artificial pili like structures were designed and have shown conductivity in-vitro ( Figure 1(B)). [38]…”

Section: Enzymes Conducting Proteins and Electrodesmentioning

confidence: 99%

“…Adapted with permission from the American Chemical Society, based on reference. [38] Adapted from, [41] which is licensed under a Creative Commons Attribution 4.0 International License.…”

Section: Wearable Devicesmentioning

confidence: 99%

“… (A) bacterial nanowires made of self‐assembled cytochoromes expressed by the electrochemically active Geobacter sulforeducens adapted from Yale University website based on reference; [36] (B) Self‐assembly of filamentous proteins with metalloproteins that allows long range electron transfer. Adapted with permission from the American Chemical Society, based on reference [38] …”

Section: Introductionmentioning

confidence: 99%

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Bioelectrochemistry and the Singularity Point “I Robot”?**

Alfonta

2021

Israel Journal of Chemistry

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In his book “The Singularity Is Near: When Humans Transcend Biology” Ray Kurtzweil described the concept of artificial intelligence in an unorthodox way. It describes how humans will interface with machines and eventually will become one with machines. Hence, we can define a time point, which is a theoretical point when humans and machines will become one. In order to reach this point, a successful interface between the biological/organic to the inorganic matter is needed. In order for these pieces of “machinery” to communicate between one another, an exchange of matter and energy should be achieved. Electron transfer between the inorganic and organic has been the mission of bioelectrochemical systems in the past few decades. Enzymes, antibodies and nucleic acids attachment to electrodes has been achieved more than three decades ago. In the following assay I am reviewing the different advances that were made towards an integration between biological entities to inorganic ones.

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Fabrication of Electronically Conductive Protein‐Heme Nanowires for Power Harvesting

Travaglini,

Lam,

Sawicki

et al. 2024

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Electronically conductive protein‐based materials can enable the creation of bioelectronic components and devices from sustainable and nontoxic materials, while also being well‐suited to interface with biological systems, such as living cells, for biosensor applications. However, as proteins are generally electrical insulators, the ability to render protein assemblies electroactive in a tailorable manner can usher in a plethora of useful materials. Here, an approach to fabricate electronically conductive protein nanowires is presented by aligning heme molecules in proximity along protein filaments, with these nanowires also possessing charge transfer abilities that enable energy harvesting from ambient humidity. The heme‐incorporated protein nanowires demonstrate electron transfer over micrometer distances, with conductive atomic force microscopy showing individual nanowires having comparable conductance to other previously characterized heme‐based bacterial nanowires. Exposure of multilayer nanowire films to humidity produces an electrical current, presumably through water molecules ionizing carboxyl groups in the filament and creating an unbalanced total charge distribution that is enhanced by the heme. Incorporation of heme and potentially other metal‐center porphyrin molecules into protein nanostructures could pave the way for structurally‐ and electrically‐defined protein‐based bioelectronic devices.

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Structural Determination of a Filamentous Chaperone to Fabricate Electronically Conductive Metalloprotein Nanowires

Cited by 24 publications

References 48 publications

A Protein‐Based Free‐Standing Proton‐Conducting Transparent Elastomer for Large‐Scale Sensing Applications

A Protein‐Based Free‐Standing Proton‐Conducting Transparent Elastomer for Large‐Scale Sensing Applications

Bioelectrochemistry and the Singularity Point “I Robot”?**

Fabrication of Electronically Conductive Protein‐Heme Nanowires for Power Harvesting

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