Abstract
AbstractElectrically conductive protein nanowires (e-PNs), microbially produced from a pilin monomer, are a novel, sustainable electronic material that can be genetically tailored for specific functions. e-PNs, expressed withEscherichia coligrown on the biodiesel byproduct glycerol, and mixed with polyvinyl butyral yielded a transparent, electrically conductive water-stable composite.Composite conductivity was adjusted by modifying the e-PN concentration or incorporating e-PNs genetically tuned for different conductivities. Electronic devices in which composites were the sensor component differentially responded to dissolved ammonia over a wide concentration range (1µM-1M). Genetically modifying e-PNs to display an ammonia-binding peptide on their outer surface increased the sensor response to ammonia 10-fold. These results, coupled with the flexibility to design peptides for specific binding of diverse analytes, demonstrate that sustainably produced e-PNs offer the possibility of incorporating multiple sensor components, each specifically designed to detect different analytes with high sensitivity and selectivity, within one small sensor device.
Publisher
Cold Spring Harbor Laboratory
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