A nicotine biosensor derived from microbial screening
Kuzmanovic, U.; Chen, M.; Charles, R.; Addokhi, A.; Tararina, M. A.; Hughes, K. A.; DeMaria, A. M.; Sensharma, P.; Gupta, A.; Dasari, S.; Dantas, N. L. G.; Sankar, K.; Zhang, Z.; Zang, H.; Allen, K. N.; Klapperich, C. M.; Grinstaff, M. W.; Galagan, J. E.
Show abstract
Physiologically relevant biosensors are in increasingly high demand, yet existing ones are severely limited in the number and type of biomarkers that are detected. The lack of biorecognition elements for most medically relevant biomarkers restricts the development of next generation single and continuous use monitors. Over billions of years, microbes have evolved a vast array of proteins to sense and metabolize small molecules, including those pertinent to human health. Of particular interest to us is the identification and subsequent integration of new microbial redox enzymes into electronic biosensors building off the established electrochemical technology of the continuous glucose monitor. Here we deploy genomic screening to identify analyte specific redox enzymes for biosensor development. As a proof of concept, we report the first electrochemical enzyme-based nicotine biosensor from a novel microbial enzyme, and use a variant with improved catalytic performance to enhance sensor performance. The biosensor detects nicotine over 0.4-100 M, a range relevant to nicotine concentrations present in active smoker sweat, saliva, gastric juice, and urine. This microbial mining approach for discovering redox enzymes expands the sensing parts toolbox available over conventional antibodies and aptamers.
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