Efficient Design Strategy for Whole-Cell and Cell-Free Biosensors based on Engineered Riboswitches

Abstract We have applied dual genetic selection to design a bacterial riboswitch with improved sensitivity by employing a high-affinity heterologous thiamine pyrophosphate (TPP) aptamer and modified selection conditions in Escherichia coli. The cells transformed with the engineered TPP riboswitches were characterized as whole-cell biosensors. The riboswitches were further studied in cell-free translation systems where they exhibited characteristics similar to those in vivo and a shorter response time for analysis. The flexibility of the riboswitch-based biosensors to accommodate different reporter genes was also demonstrated. Tuning of biosensor characteristics in vivo enables efficient development of aptamer-based whole-cell and cell-free biosensors.

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