Quantitative Characterization of Recombinase-based Digitizer Circuits Enables Predictable Amplification of Biological Signals

Overview

Journal Commun Biol

Specialty Biology

Date 2021 Jul 16

PMID 34267310

Citations 6

Authors

Katherine A Kiwimagi

Justin H Letendre

Benjamin H Weinberg

Junmin Wang

Mingzhe Chen

Leandro Watanabe

Chris J Myers

Jacob Beal

Wilson W Wong

Ron Weiss

Affiliations

Soon will be listed here.

Abstract

Many synthetic gene circuits are restricted to single-use applications or require iterative refinement for incorporation into complex systems. One example is the recombinase-based digitizer circuit, which has been used to improve weak or leaky biological signals. Here we present a workflow to quantitatively define digitizer performance and predict responses to different input signals. Using a combination of signal-to-noise ratio (SNR), area under a receiver operating characteristic curve (AUC), and fold change (FC), we evaluate three small-molecule inducible digitizer designs demonstrating FC up to 508x and SNR up to 3.77 dB. To study their behavior further and improve modularity, we develop a mixed phenotypic/mechanistic model capable of predicting digitizer configurations that amplify a synNotch cell-to-cell communication signal (Δ SNR up to 2.8 dB). We hope the metrics and modeling approaches here will facilitate incorporation of these digitizers into other systems while providing an improved workflow for gene circuit characterization.

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