Mathematical Modeling of RNA-Based Architectures for Closed Loop Control of Gene Expression

Overview

Journal ACS Synth Biol

Publisher American Chemical Society

Specialties Biotechnology
Molecular Biology

Date 2018 May 1

PMID 29709170

Citations 15

Authors

Deepak K Agrawal

Xun Tang

Alexandra Westbrook

Ryan Marshall

Colin S Maxwell

Julius Lucks

Vincent Noireaux

Chase L Beisel

Mary J Dunlop

Elisa Franco

Affiliations

Soon will be listed here.

Abstract

Feedback allows biological systems to control gene expression precisely and reliably, even in the presence of uncertainty, by sensing and processing environmental changes. Taking inspiration from natural architectures, synthetic biologists have engineered feedback loops to tune the dynamics and improve the robustness and predictability of gene expression. However, experimental implementations of biomolecular control systems are still far from satisfying performance specifications typically achieved by electrical or mechanical control systems. To address this gap, we present mathematical models of biomolecular controllers that enable reference tracking, disturbance rejection, and tuning of the temporal response of gene expression. These controllers employ RNA transcriptional regulators to achieve closed loop control where feedback is introduced via molecular sequestration. Sensitivity analysis of the models allows us to identify which parameters influence the transient and steady state response of a target gene expression process, as well as which biologically plausible parameter values enable perfect reference tracking. We quantify performance using typical control theory metrics to characterize response properties and provide clear selection guidelines for practical applications. Our results indicate that RNA regulators are well-suited for building robust and precise feedback controllers for gene expression. Additionally, our approach illustrates several quantitative methods useful for assessing the performance of biomolecular feedback control systems.

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