Predicting Composition of Genetic Circuits with Resource Competition: Demand and Sensitivity

Author(s)

McBride, Cameron D; Del Vecchio, Domitilla

Abstract

The design of genetic circuits typically relies on characterization of constituent modules in isolation to predict the behavior of modules' composition. However, it has been shown that the behavior of a genetic module changes when other modules are in the cell due to competition for shared resources. In order to engineer multimodule circuits that behave as intended, it is thus necessary to predict changes in the behavior of a genetic module when other modules load cellular resources. Here, we introduce two characteristics of circuit modules: the demand for cellular resources and the sensitivity to resource loading. When both are known for every genetic module in a circuit library, they can be used to predict any module's behavior upon addition of any other module to the cell. We develop an experimental approach to measure both characteristics for any circuit module using a resource sensor module. Using the measured resource demand and sensitivity for each module in a library, the outputs of the modules can be accurately predicted when they are inserted in the cell in arbitrary combinations. These resource competition characteristics may be used to inform the design of genetic circuits that perform as predicted despite resource competition.

Date issued

2021-11-15

URI

https://hdl.handle.net/1721.1/138591

Department

Massachusetts Institute of Technology. Department of Mechanical Engineering

Journal

ACS Synthetic Biology

Publisher

American Chemical Society (ACS)

Citation

McBride, Cameron D and Del Vecchio, Domitilla. 2021. "Predicting Composition of Genetic Circuits with Resource Competition: Demand and Sensitivity." ACS Synthetic Biology.

Version: Author's final manuscript