Gene Architectures That Minimize Cost of Gene Expression

Overview

Journal Mol Cell

Publisher Cell Press

Specialty Cell Biology

Date 2016 Dec 20

PMID 27989436

Citations 40

Authors

Idan Frumkin

Dvir Schirman

Aviv Rotman

Fangfei Li

Liron Zahavi

Ernest Mordret

Omer Asraf

Song Wu

Sasha F Levy

Yitzhak Pilpel

Affiliations

Soon will be listed here.

Abstract

Gene expression burdens cells by consuming resources and energy. While numerous studies have investigated regulation of expression level, little is known about gene design elements that govern expression costs. Here, we ask how cells minimize production costs while maintaining a given protein expression level and whether there are gene architectures that optimize this process. We measured fitness of ∼14,000 E. coli strains, each expressing a reporter gene with a unique 5' architecture. By comparing cost-effective and ineffective architectures, we found that cost per protein molecule could be minimized by lowering transcription levels, regulating translation speeds, and utilizing amino acids that are cheap to synthesize and that are less hydrophobic. We then examined natural E. coli genes and found that highly expressed genes have evolved more forcefully to minimize costs associated with their expression. Our study thus elucidates gene design elements that improve the economy of protein expression in natural and heterologous systems.

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