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Colloidal Physics Modeling Reveals How Per-Ribosome Productivity Increases with Growth Rate in Escherichia coli

Akshay J. Maheshwari, Alp M. Sunol, Emma González, Drew Endy, Roseanna N. Zia

2022mBio18 citationsDOIOpen Access PDF

Abstract

Ribosomes are the factories in cells that synthesize proteins. When cells grow faster, there are not enough ribosomes to keep up with the demand for faster protein synthesis without individual ribosomes becoming more productive. Yet, faster-growing cells are more crowded, seemingly making it harder for each ribosome to do its work. Our computational model of the physics of translation elongation reveals the underlying mechanism for how individual ribosomes become more productive: proximity and stoichiometry of translation molecules overcome crowding. Our model also suggests a universal physical limitation of cell growth rates.

Topics & Concepts

RibosomeBiophysicsDiffusionProtein biosynthesisMacromolecular crowdingBiologyCytoplasmCrowdingPhysicsNanotechnologyChemistryChemical physicsCell biologyBiochemistryRNAMaterials scienceThermodynamicsGeneNeuroscienceMacromoleculeBacterial Genetics and BiotechnologyRNA and protein synthesis mechanismsBacteriophages and microbial interactions
Colloidal Physics Modeling Reveals How Per-Ribosome Productivity Increases with Growth Rate in Escherichia coli | Litcius