Cotranslational Pulling Forces Alter Outcomes of Protein Synthesis

Author: Zimmer, Matthew Holden

Year: 2022

Degree: Dissertation (Ph.D.)

Advisor: Miller, Thomas F.

Committee Members: Clemons, William M.; Voorhees, Rebecca M.; Wang, Zhen-Gang; Miller, Thomas F.

Option: Biochemistry and Molecular Biophysics

DOI: 10.7907/p7vk-cf03

Abstract

As nascent proteins are synthesized by the ribosome, interactions between the nascent protein and its environment can create pulling forces that are transmitted to the ribosome's catalytic center. These forces can affect the rate and outcomes of translation. We use atomistic and coarse-grained simulation to characterize the origins of pulling forces, the propagation of force to catalytic center of the ribosome, and the effects of force on synthetic outcomes. We uncover a novel form of pulling force-mediated regulation in which the forces generated by the integration of a transmembrane helix induce frameshifting in a viral polyprotein. Computational force measurements of hundreds of mutant viral sequences in combination with deep mutational scanning experiments reveal the structural and sequence-level features that enable this powerful regulatory mechanism. Force measurements are also used to provide a molecular picture for complex pulling force experiments on multispanning membrane proteins. In particular, we identify signatures of cotranslational helix packing interactions and the translocation of surface helices. To understand how forces are propagated through the nascent protein in the ribosomal exit tunnel, we ran and analyzed hundreds of microseconds of atomistic molecular dynamics with an applied pulling force on the nascent protein. The simulations reveal how the secondary structure of nascent proteins and their interactions with the ribosome control force propagation. The inhibition of force transduction by nascent protein-ribosome interactions explains how amino acids tens of angstroms away from the catalytic center of the ribosome can still influence the force-induced restart of stalled ribosomes.

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