Litcius/Paper detail

Replication fork binding triggers structural changes in the PriA helicase that govern DNA replication restart in E. coli

Alexander T. Duckworth, Peter Ducos, Sarah D. McMillan, Kenneth A. Satyshur, Katelien H Blumenthal, Haley R. Deorio, Joseph A. Larson, Steven J. Sandler, Timothy Grant, James L. Keck

2023Nature Communications18 citationsDOIOpen Access PDF

Abstract

Bacterial replisomes often dissociate from replication forks before chromosomal replication is complete. To avoid the lethal consequences of such situations, bacteria have evolved replication restart pathways that reload replisomes onto prematurely terminated replication forks. To understand how the primary replication restart pathway in E. coli (PriA-PriB) selectively acts on replication forks, we determined the cryogenic-electron microscopy structure of a PriA/PriB/replication fork complex. Replication fork specificity arises from extensive PriA interactions with each arm of the branched DNA. These interactions reshape the PriA protein to create a pore encircling single-stranded lagging-strand DNA while also exposing a surface of PriA onto which PriB docks. Together with supporting biochemical and genetic studies, the structure reveals a switch-like mechanism for replication restart initiation in which restructuring of PriA directly couples replication fork recognition to PriA/PriB complex formation to ensure robust and high-fidelity replication re-initiation.

Topics & Concepts

ReplisomeReplication (statistics)DNA replicationTer proteinControl of chromosome duplicationdnaB helicasePre-replication complexSemiconservative replicationBiologyFork (system call)Origin recognition complexMinichromosome maintenanceCell biologyReplication factor CDNAEukaryotic DNA replicationHelicaseGeneticsComputer scienceGeneVirologyOperating systemRNADNA Repair MechanismsBacterial Genetics and BiotechnologyEnzyme Structure and Function