Inducing a site specific replication blockage in E. coli using a fluorescent repressor operator system

Mettrick, Karla A.; Lawrence, Nikki; Mason, Claire; Weaver, Georgia M.; Corocher, Tayla-Ann; Grainge, Ian

Title: Inducing a site specific replication blockage in E. coli using a fluorescent repressor operator system
Creator: Mettrick, Karla A.; Lawrence, Nikki; Mason, Claire; Weaver, Georgia M.; Corocher, Tayla-Ann; Grainge, Ian
Relation: ARC.DP11010246 http://purl.org/au-research/grants/arc/DP11010246
Relation: Journal of Visualized Experiments Vol. 2016, Issue 114, no. e54434
Publisher Link: http://dx.doi.org/10.3791/54434
Publisher: JoVe
Resource Type: journal article
Date: 2016
Description: Obstacles present on DNA, including tightly-bound proteins and various lesions, can severely inhibit the progression of the cell's replication machinery. The stalling of a replisome can lead to its dissociation from the chromosome, either in part or its entirety, leading to the collapse of the replication fork. The recovery from this collapse is a necessity for the cell to accurately complete chromosomal duplication and subsequently divide. Therefore, when the collapse occurs, the cell has evolved diverse mechanisms that take place to restore the DNA fork and allow replication to be completed with high fidelity. Previously, these replication repair pathways in bacteria have been studied using UV damage, which has the disadvantage of not being localized to a known site. This manuscript describes a system utilizing a Fluorescence Repressor Operator System (FROS) to create a site-specific protein block that can induce the stalling and collapse of replication forks in Escherichia coli. Protocols detail how the status of replication can be visualized in single living cells using fluorescence microscopy and DNA replication intermediates can be analyzed by 2-dimensional agarose gel electrophoresis. Temperature sensitive mutants of replisome components (e.g. DnaBts) can be incorporated into the system to induce a synchronous collapse of the replication forks. Furthermore, the roles of the recombination proteins and helicases that are involved in these processes can be studied using genetic knockouts within this system.
Subject: cellular biology; DNA replication; DNA repair; FROS; 2-Dimensional agarose gel; replication intermediates; nucleoprotein block; replication fork reversal
Identifier: http://hdl.handle.net/1959.13/1348127
Identifier: uon:30154
Identifier: ISSN:1940-087X
Language: eng
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