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The Role of the MCM2-7 Complex in the Replication Fork Processivity

$249,927R01FY2013GMNIH

University Of Pittsburgh At Pittsburgh, Pittsburgh PA

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Abstract

The long-term goal of our research is to elucidate the regulation and mechanism of eukaryotic DNA replication. This essential process requires complex coordination to produce an exact copy of the genome every cell cycle. Central to the regulation and mechanism of essentially all aspects of DNA replication is the MCM2-7 complex, a hexameric ATPase believed to be the replicative helicase - the molecular motor that unwinds duplex DNA at the replication fork. As one of the few factors essential in both the initiation and elongation phases of DNA replication, defects in MCM activity can compromise the precision of DNA replication in multiple ways. In particular, displacement of the MCM2-7 complex from replication forks can potentially occur as it encounters various obstacles. Such displacement will lead to collapse of the replication fork, a defect that creates the types of genomic instability characteristic of cancer and birth defects. The following Aims build upon our previous work with the MCM2-7 complex: 1) Does defective DNA unwinding lead to replication fork collapse? Evidence suggests that MCM2-7 is essential for replication fork progression. However, our in vitro analysis indicates that MCM2-7 may be intrinsically inefficient at unwinding DNA, suggesting the need for additional factors in vivo. We will quantify the in vitro and in vivo ability of both wild type and mutant MCM2-7 complexes to unwind a variety of DNA substrates, assess the role that additional replication factors have on this activity, and use a genetic screen to identify novel factors that assist MCM2-7 fork progression. 2) Is a newly discovered discontinuity in the MCM2-7 complex required for initiation and helicase activation? Our in vitro analysis indicates that two MCM subunits form a reversible ATP-regulated gate in the toroidal structure. Using our MCM mutants defective for this activity in vitro, we propose to test the utility of this gate in vivo on the assembly of MCM2-7 onto DNA using chromatin immunoprecipitation, and activation of the MCM2-7 helicase by the replication specific kinase CDC7/DBF4. (3) What is the relationship between ATP binding, hydrolysis and DNA unwinding within the MCM2-7 complex? ATPases are abundant and perform diverse cellular functions, but considerable controversy exists as to how they couple ATP binding and hydrolysis to mechanical work. Unlike most ATPases, MCM2-7 has six distinct subunits that can be individually modified, making it ideal for studying the function these machines. We propose to mutate two specific structural motifs with predicted involvement in DNA binding and active site coordination - the pre- Sensor I insert and the Sensor II motif - then test the consequences on MCM2-7 activity using our established in vivo and in vitro functional assays.

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