DNA replication must occur with extraordinary accuracy to permit proper organismal development and to maintain cellular homeostasis. Inevitably, DNA damage occurs due to intrinsic and exogenous factors such as irradiation and chemical exposure. DNA damage is particularly dangerous during the DNA replication process because it can cause DNA replication forks to """"""""stall"""""""", leading to even more severe DNA damage or chromosomal instabilities. Cells have evolved complex mechanisms to repair DNA damage, as well as cell cycle checkpoints to inhibit DNA replication and mitosis while providing an opportunity for DNA repair. We have recently found that the intra-S checkpoint regulates DNA synthesis at replication forks, inhibiting replication upon checkpoint activation and permitting replication fork restart upon deactivation of the checkpoint. This direct connection between DNA synthesis at the fork and checkpoint regulation strongly suggests that the intra-S checkpoint coordinates replication fork restart and DNA repair mechanisms, collectively referred to as """"""""DNA-Damage Tolerance"""""""" (DDT) pathways, with DNA replication. We propose to study the involvement of DDT in the restart of replication forks that have stalled in response DNA damage, as well as the regulation of DDT by the intra-S checkpoint.
The Specific Aims of this proposal are to: 1) Characterize replication fork dynamics in response to DNA damage, 2) Investigate the role of the intra-S checkpoint pathway in replication fork restart, 3) Perform molecular and genetic analysis of DDT mechanisms in replication fork restart. Lay Abstract: Cancers, developmental defects, and other genetic disorders are frequently caused by mutation of DNA. Mutations, though rare, sometimes occur during DNA replication, the process that produces an exact copy of an organism's copies entire DNA sequence to produce new cells. Because the uncontrolled growth of cancer cells depends on DNA replication, many chemotherapies act by disrupting DNA replication, which unfortunately have side-effects for normal cell growth. We have developed new technologies to study DNA replication at replication forks where the DNA is actually copied. This study will investigate the cellular processes that regulate replication forks to prevent mutations or minimize their potential damage. These studies have the potential of providing improved methods for the detection and treatment of cancer.

Public Health Relevance

Project Narrative This proposal will investigate the regulation and molecular mechanisms of replication fork restart after DNA damage in S. cerevisiae. Our studies will focus on the role of intra-S checkpoint factor Rad53 in controlling the activity of replication forks encountering DNA damage and coordination of DNA-damage tolerance mechanisms that function in replication restart and DNA repair. These checkpoint and DNA repair mechanisms are critical to the prevention of genome instabilities that can lead to the development of cancers and other genetic disorders.

Agency
National Institute of Health (NIH)
Institute
National Institute of General Medical Sciences (NIGMS)
Type
Research Project (R01)
Project #
5R01GM065494-09
Application #
8111989
Study Section
Molecular Genetics B Study Section (MGB)
Program Officer
Janes, Daniel E
Project Start
2003-02-01
Project End
2013-07-31
Budget Start
2011-08-01
Budget End
2013-07-31
Support Year
9
Fiscal Year
2011
Total Cost
$317,552
Indirect Cost
Name
University of Southern California
Department
Biology
Type
Schools of Arts and Sciences
DUNS #
072933393
City
Los Angeles
State
CA
Country
United States
Zip Code
90089
Ostrow, A Zachary; Kalhor, Reza; Gan, Yan et al. (2017) Conserved forkhead dimerization motif controls DNA replication timing and spatial organization of chromosomes in S. cerevisiae. Proc Natl Acad Sci U S A 114:E2411-E2419
Ostrow, A Zachary; Aparicio, Oscar M (2017) Identification of Fkh1 and Fkh2 binding site variants associated with dynamically bound DNA elements including replication origins. Nucleus 8:600-604
Peace, Jared M; Villwock, Sandra K; Zeytounian, John L et al. (2016) Quantitative BrdU immunoprecipitation method demonstrates that Fkh1 and Fkh2 are rate-limiting activators of replication origins that reprogram replication timing in G1 phase. Genome Res 26:365-75
Ostrow, A Zachary; Viggiani, Christopher J; Aparicio, Jennifer G et al. (2015) ChIP-Seq to Analyze the Binding of Replication Proteins to Chromatin. Methods Mol Biol 1300:155-68
Ostrow, A Zachary; Nellimoottil, Tittu; Knott, Simon R V et al. (2014) Fkh1 and Fkh2 bind multiple chromosomal elements in the S. cerevisiae genome with distinct specificities and cell cycle dynamics. PLoS One 9:e87647
Villwock, Sandra K; Aparicio, Oscar M (2014) Two-dimensional agarose gel electrophoresis for analysis of DNA replication. Methods Mol Biol 1205:329-40
Massilamany, Chandirasegaran; Marciano-Cabral, Francine; Rocha-Azevedo, Bruno da et al. (2014) SJL mice infected with Acanthamoeba castellanii develop central nervous system autoimmunity through the generation of cross-reactive T cells for myelin antigens. PLoS One 9:e98506
Peace, Jared M; Ter-Zakarian, Anna; Aparicio, Oscar M (2014) Rif1 regulates initiation timing of late replication origins throughout the S. cerevisiae genome. PLoS One 9:e98501
Aparicio, Oscar M (2013) Location, location, location: it's all in the timing for replication origins. Genes Dev 27:117-28
Pope, Benjamin D; Aparicio, Oscar M; Gilbert, David M (2013) SnapShot: Replication timing. Cell 152:1390-1390.e1

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