Abstract

Mutations play a critical role in the etiology of many diseases, such as autism, schizophrenia, diabetes, and cancer. Most mutations arise during the replication of damaged DNA, a process called translesion synthesis (TLS). TLS is carried out by specialized TLS polymerases, which have evolved to accommodate DNA damage. Several fundamental, unanswered questions about TLS polymerases remain.
In Aim 1, we will address the following question: how are TLS polymerases recruited to stalled replication forks? To do this, we will use both ensemble and single-molecule binding assays and steady state kinetics. These studies will reveal the mechanisms of TLS polymerase recruitment to ubiquitin-modified PCNA (UbPCNA), a key component of stalled replication forks. These studies will also reveal the structural motifs required for these interactions.
In Aim 2, we will address the following question: how are TLS polymerases selected for recruitment to specific DNA lesions? To do this, we will use ensemble and single-molecule binding assay. These studies will reveal the mechanisms of TLS polymerase selection and the influence of the DNA lesion on this process.
In Aim 3, we will address the following question: how are TLS polymerases structurally organized at stalled replication fork? To do this, we will use X-ray crystallography, computational modeling and simulations, and a variety of experimental distance measurements. These studies will provide the first glimpse of the structural organization of TLS polymerases within these protein-DNA complexes and will reveal how the different TLS polymerases are coordinated during the multi-step process of TLS.

Public Health Relevance

Mutations, which play a critical role in causing many diseases, mainly arise during the replication of damaged DNA. Specialized enzymes called TLS polymerases are essential for this process. Understanding their detailed mechanisms, the objective of this proposal, will be important for developing novel strategies to eliminate mutations.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Institute of General Medical Sciences (NIGMS)
Type
Research Project (R01)
Project #
5R01GM081433-07
Application #
8911327
Study Section
Special Emphasis Panel (ZRG1-GGG-Q (02))
Program Officer
Reddy, Michael K
Project Start
2008-07-01
Project End
2018-06-30
Budget Start
2015-07-01
Budget End
2016-06-30
Support Year
7
Fiscal Year
2015
Total Cost
$318,690
Indirect Cost
$100,660

  Institution

Name
University of Iowa
Department
Biochemistry
Type
Schools of Medicine
DUNS #
062761671
City
Iowa City
State
IA
Country
United States
Zip Code
52246

  Publications

Powers, Kyle T; Washington, M Todd (2018) Eukaryotic translesion synthesis: Choosing the right tool for the job. DNA Repair (Amst) :
Kondratick, Christine M; Litman, Jacob M; Shaffer, Kurt V et al. (2018) Crystal structures of PCNA mutant proteins defective in gene silencing suggest a novel interaction site on the front face of the PCNA ring. PLoS One 13:e0193333
Powers, Kyle T; Lavering, Emily D; Washington, M Todd (2018) Conformational Flexibility of Ubiquitin-Modified and SUMO-Modified PCNA Shown by Full-Ensemble Hybrid Methods. J Mol Biol 430:5294-5303
Powers, Kyle T; Elcock, Adrian H; Washington, M Todd (2018) The C-terminal region of translesion synthesis DNA polymerase ? is partially unstructured and has high conformational flexibility. Nucleic Acids Res 46:2107-2120
Liu, Jie; Ede, Christopher; Wright, William D et al. (2017) Srs2 promotes synthesis-dependent strand annealing by disrupting DNA polymerase ?-extending D-loops. Elife 6:
Zhao, Linlin; Washington, M Todd (2017) Translesion Synthesis: Insights into the Selection and Switching of DNA Polymerases. Genes (Basel) 8:
Powers, Kyle T; Washington, M Todd (2017) Analyzing the Catalytic Activities and Interactions of Eukaryotic Translesion Synthesis Polymerases. Methods Enzymol 592:329-356
Boehm, Elizabeth M; Washington, M Todd (2016) R.I.P. to the PIP: PCNA-binding motif no longer considered specific: PIP motifs and other related sequences are not distinct entities and can bind multiple proteins involved in genome maintenance. Bioessays 38:1117-1122
Washington, M Todd (2016) DNA Polymerase Fidelity: Beyond Right and Wrong. Structure 24:1855-1856
Boehm, E M; Subramanyam, S; Ghoneim, M et al. (2016) Quantifying the Assembly of Multicomponent Molecular Machines by Single-Molecule Total Internal Reflection Fluorescence Microscopy. Methods Enzymol 581:105-145

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