We propose to elucidate the mechanism of Cas9/CRISPR- (CRISPR associated 9/clustered regularly interspaced short palindromic repeats) initiated gene modification. Specifically, we propose to identify the cellular recombination mechanisms that are engaged when cleavase, nickase or dual nickase versions of Cas9- are utilized and to also begin to identify and characterize the genes that regulate these processes. In the previous funding period we were able to demonstrate (unexpectedly) that rAAV (recombinant adeno- associated virus), a naturally single-stranded virus, uses a double-stranded form (probably a replicative intermediate) to facilitate gene modification. In addition, w unequivocally demonstrated that rAAV-mediated gene targeting events and random insertions are mechanistically distinct and are carried out by separate DNA DSB (double-strand break) repair pathways. In addition, we demonstrated that the introduction of a chromosomal DSB radically altered the way that rAAV carries out gene modification. Lastly, we have identified that the mismatch repair status of a target cell is the single most important factor that determines the susceptibility of that cell to gene-editing activities. In this grant application, we propose to exend our mechanistic studies to Cas9/CRISPR-initiated gene modification. We will do this by defining the cellular recombination pathways that are engaged when cleavase, nickase or dual nickase versions of Cas9 are utilized. Secondly, we will identify and characterize druggable candidate genes that regulate the process of gene modification. Finally, we propose to carry out whole genome screens to identify new factors that regulate gene modification in human somatic cells. The importance of understanding these processes for gene therapy is clear. Thus, the ability to perform safe, high-frequency molecular surgery on human cells is paramount to realizing the goal of gene therapy. In a larger view, we are investigating pathways of DNA DSB repair that - besides gene modification - regulate many other cellular processes including genomic stability. Thus, the likelihood of discovering ancillary insights into immortalization, aging, tumorigenesis etc. lends confidence to the belief that these proposed experiments are important. To our knowledge, we are one of only a few laboratories in the world utilizing genetic, loss-of-function approaches to study gene modification in human cells and thus we are well-positioned to gain insight into the mechanism of gene editing that cannot be obtained elsewhere.

Public Health Relevance

Gene therapy is the holy grail of modern molecular human medicine. Herein, we describe approaches by which we will improve gene editing and correction methodology for use in human cells. As the wealth of information concerning the human genome continues to grow, the ability to perform molecular surgery in human cells will be essential if we are to realize the full potential of that information.

Agency
National Institute of Health (NIH)
Institute
National Institute of General Medical Sciences (NIGMS)
Type
Research Project (R01)
Project #
5R01GM088351-08
Application #
9441797
Study Section
Therapeutic Approaches to Genetic Diseases Study Section (TAG)
Program Officer
Willis, Kristine Amalee
Project Start
2010-03-15
Project End
2019-02-28
Budget Start
2018-03-01
Budget End
2019-02-28
Support Year
8
Fiscal Year
2018
Total Cost
Indirect Cost
Name
University of Minnesota Twin Cities
Department
Biochemistry
Type
Schools of Medicine
DUNS #
555917996
City
Minneapolis
State
MN
Country
United States
Zip Code
55455
Harvey, Adam; Mielke, Nicholas; Grimstead, Julia W et al. (2018) PARP1 is required for preserving telomeric integrity but is dispensable for A-NHEJ. Oncotarget 9:34821-34837
Baird, Duncan M; Hendrickson, Eric A (2018) Telomeres and Chromosomal Translocations : There's a Ligase at the End of the Translocation. Adv Exp Med Biol 1044:89-112
Thompson, Elizabeth L; Yeo, Jung E; Lee, Eun-A et al. (2017) FANCI and FANCD2 have common as well as independent functions during the cellular replication stress response. Nucleic Acids Res 45:11837-11857
Kan, Yinan; Batada, Nizar N; Hendrickson, Eric A (2017) Human somatic cells deficient for RAD52 are impaired for viral integration and compromised for most aspects of homology-directed repair. DNA Repair (Amst) 55:64-75
Kan, Yinan; Ruis, Brian; Takasugi, Taylor et al. (2017) Mechanisms of precise genome editing using oligonucleotide donors. Genome Res 27:1099-1111
Alotaibi, Moureq; Sharma, Khushboo; Saleh, Tareq et al. (2016) Radiosensitization by PARP Inhibition in DNA Repair Proficient and Deficient Tumor Cells: Proliferative Recovery in Senescent Cells. Radiat Res 185:229-45
Neal, Jessica A; Xu, Yao; Abe, Masumi et al. (2016) Restoration of ATM Expression in DNA-PKcs-Deficient Cells Inhibits Signal End Joining. J Immunol 196:3032-42
Liddiard, Kate; Ruis, Brian; Takasugi, Taylor et al. (2016) Sister chromatid telomere fusions, but not NHEJ-mediated inter-chromosomal telomere fusions, occur independently of DNA ligases 3 and 4. Genome Res 26:588-600
Roy, Sunetra; de Melo, Abinadabe J; Xu, Yao et al. (2015) XRCC4/XLF Interaction Is Variably Required for DNA Repair and Is Not Required for Ligase IV Stimulation. Mol Cell Biol 35:3017-28
Batenburg, Nicole L; Thompson, Elizabeth L; Hendrickson, Eric A et al. (2015) Cockayne syndrome group B protein regulates DNA double-strand break repair and checkpoint activation. EMBO J 34:1399-416

Showing the most recent 10 out of 28 publications