Radiation and chemotherapeutic agents eradicate tumors by inducing irreparable DNA damage. However, cancer cells often develop resistance to therapy by manipulating the DNA repair machinery. Conversely, a dividing cell constantly exposed to environmental and endogenous DNA damaging agents can transform into a tumor due to incorrect repair. Therefore the expression level of DNA repair proteins is critical both for cancer therapy and tumorigenesis. In our preliminary studies we have discovered a novel connection between a new class of gene expression regulators, microRNAs and DNA repair proteins. MicroRNAs (miRNAs) are small non-coding RNAs that typically dampen gene expression. There is accumulating evidence that miRNAs are mis-expressed in cancer cells. It is noteworthy that ectopic overexpression of miRNAs downregulating DNA repair proteins could sensitize cancer cells to radiation and other genotoxic reagents. Alternatively, tumors that delete these miRNAs may develop resistance to conventional cancer therapy. DNA repair is a 'house keeping'function, and micro-RNA mediated attenuation of DNA repair may appear counter intuitive. However, normal cells down modulate DNA repair in a terminally differentiated state where overall DNA repair is downregulated. Using the experimental system of in vitro hematopoietic cell differentiation, we have identified microRNAs (miRNAs), miR-24 and a polycistronic miRNA cluster including miRNAs (183, 96, 182), that are upregulated in terminally differentiated non-dividing cells but are rapidly down regulated in response to ionizing radiation (IR) in dividing cells. We hypothesize that in post-mitotic cells DNA damage induces apoptosis and miRNAs attenuate the DNA repair machinery promoting cell death. Conversely, in response to IR the miRNAs are downmodulated in dividing cells to accentuate the production of DNA repair proteins and boost the DNA damage response. In support of this contention, we observed, that miR-24, downregulates the expression of a key DSB repair protein, H2AX and impedes DSB repair in terminally differentiated blood cells. The miRNAs (182,183 and 96) that we propose to study have already been noted for aberrant expression in a variety of tumors. A direct effect of these miRNAs on cancer could be by dysregulation of the DNA repair machinery. Bioinformatic predictions suggest that several DNA repair genes, such as, BRCA1, ATR, XLF, etc. are targeted by the miRNAs-183, 96 and 182. Preliminary experiments validate the prediction that miR-182 regulates BRCA1.
In Aim #1 we will use different computational, and biochemical strategies, to identify and validate DNA repair factors targeted by miRNAs-183, 96 and 182 in transformed cell lines and primary cells.
In Aim #2 we will systematically study the effect of these miRNAs on DSB repair and determine their impact on each repair pathway. Finally we will evaluate the radiosensitivity of cancer cells expressing these miRNAs. There is limited understanding of the role of miRNAs in DNA repair and this study will address this issue and also elucidate the impact of miRNAs on radiotherapy.

Public Health Relevance

Radiation and chemotherapeutic agents eradicate tumors by inducing irreparable DNA damage, and cancer cells often counter this treatment by manipulating the DNA repair machinery to develop resistance. In our preliminary studies we have discovered a novel connection between a new class of gene expression regulators, microRNAs (miRNAs) and DNA repair proteins, and the miRNAs (182, 183 and 96) that we propose to investigate have already been recognized for aberrant expression in a variety of tumors. Identifying specific miRNAs that suppress DNA repair, and their functional impact upon the DNA repair pathways, and radiosensitivity of cells, will have significant clinical implications in cancer biology.

Agency
National Institute of Health (NIH)
Institute
National Cancer Institute (NCI)
Type
Research Project (R01)
Project #
5R01CA142698-02
Application #
8016631
Study Section
Radiation Therapeutics and Biology Study Section (RTB)
Program Officer
Mietz, Judy
Project Start
2010-02-01
Project End
2015-01-31
Budget Start
2011-02-01
Budget End
2012-01-31
Support Year
2
Fiscal Year
2011
Total Cost
$352,231
Indirect Cost
Name
Dana-Farber Cancer Institute
Department
Type
DUNS #
076580745
City
Boston
State
MA
Country
United States
Zip Code
02215
Botuyan, Maria Victoria; Cui, Gaofeng; Drané, Pascal et al. (2018) Mechanism of 53BP1 activity regulation by RNA-binding TIRR and a designer protein. Nat Struct Mol Biol 25:591-600
Meghani, Khyati; Fuchs, Walker; Detappe, Alexandre et al. (2018) Multifaceted Impact of MicroRNA 493-5p on Genome-Stabilizing Pathways Induces Platinum and PARP Inhibitor Resistance in BRCA2-Mutated Carcinomas. Cell Rep 23:100-111
Elias, Kevin M; Fendler, Wojciech; Stawiski, Konrad et al. (2017) Diagnostic potential for a serum miRNA neural network for detection of ovarian cancer. Elife 6:
Drané, Pascal; Brault, Marie-Eve; Cui, Gaofeng et al. (2017) TIRR regulates 53BP1 by masking its histone methyl-lysine binding function. Nature 543:211-216
Fendler, Wojciech; Malachowska, Beata; Meghani, Khyati et al. (2017) Evolutionarily conserved serum microRNAs predict radiation-induced fatality in nonhuman primates. Sci Transl Med 9:
Choi, Young Eun; Meghani, Khyati; Brault, Marie-Eve et al. (2016) Platinum and PARP Inhibitor Resistance Due to Overexpression of MicroRNA-622 in BRCA1-Mutant Ovarian Cancer. Cell Rep 14:429-439
Tubbs, Anthony T; Dorsett, Yair; Chan, Elizabeth et al. (2014) KAP-1 promotes resection of broken DNA ends not protected by ?-H2AX and 53BP1 in G?-phase lymphocytes. Mol Cell Biol 34:2811-21
Moskwa, Patryk; Zinn, Pascal O; Choi, Young Eun et al. (2014) A functional screen identifies miRs that induce radioresistance in glioblastomas. Mol Cancer Res 12:1767-78
Shaltiel, Indra A; Aprelia, Melinda; Saurin, Adrian T et al. (2014) Distinct phosphatases antagonize the p53 response in different phases of the cell cycle. Proc Natl Acad Sci U S A 111:7313-8
Lee, Dong-Hyun; Acharya, Sanket S; Kwon, Mijung et al. (2014) Dephosphorylation enables the recruitment of 53BP1 to double-strand DNA breaks. Mol Cell 54:512-25

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