Late DNA Damage Mediated by Homologous Recombination Repair Results in Radiosensitization with Gemcitabine

Late DNA Damage Mediated by Homologous Recombination Repair Results in Radiosensitization with Gemcitabine

Gemcitabine (dFdCyd) shows broad antitumor activity in solid tumors in chemotherapeutic regimens or when combined with ionizing radiation (radiosensitization). While it is known that mismatches in DNA are necessary for dFdCyd radiosensitization, the critical event resulting in radiosensitization has...

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Bibliographic Details
Published in:Radiation research Vol. 186; no. 5; pp. 466 - 477
Main Authors: Im, Michael M., Flanagan, Sheryl A., Ackroyd, Jeffrey J., Knapp, Brendan, Kramer, Aaron, Shewach, Donna S.
Format: Journal Article
Language:English
Published: United States The Radiation Research Society 01-11-2016
Radiation Research Society
Allen Press Inc
Subjects:
Damage
Deoxycytidine - analogs & derivatives
Deoxycytidine - pharmacology
Deoxyribonucleic acid
DNA
DNA Breaks, Double-Stranded - drug effects
DNA Breaks, Double-Stranded - radiation effects
DNA Damage
DNA-Binding Proteins - metabolism
Dose-Response Relationship, Drug
Drugs
Gamma Rays
Histones - metabolism
Homology
Humans
Ionizing radiation
Irradiation
MCF-7 Cells
Rad51 Recombinase - antagonists & inhibitors
Radiation damage
Radiation-Sensitizing Agents - pharmacology
Recombinational DNA Repair - drug effects
Recombinational DNA Repair - radiation effects
REGULAR ARTICLES
Repair
Space life sciences
Time Factors
Tumors
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Summary:Gemcitabine (dFdCyd) shows broad antitumor activity in solid tumors in chemotherapeutic regimens or when combined with ionizing radiation (radiosensitization). While it is known that mismatches in DNA are necessary for dFdCyd radiosensitization, the critical event resulting in radiosensitization has not been identified. Here we hypothesized that late DNA damage (≥24 h after drug washout/irradiation) is a causal event in radiosensitization by dFdCyd, and that homologous recombination repair (HRR) is required for this late DNA damage. Using γ-H2AX as a measurement of DNA damage in MCF-7 breast cancer cells, we demonstrate that 10 or 80 nM dFdCyd alone produced significantly more late DNA damage compared to that observed within 4 h after treatment. The combination of dFdCyd treatment followed by irradiation did not produce a consistent increase in DNA damage in the first 4 h after treatment, however, there was a synergistic increase 24–48 h later relative to treatment with dFdCyd or radiation alone. RNAi suppression of the essential HRR protein, XRCC3, significantly decreased both radiosensitization and late DNA damage. Furthermore, inhibition of HRR with the Rad51 inhibitor B02 prevented radiosensitization when added after, but not during, treatment with dFdCyd and radiation. To our knowledge, this is the first published study to show that radiosensitization with dFdCyd results from a synergistic increase in DNA damage at 24–48 h after drug and radiation treatment, and that this damage and radiosensitization require HRR. These results suggest that tumors that overexpress HRR will be more vulnerable to chemoradiotherapy, and treatments that increase HRR and/or mismatches in DNA will enhance dFdCyd radiosensitization.
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ISSN:0033-7587
1938-5404
DOI:10.1667/RR14443.1