TY - JOUR
T1 - Repurposing DNA repair factors to eradicate tumor cells upon radiotherapy
AU - Bhattacharya, Souparno
AU - Asaithamby, Aroumougame
N1 - Funding Information:
We thank Dr. Jonathan Feinberg for the critical reading of this review.The research in Asaithamby Aroumougame's laboratory was partially supported by National Aeronautics and Space Administration (NNX13AD57G and NNX15AE06G), Cancer Prevention and Research Institute of Texas (RP160520), and National Institutes of Health (R01AG053341) grants.
Publisher Copyright:
© Translational Cancer Research.
PY - 2017/7/1
Y1 - 2017/7/1
N2 - Cancer is the leading cause of death worldwide. Almost 50% of all cancer patients undergo radiation therapy (RT) during treatment, with varying success. The main goal of RT is to kill tumor cells by damaging their DNA irreversibly while sparing the surrounding normal tissue. The outcome of RT is often determined by how tumors recognize and repair their damaged DNA. A growing body of evidence suggests that tumors often show abnormal expression of DNA double-strand break (DSB) repair genes that are absent from normal cells. Defects in a specific DNA repair pathway make tumor cells overly dependent on alternative or backup pathways to repair their damaged DNA. These tumor cell-specific abnormalities in the DNA damage response (DDR) machinery can potentially be used as biomarkers for treatment outcomes or as targets for sensitization to ionizing radiation (IR). An improved understanding of genetic or epigenetic alterations in the DNA repair pathways specific to cancer cells has paved the way for new treatments that combine pharmacological exploitation of tumor-specific molecular vulnerabilities with IR. Inhibiting DNA repair pathways has the potential to greatly enhance the therapeutic ratio of RT. In this review, we will discuss DNA repair pathways in active cells and how these pathways are deregulated in tumors. We will also describe the impact of targeting cancer-specific aberrations in the DDR as a treatment strategy to improve the efficacy of RT. Finally, we will address the current roadblocks and future prospects of these approaches.
AB - Cancer is the leading cause of death worldwide. Almost 50% of all cancer patients undergo radiation therapy (RT) during treatment, with varying success. The main goal of RT is to kill tumor cells by damaging their DNA irreversibly while sparing the surrounding normal tissue. The outcome of RT is often determined by how tumors recognize and repair their damaged DNA. A growing body of evidence suggests that tumors often show abnormal expression of DNA double-strand break (DSB) repair genes that are absent from normal cells. Defects in a specific DNA repair pathway make tumor cells overly dependent on alternative or backup pathways to repair their damaged DNA. These tumor cell-specific abnormalities in the DNA damage response (DDR) machinery can potentially be used as biomarkers for treatment outcomes or as targets for sensitization to ionizing radiation (IR). An improved understanding of genetic or epigenetic alterations in the DNA repair pathways specific to cancer cells has paved the way for new treatments that combine pharmacological exploitation of tumor-specific molecular vulnerabilities with IR. Inhibiting DNA repair pathways has the potential to greatly enhance the therapeutic ratio of RT. In this review, we will discuss DNA repair pathways in active cells and how these pathways are deregulated in tumors. We will also describe the impact of targeting cancer-specific aberrations in the DDR as a treatment strategy to improve the efficacy of RT. Finally, we will address the current roadblocks and future prospects of these approaches.
KW - Cancer
KW - Charged particle therapy (CPT)
KW - DNA damage
KW - DNA repair
KW - Ionizing radiation (IR)
KW - Radiotherapy
KW - Synthetic lethality
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U2 - 10.21037/tcr.2017.05.22
DO - 10.21037/tcr.2017.05.22
M3 - Review article
C2 - 30613483
AN - SCOPUS:85025594268
SN - 2218-676X
VL - 6
SP - S822-S839
JO - Translational Cancer Research
JF - Translational Cancer Research
ER -