Poly(ADP-Ribose) Polymerase Inhibitor Induces Accelerated Senescence in Irradiated Breast Cancer Cells and Tumors

Efimova, Elena V.; Mauceri, Helena J.; Golden, Daniel W.; Labay, Edwardine; Bindokas, Vytautas P.; Darga, Thomas E.; Chakraborty, Chaitali; Barreto-Andrade, Juan Camilo; Crawley, Clayton D.; Sutton, Harold G.; Kron, Stephen J.; Weichselbaum, Ralph R.

doi:10.1158/0008-5472.can-09-4224

Cited by 97 publications

(118 citation statements)

References 22 publications

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“…While several studies have previously shown that epithelial cancer cells readily undergo senescence after radiation treatment in vitro (reviewed in ref. 20), a recent report from Efimova and colleagues identified accelerated senescence in breast cancer xenografts treated with radiation and the PARP inhibitor ABT-888 (42). We similarly found that growth delay of irradiated H460 xenografts by BEZ235 was associated with a robust accelerated senescence response.…”

Section: Discussionsupporting

confidence: 73%

Inhibition of DNA-Dependent Protein Kinase Induces Accelerated Senescence in Irradiated Human Cancer Cells

Azad

Jackson

Cullinane

et al. 2011

Molecular Cancer Research

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DNA-dependent protein kinase (DNA-PK) plays a pivotal role in the repair of DNA double-strand breaks (DSB) and is centrally involved in regulating cellular radiosensitivity. Here, we identify DNA-PK as a key therapeutic target for augmenting accelerated senescence in irradiated human cancer cells. We find that BEZ235, a novel inhibitor of DNA-PK and phosphoinositide 3-kinase (PI3K)/mTOR, abrogates radiation-induced DSB repair resulting in cellular radiosensitization and growth delay of irradiated tumor xenografts. Importantly, radiation enhancement by BEZ235 coincides with a prominent p53-dependent accelerated senescence phenotype characterized by positive b-galactosidase staining, G 2 -M cell-cycle arrest, enlarged and flattened cellular morphology, and increased p21 expression and senescence-associated cytokine secretion. Because this senescence response to BEZ235 is accompanied by unrepaired DNA DSBs, we examined whether selective targeting of DNA-PK also induces accelerated senescence in irradiated cells. Significantly, we show that specific pharmacologic inhibition of DNA-PK, but not PI3K or mTORC1, delays DSB repair leading to accelerated senescence after radiation. We additionally show that PRKDC knockdown using siRNA promotes a striking accelerated senescence phenotype in irradiated cells comparable with that of BEZ235. Thus, in the context of radiation treatment, our data indicate that inhibition of DNA-PK is sufficient for the induction of accelerated senescence. These results validate DNA-PK as an important therapeutic target in irradiated cancer cells and establish accelerated senescence as a novel mechanism of radiosensitization induced by DNA-PK blockade. Mol Cancer Res; 9(12); 1696-707. Ó2011 AACR.

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Section: Discussionsupporting

confidence: 73%

Inhibition of DNA-Dependent Protein Kinase Induces Accelerated Senescence in Irradiated Human Cancer Cells

Azad

Jackson

Cullinane

et al. 2011

Molecular Cancer Research

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“…To date, no targeted protocol has been developed for the treatment of triple-negative breast cancer. Although studies show that parp1 (poly[ADP-ribose] polymerase-1) inhibitor can potentially increase the sensitivity of triple-negative breast cancer to radiotherapy 17,18 , treatment of triple-negative breast cancer with parp1 inhibitor and irradiation is still in its infancy.…”

Section: Discussionmentioning

confidence: 99%

“…Some investigators experimented with altering the patterns of radiotherapy in breast cancer patients with a high risk of lrr, applying targeted biologic therapy 6,[16][17][18] and an increase in the radiation dose. Panoff et al 22 used chest irradiation at the recommended dose of more than 50 Gy and found that the 5-year lrr rate was 5.7% for patients receiving a radiation dose of more than 50.4 Gy (median: 60.4 Gy) and 12.7% for those receiving 50.4 Gy or less (median: 50.4 Gy, p = 0.054).…”

Section: Discussionmentioning

confidence: 99%

Risk Factors for Locoregional Recurrence After Postmastectomy Radiotherapy in Breast Cancer Patients with Four or More Positive Axillary Lymph Nodes

Zhou

et al. 2014

Current Oncology

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“…In contrast, radiation is used in a wide range of treatment; over 50% of all cancer treatment protocols include the use of radiation. Target tissues range from skin to skeletal muscles and bone marrow; each tissue type has special cellular components that influence the absorbed radiation dose, and manifests side effects differently.In recent years, cell-based and genetic studies have improved our understanding of the molecular and genetic basis of radiosensitivity by identifying the genes and pathways that are involved in radiation response (Amundson et al 2001(Amundson et al , 2008Smirnov et al 2009;Efimova et al 2010;Niu et al 2010;Noon et al 2010). In this study, we focused on radiation-induced cell death.…”

mentioning

confidence: 99%

Genetic variation in radiation-induced cell death

et al. 2011

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Radiation exposure through environmental, medical, and occupational settings is increasingly common. While radiation has harmful effects, it has utility in many applications such as radiotherapy for cancer. To increase the efficacy of radiation treatment and minimize its risks, a better understanding of the individual differences in radiosensitivity and the molecular basis of radiation response is needed. Here, we integrated human genetic and functional genomic approaches to study the response of human cells to radiation. We measured radiation-induced changes in gene expression and cell death in B cells from normal individuals. We found extensive individual variation in gene expression and cellular responses. To understand the genetic basis of this variation, we mapped the DNA sequence variants that influence expression response to radiation. We also identified radiation-responsive genes that regulate cell death; silencing of these genes by small interfering RNA led to an increase in radiation-induced cell death in human B cells, colorectal and prostate cancer cells. Together these results uncovered DNA variants that contribute to radiosensitivity and identified genes that can be targeted to increase the sensitivity of tumors to radiation. [Supplemental material is available for this article.]Radiation exposure is increasingly common. Medical diagnostic tools such as the X-ray and computed tomography imaging expose patients to ionizing radiation (IR), which can cause DNA damage and increase one's risk of malignancies. However, these radiation-based devices have greatly improved the diagnosis and treatment of many diseases. Thus, the solution is not to eliminate radiation exposure but to protect individuals who are the most sensitive to radiation and to minimize dose and exposure to all individuals (Barnett et al. 2009).Pharmacogenetics has made significant contributions in maximizing therapeutic gains while minimizing side effects; however, those studies have focused mainly on chemicals as therapeutics and have not included radiation. The exclusion of radiation in pharmacogenetics is not surprising since radiation presents a unique set of challenges. Most people are exposed to radiation in nonmedical settings in addition to medical exposures, thus complicating the monitoring of exposure. Safety trials of radiation are impossible given its known toxic effects. Third, most drugs are developed for one or a few diseases. In contrast, radiation is used in a wide range of treatment; over 50% of all cancer treatment protocols include the use of radiation. Target tissues range from skin to skeletal muscles and bone marrow; each tissue type has special cellular components that influence the absorbed radiation dose, and manifests side effects differently.In recent years, cell-based and genetic studies have improved our understanding of the molecular and genetic basis of radiosensitivity by identifying the genes and pathways that are involved in radiation response (Amundson et al. 2001(Amundson et al. , 2008Smirnov et al. ...

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Poly(ADP-Ribose) Polymerase Inhibitor Induces Accelerated Senescence in Irradiated Breast Cancer Cells and Tumors

Cited by 97 publications

References 22 publications

Inhibition of DNA-Dependent Protein Kinase Induces Accelerated Senescence in Irradiated Human Cancer Cells

Inhibition of DNA-Dependent Protein Kinase Induces Accelerated Senescence in Irradiated Human Cancer Cells

Risk Factors for Locoregional Recurrence After Postmastectomy Radiotherapy in Breast Cancer Patients with Four or More Positive Axillary Lymph Nodes

Genetic variation in radiation-induced cell death

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