Loss of TGFß signaling increases alternative end-joining DNA repair that sensitizes to genotoxic therapies across cancer types.

Among the pleotropic roles of transforming growth factor-ß (TGFß) signaling in cancer, its impact on genomic stability is least understood. Inhibition of TGFß signaling increases use of alternative end joining (alt-EJ), an error-prone DNA repair process that typically functions as a "backup" pathway if double-strand break repair by homologous recombination or nonhomologous end joining is compromised. However, the consequences of this functional relationship on therapeutic vulnerability in human cancer remain unknown. Here, we show that TGFß broadly controls the DNA damage response and suppresses alt-EJ genes that are associated with genomic instability. Mechanistically based TGFß and alt-EJ gene expression signatures were anticorrelated in glioblastoma, squamous cell lung cancer, and serous ovarian cancer. Consistent with error-prone repair, more of the genome was altered in tumors classified as low TGFß and high alt-EJ, and the corresponding patients had better outcomes. Pan-cancer analysis of solid neoplasms revealed that alt-EJ genes were coordinately expressed and anticorrelated with TGFß competency in 16 of 17 cancer types tested. Moreover, regardless of cancer type, tumors classified as low TGFß and high alt-EJ were characterized by an insertion-deletion mutation signature containing short microhomologies and were more sensitive to genotoxic therapy. Collectively, experimental studies revealed that loss or inhibition of TGFß signaling compromises the DNA damage response, resulting in ineffective repair by alt-EJ. Translation of this mechanistic relationship into gene expression signatures identified a robust anticorrelation that predicts response to genotoxic therapies, thereby expanding the potential therapeutic scope of TGFß biology.

DNA double strand break repair inhibition as a cause of heat radiosensitization: re-evaluation considering backup pathways of NHEJ.

Heat shock is one of the most effective radiosensitizers known. As a result, combination of heat with ionizing radiation (IR) is considered a promising strategy in the management of human cancer. The mechanism of heat radiosensitization has been the subject of extensive work but a unifying mechanistic model is presently lacking. To understand the cause of excessive death in irradiated cells after heat exposure, it is necessary to characterize the lesion(s) underlying the effect and to determine which of the pathways processing this lesion are affected by heat. Since DNA double strand breaks (DSBs) are the main cause for IR-induced cell death, inhibition of DSB processing has long been considered a major candidate for heat radiosensitization. However, effective radiosensitization of mutants with defects in homologous recombination repair (HRR), or in DNA-PK dependent non-homologous end joining (D-NHEJ), the two primary pathways of DSB repair, has led to the formulation of models excluding DSBs as a cause for this phenomenon and attributing heat radiosensitization to inhibition of base damage processing. Since direct evidence for a major role of base damage in heat radiosensitization, or in IR-induced killing for that matter, is scarce and new insights in DSB repair allow alternative interpretations of existing data with repair mutants, we attempt here a re-evaluation of the role of DSBs and their repair in heat radiosensitization. First, we reanalyse data obtained with various DSB repair mutants on first principles and in the light of the recent recognition that alternative pathways of NHEJ, operating as backup (B-NHEJ), substantially contribute to DSB repair and thus probably also to heat radiosensitization. Second, we review aspects of combined action of heat and radiation, such as modulation in the cell-cycle-dependent variation in radiosensitivity to killing, as well as heat radiosensitization as a function of LET, and examine whether the observed effects are compatible with DSB repair inhibition. We conclude with a model reclaiming a central role for DSBs in heat radiosensitization.

DNA-PKcs subunits in radiosensitization by hyperthermia on hepatocellular carcinoma hepG2 cell line.

AIM: To investigate the role of DNA-PKcs subunits in radiosensitization by hyperthermia on hepatocellular carcinoma HepG(2) cell lines. METHODS: Hep G(2) cells were exposed to hyperthermia and irradiation. Hyperthermia was given at 45.5 degrees C. Cell survival was determined by an in vitro clonogenic assay for the cells treated with or without hyperthermia at various time points. DNA DSB rejoining was measured using asymmetric field inversion gel electrophoresis (AFIGE). The DNA-PKcs activities were measured using DNA-PKcs enzyme assay system. RESULTS: Hyperthermia can significantly enhance irradiation-killing cells. Thermal enhancement ratio as calculated at 10 % survival was 2.02. The difference in radiosensitivity between two treatment modes manifested as a difference in the alpha components and the almost same beta components, which alpha value was considerably higher in the cells of combined radiation and hyperthermia as compared with irradiating cells (1.07 Gy(-1) versus 0.44 Gy(-1)). Survival fraction showed 1 logarithm increase after an 8-hour interval between heat and irradiation, whereas DNA-PKcs activity did not show any recovery. The cells were exposed to heat 5 minutes only, DNA-PKcs activity was inhibited at the nadir, even though the exposure time was lengthened. Whereas the ability of DNA DSB rejoining was inhibited with the increase of the length of hyperthermic time. The repair kinetics of DNA DSB rejoining after treatment with Wortmannin is different from the hyperthermic group due to the striking high slow rejoining component. CONCLUSION: Determination with the cell extracts and the peptide phosphorylation assay, DNA-PKcs activity was inactivated by heat treatment at 45.5 degrees C, and could not restore. Cell survival is not associated with the DNA-PKcs inactivity after heat. DNA-PKcs is not a unique factor affecting the DNA DSB repair. This suggests that DNA-PKcs do not play a crucial role in the enhancement of cellular radiosensitivity by hyperthermia.