Purpose To determine whether inhibition of TGFβ signaling prior to irradiation sensitizes human and murine cancer cells in vitro and in vivo. Experimental Design TGFβ-mediated growth and Smad phosphorylation of MCF7, Hs578T, MDA-MB-231, and T47D human breast cancer cell lines were examined and correlated with clonogenic survival following graded radiation doses with and without pretreatment with LY364947, a small molecule inhibitor of the TGFβ type I receptor kinase. The DNA damage response was assessed in irradiated MDA-MB-231 cells pretreated with LY364947 in vitro and LY2109761, a pharmacokinetically stable inhibitor of TGFβ signaling, in vivo. The in vitro response of a syngeneic murine tumor, 4T1, was tested using a TGFβ neutralizing antibody, 1D11, with single or fractionated radiation doses in vivo. Results Human breast cancer cell lines pretreated with TGFβ small molecule inhibitor were radio-sensitized, irrespective of sensitivity to TGFβ growth inhibition. Consistent with increased clonogenic cell death, radiation-induced phosphorylation of H2AX and p53 was significantly reduced in MDA-MB-231 triple-negative breast cancer cells when pretreated in vitro or in vivo with a TGFfS type I receptor kinase inhibitor. Moreover, TGFβ neutralizing antibodies increased radiation sensitivity, blocked γH2AX foci formation, and significantly increased tumor growth delay in 4T1 murine mammary tumors in response to single and fractionated radiation exposures. Conclusion These results show that TGFβ inhibition prior to radiation attenuated DNA damage responses, increased clonogenic cell death, and promoted tumor growth delay, and thus may be an effective adjunct in cancer radiotherapy.
The induction of DNA double-strand breaks (DSBs) by genotoxic treatment leads to high toxicity and genetic instability. Various approaches have been undertaken to quantify the number of breaks and to follow the kinetic of DSB repair. Recently, the phosphorylation of the variant histone H2AX (named gammaH2AX), quantified by specific immunodetection approaches, has provided a valuable and highly sensitive method to monitor DSBs formation. Although it is admitted that the number of gammaH2AX foci reflected that of DSBs, contradictory reports leave open the question of a link between the disappearance of gammaH2AX signal and DSBs repair. We determined gammaH2AX expression (i) in cells either proficient or not in DSBs repair capacity, (ii) after exposure to ionizing radiation (IR) or calicheamicin gamma1, a radiomimetic compound, (iii) and by three different immunodetection methods, foci numbering, flow cytometry or Western blotting. We showed here that gammaH2AX loss correlates with DSB repair activity only at low cytotoxic doses, when less than 100-150 DSBs breaks per genome are produced, independently of the method used. In addition, in DNA repair proficient cells, the early decrease in the number and intensity of gammaH2AX foci observed after a 2 Gy exposure was not associated with a significant change in the global gammaH2AX level as determined by Western blotting or flow cytometry. These results suggest that the dephosphorylation step of gammaH2AX may be limiting and that the loss of foci is mediated not only by gammaH2AX dephosphorylation but also through its redistribution towards the chromatin.
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