抗辐射性
癌症研究
克隆形成试验
DNA修复
奥拉帕尼
HDAC3型
基因敲除
DNA损伤
辐射敏感性
合成致死
生物
放射增敏剂
细胞
化学
细胞培养
聚ADP核糖聚合酶
放射治疗
医学
组蛋白
遗传学
DNA
组蛋白脱乙酰基酶
内科学
聚合酶
作者
Ujas A. Patel,Mary Y. Shi,Jalal M. Kazan,Kevin C. Nixon,Xiaozhuo Ran,Sree Narayanan Nair,Olivia Huang,Lifang Song,Mansi K. Aparnathi,Michael Y. He,Mehran Bakthiari,Rehna Krishnan,Razan Hessenow,Vivek Philip,Troy Ketela,Verena Jendrossek,Razqallah Hakem,Housheng Hansen He,Robert Kridel,Benjamin H. Lok
标识
DOI:10.1158/1535-7163.mct-24-0861
摘要
Small cell lung cancer (SCLC) is an aggressive malignancy, with most patients presenting with prognostically poor extensive-stage disease. Limited progress in standard care stresses the urgent need for novel therapies. Radiotherapy offers some survival benefit for selected patients with SCLC but could be enhanced with radiosensitizers. In this study, we identify HDAC3 as a novel radiosensitizing target in SCLC using a CRISPR knockout screen and demonstrate its efficacy and mechanism. SBC5 cells were transduced with a custom EpiDrug single-guide RNA library and treated with ionizing radiation (IR) to identify radiosensitizing genes. HDAC3 emerged as a candidate and was validated through genetic knockdown and pharmacologic inhibition (RGFP966) in multiple SCLC cell lines. Both approaches enhanced radiosensitivity, as shown by cell viability (dose modification factor10 = 1.14-1.69) and clonogenic assays (dose modification factor10 = 1.16-1.41). We assessed changes in chromatin accessibility by assay for transposase-accessible chromatin using sequencing and IR-induced DNA damage and repair using γH2AX foci detection, double-strand break (DSB) repair assays, and immunoblotting of repair proteins. HDAC3-deficient cells exhibited increased chromatin accessibility, greater IR-induced DSBs, and impaired repair capacity, resulting in persistent DNA damage. This repair defect sensitized cells to PARP inhibitors, for which combining RGFP966 with olaparib or talazoparib produced additive to synergistic effects. In SCLC xenograft models, HDAC3 knockdown or RGFP966, combined with IR, achieved significant tumor growth inhibition. Collectively, we identified HDAC3 as a novel radiosensitizing target in SCLC. Its functional loss increased the generation and persistence of IR-induced DNA DSBs, effectively sensitizing SCLC cell lines and xenografts to IR, providing a potential radiosensitization strategy to treat SCLC.
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