Combinatorial functionomics identifies HDAC6-dependent molecular vulnerability of radioresistant head and neck cancer.

IF 9.4 1区医学 Q1 HEMATOLOGY Experimental Hematology & Oncology Pub Date : 2025-01-12 DOI:10.1186/s40164-024-00590-8

Sharon Pei Yi Chan, Celestia Pei Xuan Yeo, Boon Hao Hong, Evelyn Mui Cheng Tan, Chaw Yee Beh, Eugenia Li Ling Yeo, Dennis Jun Jie Poon, Pek Lim Chu, Khee Chee Soo, Melvin Lee Kiang Chua, Edward Kai-Hua Chow

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Abstract

Background: Radiotherapy is the primary treatment modality for most head and neck cancers (HNCs). Despite the addition of chemotherapy to radiotherapy to enhance its tumoricidal effects, almost a third of HNC patients suffer from locoregional relapses. Salvage therapy options for such recurrences are limited and often suboptimal, partly owing to divergent tumor and microenvironmental factors underpinning radioresistance. In this study, we utilized a combinatorial functionomics approach, the Quadratic Phenotypic Optimization Platform (QPOP), to rationally design drug pairings that exploit the molecular fingerprint and vulnerability of established in vitro isogenic radioresistant (RR)-HNC models.

Methods: A QPOP-specific protocol was applied to RR-HNC models to rank and compare all possible drug combinations from a 12-drug set comprising standard chemotherapy, small molecule inhibitors and targeted therapies specific to HNC. Drug combination efficacy was evaluated by computing combination index scores, and by measuring apoptotic response. Drug targeting was validated by western blot analyses, and the Comet assay was used to quantify DNA damage. Enhanced histone deacetylase inhibitor (HDACi) efficacy in RR models was further examined by in vivo studies, and genetic and chemical inhibition of major Class I/II HDACs. Regulatory roles of HDAC6/SP1 axis were investigated using immunoprecipitation, gel shift and ChIP-qPCR assays. Comparative transcriptomic analyses were employed to determine the prognostic significance of targeting HDAC6.

Results: We report the therapeutic potential of combining panobinostat (pan-HDAC inhibitor) with AZD7762 (CHK1/2 inhibitor; AstraZeneca) or ionizing radiation (IR) to re-sensitize RR-HNC cells and showed increased DNA damage underlying enhanced synergy. We further refined this RR-specific drug combination and prioritized HDAC6 as a targetable dependency in reversing radioresistance. We provide mechanistic insights into HDAC6-mediated regulation via a crosstalk involving SP1 and oncogenic and repair genes. From two independent patient cohorts, we identified a four-gene signature that may have discriminative ability to predict for radioresistance and amenable to HDAC6 inhibition.

Conclusion: We have uncovered HDAC6 as a promising molecular vulnerability that should be explored to treat RR-HNC.

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组合功能鉴定hdac6依赖的放射耐药头颈癌分子易损性。

背景：放疗是大多数头颈癌（HNCs）的主要治疗方式。尽管在放疗的基础上增加化疗以增强其杀瘤效果，但近三分之一的HNC患者出现局部复发。这种复发的挽救治疗选择是有限的，而且往往是次优的，部分原因是肿瘤分化和微环境因素支持放射耐药。在这项研究中，我们利用组合函数学方法，二次型表型优化平台（QPOP），合理设计药物配对，利用已建立的体外等基因辐射耐药(RR)-HNC模型的分子指纹和脆弱性。方法：将qpop特异性方案应用于RR-HNC模型，对包括标准化疗、小分子抑制剂和HNC特异性靶向治疗在内的12种药物组合中的所有可能的药物组合进行排名和比较。通过计算联合指数得分和测定细胞凋亡反应来评价药物联合疗效。通过western blot分析验证药物靶向性，并使用Comet测定定量DNA损伤。组蛋白去乙酰化酶抑制剂（HDACi）在RR模型中的有效性通过体内研究和主要的I/II类hdac的遗传和化学抑制进一步得到验证。采用免疫沉淀、凝胶移位和ChIP-qPCR检测HDAC6/SP1轴的调控作用。采用比较转录组学分析来确定靶向HDAC6的预后意义。结果：我们报道了panobinostat （pan-HDAC抑制剂）联合AZD7762 (CHK1/2抑制剂；阿斯利康（AstraZeneca）或电离辐射（IR）对RR-HNC细胞进行再敏化，结果显示协同作用增强导致DNA损伤增加。我们进一步完善了这种rr特异性药物组合，并优先考虑HDAC6作为逆转放射耐药的靶向依赖性。我们通过SP1与致癌和修复基因的串扰，提供了hdac6介导的调控机制。从两个独立的患者队列中，我们确定了一个四基因标记，该标记可能具有预测放射耐药的判别能力，并且适合HDAC6抑制。结论：我们发现HDAC6是一个有希望的分子易感性，值得探索治疗RR-HNC。

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来源期刊

Experimental Hematology & Oncology Medicine-Oncology

CiteScore

12.60

自引率

7.30%

发文量

审稿时长

6 weeks

期刊介绍： Experimental Hematology & Oncology is an open access journal that encompasses all aspects of hematology and oncology with an emphasis on preclinical, basic, patient-oriented and translational research. The journal acts as an international platform for sharing laboratory findings in these areas and makes a deliberate effort to publish clinical trials with 'negative' results and basic science studies with provocative findings. Experimental Hematology & Oncology publishes original work, hypothesis, commentaries and timely reviews. With open access and rapid turnaround time from submission to publication, the journal strives to be a hub for disseminating new knowledge and discussing controversial topics for both basic scientists and busy clinicians in the closely related fields of hematology and oncology.