Shukla Vivek, Wang Haitao, Varticovski Lyuba, Baek Songjoon, Wang Ruihong, Wu Xinwei, Echtenkamp Frank, Villa-Hernandez Frank, Prothro Katherine P, Gara Sudheer K, Zhang Mary R, Shiffka Stephanie, Raziuddin Razi, Neckers Leonard M, Linehan W Marston, Chen Haobin, Hager Gordon L, Schrump David S
Thoracic Epigenetics Section, Thoracic Surgery Branch, Center for Cancer Research, National Cancer Institute, National Institutes of Health, Bethesda, Maryland; Present Address: Division of Nonclinical Sciences (DNCS), FDA, Silver Spring, Maryland.
Thoracic Epigenetics Section, Thoracic Surgery Branch, Center for Cancer Research, National Cancer Institute, National Institutes of Health, Bethesda, Maryland.
J Thorac Oncol. 2024 Aug;19(8):1201-1217. doi: 10.1016/j.jtho.2024.03.023. Epub 2024 Apr 5.
Recent insights regarding mechanisms mediating stemness, heterogeneity, and metastatic potential of lung cancers have yet to be fully translated to effective regimens for the treatment of these malignancies. This study sought to identify novel targets for lung cancer therapy.
Transcriptomes and DNA methylomes of 14 SCLC and 10 NSCLC lines were compared with normal human small airway epithelial cells (SAECs) and induced pluripotent stem cell (iPSC) clones derived from SAEC. SCLC lines, lung iPSC (Lu-iPSC), and SAEC were further evaluated by DNase I hypersensitive site sequencing (DHS-seq). Changes in chromatin accessibility and depths of transcription factor (TF) footprints were quantified using Bivariate analysis of Genomic Footprint. Standard techniques were used to evaluate growth, tumorigenicity, and changes in transcriptomes and glucose metabolism of SCLC cells after NFIC knockdown and to evaluate NFIC expression in SCLC cells after exposure to BET inhibitors.
Considerable commonality of transcriptomes and DNA methylomes was observed between Lu-iPSC and SCLC; however, this analysis was uninformative regarding pathways unique to lung cancer. Linking results of DHS-seq to RNA sequencing enabled identification of networks not previously associated with SCLC. When combined with footprint depth, NFIC, a transcription factor not previously associated with SCLC, had the highest score of occupancy at open chromatin sites. Knockdown of NFIC impaired glucose metabolism, decreased stemness, and inhibited growth of SCLC cells in vitro and in vivo. ChIP-seq analysis identified numerous sites occupied by BRD4 in the NFIC promoter region. Knockdown of BRD4 or treatment with Bromodomain and extra-terminal domain (BET) inhibitors (BETis) markedly reduced NFIC expression in SCLC cells and SCLC PDX models. Approximately 8% of genes down-regulated by BETi treatment were repressed by NFIC knockdown in SCLC, whereas 34% of genes repressed after NFIC knockdown were also down-regulated in SCLC cells after BETi treatment.
NFIC is a key TF and possible mediator of transcriptional regulation by BET family proteins in SCLC. Our findings highlight the potential of genome-wide chromatin accessibility analysis for elucidating mechanisms of pulmonary carcinogenesis and identifying novel targets for lung cancer therapy.
关于介导肺癌干性、异质性和转移潜能的机制的最新见解尚未完全转化为治疗这些恶性肿瘤的有效方案。本研究旨在确定肺癌治疗的新靶点。
将14个小细胞肺癌(SCLC)和10个非小细胞肺癌(NSCLC)细胞系的转录组和DNA甲基化组与正常人小气道上皮细胞(SAEC)以及源自SAEC的诱导多能干细胞(iPSC)克隆进行比较。通过DNA酶I超敏位点测序(DHS-seq)对SCLC细胞系、肺iPSC(Lu-iPSC)和SAEC进行进一步评估。使用基因组足迹双变量分析对染色质可及性变化和转录因子(TF)足迹深度进行量化。采用标准技术评估NFIC敲低后SCLC细胞的生长、致瘤性以及转录组和葡萄糖代谢的变化,并评估暴露于溴结构域和额外末端结构域(BET)抑制剂后SCLC细胞中NFIC的表达。
在Lu-iPSC和SCLC之间观察到转录组和DNA甲基化组有相当大的共性;然而,该分析对于肺癌特有的通路并无信息价值。将DHS-seq结果与RNA测序相结合,能够识别出先前与SCLC无关的网络。与足迹深度相结合时,NFIC(一种先前与SCLC无关的转录因子)在开放染色质位点的占据得分最高。NFIC敲低会损害葡萄糖代谢、降低干性,并在体外和体内抑制SCLC细胞的生长。染色质免疫沉淀测序(ChIP-seq)分析确定了BRD4在NFIC启动子区域占据的多个位点。敲低BRD4或用溴结构域和额外末端结构域(BET)抑制剂(BETis)处理可显著降低SCLC细胞和SCLC患者来源的异种移植(PDX)模型中NFIC的表达。在SCLC中,约8%经BETi处理下调的基因在NFIC敲低后受到抑制,而在NFIC敲低后受到抑制的基因中,34%在SCLC细胞经BETi处理后也下调。
NFIC是SCLC中BET家族蛋白转录调控的关键TF和可能的介质。我们的研究结果突出了全基因组染色质可及性分析在阐明肺癌发生机制和确定肺癌治疗新靶点方面的潜力。
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