William B Alexander, Wenjia Wang, Margaret A Hill, Michael R O'Dell, Luis I Ruffolo, Bing Guo, Katherine M Jackson, Nicholas Ullman, Scott C Friedland, Matthew N McCall, Ankit Patel, Nathania Figueroa-Guilliani, Mary Georger, Brian A Belt, Christa L Whitney-Miller, David C Linehan, Patrick J Murphy, Aram F Hezel
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引用次数: 0
Abstract
Cholangiocarcinoma (CCA) is a deadly and heterogeneous type of cancer characterized by a spectrum of epidemiologic associations as well as genetic and epigenetic alterations. We seek to understand how these features inter-relate in the earliest phase of cancer development and through the course of disease progression. For this, we studied murine models of liver injury integrating the most commonly occurring gene mutations of CCA - including Kras, Tp53, Arid1a and Smad4 - as well as murine hepatobiliary cancer models and derived primary cell lines based on these mutations. Among commonly mutated genes in CCA, we found that Smad4 functions uniquely to restrict reactive cholangiocyte expansion to liver injury through restraint of the proliferative response. Inactivation of Smad4 accelerates carcinogenesis, provoking pre-neoplastic biliary lesions and CCA development in an injury setting. Expression analyses of Smad4-perturbed reactive cholangiocytes and CCA lines demonstrated shared enriched pathways, including cell-cycle regulation, MYC signaling and oxidative phosphorylation, suggesting that Smad4 may act via these mechanisms to regulate cholangiocyte proliferation and progression to CCA. Overall, we showed that TGFβ/SMAD4 signaling serves as a critical barrier restraining cholangiocyte expansion and malignant transformation in states of biliary injury.
胆管癌(CCA)是一种致命的异质性癌症,具有一系列流行病学关联以及遗传和表观遗传学改变的特点。我们试图了解这些特征在癌症发展的最初阶段和疾病进展过程中是如何相互关联的。为此,我们研究了整合 CCA 最常见基因突变(包括 Kras、Tp53、Arid1a 和 Smad4)的小鼠肝损伤模型,以及小鼠肝胆癌模型和基于这些突变基因衍生的原代细胞系。在 CCA 的常见突变基因中,我们发现 Smad4 的独特功能是通过抑制增殖反应来限制反应性胆管细胞对肝损伤的扩张。Smad4失活会加速癌变,引发肿瘤前胆道病变和损伤环境中的CCA发展。对受到 Smad4 干扰的反应性胆管细胞和 CCA 株系进行的表达分析表明,细胞周期调控、MYC 信号转导和氧化磷酸化等途径具有共同的丰富性,这表明 Smad4 可能通过这些机制调节胆管细胞的增殖和向 CCA 的发展。总之,我们的研究表明,在胆道损伤状态下,TGFβ/SMAD4 信号是抑制胆管细胞扩张和恶性转化的关键屏障。
期刊介绍:
Disease Models & Mechanisms (DMM) is an online Open Access journal focusing on the use of model systems to better understand, diagnose and treat human disease.