Department of Medicine, Baylor College of Medicine, Houston, TX 77030, USA.
Department of Pediatrics, Division of Medical Genetics, Y.T. and Alice Chen Pediatric Genetics and Genomics Research Center, Duke University, Durham, NC 27710, USA.
J Hepatol. 2024 Feb;80(2):282-292. doi: 10.1016/j.jhep.2023.10.018. Epub 2023 Oct 27.
BACKGROUND & AIMS: Chronic circadian dysfunction increases the risk of non-alcoholic fatty liver disease (NAFLD)-related hepatocellular carcinoma (HCC), but the underlying mechanisms and direct relevance to human HCC have not been established. In this study, we aimed to determine whether chronic circadian dysregulation can drive NAFLD-related carcinogenesis from human hepatocytes and human HCC progression.
Chronic jet lag of mice with humanized livers induces spontaneous NAFLD-related HCCs from human hepatocytes. The clinical relevance of this model was analysed by biomarker, pathological/histological, genetic, RNA sequencing, metabolomic, and integrated bioinformatic analyses.
Circadian dysfunction induces glucose intolerance, NAFLD-associated human HCCs, and human HCC metastasis independent of diet in a humanized mouse model. The deregulated transcriptomes in necrotic-inflammatory humanized livers and HCCs bear a striking resemblance to those of human non-alcoholic steatohepatitis (NASH), cirrhosis, and HCC. Stable circadian entrainment of hosts rhythmically paces NASH and HCC transcriptomes to decrease HCC incidence and prevent HCC metastasis. Circadian disruption directly reprogrammes NASH and HCC transcriptomes to drive a rapid progression from hepatocarcinogenesis to HCC metastasis. Human hepatocyte and tumour transcripts are clearly distinguishable from mouse transcripts in non-parenchymal cells and tumour stroma, and display dynamic changes in metabolism, inflammation, angiogenesis, and oncogenic signalling in NASH, progressing to hepatocyte malignant transformation and immunosuppressive tumour stroma in HCCs. Metabolomic analysis defines specific bile acids as prognostic biomarkers that change dynamically during hepatocarcinogenesis and in response to circadian disruption at all disease stages.
Chronic circadian dysfunction is independently carcinogenic to human hepatocytes. Mice with humanized livers provide a powerful preclinical model for studying the impact of the necrotic-inflammatory liver environment and neuroendocrine circadian dysfunction on hepatocarcinogenesis and anti-HCC therapy.
Human epidemiological studies have linked chronic circadian dysfunction to increased hepatocellular carcinoma (HCC) risk, but direct evidence that circadian dysfunction is a human carcinogen has not been established. Here we show that circadian dysfunction induces non-alcoholic steatohepatitis (NASH)-related carcinogenesis from human hepatocytes in a murine humanized liver model, following the same molecular and pathologic pathways observed in human patients. The gene expression signatures of humanized HCC transcriptomes from circadian-disrupted mice closely match those of human HCC with the poorest prognostic outcomes, while those from stably circadian entrained mice match those from human HCC with the best prognostic outcomes. Our studies establish a new model for defining the mechanism of NASH-related HCC and highlight the importance of circadian biology in HCC prevention and treatment.
慢性生物钟功能障碍会增加非酒精性脂肪性肝病(NAFLD)相关肝细胞癌(HCC)的风险,但尚未确定其潜在机制及其与人类 HCC 的直接相关性。本研究旨在确定慢性生物钟失调是否会导致人类肝细胞发生 NAFLD 相关癌变以及人 HCC 的进展。
利用具有人类肝脏的小鼠的慢性时差反应诱导源自人类肝细胞的自发性 NAFLD 相关 HCC。通过生物标志物、病理/组织学、遗传、RNA 测序、代谢组学和综合生物信息学分析来分析该模型的临床相关性。
生物钟功能障碍在人源化小鼠模型中可诱导葡萄糖不耐受、NAFLD 相关 HCC 和 HCC 转移,而与饮食无关。坏死性炎症性人源化肝脏和 HCC 中的失调转录组与非酒精性脂肪性肝炎(NASH)、肝硬化和 HCC 的转录组非常相似。宿主节律性的稳定生物钟节律可使 NASH 和 HCC 转录组有节奏地发生变化,从而降低 HCC 的发生率并防止 HCC 转移。生物钟破坏可直接重编程 NASH 和 HCC 转录组,从而迅速促进从肝癌发生到 HCC 转移的发展。人肝细胞和肿瘤转录本在非实质细胞和肿瘤基质中明显可与小鼠转录本区分开来,并在 NASH 中显示出代谢、炎症、血管生成和致癌信号的动态变化,进展为 HCC 中的肝细胞恶性转化和免疫抑制性肿瘤基质。代谢组学分析确定了特定的胆汁酸作为在肝癌发生过程中动态变化并对所有疾病阶段的生物钟破坏作出反应的预后生物标志物。
慢性生物钟功能障碍对人类肝细胞具有独立的致癌性。具有人源化肝脏的小鼠为研究坏死性炎症性肝脏环境和神经内分泌生物钟功能障碍对肝癌发生和抗 HCC 治疗的影响提供了强大的临床前模型。
人类流行病学研究已将慢性生物钟功能障碍与肝细胞癌(HCC)风险增加联系起来,但尚未确定生物钟功能障碍是人类致癌物的直接证据。在这里,我们在一种啮齿动物人源化肝脏模型中表明,生物钟功能障碍会诱导非酒精性脂肪性肝炎(NASH)相关的人类肝细胞癌变,遵循与人类患者相同的分子和病理途径。来自生物钟紊乱小鼠的人源化 HCC 转录组的基因表达谱与预后最差的人类 HCC 非常匹配,而来自稳定生物钟节律的小鼠的基因表达谱则与预后最好的人类 HCC 相匹配。我们的研究建立了一种新的模型来定义 NASH 相关 HCC 的发病机制,并强调了生物钟生物学在 HCC 预防和治疗中的重要性。