Shaking culture attenuates circadian rhythms in induced pluripotent stem cells during osteogenic differentiation through the TEAD-Fbxl3-CRY axis.

IF 6.1 2区生物学 Q1 CELL BIOLOGY

Cell Death Discovery Pub Date : 2025-05-24 DOI:10.1038/s41420-025-02533-6

Yunyu Fu, Hiroko Okawa, Naruephorn Vinaikosol, Satomi Mori, Phoonsuk Limraksasin, Praphawi Nattasit, Yu Tahara, Hiroshi Egusa

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Abstract

Circadian rhythms, which synchronize cellular and organismal activities with the Earth's 24-hour light-dark cycle, are controlled by clock genes. These genes not only regulate metabolic and physiological processes but also influence osteogenesis. Despite extensive research on the genetic control of circadian rhythms, little is known about the mechanisms by which mechanical factors in the extracellular environment affect these rhythms during the osteogenic differentiation of induced pluripotent stem cells (iPSCs). Shaking culture, which promotes the formation of three-dimensional organoid-like constructs from iPSC embryoid bodies (iPSC-EBs), introduces distinct biomechanical forces compared with static adherent culture. This raises the question of how these forces affect the circadian gene expression during osteogenic differentiation. In this study, we investigated the effects of shaking cultures on the circadian rhythm of key clock genes (Clock, Bmal1, and Npas2) in iPSC-EBs. In the adherent culture, iPSC-EBs displayed rhythmic oscillations of the clock genes, which were attenuated in the shaking culture. RNA-seq analysis revealed that the yes-associated protein (YAP)-transcriptional enhanced associate domain (TEAD) transcriptional cascade was activated in the shaking culture. Further investigations using assay for transposase-accessible chromatin with sequencing and chromatin immunoprecipitation assays identified Fbxl3 as a direct target of this transcriptional cascade. Fbxl3 upregulation in the shaking culture enhanced the degradation of CRY proteins, which are essential components of the circadian feedback loop, thereby suppressing clock gene oscillations. In addition, treatment with verteporfin, a YAP-TEAD inhibitor, restored circadian gene oscillations and increased the expression of osteogenic markers in shaking culture. These findings highlight a novel mechanistic link between biomechanical cues and circadian regulation and offer potential insights for optimizing tissue engineering strategies in regenerative medicine.

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振荡培养通过tead - fbx13 - cry轴减弱诱导多能干细胞成骨分化过程中的昼夜节律。

昼夜节律是由生物钟基因控制的，它使细胞和有机体的活动与地球24小时的昼夜循环同步。这些基因不仅调节代谢和生理过程，而且影响成骨。尽管对昼夜节律的遗传控制进行了广泛的研究，但对细胞外环境中的机械因素在诱导多能干细胞（iPSCs）成骨分化过程中影响这些节律的机制知之甚少。与静态贴壁培养相比，振荡培养促进了iPSC胚状体（iPSC- ebs）三维类器官结构的形成，引入了不同的生物力学力。这就提出了在成骨分化过程中这些力量如何影响昼夜节律基因表达的问题。在这项研究中，我们研究了摇培养对iPSC-EBs关键时钟基因（clock， Bmal1和Npas2）昼夜节律的影响。在贴壁培养中，iPSC-EBs显示时钟基因的节律振荡，在摇壁培养中减弱。RNA-seq分析显示，在摇培养中，yes-associated protein (YAP)-transcriptional enhanced associate domain （TEAD）转录级联被激活。进一步的研究使用转座酶可及的染色质测序和染色质免疫沉淀试验确定Fbxl3是该转录级联的直接靶点。振荡培养中Fbxl3的上调增强了CRY蛋白的降解，而CRY蛋白是昼夜节律反馈回路的重要组成部分，从而抑制了时钟基因的振荡。此外，用一种YAP-TEAD抑制剂维替波芬治疗，恢复了昼夜节律基因振荡，并增加了摇晃培养中成骨标志物的表达。这些发现强调了生物力学线索和昼夜节律调节之间的一种新的机制联系，并为优化再生医学中的组织工程策略提供了潜在的见解。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Cell Death Discovery Biochemistry, Genetics and Molecular Biology-Cell Biology

CiteScore

8.30

自引率

1.40%

发文量

468

审稿时长

9 weeks

期刊介绍： Cell Death Discovery is a multidisciplinary, international, online-only, open access journal, dedicated to publishing research at the intersection of medicine with biochemistry, pharmacology, immunology, cell biology and cell death, provided it is scientifically sound. The unrestricted access to research findings in Cell Death Discovery will foster a dynamic and highly productive dialogue between basic scientists and clinicians, as well as researchers in industry with a focus on cancer, neurobiology and inflammation research. As an official journal of the Cell Death Differentiation Association (ADMC), Cell Death Discovery will build upon the success of Cell Death & Differentiation and Cell Death & Disease in publishing important peer-reviewed original research, timely reviews and editorial commentary. Cell Death Discovery is committed to increasing the reproducibility of research. To this end, in conjunction with its sister journals Cell Death & Differentiation and Cell Death & Disease, Cell Death Discovery provides a unique forum for scientists as well as clinicians and members of the pharmaceutical and biotechnical industry. It is committed to the rapid publication of high quality original papers that relate to these subjects, together with topical, usually solicited, reviews, editorial correspondence and occasional commentaries on controversial and scientifically informative issues.