Rh3R Attenuates RANKL-Induced Osteoclast Differentiation and F-Actin Ring Formation via the Suppression of c-Fos/NFATc1 Signaling in Primary Murine Cells.

IF 4 2区生物学 Q2 CELL BIOLOGY

Journal of Cellular Physiology Pub Date : 2026-04-01 DOI:10.1002/jcp.70174

Hyung-Mun Yun, Soo Hyun Kim, Joonyeop Lee, Kyung-Ran Park

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引用次数: 0

Abstract

The homeostatic balance of bone remodeling is governed by the precise coordination between bone-forming osteoblasts and bone-resorbing osteoclasts. In this study, we investigated the anti-resorptive properties of rhamnocitrin-3-rhamnoside (Rh3R), a flavonoid isolated from Loranthus tanakae, using primary bone marrow-derived macrophages (BMMs) and calvaria-derived osteogenic progenitor cells (COCs) to ensure biological relevance. Our findings demonstrate that Rh3R potently inhibits the RANKL-induced differentiation of BMMs into TRAP-positive multinucleated osteoclasts in a dose-dependent manner, without inducing cytotoxicity. Mechanistically, Rh3R effectively attenuates RANKL-induced downstream signaling cascades, as evidenced by the attenuated phosphorylation of MAPKs (ERK1/2, JNK, p38), AKT, and IκB. This signaling blockade subsequently suppresses the induction of the master transcription factors, c-Fos and NFATc1. Furthermore, Rh3R impairs the functional resorptive capacity of mature osteoclasts by destabilizing F-actin-rich ring structures accompanied by decreased integrin β3 expression, thereby preventing the formation of a functional sealing zone. The inhibitory effect of Rh3R on bone-degrading activity was further confirmed by a significant reduction in the total area of resorption pits on bone slices. Notably, Rh3R exhibits a lineage-specific inhibitory effect, showing no adverse influence on osteoblastogenesis or the mineralizing capacity of primary osteogenic cells. Furthermore, the effect of Rh3R was consistently maintained in a co-culture system of primary osteoblasts and BMMs. Collectively, these in vitro findings identify Rh3R as a bioactive modulator of osteoclast differentiation and function via suppression of RANKL-induced downstream signaling, warranting future in vivo and pharmacological studies to evaluate efficacy, exposure, and safety.

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Rh3R通过抑制原代小鼠细胞中的c-Fos/NFATc1信号通路，减弱rankl诱导的破骨细胞分化和F-Actin环的形成。

骨重塑的稳态平衡是由成骨细胞和骨吸收破骨细胞之间的精确协调所控制的。在这项研究中，我们研究了鼠李糖素-3-鼠李糖苷（Rh3R）的抗吸收特性，这是一种从牡丹中分离出来的类黄酮，利用原代骨髓源性巨噬细胞（BMMs）和颅骨源性成骨祖细胞（COCs）来确保生物学相关性。我们的研究结果表明，Rh3R以剂量依赖的方式有效抑制rankl诱导的BMMs向trap阳性多核破骨细胞的分化，而不诱导细胞毒性。在机制上，Rh3R有效地减弱了rankl诱导的下游信号级联反应，如MAPKs (ERK1/2， JNK, p38)， AKT和i - κ b的磷酸化减弱。这种信号阻断随后抑制主转录因子c-Fos和NFATc1的诱导。此外，Rh3R破坏了成熟破骨细胞的功能吸收能力，破坏了富含f -actin的环结构，同时降低了整合素β3的表达，从而阻止了功能密封区的形成。Rh3R对骨降解活性的抑制作用进一步被骨片上吸收坑总面积的显著减少所证实。值得注意的是，Rh3R表现出谱系特异性抑制作用，对成骨细胞的形成或原代成骨细胞的矿化能力没有不利影响。此外，Rh3R的作用在原代成骨细胞和bmp的共培养系统中一直保持不变。总的来说，这些体外研究结果表明，Rh3R是一种生物活性调节剂，通过抑制rankl诱导的下游信号传导来调节破骨细胞的分化和功能，这为未来的体内和药理学研究提供了依据，以评估其功效、暴露和安全性。

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

Journal of Cellular Physiology 生物-生理学

CiteScore

14.70

自引率

0.00%

发文量

256

审稿时长

1 months

期刊介绍： The Journal of Cellular Physiology publishes reports of high biological significance in areas of eukaryotic cell biology and physiology, focusing on those articles that adopt a molecular mechanistic approach to investigate cell structure and function. There is appreciation for the application of cellular, biochemical, molecular and in vivo genetic approaches, as well as the power of genomics, proteomics, bioinformatics and systems biology. In particular, the Journal encourages submission of high-interest papers investigating the genetic and epigenetic regulation of proliferation and phenotype as well as cell fate and lineage commitment by growth factors, cytokines and their cognate receptors and signal transduction pathways that influence the expression, integration and activities of these physiological mediators. Similarly, the Journal encourages submission of manuscripts exploring the regulation of growth and differentiation by cell adhesion molecules in addition to the interplay between these processes and those induced by growth factors and cytokines. Studies on the genes and processes that regulate cell cycle progression and phase transition in eukaryotic cells, and the mechanisms that determine whether cells enter quiescence, proliferate or undergo apoptosis are also welcomed. Submission of papers that address contributions of the extracellular matrix to cellular phenotypes and physiological control as well as regulatory mechanisms governing fertilization, embryogenesis, gametogenesis, cell fate, lineage commitment, differentiation, development and dynamic parameters of cell motility are encouraged. Finally, the investigation of stem cells and changes that differentiate cancer cells from normal cells including studies on the properties and functions of oncogenes and tumor suppressor genes will remain as one of the major interests of the Journal.