Mechanoinduction of PTHrP/cAMP-signaling governs proteoglycan production in mesenchymal stromal cell-derived neocartilage.

IF 4.5 2区生物学 Q2 CELL BIOLOGY

Journal of Cellular Physiology Pub Date : 2024-09-05 DOI:10.1002/jcp.31430

Janine Lückgen, Solvig Diederichs, Elisabeth Raqué, Tobias Renkawitz, Wiltrud Richter, Justyna Buchert

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引用次数: 0

Abstract

Abnormal mechanical loading is one of the major risk factors for articular cartilage degeneration. Engineered mesenchymal stromal cell (MSC)-derived cartilage holds great promise for cell-based cartilage repair. However, physiological loading protocols were shown to reduce matrix synthesis of MSC-derived neocartilage in vitro and the regulators of this undesired mechanoresponse remain poorly understood. Parathyroid hormone-related protein (PTHrP) is involved in cartilage development and can affect extracellular matrix (ECM) production during MSC chondrogenesis opposingly, depending on a continuous or transient exposure. PTHrP is induced by various mechanical cues in multiple tissues and species; but whether PTHrP is regulated in response to loading of human engineered neocartilage and may affect matrix synthesis in a positive or negative manner is unknown. The aim of this study was to investigate whether dynamic loading adjusts PTHrP-signaling in human MSC-derived neocartilage and whether it regulates matrix synthesis and other factors involved in the MSC mechanoresponse. Interestingly, MSC-derived chondrocytes significantly upregulated PTHrP mRNA (PTHLH) expression along with its second messenger cAMP in response to loading in our custom-built bioreactor. Exogenous PTHrP(1-34) induced the expression of known mechanoresponse genes (FOS, FOSB, BMP6) and significantly decreased glycosaminoglycan (GAG) and collagen synthesis similar to loading. The adenylate-cyclase inhibitor MDL-12,330A rescued the load-mediated decrease in GAG synthesis, indicating a direct involvement of cAMP-signaling in the reduction of ECM production. According to COL2A1-corrected hypertrophy-associated marker expression, load and PTHrP treatment shared the ability to reduce expression of MEF2C and PTH1R. In conclusion, the data demonstrate a significant mechanoinduction of PTHLH and a negative contribution of the PTHrP-cAMP signaling axis to GAG synthesis in MSC-derived chondrocytes after loading. To improve ECM synthesis and the mechanocompetence of load-exposed neocartilage, inhibition of PTHrP activity should be considered for MSC-based cartilage regeneration strategies.

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PTHrP/cAMP信号的机制诱导控制着间充质基质细胞衍生的新软骨中蛋白多糖的产生。

异常机械负荷是导致关节软骨退化的主要风险因素之一。间充质基质细胞（MSC）衍生的工程软骨为基于细胞的软骨修复带来了巨大希望。然而，生理加载方案显示会减少间充质干细胞衍生的新软骨在体外的基质合成，而这种不良机械反应的调节因素仍然鲜为人知。甲状旁腺激素相关蛋白（PTHrP）参与软骨的发育，并可在间充质干细胞软骨形成过程中影响细胞外基质（ECM）的生成，这取决于持续或瞬时暴露。在多种组织和物种中，PTHrP 会受到各种机械线索的诱导；但 PTHrP 是否会在人体工程新软骨的加载过程中受到调节，并以积极或消极的方式影响基质合成，目前尚不清楚。本研究旨在探讨动态加载是否会调整人间叶干细胞衍生新软骨中的PTHrP信号，以及它是否会调节基质合成和间叶干细胞机械响应中涉及的其他因素。有趣的是，在我们定制的生物反应器中，间充质干细胞衍生的软骨细胞在加载过程中PTHrP mRNA（PTHLH）及其第二信使cAMP的表达明显上调。外源性 PTHrP(1-34) 能诱导已知机械反应基因（FOS、FOSB、BMP6）的表达，并能显著减少糖胺聚糖（GAG）和胶原蛋白的合成，与加载类似。腺苷酸环化酶抑制剂 MDL-12,330A 挽救了负荷介导的 GAG 合成减少，表明 cAMP 信号直接参与了 ECM 生成的减少。根据经 COL2A1 校正的肥大相关标记物的表达，负荷和 PTHrP 处理都能降低 MEF2C 和 PTH1R 的表达。总之，这些数据证明了 PTHLH 的显著机械诱导作用以及 PTHrP-cAMP 信号轴对加载后间叶干细胞衍生软骨细胞中 GAG 合成的负作用。为了改善ECM的合成和负载暴露的新软骨的机械能力，基于间充质干细胞的软骨再生策略应考虑抑制PTHrP的活性。

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.