Yanzhi Liu , Rui Lin , Haiping Fang , Lixian Li, Min Zhang, Lujiao Lu, Xiang Gao, Jintong Song, Jinsong Wei, Qixian Xiao, Fucheng Zhang, Kefeng Wu, Liao Cui
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CCK-8 assays, Alcian blue staining, RT-qPCR and Western blotting were used to verify the chondrogenesis of SP <em>in vitro</em>. To assess the efficacy of SP <em>in vivo</em>, surgically induced medial meniscus destabilization (DMM) OA rats underwent an 8-week SP treatment. The therapeutic effects of SP in OA rats were comprehensively evaluated using X-ray imaging, micro-computed tomography (μ-CT), histopathological analysis, as well as immunohistochemical and immunofluorescent staining. Following these assessments, we delved into the potential signaling pathways of SP in inflammatory chondrocytes utilizing RNA-seq analysis. Validation of these findings was conducted through RT-qPCR and western blotting techniques.</p></div><div><h3>Results</h3><p>SP significantly enhance the viability of C28 chondrocytes, and increased the secretion of acidic glycoproteins. Moreover, SP stimulated the expression of chondrogenic genes (<em>Aggrecan</em>, <em>Sox9</em>, <em>Col2a1</em>) and facilitated the synthesis of Collagen II protein in C28 inflammatory chondrocytes. <em>In vivo</em> experiments revealed that SP markedly ameliorated knee joint stenosis, alleviated bone and cartilage injuries, and reduced the histopathological scores in the OA rats. μ-CT analysis confirmed that SP lessened bone impairments in the medial femoral condyle and the subchondral bone of the tibial plateau, significantly improving the microarchitectural parameters of the subchondral bone. Histopathological analyses indicated that SP notably enhanced cartilage quality on the surface of the tibial plateau, leading to increased cartilage thickness and area. Immunohistochemistry staining and immunofluorescence staining corroborated these findings by showing a significant promotion of Collagen II expression in OA joints treated with SP. RNA-seq analysis suggest that SP's effects were mediated through the regulation of the ITGβ1-PI3K-AKT signaling axis, thereby stimulating chondrogenesis. Verification through RT-qPCR and Western blot analyses confirmed that SP significantly upregulated the expression of ITGβ1, p110δ, AKT1, ACAN, and Col2a1. Notably, knock-down of ITGβ1 using siRNA in C28 chondrocytes inhibited the expression of ITGβ1, p110δ, AKT1, and ACAN. However, these inhibitory effects were not completely reversed by supplemental SP intervention.</p></div><div><h3>Conclusions</h3><p>In summary, our findings reveal that SP significantly enhances chondrogenesis both <em>in vitro</em> and <em>in vivo</em>, alleviating OA progression both in bone and cartilage. The observed beneficial effects are intricately linked to the activation of the ITGβ1-PI3K-AKT signaling axis.</p></div><div><h3>The translational potential of this article</h3><p>Our research marks the first instance unveiling the advantageous effects and underlying mechanisms of SP in OA treatment. 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Following these assessments, we delved into the potential signaling pathways of SP in inflammatory chondrocytes utilizing RNA-seq analysis. Validation of these findings was conducted through RT-qPCR and western blotting techniques.</p></div><div><h3>Results</h3><p>SP significantly enhance the viability of C28 chondrocytes, and increased the secretion of acidic glycoproteins. Moreover, SP stimulated the expression of chondrogenic genes (<em>Aggrecan</em>, <em>Sox9</em>, <em>Col2a1</em>) and facilitated the synthesis of Collagen II protein in C28 inflammatory chondrocytes. <em>In vivo</em> experiments revealed that SP markedly ameliorated knee joint stenosis, alleviated bone and cartilage injuries, and reduced the histopathological scores in the OA rats. μ-CT analysis confirmed that SP lessened bone impairments in the medial femoral condyle and the subchondral bone of the tibial plateau, significantly improving the microarchitectural parameters of the subchondral bone. Histopathological analyses indicated that SP notably enhanced cartilage quality on the surface of the tibial plateau, leading to increased cartilage thickness and area. Immunohistochemistry staining and immunofluorescence staining corroborated these findings by showing a significant promotion of Collagen II expression in OA joints treated with SP. RNA-seq analysis suggest that SP's effects were mediated through the regulation of the ITGβ1-PI3K-AKT signaling axis, thereby stimulating chondrogenesis. Verification through RT-qPCR and Western blot analyses confirmed that SP significantly upregulated the expression of ITGβ1, p110δ, AKT1, ACAN, and Col2a1. Notably, knock-down of ITGβ1 using siRNA in C28 chondrocytes inhibited the expression of ITGβ1, p110δ, AKT1, and ACAN. 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引用次数: 0
摘要
背景骨关节炎(OA)是一项艰巨的挑战,其特点是软骨内错综复杂的机械结构和骨平衡失调。我们的初步数据显示,马尾藻多糖(SP)在促进软骨生成方面具有令人鼓舞的潜力。我们研究的目的是全面评估马尾藻多糖对 OA 模型的治疗效果,并进一步阐明其潜在机制。方法首先在炎症诱导的人软骨细胞(C28)模型中评估马尾藻多糖的保护作用。方法首先在炎症诱导的人软骨细胞(C28)模型中评估了SP的保护作用,并使用CCK-8测定、阿尔西恩蓝染色、RT-qPCR和Western印迹法验证了SP在体外的软骨生成作用。为了评估SP在体内的疗效,对手术诱导的内侧半月板失稳(DMM)OA大鼠进行了为期8周的SP治疗。我们使用 X 射线成像、微型计算机断层扫描(μ-CT)、组织病理学分析以及免疫组织化学和免疫荧光染色对 SP 对 OA 大鼠的治疗效果进行了全面评估。在这些评估之后,我们利用 RNA-seq 分析深入研究了 SP 在炎性软骨细胞中的潜在信号通路。结果 SP 显著提高了 C28 软骨细胞的活力,并增加了酸性糖蛋白的分泌。此外,SP 还能刺激 C28 炎性软骨细胞中软骨生成基因(Aggrecan、Sox9、Col2a1)的表达,促进胶原蛋白 II 的合成。μ-CT分析证实,SP减轻了股骨内侧髁和胫骨平台软骨下骨的骨损伤,显著改善了软骨下骨的微结构参数。组织病理学分析表明,SP 显著提高了胫骨平台表面软骨的质量,增加了软骨的厚度和面积。免疫组化染色和免疫荧光染色也证实了这些发现,显示在使用 SP 治疗的 OA 关节中,胶原蛋白 II 的表达明显增加。RNA-seq分析表明,SP的作用是通过调节ITGβ1-PI3K-AKT信号轴介导的,从而刺激软骨生成。RT-qPCR 和 Western 印迹分析证实,SP 能显著上调 ITGβ1、p110δ、AKT1、ACAN 和 Col2a1 的表达。值得注意的是,在 C28 软骨细胞中使用 siRNA 敲除 ITGβ1,可抑制 ITGβ1、p110δ、AKT1 和 ACAN 的表达。总之,我们的研究结果表明,SP 能显著增强体外和体内的软骨生成,缓解骨和软骨中的 OA 进展。我们的研究首次揭示了 SP 在治疗 OA 中的优势作用和潜在机制。SP的临床前景为下一代多糖类药物治疗OA提供了令人信服的新证据。
Sargassum polysaccharide attenuates osteoarthritis in rats and is associated with the up-regulation of the ITGβ1-PI3K-AKT signaling pathway
Background
Osteoarthritis (OA) presents a formidable challenge, characterized by as-yet-unclear mechanical intricacies within cartilage and the dysregulation of bone homeostasis. Our preliminary data revealed the encouraging potential of a Sargassum polysaccharide (SP), in promoting chondrogenesis. The aim of our study is to comprehensively assess the therapeutic effects of SP on OA models and further elucidate its potential mechanism.
Methods
The protective effects of SP were initially evaluated in an inflammation-induced human chondrocyte (C28) cell model. CCK-8 assays, Alcian blue staining, RT-qPCR and Western blotting were used to verify the chondrogenesis of SP in vitro. To assess the efficacy of SP in vivo, surgically induced medial meniscus destabilization (DMM) OA rats underwent an 8-week SP treatment. The therapeutic effects of SP in OA rats were comprehensively evaluated using X-ray imaging, micro-computed tomography (μ-CT), histopathological analysis, as well as immunohistochemical and immunofluorescent staining. Following these assessments, we delved into the potential signaling pathways of SP in inflammatory chondrocytes utilizing RNA-seq analysis. Validation of these findings was conducted through RT-qPCR and western blotting techniques.
Results
SP significantly enhance the viability of C28 chondrocytes, and increased the secretion of acidic glycoproteins. Moreover, SP stimulated the expression of chondrogenic genes (Aggrecan, Sox9, Col2a1) and facilitated the synthesis of Collagen II protein in C28 inflammatory chondrocytes. In vivo experiments revealed that SP markedly ameliorated knee joint stenosis, alleviated bone and cartilage injuries, and reduced the histopathological scores in the OA rats. μ-CT analysis confirmed that SP lessened bone impairments in the medial femoral condyle and the subchondral bone of the tibial plateau, significantly improving the microarchitectural parameters of the subchondral bone. Histopathological analyses indicated that SP notably enhanced cartilage quality on the surface of the tibial plateau, leading to increased cartilage thickness and area. Immunohistochemistry staining and immunofluorescence staining corroborated these findings by showing a significant promotion of Collagen II expression in OA joints treated with SP. RNA-seq analysis suggest that SP's effects were mediated through the regulation of the ITGβ1-PI3K-AKT signaling axis, thereby stimulating chondrogenesis. Verification through RT-qPCR and Western blot analyses confirmed that SP significantly upregulated the expression of ITGβ1, p110δ, AKT1, ACAN, and Col2a1. Notably, knock-down of ITGβ1 using siRNA in C28 chondrocytes inhibited the expression of ITGβ1, p110δ, AKT1, and ACAN. However, these inhibitory effects were not completely reversed by supplemental SP intervention.
Conclusions
In summary, our findings reveal that SP significantly enhances chondrogenesis both in vitro and in vivo, alleviating OA progression both in bone and cartilage. The observed beneficial effects are intricately linked to the activation of the ITGβ1-PI3K-AKT signaling axis.
The translational potential of this article
Our research marks the first instance unveiling the advantageous effects and underlying mechanisms of SP in OA treatment. With its clinical prospects, SP presents compelling new evidence for the advancement of a next-generation polysaccharide drug for OA therapy.
期刊介绍:
The Journal of Orthopaedic Translation (JOT) is the official peer-reviewed, open access journal of the Chinese Speaking Orthopaedic Society (CSOS) and the International Chinese Musculoskeletal Research Society (ICMRS). It is published quarterly, in January, April, July and October, by Elsevier.