SPP1 in Notochord Cells Modulates Intervertebral Disc Degeneration Through CD44 Recognition by Macrophages Based on Single Cell Transcriptome Analysis.

IF 10.1 2区医学 Q1 SURGERY

International journal of surgery Pub Date : 2025-10-09 DOI:10.1097/JS9.0000000000003454

Qiuwei Li, Peilin Jin, Chenhao Zhao, Renjie Zhang, Cailiang Shen

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引用次数: 0

Abstract

Background: Intervertebral disc degeneration (IVDD) is a major cause of spinal disorders, often leading to chronic pain and mobility issues. Mechanical stress is a key factor in IVDD progression, but the underlying mechanisms remain unclear. In this study, we improved a rat intervertebral disc pressure model to explore how mechanical stress affects IVDD, focusing on notochord cell populations and their interactions in the degenerative process.

Methods: We developed a custom pressure device for rats, validated using imaging techniques. Following pressure application, single-cell transcriptomics was employed to analyze dynamic changes in notochord cells in both surgical and sham groups. Gene expression profiles were analyzed for immune regulation, matrix metabolism, and intercellular signaling. We also studied the SPP1 signaling pathway and its interaction with CD44.Finally, we combined Mendelian randomization(MR) and human GEO sequencing data to support our results.

Results: Pressure application resulted in significant structural damage and abnormal changes in matrix components, worsening over time. Single-cell analysis revealed differences in notochord cell populations between surgical and sham groups, with increased immune regulation and matrix metabolism activity. The SPP1-CD44 signaling pathway was activated in degenerated discs, especially in CD44-expressing cells, underscoring its role in matrix remodeling and inflammation.MR and human GEO sequencing data also support these ideas.

Conclusion: This study provides insights into IVDD mechanisms, focusing on the role of the SPP1-CD44 pathway in disc degeneration. We suggest that targeting this pathway may offer potential therapeutic strategies for degenerative spinal diseases.

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基于单细胞转录组分析的脊索细胞SPP1通过巨噬细胞识别CD44调控椎间盘退变

背景：椎间盘退变（IVDD）是脊柱疾病的主要原因，常导致慢性疼痛和活动问题。机械应力是IVDD进展的关键因素，但潜在的机制尚不清楚。在这项研究中，我们改进了大鼠椎间盘压力模型，以探索机械应力如何影响IVDD，重点关注脊索细胞群及其在退行性过程中的相互作用。方法：我们开发了一种定制的大鼠压力装置，并使用成像技术进行验证。施加压力后，采用单细胞转录组学分析手术组和假手术组脊索细胞的动态变化。分析了免疫调节、基质代谢和细胞间信号的基因表达谱。我们还研究了SPP1信号通路及其与CD44的相互作用。最后，我们结合孟德尔随机化（MR）和人类GEO测序数据来支持我们的结果。结果：压力作用导致了明显的结构损伤和基质成分的异常变化，并随着时间的推移而恶化。单细胞分析显示，手术组和假手术组脊索细胞群存在差异，免疫调节和基质代谢活性增加。SPP1-CD44信号通路在退变椎间盘中被激活，特别是在表达cd44的细胞中，强调其在基质重塑和炎症中的作用。MR和人类GEO测序数据也支持这些观点。结论：本研究提供了IVDD机制的见解，重点关注SPP1-CD44通路在椎间盘退变中的作用。我们认为，靶向这一途径可能为退行性脊柱疾病提供潜在的治疗策略。

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

International journal of surgery SURGERY-

CiteScore

17.70

自引率

3.30%

发文量

审稿时长

6-12 weeks

期刊介绍： The International Journal of Surgery (IJS) has a broad scope, encompassing all surgical specialties. Its primary objective is to facilitate the exchange of crucial ideas and lines of thought between and across these specialties.By doing so, the journal aims to counter the growing trend of increasing sub-specialization, which can result in "tunnel-vision" and the isolation of significant surgical advancements within specific specialties.