单细胞RNA测序揭示了骨骼祖细胞的异质性以及骨修复过程中细胞间的相互作用。
Single-cell RNA sequencing unravels heterogeneity of skeletal progenitors and cell-cell interactions underlying the bone repair process.
作者信息
Nakayama Mika, Okada Hiroyuki, Seki Masahide, Suzuki Yutaka, Chung Ung-Il, Ohba Shinsuke, Hojo Hironori
机构信息
Department of Bioengineering, Graduate School of Engineering, The University of Tokyo, Tokyo, 113-8655, Japan.
Laboratory of Clinical Biotechnology, Center for Disease Biology and Integrative Medicine, Graduate School of Medicine, The University of Tokyo, Tokyo, 113-8655, Japan.
出版信息
Regen Ther. 2022 May 18;21:9-18. doi: 10.1016/j.reth.2022.05.001. eCollection 2022 Dec.
INTRODUCTION
Activation of skeletal progenitors upon tissue injury and the subsequent cell fate specification are tightly coordinated in the bone repair process. Although known osteoimmunological signaling networks play important roles in the microenvironment of the bone defect sites, the molecular mechanism underlying the bone repair process has not been fully understood.
METHODS
To better understand the behavior of the skeletal progenitors and the heterogeneity of the cells during bone repair at the microenvironmental level, we performed a combinatorial analysis consisting of lineage tracing for skeletal progenitors using the mouse line followed by single-cell RNA sequencing (scRNA-seq) analysis using a mouse model of calvarial bone repair. To identify a therapeutic target for bone regeneration, further computational analysis was performed focusing on the identification of the cell-cell interactions, followed by pharmacological assessments with a critical-size calvarial bone defect mouse model.
RESULTS
Lineage tracing analysis showed that skeletal progenitors marked by Sox9 were activated upon bone injury and contributed to bone repair by differentiating into osteoblasts. The scRNA-seq analysis characterized heterogeneous cell populations at the bone defect sites; the computational analysis predicted a bifurcated lineage from skeletal progenitors toward osteogenic and adipogenic lineages. Chemokine C-C motif ligand 9 (Ccl9) was identified as a signaling molecule that regulates bone regeneration in the mouse model, possibly through the regulation of adipogenic differentiation at the bone defect site.
CONCLUSION
Multipotential skeletal progenitors and the direction of the cell differentiation were characterized at single cell resolution in a mouse bone repair model. The Ccl9 signaling pathway may be a key factor directing osteogenesis from the progenitors in the model and may be a therapeutic target for bone regeneration.
引言
在骨修复过程中,组织损伤时骨骼祖细胞的激活以及随后的细胞命运特化是紧密协调的。尽管已知的骨免疫信号网络在骨缺损部位的微环境中发挥重要作用,但骨修复过程的分子机制尚未完全阐明。
方法
为了在微环境水平上更好地了解骨骼祖细胞的行为以及骨修复过程中细胞的异质性,我们进行了一项组合分析,包括使用小鼠品系对骨骼祖细胞进行谱系追踪,随后使用颅骨修复小鼠模型进行单细胞RNA测序(scRNA-seq)分析。为了确定骨再生的治疗靶点,进一步进行了计算分析,重点是识别细胞间相互作用,随后使用临界大小的颅骨缺损小鼠模型进行药理学评估。
结果
谱系追踪分析表明,以Sox9标记的骨骼祖细胞在骨损伤时被激活,并通过分化为成骨细胞促进骨修复。scRNA-seq分析对骨缺损部位的异质细胞群体进行了表征;计算分析预测了从骨骼祖细胞向成骨和成脂谱系的分叉谱系。趋化因子C-C基序配体9(Ccl9)被确定为一种信号分子,它可能通过调节骨缺损部位的脂肪生成分化来调节小鼠模型中的骨再生。
结论
在小鼠骨修复模型中,以单细胞分辨率表征了多能骨骼祖细胞和细胞分化方向。Ccl9信号通路可能是该模型中指导祖细胞成骨的关键因素,并可能成为骨再生的治疗靶点。
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