Single-cell RNA sequencing reveals the intercellular crosstalk and the regulatory landscape of stromal cells during the whole life of the mouse ovary.

IF 6 Life medicine Pub Date : 2024-12-28 eCollection Date: 2024-12-01 DOI:10.1093/lifemedi/lnae041

Wan Jiang, Wenya Sun, Yue Peng, Hao Xu, Haonan Fan, Xin Jin, Yue Xiao, Yuxiang Wang, Pin Yang, Wenjie Shu, Jing Li

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Abstract

The heterogeneity of ovarian mesenchymal/stromal cells has just been revealed in both mice and humans. However, it remains unclear about the cellular development trace and the intercellular communication network in the whole life of the ovary. In the study, we integrated ours and published single-cell RNA sequencing data from E11.5 (embryonic day 11.5) until M12 (12-month-old) ovaries to show the dynamics of somatic cells along the developmental timeline. The intercellular crosstalk among somatic cell types was depicted with collagen signaling pathway as the most outgoing signals from stromal cells. We identified mesenchymal progenitor cells (CD24⁺) as the origin of stromal cells. Although their numbers decreased significantly in adults, the cells served as the major signal sender until ovarian senescence. Moreover, the ovarian injury could activate these stem cells and induce stroma remodeling in the aged ovary. Thus, mesenchymal progenitor cells may represent a new strategy to delay ovarian aging in the future.

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单细胞RNA测序揭示了小鼠卵巢整个生命周期间质细胞的细胞间串扰和调控景观。

卵巢间充质/间质细胞的异质性刚刚在小鼠和人类中被发现。然而，卵巢整个生命周期的细胞发育轨迹和细胞间通讯网络尚不清楚。在这项研究中，我们整合并发表了从E11.5（胚胎期11.5天）到M12（12个月）卵巢的单细胞RNA测序数据，以显示体细胞沿着发育时间轴的动态变化。体细胞类型间的细胞间串扰以胶原蛋白信号通路作为基质细胞的最大输出信号来描述。我们确定间充质祖细胞（CD24+）是基质细胞的起源。尽管它们的数量在成人中显著减少，但在卵巢衰老之前，这些细胞一直是主要的信号发送者。卵巢损伤可激活这些干细胞，诱导衰老卵巢间质重塑。因此，间充质祖细胞可能是未来延缓卵巢衰老的新策略。

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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Life medicine

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