Human neural stem cells derived from fetal human brain communicate with each other and rescue ischemic neuronal cells through tunneling nanotubes.

IF 8.1 1区 生物学 Q1 CELL BIOLOGY
D L Capobianco, R De Zio, D C Profico, M Gelati, L Simone, A M D'Erchia, F Di Palma, E Mormone, P Bernardi, A Sbarbati, A Gerbino, G Pesole, A L Vescovi, M Svelto, F Pisani
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引用次数: 0

Abstract

Pre-clinical trials have demonstrated the neuroprotective effects of transplanted human neural stem cells (hNSCs) during the post-ischemic phase. However, the exact neuroprotective mechanism remains unclear. Tunneling nanotubes (TNTs) are long plasma membrane bridges that physically connect distant cells, enabling the intercellular transfer of mitochondria and contributing to post-ischemic repair processes. Whether hNSCs communicate through TNTs and their role in post-ischemic neuroprotection remains unknown. In this study, non-immortalized hNSC lines derived from fetal human brain tissues were examined to explore these possibilities and assess the post-ischemic neuroprotection potential of these hNSCs. Using Tau-STED super-resolution confocal microscopy, live cell time-lapse fluorescence microscopy, electron microscopy, and direct or non-contact homotypic co-cultures, we demonstrated that hNSCs generate nestin-positive TNTs in both 3D neurospheres and 2D cultures, through which they transfer functional mitochondria. Co-culturing hNSCs with differentiated SH-SY5Y (dSH-SY5Y) revealed heterotypic TNTs allowing mitochondrial transfer from hNSCs to dSH-SY5Y. To investigate the role of heterotypic TNTs in post-ischemic neuroprotection, dSH-SY5Y were subjected to oxygen-glucose deprivation (OGD) followed by reoxygenation (OGD/R) with or without hNSCs in direct or non-contact co-cultures. Compared to normoxia, OGD/R dSH-SY5Y became apoptotic with impaired electrical activity. When OGD/R dSH-SY5Y were co-cultured in direct contact with hNSCs, heterotypic TNTs enabled the transfer of functional mitochondria from hNSCs to OGD/R dSH-SY5Y, rescuing them from apoptosis and restoring the bioelectrical profile toward normoxic dSH-SY5Y. This complete neuroprotection did not occur in the non-contact co-culture. In summary, our data reveal the presence of a functional TNTs network containing nestin within hNSCs, demonstrate the involvement of TNTs in post-ischemic neuroprotection mediated by hNSCs, and highlight the strong efficacy of our hNSC lines in post-ischemic neuroprotection. Human neural stem cells (hNSCs) communicate with each other and rescue ischemic neurons through nestin-positive tunneling nanotubes (TNTs). A Functional mitochondria are exchanged via TNTs between hNSCs. B hNSCs transfer functional mitochondria to ischemic neurons through TNTs, rescuing neurons from ischemia/reperfusion ROS-dependent apoptosis.

Abstract Image

从胎儿人脑中提取的人类神经干细胞通过隧道纳米管相互沟通并挽救缺血的神经细胞。
临床前试验证明,移植的人类神经干细胞(hNSCs)在缺血后阶段具有神经保护作用。然而,神经保护的确切机制仍不清楚。隧道纳米管(TNTs)是一种长质膜桥,可物理连接远处的细胞,实现线粒体的细胞间转移,有助于缺血后的修复过程。hNSCs 是否通过 TNTs 进行交流及其在缺血后神经保护中的作用仍是未知数。在本研究中,研究人员研究了来源于胎儿人脑组织的非模式化 hNSCs 株系,以探索这些可能性并评估这些 hNSCs 在缺血后神经保护方面的潜力。通过使用 Tau-STED 超分辨率共聚焦显微镜、活细胞延时荧光显微镜、电子显微镜和直接或非接触同型共培养,我们证明了 hNSCs 在三维神经球和二维培养物中都能生成巢蛋白阳性的 TNT,并通过 TNT 转移功能线粒体。将 hNSCs 与分化的 SH-SY5Y(dSH-SY5Y)共培养,发现了异型 TNT,允许线粒体从 hNSCs 转移到 dSH-SY5Y。为了研究异型 TNTs 在缺血后神经保护中的作用,dSH-SY5Y 在直接或非接触共培养中与 hNSCs 一起或不与 hNSCs 一起接受氧-葡萄糖剥夺(OGD)后再氧合(OGD/R)。与常氧状态相比,OGD/R dSH-SY5Y 出现凋亡,电活动受损。当OGD/R dSH-SY5Y与hNSCs直接接触共培养时,异型TNTs能使功能线粒体从hNSCs转移到OGD/R dSH-SY5Y,使它们免于凋亡,并使生物电特征恢复到正常缺氧状态的dSH-SY5Y。这种完全的神经保护并没有发生在非接触共培养中。总之,我们的数据揭示了 hNSCs 中含有 nestin 的 TNTs 功能网络的存在,证明了 TNTs 参与了 hNSCs 介导的缺血后神经保护,并强调了我们的 hNSC 系在缺血后神经保护中的强大功效。人神经干细胞(hNSCs)通过巢蛋白阳性的隧道纳米管(TNTs)相互交流并拯救缺血神经元。A hNSCs之间通过TNTs交换功能线粒体。B hNSCs通过TNTs将功能线粒体转移到缺血神经元,拯救神经元免于缺血/再灌注ROS依赖性凋亡。
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来源期刊
Cell Death & Disease
Cell Death & Disease CELL BIOLOGY-
CiteScore
15.10
自引率
2.20%
发文量
935
审稿时长
2 months
期刊介绍: Brought to readers by the editorial team of Cell Death & Differentiation, Cell Death & Disease is an online peer-reviewed journal specializing in translational cell death research. It covers a wide range of topics in experimental and internal medicine, including cancer, immunity, neuroscience, and now cancer metabolism. Cell Death & Disease seeks to encompass the breadth of translational implications of cell death, and topics of particular concentration will include, but are not limited to, the following: Experimental medicine Cancer Immunity Internal medicine Neuroscience Cancer metabolism
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