PIEZO1-dependent mode switch of neuronal migration in heterogeneous microenvironments in the developing brain.

IF 6.9 1区生物学 Q1 CELL BIOLOGY Cell reports Pub Date : 2025-03-25 Epub Date: 2025-03-06 DOI:10.1016/j.celrep.2025.115405

Naotaka Nakazawa, Gianluca Grenci, Yoshitaka Kameo, Noriko Takeda, Tsuyoshi Sawada, Junko Kurisu, Zhejing Zhang, Kenichi Toma, Taiji Adachi, Keiko Nonomura, Mineko Kengaku

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Abstract

The migration of newborn neurons is essential for brain morphogenesis and circuit formation, yet controversy exists regarding how neurons generate the driving force against strong mechanical stresses in crowded neural tissues. We found that cerebellar granule neurons employ a mechanosensing mechanism to switch the driving forces to maneuver in irregular brain tissue. In two-dimensional (2D) cultures, actomyosin is enriched in the leading process, exerting traction force on the cell soma. In tissue or 3D confinement, however, actomyosin concentrates at the posterior cell membrane, generating contractile forces that assist passage through narrow spaces, working alongside the traction force in the leading process. The 3D migration is initiated by the activation of a mechanosensitive channel, PIEZO1. PIEZO1-induced calcium influx in the soma triggers the PKC-ezrin cascade, which recruits actomyosin and transmits its contractile force to the posterior plasma membrane. Thus, migrating neurons adapt their motility modes in distinct extracellular environments in the developing brain.

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发育中的大脑中异质微环境中神经元迁移的piezo1依赖模式开关。

新生神经元的迁移对大脑形态发生和回路形成至关重要，但关于神经元如何在拥挤的神经组织中产生对抗强机械应力的驱动力存在争议。我们发现小脑颗粒神经元在不规则脑组织中采用机械传感机制来转换驱动力以进行机动。在二维（2D）培养中，肌动球蛋白在先导过程中富集，对细胞体施加牵引力。然而，在组织或三维约束中，肌动球蛋白集中在后细胞膜，产生收缩力，帮助通过狭窄的空间，在引导过程中与牵引力一起工作。三维迁移是由机械敏感通道PIEZO1的激活引发的。piezo1诱导的胞体钙内流触发PKC-ezrin级联，该级联招募肌动球蛋白并将其收缩力传递给后质膜。因此，在发育中的大脑中，迁移神经元在不同的细胞外环境中调整其运动模式。

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来源期刊

Cell reports CELL BIOLOGY-

CiteScore

13.80

自引率

1.10%

发文量

1305

审稿时长

77 days

期刊介绍： Cell Reports publishes high-quality research across the life sciences and focuses on new biological insight as its primary criterion for publication. The journal offers three primary article types: Reports, which are shorter single-point articles, research articles, which are longer and provide deeper mechanistic insights, and resources, which highlight significant technical advances or major informational datasets that contribute to biological advances. Reviews covering recent literature in emerging and active fields are also accepted. The Cell Reports Portfolio includes gold open-access journals that cover life, medical, and physical sciences, and its mission is to make cutting-edge research and methodologies available to a wide readership. The journal's professional in-house editors work closely with authors, reviewers, and the scientific advisory board, which consists of current and future leaders in their respective fields. The advisory board guides the scope, content, and quality of the journal, but editorial decisions are independently made by the in-house scientific editors of Cell Reports.