皮层中间神经元发育:小Rho gtpase的作用。

IF 1 4区 生物学 Q4 DEVELOPMENTAL BIOLOGY
Zouzana Kounoupa, Domna Karagogeos
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引用次数: 2

摘要

gaba能中间神经元控制皮层兴奋/抑制平衡,与严重的神经发育障碍有关。与皮层中间神经元产生和迁移的多重信号相反,介导这些信号反应的细胞内蛋白在很大程度上是未知的。我们已经证明了Rho gtpase Rac1和3在细胞周期和形态中的独特和多样的作用,其中Rac1和Rac1/3在皮质中间神经元中被特异性地切除。在Rac1突变体中,祖细胞延迟其细胞周期退出,可能是由于G1期延长导致皮层中间神经元减少50%和皮层回路中兴奋/抑制的不平衡。这种gaba能抑制的破坏改变了成人皮层的谷氨酸能功能,这可以通过在出生后早期增强gaba能功能来逆转。此外,这种破坏扰乱了成人皮层的神经元同步。在双突变体中,额外的严重细胞骨架缺陷导致80%的中间神经元减少。这两个系都死于产后癫痫发作。我们已经在表征Rac1突变中间神经元祖细胞的细胞周期缺陷,确定单和双突变中间神经元的形态和突触特征以及通过蛋白质组学分析确定Rac1发挥作用的一些分子参与者方面取得了进展。在我们目前的工作中,我们回顾了这些研究,并讨论了开放的问题和未来的前景。我们希望我们的数据将有助于理解皮层中间神经元的功能,特别是因为基于中间神经元的细胞治疗的临床前模型正在建立。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Cortical interneuron development: a role for small Rho GTPases.

GABAergic interneurons control cortical excitation/inhibition balance and are implicated in severe neurodevelopmental disorders. In contrast to the multiplicity of signals underlying the generation and migration of cortical interneurons, the intracellular proteins mediating the response to these cues are largely unknown. We have demonstrated the unique and diverse roles of the Rho GTPases Rac1 and 3 in cell cycle and morphology in transgenic animals where Rac1 and Rac1/3 were ablated specifically in cortical interneurons. In the Rac1 mutant, progenitors delay their cell cycle exit, probably due to a prolonged G1 phase resulting in a cortex with 50% reductions in interneurons and an imbalance of excitation/inhibition in cortical circuits. This disruption in GABAergic inhibition alters glutamatergic function in the adult cortex, which could be reversed by enhancement of GABAergic functions during an early postnatal period. Furthermore, this disruption disturbs neuronal synchronization in the adult cortex. In the double mutant, additional severe cytoskeletal defects result in an 80% interneuron decrease. Both lines die postnatally from epileptic seizures. We have made progress towards characterizing the cell cycle defect in Rac1 mutant interneuron progenitors, determining the morphological and synaptic characteristics of single and double mutant interneurons and identifying some of the molecular players through which Racs exert their actions via proteomic analysis. In our present work, we review these studies and discuss open questions and future perspectives. We hope that our data will contribute to the understanding of the function of cortical interneurons, especially since preclinical models of interneuron-based cell therapies are being established.

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来源期刊
CiteScore
1.90
自引率
0.00%
发文量
16
审稿时长
2 months
期刊介绍: The International Journal of Developmental Biology (ISSN: 0214- 6282) is an independent, not for profit scholarly journal, published by scientists, for scientists. The journal publishes papers which throw light on our understanding of animal and plant developmental mechanisms in health and disease and, in particular, research which elucidates the developmental principles underlying stem cell properties and cancer. Technical, historical or theoretical approaches also fall within the scope of the journal. Criteria for acceptance include scientific excellence, novelty and quality of presentation of data and illustrations. Advantages of publishing in the journal include: rapid publication; free unlimited color reproduction; no page charges; free publication of online supplementary material; free publication of audio files (MP3 type); one-to-one personalized attention at all stages during the editorial process. An easy online submission facility and an open online access option, by means of which papers can be published without any access restrictions. In keeping with its mission, the journal offers free online subscriptions to academic institutions in developing countries.
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