3D model for human glia conversion into subtype-specific neurons, including dopamine neurons.

IF 4.3 Q1 BIOCHEMICAL RESEARCH METHODS Cell Reports Methods Pub Date : 2024-09-16 Epub Date: 2024-09-04 DOI:10.1016/j.crmeth.2024.100845

Jessica Giacomoni, Andreas Bruzelius, Mette Habekost, Janko Kajtez, Daniella Rylander Ottosson, Alessandro Fiorenzano, Petter Storm, Malin Parmar

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Abstract

Two-dimensional neuronal cultures have a limited ability to recapitulate the in vivo environment of the brain. Here, we introduce a three-dimensional in vitro model for human glia-to-neuron conversion, surpassing the spatial and temporal constrains of two-dimensional cultures. Focused on direct conversion to induced dopamine neurons (iDANs) relevant to Parkinson disease, the model generates functionally mature iDANs in 2 weeks and allows long-term survival. As proof of concept, we use single-nucleus RNA sequencing and molecular lineage tracing during iDAN generation and find that all glial subtypes generate neurons and that conversion relies on the coordinated expression of three neural conversion factors. We also show the formation of mature and functional iDANs over time. The model facilitates molecular investigations of the conversion process to enhance understanding of conversion outcomes and offers a system for in vitro reprogramming studies aimed at advancing alternative therapeutic strategies in the diseased brain.

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人类胶质细胞转化为亚型特异性神经元（包括多巴胺神经元）的三维模型。

二维神经元培养物重现大脑体内环境的能力有限。在这里，我们介绍了一种人类胶质细胞向神经元转化的三维体外模型，它超越了二维培养的空间和时间限制。该模型侧重于直接转化为与帕金森病相关的诱导多巴胺神经元（iDANs），可在两周内生成功能成熟的 iDANs，并允许其长期存活。作为概念验证，我们在 iDAN 生成过程中使用了单核 RNA 测序和分子谱系追踪，并发现所有神经胶质亚型都能生成神经元，而且转换依赖于三种神经转换因子的协调表达。我们还展示了成熟和功能性 iDAN 的形成过程。该模型有助于对转化过程进行分子研究，从而加深对转化结果的理解，并为体外重编程研究提供了一个系统，旨在推进对患病大脑的替代治疗策略。

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