Marangon Davide, Caporale Nicolò, Boccazzi Marta, Abbracchio Maria P, Testa Giuseppe, Lecca Davide
Laboratory of Molecular and Cellular Pharmacology of Purinergic Transmission, Department of Pharmaceutical Sciences, Università degli Studi di Milano, Milan, Italy.
Department of Oncology and Hemato-Oncology, University of Milan, Milan, Italy.
Front Cell Neurosci. 2021 Oct 14;15:748849. doi: 10.3389/fncel.2021.748849. eCollection 2021.
Myelin is the lipidic insulating structure enwrapping axons and allowing fast saltatory nerve conduction. In the central nervous system, myelin sheath is the result of the complex packaging of multilamellar extensions of oligodendrocyte (OL) membranes. Before reaching myelinating capabilities, OLs undergo a very precise program of differentiation and maturation that starts from OL precursor cells (OPCs). In the last 20 years, the biology of OPCs and their behavior under pathological conditions have been studied through several experimental models. When co-cultured with neurons, OPCs undergo terminal maturation and produce myelin tracts around axons, allowing to investigate myelination in response to exogenous stimuli in a very simple system. On the other hand, models more closely reproducing some of the features of human pathophysiology enabled to assess the consequences of demyelination and the molecular mechanisms of remyelination, and they are often used to validate the effect of pharmacological agents. However, they are very complex, and not suitable for large scale drug discovery screening. Recent advances in cell reprogramming, biophysics and bioengineering have allowed impressive improvements in the methodological approaches to study brain physiology and myelination. Rat and mouse OPCs can be replaced by human OPCs obtained by induced pluripotent stem cells (iPSCs) derived from healthy or diseased individuals, thus offering unprecedented possibilities for personalized disease modeling and treatment. OPCs and neural cells can be also artificially assembled, using 3D-printed culture chambers and biomaterial scaffolds, which allow modeling cell-to-cell interactions in a highly controlled manner. Interestingly, scaffold stiffness can be adopted to reproduce the mechanosensory properties assumed by tissues in physiological or pathological conditions. Moreover, the recent development of iPSC-derived 3D brain cultures, called organoids, has made it possible to study key aspects of embryonic brain development, such as neuronal differentiation, maturation and network formation in temporal dynamics that are inaccessible to traditional cultures. Despite the huge potential of organoids, their application to myelination studies is still in its infancy. In this review, we shall summarize the novel most relevant experimental approaches and their implications for the identification of remyelinating agents for human diseases such as multiple sclerosis.
髓磷脂是包裹轴突并允许快速跳跃式神经传导的脂质绝缘结构。在中枢神经系统中,髓鞘是少突胶质细胞(OL)膜多层延伸的复杂包装结果。在具备髓鞘形成能力之前,OL会经历一个从少突胶质前体细胞(OPC)开始的非常精确的分化和成熟程序。在过去20年中,通过多种实验模型对OPC的生物学特性及其在病理条件下的行为进行了研究。当与神经元共培养时,OPC会经历终末成熟并在轴突周围产生髓鞘束,从而能够在一个非常简单的系统中研究对外源刺激的髓鞘形成反应。另一方面,更能重现人类病理生理学某些特征的模型能够评估脱髓鞘的后果和再髓鞘化的分子机制,并且它们经常被用于验证药物制剂的效果。然而,它们非常复杂,不适合大规模药物发现筛选。细胞重编程、生物物理学和生物工程方面的最新进展使得研究脑生理学和髓鞘形成的方法有了显著改进。大鼠和小鼠的OPC可以被源自健康或患病个体的诱导多能干细胞(iPSC)获得的人类OPC所替代,从而为个性化疾病建模和治疗提供了前所未有的可能性。OPC和神经细胞也可以使用3D打印培养室和生物材料支架进行人工组装,这允许以高度可控的方式模拟细胞间相互作用。有趣的是,支架硬度可以用来重现生理或病理条件下组织所具有的机械感觉特性。此外,最近iPSC衍生的3D脑培养物(称为类器官)的发展使得研究胚胎脑发育的关键方面成为可能,例如传统培养无法触及的神经元分化、成熟和网络形成的时间动态。尽管类器官具有巨大潜力,但其在髓鞘形成研究中的应用仍处于起步阶段。在本综述中,我们将总结最新的最相关实验方法及其对鉴定用于治疗诸如多发性硬化症等人类疾病的再髓鞘化药物的意义。
