Cells and Signaling in Oligodendrocyte Development

JNEN: Journal of Neuropathology & Experimental Neurology Pub Date : 2002-04-01 DOI:10.1093/JNEN/61.4.297

J. Grinspan

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引用次数: 58

Abstract

The myelin-synthesizing oligodendrocyte is compromised in many neuropathological diseases, including demyelinating diseases (e.g. multiple sclerosis), metabolic diseases (e.g. Pelizaeus-Merzbacher), infectious diseases (e.g. progressive multifocal leukoencephalopathy), neurodegenerative diseases (e.g. multisystem degeneration), and possibly neoplasms (e.g. oligodendrogliomas). Understanding the development of the oligodendrocyte has important implications for both the pathogenesis of these diseases and also potential therapy. Over the past 20 yr, research in oligodendrocyte development has delineated a pathway from progenitors to mature oligodendrocytes. In fact, the oligodendrocyte has served as a model for lineage development in part due to the identification of specific phenotypic stages during maturation. From this has come the identification of numerous signaling molecules that instruct oligodendrocyte development. More recently, transgenic and targeted mutagenesis studies have begun to identify new factors involved in oligodendrocyte development and have questioned some of the older observations. This review will attempt to update the current state of research on the progression of the oligodendrocyte lineage. Oligodendrocytes develop from proliferating precursor cells migrating out of germinal zones in the brain and spinal cord. When the cells reach their final destination in the brain parenchyma, they become postmitotic, extend processes, and begin to synthesize the components of myelin as extensions of their plasma membranes. In most animals, this occurs relatively late in CNS development during late embryonic and early postnatal life, after neurons and astrocytes are formed. This myelin forms an insulating sheath around axons, serving dual functions in the nervous system. Historically, myelin was recognized as critical because it facilitates rapid propagation of nervous impulses through very small spaces, thus permitting axons to be of small caliber (1). More recently, myelin has been found to modulate axonal structure and support axonal integrity, as well (2). The oligodendrocyte has become a model CNS cell type for the study of lineage development due …

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少突胶质细胞发育中的细胞和信号传导

髓磷脂合成少突胶质细胞在许多神经病理疾病中受损，包括脱髓鞘疾病(如多发性硬化症)、代谢性疾病(如Pelizaeus-Merzbacher)、感染性疾病(如进行性多灶性白质脑病)、神经退行性疾病(如多系统变性)，以及可能的肿瘤(如少突胶质细胞瘤)。了解少突胶质细胞的发育对这些疾病的发病机制和潜在的治疗具有重要意义。在过去的20年里，对少突胶质细胞发育的研究已经描绘了一条从祖细胞到成熟少突胶质细胞的途径。事实上，少突胶质细胞已经成为谱系发育的模型，部分原因是成熟过程中特定表型阶段的鉴定。由此发现了许多指示少突胶质细胞发育的信号分子。最近，转基因和靶向诱变研究已经开始确定参与少突胶质细胞发育的新因素，并对一些旧的观察结果提出了质疑。本文将对目前关于少突胶质细胞谱系进展的研究现状进行综述。少突胶质细胞是由增殖的前体细胞从脑和脊髓的生发区迁移而来的。当细胞到达最终目的地脑实质时，它们进入有丝分裂后，扩展过程，并开始合成髓磷脂成分作为其质膜的延伸。在大多数动物中，这发生在相对较晚的中枢神经系统发育阶段，即胚胎晚期和出生后早期，即神经元和星形胶质细胞形成之后。髓磷脂在轴突周围形成绝缘鞘，在神经系统中起双重作用。从历史上看，髓磷脂被认为是至关重要的，因为它促进神经冲动通过非常小的空间快速传播，从而允许轴突具有小直径(1)。最近，髓磷脂被发现调节轴突结构并支持轴突完整性(2)。由于…

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JNEN: Journal of Neuropathology & Experimental Neurology

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