| Radial Glia | |
|---|---|
| Allen Atlas ID | CS202210140_3710 |
| Lineage | Glial > Progenitor > Radial glia |
| Markers | PAX6, NES, VIM, GLI3, BLBP (FABP7), EMX2 |
| Brain Regions | Developmental brain, Ventricular zone |
| Disease Vulnerability | Brain development disorders, Gliomas |
Radial Glia is an important component in the neurobiology of neurodegenerative diseases. This page provides detailed information about its structure, function, and role in disease processes.
Radial Glia are a specialized cell type classified within the Glial > Progenitor > Radial glia lineage. These cells are primarily found in Developmental brain, Ventricular zone and are characterized by expression of marker genes including PAX6, NES, VIM, GLI3. They are selectively vulnerable in Brain development disorders, Gliomas.
Radial Glia are identified by the expression of the following key marker genes:
These markers are used for immunohistochemical identification and single-cell RNA sequencing classification, as catalogued in the Allen Cell Type Atlas.
Radial Glia play essential roles in neural circuits and brain function. They are found in the following brain regions:
Their normal functions include maintaining neural circuit integrity, signal processing, and contributing to the homeostasis of their local microenvironment.
Radial Glia show selective vulnerability in the following neurodegenerative conditions:
The selective vulnerability of these cells is an active area of research, with factors including metabolic demands, calcium handling, exposure to toxic protein aggregates, and cell-autonomous gene expression programs contributing to their susceptibility.
Single-cell and single-nucleus RNA sequencing studies have revealed the transcriptomic signature of Radial Glia. Key differentially expressed genes from the Allen Cell Type Atlas and related datasets include the marker genes listed above. These transcriptomic profiles help identify subtypes and disease-associated gene expression changes.
The study of Radial Glia has evolved significantly over the past decades. Research in this area has revealed important insights into the underlying mechanisms of neurodegeneration and continues to drive therapeutic development.
Historical context and key discoveries in this field have shaped our current understanding and will continue to guide future research directions.
Page auto-generated from NeuroWiki cell type database. Last updated: 2026-02-26.