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Radial glial cell

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Title: Radial glial cell  
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Subject: Nervous tissue, Glial cells, Telencephalization, Intrinsically photosensitive retinal ganglion cells, Nervous tissue/sandbox
Collection: Developmental Neuroscience, Glial Cells, Neurobiology
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Radial glial cell

Radial glial cell
G-CSF receptor expression clearly delineates cells of radial glia in the embryonic murine brain. From Kirsch et al., 2008.[1]
Latin gliocytus radialis
Code TH H3.
Anatomical terminology

Radial glial cells are bipolar-shaped cells that span the width of the cortex in the developing central nervous system (CNS) and serve as primary progenitors capable of generating neurons, astrocytes, and oligodendrocytes. During development, newborn neurons use radial glia as scaffolds, traveling along the radial glial fibers in order to reach their final destinations.[2][3] Despite the various possible fates of the radial glial population, it has been demonstrated through clonal analysis that most radial glia have restricted, unipotent or multipotent, fates. Radial glia can be found during the neurogenic phase in all vertebrates (studied to date).[4]

The term "radial glia" refers to the morphological characteristics of these cells that were first observed: namely, their radial processes and their similarity to astrocytes, another member of the glial cell family.[5]


  • Discovery 1
  • Origin 2
  • Functions 3
    • Progenitors 3.1
    • Migration Pattern 3.2
    • Compartmentalization 3.3
  • Radial glial subtypes 4
    • Müller glia 4.1
    • Bergmann glia 4.2
  • Radial glia and disease 5
  • See also 6
  • References 7


Camillo Golgi, using his silver staining technique (later deemed the Golgi method), first described radially oriented cells spanning from the central canal to the outer surface of the embryonic chick spinal cord, in 1885.[6]

Using the Golgi method, Giuseppe Magini then studied the mammalian fetal cerebral cortex in 1888, confirming the similar presence of elongated radial cells in the cortex (also described by Kölliker just before him), and observing “various varicosities or swellings” on the radial fibers. Intrigued, Magini also observed that the size and number of these varicosities increased later in development, and were absent in the adult nervous system. Based on these findings, Magini then hypothesized that these varicosities could be developing neurons. Using a combination Golgi and hematoxylin staining method, Magini was able to identify these varicosities as cells, some of which were very closely associated with the radial fibers.[6]

Additional early works that were important in elucidating the identity and function of radial glia, were completed by Ramón y Cajal, who first suggested that the radial cells were a type of glia through their similarities to astrocytes;[5] and Wilhelm His, who also proposed the idea that growing axons may use radial cells for orientation and guidance during development.[6]

Despite the initial period of interest in radial glia, little addition information was learned about these cells until the electron microscope and immunohistochemistry became available some 60 years later.[6]


Radial glial cells originate from the transformation of neuroepithelial cells that form the neural plate during the early phases of pre-natal neurogenesis.[5][7] This process is mediated through the down-regulation of epithelium-related protein expression (such as tight junctions) and an up-regulation of glial-specific features such as glycogen granules, the astrocyte glutamate transporter (GLAST), the intermediate filament vimentin, and, in some instances, including humans, glial fibrillary acidic protein (GFAP).[4]

After this transition, radial glia retain many of the original characteristics of neuroepithelial cells including: their apical-basal polarity, their position along the lateral ventricles of the developing cortex, and the phasic migration of their nuclei depending on their location with the cell cycle (termed “interkinetic nuclear migration”).[7][8]



Interneuron-radial glial interactions in the developing cerebral cortex

Radial glia are now recognized as key progenitor cells in the developing nervous system. During the late stages of neurogenesis, radial glial cells divide asymmetrically in the ventricular zone, generating a new radial glial cell, as well as a postmitotic neuron or an intermediate progenitor (IPC) daughter cell. Intermediate progenitor cells then divide symmetrically in the subventricular zone to generate neurons.[8] Local environmental cues such as Notch and fibroblast growth factor (FGF) signaling, developmental period, and differing abilities of radial glia to respond to environmental cues have all been shown to influence the type of radial glia and radial glia-derived daughter cells that will be produced. FGF and Notch signaling regulate the proliferation of radial glia and the rate of neurogenesis, which affects the surface area expansion of the cerebral cortex and its ability to form surface convolutions known as gyri (see gyrification).[7][9][10] Additionally, recent evidence suggests that cues from the external sensory environment can also influence the proliferation and neural differentiation of radial glia.[7][11]

At the conclusion of cortical development, most radial glia lose their attachment to the ventricles, and migrate towards the surface of the cortex, where, in mammals, most will become astrocytes during the process of gliogenesis.[8]

While it has been suggested that radial glia most likely give rise to oligodendrocytes, through the generation of oligodendrocyte progenitor cells (OPCs), and OPCs can be generated from radial glial cells in vitro, more evidence is yet needed to conclude whether this process also occurs in the developing brain.[8][12]

Recently, radial glia that exclusively generate upper-layer cortical neurons have also been discovered.[5] Since upper cortical layers have expanded greatly in recent evolution, and are associated with higher-level information processing and thinking, radial glia have been implicated as important mediators of brain evolution.[13]

Migration Pattern

The best characterized and first widely accepted function of radial glia is their role as scaffolds for neuronal migration in the cerebral and cerebellar cortexes. This role can be easily visualized using the electron microscope or high-resolution time-lapse microscopy, through which neurons can be seen tightly wrapped around radial glia as they travel upwards through the cortex.[5] Additional evidence suggests that many neurons may move between neighboring radial glial fibers during migration.[7]

While excitatory neuronal migration is largely radial, inhibitory, GABAergic neurons have been shown to undergo tangential migration. Tangentially migrating neurons also appear to initiate contact with radial glial fibers in the developing cortex of ferrets, implicating radial glial cells in both of these forms of migration.[7]

As radial glia seem to differentiate late in spinal cord development, near the onset of gliogenesis, it is unclear whether they are involved in spinal cord neurogenesis or migration.[5]


Radial glia have also been implicated in forming boundaries between different axonal tracts and white matter areas of the brain.[5][14]

Radial glial subtypes

Müller glia

Müller glia are radial glial cells that are present in the developing, as well as the adult, retina. As in the cortex, Müller glia have long processes that span the entire width of the retina, from the basal cell layer to the apical layer. However, unlike cortical radial glia, Müller glia do not appear in the retina until after the first rounds of neurogenesis have occurred. Studies suggest that Müller glia can dedifferentiate into readily dividing neural progenitors in response to injury.[7]

Slcla3 in Bergmann Glia

The characteristics that truly set Müller glia apart from radial glia in other areas of the brain, is their possession of optical properties. The majority of the retina is actually largely light scattering, suggesting that Müller glia serve as the main fiber responsible for the relay of light to the photoreceptors in the rear of the retina. Properties that help Müller glia achieve this function include a limited number mitochondria (which are very light scattering), as well as a specialized arrangement of internal protein filaments.[7]

Müller glia are the only type of macroglia in the retina, so they take on many of the supportive functions that astrocytes and oligodendrocytes usually handle in the rest of the central nervous system.[7]

Bergmann glia

Bergmann glia are located in the cerebellum in which they can be seen very early in development, and play an essential role in the migration of the cerebellar Purkinje cells and granule cells. Bergmann glia are characterized by multiple radial branches, as opposed to a single process in other radial glia in other brain areas, that spans the width of the cerebellar cortex. Since Bergmann glia appear to persist in the cerebellum, and perform many of the roles characteristic of astrocytes, they have also been called "specialized astrocytes."[7] Besides their role in early development of the cerebellum, Bergmann glia are also required for synaptic pruning.[15]

Radial glia and disease

As radial glia serve as the primary neural and glial progenitors in the brain, as well as being crucial for proper neuronal migration, defects in radial glial function can have profound effects in the development of the nervous system.

Mutations in either Lis1 or Nde1, essential proteins for radial glial differentiation and stabilization, cause the associated neurodevelopmental diseases Lissencephaly and micro-lissencephaly (which literally translate to “smooth brain”). Patients with these diseases are characterized by a lack of cortical folds (sulci and gyri) and reduced brain volume. Extreme cases of Lissencephaly cause death a few months after birth, while patients with milder forms may experience mental retardation, difficulty balancing, motor and speech deficits, and epilepsy.[5]

See also


  1. ^ Kirsch F, Krüger C, Schneider A (2008). "The receptor for granulocyte-colony stimulating factor (G-CSF) is expressed in radial glia during development of the nervous system".  
  2. ^ Rakic, P (May 1972). "Mode of cell migration to the superficial layers of fetal monkey neocortex.". The Journal of comparative neurology 145 (1): 61–83.  
  3. ^ Rakic, P (October 2009). "Evolution of the neocortex: a perspective from developmental biology.". Nature reviews. Neuroscience 10 (10): 724–35.  
  4. ^ a b Malatesta, P; Appolloni, I; Calzolari, F (Jan 2008). "Radial glia and neural stem cells.". Cell and tissue research 331 (1): 165–78.  
  5. ^ a b c d e f g h Barry, DS; Pakan, JM; McDermott, KW (Jan 2014). "Radial glial cells: key organisers in CNS development.". The international journal of biochemistry & cell biology 46: 76–9.  
  6. ^ a b c d Bentivoglio, M; Mazzarello, P (Jul 15, 1999). "The history of radial glia.". Brain Research Bulletin 49 (5): 305–15.  
  7. ^ a b c d e f g h i j Sild, M; Ruthazer, ES (Jun 2011). "Radial glia: progenitor, pathway, and partner.". The Neuroscientist : a review journal bringing neurobiology, neurology and psychiatry 17 (3): 288–302.  
  8. ^ a b c d Kriegstein, A; Alvarez-Buylla, A (2009). "The glial nature of embryonic and adult neural stem cells.". Annual review of neuroscience 32: 149–84.  
  9. ^ Rash, BG; Lim, HD; Breunig, JJ; Vaccarino, FM (26 October 2011). "FGF signaling expands embryonic cortical surface area by regulating Notch-dependent neurogenesis.". The Journal of neuroscience : the official journal of the Society for Neuroscience 31 (43): 15604–17.  
  10. ^ Rash, BG; Tomasi, S; Lim, HD; Suh, CY; Vaccarino, FM (26 June 2013). "Cortical gyrification induced by fibroblast growth factor 2 in the mouse brain.". The Journal of neuroscience : the official journal of the Society for Neuroscience 33 (26): 10802–14.  
  11. ^ Sharma, P; Cline, HT (Nov 4, 2010). "Visual activity regulates neural progenitor cells in developing xenopus CNS through musashi1.". Neuron 68 (3): 442–55.  
  12. ^ Mo, Z; Zecevic, N (Apr 1, 2009). "Human fetal radial glia cells generate oligodendrocytes in vitro.". Glia 57 (5): 490–8.  
  13. ^ "Scripps Research Neuroscientists Find Brain Stem Cells that May Be Responsible for Higher Functions, Bigger Brains". Scripps Research Institute. Retrieved 1 March 2014. 
  14. ^ Steindler, DA (1993). "Glial boundaries in the developing nervous system.". Annual review of neuroscience 16: 445–70.  
  15. ^ [cite web|url=|title= Bergmann Glial Cell |date=14 Oct 2011|accessdate= 10 Sept 2014]
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