Neuroglia

"Glia" redirects here. For the scientific journal, see Glia (journal).
Glia

Illustration of the four different types of glial cells found in the central nervous system: Ependymal cells, Astrocytes, Microglial cells, and oligodendrocytes.
Identifiers
MeSH Glia
Code TH H2.00.06.2.00001
TA A14.0.00.005
FMA 54541

Anatomical terminology

Neuroglia of the brain shown by Golgi's method
Astrocytes can be identified in culture because, unlike other mature glia, they express glial fibrillary acidic protein (GFAP)
Glial cells in a rat brain stained with an antibody against GFAP
23-week fetal brain culture astrocyte
Neoplastic glial cells stained with an antibody against GFAP (brown), from a brain biopsy

Glial cells, sometimes called neuroglia or simply glia (Greek γλία and γλοία "glue"; pronounced in English as either /ˈɡlə/ or /ˈɡlə/), are non-neuronal cells that maintain homeostasis, form myelin, and provide support and protection for neurons in the central nervous system and peripheral nervous system.[1]

As the Greek name implies, glia are commonly known as the glue of the nervous system; however, this is not fully accurate. Glia were discovered in 1856, by the pathologist Rudolf Virchow in his search for a "connective tissue" in the brain.[2] Neuroscience currently identifies four main functions of glial cells:

  1. To surround neurons and hold them in place
  2. To supply nutrients and oxygen to neurons
  3. To insulate one neuron from another
  4. To destroy pathogens and remove dead neurons.

For over a century, it was believed that the neuroglia did not play any role in neurotransmission. However 21st century neuroscience has recognized that glial cells do have some effects on certain physiological processes like breathing,[3][4] and in assisting the neurons to form synaptic connections between each other.[5]

Functions

Some glial cells function primarily as the physical support for neurons. Others regulate the internal environment of the brain, especially the fluid surrounding neurons and their synapses, and nutrify neurons. During early embryogenesis glial cells direct the migration of neurons and produce molecules that modify the growth of axons and dendrites. Recent research[6] indicates that glial cells of the hippocampus and cerebellum participate in synaptic transmission, regulate the clearance of neurotransmitters from the synaptic cleft, and release gliotransmitters such as ATP, which modulate synaptic function.

Glial cells are known to be capable of mitosis. By contrast, scientific understanding of whether neurons are permanently post-mitotic,[7] or capable of mitosis,[8][9][10] is still developing. In the past, glia had been considered to lack certain features of neurons. For example, glial cells were not believed to have chemical synapses or to release transmitters. They were considered to be the passive bystanders of neural transmission. However, recent studies have shown this to be untrue.[11]

For example, astrocytes are crucial in clearance of neurotransmitters from within the synaptic cleft, which provides distinction between arrival of action potentials and prevents toxic build-up of certain neurotransmitters such as glutamate (excitotoxicity). It is also thought that glia play a role in many neurological diseases, including Alzheimer's disease. Furthermore, at least in vitro, astrocytes can release gliotransmitter glutamate in response to certain stimulation. Another unique type of glial cell, the oligodendrocyte precursor cells or OPCs, have very well-defined and functional synapses from at least two major groups of neurons.[12] The only notable differences between neurons and glial cells are neurons' possession of axons and dendrites, and capacity to generate action potentials.

Glia ought not to be regarded as "glue" in the nervous system as the name implies; rather, they are more of a partner to neurons.[13] They are also crucial in the development of the nervous system and in processes such as synaptic plasticity and synaptogenesis. Glia have a role in the regulation of repair of neurons after injury. In the central nervous system (CNS), glia suppress repair. Glial cells known as astrocytes enlarge and proliferate to form a scar and produce inhibitory molecules that inhibit regrowth of a damaged or severed axon. In the peripheral nervous system (PNS), glial cells known as Schwann cells promote repair. After axonal injury, Schwann cells regress to an earlier developmental state to encourage regrowth of the axon. This difference between the CNS and the PNS, raises hopes for the regeneration of nervous tissue in the CNS. For example, a spinal cord may be able to be repaired following injury or severance. Schwann cells are also known as neuri-lemmocytes. These cells envelop nerve fibers of the PNS by winding repeatedly around a nerve fiber with the nucleus inside of it. This process creates a myelin sheath, which not only aids in conductivity but also assists in the regeneration of damaged fibers. Oligodendrocytes are another type of glial cell of the CNS. These dendrocytes resemble an octopus bulbous body and contain up to fifteen arm-like processes. Each “arm” reaches out to a nerve fiber and spirals around it, creating a myelin sheath. This myelin sheath insulates the nerve fiber from the extracellular fluid as well as speeds up the signal conduction in the nerve fiber.[14]

Types

Different types of neuroglia

Microglia

For more details on this topic, see Microglia.

Microglia are specialized macrophages capable of phagocytosis that protect neurons of the central nervous system.[15] They are derived from hematopoietic stem cells in mesodermal tissue; they are commonly categorized as such because of their supportive role to neurons.

These cells are found in all regions of the brain and spinal cord. Microglial cells are small relative to macroglial cells, with changing shapes and oblong nuclei. They are mobile within the brain and multiply when the brain is damaged. In the healthy central nervous system, microglia processes constantly sample all aspects of their environment (neurons, macroglia and blood vessels). In a healthy brain, microglia direct the immune response to brain damage and play an important role in the inflammation that accompanies the damage. Many diseases and disorders are associated with deficient microglia, such as, Alzheimer's disease, Parkinson's disease, and ALS.

Macroglia

Derived from ectodermal tissue.

Location Name Description
CNS Astrocytes

The most abundant type of macroglial cell in the CNS,[16] astrocytes (also called astroglia) have numerous projections that anchor neurons to their blood supply. They regulate the external chemical environment of neurons by removing excess ions, the notable one being potassium, and recycling neurotransmitters released during synaptic transmission. The current theory suggests that astrocytes may be the predominant "building-blocks" of the blood–brain barrier. Astrocytes may regulate vasoconstriction and vasodilation by producing substances such as arachidonic acid, whose metabolites are vasoactive.

Astrocytes signal each other using calcium. The gap junctions (also known as electrical synapses) between astrocytes allow the messenger molecule IP3 to diffuse from one astrocyte to another. IP3 activates calcium channels on cellular organelles, releasing calcium into the cytoplasm. This calcium may stimulate the production of more IP3. The net effect is a calcium wave that propagates from cell to cell. Extracellular release of ATP, and consequent activation of purinergic receptors on other astrocytes, may also mediate calcium waves in some cases.

In general, there are two types of astrocytes, protoplasmic and fibrous, similar in function but distinct in morphology and distribution. Protoplasmic astrocytes have short, thick, highly branched processes and are typically found in gray matter. Fibrous astrocytes have long, thin, less branched processes and are more commonly found in white matter.

It has recently been shown that astrocyte activity is linked to blood flow in the brain, and that this is what is actually being measured in fMRI.[17] They also have been involved in neuronal circuits playing an inhibitory role after sensing changes in extracellular calcium.[18]

CNS Oligodendrocytes

Oligodendrocytes are cells that coat axons in the central nervous system (CNS) with their cell membrane, forming a specialized membrane differentiation called myelin, producing the so-called myelin sheath. The myelin sheath provides insulation to the axon that allows electrical signals to propagate more efficiently.[19]

CNS Ependymal cells

Ependymal cells, also named ependymocytes, line the spinal cord and the ventricular system of the brain. These cells are involved in the creation and secretion of cerebrospinal fluid (CSF) and beat their cilia to help circulate the CSF and make up the blood-CSF barrier. They are also thought to act as neural stem cells.[20]

CNS Radial glia

Radial glia cells arise from neuroepithelial cells after the onset of neurogenesis. Their differentiation abilities are more restricted than those of neuroepithelial cells. In the developing nervous system, radial glia function both as neuronal progenitors and as a scaffold upon which newborn neurons migrate. In the mature brain, the cerebellum and retina retain characteristic radial glial cells. In the cerebellum, these are Bergmann glia, which regulate synaptic plasticity. In the retina, the radial Müller cell is the principal glial cell, and participates in a bidirectional communication with neurons.[21]

PNS Schwann cells

Similar in function to oligodendrocytes, Schwann cells provide myelination to axons in the peripheral nervous system (PNS). They also have phagocytotic activity and clear cellular debris that allows for regrowth of PNS neurons.[22]

PNS Satellite cells

Satellite glial cells are small cells that surround neurons in sensory, sympathetic, and parasympathetic ganglia.[23] These cells help regulate the external chemical environment. Like astrocytes, they are interconnected by gap junctions and respond to ATP by elevating intracellular concentration of calcium ions. They are highly sensitive to injury and inflammation, and appear to contribute to pathological states, such as chronic pain.[24]

PNS Enteric glial cells

Are found in the intrinsic ganglia of the digestive system. They are thought to have many roles in the enteric system, some related to homeostasis and muscular digestive processes.[25]

Other

Pituicytes from the posterior pituitary are glia cells with characteristics in common to astrocytes.[26] Tanycytes in the median eminence of the hypothalamus are a type of ependymal cell that descend from radial glia and line the base of the third ventricle.[27]

Capacity to divide

Glia retain the ability to undergo cell division in adulthood, whereas most neurons cannot. The view is based on the general deficiency of the mature nervous system in replacing neurons after an injury, such as a stroke or trauma, while very often there is a profound proliferation of glia, or gliosis near or at the site of damage. However, detailed studies found no evidence that 'mature' glia, such as astrocytes or oligodendrocytes, retain the ability of mitosis. Only the resident oligodendrocyte precursor cells seem to keep this ability after the nervous system matures. On the other hand, there are a few regions in the mature nervous system, such as the dentate gyrus of the hippocampus and the subventricular zone, where generation of new neurons can be observed.[28]

Embryonic development

Most glia are derived from ectodermal tissue of the developing embryo, in particular the neural tube and crest. The exception is microglia, which are derived from hemopoietic stem cells. In the adult, microglia are largely a self-renewing population and are distinct from macrophages and monocytes, which infiltrate the injured and diseased CNS.

In the central nervous system, glia develop from the ventricular zone of the neural tube. These glia include the oligodendrocytes, ependymal cells, and astrocytes. In the peripheral nervous system, glia derive from the neural crest. These PNS glia include Schwann cells in nerves and satellite glial cells in ganglia.

Current research involving glial cells in the human cochlea proposes that these cells are the common precursor to both mature Schwann cells and satellite glial cells. Additionally, the peripheral glial cells located along the peripheral processes expressed NGFR, indicating a phenotype distinct from the peripheral glial cells located along the central processes.[29]

This scientific finding could support the speculation that glial cells have a differentiation type of biological evolution depending on their location in the brain. Perhaps specialized types of glial cells have evolved in certain areas of the brain due to its compatibility/affinity with that specific region's group of cellular nuclei physiology.

History

Glia were first described in 1856 by the pathologist Rudolf Virchow in a comment to his 1846 publication on connective tissue. A more detailed description of glial cells was provided in the 1858 book Cellular Pathology by the same author.[30]

When markers for different types of cells were analyzed, Einstein's brain was discovered to contain significantly more glia than normal brains in the left angular gyrus, an area thought to be responsible for mathematical processing and language. The ratio of glia to neurons increases with our definition of intelligence. Not only does the ratio of glia to neurons increase through evolution, but so does the size of the glia. Astroglial cells in the human have a volume 27 times greater than the same cells in the mouse's brain.[31]

These important scientific findings may begin to shift the neuron-specific perspective into a more holistic view of the brain which encompasses the glial cells as well. The glia's importance is becoming ever more clear as time goes on and new research is conducted. For the vast part of the last century, scientists have written off glial cells to be nothing more than the structure and foundations that hold the neurons in place. But now, there is direct evidence that correlates the number of glial cells in the brain with the amount of intelligence that any given species possesses.[32] Future research will begin to shed light on the mysterious, yet increasingly crucial, role of glial cells.

Numbers

In general, neuroglial cells are smaller than neurons; there are about 86 billion neurons and 85 billion "nonneuronal" (glial) cells in the human male brain. Glial cells comprise about half the total volume of the brain and spinal cord.[33][34] The ratio differs from one part of the brain to another. The glia/neuron ratio in the cerebral cortex is 3.72 (60.84 billion glia (72%); 16.34 billion neurons), while that of the cerebellum is only 0.23 (16.04 billion glia; 69.03 billion neurons). The ratio in the cerebral cortex gray matter is 1.48 and for the combined gray and white matter is 3.76.[34] The ratio of the basal ganglia, diencephalon and brainstem combined is 11.35.[34]

Most cerebral cortex glia are oligodendrocytes (75.6%); astrocytes account for 17.3% and microglia for 6.5%.[35]

Additional images

See also

References

Notes

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  2. "Classic Papers". Network Glia. Max Delbrueck Center für Molekulare Medizin (MDC) Berlin-Buch. Retrieved 14 November 2015.
  3. Swaminathan, Nikhil (Jan–Feb 2011). "Glia—the other brain cells". Discover.
  4. Gourine AV, Kasymov V, Marina N, et al. (July 2010). "Astrocytes control breathing through pH-dependent release of ATP". Science 329 (5991): 571–5. doi:10.1126/science.1190721. PMC 3160742. PMID 20647426.
  5. Wolosker H, Dumin E, Balan L, Foltyn VN (July 2008). "D-amino acids in the brain: D-serine in neurotransmission and neurodegeneration". The FEBS Journal 275 (14): 3514–26. doi:10.1111/j.1742-4658.2008.06515.x. PMID 18564180.
  6. Newman, Eric A. (2003). "New roles for astrocytes: Regulation of synaptic transmission". Trends in Neurosciences 10 (26): 536–542. doi:10.1016/S0166-2236(03)00237-6.
  7. Herrup K, Yang Y (May 2007). "Cell cycle regulation in the postmitotic neuron: oxymoron or new biology?". Nature Reviews. Neuroscience 8 (5): 368–78. doi:10.1038/nrn2124. PMID 17453017.
  8. Goldman SA, Nottebohm F (April 1983). "Neuronal production, migration, and differentiation in a vocal control nucleus of the adult female canary brain". Proceedings of the National Academy of Sciences of the United States of America 80 (8): 2390–4. doi:10.1073/pnas.80.8.2390. PMC 393826. PMID 6572982.
  9. Eriksson PS, Perfilieva E, Björk-Eriksson T, et al. (November 1998). "Neurogenesis in the adult human hippocampus". Nature Medicine 4 (11): 1313–7. doi:10.1038/3305. PMID 9809557.
  10. Gould E, Reeves AJ, Fallah M, Tanapat P, Gross CG, Fuchs E (April 1999). "Hippocampal neurogenesis in adult Old World primates". Proceedings of the National Academy of Sciences of the United States of America 96 (9): 5263–7. doi:10.1073/pnas.96.9.5263. PMC 21852. PMID 10220454.
  11. The Other Brain, by R. Douglas Fields, Ph. D. Simon & Schuster, 2009
  12. Feezel, Charlie. World Cocoa Foundation: Knowledge Creation in Rulal West Africa. US Aid Education Workshop.
  13. The Root of Thought: Unlocking Glia, by Andrew Koob, FT Science Press, 2009
  14. Saladin, Kenneth. Anatomy and Physiology, 6th Edition. McGraw Hill 2012. Page 446-448.
  15. Brodal, 2010: p. 19
  16. http://www.scientificamerican.com/article.cfm?id=the-root-of-thought-what[]
  17. Swaminathan N (2008). "Brain-scan mystery solved". Scientific American Mind. Oct–Nov: 7.
  18. Torres A (2012). "Extracellular Ca2+ Acts as a Mediator of Communication from Neurons to Glia". Science Signaling. 5 Jan 24: 208. doi:10.1126/scisignal.2002160.
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  20. Johansson CB, Momma S, Clarke DL, Risling M, Lendahl U, Frisén J (January 1999). "Identification of a neural stem cell in the adult mammalian central nervous system". Cell 96 (1): 25–34. doi:10.1016/S0092-8674(00)80956-3. PMID 9989494.
  21. Campbell K, Götz M (May 2002). "Radial glia: multi-purpose cells for vertebrate brain development". Trends in Neurosciences 25 (5): 235–8. doi:10.1016/s0166-2236(02)02156-2. PMID 11972958.
  22. Jessen KR, Mirsky R (September 2005). "The origin and development of glial cells in peripheral nerves". Nature Reviews. Neuroscience 6 (9): 671–82. doi:10.1038/nrn1746. PMID 16136171.
  23. Hanani, M. Satellite glial cells in sensory ganglia: from form to function. Brain Res. Rev. 48:457–476, 2005
  24. Ohara PT, Vit JP, Bhargava A, Jasmin L (December 2008). "Evidence for a role of connexin 43 in trigeminal pain using RNA interference in vivo". Journal of Neurophysiology 100 (6): 3064–73. doi:10.1152/jn.90722.2008. PMC 2604845. PMID 18715894.
  25. Bassotti G, Villanacci V, Antonelli E, Morelli A, Salerni B (July 2007). "Enteric glial cells: new players in gastrointestinal motility?". Laboratory Investigation 87 (7): 628–32. doi:10.1038/labinvest.3700564. PMID 17483847.
  26. Miyata, S; Furuya, K; Nakai, S; Bun, H; Kiyohara, T (April 1999). "Morphological plasticity and rearrangement of cytoskeletons in pituicytes cultured from adult rat neurohypophysis.". Neuroscience research 33 (4): 299–306. doi:10.1016/s0168-0102(99)00021-8. PMID 10401983.
  27. Rodríguez, EM; Blázquez, JL; Pastor, FE; Peláez, B; Peña, P; Peruzzo, B; Amat, P (2005). "Hypothalamic tanycytes: a key component of brain-endocrine interaction.". International review of cytology 247: 89–164. doi:10.1016/s0074-7696(05)47003-5. PMID 16344112.
  28. Kornack DR, Rakic P (May 1999). "Continuation of neurogenesis in the hippocampus of the adult macaque monkey". Proceedings of the National Academy of Sciences of the United States of America 96 (10): 5768–73. doi:10.1073/pnas.96.10.5768. PMC 21935. PMID 10318959.
  29. Locher H, de Groot JC, van Iperen L, Huisman MA, Frijns JH, Chuva de Sousa Lopes SM (2014). "Distribution and development of peripheral glial cells in the human fetal cochlea". PLoS ONE 9 (1): e88066. doi:10.1371/journal.pone.0088066. PMC 3909285. PMID 24498246.
  30. Kettenmann H, Verkhratsky A (December 2008). "Neuroglia: the 150 years after". Trends in Neurosciences 31 (12): 653–9. doi:10.1016/j.tins.2008.09.003. PMID 18945498.
  31. Koob, Andrew (2009). The Root of Thought. FT Press. p. 186. ISBN 978-0-13-715171-4.
  32. Aw, B.L. "5 Reasons why Glial Cells Were So Critical to Human Intelligence.". Scientific Brains. Retrieved 5 January 2015.
  33. Clinical Neuro-Anatomy, Richard S. Snell, 7th edition
  34. 1 2 3 Azevedo FA, Carvalho LR, Grinberg LT, et al. (April 2009). "Equal numbers of neuronal and nonneuronal cells make the human brain an isometrically scaled-up primate brain". The Journal of Comparative Neurology 513 (5): 532–41. doi:10.1002/cne.21974. PMID 19226510.
  35. Pelvig DP, Pakkenberg H, Stark AK, Pakkenberg B (November 2008). "Neocortical glial cell numbers in human brains". Neurobiology of Aging 29 (11): 1754–62. doi:10.1016/j.neurobiolaging.2007.04.013. PMID 17544173. (figures given are those for females)

Bibliography

Further reading

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