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Glial scar

January 01, 1970

A glial scar formation (gliosis) is a reactive cellular process involving astrogliosis that occurs after injury to the central nervous system. As with scarring in other organs and tissues, the glial scar is the body's mechanism to protect and begin the healing process in the nervous system.

Glial scar
Micrograph of the superficial cerebral cortex showing neuron loss and reactive astrocytes in a person who had a stroke. H&E-LFB stain.
SpecialtyPathology
CausesTrauma

In the context of neurodegeneration, formation of the glial scar has been shown to have both beneficial and detrimental effects. Particularly, many neuro-developmental inhibitor molecules are secreted by the cells within the scar that prevent complete physical and functional recovery of the central nervous system after injury or disease.[citation needed] On the other hand, absence of the glial scar has been associated with impairments in the repair of the blood brain barrier.[1]

Scar components edit

The glial scar is composed of several components briefly discussed below.

Reactive astrocytes edit

Reactive astrocytes are the main cellular component of the glial scar.[2] After injury, astrocytes undergo morphological changes, extend their processes, and increase synthesis of glial fibrillary acidic protein (GFAP). GFAP is an important intermediate filament protein that allows the astrocytes to begin synthesizing more cytoskeletal supportive structures and extend pseudopodia. Ultimately, the astrocytes form a dense web of their plasma membrane extensions that fills the empty space generated by the dead or dying neuronal cells (a process called astrogliosis). The heavy proliferation of astrocytes also modifies the extracellular matrix surrounding the damaged region by secreting many molecules including laminin, fibronectin, tenascin C, and proteoglycans.[3][4] These molecules are important modulators of neuronal outgrowth. Accordingly, their presence after injury contributes to inhibition of regeneration.[5][6]

Another important caveat of the astrocytic response to CNS injuries is its heterogeneity. Particularly, the response of the astrocytes to the injury varies depending on factors such as the nature of the injury and the microenvironment at the injury location.[7][8] Further, the reactive astrocytes in the immediate vicinity of the injury increase gene expression, thus compounding the response of other astrocytes and contributing to the heterogeneity. Particularly, astrocytes closest to the lesion generally secrete more inhibitory molecules into the extracellular matrix.[2]

Microglia edit

Microglia are the second most prominent cell type present within the glial scar. They are the nervous system analog of immune system macrophages. Microglia rapidly activate near the injury and secrete several cytokines, bioactive lipids, coagulation factors, reactive oxygen intermediates, and neurotrophic factors.[9] The expression of these molecules depends on the location of the microglial cells relative to the injury, with the cells closest to the injury secreting the largest amount of such biologically active molecules.[citation needed]

Endothelial cells and fibroblasts edit

The various biologically active molecules secreted by microglia stimulate and recruit endothelial cells and fibroblasts. These cells help stimulate angiogenesis and collagen secretion into the injured area. Ultimately, the amount of capillaries extended into the injured area is twice that of uninjured central nervous system regions.[10]

Basal membrane edit

The basal membrane is a histopathological extracellular matrix feature that forms at the center of injury and partially covers the astrocytic processes. It is composed of three layers with the basal lamina as the prominent layer. Molecularly, the basal membrane is created by glycoprotein and proteoglycan protomers. Further, two independent networks are formed within the basal membrane by collagen IV and laminin for structural support. Other molecular components of the basal membrane include fibulin-1, fibronectin, entactin, and heparin sulfate proteoglycan perlecan. Ultimately, the astrocytes attach to the basal membrane, and the complex surrounds the blood vessels and nervous tissue to form the initial wound covering.[2]

Beneficial effects of the scar edit

The ultimate function of the glial scar is to reestablish the physical and chemical integrity of the CNS. This is done by generating a barrier across the injured area that seals the nervous/non-nervous tissue boundary. This also allows for the regeneration of the selective barrier to prevent further microbial infections and spread of cellular damage. Moreover, the glial scar stimulates revascularization of blood capillaries to increase the nutritional, trophic, and metabolic support of the nervous tissue.[2]

Detrimental effects of the scar edit

The glial scar also prevents neuronal regrowth. Following trauma to the CNS, axons begin to sprout and attempt to extend across the injury site in order to repair the damaged regions. However, the scar prevents axonal extensions via physical and chemical means. Astrocytes form a dense network of gap junctions that generates a physical barrier to axonal regrowth. Further, the astrocytes secrete several growth-inhibitory molecules that chemically prevent axonal extensions. Moreover, the basal membrane component is expected to generate an additional physical and chemical barrier to axonal extensions.[2]

Primary scar molecular inducers edit

The formation of the glial scar is a complex process. Several main classes of molecular mediators of gliosis have been identified and are briefly discussed below.

Transforming growth factor β edit

Two neuronally-important subclasses of transforming growth factor family of molecules are TGFβ-1 and TGFβ-2 that directly stimulate astrocytes, endothelial cells, and macrophages. TGFβ-1 has been observed to increase immediately after injury to the central nervous system, whereas TGFβ-2 expression occurs more slowly near the injury site. Further, TGFβ-2 has been shown to stimulate growth-inhibitory proteoglycans by astrocytes.[11] Experimental reduction of TGFβ-1 and TGFβ-2 has been shown to partially reduce glial scarring.[12]

Interleukins edit

Interleukins are another potential family of scar-inducing cellular messengers. Particularly, interleukin-1, a protein produced by mononuclear phagocytes, helps to initiate the inflammatory response in astrocytes, leading to reactive astrogliosis and the formation of the glial scar.[13][14]

Cytokines edit

The cytokine family of glial scar inducers include interferon-γ (IFNγ) and fibroblast growth factor 2 (FGF2). IFNγ has been shown to induce astrocyte proliferation and increase the extent of glial scarring in injured brain models.[15] Further, FGF2 production increases after injury to the brain and spinal cord. FGF2 has also been shown to increase astrocyte proliferation in vitro.[16][17]

Ciliary neurotrophic factor edit

Ciliary neurotrophic factor (CNTF) is a cytosolic protein that is not secreted. CNTF has been shown to promote the survival of neuronal cultures in vitro, and it can also act as a differentiator and trophic factor on glial cells. Further, CNTF has been previously shown to affect the differentiation of glial precursor cells in vitro; however, the influence of CNTF in the in vivo setting has only recently been determined. Winter et al. used CNTF over-expressing transgenic mice as well as wildtype controls that had CNTF levels artificially elevated via injection, were subjected to neuronal damage using ZnSO4 (a known neuronal degenerative factor), which was injected intranasally in the olfactory epithelium. The olfactory bulb was then assessed for the expression of GFAP mRNA- a common marker for the glial scar. It was determined that mice with elevated levels of CNTF increased their GFAP mRNA expression two-fold. This data suggests that CNTF may mediate glial scar formation following CNS damage.[18]

Upregulation of nestin intermediate filament protein edit

Nestin is an intermediate filament (IF) protein that assists with IF polymerization and macromolecule stability. Intermediate filaments are an integral part of cell motility, a requirement for any large migration or cellular reaction. Nestin is normally present during (CNS) development and reactivates after minor stresses to the nervous system. However, Frisen et al. determined that nestin is also upregulated during severe stresses such as lesions which involve the formation of the glial scar. Mid-thoracic spinal cord lesions, optic nerve lesions, but not lesions to the sciatic nerve, have shown marked increases in nestin expression within the first 48 hours after trauma. Further, nestin upregulation was shown to last for up to 13 months post-injury. This data suggests that nestin upregulation may be associated with CNS glial scarring.[19]

Suppression of glial scar formation edit

Several techniques have been devised to impede scar formation. Such techniques can be combined with other neuroregeneration techniques to help with functional recovery.

Olomoucine edit

Olomoucine, a purine derivative, is a cyclin-dependent kinase (CDK) inhibitor. CDK is a cell-cycle promoting protein, which along with other pro-growth proteins is abnormally activated during glial scar formation.[citation needed] Such proteins can increase astrocyte proliferation and can also lead to cell death, thus exacerbating cellular damage at the lesion site. Administration of olomoucine peritoneally has been shown to suppress CDK function. Further, olomoucine has been shown to reduce neuronal cell death, reduce astroglial proliferation (and therefore reduce astrogliosis), and increase GAP-43 expression, a useful protein marker for neurite growth. Moreover, reduced astrocyte proliferation decreases expression of chondroitin sulfate proteoglycans (CSPGs), major extracellular matrix molecules associated with inhibition of neuroregneration after trauma to the CNS.[20]

Recent work has also shown that olomoucine suppresses microglial proliferation within the glial scar. This is particularly important because microglia play an important role in the secondary damage following lesion to the CNS, during the time of scar formation. Microglial cells are activated via various pro-inflammatory cytokines (some discussed above). Rat spinal cord injury models have shown remarkable improvements after the administration of olomoucine. One hour-post administration, olomoucine suppressed microglial proliferation, as well as reduced the tissue edema normally present during the early stages of glial scar formation. Further, 24 hours post-administration, a reduction in concentration of interleukin-1β was observed. Additionally, the administration of olomoucine has also been shown to decrease neuronal cell death.[21]

Inhibition of phosphodiesterase 4 (PDE4) edit

Phosphodiesterase 4 is a member of the phosphodiesterase family of proteins that cleave phosphodiester bonds. This is an important step in degrading cyclic adenosine monophosphate (cAMP), a major intracellular signaling molecule; conversely, blocking PDE4 will increase cAMP. Increased intracellular cAMP levels in neurons has been previously shown to induce axonal growth.[22] In 2004, Nikulina et al. showed that administration of rolipram, a PDE4 inhibitor, can increase cAMP levels in neurons after spinal cord injury. This is partially possible because rolipram is sufficiently small to pass through the blood–brain barrier and immediately begin to catalyze reactions in neurons. 10 day administration of rolipram in spinal cord injured rodents resulted in considerable axonal growth associated with a reduction in glial scarring at 2 weeks post-injury. The mechanism for this reduction in glial scarring is currently unknown, but possible mechanisms include axonal extensions that physically prevent reactive astrocytes from proliferating, as well as chemical signaling events to reduce reactive astrogliosis.[23]

Ribavirin edit

Ribavirin is a purine nucleoside analogue that is generally used as an anti-viral medication. However, it has also been shown to decrease the amount of reactive astrocytes. Daily administration for at least five days following brain trauma was shown to significantly decrease the number of reactive astrocytes.[24]

Antisense GFAP retrovirus edit

An antisense GFAP retrovirus (PLBskG) to reduce GFAP mRNA expression, has been implemented in suppressing growth and arresting astrocytes in the G1 phase of the cell cycle. However, a main caveat to the clinical application of retroviral use is the non-discriminatory effects of PLBskG on normal as well as injured astrocytes. Further in vivo studies are needed to determine the systemic effects of PLBskG administration.[25]

Recombinant monoclonal antibody to transforming growth factor-β2 edit

As noted in the above section, transforming growth factor-β2 (TGFβ2) is an important glial scar stimulant that directly affects astrocyte proliferation. Logan et al. developed monoclonal antibodies to TGFβ2, cerebral wounds were generated in rat brains, and the antibodies were administered via the ventricles, daily for 10 days. Subsequent analysis showed a marked reduction in glial scarring. Particularly, extracellular matrix protein deposition (laminin, fibronectin, and chondroitin sulfate proteoglycans) was closer to baseline (levels of protein expression in an uninjured animal). Further, a reduction in astrocytes and microglia, as well as a reduction in inflammation and angiogenesis, were observed.[26]

Recombinant monoclonal antibody to interleukin-6 receptor edit

Interleukin-6 (IL-6) is thought to be a molecular mediator of glial scar formation. It has been shown to promote differentiation of neural stem cells into astrocytes.[citation needed] A monoclonal antibody, MR16-1, has been used to target and block the IL-6 receptors in rat spinal cord injury models. In a study by Okada et al., mice were intraperitoneally injected with a single dose of MR16-1 immediately after generating a spinal cord injury. Blockade of IL-6 receptors decreased the number of astrocytes present at the spinal cord lesion and this decrease was associated with a reduction in glial scarring.[27]

Glial scar treatment or removal edit

Chondroitinase ABC has been shown to degrade glial scars.[28][29] Degrading the glial scar with chondroitinase has been shown to promote recovery from spinal cord injury,[30] especially when combined with other techniques such as nerve guidance conduits, schwann cell transplants,[31] and peripheral nerve autografts.[32]

See also edit

References edit

  1. ^ Faulkner JR, Herrmann JE, Woo MJ, Tansey KE, Doan NB, Sofroniew MV (March 2004). "Reactive astrocytes protect tissue and preserve function after spinal cord injury". J. Neurosci. 24 (9): 2143–55. doi:10.1523/JNEUROSCI.3547-03.2004. PMC 6730429. PMID 14999065.
  2. ^ a b c d e Stichel CC, Müller HW (October 1998). "The CNS lesion scar: new vistas on an old regeneration barrier". Cell Tissue Res. 294 (1): 1–9. doi:10.1007/s004410051151. PMID 9724451. S2CID 13652357.
  3. ^ Jones LL, Margolis RU, Tuszynski MH (August 2003). "The chondroitin sulfate proteoglycans neurocan, brevican, phosphacan, and versican are differentially regulated following spinal cord injury". Exp. Neurol. 182 (2): 399–411. doi:10.1016/S0014-4886(03)00087-6. PMID 12895450. S2CID 16748373.
  4. ^ 14561854
  5. ^ Davies SJ, Fitch MT, Memberg SP, Hall AK, Raisman G, Silver J (1997). "Regeneration of adult axons in white matter tracts of the central nervous system". Nature. 390 (6661): 680–3. Bibcode:1997Natur.390..680D. doi:10.1038/37776. PMID 9414159. S2CID 205026020.
  6. ^ Silver, Jerry (2004). "Regeneration beyond the glial scar". Nature Reviews Neuroscience. 5 (2): 146–156. doi:10.1038/nrn1326. PMID 14735117.
  7. ^ David S, Ness R. (1993). "Heterogeneity of reactive astrocytes." In: Fedoroff S (ed) Biology and pathology of astrocyte-neuron interactions. Plenum Press, New York, pp. 303-312.
  8. ^ Fernaud-Espinosa I, Nieto-Sampedro N, Bovolenta P. (1993). "Differential activation of microglia and astrocytes in aniso- and isomorphic gliotic tissue." Glia 8: 277-291.
  9. ^ Elkabes S, DiCicco-Bloom EM, Black IB (1996). "Brain microglia/ macrophages express neurotrophins that selectively regulate microglial proliferation and function", Journal of Neuroscience 16: 2508–2521
  10. ^ Jaeger CB, Blight AR (1997). "Spinal compression injury in guinea pigs: structural changes of endothelium and its perivascular cell associations after blood–brain barrier breakdown and repair." Experimental Neurology 144: 381-399.
  11. ^ Asher RA, et al. (2000). "Neurocan is upregulated in injured brain and in cytokine-treated astrocytes." Journal of Neurosciemce 20, 2427–2438.
  12. ^ Moon LDF, Fawcett JW. (2001). "Reduction in CNS scar formation without concomitant increase in axon regeneration following treatment of adult rat brain with a combination of antibodies to TGFβ1 and β2." European Journal of Neuroscience 14, 1667–1677.
  13. ^ Giulian D, et al. (1988). "Interleukin-1 injected into mammalian brain stimulates astrogliosis and neovascularization." Journal of Neuroscience 8, 2485–2490.
  14. ^ Silver J, Miller J. (2004). "Regeneration beyond the glial scar." Nature Reviews Neuroscience. 5(2): 146-156.
  15. ^ Yong VW et al. (1991). "γ-Interferon promotes proliferation of adult human astrocytes in vitro and reactive gliosis in the adult mouse brain in vivo." PNAS USA 88, 7016–7020.
  16. ^ Lander C, et al. (1997). "A family of activity-dependent neuronal cell-surface chondroitin sulfate proteoglycans in cat visual cortex." Journal of Neuroscience 17, 1928–1939.
  17. ^ Mocchetti I, et al. (1996). "Increased basic fibroblast growth factor expression following contusive spinal cord injury." Experimental Neurology 141, 154–164.
  18. ^ Winger, CG, et al. (1995). "A role for ciliary neurotrophic factor as an inducer of reactive gliosis, the glial response to central nervous system injury", Proc. Natl. Acad. Sci, USA, 92, 5865 - 5869.
  19. ^ Frisen, J. (1995). "Rapid, widespread, and long lasting induction of nestin contributes to the generation of glial scar tissue after CNS injury", The Journal of Cell Biology 131(2): 453-464.
  20. ^ Tian D, et al. (2006). "Suppression of Astroglial Scar Formation and Enhanced Axonal Regeneration Associated with Functional Recovery in a Spinal Cord Injury Rat Model by the Cell Cycle Inhibitor Olomoucine", Journal of Neuroscience Research 84: 1053-1063.
  21. ^ Tian D., et al. (2007). "Cell cycle inhibition attenuates microglia induced inflammatory response and alleviates neuronal cell death after spinal cord injury in rats." Brain Research 1135: 177-185.
  22. ^ Neumann, S., et al. (2002). "Regeneration of Sensory Axons within the Injured Spinal Cord Induced by Intraganglionic cAMP Elevation." Neuron 34, 885–893.
  23. ^ Nikulina, E. et al. (2004). "The phosphodiesterase inhibitor rolipram delivered after a spinal cord lesion promotes axonal regeneration and functional recovery", Proc Natl Acad Sci USA 101(23): 8786–8790.
  24. ^ Pekovic, S., et al. (2006). "Downregulation of glial scarring after brain injury", Annals of the New York Academy of Sciences 1048(1): 296-310.
  25. ^ Huang QL, Cai WQ, Zhang KC. (2000). "Effect of the control proliferation of astrocyte on the formation of glial scars by antisense GFAP retrovirus", Chinese Science Bulletin 45(1): 38-44.
  26. ^ Logan A, et al. (1999). "Inhibition of glial scarring in the injured rat brain by a recombinant human monoclonal antibody to transforming growth factor-β2", European Journal of Neuroscience 11: 2367-2374.
  27. ^ Okada S, et al. (2004). "Blockade of Interleukin-6 Receptor Suppresses Reactive Astrogliosis and Ameliorates Functional Recovery in Experimental Spinal Cord Injury", Journal of Neuroscience Research 76: 265-276.
  28. ^ Bradbury, Elizabeth J. (2002). "Chondroitinase ABC promotes functional recovery after spinal cord injury". Nature. 416 (6881): 636–640. Bibcode:2002Natur.416..636B. doi:10.1038/416636a. PMID 11948352. S2CID 4430737.
  29. ^ "Re-engineered enzyme could help reverse damage from spinal cord injury and stroke". August 24, 2020.
  30. ^ Bradbury, Elizabeth J. (2011). "Manipulating the glial scar: chondroitinase ABC as a therapy for spinal cord injury". Brain Research Bulletin. 84 (4–5): 306–316. doi:10.1016/j.brainresbull.2010.06.015. PMID 20620201. S2CID 10605553.
  31. ^ Fouad, Karim; Lisa Schnell; Mary B. Bunge; Martin E. Schwab; Thomas Liebscher; Damien D. Pearse (2 February 2005). "Combining Schwann Cell Bridges and Olfactory-Ensheathing Glia Grafts with Chondroitinase Promotes Locomotor Recovery after Complete Transection of the Spinal Cord". The Journal of Neuroscience. 25 (5): 1169–1178. doi:10.1523/JNEUROSCI.3562-04.2005. PMC 6725952. PMID 15689553.
  32. ^ Alilain, Warren J. (2011). "Functional regeneration of respiratory pathways after spinal cord injury". Nature. 475 (7355): 196–200. doi:10.1038/nature10199. PMC 3163458. PMID 21753849.

January 01, 1970
glial, scar, glial, scar, formation, gliosis, reactive, cellular, process, involving, astrogliosis, that, occurs, after, injury, central, nervous, system, with, scarring, other, organs, tissues, glial, scar, body, mechanism, protect, begin, healing, process, n. A glial scar formation gliosis is a reactive cellular process involving astrogliosis that occurs after injury to the central nervous system As with scarring in other organs and tissues the glial scar is the body s mechanism to protect and begin the healing process in the nervous system Glial scarMicrograph of the superficial cerebral cortex showing neuron loss and reactive astrocytes in a person who had a stroke H amp E LFB stain SpecialtyPathologyCausesTrauma In the context of neurodegeneration formation of the glial scar has been shown to have both beneficial and detrimental effects Particularly many neuro developmental inhibitor molecules are secreted by the cells within the scar that prevent complete physical and functional recovery of the central nervous system after injury or disease citation needed On the other hand absence of the glial scar has been associated with impairments in the repair of the blood brain barrier 1 Contents 1 Scar components 1 1 Reactive astrocytes 1 2 Microglia 1 3 Endothelial cells and fibroblasts 1 4 Basal membrane 2 Beneficial effects of the scar 3 Detrimental effects of the scar 4 Primary scar molecular inducers 4 1 Transforming growth factor b 4 2 Interleukins 4 3 Cytokines 4 4 Ciliary neurotrophic factor 4 5 Upregulation of nestin intermediate filament protein 5 Suppression of glial scar formation 5 1 Olomoucine 5 2 Inhibition of phosphodiesterase 4 PDE4 5 3 Ribavirin 5 4 Antisense GFAP retrovirus 5 5 Recombinant monoclonal antibody to transforming growth factor b2 5 6 Recombinant monoclonal antibody to interleukin 6 receptor 6 Glial scar treatment or removal 7 See also 8 ReferencesScar components editThe glial scar is composed of several components briefly discussed below Reactive astrocytes edit Reactive astrocytes are the main cellular component of the glial scar 2 After injury astrocytes undergo morphological changes extend their processes and increase synthesis of glial fibrillary acidic protein GFAP GFAP is an important intermediate filament protein that allows the astrocytes to begin synthesizing more cytoskeletal supportive structures and extend pseudopodia Ultimately the astrocytes form a dense web of their plasma membrane extensions that fills the empty space generated by the dead or dying neuronal cells a process called astrogliosis The heavy proliferation of astrocytes also modifies the extracellular matrix surrounding the damaged region by secreting many molecules including laminin fibronectin tenascin C and proteoglycans 3 4 These molecules are important modulators of neuronal outgrowth Accordingly their presence after injury contributes to inhibition of regeneration 5 6 Another important caveat of the astrocytic response to CNS injuries is its heterogeneity Particularly the response of the astrocytes to the injury varies depending on factors such as the nature of the injury and the microenvironment at the injury location 7 8 Further the reactive astrocytes in the immediate vicinity of the injury increase gene expression thus compounding the response of other astrocytes and contributing to the heterogeneity Particularly astrocytes closest to the lesion generally secrete more inhibitory molecules into the extracellular matrix 2 Microglia edit Microglia are the second most prominent cell type present within the glial scar They are the nervous system analog of immune system macrophages Microglia rapidly activate near the injury and secrete several cytokines bioactive lipids coagulation factors reactive oxygen intermediates and neurotrophic factors 9 The expression of these molecules depends on the location of the microglial cells relative to the injury with the cells closest to the injury secreting the largest amount of such biologically active molecules citation needed Endothelial cells and fibroblasts edit The various biologically active molecules secreted by microglia stimulate and recruit endothelial cells and fibroblasts These cells help stimulate angiogenesis and collagen secretion into the injured area Ultimately the amount of capillaries extended into the injured area is twice that of uninjured central nervous system regions 10 Basal membrane edit The basal membrane is a histopathological extracellular matrix feature that forms at the center of injury and partially covers the astrocytic processes It is composed of three layers with the basal lamina as the prominent layer Molecularly the basal membrane is created by glycoprotein and proteoglycan protomers Further two independent networks are formed within the basal membrane by collagen IV and laminin for structural support Other molecular components of the basal membrane include fibulin 1 fibronectin entactin and heparin sulfate proteoglycan perlecan Ultimately the astrocytes attach to the basal membrane and the complex surrounds the blood vessels and nervous tissue to form the initial wound covering 2 Beneficial effects of the scar editThe ultimate function of the glial scar is to reestablish the physical and chemical integrity of the CNS This is done by generating a barrier across the injured area that seals the nervous non nervous tissue boundary This also allows for the regeneration of the selective barrier to prevent further microbial infections and spread of cellular damage Moreover the glial scar stimulates revascularization of blood capillaries to increase the nutritional trophic and metabolic support of the nervous tissue 2 Detrimental effects of the scar editThe glial scar also prevents neuronal regrowth Following trauma to the CNS axons begin to sprout and attempt to extend across the injury site in order to repair the damaged regions However the scar prevents axonal extensions via physical and chemical means Astrocytes form a dense network of gap junctions that generates a physical barrier to axonal regrowth Further the astrocytes secrete several growth inhibitory molecules that chemically prevent axonal extensions Moreover the basal membrane component is expected to generate an additional physical and chemical barrier to axonal extensions 2 Primary scar molecular inducers editThe formation of the glial scar is a complex process Several main classes of molecular mediators of gliosis have been identified and are briefly discussed below Transforming growth factor b edit Two neuronally important subclasses of transforming growth factor family of molecules are TGFb 1 and TGFb 2 that directly stimulate astrocytes endothelial cells and macrophages TGFb 1 has been observed to increase immediately after injury to the central nervous system whereas TGFb 2 expression occurs more slowly near the injury site Further TGFb 2 has been shown to stimulate growth inhibitory proteoglycans by astrocytes 11 Experimental reduction of TGFb 1 and TGFb 2 has been shown to partially reduce glial scarring 12 Interleukins edit Interleukins are another potential family of scar inducing cellular messengers Particularly interleukin 1 a protein produced by mononuclear phagocytes helps to initiate the inflammatory response in astrocytes leading to reactive astrogliosis and the formation of the glial scar 13 14 Cytokines edit The cytokine family of glial scar inducers include interferon g IFNg and fibroblast growth factor 2 FGF2 IFNg has been shown to induce astrocyte proliferation and increase the extent of glial scarring in injured brain models 15 Further FGF2 production increases after injury to the brain and spinal cord FGF2 has also been shown to increase astrocyte proliferation in vitro 16 17 Ciliary neurotrophic factor edit Ciliary neurotrophic factor CNTF is a cytosolic protein that is not secreted CNTF has been shown to promote the survival of neuronal cultures in vitro and it can also act as a differentiator and trophic factor on glial cells Further CNTF has been previously shown to affect the differentiation of glial precursor cells in vitro however the influence of CNTF in the in vivo setting has only recently been determined Winter et al used CNTF over expressing transgenic mice as well as wildtype controls that had CNTF levels artificially elevated via injection were subjected to neuronal damage using ZnSO4 a known neuronal degenerative factor which was injected intranasally in the olfactory epithelium The olfactory bulb was then assessed for the expression of GFAP mRNA a common marker for the glial scar It was determined that mice with elevated levels of CNTF increased their GFAP mRNA expression two fold This data suggests that CNTF may mediate glial scar formation following CNS damage 18 Upregulation of nestin intermediate filament protein edit Nestin is an intermediate filament IF protein that assists with IF polymerization and macromolecule stability Intermediate filaments are an integral part of cell motility a requirement for any large migration or cellular reaction Nestin is normally present during CNS development and reactivates after minor stresses to the nervous system However Frisen et al determined that nestin is also upregulated during severe stresses such as lesions which involve the formation of the glial scar Mid thoracic spinal cord lesions optic nerve lesions but not lesions to the sciatic nerve have shown marked increases in nestin expression within the first 48 hours after trauma Further nestin upregulation was shown to last for up to 13 months post injury This data suggests that nestin upregulation may be associated with CNS glial scarring 19 Suppression of glial scar formation editSeveral techniques have been devised to impede scar formation Such techniques can be combined with other neuroregeneration techniques to help with functional recovery Olomoucine edit Olomoucine a purine derivative is a cyclin dependent kinase CDK inhibitor CDK is a cell cycle promoting protein which along with other pro growth proteins is abnormally activated during glial scar formation citation needed Such proteins can increase astrocyte proliferation and can also lead to cell death thus exacerbating cellular damage at the lesion site Administration of olomoucine peritoneally has been shown to suppress CDK function Further olomoucine has been shown to reduce neuronal cell death reduce astroglial proliferation and therefore reduce astrogliosis and increase GAP 43 expression a useful protein marker for neurite growth Moreover reduced astrocyte proliferation decreases expression of chondroitin sulfate proteoglycans CSPGs major extracellular matrix molecules associated with inhibition of neuroregneration after trauma to the CNS 20 Recent work has also shown that olomoucine suppresses microglial proliferation within the glial scar This is particularly important because microglia play an important role in the secondary damage following lesion to the CNS during the time of scar formation Microglial cells are activated via various pro inflammatory cytokines some discussed above Rat spinal cord injury models have shown remarkable improvements after the administration of olomoucine One hour post administration olomoucine suppressed microglial proliferation as well as reduced the tissue edema normally present during the early stages of glial scar formation Further 24 hours post administration a reduction in concentration of interleukin 1b was observed Additionally the administration of olomoucine has also been shown to decrease neuronal cell death 21 Inhibition of phosphodiesterase 4 PDE4 edit Phosphodiesterase 4 is a member of the phosphodiesterase family of proteins that cleave phosphodiester bonds This is an important step in degrading cyclic adenosine monophosphate cAMP a major intracellular signaling molecule conversely blocking PDE4 will increase cAMP Increased intracellular cAMP levels in neurons has been previously shown to induce axonal growth 22 In 2004 Nikulina et al showed that administration of rolipram a PDE4 inhibitor can increase cAMP levels in neurons after spinal cord injury This is partially possible because rolipram is sufficiently small to pass through the blood brain barrier and immediately begin to catalyze reactions in neurons 10 day administration of rolipram in spinal cord injured rodents resulted in considerable axonal growth associated with a reduction in glial scarring at 2 weeks post injury The mechanism for this reduction in glial scarring is currently unknown but possible mechanisms include axonal extensions that physically prevent reactive astrocytes from proliferating as well as chemical signaling events to reduce reactive astrogliosis 23 Ribavirin edit Ribavirin is a purine nucleoside analogue that is generally used as an anti viral medication However it has also been shown to decrease the amount of reactive astrocytes Daily administration for at least five days following brain trauma was shown to significantly decrease the number of reactive astrocytes 24 Antisense GFAP retrovirus edit An antisense GFAP retrovirus PLBskG to reduce GFAP mRNA expression has been implemented in suppressing growth and arresting astrocytes in the G1 phase of the cell cycle However a main caveat to the clinical application of retroviral use is the non discriminatory effects of PLBskG on normal as well as injured astrocytes Further in vivo studies are needed to determine the systemic effects of PLBskG administration 25 Recombinant monoclonal antibody to transforming growth factor b2 edit As noted in the above section transforming growth factor b2 TGFb2 is an important glial scar stimulant that directly affects astrocyte proliferation Logan et al developed monoclonal antibodies to TGFb2 cerebral wounds were generated in rat brains and the antibodies were administered via the ventricles daily for 10 days Subsequent analysis showed a marked reduction in glial scarring Particularly extracellular matrix protein deposition laminin fibronectin and chondroitin sulfate proteoglycans was closer to baseline levels of protein expression in an uninjured animal Further a reduction in astrocytes and microglia as well as a reduction in inflammation and angiogenesis were observed 26 Recombinant monoclonal antibody to interleukin 6 receptor edit Interleukin 6 IL 6 is thought to be a molecular mediator of glial scar formation It has been shown to promote differentiation of neural stem cells into astrocytes citation needed A monoclonal antibody MR16 1 has been used to target and block the IL 6 receptors in rat spinal cord injury models In a study by Okada et al mice were intraperitoneally injected with a single dose of MR16 1 immediately after generating a spinal cord injury Blockade of IL 6 receptors decreased the number of astrocytes present at the spinal cord lesion and this decrease was associated with a reduction in glial scarring 27 Glial scar treatment or removal editChondroitinase ABC has been shown to degrade glial scars 28 29 Degrading the glial scar with chondroitinase has been shown to promote recovery from spinal cord injury 30 especially when combined with other techniques such as nerve guidance conduits schwann cell transplants 31 and peripheral nerve autografts 32 See also editFibrosis Lesional demyelinations of the central nervous system Pathology of multiple sclerosisReferences edit Faulkner JR Herrmann JE Woo MJ Tansey KE Doan NB Sofroniew MV March 2004 Reactive astrocytes protect tissue and preserve function after spinal cord injury J Neurosci 24 9 2143 55 doi 10 1523 JNEUROSCI 3547 03 2004 PMC 6730429 PMID 14999065 a b c d e Stichel CC Muller HW October 1998 The CNS lesion scar new vistas on an old regeneration barrier Cell Tissue Res 294 1 1 9 doi 10 1007 s004410051151 PMID 9724451 S2CID 13652357 Jones LL Margolis RU Tuszynski MH August 2003 The chondroitin sulfate proteoglycans neurocan brevican phosphacan and versican are differentially regulated following spinal cord injury Exp Neurol 182 2 399 411 doi 10 1016 S0014 4886 03 00087 6 PMID 12895450 S2CID 16748373 14561854 Davies SJ Fitch MT Memberg SP Hall AK Raisman G Silver J 1997 Regeneration of adult axons in white matter tracts of the central nervous system Nature 390 6661 680 3 Bibcode 1997Natur 390 680D doi 10 1038 37776 PMID 9414159 S2CID 205026020 Silver Jerry 2004 Regeneration beyond the glial scar Nature Reviews Neuroscience 5 2 146 156 doi 10 1038 nrn1326 PMID 14735117 David S Ness R 1993 Heterogeneity of reactive astrocytes In Fedoroff S ed Biology and pathology of astrocyte neuron interactions Plenum Press New York pp 303 312 Fernaud Espinosa I Nieto Sampedro N Bovolenta P 1993 Differential activation of microglia and astrocytes in aniso and isomorphic gliotic tissue Glia 8 277 291 Elkabes S DiCicco Bloom EM Black IB 1996 Brain microglia macrophages express neurotrophins that selectively regulate microglial proliferation and function Journal of Neuroscience 16 2508 2521 Jaeger CB Blight AR 1997 Spinal compression injury in guinea pigs structural changes of endothelium and its perivascular cell associations after blood brain barrier breakdown and repair Experimental Neurology 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21753849 Retrieved from https en wikipedia org w index php title Glial scar amp oldid 1134480359 Reactive astrocytes, wikipedia, wiki, book, books, library,

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