The neuro-glial coagulonome: the thrombin receptor and coagulation pathways as major players in neurological diseases

The neuro-glial interface extends far beyond mechanical support alone and includes interactions throu-gh coagulation cascade proteins. Here, we systematically review the evidence indicating that synaptic and node of Ranvier glia cell components modulate synaptic transmission and axonal conduction by...

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Main Authors: Shany G Gofrit, Efrat Shavit-Stein
Format: Article
Language:English
Published: Wolters Kluwer Medknow Publications 2019-01-01
Series:Neural Regeneration Research
Subjects:
Online Access:http://www.nrronline.org/article.asp?issn=1673-5374;year=2019;volume=14;issue=12;spage=2043;epage=2053;aulast=Gofrit
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spelling doaj-dd4d4f2b50f740328dcda822d8677eba2020-11-25T03:43:01ZengWolters Kluwer Medknow PublicationsNeural Regeneration Research1673-53742019-01-0114122043205310.4103/1673-5374.262568The neuro-glial coagulonome: the thrombin receptor and coagulation pathways as major players in neurological diseasesShany G GofritEfrat Shavit-SteinThe neuro-glial interface extends far beyond mechanical support alone and includes interactions throu-gh coagulation cascade proteins. Here, we systematically review the evidence indicating that synaptic and node of Ranvier glia cell components modulate synaptic transmission and axonal conduction by a coagulation cascade protein system, leading us to propose the concept of the neuro-glial coagulonome. In the peripheral nervous system, the main thrombin receptor protease activated receptor 1 (PAR1) is located on the Schwann microvilli at the node of Ranvier and at the neuromuscular junction. PAR1 activation effects can be both neuroprotective or harmful, depending on thrombin activity levels. Low physiological levels of thrombin induce neuroprotective effects in the Schwann cells which are mediated by the endothelial protein C receptor. High levels of thrombin induce conduction deficits, as found in experimental autoimmune neuritis, the animal model for Guillaine-Barre syndrome. In the central nervous system, PAR1 is located on the peri-synaptic astrocyte end-feet. Its activation by high thrombin levels is involved in the pathology of primary inflammatory brain diseases such as multiple sclerosis, as well as in other central nervous system insults, including trauma, neoplasms, epilepsy and vascular injury. Following activation of PAR1 by high thrombin levels the seizure threshold is lowered. On the other hand, PAR1 activation by lower levels of thrombin in the central nervous system protects against a future ischemic insult. This review presents the known structure and function of the neuro-glial coagulonome, focusing on coagulation, thrombin and PAR1 in a pathway which may be either physiological (neuroprotective) or detrimental in peripheral nervous system and central nervous system diseases. Understanding the neuro-glial coagulonome may open opportunities for novel pharmacological interventions in neurological diseases.http://www.nrronline.org/article.asp?issn=1673-5374;year=2019;volume=14;issue=12;spage=2043;epage=2053;aulast=Gofritthrombin; protease activated receptor 1; protease nexin 1; glia; node of Ranvier; synapse; epilepsy; glioblastoma; Guillaine-Barre syndrome
collection DOAJ
language English
format Article
sources DOAJ
author Shany G Gofrit
Efrat Shavit-Stein
spellingShingle Shany G Gofrit
Efrat Shavit-Stein
The neuro-glial coagulonome: the thrombin receptor and coagulation pathways as major players in neurological diseases
Neural Regeneration Research
thrombin; protease activated receptor 1; protease nexin 1; glia; node of Ranvier; synapse; epilepsy; glioblastoma; Guillaine-Barre syndrome
author_facet Shany G Gofrit
Efrat Shavit-Stein
author_sort Shany G Gofrit
title The neuro-glial coagulonome: the thrombin receptor and coagulation pathways as major players in neurological diseases
title_short The neuro-glial coagulonome: the thrombin receptor and coagulation pathways as major players in neurological diseases
title_full The neuro-glial coagulonome: the thrombin receptor and coagulation pathways as major players in neurological diseases
title_fullStr The neuro-glial coagulonome: the thrombin receptor and coagulation pathways as major players in neurological diseases
title_full_unstemmed The neuro-glial coagulonome: the thrombin receptor and coagulation pathways as major players in neurological diseases
title_sort neuro-glial coagulonome: the thrombin receptor and coagulation pathways as major players in neurological diseases
publisher Wolters Kluwer Medknow Publications
series Neural Regeneration Research
issn 1673-5374
publishDate 2019-01-01
description The neuro-glial interface extends far beyond mechanical support alone and includes interactions throu-gh coagulation cascade proteins. Here, we systematically review the evidence indicating that synaptic and node of Ranvier glia cell components modulate synaptic transmission and axonal conduction by a coagulation cascade protein system, leading us to propose the concept of the neuro-glial coagulonome. In the peripheral nervous system, the main thrombin receptor protease activated receptor 1 (PAR1) is located on the Schwann microvilli at the node of Ranvier and at the neuromuscular junction. PAR1 activation effects can be both neuroprotective or harmful, depending on thrombin activity levels. Low physiological levels of thrombin induce neuroprotective effects in the Schwann cells which are mediated by the endothelial protein C receptor. High levels of thrombin induce conduction deficits, as found in experimental autoimmune neuritis, the animal model for Guillaine-Barre syndrome. In the central nervous system, PAR1 is located on the peri-synaptic astrocyte end-feet. Its activation by high thrombin levels is involved in the pathology of primary inflammatory brain diseases such as multiple sclerosis, as well as in other central nervous system insults, including trauma, neoplasms, epilepsy and vascular injury. Following activation of PAR1 by high thrombin levels the seizure threshold is lowered. On the other hand, PAR1 activation by lower levels of thrombin in the central nervous system protects against a future ischemic insult. This review presents the known structure and function of the neuro-glial coagulonome, focusing on coagulation, thrombin and PAR1 in a pathway which may be either physiological (neuroprotective) or detrimental in peripheral nervous system and central nervous system diseases. Understanding the neuro-glial coagulonome may open opportunities for novel pharmacological interventions in neurological diseases.
topic thrombin; protease activated receptor 1; protease nexin 1; glia; node of Ranvier; synapse; epilepsy; glioblastoma; Guillaine-Barre syndrome
url http://www.nrronline.org/article.asp?issn=1673-5374;year=2019;volume=14;issue=12;spage=2043;epage=2053;aulast=Gofrit
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