Litcius/Paper detail

Astrocytic potassium and calcium channels as integrators of the inflammatory and ischemic CNS microenvironment

Samantha Schmaul, Nicholas Hanuscheck, Stefan Bittner

2021Biological Chemistry13 citationsDOI

Abstract

Abstract Astrocytes are key regulators of their surroundings by receiving and integrating stimuli from their local microenvironment, thereby regulating glial and neuronal homeostasis. Cumulating evidence supports a plethora of heterogenic astrocyte subpopulations that differ morphologically and in their expression patterns of receptors, transporters and ion channels, as well as in their functional specialisation. Astrocytic heterogeneity is especially relevant under pathological conditions. In experimental autoimmune encephalomyelitis (EAE), a mouse model of multiple sclerosis (MS), morphologically distinct astrocytic subtypes were identified and could be linked to transcriptome changes during different disease stages and regions. To allow for continuous awareness of changing stimuli across age and diseases, astrocytes are equipped with a variety of receptors and ion channels allowing the precise perception of environmental cues. Recent studies implicate the diverse repertoire of astrocytic ion channels – including transient receptor potential channels, voltage-gated calcium channels, inwardly rectifying K + channels, and two-pore domain potassium channels – in sensing the brain state in physiology, inflammation and ischemia. Here, we review current evidence regarding astrocytic potassium and calcium channels and their functional contribution in homeostasis, neuroinflammation and stroke.

Topics & Concepts

NeuroscienceExperimental autoimmune encephalomyelitisIon channelNeuroinflammationAstrocyteTransient receptor potential channelBiologyMultiple sclerosisVoltage-dependent calcium channelHomeostasisReceptorMicrogliaCell biologyInflammationCalciumChemistryImmunologyCentral nervous systemBiochemistryOrganic chemistryNeuroinflammation and Neurodegeneration MechanismsNeuroscience and Neuropharmacology ResearchIon Channels and Receptors