Energy Metabolism Supports Molecular and Functional Heterogeneity of Reactive Astrocytes in Central Nervous System Disorders.

Abstract

Astrocytes undergo a reactive transformation in central nervous system (CNS) disorders, manifesting significant heterogeneity in morphology, molecules, function, and spatial distribution. Just like all cells, astrocytes necessitate energy for their basic functions. Energy production proves critical for the survival and development of astrocytes, as well as their fate determination and functional diversity. The activation process of astrocytes involves a metabolic shift in energy, yet our understanding of how this change impacts the heterogeneity of reactive astrocytes remains limited. In this comprehensive review, we begin by outlining the advancements in research on reactive astrocytes in CNS disorders, establishing a crucial association between the energy metabolism of reactive astrocytes and their molecular and functional aspects. Following this, we delve into a thorough analysis of the energy metabolic transitions of reactive astrocytes within the context of CNS diseases. Starting from the essential pathways of energy metabolism, we present a novel perspective, shedding light on the molecular and functional heterogeneity of reactive astrocytes by considering the heterogeneity in energy metabolism. In conclusion, we propose that the modulation of energy metabolism in reactive astrocytes, coupled with the promotion of their functionality toward disease recovery, represents a cutting-edge and promising strategy for the treatment of CNS diseases.