Background: Neurodegenerative disorders impose a growing global burden, yet disease-modifying therapies remain limited. Glial fibrillary acidic protein (GFAP) has shifted from a passive astrocytic marker to an active effector that shapes neurodegenerative pathology.
Aim: of Review: This review synthesizes mechanistic and translational evidence that defines GFAP as a proteoform-governed hub and highlights its value for biomarker-guided precision intervention. Key Scientific Concepts of Review: An extensive literature search across major databases was conducted using predefined keywords and strict inclusion criteria, covering mechanistic, pathological, and clinical studies. Evidence supports a GFAP proteoform code in which alternative splicing generates functionally distinct isoforms, and PTMs encode context-dependent assembly dynamics and signaling outputs. We summarize how GFAP proteoforms integrate cytoskeletal remodeling with inflammatory transcriptional programs (notably STAT3 and NF-κB), proteostasis stress, and mitochondrial dysfunction, thereby coupling astrocyte state transitions to neuronal vulnerability and synaptic impairment. Disease trajectories are context-specific: GFAP dysfunction drives primary toxicity in Alexander disease (AxD); in Alzheimer's disease (AD), isoform-specific mechanisms intersect with amyloidogenic machinery and track early preclinical astrocyte activation; and in frontotemporal dementia (FTD), Parkinson's disease (PD) and amyotrophic lateral sclerosis (ALS), GFAP reflects inflammatory-metabolic coupling during progression. Translationally, ultrasensitive plasma assays reveal GFAP elevation years to decades before symptom onset, complementing NfL and amyloid/tau within AT(N)-oriented diagnostic frameworks. Therapeutically, we evaluate precision strategies beyond global suppression, including ASO-based modulation, targeting STAT3/NF-κB-driven reactive programs, and restoring proteostasis via chaperone/autophagy pathways. Future progress hinges on isoform-/PTM-specific probes, conformational sensors, and spatial proteomic atlases validated in prospective longitudinal cohorts. In conclusion, GFAP represents both a mechanistic driver and a scalable biomarker, offering a translationally actionable axis to advance precision medicine in neurodegeneration.
Keywords: Astrocyte reactivity; GFAP; Plasma biomarkers; Proteoforms; Therapeutic targeting.
Copyright © 2026 The Author(s). Published by Elsevier B.V. All rights reserved.