@article{10.37349/en.2025.1006118,
abstract = {Neurological disorders constitute a major global health burden with limited effective treatments. Despite advances in molecular neuroscience, critical gaps persist in understanding intercellular communication systems underlying central nervous system homeostasis and neurodegeneration. Extracellular vesicles (EVs), nanoscale to microscale membrane-bound vesicles secreted by virtually all cell types, have emerged as pivotal mediators of intercellular communication in neurological pathologies. This review examines molecular mechanisms governing EV biogenesis, cargo selection, and pathological functions in neurological disorders, emphasizing the emerging role of ubiquitin-like protein 3 (UBL3) as a novel regulator of EV-mediated protein sorting. Neural cell populations produce specialized EV subtypes containing distinct molecular cargo reflecting their physiological states. UBL3, a membrane-anchored post-translational modifier, operates through geranylgeranylation-dependent mechanisms to promote selective protein incorporation into small EVs (sEVs), with knockout studies demonstrating approximately 60% reduction in EV protein content. Proteomic analyses reveal UBL3 interacts with over 1,200 proteins, with ~30% classified as EV cargo proteins. Critically, UBL3-mediated sorting influences disease-associated protein trafficking, including α-synuclein in Parkinson’s disease and mutant huntingtin in Huntington’s disease, suggesting involvement in prion-like spreading mechanisms. EVs’ dual nature as pathological mediators and therapeutic vehicles represents a paradigm shift in neurological medicine. EVs offer advantages as natural drug delivery systems capable of crossing the blood-brain barrier, accessible biomarkers for noninvasive disease monitoring via liquid biopsies (achieving diagnostic accuracies exceeding 0.88 ROC-AUC), and engineered therapeutic platforms for delivering CRISPR-Cas9 systems and neuroprotective factors. However, clinical translation requires addressing challenges, including standardizing isolation protocols, elucidating cell-type-specific cargo sorting mechanisms, and defining optimal administration routes. Understanding UBL3-mediated cargo sorting mechanisms presents promising therapeutic opportunities by selectively modulating pathogenic protein trafficking. EVs, positioned at the intersection of pathogenesis and therapy, represent attractive targets for precision medicine approaches in neurological conditions, with UBL3 emerging as a novel molecular handle for manipulating EV composition and function.},
author = {Mimi, Mst. Afsana and Hasan, Md. Mahmudul},
doi = {10.37349/en.2025.1006118},
journal = {Exploration of Neuroscience},
elocation-id = {1006118},
title = {Extracellular vesicles in neurological disorders: emerging roles and underlying molecular mechanisms},
url = {https://www.explorationpub.com/Journals/en/Article/1006118},
volume = {4},
year = {2025}
}