A novel transgenic reporter mouse line of astrocyte-derived small extracellular vesicles for investigating intercellular communication in vivo

Authors

Zhongwu Liu, Henry Ford HealthFollow
Yi Zhang, Henry Ford HealthFollow
Amy Kemper, Henry Ford HealthFollow
Yanfeng Li, Henry Ford HealthFollow
Andrew C. Dudley
Michael Chopp, Henry Ford HealthFollow
Zhenggang Zhang, Henry Ford HealthFollow

Recommended Citation

Liu Z, Zhang Y, Kemper A, Li Y, Dudley AC, Chopp M, Zhang ZG. A novel transgenic reporter mouse line of astrocyte-derived small extracellular vesicles for investigating intercellular communication in vivo. J Neurosci Methods. 2026;429:110705.

Document Type

Article

Publication Date

5-1-2026

Publication Title

Journal of neuroscience methods

Keywords

Animals, Astrocytes, Mice, Transgenic, Extracellular Vesicles, Cell Communication, Mice, Tamoxifen, Tetraspanin 30, Green Fluorescent Proteins, Glial Fibrillary Acidic Protein, Brain, Spinal Cord, Neurons, Genes, Reporter

Abstract

BACKGROUND: Small extracellular vesicles (sEVs) mediate intercellular communication in the central nervous system, regulating processes ranging from homeostatic maintenance to injury repair. Although astrocytes are a major source of sEVs in the brain, in vivo investigation of their endogenous and cell-specific signaling remains technically challenging.

NEW METHOD: To address this limitation, we developed a novel inducible transgenic reporter mouse line, GFAP-CD63-GFP, that enables specific labeling of astrocyte-derived sEVs. The mouse line was generated by crossing GFAP-CreERT2 mice with CD63-emGFPloxP/stop/loxP mice. This system enables Tamoxifen-inducible, astrocyte-specific expression of GFP-tagged CD63, a tetraspanin enriched in sEVs. The model allows visualization and quantification of astrocyte-derived CD63-positive sEVs in vivo.

RESULTS: Following Tamoxifen induction, GFP expression was robustly detected in the brain and spinal cord. Immunogold transmission electron microscopy further identified GFP-positive sEVs within neurons, providing ultrastructural evidence of astrocyte-to-neuron vesicle transfer. As a proof-of-concept, ischemic stroke significantly increased astrocyte-derived sEVs in the ipsilesional cerebral hemisphere and the stroke-impaired side of the spinal cord, accompanied by enhanced neuronal endocytosis.

COMPARISON WITH EXISTING METHODS: Current approaches rely primarily on in vitro EV isolation or nonspecific membrane dyes. The GFAP-CD63-GFP model enables cell type-specific, temporally controlled, and in situ tracking of astrocyte-derived sEVs.

CONCLUSIONS: These findings provide the first in vivo demonstration of increased astrocyte-to-neuron sEV communication during post-stroke recovery. The GFAP-CD63-GFP reporter mouse thus provides a powerful platform for investigating astrocyte-derived sEV signaling under both physiological and pathophysiological conditions of the CNS.

Medical Subject Headings

Animals; Astrocytes; Mice, Transgenic; Extracellular Vesicles; Cell Communication; Mice; Tamoxifen; Tetraspanin 30; Green Fluorescent Proteins; Glial Fibrillary Acidic Protein; Brain; Spinal Cord; Neurons; Genes, Reporter

PubMed ID

41654312

Volume

429

First Page

110705

Last Page

110705