Oligodendrocyte differentiation on murine decellularized brain tissue

Neurosci Lett. 2024 Dec 9:846:138079. doi: 10.1016/j.neulet.2024.138079. Online ahead of print.

Abstract

Loss of oligodendrocytes causes severe neurological damage. Oligodendrogenesis is the production of new oligodendrocytes throughout life and includes several developmental stages starting from oligodendrocyte precursor cells (OPCs). The GPR17-expressing cell population, an important intermediate stage in oligodendrocyte development, acts as a reservoir responding to brain injury and ischemia. GPR17 plays a complex role in oligodendrocyte maturation and response to injury; its activation promotes differentiation into more mature phenotypes. However, our understanding of GPR17-expressing oligodendrocytes in vitro remains limited. No methods have been elucidated for studying these short-lived and changeable cell populations using culture systems. The extracellular matrix (ECM) plays an important role in regulating the proliferation and differentiation of these cells; however, conventional two-dimensional culture systems cannot reproduce the complex structure and environmental conditions of the ECM in vivo. Herein, a culture system with decellularized brain tissue that retains organized ECM scaffolds was introduced to better mimic the in vivo environment. This system enabled the study of interactions between OPCs, ECM, and other cell types. Neurospheres containing progenitor cells that differentiate into oligodendrocyte lineage cells, neurons, and astrocytes were transplanted into decellularized brain slices. The results showed that this method not only promoted stem cell differentiation but also significantly enhanced differentiation into oligodendrocytes when supplemented with oligo buffer. This model system provides a better understanding of the interaction between OPCs and the ECM and a novel approach for studying the differentiation of GPR17-expressing cells, which may be useful for future therapeutic strategies for promoting remyelination and central nervous system repair.

Keywords: Chondroitin sulfate chains; Decellularization; Extracellular matrix; Oligodendrocyte.