Internalization of exogenous myelin by oligodendroglia promotes lineage progression

Oligodendrocytes, traditionally recognized for their role in central nervous system myelination, have emerged during the last decades as key participants maintaining brain homoeostasis in response to metabolic demands and stress. In addition, injury to myelin prompts a regenerative response that leads to the formation of new myelin sheaths. However, the signals regulating effective remyelination by oligodendrocytes are still not completely understood. Here, we report that oligodendrocytes can internalize exogenous myelin both in vitro and in vivo, which leads to an increase in their proliferation and differentiation when their functions are not compromised. RNA sequencing reveals that myelin debris alters oligodendrocyte transcriptional profile, suppressing immune-related pathways and de novo cholesterol and fatty acid biosynthesis, while inducing lipid droplet formation to store and process internalized myelin particles. As a result, progression of the oligodendroglial lineage is enhanced in primary cell cultures, as shown by increased viability, proliferation and differentiation. Oligodendrocytes also acquire a more differentiated phenotype, with larger cell areas, a more complex morphology and myelination of synthetic nanofibers. Stereotaxic injection of fluorescent myelin into mouse cortex shows internalization by microglia and, to a lesser extent, by oligodendroglia. Notably, in the zebrafish model, ventricular injections of myelin also increase the number of ventral oligodendrocytes in the spinal cord, further supporting that myelin can promote lineage progression. These findings challenge the classical view that myelin debris intrinsically inhibits oligodendrocyte proliferation, suggesting instead that oligodendrocytes can use myelin to support self-renewal and maturation, acting as a trophic factor in the absence of pathological cues.