Large‐scale electron microscopic volume imaging of interfascicular oligodendrocytes in the mouse corpus callosum

Single oligodendrocytes produce myelin sheaths around multiple axons in the central nervous system. Interfascicular oligodendrocytes (IOs) facilitate nerve conduction, but their detailed morphologies remain largely unknown. In the present study, we three‐dimensionally reconstructed IOs in the corpus...

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Bibliographic Details
Published in:Glia 2021-10, Vol.69 (10), p.2488-2502
Main Authors: Tanaka, Tatsuhide, Ohno, Nobuhiko, Osanai, Yasuyuki, Saitoh, Sei, Thai, Truc Quynh, Nishimura, Kazuya, Shinjo, Takeaki, Takemura, Shoko, Tatsumi, Kouko, Wanaka, Akio
Format: Article
Language:English
Subjects:
Animals
axon
Axons
Axons - physiology
Cell body
Central nervous system
Corpus callosum
Corpus Callosum - metabolism
Cytoplasm
Diameters
Electrons
Mice
Morphology
Myelin
Myelin Sheath - metabolism
Myelination
Nerve conduction
oligodendrocyte
Oligodendrocytes
Oligodendroglia - metabolism
Rabies
SBF‐SEM
Scanning electron microscopy
Sheaths
Statistical analysis
Thickness
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Summary:Single oligodendrocytes produce myelin sheaths around multiple axons in the central nervous system. Interfascicular oligodendrocytes (IOs) facilitate nerve conduction, but their detailed morphologies remain largely unknown. In the present study, we three‐dimensionally reconstructed IOs in the corpus callosum of adult mouse using serial block face scanning electron microscopy. The cell bodies of IOs were morphologically polarized and extended thick processes from the cytoplasm‐rich part of the cell. Processes originating from the cell body of each IO can be classified into two types: one myelinates an axon without branching, while the other type branches and each branch myelinates a distinct axon. Myelin sheaths originating from a particular IO have biased thicknesses, wrapping axons of a limited range of diameters. Consistent with this finding, IOs transduced and visualized with a rabies viral vector expressing GFP showed statistically significant variation in their myelination patterns. We further reconstructed the sheath immediately adjacent to that derived from each of the analyzed IOs; the thicknesses of the pair of sheaths were significantly correlated despite emanating from different IOs. These results suggest that a single axon could regulate myelin sheath thicknesses, even if the sheaths are derived from distinct IOs. Collectively, our results indicate that the IOs have their own myelin profiles defined by myelin thickness and axonal diameter although axons may regulate thickness of myelin sheath. MAIN POINTS IOs extend a thick process from the cytoplasm‐rich part of the cell. Each IO myelinates multiple axons with biased myelin thicknesses. Adjacent myelin sheaths are of similar thickness, implying an axonal influence on sheath thickness.
ISSN:0894-1491
1098-1136
DOI:10.1002/glia.24055