Late motor decline after accomplished remyelination: impact for progressive multiple sclerosis.

OBJECTIVE: To investigate the impact of single or repeated episodes of reversible demyelination on long-term locomotor performance and neuroaxonal integrity, and to analyze the myelin proteome after remyelination and during aging. METHODS: Long-term locomotor performance of previously cuprizone-treated animals was monitored using the motor skill sequence (MOSS). Quantitative analysis of myelin proteome and histopathological analysis of neuronal/axonal integrity was performed after successful remyelination. Histopathological findings observed in experimental chronic remyelinated lesions were verified in chronic remyelinated lesions from multiple sclerosis (MS) patients. RESULTS: Following cessation of cuprizone treatment, animals showed an initial recovery of locomotor performance. However, long after remyelination was completed (approximately 6 months after the last demyelinating episode), locomotor performance again declined in remyelinated animals as compared to age-matched controls. This functional decline was accompanied by brain atrophy and callosal axonal loss. Furthermore, the number of acutely damaged amyloid precursor protein-positive (APP+) axons was still significantly elevated in long-term remyelinated animals as compared to age-matched controls. Confocal analysis revealed that a substantial proportion of these APP+ spheroids were ensheathed by myelin, a finding that was confirmed in the chronic remyelinated lesions of MS patients. Moreover, quantitative analysis of myelin proteome revealed that remyelinated myelin displays alterations in composition that are in some aspects similar to the myelin of older animals. INTERPRETATION: We propose that even after completed remyelination, axonal degeneration continues to progress at a low level, accumulating over time, and that once a threshold is passed axonal degeneration can become functionally apparent in the long-term. The presented model thus mimics some of the aspects of axonal degeneration in chronic progressive MS.

Cell type- and brain region-resolved mouse brain proteome.

Brain transcriptome and connectome maps are being generated, but an equivalent effort on the proteome is currently lacking. We performed high-resolution mass spectrometry-based proteomics for in-depth analysis of the mouse brain and its major brain regions and cell types. Comparisons of the 12,934 identified proteins in oligodendrocytes, astrocytes, microglia and cortical neurons with deep sequencing data of the transcriptome indicated deep coverage of the proteome. Cell type-specific proteins defined as tenfold more abundant than average expression represented about a tenth of the proteome, with an overrepresentation of cell surface proteins. To demonstrate the utility of our resource, we focused on this class of proteins and identified Lsamp, an adhesion molecule of the IgLON family, as a negative regulator of myelination. Our findings provide a framework for a system-level understanding of cell-type diversity in the CNS and serves as a rich resource for analyses of brain development and function.

Targeted ablation of oligodendrocytes triggers axonal damage.

Glial dysfunction has been implicated in a number of neurodegenerative diseases. In this study we investigated the consequences of glial and oligodendrocyte ablation on neuronal integrity and survival in Drosophila and adult mice, respectively. Targeted genetic ablation of glia was achieved in the adult Drosophila nervous system using the GAL80-GAL4 system. In mice, oligodendrocytes were depleted by the injection of diphtheria toxin in MOGi-Cre/iDTR double transgenic animals. Acute depletion of oligodendrocytes induced axonal injury, but did not cause neuronal cell death in mice. Ablation of glia in adult flies triggered neuronal apoptosis and resulted in a marked reduction in motor performance and lifespan. Our study shows that the targeted depletion of glia triggers secondary neurotoxicity and underscores the central contribution of glia to neuronal homeostasis. The models used in this study provide valuable systems for the investigation of therapeutic strategies to prevent axonal or neuronal damage.

Regulation of exosome secretion by Rab35 and its GTPase-activating proteins TBC1D10A-C.

Oligodendrocytes secrete vesicles into the extracellular space, where they might play a role in neuron-glia communication. These exosomes are small vesicles with a diameter of 50-100 nm that are formed within multivesicular bodies and are released after fusion with the plasma membrane. The intracellular pathways that generate exosomes are poorly defined. Because Rab family guanosine triphosphatases (GTPases) together with their regulators are important membrane trafficking organizers, we investigated which Rab GTPase-activating proteins interfere with exosome release. We find that TBC1D10A-C regulate exosome secretion in a catalytic activity-dependent manner. We show that Rab35 is the target of TBC1D10A-C and that the inhibition of Rab35 function leads to intracellular accumulation of endosomal vesicles and impairs exosome secretion. Rab35 localizes to the surface of oligodendroglia in a GTP-dependent manner, where it increases the density of vesicles, suggesting a function in docking or tethering. These findings provide a basis for understanding the biogenesis and function of exosomes in the central nervous system.