Early reduction and impaired targeting of myelin-associated glycoprotein to myelin membranes in Huntington’s disease

  1. Adel Boudi
  2. Ellen Sapp
  3. Yvonnie Y Li
  4. Kai Lee Shing
  5. Kimberly Kegel-Gleason
  6. Tiziana Petrozziello
  7. Ghazaleh Sadri-Vakili
  8. Neil Aronin
  9. Marian DiFiglia
  10. Xueyi Li
0 evaluations Published on
Read the full article Related papers
This article on Sciety

Abstract

Background

Huntington’s disease (HD) is a hereditary life-threatening disease marked by progressive neuronal loss and atrophy of grey matter structures, particularly the caudate putamen. Brain imaging studies have revealed that the degradation of the white matter occurs many years prior to symptomatic onset and neuronal loss, suggesting that the decay of brain white matter is an active contributor to the disease progression. However, the mechanisms by which the HD mutation triggers white matter loss is not well understood.

Methods

Western blot, immunohistochemistry, and electron microscopy were conducted to assess white matter pathology and explore the relevant mechanisms in CAG140 knock-in mice, which express the HD protein in the same way as patients suffering from HD and thus biologically replicate HD in human.

Results

Western blot analysis of proteins localized at different layers of the myelin coat revealed that the myelin-associated glycoprotein (MAG), which is localized at the innermost layer of the myelin coat and essential for maintaining the periaxonal space and the integrity of the myelin sheath, manifested as an early and progressive decline in HD mouse caudate putamen. The loss of MAG was detected at myelinated axons and in fiber bundles in HD mouse brains at an age when the abundance of myelinated axons was normal. Fluorescence immunohistochemical studies found that MAG labeling was concentrated in the soma of a subset of oligodendrocytes, which expressed breast carcinoma amplified sequence 1, a marker for new oligodendrocytes. While their abundance was normal, new oligodendrocytes in HD mouse caudate appeared to be impeded in acquiring the expression of MAG and in targeting MAG away from perinuclear punctate structures to processes, signs of impaired maturation. Compared with those in wildtype mouse brains, oligodendrocytes in HD mouse brains had a reduced abundance of small vesicles whereas an increased abundance of large punctate structures in the perinuclear region, implying defective generation of small vesicles transporting MAG from large punctate structures in the soma to processes. The MAG-containing perinuclear punctate structures were negative for proteins specifying trans-Golgi networks, early endosomes, or exosomes but had a minor portion labeled with lysosome-associated membrane protein 1, indicating that the structures where MAG accumulates in the soma are derived from the late endosomal lysosomal compartment.

Conclusions

Our study suggests that the decay of the brain white matter in Huntington’s disease involves a deficit in trafficking of myelin-associated glycoprotein, preventing its proper delivery from the soma of oligodendrocytes to myelin-forming processes.

Related articles

Related articles are currently not available for this article.