Acta Neuropathologica Communications (Aug 2024)

A deep phenotyping study in mouse and iPSC models to understand the role of oligodendroglia in optic neuropathy in Wolfram syndrome

  • K. Ahuja,
  • M. Vandenabeele,
  • F. Nami,
  • E. Lefevere,
  • J. Van hoecke,
  • S. Bergmans,
  • M. Claes,
  • T. Vervliet,
  • K. Neyrinck,
  • T. Burg,
  • D. De Herdt,
  • P. Bhaskar,
  • Y. Zhu,
  • Z. J. Looser,
  • J. Loncke,
  • W. Gsell,
  • M. Plaas,
  • P. Agostinis,
  • J. V. Swinnen,
  • L. Van Den Bosch,
  • G. Bultynck,
  • A. S. Saab,
  • E. Wolfs,
  • Y. C. Chai,
  • U. Himmelreich,
  • C. Verfaillie,
  • L. Moons,
  • L. De Groef

DOI
https://doi.org/10.1186/s40478-024-01851-7
Journal volume & issue
Vol. 12, no. 1
pp. 1 – 23

Abstract

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Abstract Wolfram syndrome (WS) is a rare childhood disease characterized by diabetes mellitus, diabetes insipidus, blindness, deafness, neurodegeneration and eventually early death, due to autosomal recessive mutations in the WFS1 (and WFS2) gene. While it is categorized as a neurodegenerative disease, it is increasingly becoming clear that other cell types besides neurons may be affected and contribute to the pathogenesis. MRI studies in patients and phenotyping studies in WS rodent models indicate white matter/myelin loss, implicating a role for oligodendroglia in WS-associated neurodegeneration. In this study, we sought to determine if oligodendroglia are affected in WS and whether their dysfunction may be the primary cause of the observed optic neuropathy and brain neurodegeneration. We demonstrate that 7.5-month-old Wfs1 ∆exon8 mice display signs of abnormal myelination and a reduced number of oligodendrocyte precursor cells (OPCs) as well as abnormal axonal conduction in the optic nerve. An MRI study of the brain furthermore revealed grey and white matter loss in the cerebellum, brainstem, and superior colliculus, as is seen in WS patients. To further dissect the role of oligodendroglia in WS, we performed a transcriptomics study of WS patient iPSC-derived OPCs and pre-myelinating oligodendrocytes. Transcriptional changes compared to isogenic control cells were found for genes with a role in ER function. However, a deep phenotyping study of these WS patient iPSC-derived oligodendroglia unveiled normal differentiation, mitochondria-associated endoplasmic reticulum (ER) membrane interactions and mitochondrial function, and no overt signs of ER stress. Overall, the current study indicates that oligodendroglia functions are largely preserved in the WS mouse and patient iPSC-derived models used in this study. These findings do not support a major defect in oligodendroglia function as the primary cause of WS, and warrant further investigation of neurons and neuron-oligodendroglia interactions as a target for future neuroprotective or -restorative treatments for WS.

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