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Distinct cell type-specific protein signatures in GRN and MAPT genetic subtypes of frontotemporal dementia
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Distinct cell type-specific protein signatures in GRN and MAPT genetic subtypes of frontotemporal dementia
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Distinct cell type-specific protein signatures in GRN and MAPT genetic subtypes of frontotemporal dementia
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Journal Article
Distinct cell type-specific protein signatures in GRN and MAPT genetic subtypes of frontotemporal dementia
2022
Overview
Frontotemporal dementia is characterized by progressive atrophy of frontal and/or temporal cortices at an early age of onset. The disorder shows considerable clinical, pathological, and genetic heterogeneity. Here we investigated the proteomic signatures of frontal and temporal cortex from brains with frontotemporal dementia due to
GRN
and
MAPT
mutations to identify the key cell types and molecular pathways in their pathophysiology. We compared patients with mutations in the
GRN
gene (n = 9) or with mutations in the
MAPT
gene (n = 13) with non-demented controls (n = 11). Using quantitative proteomic analysis on laser-dissected tissues we identified brain region-specific protein signatures for both genetic subtypes. Using published single cell RNA expression data resources we deduced the involvement of major brain cell types in driving these different protein signatures. Subsequent gene ontology analysis identified distinct genetic subtype- and cell type-specific biological processes. For the
GRN
subtype, we observed a distinct role for immune processes related to endothelial cells and for mitochondrial dysregulation in neurons. For the
MAPT
subtype, we observed distinct involvement of dysregulated RNA processing, oligodendrocyte dysfunction, and axonal impairments. Comparison with an in-house protein signature of Alzheimer’s disease brains indicated that the observed alterations in RNA processing and oligodendrocyte function are distinct for the frontotemporal dementia
MAPT
subtype. Taken together, our results indicate the involvement of different brain cell types and biological mechanisms in genetic subtypes of frontotemporal dementia. Furthermore, we demonstrate that comparison of proteomic profiles of different disease entities can separate general neurodegenerative processes from disease-specific pathways, which may aid the development of disease subtype-specific treatment strategies.
