Data related to "Human TDP-43 expression worsens FTD-related phenotypes in progranulin-insufficient mice"

Authors

Anna K. Cook, University of Alabama at Birmingham
Benjamin Lin, University of Alabama at Birmingham
Kelsey M. Greathouse, University of Alabama at Birmingham
Azariah K. Kaplelach, University of Alabama at Birmingham
Skylar E. Davis, University of Alabama at Birmingham
Anna C. Stoll, University of Alabama at Birmingham
Justin A. Hall, University of Alabama at Birmingham
Ahmad R. Hakim, University of Alabama at Birmingham
Jakub F. Hel, University of Alabama at Birmingham
Giacynta A. Vollmer, University of Alabama at Birmingham
Alexandria C. Howard, University of Alabama at Birmingham
Noelle H. Cooper, University of Alabama at Birmingham
Phaedra N. Manuel, University of Alabama at Birmingham
Juliana M. Eberhardt, University of Alabama at Birmingham
C. Ryan Miller, University of Alabama at Birmingham
Ashley S. Harms, University of Alabama at Birmingham
Jeremy H. Herskowitz, University of Alabama at Birmingham
Andrew E. Arrant, University of Alabama at Birmingham

Publication Date

9-27-2025

Abstract

Loss-of-function progranulin (GRN) mutations cause frontotemporal dementia with TDP-43 pathology (FTD-TDP). Nearly all pathogenic GRN mutations cause progranulin haploinsufficiency, but it is unclear how progranulin insufficiency causes FTD-TDP. To address this question, we crossed progranulin-insufficient mice with a human TDP-43 transgenic mouse line (RRID:IMSR_JAX:012836) in which homozygous mice (hTDP++) develop TDP-43 aggregates at an early age, but hemizygous mice (hTDP+) do not. Despite observing no change in TDP-43 aggregation with Grn genotype in hTDP+ or hTDP++ mice, we found that human TDP-43 expression worsened FTD-related phenotypes in progranulin-insufficient mice. Human TDP-43 expression worsened social dominance behavior in Grn^+/− mice, which was associated with dendritic spine abnormalities in medial prefrontal cortex (mPFC). Human TDP-43 also had distinct effects on RNA splicing in frontal cortex of Grn^+/− versus wild-type mice. All hTDP++ mice developed severe motor deficits and neuroinflammation. However, human TDP-43 expression induced worse motor deficits in Grn^−/−:hTDP++ mice, as well as an abnormal inflammatory response characterized by increased markers of disease-associated microglia and signs of an impaired adaptive immune response. These results highlight dysfunction of mPFC neurons as a potential mechanism of behavioral changes in FTD-GRN, and implicate dysregulated inflammation as a potential driver of disease progression in FTD-GRN.

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Funder

Funder: National Institute of Neurological Disorders and Stroke
R01NS128031