Neurotrophin receptor p75NTR mediates Huntington’s disease–associated synaptic and memory dysfunction
Verónica Brito, Albert Giralt, Lilian Enriquez-Barreto, Mar Puigdellívol, Nuria Suelves, Alfonsa Zamora-Moratalla, Jesús J. Ballesteros, Eduardo D. Martín, Nuria Dominguez-Iturza, Miguel Morales, Jordi Alberch, Sílvia Ginés
Verónica Brito, Albert Giralt, Lilian Enriquez-Barreto, Mar Puigdellívol, Nuria Suelves, Alfonsa Zamora-Moratalla, Jesús J. Ballesteros, Eduardo D. Martín, Nuria Dominguez-Iturza, Miguel Morales, Jordi Alberch, Sílvia Ginés
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Research Article Neuroscience

Neurotrophin receptor p75NTR mediates Huntington’s disease–associated synaptic and memory dysfunction

Abstract

Learning and memory deficits are early clinical manifestations of Huntington’s disease (HD). These cognitive impairments have been mainly associated with frontostriatal HD pathology; however, compelling evidence provided by several HD murine models suggests that the hippocampus may contribute to synaptic deficits and memory dysfunction in HD. The neurotrophin receptor p75NTR negatively regulates spine density, which is associated with learning and memory; therefore, we explored whether disturbed p75NTR function in the hippocampus could contribute to synaptic dysfunction and memory deficits in HD. Here, we determined that levels of p75NTR are markedly increased in the hippocampus of 2 distinct mouse models of HD and in HD patients. Normalization of p75NTR levels in HD mutant mice heterozygous for p75NTR prevented memory and synaptic plasticity deficits and ameliorated dendritic spine abnormalities, likely through normalization of the activity of the GTPase RhoA. Moreover, viral-mediated overexpression of p75NTR in the hippocampus of WT mice reproduced HD learning and memory deficits, while knockdown of p75NTR in the hippocampus of HD mice prevented cognitive decline. Together, these findings provide evidence of hippocampus-associated memory deficits in HD and demonstrate that p75NTR mediates synaptic, learning, and memory dysfunction in HD.

Authors

Verónica Brito, Albert Giralt, Lilian Enriquez-Barreto, Mar Puigdellívol, Nuria Suelves, Alfonsa Zamora-Moratalla, Jesús J. Ballesteros, Eduardo D. Martín, Nuria Dominguez-Iturza, Miguel Morales, Jordi Alberch, Sílvia Ginés

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Figure 10

Increased RhoA activity contributes to p75NTR-mediated dendritic spine loss in mutant KI mice.

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Increased RhoA activity contributes to p75NTR-mediated dendritic spine l...
(A) Hippocampal lysates from WT, KI, p75+/–, and KI:p75+/– mice at 6 months of age were subjected to RhoA activity assays. Quantification of the RhoA-GTP levels adjusted to the total RhoA is shown. One-way ANOVA with Tukey post hoc comparisons was performed; n = 5 animals per genotype. **P < 0.01 compared with WT mice. (B) Hippocampal lysates from AAV-ctl– and AAV-p75–transduced WT mice were subjected to RhoA activity. Quantification of the RhoA-GTP levels adjusted to the total RhoA is shown. Student’s 2-tailed t test was performed; n = 5–6 per genotype. §§§P < 0.001 compared with AAV-ctl mice. (C) Left: Quantitative analysis showing dendritic spine density. AAV-p75 mice exhibit a significant reduction in dendritic spines compared with AAV-ctl mice. Student’s 2-tailed t test was performed; 32 dendrites (AAV-ctl) and 26 dendrites (AAV-p75) from 3 animals per condition were analyzed. §§§P < 0.001 compared with AAV-ctl mice. Right: Representative confocal microscopy images of CA1 dendrites from AAV-ctl and AAV-p75 mice. Arrowheads indicate dendritic spines. (D) Hippocampal neurons were transduced at DIV14 with AAV-ctl or AAV-p75 and at DIV20 treated with the RhoA inhibitor C3 transferase. Left: Quantitative analysis showing the density of PSD95 clusters. Two-way ANOVA comparing groups × treatment with Bonferroni post hoc comparisons was performed. §§§P < 0.001 compared with control AAV-ctl–treated neurons. Right: Representative confocal microscopy images showing PSD95 clusters (red) in GFP-labeled neurons. All histograms represent mean ± SEM.