Regulation of PPARα by APP in Alzheimer disease affects the pharmacological modulation of synaptic activity
Francisco Sáez-Orellana, Thomas Leroy, Floriane Ribeiro, Anna Kreis, Karelle Leroy, Fanny Lalloyer, Eric Baugé, Bart Staels, Charles Duyckaerts, Jean-Pierre Brion, Philippe Gailly, Jean-Noël Octave, Nathalie Pierrot
Francisco Sáez-Orellana, Thomas Leroy, Floriane Ribeiro, Anna Kreis, Karelle Leroy, Fanny Lalloyer, Eric Baugé, Bart Staels, Charles Duyckaerts, Jean-Pierre Brion, Philippe Gailly, Jean-Noël Octave, Nathalie Pierrot
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Research Article Neuroscience

Regulation of PPARα by APP in Alzheimer disease affects the pharmacological modulation of synaptic activity

Abstract

Among genetic susceptibility loci associated with late-onset Alzheimer disease (LOAD), genetic polymorphisms identified in genes encoding lipid carriers led to the hypothesis that a disruption of lipid metabolism could promote disease progression. We previously reported that amyloid precursor protein (APP) involved in Alzheimer disease (AD) physiopathology impairs lipid synthesis needed for cortical networks’ activity and that activation of peroxisome proliferator–activated receptor α (PPARα), a metabolic regulator involved in lipid metabolism, improves synaptic plasticity in an AD mouse model. These observations led us to investigate a possible correlation between PPARα function and full-length APP expression. Here, we report that PPARα expression and activation were inversely related to APP expression both in LOAD brains and in early-onset AD cases with a duplication of the APP gene, but not in control human brains. Moreover, human APP expression decreased PPARA expression and its related target genes in transgenic mice and in cultured cortical cells, while opposite results were observed in APP-silenced cortical networks. In cultured neurons, APP-mediated decrease or increase in synaptic activity was corrected by a PPARα-specific agonist and antagonist, respectively. APP-mediated control of synaptic activity was abolished following PPARα deficiency, indicating a key function of PPARα in this process.

Authors

Francisco Sáez-Orellana, Thomas Leroy, Floriane Ribeiro, Anna Kreis, Karelle Leroy, Fanny Lalloyer, Eric Baugé, Bart Staels, Charles Duyckaerts, Jean-Pierre Brion, Philippe Gailly, Jean-Noël Octave, Nathalie Pierrot

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Figure 1

PPARA expression and PPARα downstream target genes in brains from patients with AD.

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PPARA expression and PPARα downstream target genes in brains from patie...
Frontal cortex of postmortem human brain tissues from late-onset (LOAD, n = 9) and early-onset AD cases with an APP duplication locus (APPdup, n = 2) and respective control subjects (CTL in LOAD and APPdup cases, n = 8 and 2, respectively) was analyzed. (A, B, H, and I) Quantitative real-time PCR analyses for PPARA and ACOX1 mRNA levels. Results were normalized to ACTB mRNA, and relative differences are expressed according to respective CTL as mean ± SEM (LOAD: PPARA mRNA, P = 0.009, ACOX1 mRNA, P = 0.003; Student’s t test). (C) mRNA correlation between ACOX1 and PPARA in LOAD. (D and J) Human APP (hAPP) expression in human brain lysates by immunoblot analysis (see complete unedited blots in the supplemental material). (E and K) Relative density of hAPP expression compared with α-tubulin. Results were normalized compared with respective CTL and are shown as mean ± SEM. A Student’s t test (LOAD: hAPP, P = 0.0608) was used to assess significance of the mean. (F and G) Quantification of hAPP densitometry arbitrary units indicating an inverse correlation between hAPP expression and PPARA levels in LOAD. **P < 0.01 and nonsignificant (ns) P > 0.05.