HDAC inhibitor–dependent transcriptome and memory reinstatement in cognitive decline models
Eva Benito, Hendrik Urbanke, Binu Ramachandran, Jonas Barth, Rashi Halder, Ankit Awasthi, Gaurav Jain, Vincenzo Capece, Susanne Burkhardt, Magdalena Navarro-Sala, Sankari Nagarajan, Anna-Lena Schütz, Steven A. Johnsen, Stefan Bonn, Reinhardt Lührmann, Camin Dean, André Fischer
Eva Benito, Hendrik Urbanke, Binu Ramachandran, Jonas Barth, Rashi Halder, Ankit Awasthi, Gaurav Jain, Vincenzo Capece, Susanne Burkhardt, Magdalena Navarro-Sala, Sankari Nagarajan, Anna-Lena Schütz, Steven A. Johnsen, Stefan Bonn, Reinhardt Lührmann, Camin Dean, André Fischer
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Research Article Neuroscience

HDAC inhibitor–dependent transcriptome and memory reinstatement in cognitive decline models

Abstract

Aging and increased amyloid burden are major risk factors for cognitive diseases such as Alzheimer’s disease (AD). Effective therapies for these diseases are lacking. Here, we evaluated mouse models of age-associated memory impairment and amyloid deposition to study transcriptome and cell type–specific epigenome plasticity in the brain and peripheral organs. We determined that aging and amyloid pathology are associated with inflammation and impaired synaptic function in the hippocampal CA1 region as the result of epigenetic-dependent alterations in gene expression. In both amyloid and aging models, inflammation was associated with increased gene expression linked to a subset of transcription factors, while plasticity gene deregulation was differentially mediated. Amyloid pathology impaired histone acetylation and decreased expression of plasticity genes, while aging altered H4K12 acetylation–linked differential splicing at the intron-exon junction in neurons, but not nonneuronal cells. Furthermore, oral administration of the clinically approved histone deacetylase inhibitor vorinostat not only restored spatial memory, but also exerted antiinflammatory action and reinstated epigenetic balance and transcriptional homeostasis at the level of gene expression and exon usage. This study provides a systems-level investigation of transcriptome plasticity in the hippocampal CA1 region in aging and AD models and suggests that histone deacetylase inhibitors should be further explored as a cost-effective therapeutic strategy against age-associated cognitive decline.

Authors

Eva Benito, Hendrik Urbanke, Binu Ramachandran, Jonas Barth, Rashi Halder, Ankit Awasthi, Gaurav Jain, Vincenzo Capece, Susanne Burkhardt, Magdalena Navarro-Sala, Sankari Nagarajan, Anna-Lena Schütz, Steven A. Johnsen, Stefan Bonn, Reinhardt Lührmann, Camin Dean, André Fischer

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Figure 2

SAHA reinstates physiological exon usage and H4K12ac levels at intron-exon junctions.

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SAHA reinstates physiological exon usage and H4K12ac levels at intron-ex...
(A) Profile plot for H4K12ac for genes downregulated during aging and whose expression is fully reversed by SAHA in the neuronal (left) and nonneuronal (right) population. Inset shows box plots of the signal within the shaded area. (B) Functional categories and their significance associated with aging-downregulated genes whose expression is fully reversed by SAHA. (C) Number of splice sites significantly different in each of the indicated comparisons. (D) Of all genes found to be differentially expressed at the gene or exon level, the number and percentage (numbers inside each segment) of genes found in the RNA-seq only, in the DEX-seq analysis, or in common are represented. (E) Sample functional categories enriched within genes that contain 1 or more differential splicing events. (F) Volcano plot illustrating the magnitude and significance of changes at the exonic level that occur during aging after treatment with vehicle (black) or SAHA (red). Note that, whereas the distribution is clearly skewed toward the right (upregulations) in aged animals, this is reversed after SAHA treatment. Numbers within the graph denote the specific count of up- and downregulated exons at the indicated threshold for aged animals. Inset: percentage of exons with a higher inclusion rate (red) and a lower inclusion rate (blue) during aging. (G) H4K12ac signal around differentially spliced exons (left) and around a random set of exons (right) in the neuronal population. Insets represent box plots of the signal within the shaded area. DEX, differentially expressed exon. (H) Distribution of differentially spliced exons in aging across genes (left) and within the gene body (right).