Abstract
BackgroundIn spite of many years of research, our understanding of the molecular bases of Alzheimer’s disease (AD) is still incomplete, and the medical treatments available mainly target the disease symptoms and are hardly effective. Indeed, the modulation of a single target (e.g., β-secretase) has proven to be insufficient to significantly alter the physiopathology of the disease, and we should therefore move from gene-centric to systemic therapeutic strategies, where AD-related changes are modulated globally.MethodsHere we present the complete characterization of three murine models of AD at different stages of the disease (i.e., onset, progression and advanced). We combined the cognitive assessment of these mice with histological analyses and full transcriptional and protein quantification profiling of the hippocampus. Additionally, we derived specific Aβ-related molecular AD signatures and looked for drugs able to globally revert them.ResultsWe found that AD models show accelerated aging and that factors specifically associated with Aβ pathology are involved. We discovered a few proteins whose abundance increases with AD progression, while the corresponding transcript levels remain stable, and showed that at least two of them (i.e., lfit3 and Syt11) co-localize with Aβ plaques in the brain. Finally, we found two NSAIDs (dexketoprofen and etodolac) and two anti-hypertensives (penbutolol and bendroflumethiazide) that overturn the cognitive impairment in AD mice while reducing Aβ plaques in the hippocampus and partially restoring the physiological levels of AD signature genes to wild-type levels.ConclusionsThe characterization of three AD mouse models at different disease stages provides an unprecedented view of AD pathology and how this differs from physiological aging. Moreover, our computational strategy to chemically revert AD signatures has shown that NSAID and anti-hypertensive drugs may still have an opportunity as anti-AD agents, challenging previous reports.
Highlights
In spite of many years of research, our understanding of the molecular bases of Alzheimer’s disease (AD) is still incomplete, and the medical treatments available mainly target the disease symptoms and are hardly effective
The characterization of three AD mouse models at different disease stages provides an unprecedented view of AD pathology and how this differs from physiological aging
Our computational strategy to chemically revert AD signatures has shown that non-steroidal anti-inflammatory drugs (NSAIDs) and anti-hypertensive drugs may still have an opportunity as anti-AD agents, challenging previous reports
Summary
In spite of many years of research, our understanding of the molecular bases of Alzheimer’s disease (AD) is still incomplete, and the medical treatments available mainly target the disease symptoms and are hardly effective. Mutations in genes that are part of the Aβ processing pathway (e.g., APP, PSEN1, and PSEN2) cause infrequent cases of hereditary AD [2] This observation reinforces the hypothesis that Aβ accumulation plays a necessary role in AD onset. Given the accumulation of proteins in the plaques, quantitative proteomics might be a fundamental approach to understand protein-related changes in AD pathogenesis. To date, these studies have been limited to single time points and decoupled from gene-expression data [10,11,12,13,14]. It is clear that combining transcriptional and proteomics data provides key insights into aging processes in rats [15]
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