‘Innate immune memory’ is a vital mechanism of myeloid cell
plasticity that occurs in response to environmental stimuli and alters
subsequent immune responses. Two types of immunological imprinting can be
distinguished, training and tolerance, which
are epigenetically mediated and enhance or suppress subsequent inflammation,
respectively. Whether immune memory occurs in tissue-resident macrophages
in vivo and how it may affect pathology remains largely
unknown. Here we demonstrate that peripherally applied inflammatory stimuli
induce acute immune training and tolerance in the brain and lead to differential
epigenetic reprogramming of brain-resident macrophages, microglia, that persists
for at least six months. Strikingly, in a mouse model of Alzheimer’s
pathology, immune training exacerbates cerebral β-amyloidosis while
tolerance alleviates it; similarly, peripheral immune stimulation modifies
pathological features after stroke. Our results identify immune memory in the
brain as an important modifier of neuropathology.
Aging is accompanied by gradually increasing impairment of cognitive abilities and constitutes the main risk factor of neurodegenerative conditions like Alzheimer's disease (AD). The underlying mechanisms are however not well understood. Here we analyze the hippocampal transcriptome of young adult mice and two groups of mice at advanced age using RNA sequencing. This approach enabled us to test differential expression of coding and non-coding transcripts, as well as differential splicing and RNA editing. We report a specific age-associated gene expression signature that is associated with major genetic risk factors for late-onset AD (LOAD). This signature is dominated by neuroinflammatory processes, specifically activation of the complement system at the level of increased gene expression, while de-regulation of neuronal plasticity appears to be mediated by compromised RNA splicing.
Age‐associated memory decline is due to variable combinations of genetic and environmental risk factors. How these risk factors interact to drive disease onset is currently unknown. Here we begin to elucidate the mechanisms by which post‐traumatic stress disorder (PTSD) at a young age contributes to an increased risk to develop dementia at old age. We show that the actin nucleator Formin 2 (Fmn2) is deregulated in PTSD and in Alzheimer's disease (AD) patients. Young mice lacking the Fmn2 gene exhibit PTSD‐like phenotypes and corresponding impairments of synaptic plasticity, while the consolidation of new memories is unaffected. However, Fmn2 mutant mice develop accelerated age‐associated memory decline that is further increased in the presence of additional risk factors and is mechanistically linked to a loss of transcriptional homeostasis. In conclusion, our data present a new approach to explore the connection between AD risk factors across life span and provide mechanistic insight to the processes by which neuropsychiatric diseases at a young age affect the risk for developing dementia.
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