Early-life stress exposure impacts the hippocampal synaptic proteome in a mouse model of Alzheimer’s disease: age- and pathology-dependent effects on mitochondrial proteins

Abstract

AbstractEpidemiological evidence indicates that early life stress (ES) exposure increases the risk for later-life diseases, such as Alzheimer’s disease (AD). Accordingly, we and others have shown that ES aggravates the development of, and response to, amyloid-beta (Aβ) pathology in animal models. Moreover, ES-exposed transgenic APP/PS1 mice display deficits in both cognitive flexibility and synaptic function. As the mechanisms behind these changes were unclear, we here investigated how exposure to ES, using the limited nesting and bedding model, affects the synaptic proteome across 2 different ages in both wildtype and APP/PS1 transgenic mice.We found that, compared to wildtype mice, the hippocampal synaptosomes of APP/PS1 mice at an early pathological stage (4 months) showed a higher abundance of mitochondrial proteins and lower levels of proteins involved in actin dynamics. Interestingly, ES exposure in wildtype mice had similar effects on the level of mitochondrial and actin-related synaptosomal proteins at this age, whereas ES exposure had no additional effect on the synaptosomal proteome of early-stage APP/PS1 mice. Accordingly, ultrastructural analysis of the synapse using electron microscopy in a follow-up cohort showed fewer mitochondria in pre- and post-synaptic compartments of APP/PS1 and ES-exposed mice, respectively.At a later pathological stage (10 months), the hippocampal synaptic proteome of APP/PS1 mice revealed an upregulation of proteins related to Aβ processing, that was accompanied by a downregulation of proteins related to postsynaptic receptor endocytosis. ES exposure no longer affected the synaptic proteome of wildtype animals by this age, whereas it affected the expression of astrocytic proteins involved in lipid metabolism in APP/PS1 mice. We confirmed a dysregulation of astrocyte protein expression in a separate cohort of 12-month-old mice, by immunostaining for the alpha subunit of the mitochondrial trifunctional protein and fatty acid synthase in astrocytes.In conclusion, our data suggest that ES and amyloidosis share pathogenic pathways involving synaptic mitochondrial dysfunction and astrocytic lipid metabolism. These pathways might be underlying contributors to the long-term aggravation of the APP/PS1 phenotype by ES, as well as to the ES-associated risk for AD progression.These data are publicly accessible online as a web app viahttps://amsterdamstudygroup.shinyapps.io/ES_Synaptosome_Proteomics_Visualizer/.