Abstract WP318: Increased Synapse Elimination by Inflammatory Cells Contribute to Lon-Lasting Post-Stroke Memory Dysfunction in Aged Mice

Abstract

Background and Purpose: Memory impairments are common after stroke. Memory dysfunction lasted longer in aged than in young mice, but the mechanisms are still unclear. Microglia maintain normal memory via removing excessive synapses and increase turnover of synaptic connections after stroke. Long-term memory deficits in aged mice may be associated with increased microglia in the brain. Hypothesis: Increased synapse removal by inflammatory cells contribute to the long-lasting post-stroke memory dysfunction of aged mice. Methods: Permanent distal middle cerebral artery occlusion (pMCAO) was induced in young and aged mice. The memory functions were analyzed weekly for 8 weeks by Y-maze test and at 8 weeks post stroke by novel objective recognition (NOR) test. Brain samples were collected 8 weeks after pMCAO induction. RNAseq analysis was performed to study gene expression profiles in peri-infarct area and hippocampus. Nissl staining was used to measure infarct volume and immunostaining was done to detect CD68 + and GFAP + cells and synapse in peri-infarct region and hippocampus. Results: RNAseq data shown up-regulation of CD68, GFAP, pro-inflammatory cytokines, immune response, microglia chemotaxins and phagocytosis genes; and down-regulation of synaptic assembly and transmission, synaptic plasticity, and long-term potentiation genes in aged mice at peri-infarct region and ipsilateral hippocampi. Aged mice had larger infarct volumes, more CD68 + and GFAP + cells in the peri-infarct region and ipsilateral hippocampi than young mice and had more CD68 + cells in the ipsilateral than the contralateral hippocampi. In Y-maze test, aged stroke mice made fewer spontaneous alternations from 3 to 8 weeks after pMCAO than young stroke and sham operated aged mice. In the NOR test, aged stroke mice spent less time on the novel objects than young stroke and sham aged mice. Increased synaptophysin positive CD68 + cells were detected in the hippocampi of aged stroke mice. Conclusions: Increase of synaptic elements by inflammatory cells contribute to the long-lasting post-stroke memory deficit in the aged mice, and reduction of neuroinflammation may improve their memory function.