Analysis of Alzheimer’s disease‐related synaptic alterations using microfluidic microglia/neuron co‐cultures

Abstract

AbstractBackgroundMicroglial cells are resident macrophages of the central nervous system. Genome‐wide association studies identified numerous Alzheimer’s disease (AD) risk genes highly or exclusively expressed in microglia, supporting their role as major players in AD pathogenesis. We aim to describe the effect of microglia activation on synaptic connectivity and its potential modulation by AD risk genes.MethodWe developed a microfluidic co‐culture device where fluidically isolated, mature neuronal synapses are brought in contact with microglia, enabling exclusive genetic and pharmacological interventions to neurons and microglia. We cultured cortical neurons from WT embryonic mice in pre‐ and postsynaptic chambers for 7 days, after which primary microglia from 10‐month‐old WT and APP (hAPPJ20, PDGFAPPSw,Ind) mice were added into the synapse chamber. Microglia morphology and synaptic connectivity near microglia were analyzed via immunocytochemistry and confocal microscopy.ResultExposure to lipopolysaccharide (LPS) activated microglia as evidenced by increased surface area and circularity. Morphological changes were correlated with Interleukin‐1 concentration in the medium, indicative of an inflammatory response. We observed a higher reactivity to LPS in microglia from APP mice compared to WT mice, suggesting that genotype‐related differences in microglia reactivity could also be applicable to pathologically relevant stimuli, such as exposure to amyloid‐β oligomers. On‐going work is focused on the synapse pruning process via live‐cell recordings of fluorescent microglia and neurons expressing fluorescently‐tagged synaptic proteins. This model will be used to characterize the dynamic response of microglia to amyloid‐β and include microglia harvested from mice carrying mutations for microglia‐related AD risk genes.ConclusionOur microfluidic co‐culture device enables specific modulation and high‐content analysis of microglial activity and synaptic connectivity in physiological and AD pathological conditions.