Title: The impact of AD-associated genetic variants in 3D human mixed neural-glial models of AD Project summary A growing number of Alzheimer?s disease (AD)-associated genes are associated with innate immunity and neuroinflammatory pathways. Network-based integrative analyses of AD-related genes have shown that microglial gene networks are strongly associated with AD neuropathology (1,5). We have shown that the protective AD-associated CD33 variant, rs3865444, leads to reduced CD33 expression and lower levels of A?42)(1). Conversely, microglial TREM2 variants, which increase AD risk, reduce microglial clearance of Ab. In addition to AD-linked functional variants in CD33 and TREM2, our AD whole genome sequencing (WGS) and whole exome sequencing (WES) datasets from AD families and case-controls, have revealed functional variants in AD-associated microglial genes linked to innate immunity and neuroinflammation, including CD33, TREM2, MS4A cluster, ABCA7, ABI3, PLGC2, CR1, and others. To test the impact of microglial genetic variants on AD pathogenesis on human genetic background, we developed a novel 3D human neuron- astrocyte-microglia tri-culture AD model using a unique 3D microfluidic system. We demonstrated that human microglial cells are recruited towards 3D AD (Ab-producing) neuron-astrocyte cultures via microglia-specific migration channels, in a chemokine-dependent manner, leading to neuroinflammation and neurodegeneration. Here, we propose to use our extensive collection of AD WGS and WES datasets, together with our 3D human tri-culture AD model, to evaluate the pathogenic effects of functional variants in AD-associated innate immune genes linked to neuroinflammation.
In Aim 1, we will identify functional genomic variants and enriched gene networks that are linked to innate immunity and neuroinflammation. We will then examine the pathogenic roles of microglial AD risk or protective genes and their functional variants in 3D human mixed neural-astrocyte- microglial models of AD (Aim 2), explore AD pathogenic pathways that are linked to microglial AD risk genes and their functional variants using integrated multi-omics approaches, and validate selectively blocking these pathway (Aim 3). The overarching goals of this proposal are to comprehensively assess the pathogenic effects of functional variants in innate immune AD-risk genes on AD pathogenesis and explore underlying molecular networks, which will provide novel therapeutic targets for AD patients.
We will investigate the impact of AD-associated microglial functional genetic variants on AD pathology and neuroinflammation using our extensive collection of AD WGS and WES datasets, together with our novel human neuron-astrocyte-microglia tri-culture AD model. The proposed study will validate the pathogenic effects of microglial AD-risk gene mutations and elucidate novel pathogenic mechanisms in AD pathogenesis related to innate immunity and neuroinflammation, which will provide novel therapeutic targets for AD patients.
