Investigating the Role of APOE Genotype in Human Microglia.

Background: Although the pivotal role of apolipoprotein E () in AD has been recognized for three decades, its function in different brain cells is far from understood. Knockout studies of the APOE gene may shed light of the function of ApoE. The aim of the present study was to unravel its function in induced pluripotent stem cell (iPSC) derived microglia. Method: We studied two human iPSC‐derived microglia cell cultures, one derived from a healthy control (Bioni010‐C – endogenous genotype apolipoprotein E34 (APOE34)) and one from an AD patient (UKBi011‐A – endogenous genotype APOE44) and their edited isogenic cell‐lines (for UKBi011‐A, APOE22 and APOE33 and for Bioni010‐C, hemizygous due to gene editing, APOE2‐ and APOE3‐ (32971461, 29753274)). Additionally, APOE KO lines were generated from both backgrounds. We performed whole genome transcriptomic (IlluminaTruSequencing) and proteomic (TMT‐labelled Nano‐LC peptidomic MS) analysis (n = six per genotype). For transcriptomic data, log2‐normalized intensities were analysed with (in R); there were 13115 unique transcripts. For proteomics analysis, after global normalization, the data were locally normalized (by protein), the limma package was used to calculate FDR‐corrected p‐values (1% cut off); there were 3975 (Bioni010 samples) and 4349 (UKBi011 samples) proteins. In the quality control analysis for the proteomics, we excluded one outlier of the six per line based on principle component/Euclidean distance analysis. We extracted pairwise comparisons to APOE KO in transcriptomic (|logFC|>0.5, FDR <0.05) and proteomic (|logFC|>0 and FDR <0.05) data. Result: Twenty transcripts (including APOE) were concordantly differentially expressed across all comparisons between APOE‐expressing and KO. These are broadly involved in processes related to mitochondrial function/organization, apoptosis, transcriptional regulation, immune functions, extracellular matrix, and energy metabolism among others. Seven proteins were concordantly differentially expressed across all pairwise comparisons with APOE KO, involved in extracellular matrix, immune signalling, energy metabolism, and cytoskeletal structure. Conclusion: Our study finds APOE knockout leads to a number of changes related to immune, mitochondrial, and extracellular matrix genes, suggesting that APOE in human iPSC‐derived microglia cells influences immune and mitochondrial functions. [ABSTRACT FROM AUTHOR]