Divergent consequences of PSEN1 knockout and PSEN2 knockout in stem cell derived models of the brain

{gamma}-secretase is a multi-subunit enzyme complex responsible for cleaving hundreds of substrates in diverse cellular contexts. Variation in subunit composition - including the use of alternate catalytic subunits Presenilin 1 (PSEN1) and Presenilin 2 (PSEN2) - results in diverse {gamma}-secretase complexes. Point mutations in PSEN1 and PSEN2 cause familial forms of Alzheimers disease, while loss-of-function mutations in the {gamma}-secretase subunits PSEN1, PSENEN and NCSTN cause acne inversa. To advance therapeutic strategies targeting {gamma}-secretase in Alzheimers disease, a better understanding of individual {gamma}-secretase complexes is required. In this study, we used CRISPR-Cas9 genome engineering to generate PSEN2-knockout iPSCs in order to compare the consequence of PSEN2 knockout versus PSEN1 knockout in iPSC-derived brain cells. In contrast to PSEN1-knockout, PSEN2-knockout did not alter APP cleavage or A{beta} generation in iPSC-neurons, nor did it disrupt Nicastrin maturation. Similarly, PSEN2-knockout had little impact on TREM2 processing in iPSC-microglia. Instead, our data indicate that loss of PSEN2 primarily impacts the endo-lysosomal system in iPSC-neurons, causing an accumulation of early endosome markers and a reduction in lysosomal markers - phenotypes not observed in PSEN1-knockout neurons. Taken together, these findings highlight distinct and non-redundant functions of PSEN1 and PSEN2 in human brain cells, reinforcing findings in animal models and subcellular localisation studies. This work advances our understanding of distinct {gamma}-secretase complex functions and provides insights that will support future therapeutic efforts to inhibit, modulate or stabilise {gamma}-secretase.