Decoding the role of ADAptor2 (ADA2) of HAT complex in autophagy and phospholipid metabolism to maintain ER homeostasis and triterpene regulation

In yeast, transcriptional adaptor 2 (ADA2; SAGA complex subunit ADA2), a member of histone acetyltransferase (HAT) complex, regulates transcription through cell signalling, but its precise role in cellular metabolism remains unclear. In this study, genetic loss of ADA2 (ada2{Delta}) induces squalene (SQ) accumulation, indicating aberrant triterpene metabolism, coupled with endoplasmic reticulum (ER)/nuclear ER (nER) expansion. Lipid analyses of ada2{Delta} revealed elevated phosphatidic acid (PA) and phosphatidylcholine (PC) levels, indicating disrupted phospholipid metabolism. The expanded ER causes basal autophagy elevation, cellular recycling, and nER phagy, suggesting a regulatory role for ADA2 in autophagy. Downregulation of phosphatidate cytidylyltransferase (CDS1) and inositol-3-phosphate synthase (INO1), coupled with elevated PA and PC in ada2{Delta}, points to a significant disruption in cytidine-diphosphate-diacylglycerol and phosphatidylinositol pathway. Overexpression of CDS1 or INO1, or the inositol supplementation, in ada2{Delta} restores SQ, basal autophagy and ER phagy. The observed target of rapamycin Ser/Thr kinase complex (TORC1) activity in ada2{Delta} is due to the high PA content. Rapamycin-mediated inhibition of TORC1 reduced SQ, PA and ER expansion while increasing lipid droplets. In contrast, a rapamycin-treated ada2{Delta}pah1{Delta} strain retained high PA, SQ and ER expansion, underscoring the functional role of TORC1-nuclear envelope morphology protein 1 (Nem1)/sporulation-specific protein SPO7 (Spo7)-Pah1 axis. Notably, SQ levels remained unchanged in a rapamycin-treated ada2{Delta}atg39{Delta} strain, suggesting that loss of nER-phagy receptor, Atg39, impairs the effectiveness of TORC1 inhibition. In conclusion, our data unveiled a critical role for Ada2 in maintaining the intricate relationship between lipid and triterpene/sterol metabolism and connecting autophagy and ER homeostasis.