Highlights d Drosophila PIP4K mutant larvae have increased PIP 3 levels in cells d Cells show enhanced sensitivity to insulin in the absence of PIP4K d PIP4K regulates enzymes involved in PIP 3 turnover at the plasma membrane d Loss of PIP4K suppresses insulin resistance phenotypes
Edited by Hitoshi NakatogawaPhospholipases play a vital role in maintaining membrane phospholipids. In this study, we found that deletion of the three major phospholipases B in Saccharomyces cerevisiae did not affect the hydrolysis of phospholipids, thus suggesting the presence of other, as yet unidentified, phospholipases. Indeed, in silico analysis of the S. cerevisiae genome identified 13 proteins that contain a conserved, putative serine hydrolase motif. In addition, expression profiling revealed that ATG15 (Autophagy 15) was highly expressed in the phospholipase B triple mutant. ATG15 encodes a phospholipase that preferentially hydrolyzes phosphatidylserine. Our analysis of the ATG15 promoter identified binding sites for Yap1p. In vivo and in vitro results showed that Yap1p positively regulates ATG15 expression. Collectively, we demonstrate that Atg15p is a phosphatidylserine lipase and that Yap1p activates the expression of ATG15 during autophagy.
Phosphatidylinositol-5-phosphate (PI5P) is a low abundance lipid proposed to have functions in cell migration, DNA damage responses, receptor trafficking and insulin signalling in metazoans. However, studies of PI5P function are limited by the lack of scalable techniques to quantify its level from cells and tissues in multicellular organisms. Currently, PI5P measurement requires the use of radionuclide labelling approaches that are not easily applicable in tissues or in vivo samples. In the present study, we describe a simple and reliable, non-radioactive mass assay to measure total PI5P levels from cells and tissues of Drosophila, a genetically tractable multicellular model. We use heavy oxygen-labelled ATP (18O-ATP) to label PI5P from tissue extracts while converting it into PI(4,5)P2 using an in vitro kinase reaction. The product of this reaction can be selectively detected and quantified with high sensitivity using a liquid chromatography-tandem mass spectrometry (LC-MS/MS) platform. Further, using this method, we capture and quantify the unique acyl chain composition of PI5P from Drosophila cells and tissues. Finally, we demonstrate the use of this technique to quantify elevations in PI5P levels, from Drosophila larval tissues and cultured cells depleted of phosphatidylinositol 5 phosphate 4-kinase (PIP4K), that metabolizes PI5P into PI(4,5)P2 thus regulating its levels. Thus, we demonstrate the potential of our method to quantify PI5P levels with high sensitivity from cells and tissues of multicellular organisms thus accelerating understanding of PI5P functions in vivo.
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