Phosphatidic Acid Plays a Central Role in the Transcriptional Regulation of Glycerophospholipid Synthesis in Saccharomyces cerevisiae

“…Since local concentration of Ca 2þ and Mg 2þ can fluctuate very rapidly in particular cellular condition, this chemical property of PA is an important feature to probe its environment. As a consequence PA can behave as a pH biosensor as notably reported in yeast for regulation of expression of phospholipid metabolic genes through PA-dependent sequestration in the ER of the transcription factor Opi1p [16,51,52]. Interestingly it has been recently demonstrated that during the first minutes of carbon deprivation the cytosolic pH of plant cells rises from 7.4 to stabilize at 7.8 and recovers to more acidic pH within 5 min after carbon repletion accompanying modification of level of soluble phosphorous metabolites [53].…”

“…PA formed by ER acyltransferases can generate phospholipids via 2 different pathways: i) the CDP-DAG pathway and ii) the Kennedy pathway through dephosphorylation of PA into DAG. In yeast, both pathways generate PC and PE [16]. The CDP-DAG pathway is more active in the growth phase but nutrient depletion induces a shift towards the Kennedy pathway [16].…”

“…In yeast, both pathways generate PC and PE [16]. The CDP-DAG pathway is more active in the growth phase but nutrient depletion induces a shift towards the Kennedy pathway [16]. The Kennedy pathway indeed contributes to recycling the polar head of phospholipids such as choline and ethanolamine [20] According to [21] Leaf Root Whole seedling ATS1 Glycerol-3-phosphate acyltransferase through phospholipases D (PLDs) and eventually to remodelling of membranes.…”

“…The Kennedy pathway indeed contributes to recycling the polar head of phospholipids such as choline and ethanolamine [20] According to [21] Leaf Root Whole seedling ATS1 Glycerol-3-phosphate acyltransferase through phospholipases D (PLDs) and eventually to remodelling of membranes. The PA phosphatase Pah1p is critical for the shift from the CDP-DAG to the Kennedy pathway because it catalyzes the hydrolysis of PA into DAG, and furthermore because the Pah1p-produced DAG negatively regulates the level of expression of genes encoding the CDP-DAG pathway [16]. In plants, the biosynthetic pathways show similarity with yeast but also major differences partly related with galactolipid synthesis.…”

Role of phosphatidic acid in plant galactolipid synthesis

“…Since local concentration of Ca 2þ and Mg 2þ can fluctuate very rapidly in particular cellular condition, this chemical property of PA is an important feature to probe its environment. As a consequence PA can behave as a pH biosensor as notably reported in yeast for regulation of expression of phospholipid metabolic genes through PA-dependent sequestration in the ER of the transcription factor Opi1p [16,51,52]. Interestingly it has been recently demonstrated that during the first minutes of carbon deprivation the cytosolic pH of plant cells rises from 7.4 to stabilize at 7.8 and recovers to more acidic pH within 5 min after carbon repletion accompanying modification of level of soluble phosphorous metabolites [53].…”

“…PA formed by ER acyltransferases can generate phospholipids via 2 different pathways: i) the CDP-DAG pathway and ii) the Kennedy pathway through dephosphorylation of PA into DAG. In yeast, both pathways generate PC and PE [16]. The CDP-DAG pathway is more active in the growth phase but nutrient depletion induces a shift towards the Kennedy pathway [16].…”

“…In yeast, both pathways generate PC and PE [16]. The CDP-DAG pathway is more active in the growth phase but nutrient depletion induces a shift towards the Kennedy pathway [16]. The Kennedy pathway indeed contributes to recycling the polar head of phospholipids such as choline and ethanolamine [20] According to [21] Leaf Root Whole seedling ATS1 Glycerol-3-phosphate acyltransferase through phospholipases D (PLDs) and eventually to remodelling of membranes.…”

“…The Kennedy pathway indeed contributes to recycling the polar head of phospholipids such as choline and ethanolamine [20] According to [21] Leaf Root Whole seedling ATS1 Glycerol-3-phosphate acyltransferase through phospholipases D (PLDs) and eventually to remodelling of membranes. The PA phosphatase Pah1p is critical for the shift from the CDP-DAG to the Kennedy pathway because it catalyzes the hydrolysis of PA into DAG, and furthermore because the Pah1p-produced DAG negatively regulates the level of expression of genes encoding the CDP-DAG pathway [16]. In plants, the biosynthetic pathways show similarity with yeast but also major differences partly related with galactolipid synthesis.…”

Role of phosphatidic acid in plant galactolipid synthesis

“…The first identified yeast bHLH protein, Pho4p, forms a homodimer required for the induction of phosphate utilization genes when phosphate levels are low (Berben et al, 1990;Johnston and Carlson, 1992;Oshima, 1997). The Ino2p : Ino4p heterodimer induces phospholipid biosynthetic gene expression in response to inositol deprivation (Carman and Han, 2008;Carman and Henry, 2007;. The Sgc1p homodimer activates expression of glycolytic genes (e.g.…”

Multiple bHLH proteins regulate CIT2 expression in Saccharomyces cerevisiae

Molecular and Cellular Mechanisms for Lipid Synthesis and Accumulation in Microalgae: Biotechnological Implications