Abstract: A multidimensional profiling strategy that combines activity-based proteomics and metabolomics was used to determine that an active protein, which is a previously uncharacterized enzyme highly elevated in aggressive cancer cells, serves as a central node in an ether lipid signaling network that bridges platelet-activating factor and the lysophospholipids. Biochemical studies confirmed that the active protein regulates this pathway by hydrolyzing the metabolic intermediate 2-acetyl monoalkylglycerol. Inactivation of the active protein disrupted ether lipid metabolism in cancer cells and impaired cell migration and tumor growth in vivo.

Abstract: A multidimensional profiling strategy that combines activity-based proteomics and metabolomics was used to determine that an active protein, which is a previously uncharacterized enzyme highly elevated in aggressive cancer cells, serves as a central node in an ether lipid signaling network that bridges platelet-activating factor and the lysophospholipids. Biochemical studies confirmed that the active protein regulates this pathway by hydrolyzing the metabolic intermediate 2-acetyl monoalkylglycerol. Inactivation of the active protein disrupted ether lipid metabolism in cancer cells and impaired cell migration and tumor growth in vivo.

Abstract: A multidimensional profiling strategy that combines activity-based proteomics and metabolomics was used to determine that an active protein, which is a previously uncharacterized enzyme highly elevated in aggressive cancer cells, serves as a central node in an ether lipid signaling network that bridges platelet-activating factor and the lysophospholipids. Biochemical studies confirmed that the active protein regulates this pathway by hydrolyzing the metabolic intermediate 2-acetyl monoalkylglycerol. Inactivation of the active protein disrupted ether lipid metabolism in cancer cells and impaired cell migration and tumor growth in vivo.