Abstract
We provide evidence that phosphatidic acid (PtdOH) formed during signaling in plants is metabolized by a novel pathway. In much of this study, 32Pi-labeled Chlamydomonas cells were used, and signaling was activated by adding the G-protein activator mastoparan. Within seconds of activation, large amounts of [32P]PtdOH were formed, with peak production at about 4 min, when the level was 5-25-fold higher than the control. As the level of [32P]PtdOH subsequently decreased, an unknown phospholipid (PLX) increased in radiolabeling; before activation it was barely detectable. The chromatographic properties of PLX resembled those of lyso-PtdOH and CMP.PtdOH but on close inspection were found to be different. PLX was shown to be diacylglycerol pyrophosphate (DGPP), the product of a newly discovered enzyme, phosphatidate kinase, whose in vitro activity was described recently (Wissing, J. B., and Behrbohm, H. (1993) Plant Physiol. 102, 1243-1249). The identity of DGPP was established by co-chromatrography with a standard and by degradation analysis as follows: [32P]DGPP was deacylated, and the product (glycerolpyrophosphate, GroPP) was hydrolyzed by mild acid treatment or pyrophosphatase to produce GroP and Pi as the only radioactive products. Since DGPP is the pyrophosphate derivative of PtdOH and is formed as the concentration of PtdOH decreases, we assumed that PtdOH was converted in vivo to DGPP. This was confirmed by showing that during a short labeling protocol while the specific radioactivity of DGPP was increasing, the specific radioactivity of the 32Pi derived from DGPP as above was higher than that of [32P]GroP. DGPP was also formed in suspension cultures of tomato and potato cells, and its synthesis was activated by mastoparan. Moreover, it was also found in intact tissues of a number of higher plants, for example, carnation flower petals, vetch roots, leaves of fig-leaved goosefoot, and common persicaria and microspores of rape seed. Our results suggest that DGPP is a common but minor plant lipid that increases in concentration when signaling is activated. Possible functions of DGPP in phospholpase C and D signaling cascades are discussed.
Highlights
Phosphatidic acid (PtdOH)1 is an important intermediate in the synthesis of all phospho- and glycolipids but is suggested to be an intracellular signal in mammalian cells
We show that when Chlamydomonas cells were treated with mastoparan, the initial rise in PtdOH formation was counteracted by its conversion to diacylglycerol pyrophosphate (DGPP), illustrating that this novel lipid kinase is highly active in vivo when intracellular signaling is stimulated
DGPP was further shown to be present in several higher plants and their different tissues, and its synthesis was shown to be stimulated when cells were activated by mastoparan
Summary
Phosphatidic acid (PtdOH)1 is an important intermediate in the synthesis of all phospho- and glycolipids but is suggested to be an intracellular signal in mammalian cells. A new enzyme activity was extracted from many different higher plants that was able to phosphorylate PtdOH to diacylglycerol pyrophosphate (DGPP) and was called phosphatidate kinase (Wissing and Behrbohm, 1993a, 1993b; Wissing et al, 1994). We show that when Chlamydomonas cells were treated with mastoparan, the initial rise in PtdOH formation was counteracted by its conversion to DGPP, illustrating that this novel lipid kinase is highly active in vivo when intracellular signaling is stimulated.
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