Distinct phospholipase C-regulated signalling pathways in Swiss 3T3 fibroblasts induce the rapid generation of the same polyunsaturated diacylglycerols

AbstractProstaglandin F2α, platelet-derived growth factor (PDGF) and calcium ionophore A23187 stimulated the rapid (within 25 s) generation of polyunsaturated 1,2-diacylglycerol (DAG) species, in particular 18:0/20:3n-9, 18:0/20:4n-6 and 18:0/20:5n-3, in Swiss 3T3 fibroblasts. This was followed by a second sustained phase characterised by saturated, monounsaturated and diunsaturated DAG species derived, at least partially, from a phospholipase D/phosphatidate phosphohydrolase-linked pathway. This could be directly activated by phorbol ester. Assay of rat brain protein kinase C (PKC) in lipid vesicles showed that first phase, polyunsaturated-enriched DAG isolated from Swiss 3T3 cells was a more potent activator of kinase activity compared to that achieved with DAG from control or 5 min stimulated cells. Thus activation of distinct members of the phospholipase C family leads to the rapid and almost identical generation of polyunsaturated DAG species which are capable of preferentially activating protein kinase C (PKC)

An intracellular motif of GLUT4 regulates fusion of GLUT4-containing vesicles

<p>Abstract</p> <p>Background</p> <p>Insulin stimulates glucose uptake by adipocytes through increasing translocation of the glucose transporter GLUT4 from an intracellular compartment to the plasma membrane. Fusion of GLUT4-containing vesicles at the cell surface is thought to involve phospholipase D activity, generating the signalling lipid phosphatidic acid, although the mechanism of action is not yet clear.</p> <p>Results</p> <p>Here we report the identification of a putative phosphatidic acid-binding motif in a GLUT4 intracellular loop. Mutation of this motif causes a decrease in the insulin-induced exposure of GLUT4 at the cell surface of 3T3-L1 adipocytes via an effect on vesicle fusion.</p> <p>Conclusion</p> <p>The potential phosphatidic acid-binding motif identified in this study is unique to GLUT4 among the sugar transporters, therefore this motif may provide a unique mechanism for regulating insulin-induced translocation by phospholipase D signalling.</p

[Le résultat du concours Diday...]

Concours Diday 1879-1880. Résultat du concours : Albert Gos 1er prix, Ferdinand Hodler 2e prix. Les tableaux seront visibles jusqu'au 27 mai au rez-de-chaussée de l'Athénée

Lipidomic analysis of signaling pathways

This chapter outlines methods that can be applied to determine the levels of lipids in cells and tissues. In particular, the methods focus upon the extraction and analysis of those lipids critical for monitoring signal transduction pathways. The methods address the analysis of the phosphoinositides, the lipid agonists lysophosphatidic acid and sphingosine 1-phosphate, and the neutral lipid messengers diacylglycerol and ceramide. Additionally, because of the increasing need to determine the dynamics of signaling, the analysis of phospholipids synthesis using stable isotope methods is described. The use of these methods as described or adaptation to permit both approaches should allow investigators to determine changes in signaling lipids and to better understand such processes in most cell types. The increasing appreciation of the central roles played by lipid signaling pathways has dispelled the misconception that lipids are inert structural components that are involved solely in keeping a cell intact. Advances in our understanding of cell-signaling pathways have identified particular lipids that act to regulate the functions of a number of proteins either by controlling enzyme activity directly, or by localizing proteins to particular intracellular compartments where they perform a specialized role. These lipid-binding domains (e.g., PH, PX, FYVE) have been found in many proteins, and considerable detail is recorded of the structural basis of lipid protein interaction. Additional lipid-binding domains exist, which remain less well characterized (e.g., those that bind phosphatidic acid [PA] or ceramide); however, the important regulatory roles that these lipids play and the pathways involving these messengers are increasingly appreciated. While the downstream targets are thus being defined, the actual changes in lipid concentration in a stimulated cell or membrane are less characterized. The primary reason for this lack has been a deficiency in methodology. Much of the reported studies of lipid messengers in stimulated cells have depended upon monitoring changes in radio-labeled cells. Many well-documented problems are associated with this type of methodology, including lack of isotopic equilibrium, distinct pools with different turnover rates, and inadequate separation of radio-labeled metabolites; however, much important information has been generated. The second approach has been to make use of the lipid-binding properties of the target protein domains and to generate a tagged fusion protein, generally GFP, which permits identification of a region rich in a signaling lipid (Guillou et al., 2007). This has proved useful in monitoring PI-3-kinase activation in stimulated cells; however, considerable caveats must be raised, not least the problems associated with lipid specificity and the fact that many of these domains have associated protein-binding regions that can compromise the findings. A further problem associated with these two methodologies is that they tend to group lipids together and take no account of the multiple acyl chain structures that occur in all lipids. These concerns point to the need to determine actual changes in lipid compositions. Until relatively recently, such an analysis was unachievable; however, advances in both chromatographic separation and mass spectrometry (MS) have permitted the development of lipidomic analysis. This chapter outlines a number of methods that allow determination of changes in signaling lipids. Adaptation of the methods here for the analysis of other molecules should be relatively straightforward in the future. Much of the lipidomic research in the United Kingdom is focused upon signaling lipidomics, with particular foci upon phosphoinositide-related signaling in Birmingham and Cambridge (Wakelam) and London (Larijani), upon eicosanoids in Cardiff (O'Donnell), and steroids in London (Griffiths). Meanwhile, the use of stable isotopes has been particularly developed in Southampton (Postle)