Project description:Human platelets possess about 300 receptors for platelet-activating factor (PAF) per cell with a Kd of about 0.2 nM. In the present study we investigated whether these receptors are subject to intracellular control mechanisms. Preincubation with the protein kinase C inhibitor staurosporine had no effect, and also agents that increase cyclic AMP failed to change the binding of [3H]PAF. The Ca(2+)-calmodulin inhibitors W-7 and sphingosine decreased PAF binding by 50-80%. Inhibition of energy metabolism induced a fall in adenylate energy charge [AEC = ([ATP] + 1/2[ADP])([ATP + ADP + AMP])] and an almost parallel decrease in specific [3H]PAF binding without changing the Kd. Restoration of the AEC restored the [3H]PAF binding. Abrupt arrest of energy metabolism during binding of [3H]PAF left the binding unchanged until the metabolic ATP level had decreased by about 90%. These data indicate that PAF receptors on human platelets are under close intracellular control, possibly via a Ca(2+)-calmodulin-dependent phosphorylation/dephosphorylation process.

Project description:This data series contains spotted oligo microarray data from 10 different experiments using Agilent Rat v2 microarrays. This data is being made public in support of Fillon S et al. Journal of Immunology, (2006). Proinflammatory bacterial components are at least partially responsible for causing the clinical features of sepsis, a syndrome that causes >100,000 deaths each year in the US (1). In the case of Gram positive infection, a key bacterial element recognized by the innate immune system is the cell wall, a complex network of peptidoglycan covalently linked to teichoic acids, proteins and lipoproteins. The current model of innate immune recognition of Gram positive bacteria suggests bacterial cell wall interacts with host recognition proteins, such as toll-like receptors (TLR) and Nod proteins. We describe an additional recognition system mediated by the platelet activating factor receptor (PAFr) and directed to the pathogen associated molecular pattern (PAMP) phosphorylcholine that results in uptake of bacterial components into host cells. Intravascular choline-containing cell walls bound to endothelial cells and caused rapid lethality in wild type, Tlr2-/- and Nod2-/- mice, but not in Pafr-/- mice. Cell wall exited the vasculature into the heart and brain, accumulating within endothelial cells, cardiomyocytes and neurons in a PAFr-dependent way. Physiological consequences of the cell wall/PAFr interaction were cell specific, being noninflammatory in endothelial cells and neurons, but causing rapid loss of cardiomyocyte contractility that contributed to death. Thus, PAFr shepherds phosphorylcholine-containing bacterial components such as cell wall into host cells from where the response ranges from quiescence to severe pathophysiology. Keywords: Competitive hybridizations The ten experiments in this series comprise of four distinct experiments, two of which were performed as biological triplicates and two as biological duplicates. The table below describes the overall design in detail: File Name Experiment 16011868017643v41_GEO_format.txt RBCEC Replicate 1 16011868017644v41_GEO_format.txt RBCEC Replicate 2 251186821865v41_GEO_format.txt Neuron Replicate 1 16011868021377v41_GEO_format.txt Neuron Replicate 2 251186821690v41_GEO_format.txt CW/Lyt44 Replicate 1 251186821691v41_GEO_format.txt CW/Lyt44 Replicate 2 251186821692v41_GEO_format.txt CW/Lyt44 Replicate 1 251186821693v41_GEO_format.txt CW+TNF/Lyt44+TNF Replicate 1 251186821694v41_GEO_format.txt CW+TNF/Lyt44+TNF Replicate 2 251186829677v41_GEO_format.txt CW+TNF/Lyt44+TNF Replicate 3

Project description:This data series contains spotted oligo microarray data from 10 different experiments using Agilent Rat v2 microarrays. This data is being made public in support of Fillon S et al. Journal of Immunology, (2006). Proinflammatory bacterial components are at least partially responsible for causing the clinical features of sepsis, a syndrome that causes >100,000 deaths each year in the US (1). In the case of Gram positive infection, a key bacterial element recognized by the innate immune system is the cell wall, a complex network of peptidoglycan covalently linked to teichoic acids, proteins and lipoproteins. The current model of innate immune recognition of Gram positive bacteria suggests bacterial cell wall interacts with host recognition proteins, such as toll-like receptors (TLR) and Nod proteins. We describe an additional recognition system mediated by the platelet activating factor receptor (PAFr) and directed to the pathogen associated molecular pattern (PAMP) phosphorylcholine that results in uptake of bacterial components into host cells. Intravascular choline-containing cell walls bound to endothelial cells and caused rapid lethality in wild type, Tlr2-/- and Nod2-/- mice, but not in Pafr-/- mice. Cell wall exited the vasculature into the heart and brain, accumulating within endothelial cells, cardiomyocytes and neurons in a PAFr-dependent way. Physiological consequences of the cell wall/PAFr interaction were cell specific, being noninflammatory in endothelial cells and neurons, but causing rapid loss of cardiomyocyte contractility that contributed to death. Thus, PAFr shepherds phosphorylcholine-containing bacterial components such as cell wall into host cells from where the response ranges from quiescence to severe pathophysiology. Keywords: Competitive hybridizations

Project description:Platelet-activating factor stimulates phosphatidylinositol turnover in human platelets as indicated by [32P]phosphatidate accumulation in platelets pre-labelled with [32P]Pi, and by [3H]phosphatidate accumulation and [3H]phosphatidylinositol loss in platelets pre-labelled with [3H]arachidonate. These effects of platelet-activating factor are direct and are independent of the production and/or release of endogenous platelet agonists such as ADP, 5-hydroxytryptamine and thromboxane A2.

Project description:Calyculin A, the potent inhibitor of type 1 (PP1) and type 2A (PP2A) phosphatases, has been employed in order to investigate the role of endogenously activated PP1/PP2A in the signal-transduction pathway of platelet-activating-factor (PAF)-stimulated platelets. Calyculin A alone caused an increase in protein phosphorylation in unstimulated platelets, with the detection of a number of newly phosphorylated proteins, whereas in PAF-stimulated platelets phosphorylation of the major substrates of protein kinase C and myosin light-chain kinase were no longer transient, but phosphorylation was sustained. PP1/PP2A appear to play a role in Ca2+ homoeostasis, as inhibition of PP1/PP2A caused an inhibition of Ca2+ mobilization and Ca2+ influx through the plasma membrane in PAF-stimulated platelets. The effect of calyculin A on Ca2+ mobilization correlated with the observed inhibition of the production of the signal molecule Ins(1,4,5)P3. The release reaction (which is a Ca(2+)-dependent event) was also inhibited by calyculin A. The results are discussed in relation to the possible role of protein kinase C in mediating the events leading to the effects observed with calyculin A.

Project description: Not available

Project description:Platelet-activating factor (PAF) is a potent, bioactive phospholipid that acts on multiple cells and tissues through its G protein-coupled receptor (GPCR). PAF is not stored but is rapidly generated via enzymatic acetylation of the precursor 1-O-hexadecyl-2-hydroxy-sn-glycero-3-phosphocholine (lysoPAF). The bioactivity of PAF is effectively and tightly regulated by PAF acetylhydrolases, which convert PAF back to lysoPAF. Previous studies report that lysoPAF is an inactive precursor and metabolite of PAF. However, lysoPAF has not been carefully studied in its own context. Here we report that lysoPAF has an opposing effect of PAF in the activation of neutrophils and platelets. Whereas PAF potentiates neutrophil NADPH oxidase activation, lysoPAF dose-dependently inhibits this function. Inhibition by lysoPAF is not affected by the use of a PAF receptor antagonist or genetic deletion of the PAF receptor gene. The mechanism of lysoPAF-mediated inhibition of neutrophils involves an elevation in the intracellular cAMP level, and pharmacological blockade of adenylyl cyclase completely reverses the inhibitory effect of lysoPAF. In addition, lysoPAF increases intracellular cAMP levels in platelets and inhibits thrombin-induced platelet aggregation, which can be reversed by inhibition of protein kinase A. These findings identify lysoPAF as a bioactive lipid with opposing functions of PAF and suggest a novel and intrinsic regulatory mechanism for balance of the potent activity of PAF.

Project description:Platelet-activating factor (PAF) is a pleiotropic phospholipid with proinflammatory, procoagulant and angiogenic actions on the vasculature. We and others have reported the presence of PAF receptor (Ptafr) at intracellular sites such as the nucleus. However, mechanisms of localization and physiologic functions of intracellular Ptafr remain poorly understood. We hereby identify the importance of C-terminal motif of the receptor and uncover novel roles of Rab11a GTPase and importin-5 in nuclear translocation of Ptafr in primary human retinal microvascular endothelial cells. Nuclear localization of Ptafr is independent of exogenous PAF stimulation as well as intracellular PAF biosynthesis. Moreover, nuclear Ptafr is responsible for the upregulation of unique set of growth factors, including vascular endothelial growth factor, in vitro and ex vivo. We further corroborate the intracrine PAF signaling, resulting in angiogenesis in vivo, using Ptafr antagonists with distinct plasma membrane permeability. Collectively, our findings show that nuclear Ptafr translocates in an agonist-independent manner, and distinctive functions of Ptafr based on its cellular localization point to another dimension needed for pharmacologic selectivity of drugs.

Project description:"Let's Move!" is a comprehensive initiative, launched by the First Lady, Michelle Obama, dedicates to solving problems of obesity, which is growing in child. The life behaviors do affect obesity; however, the mechanistic insight in molecular level is still not clear. In this study, by continually monitoring mouse body weight under chow and high fat western diets as well as metabolic, physical activity and food intake behaviors assessed in a CLAMS Comprehensive Lab Animal Monitoring System, we demonstrated that the platelet-activating factor receptor (PTAFR) contributes to modification of life behaviors. PTAFR does not affect metabolism of ingested dietary fat and carbohydrate in young animals; however, Ptafr ablation dramatically increased weight gain without affecting adipose tissue accumulation. Ptafr-/- mice possess new habits that increased food intake and decreased movement. Our studies suggest that regulation of PTAFR activity may be a novel strategy to control obesity in children or young adults.

Project description:Corals and humans represent two extremely disparate metazoan lineages and are therefore useful for comparative evolutionary studies. Two lipid-based molecules that are central to human immunity, platelet-activating factor (PAF) and Lyso-PAF were recently identified in scleractinian corals. To identify processes in corals that involve these molecules, PAF and Lyso-PAF biosynthesis was quantified in conditions known to stimulate PAF production in mammals (tissue growth and exposure to elevated levels of ultraviolet light) and in conditions unique to corals (competing with neighbouring colonies over benthic space). Similar to observations in mammals, PAF production was higher in regions of active tissue growth and increased when corals were exposed to elevated levels of ultraviolet light. PAF production also increased when corals were attacked by the stinging cells of a neighbouring colony, though only the attacked coral exhibited an increase in PAF. This reaction was observed in adjacent areas of the colony, indicating that this response is coordinated across multiple polyps including those not directly subject to the stress. PAF and Lyso-PAF are involved in coral stress responses that are both shared with mammals and unique to the ecology of cnidarians.