Prostaglandin D2 mediates neuronal protection via the DP1 receptor

Cyclo-oxygenases (COXs) catalyze the first committed step in the synthesis of the prostaglandins PGE(2), PGD(2), PGF(2alpha), PGI(2) and thomboxane A(2). Expression and enzymatic activity of COX-2, the inducible isoform of COX, are observed in several neurological diseases and result in significant neuronal injury. The neurotoxic effect of COX-2 is believed to occur through downstream effects of its prostaglandin products. In this study, we examined the function of PGD(2) and its two receptors DP1 and chemoattractant receptor-homologous molecule expressed on Th2 cells (CRTH2) (DP2) in neuronal survival. PGD(2) is the most abundant prostaglandin in brain and regulates sleep, temperature and nociception. It signals through two distinct G protein-coupled receptors, DP1 and DP2, that have opposing effects on cyclic AMP (cAMP) production. Physiological concentrations of PGD(2) potently and unexpectedly rescued neurons in paradigms of glutamate toxicity in cultured hippocampal neurons and organotypic slices. This effect was mimicked by the DP1-selective agonist BW245C but not by the PGD(2) metabolite 15d-PGJ(2), suggesting that neuroprotection was mediated by the DP1 receptor. Conversely, activation of the DP2 receptor promoted neuronal loss. The protein kinase A inhibitors H89 and KT5720 reversed the protective effect of PGD(2), indicating that PGD(2)-mediated neuroprotection was dependent on cAMP signaling. These studies indicate that activation of the PGD(2) DP1 receptor protects against excitotoxic injury in a cAMP-dependent manner, consistent with recent studies of PGE(2) receptors that also suggest a neuroprotective effect of prostaglandin receptors. Taken together, these data support an emerging and paradoxical neuroprotective role of prostaglandins in the CNS.     

Stimulation of hepatic glycogenolysis by phorbol 12-myristate 13-acetate.

In isolated perfused rat livers, infusion of phorbol 12-myristate 13-acetate (PMA) (150 nM) resulted in a 3-fold stimulation of the rate of glucose production. This response was maximal at a perfusate PMA concentration of 150 nM, and was significantly diminished at higher concentrations of PMA (e.g. 300 nM). Stimulation of glycogenolysis by PMA was greatly decreased in livers perfused with Ca2+-free medium. PMA infusion into livers perfused in the absence of Ca2+ did not result in Ca2+ efflux from the livers. Additionally, in hepatocytes isolated from livers of fed rats, neither PMA nor 1-oleoyl-2-acetyl-rac-glycerol stimulated the rate of glucose production. Although indomethacin has been demonstrated to block PMA-stimulated hepatic glycogenolysis [Garcia-Sainz & Hernandez-Sotomayor (1985) Biochem. Biophys. Res. Commun. 132, 204-209], infusion of PMA into perfused rat livers did not alter the rates of production of either prostaglandin E2 or 6-oxo-prostaglandin F1 alpha in the livers. These data, along with the observed increases in the perfusion pressure and decrease in O2 consumption in isolated perfused livers suggest that phorbol-ester-stimulated glycogenolysis is not a consequence of a direct effect of phorbol ester on liver parenchymal cells.     

Interleukin-4 enhances peritoneal B cell stimulation induced by phorbol ester

The activation requirements of murine peritoneal B cells differ from those of conventional (splenic) B cells; in particular, peritoneal B cells are stimulated to enter S phase by phorbol ester, acting alone. This pathway was studied to assess the susceptibility of peritoneal B cells to regulation by T cell products. Three T cell supernatants enhanced phorbol myristate acetate (PMA)-induced peritoneal B cell stimulation. This enhancement was reproduced by recombinant interleukin 4 (IL-4), and IL-4-mediated enhancement was reversed by 11B11 anti-IL-4 antibody. Enhancement of S phase entry was dose dependent for IL-4 and required stimulatory concentrations of PMA. In addition, IL-4 in combination with PMA produced a marked increase in IgM secretion by peritoneal B cells cultured in vitro. Neither an enhancement of S phase entry nor an increase in IgM secretion was observed with splenic B cells similarly treated with IL-4 and PMA. These results suggest that IL-4 modulates the proliferative and differentiative responses of the unusual B cells that reside in the peritoneal cavities of normal mice.     

P2-purinergic control of liver glycogenolysis.

Purinergic agonists cause a dose-dependent activation of glycogen phosphorylase in isolated rat hepatocytes. Half-maximally effective concentrations are 5 X 10(-7)M for ATP, 2 X 10(-6)M for ADP, and about 5 X 10(-5) M for AMP and adenosine. This potency series indicates the presence of P2-purinergic receptors. The mode of action of ATP appears to be identical with that of the Ca2+-dependent glycogenolytic hormones angiotensin, vasopressin and alpha 1-adrenergic agonists. (1) They all require Ca2+ for phosphorylase activation; (2) they do not increase cyclic AMP levels; (3) they are susceptible to heterologous desensitization by vasopressin and phenylephrine; (4) they lower cyclic AMP concentrations in hepatocytes stimulated by glucagon, most probably mediated by an enhanced phosphodiesterase activity.     

Prostaglandin D2-glycerol ester decreases carrageenan-induced inflammation and hyperalgesia in mice

Pain is one of the cardinal signs of inflammation and is present in many inflammatory conditions. Therefore, anti-inflammatory drugs such as NSAIDs also have analgesic properties. We previously showed that prostaglandin D₂-glycerol ester (PGD₂-G), endogenously produced by cyclooxygenase-2 from the endocannabinoid 2-arachidonoylglycerol, has anti-inflammatory effects in vitro and in vivo that are partly mediated by DP1 receptor activation. In this work, we investigated its effect in a model of carrageenan-induced inflammatory pain. PGD₂-G decreased hyperalgesia and edema, leading to a faster recovery. Moreover, PGD₂-G decreased carrageenan-induced inflammatory markers in the paw as well as inflammatory cell recruitment. The effects of PGD₂-G were independent from metabolite formation (PGD₂ and 15d-PGJ₂-G) or DP1 receptor activation in this model. Indeed PGD₂ delayed recovery from hyperalgesia while 15d-PGJ₂-G worsened the edema. However, while PGD₂-G decreased hyperalgesia in this model of inflammatory pain, it had no effect when tested in the capsaicin-induced pain model. While the targets mediating the effects of this bioactive lipid in inflammatory pain remain to be elucidated, our findings further support the interest of anti-inflammatory lipid mediators in the management of inflammatory pain.     

Synergistic stimulation of prolactin release by phorbol ester, A23187 and forskolin

The effects of 12-0-tetradecanoyl-phorbol-13-acetate (TPA), A23187, forskolin and thyrotropin-releasing hormone (TRH) on prolactin release from GH4C1 cells were compared. TPA caused a 2-fold release, maximum after 6 or more min, that was sustained for 30 min or more. A23187 caused only a small and variable response that peaked within 4 to 6 min. Combination of TPA and A23187 caused a rapid 3- to 5-fold increase in release that declined slowly. TRH increased prolactin release 3- to 5-fold, reaching a maximum within 4 min, followed by sustained release at lower rates. Forskolin had little effect by itself, but potentiated release caused either by combined TPA and A23187, or by TRH. These data are consistent with a model in which two branches of the Ca2+ messenger system participate in the action of TRH, a calmodulin branch and a C-kinase branch that interact to cause large amounts of sustained release. Forskolin, by regulating the cyclic AMP content of the cell determines the set point around which the Ca2+ messenger system operates.     

The stimulation of glycogenolysis in isolated hepatocytes by opioid peptides.

The opioid peptides [Leu]enkephalin and dynorphin-(1-13) were shown to enhance glycogen breakdown when added directly to hepatocytes. This was the result of a concerted effect on the enzymes of glycogen metabolism, with a stimulation of glycogen phosphorylase activity and a simultaneous decrease in glycogen synthase I activity. The latter only became significant when the enzyme was activated by incubating the cells in presence of 20 mM- or 40 mM-glucose. The effect of the opioid peptides was independent of an increase in cyclic AMP or any change in the activity ratio of the cyclic AMP-dependent protein kinase and was abolished by depleting the cells of Ca2+. Both [Leu]enkephalin and dynorphin-(1-13) produced a significant decrease in cyclic AMP formation, suggesting that in liver, as in neuronal tissue, they may act by inhibiting adenylate cyclase activity.     

Epinephrine is unessential for stimulation of liver glycogenolysis during exercise

To determine the role of adrenal medullary hormones in controlling the rate of liver glycogenolysis during exercise, adrenodemedullated (ADM) and sham-operated (SO) rats were run on a rodent treadmill at 21 m/min up a 15% grade for 0, 30, or 60 min. Rats were anesthetized by intravenous injection of pentobarbital sodium, and liver, muscle, and blood were collected and frozen. Liver glycogen decreased at similar rates in ADM and SO rats. Hepatic adenosine 3',5'-cyclic monophosphate (cAMP), plasma glucagon, and plasma free fatty acids increased to the same extent in both ADM and SO rats. The adrenodemedullation caused a reduction in glycogenolysis in the fast-twitch white region of the quadriceps, soleus, and lateral gastrocnemius during exercise. The normal exercise-induced increase in blood glucose and lactate and the decline in plasma insulin were not observed in the demedullated rats. During submaximal exercise the principal targets for epinephrine released from the adrenal medulla appear to be pancreatic beta-cells and skeletal muscle and not the liver.     

Activation of hepatic glycogenolysis by phagocytic stimulation

Infusion of latex beads into isolated perfused rat livers transiently increased glucose output, perfusate lactate/pyruvate ratio and portal vein pressure, mimicking hepatic effects of heat-aggregated IgG (HAG). Indomethacin attenuated hepatic responses to latex beads, and extracellular calcium was required for full expression of hepatic responses. Prior infusion of HAG inhibited the glycogenolytic response to latex beads, supporting a common mechanism of action for the two agents.     

Stimulation of glycogenolysis by adenine nucleotides in the perfused rat liver.

Infusion of adenine nucleotides and adenosine into perfused rat livers resulted in stimulation of hepatic glycogenolysis, transient increases in the effluent perfusate [3-hydroxybutyrate]/[acetoacetate] ratio, and increased portal vein pressure. In livers perfused with buffer containing 50 microM-Ca2+, transient efflux of Ca2+ was seen on stimulation of the liver with adenine nucleotides or adenosine. ADP was the most potent of the nucleotides, stimulating glucose output at concentrations as low as 0.15 microM, with half-maximal stimulation at approx. 1 microM, and ATP was slightly less potent, half-maximal stimulation requiring 4 microM-ATP. AMP and adenosine were much less effective, doses giving half-maximal stimulation being 40 and 20 microM respectively. Non-hydrolysed ATP analogues were much less effective than ATP in promoting changes in hepatic metabolism. ITP, GTP and GDP caused similar changes in hepatic metabolism to ATP, but were 10-20 times less potent than ATP. In livers perfused at low (7 microM) Ca2+, infusion of phenylephrine before ATP desensitized hepatic responses to ATP. Repeated infusions of ATP in such low-Ca2+-perfused livers caused homologous desensitization of ATP responses, and also desensitized subsequent Ca2+-dependent responses to phenylephrine. A short infusion of Ca2+ (1.25 mM) after phenylephrine infusion restored subsequent responses to ATP, indicating that, during perfusion with buffer containing 7 microM-Ca2+, ATP and phenylephrine deplete the same pool of intracellular Ca2+, which can be rapidly replenished in the presence of extracellular Ca2+. Measurement of cyclic AMP in freeze-clamped liver tissue demonstrated that adenosine (150 microM) significantly increased hepatic cyclic AMP, whereas ATP (15 microM) was without effect. It is concluded that ATP and ADP stimulate hepatic glycogenolysis via P2-purinergic receptors, through a Ca2+-dependent mechanism similar to that in alpha-adrenergic stimulation of hepatic tissue. However, adenosine stimulates glycogenolysis via P1-purinoreceptors and/or uptake into the cell, at least partially through a mechanism involving increase in cyclic AMP. Further, the hepatic response to adenine nucleotides may be significant in regulating hepatic glucose output in physiological and pathophysiological states.     

Synergistic stimulation of thromboxane biosynthesis by calcium ionophore and phorbol ester or thrombin in human platelets

Phorbol ester PMA and low concentrations of calcium ionophore A-23187, which given separately have minimal effect in stimulating thromboxane synthesis in human platelets, showed marked synergism when given simultaneously. A similar synergism can be also demonstrated between thrombin or collagen and low concentrations of A-23187 but not of PMA. Simultaneous addition of thrombin and PMA results in less synthesis of thromboxane than that of thrombin alone. These studies suggest that protein kinase C activation by agonists may not only induce but also regulate thromboxane synthesis in human platelets.     

The induction of glycogenolysis in the perfused liver by platelet activating factor is mediated by prostaglandin D2 from Kupffer cells

Induction of glycogenolysis in the perfused liver by platelet activating factor (PAF) was blocked by the cyclooxygenase inhibitor indomethacin. 3H-labeled PAF was shown to interact in the perfused liver primarily with Kupffer cells. The addition of PAF to Kupffer cells resulted in a dose-dependent stimulation of prostaglandin D2 (PGD2) production, which was identified as the main eicosanoid formed after PAF stimulation of the Kupffer cells. PGD2 was able to induce a dose-dependent stimulation of glycogenolysis both in the perfused liver and in isolated parenchymal cells. The time-dependency of the PGD2 production and the glucose output by the perfused liver is consistent with a primary interaction of PAF with the Kupffer cells, followed by PGD2 formation, which subsequently stimulates glucose production in parenchymal cells.     

Inhibition of thymine dimer excision by the phorbol ester, phorbol myristate acetate

The effect of the promoting agent, phorbol myristate acetate, on repair of UV-induced damage in HeLa cells was studied. The agent decreased survival and subsequent colony-forming ability of irradiated cells and inhibited removal of UV-induced thymine-containing dimers from DNA of irradiated cells.     

Control of glycogenolysis and hemodynamics in perfused rat liver by the sympathetic innervation. Dependence on stimulation frequency and duration

Perivascular stimulation of the hepatic nerves in the in situ perfused rat liver with a constant frequency of 20 Hz over a constant period of 5 min had previously been shown to cause an increase of glucose output, a shift from lactate uptake to release, a reduction in perfusion flow (Hartmann et al. (1982) Eur. J. Biochem. 123, 521-526) and an overflow of noradrenaline into the hepatic vein (Beckh et al. (1982) FEBS Lett. 149, 261-265). In the present study the dependence of the metabolic and hemodynamic effects on the frequency between 1 and 30 Hz and duration of stimulation between 0.5 and 5 min was investigated. Over a constant stimulation period of 5 min the alteration in glucose exchange was maximal with a frequency of 10 Hz and half-maximal with 4 Hz. The corresponding values for the exchange of lactate were 5 Hz and 2 Hz, respectively, and for the perfusion flow 2.5 Hz and 1.5 Hz, respectively. An increase of noradrenaline overflow was not observed with the lower frequencies of 1 and 2.5 Hz; it was maximal at 10 Hz and half-maximal at 6.5 Hz. At a constant frequency of 20 Hz the increase in glucose release was maximal with a total stimulation period of 1 min and half-maximal with a period of 0.4 min. An essentially maximal alteration of lactate exchange and perfusion flow as well as of noradrenaline overflow was also effected by a stimulation period of 1 min.(ABSTRACT TRUNCATED AT 250 WORDS)     

The influence of hypothyroidism on the adrenergic stimulation of glycogenolysis in perfused rat liver

The ability of noradrenaline (1 microM), phenylephrine (10 microM), and isoproterenol (1 microM) to stimulate glycogenolysis in euthyroid and hypothyroid perfused rat livers was investigated. It was found that hypothyroidism severely impaired alpha-receptor-mediated (noradrenaline, phenylephrine) glucose release. The initial Ca2+ efflux and K+ influx induced by these agonists in the euthyroid control group were almost totally absent in the hypothyroid group, while glycogen phosphorylase a activity in the hypothyroid rat livers was markedly lower than in the controls after infusing noradrenaline for 1 min. Diminished CA2+ efflux (and possibly diminished K+ influx) is likely to play a role in the large impairment in the action of noradrenaline or phenylephrine on glycogenolysis in the perfused hypothyroid rat liver. After prolonged stimulation (15 min) with noradrenaline, however, the phosphorylase a activity in the hypothyroid and euthyroid groups did not differ significantly. This was accompanied by Ca2+ influx in the hypothyroid livers, probably facilitated by a beta-adrenergic effect of noradrenaline in this group. Hypothyroidism potentiated the effect of isoproterenol on glycogenolysis. The glucose 6-phosphate content in the hypothyroid rat livers was markedly higher than in the euthyroid group after stimulation by noradrenaline or isoproterenol.     

Induction of ornithine decarboxylase in rat liver by phorbol ester is mediated by prostanoids from Kupffer cells

Administration of phorbol 12-myristate 13-acetate (PMA) to rats in vivo resulted in the induction of ornithine decarboxylase activity in the liver which could be blocked by preinjection of indomethacin, a cyclooxygenase inhibitor. In vitro administration of PMA to primary cultures of rat parenchymal cells did not lead to an induction of ornithine decarboxylase activity. It was investigated to what extent non-parenchymal liver cells could play an intermediary role in the expression of the PMA effect on ornithine decarboxylase activity in parenchymal liver cells. Addition of conditioned medium from PMA-activated Kupffer cells to cultured parenchymal cells led to the induction of ornithine decarboxylase activity in parenchymal cells. This effect was not observed with conditioned medium from untreated Kupffer cells or from Kupffer cells treated with PMA plus indomethacin. Conditioned media from PMA-treated or untreated endothelial liver cells were ineffective in the induction of ornithine decarboxylase activity in parenchymal liver cells. Prostaglandin D2, the main eicosanoid produced by Kupffer cells, was able to stimulate the synthesis of ornithine decarboxylase in parenchymal liver cells (up to 40-fold) in a dose-dependent way. Prostaglandin (PG) D2 appeared to be a more potent inducer of ornithine decarboxylase activity in parenchymal cells than PGE1 and PGE2. It is concluded that intercellular communication inside the liver mediated by prostaglandins derived from activated Kupffer cells may form a mechanism to induce synthesis of specific proteins in parenchymal cells.