Expression of functional prostaglandin D (DP) receptors in human corpus cavernosum smooth muscle.

Prostaglandin D(2) (PGD(2)) binds to specific G-protein coupled receptors (DP) and induces smooth muscle relaxation by stimulating the synthesis of intracellular cAMP. In this study, we examined the role of PGD(2) and DP receptors in regulating human penile smooth muscle contractility. We determined that human corpus cavernosum tissue and smooth muscle cells in culture expressed functional DP receptor and lipocalin-like prostaglandin D synthase by reverse-transcribed polymerase chain reaction (RT-PCR). Functional PGD synthase activity was confirmed by the synthesis of PGD(2) in human corpus cavernosum smooth muscle cells upon addition of exogenous arachidonic acid. Organ bath preparations of human corpus cavernosum tissue strips, contracted with phenylephrine, relaxed in a dose-dependent fashion to either PGD(2) or the DP selective agonist BW245C. Cultures of human corpus cavernosum smooth muscle cells treated with BW245C showed a two-fold increase in cAMP synthesis. These data are consistent with the expression of functional DP receptors in human corpus cavernosum. This suggests the presence of an intact prostanoid autocrine system that may play a role in regulating penile erectile function.

O2-dependent prostanoid synthesis activates functional PGE receptors on corpus cavernosum smooth muscle.

We have previously demonstrated that decreased O2 tension inhibits prostaglandin synthesis from human corpus cavernosum smooth muscle cells in static culture over 8-18 h (R. B. Moreland et al., Molecular Urology 2: 41-47, 1998). In this report, an experimental system was designed that allowed determination of the effects of O2 tension changes over the time frame of physiological penile erection. Human corpus cavernosum smooth muscle cells were cultured on microcarrier beads in enclosed stirrer flasks so that rapid changes of O2 tension could be modulated. After 18 h of equilibration at 30-40 mmHg to simulate blood PO2 at penile flaccidity, O2 tension was increased to 100 mmHg for 1 h and then returned to 30-40 mmHg. Media samples were withdrawn for prostanoid synthesis and cell samples were taken for cAMP determinations. After 18 h of 30-40 mmHg PO2 values, prostanoid synthesis by human corpus cavernosum smooth muscle cells was low (0.1-0.7 pmol/10(6) cells). When PO2 was increased to 100 mmHg, a rapid increase in PGE2 >> PGF2alpha > PGD2 was observed (thromboxane A2 was undetectable), which peaked at 5.7 pmol PGE2/10(6) cells. Increased O2 tension correlated with increased PGE2 and increased intracellular synthesis of cAMP. The prostaglandin G/H synthase inhibitor indomethacin or the E prostanoid (EP2)-selective antagonist AH-6809 each inhibited the O2-tension-dependent increases in cAMP. These data support a role of differential O2 tension in the penis in the smooth muscle synthesis of PGE2, which in turn increases cAMP synthesis via EP2 receptors.

Synthesis of 8-epi-prostaglandin F2alpha by human endothelial cells: role of prostaglandin H2 synthase.

The experiments described in this paper were designed to determine the mechanism underlying the increase in 8-isoprostaglandin F(2alpha) (8-epi-PGF(2alpha)) production by cultured human endothelial cells during reoxygenation following hypoxia. Human umbilical artery endothelial cells were grown on microcarrier beads and exposed to sequential periods of normoxia, hypoxia, and reoxygenation. The amount of 8-epi-PGF(2alpha) in the medium was determined by ELISA. The production of 8-epi-PGF(2alpha) decreased by greater than 90% during hypoxia. Upon reoxygenation 8-epi-PGF(2alpha) production increased linearly for 90 min reaching nearly 3 times normoxic levels. When added to the medium during reoxygenation, neither superoxide dismutase nor Tiron, a cell-permeable superoxide scavenger, inhibited 8-epi-PGF(2alpha) production. However, 8-epi-PGF(2alpha) production was inhibited by catalase. The production of 8-epi-PGF(2alpha) was also inhibited by indomethacin and aspirin. Exogenous hydrogen peroxide stimulated 8-epi-PGF(2alpha) production by normoxic cells, and aspirin inhibited the hydrogen peroxide-mediated increase in 8-epi-PGF(2alpha) production. These results indicate that the reactive oxygen species responsible for 8-epi-PGF(2alpha) synthesis during reoxygenation is hydrogen peroxide and that in endothelial cells 8-epi-PGF(2alpha) synthesis is mediated by prostaglandin H(2) synthase (PGHS). To verify the role of PGHS in 8-epi-PGF(2alpha) synthesis, human PGHS-1 was expressed in COS-7 cells, a PGHS negative cell line that does not synthesize 8-epi-PGF(2alpha). In the presence of exogenous arachidonic acid the COS-7 cells expressing human PGHS-1 produced substantial amounts of PGE(2) and 8-epi-PGF(2alpha). These data indicate that human PGHS-1 can support the synthesis of 8-epi-PGF(2alpha) and that 8-epi-PGF(2alpha) synthesis by cultured human endothelial cells during reoxygenation is dependent on the activity of PGHS-1.

Effect of hypoxia on steady-state arachidonic acid metabolism in bovine aortic endothelial cells.

At the onset of acute hypoxia, eicosanoid synthesis by bovine aortic endothelial cells (BAEC) markedly decreases, reflecting a decreased release of arachidonic acid from endogenous stores. To determine the cause of decreased arachidonic acid release, we pulse-labeled BAEC with [14C]arachidonic acid for 5 min under normoxic conditions and chased cells for 1 h under normoxic or hypoxic conditions. The 14C incorporation and specific activity (disintegrations per minute per nanomole) of three major arachidonyl molecular species (16:0-20:4, 18:1-20:4, and 18:0-20:4) of each phospholipid class were determined in cells chased under either of the two conditions. There was no relevant difference between normoxic and hypoxic cells in the metabolism of any of the arachidonyl molecular species of diacyl lipids. However, there was a marked decrease (approximately 40%) in the turnover of arachidonyl alkenylacyl phosphatidylethanolamine in the hypoxic cells. From these results, it appears that the source of arachidonic acid supporting constitutive eicosanoid synthesis in BAEC is alkenylacyl phosphatidylethanolamine and that the limiting enzyme activity determining the rate of eicosanoid synthesis is a plasmalogen-specific phospholipase A2.

Effects of oxygen tension and shear stress on human endothelial cell prostacyclin production.

Under in vivo conditions of ischemia and reperfusion, vascular endothelium (EC) experience concurrent changes in oxygen tension, shear stress, and the local concentration of metabolites. These studies explored the combined effects of shear stress and oxygen tension on EC prostacyclin production. EC grown on microcarrier beads were exposed to 120 min of normoxia and basal shear stress by stirring at 20 rpm. After normoxia, EC were exposed to hypoxia (2% 0(2), 20 rpm), ischemia (2%, 0(2), 5 rpm) or sham ischemia (20% 0(2), 5 rpm). Following hypoxia, EC were reoxygenated (20% 0(2), 20 rpm). After ischemia and sham ischemia, EC were reperfused (20% 0(2), 20 rpm). Minimal accumulation of metabolites occurred during normoxia, hypoxia, and reperfusion. All metabolites were allowed to accumulate in the flasks during ischemia and sham ischemia. Prostacyclin levels were measured by ELISA, and prostaglandin H2 synthase levels in cells were analyzed by immunoblotting. An acute decrease in shear stress decreased prostacyclin production. An acute decrease only in oxygen tension did not alter prostacyclin production significantly. The combined acute decrease in both shear stress and oxygen tension significantly stimulated prostacyclin production for 30 min. By 120 min of ischemia and hypoxia, prostacyclin release was significantly less than sham ischemia. Prostacyclin production after 30 min of reoxygenation was significantly less than that of cells subjected to reperfusion. By 120 min of reperfusion and reoxygenation, there was no significant difference in EC prostacyclin synthesis. These findings suggest that temporal and quantitative aspects of EC prostaglandin synthesis are dependent on both oxygen tension and shear stress.