Daniel Abran

Regulation of eNOS Expression in Brain Endothelial Cells by Perinuclear EP3 Receptors

We reported upregulation of endothelial nitric oxide synthase (eNOS) by PGE2 in tissues and presence of perinuclear PGE2 receptors (EP). We presently studied mechanisms by which PGE2 induces eNOS expression in cerebral microvessel endothelial cells (ECs). 16,16-Dimethyl PGE2 and selective EP3 receptor agonist M&B28767 increased eNOS expression in ECs and the NO-dependent vasorelaxant responses induced by substance P on cerebral microvessels. These effects could be prevented by prostaglandin transporter blocker bromcresol green and actinomycin D. EP3 immunoreactivity was confirmed on plasma and perinuclear membrane of ECs. M&B28767 increased eNOS RNA expression in EC nuclei, and this effect was augmented by overexpression of EP3 receptors. M&B28767 also induced increased phosphorylation of Erk-1/2 and Akt, as well as changes in membrane potential revealed by the potentiometric fluorescent dye RH421, which were prevented by iberiotoxin; perinuclear KCa channels were detected, and their functionality corroborated by NS1619-induced Ca2+ signals and nuclear membrane potential changes. Moreover, pertussis toxin, Ca2+ chelator, and channel blockers EGTA, BAPTA, and SK&F96365, as well as KCa channel blocker iberiotoxin, protein-kinase inhibitors wortmannin and PD 98059, and NF-&kgr;B inhibitor pyrrolidine dithiocarbamate prevented M&B28767-induced increase in Ca2+ transients and/or eNOS expression in EC nuclei. We describe for the first time that PGE2 through its access into cell by prostaglandin transporters induces eNOS expression by activating perinuclear EP3 receptors coupled to pertussis toxin-sensitive G proteins, a process that depends on nuclear envelope KCa channels, protein kinases, and NF-&kgr;B; the roles for nuclear EP3 receptors seem different from those on plasma membrane.

A Major Role for Prostacyclin in Nitric Oxide–Induced Ocular Vasorelaxation in the Piglet

We studied the mechanisms of retinal and choroidal vasorelaxation elicited by nitric oxide (NO) using piglet eyes. The NO donors sodium nitroprusside (SNP) and diethylamine-NONOate caused comparable concentration-dependent relaxation that was partially (approximately 40%) attenuated by the guanylate cyclase inhibitors methylene blue and LY83583 and reduced to a lesser extent (approximately 25%) by the inhibitor of cGMP-dependent kinase, KT 5823. In contrast, NO-induced dilatation (by NO donors and endogenous NO after stimulation with bradykinin) was substantially (approximately 70%) diminished by the KCa channel blockers tetraethylammonium (TEA), charybdotoxin, and iberiotoxin; by the cyclooxygenase inhibitors indomethacin and ibuprofen; by the prostaglandin I (PGI2) synthase inhibitor trans-2-phenyl cyclopropylamine (TPC); and by the removal of endothelium; whereas relaxation of endothelium-denuded vasculature to SNP was unaltered by indomethacin, TPC, and charybdotoxin but was nearly nullified by methylene blue and the Kv channel blocker 4-aminopyridine. NO donors significantly increased PGI2 synthesis and the putative PGI2 receptor-coupled second messenger cAMP, from ocular vasculature (retinal microvessels and choroidal perfusate), and this increase in PGI2 formation was markedly reduced by TPC, tetraethylammonium, charybdotoxin, and/or the removal of endothelium, but it was only slightly reduced by methylene blue and LY83583. Also, SNP and KCa channel openers NS1619 and NS004 caused an increase in PGI2 synthesis in cultured endothelial cells, which was virtually abolished by KCa blockers. Finally, vasorelaxation to a cGMP analogue, 8-bromo cGMP, and protein kinase G stimulant beta-phenyl-1,N2-etheno-8-bromoguanosine 3:5-cyclic monophosphate was mostly Kv dependent and, in contrast to NO, largely unrelated to PGI2 formation. In conclusion, data indicate that NO-induced ocular vasorelaxation is partly mediated by cGMP through its action on smooth muscle, and more importantly, by stimulating PGI2 formation of endothelial origin via a mechanism mostly independent of guanylate cyclase, which involves the opening of a KCa channel.

Hydrolysis of Bimatoprost (Lumigan) to its Free Acid by Ocular Tissue In Vitro

We determined whether bimatoprost, which has been reported to act via putative prostamide receptors, could be hydrolyzed to its free acid (17-phenyl-PGF(2 alpha)), a potent FP receptor agonist, by human ocular tissue in vitro. We developed a gas chromatography/mass spectrometric method to measure 17-phenyl-PGF(2 alpha) levels at sub-picomolar levels. We then analyzed the amount of 17-phenyl-PGF(2 alpha) present after incubation of 50 microl Lumigan (0.03% bimatoprost) with eye tissue using this assay. We found that cornea, sclera, iris, and ciliary body, all rapidly hydrolyzed bimatoprost to 17-phenyl-PGF(2 alpha) with linear kinetics at a rate of 6.3, 2.0, 2.8, and 1.5 pmol mg tissue(-1) hr(-1), respectively. For cornea, sclera, and ciliary body, this linear rate of hydrolysis continued over a period of at least three hours, while iris-induced hydrolysis did not continue beyond one hour. Our findings suggest that bimatoprost can act as prodrug for FP receptor activation and questions the concept of a prostamide receptor agonist.

Prevention of postasphyxial increase in lipid peroxides and retinal function deterioration in the newborn pig by inhibition of cyclooxygenase activity and free radical generation

ABSTRACT: Free radicals have been implicated in the development of injury to the immature retina. Asphyxia increases free radicals as well as prostaglandins (PG) in neural tissues. We assessed whether in the retina the cyclooxygenase pathway contributes to free radical formation after oxidative insults such as asphyxia, which in turn disrupts retinal function. Newborn pigs were treated with either saline, ibuprofen (194 μmol/kg i.v.), or allopurinol (1 mmol/kg i.v.), and retinal malondialdehyde (MDA), hydroperoxides, PGE2 and PGF2α levels, and the amplitudes and implicit times of the a- and b-waves of the full-field electroretinogram were measured before and 1 h after a 5-min period of asphyxia. In saline-treated animals, asphyxia caused a marked increase (p < 0.01) in MDA, hydroperoxides, PGE2, and PGF2α concentrations in the retina. This was associated with a significant decrease (p < 0.01) in the b-wave amplitude measured under scotopic and photopic conditions and an increase in the b-wave implicit times. Ibuprofen and another cyclooxygenase inhibitor, indomethacin (28 μmol/kg i.v.), decreased PGE2 and PGF2α levels and prevented the increase in MDA and hydroperoxides after asphyxia. Allopurinol maintained low concentrations of MDA and hydroperoxides after asphyxia. Both ibuprofen and allopurinol prevented the postasphyxial changes in the b-wave amplitude and diminished the delay in implicit time observed after asphyxia in saline-treated pigs. Our findings suggest that in the retina after asphyxia free radicals appear to originate primarily from the cyclooxygenase pathway and contribute to the deterioration in retinal electrophysiologic function of the newborn animal. Cyclooxygenase inhibitors, like free radical scavengers, may protect retinal function from deteriorating after oxidative stresses.

Light Induces Peroxidation in Retina by Activating Prostaglandin G/H Synthase

Prostaglandin G/H synthase (PGHS) has been shown to generate peroxides to a significant extent in the retina and absorbs light at the lower end of the visible spectrum. We postulated that PGHS could be an important initial source of peroxidation in the retina exposed to light, which would in turn alter retinal function. Exposure of pig eyes (in vivo) to light (350 fc/3770 lx) caused after 3 h a 50% increase and by 5 h a 30% decrease in a- and b-wave amplitudes of the electroretinogram (ERG) which were comparable at 380-650 nm and 380-440 nm but were not observed at wavelengths > 450 nm. These effects of light were prevented by free radical scavengers (dimethylthiourea and high-dose allopurinol) and PGHS inhibitors (naproxen and diclofenac), but stable analogs of prostaglandins did not affect the ERG. Both increases and subsequent decreases in ERG wave amplitudes following light exposure in vivo were associated with increases in retinal prostaglandin and malondialdehyde (peroxidation product) levels, which were inhibited by the nonselective PGHS blockers, naproxen and diclofenac. Similar observations were made in vitro on isolated porcine eyecups as well as on retinal membranes exposed to light (250 fc/ 2700 lx) 380-650 nm and 380-440 nm but not at > 500 nm. Both PGHS-1 and PGHS-2 contributed equivalently to light-induced prostaglandin synthesis, as shown after selective PGHS-2 blockers, but mRNA expression of PGHS-1 and 2 was not affected by light. Finally, light stimulated activities of pure PGHS-1 and PGHS-2 isozymes, and these were also shown to produce superoxide radical (detected with fluorogenic spin trap, proxyl fluorescamine). Taken together, data suggest that PGHS- (1 and 2) is activated by short wavelength visible light, and in the retina is an important source of reactive oxygen species which in turn alter retinal electrophysiological function. PGHS thus seems a likely chromophore in setting forth photic-induced retinal injury. Findings provide an explanation for increased sensitivity of the retina to visible light predominantly at the far blue range of its spectrum.

Characterization and ontogeny of PGE2 and PGF2α receptors on the retinal vasculature of the pig

The vasoconstrictor effects of PGE2 and PGF2 alpha are less pronounced on retinal vessels of the newborn than of the adult pig. We tested the hypothesis that the decreased vasomotor response to these prostaglandins might be due to relatively fewer receptors and/or different receptor subtypes (in the case of PGE2) on retinal vessels of the newborn animal. Binding studies using [3H]PGE2 and [3H]PGF2 alpha revealed that PGE2 (EP) and PGF2 alpha (FP) receptor densities in retinal microvessel membrane preparations from newborn animals were approximately 25% of those found in vessels from the adult. The Kd for PGF2 alpha did not differ; however, the Kd for PGE2 was less in newborn than in adult vessels. Competition binding studies using AH 6809 (EP1 antagonist), butaprost (EP2 agonist), M/+B 28,767 (EP3 agonist), and AH 23848B (EP4 antagonist) suggested that the retinal vessels of the newborn contained approximately equal number of EP1 and EP2 receptor subtypes whereas the main receptor subtype in the adult vessels was EP1. In addition, PGE2 and butaprost produced comparable increases in adenosine 3,5-cyclic monophosphate synthesis in newborn and adult vessels. PGE2, 17-phenyl trinor PGE2 (EP1 agonist) and PGF2 alpha caused a 2.5 to 3-fold greater increase in inositol 1,4,5-triphosphate (IP3) formation in adult than in newborn preparations. It is concluded that fewer PGF2 alpha receptors and an associated decrease in receptor-coupled IP3 formation in the retinal vessels of the newborn could lead to weaker vasoconstrictor effects of PGF2 alpha on retinal vessels of the newborn than of adult pigs; fewer EP1 receptors (associated with vasoconstriction) and a relatively greater proportion of EP2 receptors (associated with vasodilation) might be responsible for the reduced retinal vasoconstrictor effects of PGE2 in the newborn.

Metabolism of 4,7,10,13,16,19-Docosahexaenoic Acid in Isolated Perfused Adult and Newborn Pig Eyes

We performed open-circuit perfusions of newborn and adult pig eyes to study the age-dependent metabolism of 4,7,10,13,16,19-docosahexaenoic acid (DHA) in this organ. DHA taken up by the perfused eyes was partitioned into glycerolipids, beta-oxidation, and the intracellular nonesterified fatty acid pool. In newborn eyes, DHA was incorporated into structural lipids to a greater extent than in adult eyes. Competition experiments suggest that the adult eye is more selective for DHA than the newborn eye. Finally, pulse-chase data indicate that DHA transport from the circulation across the retinal pigment epithelium and into the retina is more rapid in adult than in newborn eyes. The results are discussed with respect to the rapid accumulation of retinal DHA in early life and the avid retention of this fatty acid by the adult retina.