Inhibition of human platelets and polymorphonuclear neutrophils by the potent and metabolically stable prostaglandin D2 analog ZK 118.182.

The actions of the novel metabolically stable and selective prostaglandin D2 receptor agonist ZK 118.182 ((5Z,13E)-(9R,11R,15S)-9-chloro-15-cyclohexyl-15- hydroxy-16,17,18,19,20-pentanor-3-oxa-5,13-prostadienoic acid) were studied in human platelets and polymorphonuclear neutrophils in vitro and compared to the naturally occurring agonist prostaglandin D2. ZK 118.182 inhibited collagen and ADP induced platelet aggregation more potently than prostaglandin D2 (IC50: 15 nM versus 60 nM) but was less effective than the stable prostacyclin mimetic iloprost (IC50: 3 nM). The same rank order of potencies was observed for the inhibition of collagen-induced platelet ATP secretion. A dose-dependent activation of adenylate cyclase could be demonstrated by ZK 118.182 which was comparable to that of prostaglandin D2 with respect to the concentration needed for half maximal stimulation (ED50) maximal cAMP level achievable. ZK 118.182 also dose dependently reduced the formyl-methionyl-leucyl-phenylalanine (FMLP) or platelet-activating factor (PAF) induced activation of polymorphonuclear neutrophils. Both, the oxygen burst resulting in the generation of superoxide anions and the degranulation of polymorphonuclear neutrophils accompanied by release of the lysosomal enzyme beta-glucuronidase, were significantly and dose dependently inhibited. ZK 118.182 was more potent than prostaglandin D2 in inhibiting polymorphonuclear neutrophil activation in all tests performed. In summary, ZK 118.182 is a prostaglandin D2 mimetic exerting potent inhibitory effects on human platelets and polymorphonuclear neutrophils.

Synergistic interaction of adenylate cyclase activators and nitric oxide donor SIN-1 on platelet cyclic AMP.

The molecular mechanism of the synergistic platelet inhibition by activators of adenylate cyclase and guanylate cyclase in human platelets was investigated. The adenylate cyclase activators iloprost and prostaglandin E1 and the guanylate cyclase activator 3-morpholino-syndnonimine (SIN-1) dose-dependently inhibited thrombin-induced aggregation of washed human platelets. Furthermore, SIN-1 at a concentration inhibiting platelet aggregation by only 10% shifted the IC50 values of iloprost and prostaglandin E1 by one order of magnitude to the left, indicating a synergistic action of adenylate cyclase and guanylate cyclase activators. Iloprost and prostaglandin E1 dose-dependently elevated platelet cAMP without a significant influence on cGMP. In contrast, the platelet cGMP level was dose-dependently elevated by SIN-1. In addiiton, SIN-1 markedly increased cAMP level induced by low concentrations of adenylate cyclase activators (0.1-0.3 nM iloprost or 10-150 nM prostaglandin E1). In contrast, the rise in cAMP induced by higher adenylate cyclase activator concentrations (3 nM iloprost or 30 microM prostaglandin E1) was significantly reduced in the presence of SIN-1. The same biphasic mode of action of SIN-1 was observed with forskolin, an adenylate cyclase stimulator acting receptor independently, indicating a prostacyclin-receptor independent mechanism. The cAMP elevating effect of SIN-1 in the presence of low prostanoid concentrations was completely abolished by piroximone, a selective inhibitor of phosphodiesterase type III. Therefore, the inhibition of phosphodiesterase III by cGMP seems to be the mechanism for the elevation of cAMP levels by SIN-1 in the presence of low concentration of adenylate cyclase activators in human platelets.(ABSTRACT TRUNCATED AT 250 WORDS)

Inhibition of neuronal noradrenaline uptake (uptake1) and desipramine binding by N-ethylmaleimide (NEM).

The inhibition of N-ethylmaleimide (NEM) of uptake1 and desipramine binding was studied on clonal rat phaeochromocytoma cells (PC12 cells) in different experimental settings: (1) 3H-noradrenaline uptake into intact PC12 cells; (2) 3H-noradrenaline uptake into isolated PC12 plasma membrane vesicles; (3) 3H-desipramine binding to isolated PC12 plasma membrane vesicles. In plasma membrane vesicles, NEM inhibited 3H-desipramine binding and 3H-noradrenaline uptake with similar potency (the IC50's were 1.36 mmol/l and 1.04 mmol/l, respectively). However, in intact cells, NEM was about 75 times more potent in inhibiting 3H-noradrenaline uptake (IC50 = 0.014 mmol/l). The increased potency of NEM in intact cells is probably due to an inhibition of the Na+/K+-ATPase and not to a direct interaction with the noradrenaline carrier. The inactivation by NEM of 3H-desipramine binding to PC12 plasma membrane vesicles was irreversible. Both an inhibitor (cocaine, 1 mmol/l) and a substrate of uptake1 (amezinium, 1 mmol/l) protected desipramine binding from inactivation. These results are compatible with the hypothesis of a common binding site for substrates and inhibitors of the neuronal noradrenaline carrier.

Characterization of the [3H]-desipramine binding site of the bovine adrenomedullary plasma membrane.

The specific (i.e. nisoxetine-sensitive) binding of [3H]desipramine was studied in membranes prepared from bovine adrenal medullae. (1) [3H]desipramine bound reversibly and with high affinity (KD = 2.8 nmol/l) to a single class of non-interacting binding sites (Hill coefficient = 0.96); the maximal number of binding sites (Bmax) was 2.1 pmol/mg protein. (2) Binding of [3H]desipramine was dependent on [Na+] and [Cl-]. Increasing the concentrations of these ions increased binding. (3) Substrates and inhibitors of the neuronal noradrenaline transport system (uptake1) inhibited binding of [3H]desipramine with a rank order of potency typical for an interaction with the uptake1 carrier. The characteristics of [3H]desipramine binding remained essentially unchanged after solubilization of adrenomedullary membranes with the non-ionic detergent digitonin. The results indicate that the plasma membrane of bovine adreno-medullary cells is endowed with the neuronal uptake1 transporter.

Inhibition of neuronal noradrenaline transport (uptake1) and desipramine binding by amiloride and ethylisopropylamiloride.

The diuretic amiloride and its N-5 substituted analogue ethylisopropylamiloride (EIPA) inhibit both the specific high affinity desipramine binding to isolated plasma membranes of PC12 rat phaeochromocytoma cells and the carrier-mediated neuronal uptake of noradrenaline into PC12 cells. The inhibition by EIPA of both desipramine binding (Ki = 5.6 mumol/l) and noradrenaline uptake (Ki = 24 mumol/l) inversely depend on the extracellular sodium concentration. The degree of inhibition increased with decreasing sodium concentration. A more detailed analysis of the mode of interaction revealed a competitive interaction between EIPA and desipramine binding but an "uncompetitive" interaction between EIPA and noradrenaline uptake. EIPA is the first inhibitor of uptake1 known so far, which reduces both Km and Vmax of neuronal noradrenaline transport. Extracellular alkalinization from pH 7.4 to 7.9 during incubation with EIPA markedly increased the effects on the kinetics of noradrenaline transport. A model has been proposed to explain the kinetic phenomena. It is based on the hypothesis that EIPA diffuses through the plasma membrane and binds to the inward facing sodium binding site of the neuronal noradrenaline carrier.

Biochemical characterization and purification of the neuronal sodium-dependent noradrenaline transporter.

The protein properties of the neuronal sodium-dependent noradrenaline (NA) transporter of PC12 (rat pheochromocytoma) cells and of bovine adreno-medullary cells were studied by means of binding of 3H-desipramine (3H-DMI). 3H-DMI binding was decreased by proteases, phospholipase A2, by disulfide reducing agents and by the sulfhydryl-group alkylating agent N-ethylmaleimide. The NA transporter was partially purified by anion exchange and affinity chromatography. Tritiated desmethylxylamine (3H-DMX) bound irreversibly and in a DMI-sensitive manner to two PC12 membrane proteins (32kd and 53kd) which may represent components of the NA transporter.

Receptor binding properties of the new and specific thromboxane receptor antagonist Bay U 3405.

Human platelet membranes were used to characterize the receptor binding properties of the specific thromboxane receptor antagonist 3H-SQ 29548 and the displacement of 3H-SQ 29548 from its binding site by the new thromboxane receptor antagonist Bay u 3405. The specific binding of 3H-SQ 29548 was saturable with an association rate constant of 1 x 10(-11) mol-1 min-1 and a dissociation rate constant of 0.032 min-1. Nonspecific binding of 3H-SQ 29548 was below 10%. When Scatchard plot analysis was performed on equilibrium saturation binding the kD was 69 nmol/l and the Bmax was calculated as 3.9 pmol/mg membrane protein. 3H-SQ 29548 was dose dependently displaced from its binding site by addition of increasing concentrations of Bay u 3405 yielding an IC50 value of 68 +/- 12 nmol/l, being not significantly different from the IC50 of nonlabelled SQ 29548 (38 +/- 13 nmol/l). The results show that Bay u 3405 is a potent and specific thromboxane receptor antagonist, displacing 3H-SQ 29548 from its binding site on human platelet membranes with IC50 values being not significantly different. These receptor binding properties and the long biological half life reported in vivo make Bay u 3405 a promissing compound for the treatment of human cardiovascular diseases.