Atrial natriuretic peptide receptors in sympathetic ganglia: biochemical response and alterations in genetically hypertensive rats

High concentration of atrial natriuretic peptide (99-126) (ANP) receptors were localized by quantitative autoradiography in superior cervical and stellate ganglia from young and adult Wistar Kyoto (WKY) rats. ANP increased cyclic GMP formation in stellate ganglia from adult rats. Both young and adult spontaneously hypertensive rats (SHR) had a much lower number of ANP receptors in the sympathetic ganglia. In spite of low receptor concentration, the cyclic GMP response to ANP in SHR was unchanged. These results suggest the existence of physiologically active ANP receptors in the rat sympathetic ganglia. These receptors may also be involved in the pathophysiology of spontaneous hypertension.     

Formation of guanosine 3′,5′-cyclic monophosphate by thyroliberlin in cultured rat pituitary cells a possible role in stimulation of prolactin synthesis

In a clonal strain of rat pituitary tumour cells (GH₄C₁ cells), thyroliberin stimulated prolactin secretion and synthesis: effects that could be demonstrated after 5 min and 4–5 h of treatment, respectively. Within 0.5–5 min after addition of thyroliberin, maximal increases (2–4 hold) in cellular cyclic GMP concentrations were observed, and this rise preceded or occurred simultaneously with that of cyclic AMP. After 60 min of treatment the concentrations of the cyclic nucleotides had returned to control values. Half maximal and maximal stimulation of cyclic GMP elevations were obtained with approx. 2·10⁹ and approx. 27·10^?9 thyroliberin, respectively. Aminophylline increased both cyclic GMP and cyclic AMP, and potentiated the stimulatory effects of thyroliberin on both cyclic nucleotides. The dibutyryl derivative of cyclic GMP (10^?4–10^?6 M) stimulated prolactin synthesis, but not hormone release. Prostaglandin E₂ (3·10^?7 M) stimulated cellular cyclic AMP concentrations, but did not affect cyclic GMP levels. We conclude that thyroliberin in the GH₄C₁ ccell strain stimulates cyclic GMP formation, in addition to elevate cyclic AMP concentrations. The stimulatory effect on cyclic GMP is probably not secondary to the rise in cyclic AMP concentration, since prostaglandin E₂ elevates only cyclic GMP is involved in the action of thyroliberin on prolactin, the present results suggest a role on hormone synthesis.     

REGULATION OF GUANOSINE 3'',5'' CYCLIC MONOPHOSPHATE IN THE RAT PINEAL AND POSTERIOR PITUITARY GLANDS

Potassium and norepinephrine stimulate the accumulation of cyclic AMP and cyclic GMP in rat pineal glands and their efflux into the medium. The efflux of both cyclic nucleotides was blocked by probenecid. The accumulation and efflux of cyclic GMP, but not of cyclic AMP, depends upon the presence of intact nerve endings and extracellular calcium. The calcium-dependent release of norepinephrine caused by veratridine was accompanied by the efflux of both cyclic AMP and cyclic GMP. In contrast, the calcium-independent release of norepinephrine caused by tyramine was accompanied by the efflux of cyclic AMP but not cyclic GMP. Changes in cyclic GMP therefore, may be related to exocytosis from the sympathetic nerve endings in the gland. High concentrations of potassium also increased tissue levels of cyclic GMP in the posterior pituitary gland. Veratridine and potassium, but not norepinephrine, stimulated the efflux of cyclic GMP from this neurosecretory gland. Thus, the relationship between cyclic GMP and exocytosis may extend beyond sympathetic nerve endings. The enhanced accumulation of cyclic GMP in the pineal gland after potassium does not appear to be mediated by extracellular (released) norepinephrine. Desmethylimipramine blocked the norepinephrine-stimulated changes in cyclic GMP, but not those caused by potassium. Investigation of the possible relationship between cyclic GMP and release of neurotransmitters is complicated by the apparent seasonal variation in the response of pineal cyclic GMP to potassium or norepinephrine.     

The G-protein–gated K+ channel,IKACh, is required for regulation of pacemaker activity and recovery of resting heart rate after sympathetic stimulation

Parasympathetic regulation of sinoatrial node (SAN) pacemaker activity modulates multiple ion channels to temper heart rate. The functional role of the G-protein–activated K⁺ current (I_KACh) in the control of SAN pacemaking and heart rate is not completely understood. We have investigated the functional consequences of loss of I_KACh in cholinergic regulation of pacemaker activity of SAN cells and in heart rate control under physiological situations mimicking the fight or flight response. We used knockout mice with loss of function of the Girk4 (Kir3.4) gene (Girk4^−/− mice), which codes for an integral subunit of the cardiac I_KACh channel. SAN pacemaker cells from Girk4^−/− mice completely lacked I_KACh. Loss of I_KACh strongly reduced cholinergic regulation of pacemaker activity of SAN cells and isolated intact hearts. Telemetric recordings of electrocardiograms of freely moving mice showed that heart rate measured over a 24-h recording period was moderately increased (10%) in Girk4^−/− animals. Although the relative extent of heart rate regulation of Girk4^−/− mice was similar to that of wild-type animals, recovery of resting heart rate after stress, physical exercise, or pharmacological β-adrenergic stimulation of SAN pacemaking was significantly delayed in Girk4^−/− animals. We conclude that I_KACh plays a critical role in the kinetics of heart rate recovery to resting levels after sympathetic stimulation or after direct β-adrenergic stimulation of pacemaker activity. Our study thus uncovers a novel role for I_KACh in SAN physiology and heart rate regulation.     

Amylase secretion by rabbit parotid gland role of cyclic AMP and cyclic GMP

Amylase secretion and changes in the levels of cyclic AMP and GMP were studied in rabbit parotid gland slices incubated in vitro with a variety of neurohumoral transmitters, their analogs and inhibitors. Cyclic GMP levels increased 8-fold 5 min after exposure to carbachol (10⁻⁴ M), without a change in cyclic AMP levels; amylase output also rose. These effects were completely inhibited by muscarinic blockade with atropine, but were unaffected by α-adrenergic blockade with phenoxybenzamine. Epinephrine (4 · 10⁻⁵ M) produced a rapid increase in the levels of both cyclic nucleotides and in amylase release. The increase in cyclic GMP level was inhibited by previous exposure of the slices to phenoxybenzamine, while the cyclic AMP rise was prevented by the β-blocking agent, propranolol. Pure α-adrenergic stimulation with methoxamine (4 · 10⁻⁴ M) produced modest elevations in cyclic GMP content and amylase output, effects blocked by pre-treatment of slices with either atropine or phenoxybenzamine. At a concentration of 4 · 10^{−6 M}, isoproterenol (a β-agonist) failed to affect cyclic GMP levels, but promptly stimulated increases in cyclic AMP levels, and after a short lag, amylase secretion. At a higher dose (4 · 10⁻⁵ M) isoproterenol produced elevations in the levels of both nucleotides. The carbachol-induced effects on cylcic GMP content and amylase release were greatly potentiated by the addition of isoproterenol (4 · 10⁻⁶ M).These data strongly suggest that cholinergic muscarinic agonists and α-adrenergic agonist stimulate amylase output in rabbit parotid gland by mechanisms involving cyclic GMP. The atropine-sensitive intracellular events effected by α-stimulation may be dependent upon endogenous generation of acetylcholine. Both cyclic nucleotides seem to be required for the early rapid secretion of amylase. The unique responses achieved by the combination of carbachol and isoproterenol suggest that isoproterenol may increase the sensitivity of this issue to the effects of cholinergic stimuli.     

Signal transduction and motility ofDictyostelium

This review is concerned with the roles of cyclic GMP and Ca²⁺ ions in signal transduction for chemotaxis ofDictyostelium. These molecules are involved in signalling between the cell surface cyclic AMP receptors and cytoskeletal myosin II involved in chemotactic cell movement. Evidence is presented for uptake and/or eflux of Ca²⁺ being regulated by cyclic GMP. The link between Ca²⁺, cyclic GMP and chemotactic cell movement has been explored using streamer F mutants whose primary defect is in the structural gene for the cyclic GMP-specific phosphodiesterase. This mutation causes the mutants to produce an abnormally prolonged peak of cyclic GMP accumulation in response to stimulation with the chemoattractant cyclic AMP. The production and relay of cyclic AMP signals is normal in these mutants, but certain events associated with movement are (like the cyclic GMP response) abnormally prolonged in the mutants. These events include Ca²⁺ uptake, myosin II association with the cytoskeleton and regulation of both myosin heavy and light chain phosphorylation. These changes can be correlated with changes in the shape of the amoebae after chemotactic stimulation. Other mutants in which the accumulation of cyclic GMP in response to cyclic AMP stimulation was absent produced no myosin II responses.A model is described in which cyclic GMP (directly or indirectly via Ca²⁺) regulates accumulation of myosin II on the cytoskeleton by regulating phosphorylation of the myosin heavy and light chain kinases.     

REGULATION OF CYCLIC NUCLEOTIDE PHOSPHODIESTERASES OF CEREBRAL CORTEX BY Ca2+ AND CYCLIC GMP

Cyclic nucleotide phosphodiesterase activity of porcine cerebral cortical extracts was measured with 0.1–100 μM-cyclic AMP and cyclic GMP and found to be dependent on both Ca²⁺ and added cyclic nucleotides. With decreasing substrate concentration activity with cyclic GMP became more dependent on Ca²⁺ whereas hydrolysis of cyclic AMP became less dependent. Cyclic GMP at 3 μM stimulated the hydrolysis of 0.1–10μM-cyclic AMP in the absence of Ca²⁺ (< 10^-10M) but inhibited activity with 200 μM-Ca²⁺ present. This differential, substrate- and Ca²⁺-dependent regulation was attributed to the presence of at least two types of phosphodiesterase distinguishable by DEAE-column chromatography. In the absence of Ca²⁺, activity with 1 μM-cyclic GMP eluted in one minor peak followed by two major peaks, D-I and D-II. Activity with 1 μM-cyclic AMP eluted almost entirely in D-II. Hydrolysis of cyclic AMP in D-II was activated by cyclic GMP. With added Ca²⁺ plus a Ca²⁺-dependent regulator (CDR), activity with 1 μM-cyclic GMP was markedly increased and eluted entirely at D-I. Total activity with 1 μM-cyclic AMP was only moderately increased and eluted as D-I with a shoulder at D-II. Elution profiles with 100 μM-substrate were relatively independent of substrate, with D-I predominant with Ca²⁺·CDR present and D-II predominant in its absence. Kinetic analysis of rechromatographed D-I showed a 20- to 40-fold activation by Ca²⁺·CDR that was largely due to an increase in V_max, with only 50% decreases in K_m Both substrates competitively inhibited hydrolysis of the other with K_i values equal to their respective K_m values (1.7 μM for cyclic GMP and 48 μM for cyclic AMP with Ca²⁺-CDR present). Studies with theophylline and trifluoperazine indicate differential, substrate-dependent inhibitions of both enzymes. These findings demonstrate that phosphodiesterase activity in neural tissue is subject to regulation by Ca²⁺, cyclic GMP, and inhibitors in a complex, substrate-specific and concentration-dependent manner.     

Cyclic GMP stimulation and inhibition of cyclic AMP phosphodiesterase from thymic lymphocytes

A particulate preparation of cyclic AMP phosphodiesterase from rat thymic lymphocytes exhibited two apparent Km's at 0.9×10⁻⁶M and 8.0×10⁻⁶M. The enzyme with the higher Km was stimulated by cyclic GMP by a mechanism involving an increase in the Vmax of the enzyme with no change in the Km. Cyclic GMP competitively inhibited the enzyme with the low apparent Km which had a Ki for cyclic GMP of 4×10⁻⁵M. The modulation of cyclic AMP phosphodiesterase activity by cyclic GMP in the control of cyclic AMP-mediated lymphocyte proliferation is discussed.     

Contribution of lipoxygenase and cyclooxygenase metabolites in the modulation of cyclic nucleotides in the guinea pig mymotrium. Differential effects of carbachol and ionophore A23187

Accumulation of cyclic GMP in estradiol-treated immature guinea pig myometrium was enhanced by carbachol, ionophore A₂₃₁₈₆, unsaturated fatty acids and their hydroperoxides. Cyclic AMP content was elevated only by arachiodonic acid, A₂₃₁₈₇ and PGI₂. Eicosatetraynoic acid (TYA), but not indomethacin prevented all cyclic GMP responses. The effects of A₂₃₁₈₇ and arachidonate on cyclic AMP were accompanied by a parallel increase (2–3 fold) on the generation of PGI₂ by the myometrium. Both events were similarly reduced by indomethacin, TYA, 15-hydroperoxyarachidonic acid and tranylcypromine, suggesting that PGI₂ was involved. Omission of Ca²⁺ or addition of mepacrine of p-bromophenacylbromide abolished the stimulatory effects of A₂₃₁₈₇ and carbachol on cyclic GMP as well as the A₂₃₁₈₇-induced elevations in both PGI₂ and cyclic AMP generation. Thus, with both exogenous arachidonate as well as with endogenous fatty acid, released through an apparent phospholipase A₂-induced activation process, the lipoxygenase pathway was associated with an activation of the cyclic GMP system and the cyclooxygenase pathway, via PGI₂ generation, with an activation of the cyclic AMP system. Carbachol failed to alter both cyclic AMP content and the release of PGI₂ suggesting a cholinergic receptor-mediated fatty acid release process, selectively coupled to the lipoxygenase route.     

Ca2+ - and Nitric Oxide-Dependent Stimulation of Cyclic GMP Synthesis in Neuronal Cell Line Induced by P2-Purinergic/Pyrimidinergic Receptor

Abstract: The mechanism by which cyclic GMP synthesis is activated through a nucleotide receptor was studied in mouse neuroblastoma × rat glioma hybrid cells [108CC15 (NG 108-15)]. The transient increase in cyclic GMP level induced by ATP reached its maximum at 20 s and lasted for ～1 min. The maximal rise in cyclic GMP level achieved was highest for ATP and decreased in the following order: ATP = adenosine 5′-(γ-thio)triphosphate > UTP = 2-methylthio-ATP > ADP ? CTP, AMP, α,β-methylene-ATP, 2′- and 3′-O-(4-benzoylbenzoyl)ATP. The EC₅₀ of 1 ± 0.2 µM for UTP was significantly lower than that for ATP (14 ± 8 µM) and for all the other nucleotides tested. The rank order of potency is consistent with the pharmacology of a P_2u receptor. At submaximal concentrations of the nucleotides ATP and UTP, the rise in cyclic GMP level was inhibited by suramin (IC₅₀ = 40–60 µM) or the pyridoxal phosphate analogue pyridoxal phosphate-6-azophenyl-2′,4′-disulfonic acid (IC₅₀ = 20–30 µM). Pretreatment of cells with the Ca²⁺ ionophore ionomycin or with 2,5-di(tert-butyl)-1,4-benzohydroquinone, an inhibitor of Ca²⁺-ATPase in the endoplasmic reticulum, a maneuver to deplete internal Ca²⁺ stores, suppressed the ATP- or UTP-induced stimulation of cyclic GMP synthesis. Similarly, loading of the cells with the Ca²⁺ chelator 1,2-bis(2-aminophenoxy)ethane-N,N,N′,N′-tetraacetic acid inhibited cyclic GMP formation by ATP. Preincubation with forskolin to raise the cyclic AMP level potentiated the ATP-induced rise in cyclic GMP level by 60%. The cyclic GMP response caused by ATP was suppressed either by arginine analogues (IC₅₀ for nitroarginine = 1 µM) or by hemoglobin (IC₅₀ = 2 µM). This indicates that ATP/UTP via a P₂-receptor causes formation of nitric oxide, which activates guanylate cyclase. The synthesis of nitric oxide depends on a preceding rise in cytosolic Ca²⁺ level, mostly due to release of Ca²⁺ from internal stores. Bradykinin induces a rise in cyclic GMP level with an amplitude and time course comparable to that caused by ATP. Therefore, we studied cross-desensitization between ATP and bradykinin receptors. Pretreatment with bradykinin completely suppressed a subsequent response to ATP. However, stimulation with ATP reduced a following response to bradykinin by ～40% only. This indicates a heterologous cross-desensitization predominantly in one direction (bradykinin ? ATP).     

Ethanol inhibition of antigen-induced histamine release from guinea pig lung: correlation with intracellular levels of cyclic nucleotides.

The effect of ethanol on histamine release from lungs of sensitized guinea pigs was studied in conjunction with measurements of tissue concentrations of cyclic AMP and cyclic GMP. Addition of antigen $\text{in vitro}$ elicited a rapid increase in cyclic AMP and cyclic GMP and stimulated release of histamine. Ethanol (2%) inhibited antigen-induced release of histamine over 95% and completely inhibited the increase in both cyclic nucleotides. The activity of cyclic AMP-dependent protein kinase was only slightly affected by ethanol.Metiamide blocked the ovalbumin stimulated increase in cyclic AMP but not cyclic GMP. Pyrilamine did not prevent the rise in either cyclic nucleotide. This suggests that the antigen-induced rise in cyclic AMP is an indirect result of histamine released from the tissue. The inability of H₁ and H₂ receptor antagonists to affect antigen-induced elevation of cyclic GMP in sensitized lung fragments suggests that an elevation in cyclic GMP might be either a primary event in the mediator release sequence or secondary to the release of a mediator other than histamine. The ability of ethanol to inhibit mediator release might be due to its capacity to attenuate the antigen-induced elevation of cyclic GMP in sensitized lung.     

Importance of Gradients in Membrane Properties and Electrical Coupling in Sinoatrial Node Pacing

The sinoatrial node (SAN) is heterogeneous in terms of cell size, ion channels, current densities, connexins and electrical coupling. For example, Na_v1.5 (responsible for I _Na) and Cx43 (responsible for electrical coupling) are absent from the centre of the SAN (normally the leading pacemaker site), but present in the periphery (at SAN-atrial muscle junction). To test whether the heterogeneity is important for the functioning of the SAN, one- and two-dimensional models of the SAN and surrounding atrial muscle were created. Normal functioning of the SAN (in terms of cycle length, position of leading pacemaker site, conduction times, activation and repolarization sequences and space constants) was observed when, from the centre to the periphery, (i) cell characteristics (cell size and ionic current densities) were changed in a gradient fashion from a central-type (lacking I _Na) to a peripheral-type (possessing I _Na) and (ii) coupling conductance was increased in a gradient fashion. We conclude that the heterogeneous nature of the node is important for its normal functioning. The presence of Na_v1.5 and Cx43 in the periphery may be essential for the node to be able to drive the atrial muscle: Na_v1.5 provides the necessary depolarizing current and Cx43 delivers it to the atrial muscle.     

Stimulatory effect of dibutyryl cyclic GMP on acid secretion in mouse isolated stomach and on histamine release in gastric mucosal cells.

We previously reported that endogenous nitric oxide (NO) is involved in the peripheral control of gastric acid secretion induced by some secretagogues, and that endogenous NO is involved in the acid secretion process via histamine release from histamine-containing cells. However, the stimulus-secretion coupling in the cells remains to be clarified. In the present study, we investigated the effect of dibutyryl cyclic GMP on gastric acid secretion in mouse isolated stomach and on histamine release in gastric mucosal cells, in comparison with those of dibutyryl cyclic AMP. Dibutyryl cyclic GMP (300 microM) produced a slight but significant increase of gastric acid secretion, which was completely inhibited by the histamine-H2 receptor antagonist famotidine. In contrast, dibutyryl cyclic GMP (1 mM) markedly inhibited histamine-induced acid secretion. Dibutyryl cyclic AMP (100 microM) produced a sustained increase of gastric acid secretion. The pretreatment with famotidine partially inhibited dibutyryl cyclic AMP-induced gastric acid secretion. Dibutyryl cyclic GMP and dibutyryl cyclic AMP significantly increased the histamine release from gastric mucosal cells. These results suggest that both intracellular cyclic GMP and cyclic AMP act as second messengers for histamine release in the histamine-containing cells, probably ECL cells. On the other hand, in gastric parietal cells, cyclic AMP has a stimulatory effect on gastric acid secretion, whereas cyclic GMP has an inhibitory effect.     

INFLUENCE OF DIVALENT CATIONS ON REGULATION OF CYCLIC GMP AND CYCLIC AMP LEVELS IN BRAIN TISSUE

—Depolarizing concentrations of K⁺ elevate levels of both adenosine 3′,5′monophosphate (cyclic AMP) and guanosine 3′,5′monophosphate (cyclic GMP) in incubated slices of mouse cerebellum. Calcium is an essential requirement for the K⁺ -induced accumulation of cyclic GMP. Barium and Sr²⁺, but not Mn²⁺ or Co²⁺, can substitute for Ca²⁺ in this process. Relatively high concentrations of Mg²⁺ inhibit the effect of Ca²⁺ on K⁺-induced accumulation of cyclic GMP. In contrast, depolarizing concentrations of K⁺ are capable of elevating cyclic AMP levels in brain slices suspended in media containing Mg²⁺ and no other divalent cations. High concentrations of Ca²⁺ (1 mm or greater) augment this Mg²⁺ -dependent, K⁺-induced accumulation of cyclic AMP, however. Strontium and Mn²⁺, but not Ba²⁺ or Co²⁺, can substitute for Ca²⁺ in this process, and high concentrations of Mg²⁺ are not inhibitory. The divalent cation ionophore, A-23187 (10 μm ), in the presence of extracellular Ca²⁺ elevates the level of cyclic GMP, but not cyclic AMP, in incubated mouse cerebellum slices. The results of this study indicate that intracellular Ca²⁺ concentration is a major factor regulating cyclic GMP levels in brain. In addition the present results suggest that, in brain tissue, depolarization-induced accumulation of cyclic GMP, but not cyclic AMP, is closely linked to some Ca²⁺-dependent mechanism(s) mediating release of intracellular substances.     

Hyperpolarization-activated cyclic nucleotide-gated channel 1 is a molecular determinant of the cardiac pacemaker current I(f)

The pacemaker current I(f) of the sinoatrial node (SAN) is a major determinant of cardiac diastolic depolarization and plays a key role in controlling heart rate and its modulation by neurotransmitters. Substantial expression of two different mRNAs (HCN4, HCN1) of the family of pacemaker channels (HCN) is found in rabbit SAN, suggesting that the native channels may be formed by different isoforms. Here we report the cloning and heterologous expression of HCN1 from rabbit SAN and its specific localization in pacemaker myocytes. rbHCN1 is an 822-amino acid protein that, in human embryonic kidney 293 cells, displayed electrophysiological properties similar to those of I(f), suggesting that HCN1 can form a pacemaker channel. The presence of HCN1 in the SAN myocytes but not in nearby heart regions, and the electrophysiological properties of the channels formed by it, suggest that HCN1 plays a central and specific role in the formation of SAN pacemaker currents.     

Presynaptic Modulation of K+-Evoked [3H]Dopamine Release in Striatal and Frontal Cortical Synaptosomes of Normotensive and Spontaneous-Hypertensive Rats

Regional differences in presynaptic [³H]dopamine ([³H]DA) release and its modulation by D₂ DA-receptors between the frontal cortex and striatum obtained from Wystar-Kyoto (WKY) and spontaneous-hypertensive rats (SHR) have been evaluated using superfused synaptosomes. Synaptosomal tritium content was significantly lower in the frontal cortex than in the striatum in both SHR and WKY (45% and 48%, respectively), but no differences in tritium content were obtained between strains. However, the 15 mM K⁺-evoked [³H]DA overflow was lower in the SHR as compared to WKY rats in both brain regions (striatum 23%, frontal cortex 21). Concentration-response curves for quinpirole (1nM-10 M)-mediated inhibition of 15mM K⁺-evoked [³H]DA release showed no differences between SHR and WKY. These results suggest that SHR has less ability to release [³H]DA as compared to WKY rats, but SHR did not show differences in the autoregulation of such release in both the frontal cortex and striatum.     

Electric field stimulation releases norepinephrine and cyclic GMP from the rat pineal gland.

Electrical field stimulation caused the release of preloaded ³H-norepinephrine and of cyclic GMP from the rat pineal gland. Increased release of catecholamines and of cyclic nucleotide occurred at low frequency and current, and was largely dependent on the presence of intact nerve endings and extracellular calcium. Presynaptic synthesis and release of cyclic GMP appears to accompany the exocytotic release of neurotransmitter.     

Modulation of platelet responsiveness through selective phosphorylation of plasma membrane proteins: Antagonistic eeffects of cyclic AMP and cyclic GMP

³²P phosphorylation of plasma membranes from human blood platelets, under conditions that closely resemble physiological ones (endogeneous phosphate donors and intact platelets in homologous plasma), result in the incorporation of the label mainly in a membrane glycoprotein of apparently high molecular weight (greater than 400 000). Dibutyryl cyclic AMP, an inhibitor of platelet aggregation, specifically increases the degree of phosphorylation of this glycoprotein. Moreover, it has been found that prostaglandin E₁ one of the most potent inhibitors of platelet aggregation which also increases phosphorylation of the same glycoprotein, is significantly more effective than cyclic AMP.Cyclic GMP does not have any apparent effect on platelet aggregation. However, incubation of platelet-rich plasma with both cyclic GMP and cyclic AMP results in a partial recovery of the platelet responsiveness towards ADP-induced aggregation. Coincidently, the degree of phosphorylation of the high molecular weight glycoprotein under these conditions, although still higher than in controls (no nucleotides added), is significantly decreased as compared with cyclic AMP-treated cells. Furthermore, cyclic GMP inhibits the cyclic AMP-dependent protein kinase activity in isolated platelet plasma membranes.These results suggest a central role for this membrane phosphoglycoprotein in the triggering of platelet aggregation and, furthermore, suggest that modulation of its degree of phosphorylation may be exerted through some cyclic AMP/cyclic GMP relationship, which in the basal state might be critical for platelet responsiveness.     

Involvement of L-Type-Like Amino Acid Transporters in S-Nitrosocysteine-Stimulated Noradrenaline Release in the Rat Hippocampus

Abstract: Nitrogen oxides, such as nitric oxide, have been shown to regulate neuronal functions, including neurotransmitter release. We investigated the effect of S-nitroso-l -cysteine (SNC) on noradrenaline (NA) release in the rat hippocampus in vivo and in vitro. SNC stimulated [³H]NA release from prelabeled hippocampal slices in a dose-dependent manner. SNC stimulated endogenous NA release within 30 min to almost five times the basal level in vivo (microdialysis in freely moving rats). In a Na⁺-containing Tyrode's buffer, SNC-stimulated [³H]NA release was inhibited 30% by the coaddition of l -leucine. In the Na⁺-free, choline-containing buffer, SNC-stimulated [³H]NA release, which was similar to that in the Na⁺-containing buffer, was inhibited markedly by l -leucine, l -alanine, l -methionine, l -phenylalanine, and l -tyrosine. The effects of the other amino acids examined were smaller or very limited. The effect of l -leucine was stronger than that of d -leucine. A specific inhibitor of the L-type amino acid transporter, 2-aminobicyclo[2.2.1]-heptane-2-carboxylate (BCH), inhibited the effects of SNC on [³H]NA release in the Na⁺-free buffer. Uptake of l -[³H]leucine into the slices in the Na⁺-free buffer was inhibited by SNC, BCH, and l -phenylalanine, but not by l -lysine. The effect of SNC on cyclic GMP accumulation was not inhibited by l -leucine, although SNC stimulated cyclic GMP accumulation at concentrations up to 25 µM, much less than the concentration that stimulates NA release. These findings suggest that SNC is incorporated into rat hippocampus via the L-type-like amino acid transporter, at least in Na⁺-free conditions, and that SNC stimulates NA release in vivo and in vitro in a cyclic GMP-independent manner.