Rupert Gerzer

Purified soluble guanylyl cyclase expressed in a baculovirus/Sf9 system: stimulation by YC-1, nitric oxide, and carbon monoxide.

Abstract Soluble guanylyl cyclase (sGC) is the main receptor for nitric oxide, a messenger molecule with multiple clinical implications. Understanding the activation of sGC is an important step for establishing new therapeutic principles. We have now overexpressed sGC in a baculovirus/Sf9 system optimized for high protein yields to facilitate spectral and kinetic studies of the activation mechanisms of this enzyme. It was expressed in a batch fermenter using a defined mixture of viruses encoding the α1 and β1 subunits of the rat lung enzyme. The expressed enzyme was purified from the cytosolic fraction by anion exchange chromatography, hydroxyapatite chromatography, and size exclusion chromatography. By use of this new method 2.5 l culture yielded about 1 mg of apparently homogeneous sGC with a content of about one heme per heterodimer without the need of a heme reconstitution step. The enzyme did not contain stoichiometric amounts of copper. The basal activities of the purified enzyme were 153 and 1259 nmol min–1 mg–1 in the presence of Mg2+ and Mn2+, respectively. The nitric oxide releasing agent 2-(N,N-diethylamino)-diazenolate-2-oxide (DEA/NO) stimulated the enzyme 160-fold with Mg2+, whereas the NO-independent activator 3-(5’-hydroxymethyl-2’-furyl)-1- benzylindazole (YC-1) induced an increase in the activity of 101-fold at a concentration of 300 µM. The combination of DEA/NO (10 µM) and YC-1 (100 µM) elicited a dose-dependent synergistic stimulation with a maximum of a 792-fold increase over the basal activity in the presence of Mg2+, resulting in a specific activity of 121 µmol min–1 mg–1. The synergistic stimulation of DEA/NO and YC-1 was attenuated by the sGC inhibitor 1H-(1,2,4)oxadiazole(4,3-a)quinoxalin-1-one (ODQ) (10 µM) by 94%. In a different experimental setup a saturated carbon monoxide solution in the absence of ambient oxygen or NO stimulated the enzyme 15-fold in the absence and 1260-fold in the presence of YC-1 compared to an argon control. The heme spectra of the enzyme showed a shift of the Soret peak from 432 to 399 and 424 nm in the presence of DEA/NO or carbon monoxide, respectively. The heme spectra were not affected by YC-1 in the absence or in the presence of DEA/NO or of carbon monoxide, which reflects the fact that YC-1 does not interact directly with the heme group of the enzyme. In summary, this study shows that our expression/purification procedure is suitable for producing large amounts of highly pure sGC which contains one heme per heterodimer without a reconstitution step. The activator experiments show that in a synergistic stimulation with YC-1 sGC can be activated maximally both by nitric oxide and by carbon monoxide and that YC-1 does not directly act via heme. The described method should help to facilitate the investigation of the new therapeutic principle of NO-independent guanylyl cyclase activators.

The circulating bioactive form of human guanylin is a high molecular weight peptide (10.3 kDa)

Guanylin is a peptide isolated from rat intestine that stimulates intestinal guanylate cyclase. We describe here the purification of circulating guanylin from human hemofiltrate. By N‐terminal protein sequence analysis 47 amino acids were determined. This sequence corresponds to the positions 22 to 68 of the prohormone deduced from the cDNA sequence of human proguanylin. Mass spectral analysis of the circulating peptide showed the molecular weight to be 10,336 Da, which corresponds to the mass calculated from position 22 to the C‐terminus of the peptide predicted from the cDNA sequence. Circulating guanylin markedly increased the cyclic GMP content of T84 cells. Our data show that the hormonal form of guanylin is circulating as a 10.3‐kDa peptide in human blood.

Activation of soluble guanylate cyclase by arachidonic acid and 15-lipoxygenase products

The activity of soluble guanylate cyclase can be increased by exposure of the enzyme to arachidonic acid or to some oxidized metabolites of the fatty acid. We have tried to determine whether activation of the enzyme by arachidonate requires that the fatty acid be converted to an oxidized metabolite, either by a possible trace contaminant of a lipoxygenase or by guanylate cyclase itself, which contains a heme moiety. Soluble guanylate cyclase purified from bovine lung was activated 4-6-fold by arachidonic acid. This activation was not dependent on the presence of oxygen in the incubation medium. No detectable metabolites of arachidonic acid were formed during incubation with soluble guanylate cyclase. Addition of soybean lipoxygenase to the incubation did not increase activation by arachidonic acid. The inhibitors of lipoxygenase activity, nordihydroguaiaretic acid and eicosatetraynoic acid, had direct effects on soluble guanylate cyclase and interfered with its activation by arachidonate, whereas another lipoxygenase inhibitor, BW 755 C, did not. The data suggest that arachidonic acid increases the activity of guanylate cyclase by direct interaction with the enzyme rather than by being converted to an active metabolite.

Isolation and expression of a guanylate cyclase-coupled heat stable enterotoxin receptor cDNA from a human colonic cell line

Heat stable enterotoxins (STs) are low molecular-weight peptides secreted by enterotoxigenic bacteria. One type of these enterotoxins (STa) induces intestinal secretion leading to acute diarrhea by binding to a membrane form of guanylate cyclase. We have isolated a cDNA from a human colonic cell line, T84, encoding for a guanylate cyclase-coupled enterotoxin receptor (STaR). The predicted amino acid sequence of the human STa receptor is 81% identical with the previously cloned enterotoxin receptor (GC-C) from rat intestine. COS-7 cells transiently transfected with the cloned cDNA expressed specific concentration-dependent response to STa as measured by cyclic GMP accumulation and is about 20 times more sensitive to the stimulation by STa than has been shown for GC-C.

NO-independent regulatory site of direct sGC stimulators like YC-1 and BAY 41-2272

BackgroundThe most important receptor for nitic oxide is the soluble guanylate cyclase (sGC), a heme containing heterodimer. Recently, a pyrazolopyridine derivative BAY 41-2272, structurally related to YC-1, was identified stimulating soluble guanylate cyclase in an NO-independent manner, which results in vasodilatation and antiplatelet activity. The study described here addresses the identification of the NO-independent site on soluble guanylate cyclase.ResultsWe developed a photoaffinity label (3H-meta-PAL) for the direct and NO-independent soluble guanylate cyclase (sGC) stimulator BAY 41-2272 by introducing an azido-group into the tritium labeled compound. The synthesized photoaffinitylabel directly stimulates the purified sGC and shows in combination with NO a synergistic effect on sGC activity. Irradiation with UV light of 3H-meta-PAL together with the highly purified sGC leads to a covalent binding to the α1-subunit of the enzyme. This binding is blocked by unlabeled meta-PAL, YC-1 and BAY 41-2272. For further identification of the NO-independent regulatory site the 3H-meta-PAL labeled sGC was fragmented by CNBr digest. The 3H-meta-PAL binds to a CNBr fragment, consisting of the amino acids 236–290 of the α1-subunit. Determination of radioactivity of the single PTH-cycles from the sequencing of this CNBr fragment detected the cysteines 238 and 243 as binding residues of the 3H-meta-PAL.ConclusionsOur data demonstrate that the region surrounding the cysteines 238 and 243 in the α1-subunit of the sGC could play an important role in regulation of sGC activity and could be the target of this new type of sGC stimulators.

Effects of nitric oxide on the adhesion of human melanocytes to extracellular matrix components

The aim of the present study was to explore whether nitric oxide (NO) interferes with the attachment of human melanocytes to the extracellular matrix (ECM) components. Consequently, the effects have been investigated of the NO‐releasing compounds 3‐morpholino‐sydnonimine (SIN‐1) and S‐nitroso‐glutathione (GSNO) on the in vitro adhesion of human melanocytic cells to fibronectin. The NO donors induced a concentration‐dependent reduction in the adhesion of both 51CrO42−‐labelled melanocytes and melanoma cells to fibronectin. Pigmented M14 melanoma cells were more susceptible to the effect of SIN‐1 (half‐maximal inhibiting effect at about 0·5 mm) than normal human melanocytes and also than the non‐pigmented melanoma cells Mel57 (half‐maximal inhibiting effects between 0·9 and 2 mm). This effect of SIN‐1 also appeared to be related to the melanin content of normal melanocytes, whereas GSNO was significantly less active. Both flow cytometric analysis and immunocytochemical staining showed expression of neuronal NO synthase in all cell lines. The results of this study suggest that aberrant in vivo production of NO during infection and inflammation may contribute to loss of melanocytes in, for example, vitiligo, by reducing de novo attachment of melanocytes to the ECM. These findings could also be important for understanding the process of metastasis.

Soluble Guanylyl Cyclase and Platelet Functiona

Soluble guanylyl cyclase is abundantly present in platelets. This heterodimeric heme-protein is activated by nitric oxide (NO) and is involved in the inhibitory action of NO on platelet function. NO interferes with early steps of platelet activation involving calcium mobilization and inhibits both adhesion and aggregation. NO is formed endogenously from endothelium and a variety of other cell types. The nitrovasodilators, commonly used for the treatment of angina pectoris, also act through the release of NO. The release of NO from these drugs is enzyme coupled, and only a little NO is released from these drugs spontaneously. Platelets do not contain the enzyme system(s) that releases NO from organic nitrates. These drugs can therefore only weakly activate platelet-soluble guanylyl cyclase and inhibit platelet activation in vitro. However, NO is released from these drugs in the vessels and can reach the platelets close to the vessel wall in vivo. Therefore, many effects of these drugs in the primary or secondary prevention of myocardial infarction might come from their antiplatelet action rather than from their ability to dilate vessels. Knowledge of the mechanisms by which soluble guanylyl cyclase is activated has contributed considerably to our understanding of the mechanisms of regulation of platelet function and has presented us with new therapeutic possibilities.

Effects of nitric oxide-containing compounds on increases in cytosolic ionized Ca2+ and on aggregation of human platelets.

The present study was undertaken to determine the modulatory effects of nitric oxide (NO)-releasing compounds on increases in cytosolic ionized calcium ([Ca2+]i) and on aggregation of gel-filtered human platelets induced via diverse agonists. We used various sydnonimines and organic nitrates as donors of NO. Gel-filtered and fura-2-loaded platelets were stimulated with ADP (4-8 microM), collagen (2-10 micrograms/ml) or thrombin (0.02-0.05 IU/ml), respectively. Half-maximal inhibiting effects of sydnonimines on agonist-evoked increases in [Ca2+]i were observed between 30 and 1000 nM, while half-maximal inhibiting effects of the compounds on aggregation were between 3 and 500 nM. The compound C 87-3754, which is the bioactive metabolite of pirsidomine, was a much stronger inhibitor of increases in [Ca2+]i than of platelet aggregation. This was due to an enhanced NO release from this compound exposed to ultraviolet light during Ca2+ measurement. The organic nitrates isosorbide 5-mono-nitrate and nicorandil inhibited both aggregation and increase of cytosolic ionized calcium in stimulated platelets at half-maximal concentrations of approximately 200 microM. The present results suggest that some of the effects of NO on platelets are independent of cytosolic ionized calcium. The results also suggest that some of the inhibitory effects of NO-releasing compounds correspond rather to the presence of the A forms (NO-containing intermediates) than to the presence of free NO.

The separation of the heme and apoheme forms of soluble guanylate cyclase

Abstract Two forms of soluble quanylate cyclase from mammalian tissues can be separated on DEAE Sephacel or Blue Sepharose CL-6B. The two forms, referred to as peak I or peak II, migrate identically during electrophoresis on polyacrylamide gels in the presence or absence of Na-dodecyl-SO4. Peak I is markedly stimulated by sodium nitroprusside and is the heme-containing form of guanylate cyclase. Peak II is only weakly stimulated by nitroprusside and contains no heme absorbance. In fresh tissue extracts, peak I is the predominant form, but it can be converted to peak II by treatments (pH 5.0, storage at 4°C) that result in the loss of the heme absorbance from the enzyme. Peak II is not formed from peak I by proteolysis.

Urodilatin and β-ANF: Binding properties and activation of particulate guanylate cyclase

Urodilatin (ANF-(95-126] and beta-ANF, the antiparallel dimer of ANF-(99-126), are naturally occurring members of the ANF family. We studied their receptor binding properties in human platelets and Triton-solubilized membranes from bovine adrenal cortex and their ability to activate particulate guanylate cyclase in bovine adrenal cortex. In human platelets containing R2-receptors not coupled to particulate guanylate cyclase urodilatin binds with similar affinity as ANF-(99-126) (KD: 55 pM), whereas beta-ANF has an affinity lower than the truncated ANF-(103-123) (KD: 295 pM and 154 pM). Scatchard analysis indicates one binding site for urodilatin as well as for beta-ANF. In adrenal cortex containing predominantly R1-receptors coupled to particulate guanylate cyclase, urodilatin binds with a higher affinity (KD: 30 pM) than ANF-(99-126) (KD: 52 pM) and stimulates to a similar extent to ANF-(99-126) (about two fold at 1 muM), whereas beta-ANF has a smaller affinity (KD: 120 pM) and stimulates particulate guanylate cyclase to a lower extent than ANF-(99-126). The data from platelets and adrenal cortex show that beta-ANF has low binding affinities but stimulates particulate guanylate cyclase, whereas urodilatin appears to be a physiological R1-agonist.