S-Nitrosothiols as potential therapeutics to induce a mobilizable vascular store of nitric oxide to counteract endothelial dysfunction.

Endothelial dysfunction predisposing to cardiovascular diseases is defined as an imbalance in the production of vasodilating factors, such as nitric oxide (NO), and vasoconstrictive factors. To insure its physiological role, NO, a radical with very short half-life, requires to be stored and transported to its action site. S-nitrosothiols (RSNOs) like S-nitrosoglutathione (GSNO) represent the main form of NO storage within the vasculature. The NO store formed by RSNOs is still bioavailable to trigger vasorelaxation. In this way, RSNOs are an emerging class of NO donors with a potential to restore NO bioavailability within cardiovascular disorders. The aim of this study was to compare S-nitrosothiols ability, formed of peptide (glutathione) like the physiologic GSNO or derived from amino acids (cysteine, valine) like the synthetics S-nitroso-N-acetylcysteine (NACNO) and S-nitroso-N-acetylpenicillamine (SNAP), respectively, to produce a vascular store of NO either in endothelium-intact or endothelium-removed aortae in order to evaluate whether RSNOs can be used as therapeutics to compensate endothelial dysfunction. Sodium nitroprusside (SNP), a marketed drug already in clinics, was used as a non-RSNO NO-donor. Endothelium-intact or endothelium-removed aortae, isolated from normotensive Wistar rats, were exposed to RSNOs or SNP. Then, NO-derived (NOx) species, representing the NO store inside the vascular wall, were quantified using the diaminonaphthalene probe coupled to mercuric ions. The bioavailability of the NO store and its ability to induce vasodilation was tested using N-acetylcysteine, then its ability to counteract vasoconstriction was challenged using phenylephrine (PHE). All the studied RSNOs were able to generate a NO store materialized by a three to five times increase in NOx species inside aortae. NACNO was the most potent RSNO to produce a vascular NO store bioavailable for vasorelaxation and the most efficient to induce vascular hyporeactivity to PHE in endothelium-removed aortae. GSNO and SNAP were equivalent and more efficient than SNP. In endothelium-intact aortae, the NO store was also formed whereas it seemed less available for vasorelaxation and did not influence PHE-induced vasoconstriction. In conclusion, RSNOs - NACNO in a better extent - are able to restore NO bioavailability as a functional NO store within the vessel wall, especially when the endothelium is removed. This was associated with a hyporeactivity to the vasoconstrictive agent phenylephrine. Treatment with RSNOs could present a benefit to restore NO-dependent functions in pathological states associated with injured endothelium.

Flush with a flash: natural three-component antimicrobial combinations based on S-nitrosothiols, controlled superoxide formation and "domino" reactions leading to peroxynitrite.

S-Nitrosothiols are ˙NO releasing agents renowned for vasodilatory and antioxidant properties. O2˙- promotes their decomposition, forming highly aggressive peroxynitrite ions (ONOO-). Since the production of O2˙- can be controlled by enzymes or by visible light, such otherwise harmless components can be turned into effective antimicrobial and nematicidal combinations with numerous potential applications in medicine.

In vivo and in silico evaluation of a new nitric oxide donor, S,S'-dinitrosobucillamine.

PURPOSE: In a previous work, we have synthetized a new dinitrosothiol, i.e. S,S'-dinitrosobucillamine BUC(NO)2 combining S-nitroso-N-acetylpenicillamine (SNAP) and S-nitroso-N-acetylcysteine (NACNO) in its structure. When exposed to isolated aorta, we observed a 1.5-fold increase of •NO content and a more potent vasorelaxation (1 log higher pD2) compared to NACNO and SNAP alone or combined (Dahboul et al., 2014). In the present study, we analyzed the thermodynamics and kinetics for the release of •NO through computational modeling techniques and correlated it to plasma assays. Then BUC(NO)2 was administered in vivo to rats, assuming it will induce higher and/or longer hypotensive effects than its two constitutive S-mononitrosothiols. METHODS: Free energies for the release of •NO entities have been computed at the density functional theory level assuming an implicit model for the aqueous environment. Degradation products of BUC(NO)2 were evaluated in vitro under heating and oxidizing conditions using HPLC coupled with tandem mass spectrometry (MS/MS). Plasma from rats were spiked with RSNO and kinetics of RSNO degradation was measured using the classical Griess-Saville method. Blood pressure was measured in awake male Wistar rats using telemetry (n = 5, each as its own control, 48 h wash-out periods between subcutaneous injections under transient isoflurane anesthesia, random order: 7 mL/kg vehicle, 3.5, 7, 14 µmol/kg SNAP, NACNO, BUC(NO)2 and an equimolar mixture of SNAP + NACNO in order to mimic the number of •NO contained in BUC(NO)2). Variations of mean (ΔMAP, reflecting arterial dilation) and pulse arterial pressures (ΔPAP, indirectly reflecting venodilation, used to determine effect duration) vs. baseline were recorded for 4 h. RESULTS: Computational modeling highlights the fact that the release of the first •NO radical in BUC(NO)2 requires a free energy which is intermediate between the values obtained for SNAP and NACNO. However, the release of the second •NO radical is significantly favored by the concerted formation of an intramolecular disulfide bond. The corresponding oxidized compound was also characterized as related substance obtained under degradation conditions. The in vitro degradation rate of BUC(NO)2 was significantly greater than for the other RSNO. For equivalent low and medium •NO-load, BUC(NO)2 produced a hypotension identical to NACNO, SNAP and the equimolar mixture of SNAP + NACNO, but its effect was greater at higher doses (-62 ± 8 and -47 ± 14 mmHg, maximum ΔMAP for BUC(NO)2 and SNAP + NACNO, respectively). Its duration of effect on PAP (-50%) lasted from 35 to 95 min, i.e. shorter than for the other RSNO (from 90 to 135 min for the mixture SNAP + NACNO). CONCLUSION: A faster metabolism explains the abilities of BUC(NO)2 to release higher amounts of •NO and to induce larger hypotension but shorter-lasting effects than those induced by the SNAP + NACNO mixture, despite an equivalent •NO-load.

Accurate measurement of reduced glutathione in gamma-glutamyltransferase-rich brain microvessel fractions.

Investigation of the redox status in the cerebral circulation is of great importance in order to evaluate intensity of oxidative stress-related diseases and the corresponding therapeutic effects. Changes in levels of reduced glutathione (GSH) are a major indicator of oxidative stress conditions. However, an important limitation for measurement of GSH as a biomarker is the possible presence in samples of gamma-glutamyltransferase (GGT) activity, i.e., the enzyme catalysing GSH breakdown. An accurate assay for the measurement of GSH in rat brain microvessels was developed, taking into account the high GGT activity expressed in this tissue compartment. Based on a sensitive fluorescence-based microtiter plate method using 2,3-naphthalenedicarboxyaldehyde as GSH-selective fluorogenic probe, the assay was applied to brain microvessels isolated from individual male Wistar rats. Pooling of microvessel fractions from several animals, as required by other procedures, could thus be avoided. In order to prevent GSH consumption via GGT activity, serine-boric acid complex (SBC) was added as inhibitor all along the microvessels isolation process. In the absence of GGT inhibition GSH in isolated brain microvessels was below the limit of quantification. Addition of SBC almost completely suppressed GGT activity, thus allowing GSH quantification (4.4±1.6 nmol.mg(-1) protein, n=3). Following the administration of a GSH depletor (diethyl maleate, 1g.kg(-1), i.p.), decreased GSH levels were measured in liver, brain tissue and brain microvessels as well, thus confirming the reliability of the method for safe GSH measurements in small-sized, individual samples presenting high GGT activity.

Mechanisms of aortic and cardiac dysfunction in uremic mice with aortic calcification.

BACKGROUND: Chronic renal failure (CRF) is associated with cardiac dysfunction and increased aortic stiffness. The mechanisms involved are not clearly understood. We examined changes over time in cardiac and aortic function in a murine CRF model. METHODS AND RESULTS: Eight-week-old mice were randomly assigned to 1 of 4 groups: wild-type non-CRF, wild-type CRF, apolipoprotein E knockout non-CRF, and apolipoprotein E knockout CRF. Echocardiography was performed and blood samples were taken at baseline and after 6 and 10 weeks of CRF. Vascular reactivity and adhesion molecule expression were studied after 6 and 10 weeks of CRF. Left ventricular hypertrophy, altered left ventricular relaxation, and increased aortic stiffness were observed after 6 weeks of CRF and persisted after 10 weeks. The 4 groups of mice did not significantly differ in terms of arterial blood pressure and aortic structure. The degree of vascular calcification and serum total cholesterol concentration were higher in the CRF groups than in the non-CRF groups. These changes, however, could not explain the cardiac and vascular differences seen in the 2 CRF groups. In contrast, alterations in vascular reactivity, the upregulation of adhesion molecule expression, and CRF status were significantly associated with these changes. CONCLUSIONS: In a mouse model of CRF, left ventricular hypertrophy, cardiac diastolic dysfunction, and increased aortic stiffness were not related to structural changes in the aorta (including aortic calcification) or high serum cholesterol levels. However, cardiac and aortic abnormalities were associated with the extent of subendothelial dysfunction and the severity of CRF.

Adhesion of Candida albicans to HeLa cells: studies using polystyrene beads.

The adherence to HeLa cells by the yeast-type cells of the Candida albicans NIH A-207 strain cultivated for 2 d at 27 degrees C in the yeast extract-added Sabouraud liquid medium (YSLM) and the 500 mM galactose-added yeast nitrogen base medium (YNB-Gal) was compared. The yeast cells cultured in the YNB-Gal clearly increased the adherence to the HeLa cells compared to the YSLM. The adherence drastically decreased by pronase treatment of the yeast cells. Next, to define the sugar receptors of the yeast cells, lactosylceramide (LC)-, the H type 1 antigen (HA)-, Lewis(a) antigen (Le(a))-, mannan- and BSA-coated polystyrene beads were used for the adherence to the yeast cells. Only the LC- and HA-beads were bound to the yeast cells. The adherence of the two beads to the yeast cells cultured in the YNB-Gal was higher than that to the yeast cells cultured in the YSLM. The yeast cell wall mannan-coated polystyrene beads did not adhere at all to the Hela cells. Based on these results, it is evident that the protein parts involving the LC and HA receptors on the surface of the yeast cells correlate with the adherence to the HeLa cells.

Effects of dexamethasone and L-canavanine on the intracellular calcium-contraction relation of the rat tail artery during septic shock.

The intracellular mechanism by which sepsis lowers vascular reactivity and the subsequent reversal by dexamethasone or nitric oxide synthase (NOS) inhibitors remain unclear. We measured the sensitivity of contraction of the rat tail artery to intracellular Ca2+ in a model of polymicrobial septic shock. At 22 h after cecal ligation and puncture (CLP), rats were treated with an anti-inflammatory glucocorticoid (dexamethasone, 1 mg/kg ip), an inducible NOS inhibitor (L-canavanine, 100 mg/kg ip), or saline. At 24 h after CLP, endothelium-denuded, perfused segments of tail artery were loaded with the intracellular Ca2+-sensitive dye fura 2 in vitro. Intracellular Ca2+ concentration and perfusion pressure were measured simultaneously. The rightward shift of the perfusion pressure-intracellular Ca2+ mobilization curve after norepinephrine stimulation subsequent to CLP indicates decreased intracellular Ca2+ sensitivity of contraction. The relation was restored by dexamethasone (which also restored in vivo blood pressure and flow), but not by L-canavanine (which restored perfusion pressure by further mobilization of intracellular Ca2+). We conclude that CLP lowers vasomotion by lowering intracellular Ca2+ sensitivity, which can be restored with glucocorticoid treatment. The involvement of inducible NOS does not solely account for the sepsis-induced reduction in Ca2+ sensitivity of contraction.

Antigenicity of cell wall mannans of Candida albicans NIH A-207 strain cells cultured in galactose-added yeast nitrogen base medium.

The cultivations of the Candida albicans NIH A-207 strain (A-strain) for 5 d at 27 and 37 degrees C in 500 mM galactose-added yeast nitrogen base medium (YNB-Gal) decreased the growth of blastoconidia and the pH in the cultures, with dry weights of 56 and 47% and with pHs of 2.41 and 2.47, compared with the dry weight of 100% and pH of 5.63 for a standard cultivation of 2 d at 27 degrees C in the yeast extract-added Sabouraud liquid medium (YSLM). The cells obtained by cultivations at 27 and 37 degrees C in the YNB-Gal clearly decreased the agglutination against serum factors 4, 5, and 6 in the commercially available kit 'Candida Check', especially at 37 degrees C, in contrast to those obtained by the standard cultivation. It was also revealed by 1H-NMR analysis that both the mannans obtained from cultures at 27 and 37 degrees C in the YNB-Gal had drastically lost a phosphate group and a beta-1,2-linked mannopyranose unit, and increased the non-reducing terminal alpha-1,3-linked mannopyranose unit, especially at 37 degrees C.

Decreased aortic smooth muscle contraction in a rat model of multibacterial sepsis.

We investigated whether blockade of the smooth muscle cell (SMC) inducible nitric oxide synthase (iNOS)-soluble guanylyl cyclase (sGC) vasodilator pathway would restore the fall in vasoreactivity produced by sepsis following cecal ligation and perforation (CLP) in rats. Contraction of adjacent aortic rings paired for the presence or absence of endothelial cells (EC) was recorded following high [K(+)](e) (40 mm) or norepinephrine (NE, 10(-8) to 10(-5) m) in the presence of the nitric oxide synthase inhibitor (NOS), N(G)-nitro-l-arginine methyl ester (l-NAME, 0.3 mm) or the sGC inhibitor, 1H-[1,2,4]oxadiazolo[4,3-alpha]quinoxalin-1-one (ODQ, 5 mum). In EC-denuded rings, sepsis halved SMC contraction induced by high [K(+)](e) or NE; neither l-NAME nor ODQ produced an increase in NE E(max) or high [K(+)](e)-evoked contraction. In conclusion, SMC contractility is globally reduced in CLP; this reduction does not appear to be explained by induction of SMC NOS in this CLP model.