Although resveratrol has widely been studied for its potential health benefits, little is known about its metabolic effects in humans. Our aims were to determine whether the polyphenol resveratrol improves insulin sensitivity in type 2 diabetic patients and to gain some insight into the mechanism of its action. After an initial general examination (including blood chemistry), nineteen patients enrolled in the 4-weeklong double-blind study were randomly assigned into two groups: a resveratrol group receiving oral 2 £ 5 mg resveratrol and a control group receiving placebo. Before and after the second and fourth weeks of the trial, insulin resistance/sensitivity, creatinine-normalised ortho-tyrosine level in urine samples (as a measure of oxidative stress), incretin levels and phosphorylated protein kinase B (pAkt):protein kinase B (Akt) ratio in platelets were assessed and statistically analysed. After the fourth week, resveratrol significantly decreased insulin resistance (homeostasis model of assessment for insulin resistance) and urinary ortho-tyrosine excretion, while it increased the pAkt:Akt ratio in platelets. On the other hand, it had no effect on parameters that relate to b-cell function (i.e. homeostasis model of assessment of b-cell function). The present study shows for the first time that resveratrol improves insulin sensitivity in humans, which might be due to a resveratrol-induced decrease in oxidative stress that leads to a more efficient insulin signalling via the Akt pathway.Key words: Resveratrol: Type 2 diabetes: Insulin sensitivity: Oxidative stress: Akt Despite the rather high average daily fat intake in France, compared with other European countries, epidemiological surveys document a relatively low rate of cardiovascular mortality. This phenomenon, which is often called the French paradox, is thought to be explained by a fairly high red wine consumption by the French (1,2) . Red wine is known to be rich in various polyphenolic compounds that might have a variety of health benefits. Among these polyphenols, the stilbene derivative resveratrol seems to be the most vigorously studied, which is probably due to the fact that it apparently affects a wide array of physiological and biochemical processes as shown in animal and cell culture studies (3) . On the other hand, human studies with conclusive results on resveratrol are regrettably lacking.Resveratrol is considered to have beneficial effects on the cardiovascular system, as it has been found to improve vasodilatation (4) , ischaemic preconditioning (5,6) , both of which seem to be the result of the activation of the endothelial NO synthase enzyme (7) , and to inhibit both platelet aggregation (3) and vascular smooth muscle cell proliferation (8) . In addition, resveratrol has also been demonstrated to show anti-inflammatory (9) and anti-tumour activities (3) , and it might even have considerable anti-ageing properties as it provokes changes in cell signalling that mimics those found upon energy restriction (3) .Oxidative stress, whi...
H2S signals via protein persulfidation. To be regulatory the modification will have to be reversible. Using a new method for persulfide detection, we discover this missing link and show that thioredoxin system acts as depersulfidase in vivo.
High blood pressure is the leading risk factor for death worldwide. One of the hallmarks is a rise of peripheral vascular resistance, which largely depends on arteriole tone. Ca 2+ -activated chloride currents (CaCCs) in vascular smooth muscle cells (VSMCs) are candidates for increasing vascular contractility. We analyzed the vascular tree and identified substantial CaCCs in VSMCs of the aorta and carotid arteries. CaCCs were small or absent in VSMCs of medium-sized vessels such as mesenteric arteries and larger retinal arterioles. In small vessels of the retina, brain, and skeletal muscle, where contractile intermediate cells or pericytes gradually replace VSMCs, CaCCs were particularly large. Targeted disruption of the calcium-activated chloride channel TMEM16A, also known as ANO1, in VSMCs, intermediate cells, and pericytes eliminated CaCCs in all vessels studied. Mice lacking vascular TMEM16A had lower systemic blood pressure and a decreased hypertensive response following vasoconstrictor treatment. There was no difference in contractility of medium-sized mesenteric arteries; however, responsiveness of the aorta and small retinal arterioles to the vasoconstrictioninducing drug U46619 was reduced. TMEM16A also was required for peripheral blood vessel contractility, as the response to U46619 was attenuated in isolated perfused hind limbs from mutant mice. Out data suggest that TMEM16A plays a general role in arteriolar and capillary blood flow and is a promising target for the treatment of hypertension.
Wall stretch is a major stimulus for the myogenic response of small arteries to pressure. Recent findings suggest that G protein‐coupled receptors can elicit a stretch response. Our aim was to determine if angiotensin II type 1 receptors (AT1R) in vascular smooth muscle cells (VSMC) exert mechanosensitivity and identify the downstream ion channel mediators of myogenic vasoconstriction. We used mice deficient in AT1R signaling molecules and putative ion channel targets, namely AT1R, angiotensinogen, TRPC6 channels or subtypes of the KCNQ (Kv7) gene family (KCNQ3, 4 or 5). We identified a mechano‐sensing mechanism in mesenteric arteries and the renal circulation that relies on coupling of the AT1R subtype a (AT1aR) to a Gq/11‐protein as a critical event to accomplish the myogenic response. The mechano‐activation occurs after block of AT1R, and in the absence of angiotensinogen or TRPC6. Activation of AT1aR suppresses XE991‐sensitive Kv channel currents in VSMCs, blocking these channels enhances mesenteric and renal myogenic tone. Although KCNQ3, 4 and 5 are expressed in VSMCs, XE991‐sensitive K+ current and myogenic contractions persist in arteries deficient in these channels. Our results provide evidence that myogenic responses of mouse mesenteric and renal arteries rely on ligand‐independent mechano‐activation of AT1aR. This signal relies on an ion channel distinct from TRPC6 or KCNQ3, 4 or 5. Grant Funding Source: Supported by Deutsche Forschungsgemeinschaft (DFG)
BackgroundHydrogen sulfide (H2S) is a potent vasodilator. However, the complex mechanisms of vasoregulation by H2S are not fully understood. We tested the hypotheses that (1) H2S exerts vasodilatory effects by opening KCNQ-type voltage-dependent (Kv) K+ channels and (2) that H2S-producing cystathionine-γ-lyase (CSE) in perivascular adipose tissue plays a major role in this pathway.Methodology/Principal FindingsWire myography of rat and mouse aortas was used. NaHS and 5-(4-hydroxyphenyl)-3H-1,2-dithiole-3-thione (ADTOH) were used as H2S donors. KCNQ-type Kv channels were blocked by XE991. 4-Propargylglycine (PPG) and ß-cyano-l-alanine (BCA), or 2-(aminooxy)-acetic acid (AOAA) were used as inhibitors of CSE or cystathionine-ß-synthase (CBS), respectively. NaHS and ADTOH produced strong vasorelaxation in rat and mouse aortas, which were abolished by KCNQ channel inhibition with XE991. Perivascular adipose tissue (PVAT) exerted an anticontractile effect in these arteries. CSE inhibition by PPG and BCA reduced this effect in aortas from rats but not from mice. CBS inhibition with AOAA did not inhibit the anticontractile effects of PVAT. XE991, however, almost completely suppressed the anticontractile effects of PVAT in both species. Exogenous l-cysteine, substrate for the endogenous production of H2S, induced vasorelaxation only at concentrations >5 mmol/l, an effect unchanged by CSE inhibition.Conclusions/SignficanceOur results demonstrate potent vasorelaxant effects of H2S donors in large arteries of both rats and mice, in which XE991-sensitive KCNQ-type channel opening play a pivotal role. CSE-H2S seems to modulate the effect of adipocyte-derived relaxing factor in rat but not in mouse aorta. The present study provides novel insight into the interaction of CSE-H2S and perivascular adipose tissue. Furthermore, with additional technical advances, a future clinical approach targeting vascular H2S/KCNQ pathways to influence states of vascular dysfunction may be possible.
Accumulating evidence indicates that angiotensin-converting enzyme 2 (ACE2) plays a critical role in cardiovascular homeostasis, and its altered expression is associated with major cardiac and vascular disorders. The aim of this study was to evaluate the regulation of vascular function and assess the vascular redox balance in ACE2-deficient (ACE2-/y) animals. Experiments were performed in 20–22 week-old C57BL/6 and ACE2-/y male mice. Evaluation of endothelium-dependent and -independent relaxation revealed an impairment of in vitro and in vivo vascular function in ACE2-/y mice. Drastic reduction in eNOS expression at both protein and mRNA levels, and a decrease in •NO concentrations were observed in aortas of ACE2-/y mice in comparison to controls. Consistently, these mice presented a lower plasma and urine nitrite concentration, confirming reduced •NO availability in ACE2-deficient animals. Lipid peroxidation was significantly increased and superoxide dismutase activity was decreased in aorta homogenates of ACE2-/y mice, indicating impaired antioxidant capacity. Taken together, our data indicate, that ACE2 regulates vascular function by modulating nitric oxide release and oxidative stress. In conclusion, we elucidate mechanisms by which ACE2 is involved in the maintenance of vascular homeostasis. Furthermore, these findings provide insights into the role of the renin-angiotensin system in both vascular and systemic redox balance.
BackgroundWe tested the controversial hypothesis that vitamin D depletion aggravates hypertension and target‐organ damage by influencing renin.Methods and ResultsFour‐week‐old double‐transgenic rats (dTGR) with excess angiotensin (Ang) II production due to overexpression of the human renin (hREN) and angiotensinogen (hAGT) genes received vitamin D‐depleted (n=18) or standard chow (n=15) for 3 weeks. The depleted group had very low serum 25‐hydroxyvitamin D levels (mean±SEM; 3.8±0.29 versus 40.6±1.19 nmol/L) and had higher mean systolic BP at week 5 (158±3.5 versus 134.6±3.7 mm Hg, P<0.001), week 6 (176.6±3.3 versus 162.3±3.8 mm Hg, P<0.01), and week 7 (171.6±5.1 versus 155.9±4.3 mm Hg, P<0.05). Vitamin D depletion led to increased relative heart weights and increased serum creatinine concentrations. Furthermore, the mRNAs of natriuretic peptides, neutrophil gelatinase‐associated lipocalin, hREN, and rRen were increased by vitamin D depletion. Regulatory T cells in the spleen and in the circulation were not affected. Ang metabolites, including Ang II and the counter‐regulatory breakdown product Ang 1 to 7, were significantly up‐regulated in the vitamin D‐depleted groups, while ACE‐1 and ACE‐2 activities were not affected.ConclusionsShort‐term severe vitamin D depletion aggravated hypertension and target‐organ damage in dTGR. Our data suggest that even short‐term severe vitamin D deficiency may directly promote hypertension and impacts on renin‐angiotensin system components that could contribute to target‐organ damage. The findings add to the evidence that vitamin D deficiency could also affect human hypertension.
Hydrogen sulfide (HS) and NO are important gasotransmitters, but how endogenous HS affects the circulatory system has remained incompletely understood. Here, we show that CTH or CSE (cystathionine γ-lyase)-produced HS scavenges vascular NO and controls its endogenous levels in peripheral arteries, which contribute to blood pressure regulation. Furthermore, eNOS (endothelial NO synthase) and phospho-eNOS protein levels were unaffected, but levels of nitroxyl were low in CTH-deficient arteries, demonstrating reduced direct chemical interaction between HS and NO. Pretreatment of arterial rings from CTH-deficient mice with exogenous HS donor rescued the endothelial vasorelaxant response and decreased tissue NO levels. Our discovery that CTH-produced HS inhibits endogenous endothelial NO bioavailability and vascular tone is novel and fundamentally important for understanding how regulation of vascular tone is tailored for endogenous HS to contribute to systemic blood pressure function.
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