RESUMEN
We hypothesized that, due to a cross-talk between cytoplasmic O2--sources and intraluminally expressed xanthine oxidase (XO), intraluminal O2- is instrumental in mediating intraluminal (endothelial dysfunction) and cytosolic (p38 and ERK1/2 MAPKs phosphorylation) manifestations of vascular oxidative stress induced by endothelin-1 (ET-1) and angiotensin II (AT-II). Isolated guinea-pig hearts were subjected to 10-min agonist perfusion causing a burst of an intraluminal O2-. ET-1 antagonist, tezosentan, attenuated AT-II-mediated O2-, indicating its partial ET-1 mediation. ET-1 and Ang-T (AT-II+tezosentan) triggered intraluminal O2-, endothelial dysfunction, MAPKs and p47phox phosphorylation, and NADPH oxidase (Nox) and XO activation. These effects were: (i) prevented by blocking PKC (chelerythrine), Nox (apocynin), mitochondrial ATP-dependent K+ channel (5-HD), complex II (TTFA), and XO (allopurinol); (ii) mimicked by the activation of Nox (NADH); and mitochondria (diazoxide, 3-NPA) and (iii) the effects by NADH were prevented by 5-HD, TTFA and chelerythrine, and those by diazoxide and 3-NPA by apocynin and chelerythrine, suggesting that the agonists coactivate Nox and mitochondria, which further amplify their activity via PKC. The effects by ET-1, Ang-T, NADH, diazoxide, and 3-NPA were opposed by blocking intraluminal O2- (SOD) and XO, and were mimicked by XO activation (hypoxanthine). Apocynin, TTFA, chelerythrine, and SOD opposed the effects by hypoxanthine. In conclusion, oxidative stress by agonists involves cellular inside-out and outside-in signaling in which Nox-mitochondria-PKC system and XO mutually maintain their activities via the intraluminal O2-.
Asunto(s)
Angiotensina II/metabolismo , Endotelina-1/metabolismo , Endotelio Vascular/metabolismo , Proteína Quinasa 1 Activada por Mitógenos/metabolismo , Miocardio/metabolismo , Consumo de Oxígeno , Transducción de Señal , Angiotensina II/farmacología , Animales , Citoplasma/metabolismo , Endotelina-1/farmacología , Endotelio Vascular/efectos de los fármacos , Endotelio Vascular/fisiopatología , Cobayas , Corazón/efectos de los fármacos , Corazón/fisiopatología , Mitocondrias/efectos de los fármacos , Mitocondrias/metabolismo , NADPH Oxidasas/metabolismo , Estrés Oxidativo , Fosforilación , Proteína Quinasa C/metabolismo , Especies Reactivas de Oxígeno/metabolismo , Superóxido Dismutasa/metabolismoRESUMEN
Seasonality in endothelial dysfunction and oxidative stress was noted in humans and rats, suggesting it is a common phenomenon of a potential clinical relevance. We aimed at studying (i) seasonal variations in cardiac superoxide (O(2)(-)) production in rodents and in 8-isoprostane urinary excretion in humans, (ii) the mechanism of cardiac O(2)(-) overproduction occurring in late spring/summer months in rodents, (iii) whether this seasonal O(2)(-)-overproduction is associated with a pro-inflammatory endothelial activation, and (iv) how the summer-associated changes compare to those caused by diabetes, a classical cardiovascular risk factor. Langendorff-perfused guinea-pig and rat hearts generated ~100% more O(2)(-), and human subjects excreted 65% more 8-isoprostane in the summer vs. other seasons. Inhibitors of NADPH oxidase, xanthine oxidase, and NO synthase inhibited the seasonal O(2)(-)-overproduction. In the summer vs. other seasons, cardiac NADPH oxidase and xanthine oxidase activity, and protein expression were increased, the endothelial NO synthase and superoxide dismutases were downregulated, and, in guinea-pig hearts, adhesion molecules upregulation and the endothelial glycocalyx destruction associated these changes. In guinea-pig hearts, the summer and a streptozotocin-induced diabetes mediated similar changes, yet, more severe endothelial activation associated the diabetes. These findings suggest that the seasonal oxidative stress is a common phenomenon, associated, at least in guinea-pigs, with the endothelial activation. Nonetheless, its biological meaning (regulatory vs. deleterious) remains unclear. Upregulated NADPH oxidase and xanthine oxidase and uncoupled NO synthase are the sources of the seasonal O(2)(-)-overproduction.
Asunto(s)
Endotelio Vascular/metabolismo , Corazón/fisiología , Superóxidos/metabolismo , Animales , Western Blotting , Dinoprost/análogos & derivados , Dinoprost/metabolismo , Femenino , Glicocálix/metabolismo , Cobayas , Humanos , Masculino , NADPH Oxidasas/metabolismo , Estrés Oxidativo/fisiología , Ratas , Ratas Wistar , Estaciones del Año , Vasodilatación/fisiología , Xantina Oxidasa/metabolismoRESUMEN
The role of calcineurin (CN) pathway in the post-myocardial infarction (MI) heart remains unclear. We investigated effects of early and brief inhibition of CN pathway with cyclosporine A (CsA) after MI on both immediate and delayed changes in left ventricular (LV) morphology, haemodynamics, and cardiomyocyte performance. CsA/saline was administered for 4 days, starting 24 h after MI/sham surgery in the rat. MI resulted in CN overactivity, peaking on day 3, accompanied by significant intracellular Ca(2+) overload due to marked decrease of NCX function. On day 7 and in week 8, CN activity decreased and normalized, respectively. It was accompanied by normalization of Ca(2+) handling parameters (only SERCA function was moderately decreased). CsA abolished post-MI CN overactivity, protected against Ca(2+) overload on day 3 and slightly improved SERCA function on day 7. Moreover, CsA reduced hypertrophy on days 3 and 7 after MI, increased wall stress on day 7 and in week 8, and lowered ejection fraction, augmented LV dilation as well increased mortality in week 8. Our study demonstrates that blockade of brief post-MI CN overactivity with CsA has delayed detrimental effects: increased mortality and worse LV function. CsA prevented early cardiomyocyte hypertrophy, decreased wall thickness and thus increased the wall stress, the main stimulus for detrimental LV dilation. Furthermore, CsA treatment prevented early Ca(2+) overload related to decreased NCX function. Role of this early Ca(2+) overload is unclear; it might be an element of positive feedback loop amplifying CN activation in post-MI heart.
Asunto(s)
Inhibidores de la Calcineurina , Calcio/química , Infarto del Miocardio/metabolismo , Animales , Calcineurina/metabolismo , Ciclosporina/farmacología , Ecocardiografía/métodos , Ventrículos Cardíacos/patología , Hemodinámica , Masculino , Miocitos Cardíacos/metabolismo , Ratas , Ratas Wistar , Retículo Sarcoplasmático/metabolismo , Factores de Tiempo , Remodelación VentricularRESUMEN
Emerging evidence supports an important role for T cells in the genesis of hypertension. Because this work has predominantly been performed in experimental animals, we sought to determine whether human T cells are activated in hypertension. We used a humanized mouse model in which the murine immune system is replaced by the human immune system. Angiotensin II increased systolic pressure to 162 versus 116 mm Hg for sham-treated animals. Flow cytometry of thoracic lymph nodes, thoracic aorta, and kidney revealed increased infiltration of human leukocytes (CD45(+)) and T lymphocytes (CD3(+) and CD4(+)) in response to angiotensin II infusion. Interestingly, there was also an increase in the memory T cells (CD3(+)/CD45RO(+)) in the aortas and lymph nodes. Prevention of hypertension using hydralazine and hydrochlorothiazide prevented the accumulation of T cells in these tissues. Studies of isolated human T cells and monocytes indicated that angiotensin II had no direct effect on cytokine production by T cells or the ability of dendritic cells to drive T-cell proliferation. We also observed an increase in circulating interleukin-17A producing CD4(+) T cells and both CD4(+) and CD8(+) T cells that produce interferon-γ in hypertensive compared with normotensive humans. Thus, human T cells become activated and invade critical end-organ tissues in response to hypertension in a humanized mouse model. This response likely reflects the hypertensive milieu encountered in vivo and is not a direct effect of the hormone angiotensin II.
Asunto(s)
Angiotensina II/farmacología , Anticuerpos Monoclonales Humanizados/inmunología , Hipertensión/inmunología , Activación de Linfocitos/inmunología , Linfocitos T Reguladores/inmunología , Adulto , Análisis de Varianza , Animales , Células Cultivadas/efectos de los fármacos , Células Cultivadas/inmunología , Distribución de Chi-Cuadrado , Modelos Animales de Enfermedad , Humanos , Hipertensión/tratamiento farmacológico , Hipertensión/fisiopatología , Riñón/efectos de los fármacos , Riñón/inmunología , Riñón/metabolismo , Activación de Linfocitos/efectos de los fármacos , Ratones , Persona de Mediana Edad , Distribución Aleatoria , Valores de Referencia , Muestreo , Estadísticas no Paramétricas , Linfocitos T Reguladores/efectos de los fármacosRESUMEN
SIGNIFICANCE: Reactive oxygen species (ROS) play a critical role in vascular disease. While there are many possible sources of ROS, nicotinamide adenine dinucleotide phosphate (NADPH) oxidases play a central role. They are a source of "kindling radicals," which affect other enzymes, such as nitric oxide synthase endothelial nitric oxide synthase or xanthine oxidase. This is important, as risk factors for atherosclerosis (hypertension, diabetes, hypercholesterolemia, and smoking) regulate the expression and activity of NADPH oxidases in the vessel wall. RECENT ADVANCES: There are seven isoforms in mammals: Nox1, Nox2, Nox3, Nox4, Nox5, Duox1 and Duox2. Nox1, Nox2, Nox4, and Nox5 are expressed in endothelium, vascular smooth muscle cells, fibroblasts, or perivascular adipocytes. Other homologues have not been found or are expressed at very low levels; their roles have not been established. Nox1/Nox2 promote the development of endothelial dysfunction, hypertension, and inflammation. Nox4 may have a role in protecting the vasculature during stress; however, when its activity is increased, it may be detrimental. Calcium-dependent Nox5 has been implicated in oxidative damage in human atherosclerosis. CRITICAL ISSUES: NADPH oxidase-derived ROS play a role in vascular pathology as well as in the maintenance of normal physiological vascular function. We also discuss recently elucidated mechanisms such as the role of NADPH oxidases in vascular protection, vascular inflammation, pulmonary hypertension, tumor angiogenesis, and central nervous system regulation of vascular function and hypertension. FUTURE DIRECTIONS: Understanding the role of individual oxidases and interactions between homologues in vascular disease is critical for efficient pharmacological regulation of vascular NADPH oxidases in both the laboratory and clinical practice.
Asunto(s)
Aterosclerosis/patología , Endotelio Vascular/patología , NADPH Oxidasas/genética , Isoformas de Proteínas/genética , Animales , Aterosclerosis/enzimología , Endotelio Vascular/enzimología , Humanos , Músculo Liso Vascular/enzimología , Músculo Liso Vascular/patología , NADPH Oxidasas/clasificación , NADPH Oxidasas/metabolismo , Estrés Oxidativo/genética , Isoformas de Proteínas/metabolismo , Especies Reactivas de Oxígeno/metabolismo , Factores de RiesgoRESUMEN
AIMS: Plasmalemmal Ca(2+)-ATPase (PMCA) is involved in Ca(2+) handling and the regulation of intracellular signalling pathways in the heart. However, there is no information on its functioning in heart hypertrophy and failure. We aimed to investigate the Ca(2+)-transporting ability of PMCA, Na(+)/Ca(2+) exchanger (NCX), and sarcoplasmic reticulum (SR) Ca(2+)-ATPase (SERCA2a), as well as the amplitude of Ca(2+) transients and cell shortening in myocytes isolated from rat hearts at various time intervals after myocardial infarction (MI). METHODS AND RESULTS: The rate of Ca(2+) transport by PMCA, NCX, and SERCA2a was estimated from the rate constants of decay of electrically and caffeine-evoked Ca(2+) transients in left ventricular myocytes isolated 1 week, 1 month, and 3 months after MI. One week, 1 month, and 3 months after MI, the transporting function of PMCA decreased by 27, 41, and 67%, respectively, compared with that in time-matched sham animals. This was accompanied by increased amplitude of Ca(2+) transients, cell shortening, and SR Ca(2+) content. Carboxyeosin, a blocker of PMCA, increased the amplitude of shortening in cells extracted from control hearts. This effect was absent 1 and 3 months after MI. PMCA1, 2, and 4 mRNAs were unchanged in the ventricular muscle 3 months after MI when compared with time-matched sham animals. The transporting function of NCX was increased by 65% only 3 months after MI, whereas that of SERCA2a was decreased by approximately 18% at all three time points after MI. CONCLUSION: The ability of PMCA to transport Ca(2+) progressively decreases over 3 months after MI. This decrease may contribute to the increase in amplitude of Ca(2+) transients and myocyte shortening.
Asunto(s)
Señalización del Calcio , Calcio/metabolismo , Infarto del Miocardio/enzimología , Miocitos Cardíacos/enzimología , ATPasas Transportadoras de Calcio del Retículo Sarcoplásmico/metabolismo , Animales , Cafeína/farmacología , Señalización del Calcio/efectos de los fármacos , Modelos Animales de Enfermedad , Regulación hacia Abajo , Estimulación Eléctrica , Masculino , Contracción Miocárdica , Infarto del Miocardio/fisiopatología , Miocitos Cardíacos/efectos de los fármacos , ATPasas Transportadoras de Calcio de la Membrana Plasmática/metabolismo , ARN Mensajero/metabolismo , Ratas , Ratas Endogámicas WKY , ATPasas Transportadoras de Calcio del Retículo Sarcoplásmico/genética , Intercambiador de Sodio-Calcio/metabolismo , Factores de Tiempo , Remodelación VentricularRESUMEN
The hypothesis was tested that endothelin-1 (ET-1)-induced superoxide (O(2)(-)) generation mediates post-ischemic coronary endothelial injury, that ischemic preconditioning (IPC) affords endothelial protection by preventing post-ischemic ET-1, and thus O(2)(-), generation, and that opening of the mitochondrial ATP-dependent potassium channel (mK(ATP)) triggers the mechanism of IPC. Furthermore, the study was aimed at identifying the source of O(2)(-) mediating the endothelial injury. Langendorff-perfused guinea-pig hearts were subjected either to 30 min ischemia/35 min reperfusion (IR) or were preconditioned prior to IR with three cycles of either 5 min ischemia/5 min reperfusion or 5 min infusion/5 min washout of mK(ATP) opener diazoxide (0.5 mM). Coronary flow responses to acetylcholine (ACh) served as a measure of endothelium-dependent vascular function. Myocardial outflow of ET-1 and O(2)(-) and functional recoveries were followed during reperfusion. NADPH oxidase and xanthine oxidase (XO) activities were measured in cardiac homogenates. IR augmented ET-1 and O(2)(-) outflow and impaired ACh response. All these effects were attenuated or prevented by IPC and diazoxide, and 5-hydroxydecanoate (a selective mK(ATP) blocker) abolished the effects of IPC and diazoxide. Superoxide dismutase and tezosentan (a mixed ET-1-receptor antagonist) mimicked the effects of IPC, although they had no effect on the ET-1 generation. IR augmented also the activity of NADPH oxidase and XO. Apocynin treatment, that resulted in NADPH oxidase inhibition, prevented XO activation and O(2)(-) generation in IR hearts. The inhibition of XO, either by allopurinol or feeding the animals with tungsten-enriched chow, prevented post-ischemic O(2)(-) generation, although these interventions had no effect on the NADPH activity. In addition, the post-ischemic activation of NADPH oxidase and XO, and O(2)(-) generation were prevented by IPC, tezosentan, thenoyltrifluoroacetone (mitochondrial complex II inhibitor), and tempol (cell-membrane permeable O(2)(-) scavenger). In guinea-pig heart: (i) ET-1-induced O(2)(-) generation mediates post-ischemic endothelial dysfunction; (ii) IPC and diazoxide afford endothelial protection by attenuating the ET-1, and thus O(2)(-) generation, and the mK(ATP) opening triggers the protection; (iii) the NADPH oxidase maintains the activity of XO, and the XO-derived O(2)(-) mediates the endothelial injury, and (iv) ET-1 and O(2)(-) (probably of mitochondrial origin) are upstream activators of the NADPH oxidase-XO cascade, and IPC prevents the cascade activation and the endothelial dysfunction by preventing the ET-1 generation.