Blockade of TGF-β 1 Signalling Inhibits Cardiac NADPH Oxidase Overactivity in Hypertensive Rats

NADPH oxidases constitute a major source of superoxide anion (·O2 −) in hypertension. Several studies suggest an important role of NADPH oxidases in different effects mediated by TGF-β 1. In this study we show that chronic administration of P144, a peptide synthesized from type III TGF-β 1 receptor, significantly reduced the cardiac NADPH oxidase expression and activity as well as in the nitrotyrosine levels observed in control spontaneously hypertensive rats (V-SHR) to levels similar to control normotensive Wistar Kyoto rats. In addition, P144 was also able to reduce the significant increases in the expression of collagen type I protein and mRNA observed in hearts from V-SHR. In addition, positive correlations between collagen expression, NADPH oxidase activity, and nitrotyrosine levels were found in all animals. Finally, TGF-β 1-stimulated Rat-2 exhibited significant increases in NADPH oxidase activity that was inhibited in the presence of P144. It could be concluded that the blockade of TGF-β 1 with P144 inhibited cardiac NADPH oxidase in SHR, thus adding new data to elucidate the involvement of this enzyme in the profibrotic actions of TGF-β 1

Low-density lipoprotein-cholesterol-induced endothelial dysfunction and oxidative stress: the role of statins

SIGNIFICANCE: Cardiovascular diseases (CVD) represent a major public health burden. High low-density lipoprotein (LDL)-cholesterol is a recognized pathogenic factor for atherosclerosis, and its complications and statins represent the most potent and widely used therapeutic approach to prevent and control these disorders. RECENT ADVANCES: A number of clinical and experimental studies concur to identify endothelial dysfunction as a primary step in the development of atherosclerosis, as well as a risk factor for subsequent clinical events. Oxidant stress resulting from chronic elevation of plasma LDL-cholesterol (LDL-chol) is a major contributor to both endothelial dysfunction and its complications, for example, through alterations of endothelial nitric oxide signaling. CRITICAL ISSUES: Statin treatment reduces morbidity and mortality of CVD, but increasing evidence questions that this is exclusively through reduction of plasma LDL-chol. The identification of ancillary effects on (cardio)vascular biology, for example, through their modulation of oxidative stress, will not only increase our understanding of their mechanisms of action, with a potential broadening of their indication(s), but also lead to the identification of new molecular targets for future therapeutic developments in CVD. FUTURE DIRECTIONS: Further characterization of molecular pathways targeted by statins, for example, not directly mediated by changes in plasma lipid concentrations, should enable a more comprehensive approach to the pathogenesis of (cardio)vascular disease, including, for example, epigenetic regulation and fine tuning of cell metabolism

Myocardial fibrosis in chronic kidney disease: potential benefits of torasemide

Interstitial and perivascular fibrosis is a constant finding in heart biopsies and necropsy studies in patients with chronic kidney disease and hypertension, namely in those with left ventricular hypertrophy. Fibrosis is the result of the unbalance between exaggerated collagen synthesis and unchanged or depressed collagen degradation. A number of factors linked to hypertension and the progressive deterioration of renal function may facilitate such an unbalance. Patients with chronic kidney disease and hypertension are prone to develop diastolic heart failure, and myocardial fibrosis has been suggested as a major determinant of disturbances in diastolic function in these patients. Thus, the therapeutic strategies aimed to reduce cardiac fibrosis may provide a particular cardioprotective benefit in patients with chronic kidney disease. In this regard, recent data suggest that the loop diuretic torasemide reduces myocardial fibrosis and ameliorates cardiac function in patients with chronic heart failure through local mechanisms beyond its effects on the renal excretion of fluid and electrolytes and systemic hemodynamics

Myocardial fibrosis in chronic kidney disease: potential benefits of torasemide

Interstitial and perivascular fibrosis is a constant finding in heart biopsies and necropsy studies in patients with chronic kidney disease and hypertension, namely in those with left ventricular hypertrophy. Fibrosis is the result of the unbalance between exaggerated collagen synthesis and unchanged or depressed collagen degradation. A number of factors linked to hypertension and the progressive deterioration of renal function may facilitate such an unbalance. Patients with chronic kidney disease and hypertension are prone to develop diastolic heart failure, and myocardial fibrosis has been suggested as a major determinant of disturbances in diastolic function in these patients. Thus, the therapeutic strategies aimed to reduce cardiac fibrosis may provide a particular cardioprotective benefit in patients with chronic kidney disease. In this regard, recent data suggest that the loop diuretic torasemide reduces myocardial fibrosis and ameliorates cardiac function in patients with chronic heart failure through local mechanisms beyond its effects on the renal excretion of fluid and electrolytes and systemic hemodynamics

Role of nitric oxide and oxidative stress in a sheep model of persistent atrial fibrillation.

In a sheep model of persistent AF, NOS3 transcript levels are attenuated and circulating NOx levels decreased. Persistent AF is associated with increased oxidative stress, probably resulting from increased NADPH oxidase activity, without major changes in anti-oxidant capacity of the atrial tissue

Role of lysyl oxidase in myocardial fibrosis: from basic science to clinical aspects

Because of its dynamic nature, the composition and structure of the myocardial collagen network can be reversibly modified to adapt to transient cardiac injuries. In response to persistent injury, however, irreversible, maladaptive changes of the network occur leading to fibrosis, mostly characterized by the excessive interstitial and perivascular deposition of collagen types I and III fibers. It is now becoming apparent that myocardial fibrosis directly contributes to adverse myocardial remodeling and the resulting alterations of left ventricular (LV) anatomy and function present in the major types of cardiac diseases. The enzyme lysyl oxidase (LOX) is a copper-dependent extracellular enzyme that catalyzes lysine-derived cross-links in collagen and elastin. LOX-mediated cross-linking of collagen types I and III fibrils leads to the formation of stiff collagen types I and III fibers and their subsequent tissue deposition. Evidence from experimental and clinical studies shows that the excess of LOX is associated with an increased collagen cross-linking and stiffness. It is thus conceivable that LOX upregulation and/or overactivity could underlie myocardial fibrosis and altered LV mechanics and contribute to the compromise of LV function in cardiac diseases. This review will consider the molecular aspects related to the regulation and actions of LOX, namely, in the context of collagen synthesis. In addition, it will address the information related to the role of myocardial LOX in heart failure and the potential benefits of controlling its expression and function

Role of lysyl oxidase in myocardial fibrosis: from basic science to clinical aspects

Because of its dynamic nature, the composition and structure of the myocardial collagen network can be reversibly modified to adapt to transient cardiac injuries. In response to persistent injury, however, irreversible, maladaptive changes of the network occur leading to fibrosis, mostly characterized by the excessive interstitial and perivascular deposition of collagen types I and III fibers. It is now becoming apparent that myocardial fibrosis directly contributes to adverse myocardial remodeling and the resulting alterations of left ventricular (LV) anatomy and function present in the major types of cardiac diseases. The enzyme lysyl oxidase (LOX) is a copper-dependent extracellular enzyme that catalyzes lysine-derived cross-links in collagen and elastin. LOX-mediated cross-linking of collagen types I and III fibrils leads to the formation of stiff collagen types I and III fibers and their subsequent tissue deposition. Evidence from experimental and clinical studies shows that the excess of LOX is associated with an increased collagen cross-linking and stiffness. It is thus conceivable that LOX upregulation and/or overactivity could underlie myocardial fibrosis and altered LV mechanics and contribute to the compromise of LV function in cardiac diseases. This review will consider the molecular aspects related to the regulation and actions of LOX, namely, in the context of collagen synthesis. In addition, it will address the information related to the role of myocardial LOX in heart failure and the potential benefits of controlling its expression and function