Oxidative Stress and Inflammation as Targets for Novel Preventive and Therapeutic Approches in Non Communicable Diseases

As recently reported by the World Health Organization (WHO), Non-Communicable Diseases (NCDs) has been rising over the last century representing the main cause of death and disability for the general population regardless of age, region, or gender [...

Oxidative Stress and Inflammation as Targets for Novel Preventive and Therapeutic Approaches in Non-Communicable Diseases II

Non-communicable diseases (NCDs) are non-infectious chronic pathologies—including obesity, metabolic syndrome, chronic kidney disease (CKD), cardiovascular (CV) diseases, cancer, and chronic respiratory diseases—which represent the main cause of death and disability for the general population [...

Investigation of Na+,K+-ATPase on a solid supported membrane: the role of acylphosphatase on the ion transport mechanism

AbstractCharge translocation by Na+,K+-ATPase was investigated by adsorbing membrane fragments containing Na+,K+-ATPase from pig kidney on a solid supported membrane (SSM). Upon adsorption, the ion pumps were activated by performing ATP concentration jumps at the surface of the SSM, and the capacitive current transients generated by Na+,K+-ATPase were measured under potentiostatic conditions. To study the behavior of the ion pump under multiple turnover conditions, ATP concentration jump experiments were carried out in the presence of Na+ and K+ ions. Current transients induced by ATP concentration jumps were also recorded in the presence of the enzyme α-chymotrypsin. The effect of acylphosphatase (AcP), a cytosolic enzyme that may affect the functioning of Na+,K+-ATPase by hydrolyzing its acylphosphorylated intermediate, was investigated by performing ATP concentration jumps both in the presence and in the absence of AcP. In the presence of Na+ but not of K+, the addition of AcP causes the charge translocated as a consequence of ATP concentration jumps to decrease by about 50% over the pH range from 6 to 7, and to increase by about 20% at pH 8. Conversely, no appreciable effect of pH upon the translocated charge is observed in the absence of AcP. The above behavior suggests that protons are involved in the AcP-catalyzed dephosphorylation of the acylphosphorylated intermediate of Na+,K+-ATPase

Modifications induced by acylphosphatase in the functional properties of heart sarcolemma Na+,K+ pump

AbstractAcylphosphatase purified from cardiac muscle actively hydrolyzes the phosphoenzyme intermediate of heart sarcolemma Na+,K+-ATPase. This effect occurred with acylphosphatase amounts (up to 800 unitsmg membrane protein) that fall within the physiological range and the low value of the apparent Km (0.69 × 10−7 M) indicates a considerable affinity of the enzyme towards this specific substrate. Acylphosphatase addition to purified sarcolemmal vesicles significantly increased the rate of Na+,K+-dependent ATP hydrolysis. Maximal stimulation, observed with 800 unitsmg protein, resulted in an ATPase activity which was about 2-fold over basal value. The same acylphosphatase amounts significantly stimulated, in a similar and to an even greater extent, the rate of ATP driven Na+ transport into sarcolemmal vesicles. These findings lead to suppose that an accelerated hydrolysis of the phosphoenzyme may result in an enhanced activity of heart sarcolemmal Na+,K+ pump, therefore suggesting a potential role of acylphosphatase in the control of this active transport system

Effects of acylphosphatase on the activity of erythrocyte memmbrane Ca2+ pump.

Acylphosphatase, purified from human erythrocytes, actively hydrolyzes the acylphosphorylated intermediate of human red blood cell membrane Ca(2+)-ATPase. This effect occurred with acylphosphatase amounts (up to 10 units/mg membrane protein) that fall within the physiological range. Furthermore, a very low Km value, 3.41 +/- 1.16 (S.E.) nM, suggests a high affinity in acylphosphatase for the phosphoenzyme intermediate, which is consistent with the small number of Ca(2+)-ATPase units in human erythrocyte membrane. Acylphosphatase addition to red cell membranes resulted in a significant increase in the rate of ATP hydrolysis. Maximal stimulation (about 2-fold over basal) was obtained at 2 units/mg membrane protein, with a concomitant decrease in apparent Km values for both Ca2+ and ATP. Conversely, similar amounts of acylphosphatase significantly decreased (by about 30%) the rate of Ca2+ transport into inside-out red cell membrane vesicles, albeit that reduced apparent Km values for Ca2+ and ATP were also observed in this case. A stoichiometry of 2.04 Ca2+/ATP hydrolyzed was calculated in the absence of acylphosphatase; in the presence of acylphosphatase optimal concentration, this ratio was reduced to 0.9. Acylphosphatase activity, rather than just protein, was essential for all the above effects. Taken together these findings suggest that, because of its hydrolytic activity on the phosphoenzyme intermediate, acylphosphatase reduces the efficiency of the erythrocyte membrane Ca2+ pump. A possible mechanism for this effect is that the phosphoenzyme is hydrolyzed before its transport work can be accomplished