12 research outputs found

    Flavonoids in prevention of diseases with respect to modulation of Ca-pump function

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    Flavonoids, natural phenolic compounds, are known as agents with strong antioxidant properties. In many diseases associated with oxidative/nitrosative stress and aging they provide multiple biological health benefits. Ca2+-ATPases belong to the main calcium regulating proteins involved in the balance of calcium homeostasis, which is impaired in oxidative/nitrosative stress and related diseases or aging. The mechanisms of Ca2+-ATPases dysfunction are discussed, focusing on cystein oxidation and tyrosine nitration. Flavonoids act not only as antioxidants but are also able to bind directly to Ca2+-ATPases, thus changing their conformation, which results in modulation of enzyme activity

    Sarcoplasmic reticulum calcium mishandling central tenet in heart failure?

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    Excitation-contraction coupling links excitation of the sarcolemmal surface membrane to mechanical contraction. In the heart this link is established via a Ca-induced Ca release process, which, following sarcolemmal depolarisation, prompts Ca release from the sarcoplasmic reticulum (SR)\ua0though the ryanodine receptor (RyR2). This substantially raises the cytoplasmic Ca concentration to trigger systole. In diastole, Ca is removed from the cytoplasm, primarily via the sarcoplasmic-endoplasmic reticulum Ca-dependent ATPase (SERCA) pump on the SR\ua0membrane, returning Ca to the SR store. Ca movement across the SR is thus fundamental to the systole/diastole cycle and plays an essential role in maintaining cardiac contractile function. Altered SR Ca homeostasis (due to disrupted Ca release, storage, and reuptake pathways) is a central tenet of heart failure and contributes to depressed contractility, impaired relaxation, and propensity to arrhythmia. This review will focus on the molecular mechanisms that underlie asynchronous Ca cycling around the SR in the failing heart. Further, this review will illustrate that the combined effects of expression changes and disruptions to RyR2 and SERCA2a regulatory pathways are critical to the pathogenesis of heart failure
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