SERCA control of cell death and survival

[Display omitted] •Changes in cellular Ca2+ dynamics contribute to the regulation of cell growth and survival.•Temporal and spatial Ca2+ signals are tightly fine-tuned by a variety of Ca2+ handling molecules, including SERCA, responsible for Ca2+ uptake.•Altered SERCA function leads to elevated cyto...

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Veröffentlicht in:Cell calcium (Edinburgh) 2018-01, Vol.69, p.46-61
Hauptverfasser: Chemaly, Elie R., Troncone, Luca, Lebeche, Djamel
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Sprache:eng
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Zusammenfassung:[Display omitted] •Changes in cellular Ca2+ dynamics contribute to the regulation of cell growth and survival.•Temporal and spatial Ca2+ signals are tightly fine-tuned by a variety of Ca2+ handling molecules, including SERCA, responsible for Ca2+ uptake.•Altered SERCA function leads to elevated cytosolic Ca2+, resulting in cellular malignancy and ER stress-associated apoptosis and organ damage.•Ca2+ homeostasis and SERCA function represent a nodal point that controls cell survival.•Pharmacological or genetic targeting of this axis constitutes a great therapeutic potential for many diseases. Intracellular calcium (Ca2+) is a critical coordinator of various aspects of cellular physiology. It is increasingly apparent that changes in cellular Ca2+ dynamics contribute to the regulation of normal and pathological signal transduction that controls cell growth and survival. Aberrant perturbations in Ca2+ homeostasis have been implicated in a range of pathological conditions, such as cardiovascular diseases, diabetes, tumorigenesis and steatosis hepatitis. Intracellular Ca2+ concentrations are therefore tightly regulated by a number of Ca2+ handling enzymes, proteins, channels and transporters located in the plasma membrane and in Ca2+ storage organelles, which work in concert to fine tune a temporally and spatially precise Ca2+ signal. Chief amongst them is the sarco/endoplasmic reticulum (SR/ER) Ca2+ ATPase pump (SERCA) which actively re-accumulates released Ca2+ back into the SR/ER, therefore maintaining Ca2+ homeostasis. There are at least 14 different SERCA isoforms encoded by three ATP2A1-3 genes whose expressions are species- and tissue-specific. Altered SERCA expression and activity results in cellular malignancy and induction of ER stress and ER stress-associated apoptosis. The role of SERCA misregulation in the control of apoptosis in various cell types and disease setting with prospective therapeutic implications is the focus of this review. Ca2+ is a double edge sword for both life as well as death, and current experimental evidence supports a model in which Ca2+ homeostasis and SERCA activity represent a nodal point that controls cell survival. Pharmacological or genetic targeting of this axis constitutes an incredible therapeutic potential to treat different diseases sharing similar biological disorders.
ISSN:0143-4160
1532-1991
DOI:10.1016/j.ceca.2017.07.001