Deconstructing calsequestrin. Complex buffering in the calcium store of skeletal muscle

AUTOR(ES)

Royer, Leandro

FONTE

Blackwell Science Inc

RESUMO

Since its discovery in 1971, calsequestrin has been recognized as the main Ca2+ binding protein inside the sarcoplasmic reticulum (SR), the organelle that stores and upon demand mobilizes Ca2+ for contractile activation of muscle. This article reviews the potential roles of calsequestrin in excitation–contraction coupling of skeletal muscle. It first considers the quantitative demands for a structure that binds Ca2+ inside the SR in view of the amounts of the ion that must be mobilized to elicit muscle contraction. It briefly discusses existing evidence, largely gathered in cardiac muscle, of two roles for calsequestrin: as Ca2+ reservoir and as modulator of the activity of Ca2+ release channels, and then considers the results of an incipient body of work that manipulates the cellular endowment of calsequestrin. The observations include evidence that both the Ca2+ buffering capacity of calsequestrin in solution and that of the SR in intact cells decay as the free Ca2+ concentration is lowered. Together with puzzling observations of increase of Ca2+ inside the SR, in cells or vesicular fractions, upon activation of Ca2+ release, this is interpreted as evidence that the Ca2+ buffering in the SR is non-linear, and is optimized for support of Ca2+ release at the physiological levels of SR Ca2+ concentration. Such non-linearity of buffering is qualitatively explained by a speculation that puts together ideas first proposed by others. The speculation pictures calsequestrin polymers as ‘wires’ that both bind Ca2+ and efficiently deliver it near the release channels. In spite of the kinetic changes, the functional studies reveal that cells devoid of calsequestrin are still capable of releasing large amounts of Ca2+ into the myoplasm, consistent with the long term viability and apparent good health of mice engineered for calsequestrin ablation. The experiments therefore suggest that other molecules are capable of providing sites for reversible binding of large amounts of Ca2+ inside the sarcoplasmic reticulum.

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