The Ca2+-ATPase Isoforms of Platelets Are Located in Distinct Functional Ca2+ Pools and Are Uncoupled by a Mechanism Different from That of Skeletal Muscle Ca2+-ATPase

Simone Engelender,Herman Wolosker,Leopoldo De Meis

doi:10.1074/jbc.270.36.21050

Simone Engelender, Herman Wolosker + Show 1 more

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https://doi.org/10.1074/jbc.270.36.21050

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Abstract

Vesicles derived from the dense tubular system of platelets possess a Ca(2+)-ATPase that can use either ATP or acetyl phosphate as a substrate. In the presence of phosphate as a precipitating anion, the maximum amount of Ca2+ accumulated by the vesicles with the use of acetyl phosphate was only one-third of that accumulated with the use of ATP. Vesicles derived from the sarcoplasmic reticulum of skeletal muscle accumulated equal amounts of Ca2+ regardless of the substrate used. When acetyl phosphate was used in platelet vesicles, the transport of Ca2+ was inhibited by Na+, Li+, and K+; in sarcoplasmic reticulum vesicles, only Na+ caused inhibition. When ATP was used as substrate, the different monovalent cation had no effect on either sarcoplasmic reticulum or platelet vesicles. The catalytic cycle of the Ca(2+)-ATPase is reversed when a Ca2+ gradient is formed across the vesicle membrane. The stoichiometry between active Ca2+ efflux and ATP synthesis was one in platelet vesicles and two in sarcoplasmic reticulum vesicles. The coupling between ATP synthesis and Ca2+ efflux in sarcoplasmic reticulum vesicles was abolished by arsenate regardless of whether the vesicles were loaded with Ca2+ using acetyl phosphate or ATP. In platelets, uncoupling was observed only when the vesicles were loaded using acetyl phosphate. In both sarcoplasmic reticulum and platelet vesicles, the effect of arsenate was antagonized by thapsigargin (2 microM), micromolar Ca2+ concentrations, P(i) (5-20 mM), and MgATP (10-100 microM). Trifluoperazine also uncoupled the platelet Ca2+ pump but, different from arsenate, this drug was effective in vesicles that were loaded using either ATP or acetyl phosphate. Trifluoperazine enhanced Ca2+ efflux from both sarcoplasmic reticulum and platelet vesicles; thapsigargin, Ca2+, Mg2+, or K+ antagonized this effect in sarcoplasmic reticulum but not in platelet vesicles. The data indicate that the Ca(2+)-transport isoforms found in sarcoplasmic reticulum and in platelets have different kinetic properties.

Highlights

When acetyl phosphate was used in platelet vesicles, the transport of Ca2؉ was inhibited by Na؉, Li؉, and K؉; in sarcoplasmic reticulum vesicles, only Na؉ caused inhibition
We found that vesicles prepared from platelets can use acetyl phosphate and ITP as substrate, but different from the muscle Ca2ϩ-ATPase, the maximum level of Ca2ϩ accumulated with these substrates was 2–3-fold smaller than that measured with ATP (Fig. 1A)
The present study shows kinetic differences between the Ca2ϩ-ATPase isoforms of skeletal muscle and platelets

Summary

Introduction

When acetyl phosphate was used in platelet vesicles, the transport of Ca2؉ was inhibited by Na؉, Li؉, and K؉; in sarcoplasmic reticulum vesicles, only Na؉ caused inhibition. When ATP was used as substrate, the different monovalent cation had no effect on either sarcoplasmic reticulum or platelet vesicles. The stoichiometry between active Ca2؉ efflux and ATP synthesis was one in platelet vesicles and two in sarcoplasmic reticulum vesicles. The coupling between ATP synthesis and Ca2؉ efflux in sarcoplasmic reticulum vesicles was abolished by arsenate regardless of whether the vesicles were loaded with Ca2؉ using acetyl phosphate or ATP. In platelets, uncoupling was observed only when the vesicles were loaded using acetyl phosphate In both sarcoplasmic reticulum and platelet vesicles, the effect of arsenate was antagonized by thapsigargin (2 ␮M), micromolar Ca2؉ concentrations, Pi (5–20 mM), and MgATP (10 –100 ␮M). Trifluoperazine uncoupled the platelet Ca2؉ pump but, different from arsenate, this drug was effective in vesicles that were loaded using either ATP or acetyl phosphate. SERCA2a is expressed in cardiac and slow skeletal muscle [2], while SERCA2b is expressed in smooth muscle and represents a generic “endoplasmic reticulum” form that, together with SERCA3, is found in several non-muscle cells [3, 4]

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