On the mechanism of the calcium paradox: the release of hydrolytic enzymes

Abstract

Sequential perfusion of the heart with Ca²⁺-free and Ca²⁺ containing solutions leads to defects in myocytal surface membranes through which excess Ca²⁺ enters and cytosolic constituents leave the cells. During Ca²⁺-free perfusion the glycocalyx of the cells is damaged Lipoprotein lipase, bound to mucopolysaccharides on the outside of cells, is released during Ca²⁺-free perfusion. This enzyme, involved in lipoprotein triglyceride uptake into the cells, is an α-lipase. which also hydrolyzes phospholipids In addition to this phospholipase A₁ activity some phospholipase A₂ activity, due to another enzyme, is partially lost during Ca²⁺-free perfusion. The partial loss of this enzyme might be a reflection of the known increase of motional freedom of membrane phospholipids in the absence of Ca²⁺. The reintroduction of Ca²⁺ might rearrange phospholipids and activate residual phospholipase A₂ so that pores arise that allow the passage of excess amounts of Ca²⁺ There is no reason to believe that the membranes of the organelles beyond the plasmalemma contribute to the early phenomena of the calcium paradox, as no soluble enzymes, contained within these organelles, are initially released from the heart. However, the calcium overload may stimulate Ca²⁺-dependent (phospho)lipases and proteases to contribute to the irreversible loss of structure and function.