Ordered and cooperative binding of opposing globular domains of calmodulin to the plasma membrane Ca-ATPase

We have investigated the mechanisms of activation of the plasma membrane (PM) Ca-ATPase by calmodulin (CaM), which result in enhanced calcium transport rates and the maintenance of low intracellular calcium levels. We have isolated the amino- or carboxyl-terminal domains of CaM (i.e. CaMN or CaMC), permitting an identification of their relative specificity for binding to sites on either the PM Ca-ATPase or a peptide (C28W) corresponding to the CaM-binding sequence. We find that either CaMN or CaMC alone is capable of productive interactions with the PM Ca-ATPase that induces enzyme activation. There are, however, large differences in the affinity and specificity of binding between CaMN and CaMC and either C28W or the PM Ca-ATPase. The initial binding interaction between CaMC and the PM Ca-ATPase is highly specific, having approximately 10,000-fold greater affinity in comparison with CaMN. However, following the initial association of either CaMC or CaMN, there is a 300-fold enhancement in the affinity of CaMN for the secondary binding site. Thus, while CaMC binds with a high affinity to the two CaM-binding sites within the PM Ca-ATPase in a sequential manner, CaMN binds cooperatively with a lower affinity to both binding sites. These large differences in the binding affinities and specificities of the amino- and carboxyl-terminal domains ensure that CaM binding to the PM Ca-ATPase normally involves the formation of a specific complex in which the initial high affinity association of the carboxyl-terminal domain promotes the association of the amino-terminal domain necessary for enzyme activation.