Abstract
Glu309, Glu771, Asn796, Thr799, Asp800, and Glu908 (ligands 1 to 6, respectively) appear to form the high affinity Ca2(+)-binding sites of the Ca2(+)-ATPase. The plasticity of the Ca2(+)-binding sites was tested by separate replacement of each of the ligands with a structurally similar oxygen-containing residue using site-specific mutagenesis. Mutant cDNAs were transfected into COS-1 cells, and ATP-dependent Ca2+ transport or partial reactions were studied in microsomes containing the expressed Ca2(+)-ATPases. In most cases where amino acid substitutions were carried out, the expressed enzymes lacked Ca2+ transport function and Ca2(+)-dependent phosphorylation by ATP. Furthermore, the mutant enzymes were phosphorylated by inorganic phosphate, even in the presence of Ca2+, which inhibits phosphorylation of the wild-type enzyme possessing intact Ca2(+)-binding sites. On mutant, however, containing an isosteric replacement of Glu by Gln at ligand 6, exhibited wild-type levels of Ca2+ transport activity and Ca2+ affinity. Two mutants exhibited properties consistent with a reduction in Ca2+ affinity. In the mutant in which Thr was replaced by Ser at ligand 4, Ca2+ transport activity was 70% of wild-type, while half-maximal activation by Ca2+ occurred at 0.8 microM as compared to 0.3 microM for the wild-type enzyme. In the mutant Glu309----Asp at ligand 1, Ca2+ transport activity was lost, but Ca2(+)-activated phosphorylation by ATP was retained. The concentration of Ca2+ required to activate phosphorylation was increased about 10-fold, however, compared to wild type. These results support our hypothesis that ligands 1 to 6, believed to reside within the transmembrane domain, interact with Ca2+ ions during the transport process. The roles of 12 other oxygen-containing residues and of His278 located in the transmembrane domain were also examined by mutation. Although the oxygen-containing side chains of these residues are potential Ca2+ ligands, their replacement with nonpolar amino acids did not abolish Ca2+ transport function, leading to the conclusion that they are not essential ligands for high affinity Ca2+ binding by the Ca2+ pump.
Highlights
Functional Consequences of Alterations to Polar Amino Acids Located in the Transmembrane Domain of the Ca2’-ATPase of Sarcoplasmic Reticulum*
Ca*+-ATPase, we proposed that the high affinity Ca*+-binding sites were located within the negatively charged stalk domain
Phosphorylation of each of the mutant enzymes with inorganic phosphate (Pi) was observed, even in the presence of Ca*+, which inhibits phosphorylation in the wild-type enzyme possessing an intact high affinity Ca2+-binding site. These results suggest that these six crucial polar groups, lying near the center of the transmembrane domain, provide ligands for one or both of the two high affinity Ca*+-binding sites in the Ca*‘-ATPase
Summary
Ca*+-ATPase, we proposed that the high affinity Ca*+-binding sites were located within the negatively charged stalk domain. When acidic or polar amino acids located in the transmembrane domain were replaced with neutral or nonpolar counterparts, mutations. Phosphorylation of each of the mutant enzymes with inorganic phosphate (Pi) was observed, even in the presence of Ca*+, which inhibits phosphorylation in the wild-type enzyme possessing an intact high affinity Ca2+-binding site. These results suggest that these six crucial polar groups, lying near the center of the transmembrane domain, provide ligands for one or both of the two high affinity Ca*+-binding sites in the Ca*‘-ATPase. We substituted 13 other polar amino acids located in the transmembrane domain with nonpolar counterparts, but found no substantial effects on Ca*+ binding or Ca2+ transport
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