Proteolytic studies on the transduction mechanism of sarcoplasmic reticulum Ca2+-ATPase: common features with other P-type ATPases.

After proteinase K-induced excision of five amino acid residues in the semiconserved polypeptide chain linking the end of the A domain with the S3/M3 transmembrane segment we find that Ca(2+) transport is blocked while partial reactions like Ca(2+) binding, ATP phosphorylation, and Ca(2+)-occlusion are left intact. However, formation of the so-called E2P state (either from the phosphorylated species formed in the presence of ATP and Ca(2+) or from the Ca(2+)-depleted unphosphorylated species) is blocked. We conclude that the proteinase K-treated ATPase, while maintaining many of the partial reactions, is incapable of energy transduction because of the absence of an E2P state with Ca(2+) binding sites exposed to the intravesicular space. Sequence comparisons and mutagenesis data point to an important role in energy transduction of P-type ATPases of a conserved motif located at the end of the A domain.

Calcium transport by sarcoplasmic reticulum Ca(2+)-ATPase. Role of the A domain and its C-terminal link with the transmembrane region.

After treatment of sarcoplasmic reticulum Ca(2+)-ATPase with proteinase K (PK) in the presence of Ca(2+) and a protecting non-phosphorylated ligand (e.g. adenosine 5'-(beta,gamma-methylenetriphosphate), we were able to prepare in high yield an ATPase species that only differs from intact ATPase because of excision of the MAATE(243) sequence from the loop linking the A domain with the third transmembrane segment. The PK-treated ATPase was unable to transport Ca(2+) and to catalyze ATP hydrolysis, but it could bind two calcium ions with high affinity and react with ATP to form a classical ADP-sensitive phosphoenzyme, Ca(2)E1P, with occluded Ca(2+). The ability of Ca(2)E1P to become converted to the Ca(2+)-free ADP-insensitive form, E2P, was strongly reduced, as was the ability of PK-treated ATPase to react with orthovanadate or to form an E2P intermediate from inorganic phosphate in the absence of Ca(2+). PK-treated ATPase also reacted with thapsigargin to form a complex with altered properties, and the tryptic cleavage "T2" site in the A domain was no longer protected in the absence of Ca(2+). It is probable that disrupting the C-terminal link of the A domain with the transmembrane region severely compromises reorientation of A and P domains and the functionally critical cross-talk of these domains with the membrane-bound Ca(2+) ions.

Involvement of the cytoplasmic loop L6-7 in the entry mechanism for transport of Ca2+ through the sarcoplasmic reticulum Ca2+-ATPase.

We previously found that mutants of conserved aspartate residues of sarcoplasmic reticulum Ca(2+)-ATPase in the cytosolic loop, connecting transmembrane segments M6 and M7 (L6-7 loop), exhibit a strongly reduced sensitivity toward Ca(2+) activation of the transport process. In this study, yeast membranes, expressing wild type and mutant Ca(2+)-ATPases, were reacted with Cr small middle dotATP and tested for their ability to occlude (45)Ca(2+) by HPLC analysis, after cation resin and C(12)E(8) treatment. We found that the D813A/D818A mutant that displays markedly low calcium affinity was capable of occluding Ca(2+) to the same extent as wild type ATPase. Using NMR and mass spectrometry we have analyzed the conformational properties of the synthetic L6-7 loop and demonstrated the formation of specific 1:1 cation complexes of the peptide with calcium and lanthanum. All three aspartate Asp(813)/Asp(815)/Asp(818) were required to coordinate the trivalent lanthanide ion. Overall these observations suggest a dual function of the loop: in addition to mediating contact between the intramembranous Ca(2+)-binding sites and the cytosolic phosphorylation site (Zhang, Z., Lewis, D., Sumbilla, C., Inesi G., and Toyoshima, C. (2001) J. Biol. Chem. 276, 15232-15239), the L6-7 loop, in a preceding step, participates in the formation of an entrance port, before subsequent high affinity binding of Ca(2+) inside the membrane.