Abstract
To study domain organization and movements in the reaction cycle of heavy metal ion pumps, CopA, a bacterial Cu+-ATPase from Thermotoga maritima was cloned, overexpressed, and purified, and then subjected to limited proteolysis using papain. Stable analogs of intermediate states were generated using AMPPCP as a nonhydrolyzable ATP analog and AlFx as a phosphate analog, following conditions established for Ca2+-ATPase (SERCA1). Characteristic digestion patterns obtained for different analog intermediates show that CopA undergoes domain rearrangements very similar to those of SERCA1. Digestion sites were identified on the loops connecting the A-domain and the transmembrane helices M2 and M3 as well as on that connecting the N-terminal metal binding domain (NMBD) and the first transmembrane helix, Ma. These digestion sites were protected in the E1P.ADP and E2P analogs, whereas the M2-A-domain loop was cleaved specifically in the absence of ions to be transported, just as in SERCA1. ATPase activity was lost when the link between the NMBD and the transmembrane domain was cleaved, indicating that the NMBD plays a critical role in ATP hydrolysis in T. maritima CopA. The change in susceptibility of the loop between the NMBD and Ma helix provides evidence that the NMBD is associated to the A-domain and recruited into domain rearrangements and that the Ma helix is the counterpart of the M1 helix in SERCA1 and Mb and Mc are uniquely inserted before M2.
Highlights
To study domain organization and movements in the reaction cycle of heavy metal ion pumps, CopA, a bacterial Cu؉-ATPase from Thermotoga maritima was cloned, overexpressed, and purified, and subjected to limited proteolysis using papain
The results show that the cytoplasmic domains of CopA undergo rearrangements quite similar to those observed with SERCA1 and that the N-terminal metal binding domain (NMBD) plays an important role in ATP hydrolysis, and participates in domain rearrangements during the reaction cycle
Our results indicate that CopA from T. maritima, a bacterial Cuϩ transporting ATPase, contains 3 papain cleavage sites on the C-terminal side of the NMBD
Summary
It is clear that PIB-type ATPases comprise 3 cytoplasmic domains and their core structures are very similar to those of SERCA1 [13, 14], there are significant differences in the regions seemingly important for domain interaction [14]. In contrast to PII-ATPases that have 10 transmembrane helices, PIB-ATPases contain only 8: the 4th to 8th bear similarity to M2 to M6 of the PII-type ATPases [2], whereas the 1st to 3rd are specific (referred to as Ma-Mc here). Given these differences in structure, the ion-translocation mechanism might be different.
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