Detailed Characterization of the Cooperative Mechanism of Ca<sup>2+</sup> Binding and Catalytic Activation in the Ca<sup>2+</sup> Transport (SERCA) ATPase

Zhang, Zhongsen; Lewis, David E.; Strock, Christopher J.; Inesi, Giuseppe; Nakasako, Masayoshi; Nomura, Hiromi; Toyoshima, Chikashi

doi:10.1021/bi000185m

Cited by 101 publications

(118 citation statements)

References 42 publications

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“…Similar results were obtained when the ATPase activity of the purified and reconstituted proteins was assayed with strontium (45,46), as displayed in the inset of (Fig. 2B) confirm the limited effect of the ADA mutation on the K m for Ca 2ϩ previously described by Zhang et al (22) for ATPases expressed in COS cells membranes. Conversely, the poor sensitivity to Ca 2ϩ of the hydrolytic activity of the ADA mutant in the presence of detergent, shown in Fig.…”

Section: Purification and Reconstitution Of Wild-type (Wt) And D813asupporting

confidence: 88%

“…At that time, as we were working with yeast microsomal membranes, we found it necessary to add a solubilizing concentration of C 12 E 8 to the medium during the activity measurements, to suppress the nonspecific hydrolytic activity arising from other proteins present in yeast membranes (this nonspecific activity was making it difficult to unambiguously attribute the small Ca 2ϩ dependent activity, amounting to about 2% of the total activity in the absence of detergent, to expressed SERCA1a). The same ADA mutant enzyme, expressed in COS cells was, however, later reported by Zhang et al (22) to display significant Ca 2ϩ -dependent ATPase activity, up to about 30% of that of the WT enzyme, a level of activity that was detected without any detergent added to the medium (Fig. 4D in Ref.…”

Section: Discussionsupporting

confidence: 58%

“…Limited Activation of ADA ATPase at Low ATP Concentration-To understand the puzzling discrepancy between the full ATPase activity of the detergent-free ADA mutant and its previously demonstrated (20,22,24) reduced ability for phosphorylation from ATP, we then reinvestigated the ability of the purified and reconstituted ATPases to become phosphorylated from ATP at various calcium concentrations, using an ATP concentration (2 M) low enough to minimize background noise. Panels A and B in Fig.…”

Section: True Equilibrium Affinity For Ca 2ϩ (Or Sr 2ϩ ) Of Unphosphomentioning

confidence: 99%

“…The reduction of the cation binding ability of the Ca 2ϩ -ATPase L6 -7 loop after mutation was confirmed by studying a chemically synthesized peptide corresponding to the L6 -7 loop, Gly 808 -Pro 827 , which was found to interact with calcium and to bind lanthanum, in contrast with a related peptide in which an AAA cluster mutation had been introduced (21). In another laboratory both the ADA ATPase mutant and a more conservative related one, D813N,D818N, were found to bind less 45 Ca 2ϩ than WT in the presence of a micromolar Ca 2ϩ concentration (22). The L6 -7 loop was thus suggested to provide an entrance port for calcium, with the negatively charged aspartic residues involved in a pre-binding site (21), and recent computer simulations accepted this view (23).…”

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Involvement of the L6–7 Loop in SERCA1a Ca2+-ATPase Activation by Ca2+ (or Sr2+) and ATP

Lenoir

Picard

Møller

et al. 2004

Journal of Biological Chemistry

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Wild-type (WT) and the double mutant D813A,D818A (ADA) of the L6 -7 loop of SERCA1a were expressed in yeast, purified, and reconstituted into lipids. This allowed us to functionally study these ATPases by both kinetic and spectroscopic means, and to solve previous discrepancies in the published literature about both experimental facts and interpretation concerning the role of this loop in P-type ATPases. We show that in a solubilized state, the ADA mutant experiences a dramatic decrease of its calcium-dependent ATPase activity. On the contrary, reconstituted in a lipid environment, it displays an almost unaltered maximal calcium-dependent ATPase activity at high (millimolar) ATP, with an apparent affinity for Ca 2؉ altered only moderately (3-fold). In the absence of ATP, the true affinity of ADA for Ca 2؉ is, however, more significantly reduced (20 -30-fold) compared with WT, as judged from intrinsic (Trp) or extrinsic (fluorescence isothiocyanate) fluorescence experiments. At low ATP, transient kinetics experiments reveal an overshoot in the ADA phosphorylation level primarily arising from the slowing down of the transition between the nonphosphorylated "E2" and "Ca 2 E1" forms of ADA. At high ATP, this slowing down is only partially compensated for, as ADA turnover remains more sensitive to orthovanadate than WT turnover. ADA ATPase also proved to have a reduced affinity for ATP in studies performed under equilibrium conditions in the absence of Ca 2؉ , highlighting the long range interactions between L6 -7 and the nucleotide-binding site. We propose that these mutations in L6 -7 could affect protonation-dependent winding and unwinding events in the nearby M6 transmembrane segment.Muscle relaxation occurs by of the removal of calcium from the cytosol and its accumulation into sarcoplasmic reticulum (SR) 1 through an active transport that consumes ATP (1, 2). In fast twitch muscle this transport is achieved by the SERCA1a isoform of Ca 2ϩ -ATPase (3), with a stoichiometry of two calcium ions transported per ATP molecule hydrolyzed (see reviews in Refs. 4 and 5). SR Ca 2ϩ -ATPase belongs to the family of P-type ATPases, which transport cations such as H ϩ , Na ϩ , K ϩ , or Ca 2ϩ across the membrane and share a common mechanism that involves autophosphorylation of the protein (see review in Ref. 6): transport is achieved through a reversible cycle, during which the ATPase is thought to sequentially adopt two main conformations (7, 8), E1 and E2, with a high and low affinity for the transported ion, and the overall cycle corresponds to completion of the following scheme: E2 3 Ca 2 E1 3 Ca 2 E1 ϳ P 3 E2P 3 E2 (for review, see Refs. 9 and 10). Much effort has gone into determining the structural organization of SR Ca 2ϩ -ATPase from primary structure predictions (11), electron microscopy (12), and three-dimensional crystallogenesis (13-15) (for a recent review see Ref. 16). Finally, the structure has been solved at the atomic level, first in a Ca 2 E1 state (14) and then in a thapsigargin-stabilized E2 state (15). T...

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Section: Purification and Reconstitution Of Wild-type (Wt) And D813asupporting

confidence: 88%

Section: Discussionsupporting

confidence: 58%

Section: True Equilibrium Affinity For Ca 2ϩ (Or Sr 2ϩ ) Of Unphosphomentioning

confidence: 99%

mentioning

confidence: 99%

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Involvement of the L6–7 Loop in SERCA1a Ca2+-ATPase Activation by Ca2+ (or Sr2+) and ATP

Lenoir

Picard

Møller

et al. 2004

Journal of Biological Chemistry

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“…Recombinant Ca 2+ ATPase was obtained from COS-1 cells infected with adenovirus vectors carrying chicken WT (33) or mutant cDNA (34). ATP and ADP binding was measured by a filtration method (35)(36)(37) For each experimental sample, 3 ml of ice cold medium were added by fast mixing to 0.3 ml medium containing 0.4 mg SR protein, and filtered after 10 seconds through a 0.65 μm Millipore filter.…”

Section: Methodsmentioning

confidence: 99%

Concerted Conformational Effects of Ca²⁺and ATP Are Required for Activation of Sequential Reactions in the Ca²⁺ATPase (SERCA) Catalytic Cycle^,

Inesi

Lewis

et al. 2006

Biochemistry

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We relate solution behavior to the crystal structure of the Ca 2+ ATPase (SERCA). We find that nucleotide binding occurs with high affinity through interaction of the adenosine moiety with the N domain, even in the absence of Ca 2+ and Mg 2+ , or to the closed conformation stabilized by thapsigargin (TG). Why then is Ca 2+ crucial for ATP utilization? The influence of AMPPCP, Ca 2+ and Mg 2+ on proteolytic digestion patterns, interpreted in the light of known crystal structures, indicates that a Ca 2+ dependent conformation of the ATPase headpiece is required for a further transition induced by nucleotide binding. This includes opening of the headpiece, which in turn allows inclination of the "A" domain and bending of the "P" domain. Thereby, the phosphate chain of bound ATP acquires an extended configuration allowing the γ-phosphate to reach Asp351 to form a complex including Mg 2+ . We demonstrate by Asp351 mutation that this "productive" conformation of the substrate-enzyme complex is unstable due to electrostatic repulsion at the phosphorylation site. However, this conformation is subsequently stabilized by covalent engagement of the γ-phosphate yielding the phosphoenzyme intermediate. We also demonstrate that the ADP product remains bound with high affinity to the transition state complex, but dissociates with lower affinity as the phosphoenzyme undergoes a further conformational change (i.e., E1P to E2-P transition). Finally, we measured low affinity ATP binding to stable phosphoenzyme analogs, demonstrating that the E1-P to E2-P transition and the enzyme turnover are accelerated by ATP binding to the phosphoenzyme in exchange for ADP.The Ca 2+ ATPase of Sarco-Endoplasmic Reticulum (SERCA) is a membrane bound enzyme that uses ATP as an energy source for Ca 2+ transport. The 100 kD ATPase protein includes ten helical segments partitioned within the membrane bilayer, and a headpiece protruding from the cytosolic membrane surface (1,2). Binding of 2 Ca 2+ is required for enzyme (E) activation, whereby the ATP terminal phosphate is utilized to form a phosphorylated enzyme intermediate (E-P). The bound Ca 2+ then undergoes occlusion and vectorial translocation. The catalytic cycle is completed by hydrolytic cleavage of E-P (3-5)

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Calcium Pump ( ATPase ) of Sarcoplasmic Reticulum

Toyoshima¹

2004

Handbook of Metalloproteins

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Ca 2+ ‐ATPase of sarcoplasmic reticulum is a membrane protein of 110 kDa and pumps Ca 2+ from the cytoplasm into the sarcoplasmic reticulum, an intracellular organelle, to relax muscle cells. Two Ca 2+ ions can be transported per ATP hydrolyzed and two or three protons are countertransported. The Ca 2+ ‐binding sites are located side by side in the transmembrane region. The crystal structures of this ATPase obtained for Ca 2+ ‐bound and unbound states show that large conformation changes take place during Ca 2+ binding and dissociation.

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Detailed Characterization of the Cooperative Mechanism of Ca²⁺ Binding and Catalytic Activation in the Ca²⁺ Transport (SERCA) ATPase

Cited by 101 publications

References 42 publications

Involvement of the L6–7 Loop in SERCA1a Ca2+-ATPase Activation by Ca2+ (or Sr2+) and ATP

Involvement of the L6–7 Loop in SERCA1a Ca2+-ATPase Activation by Ca2+ (or Sr2+) and ATP

Concerted Conformational Effects of Ca²⁺and ATP Are Required for Activation of Sequential Reactions in the Ca²⁺ATPase (SERCA) Catalytic Cycle^,

Calcium Pump ( ATPase ) of Sarcoplasmic Reticulum

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Detailed Characterization of the Cooperative Mechanism of Ca2+ Binding and Catalytic Activation in the Ca2+ Transport (SERCA) ATPase

Cited by 101 publications

References 42 publications

Involvement of the L6–7 Loop in SERCA1a Ca2+-ATPase Activation by Ca2+ (or Sr2+) and ATP

Involvement of the L6–7 Loop in SERCA1a Ca2+-ATPase Activation by Ca2+ (or Sr2+) and ATP

Concerted Conformational Effects of Ca2+and ATP Are Required for Activation of Sequential Reactions in the Ca2+ATPase (SERCA) Catalytic Cycle,

Calcium Pump ( ATPase ) of Sarcoplasmic Reticulum

Contact Info

Product

Resources

About

Detailed Characterization of the Cooperative Mechanism of Ca²⁺ Binding and Catalytic Activation in the Ca²⁺ Transport (SERCA) ATPase

Concerted Conformational Effects of Ca²⁺and ATP Are Required for Activation of Sequential Reactions in the Ca²⁺ATPase (SERCA) Catalytic Cycle^,