Abstract
Sarcoplasmic reticulum Ca(2+)-ATPase couples the motions and rearrangements of three cytoplasmic domains (A, P, and N) with Ca(2+) transport. We explored the role of electrostatic force in the domain dynamics in a rate-limiting phosphoenzyme (EP) transition by a systematic approach combining electrostatic screening with salts, computer analysis of electric fields in crystal structures, and mutations. Low KCl concentration activated and increasing salt above 0.1 m inhibited the EP transition. A plot of the logarithm of the transition rate versus the square of the mean activity coefficient of the protein gave a linear relationship allowing division of the activation energy into an electrostatic component and a non-electrostatic component in which the screenable electrostatic forces are shielded by salt. Results show that the structural change in the transition is sterically restricted, but that strong electrostatic forces, when K(+) is specifically bound at the P domain, come into play to accelerate the reaction. Electric field analysis revealed long-range electrostatic interactions between the N and P domains around their hinge. Mutations of the residues directly involved and other charged residues at the hinge disrupted in parallel the electric field and the structural transition. Favorable electrostatics evidently provides a low energy path for the critical N domain motion toward the P domain, overcoming steric restriction. The systematic approach employed here is, in general, a powerful tool for understanding the structural mechanisms of enzymes.
Highlights
Motions of cytoplasm domains in phosphoenzyme transition of Ca2ϩ-ATPase are critical for function
The binding of Kϩ (Naϩ) to a specific site on the P domain is known to occur below this concentration range and to accelerate E2P hydrolysis [5, 31, 32]
A critical role of electrostatic interactions in the association of barnase with its inhibitor protein barstar was demonstrated by the linear relationship that exists between the logarithm of association rate constant versus the logarithm of mean activity coefficient, log ␥Ϯ, which is directly related to “electrostatic potential” [28, 35]
Summary
Motions of cytoplasm domains in phosphoenzyme transition of Ca2ϩ-ATPase are critical for function. We explored the role of electrostatic force in the domain dynamics in a rate-limiting phosphoenzyme (EP) transition by a systematic approach combining electrostatic screening with salts, computer analysis of electric fields in crystal structures, and mutations. The enzyme is activated by the binding of two cytoplasmic Ca2ϩ ions at the high affinity transport sites (E2 to E1Ca2, step 1 in Fig. 1) and autophosphorylated at Asp351 with MgATP to form an ADP-sensitive phosphoenzyme. We reveal residues on the N and P domains generating the critical long-range electrostatic interactions and the role of Kϩ bound to the P domain of the ATPase for inducing the proper and efficient structural change. The approach may be usefully applied to elucidating electrostatics influences on structural transitions in other enzymes
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