ATP Binding Equilibria of the Na+,K+-ATPase

Pilotelle-Bunner, Anne; Matthews, Jacqueline M.; Cornelius, Flemming; Apell, Hans-Jürgen; Sebban, Pierre; Clarke, Ronald J.

ATP Binding Equilibria of the Na+,K+-ATPase

Dateien

Biochem_47_13103.pdfGröße: 367.49 KBDownloads: 957

Datum

2008

Autor:innen

Pilotelle-Bunner, Anne

Matthews, Jacqueline M.

Cornelius, Flemming

Apell, Hans-Jürgen

Sebban, Pierre

Clarke, Ronald J.

Open Access-Veröffentlichung

Open Access Green

Sammlungen

Biologie

Publikationstyp

Zeitschriftenartikel

Publikationsstatus

Published

Erschienen in

Biochemistry. 2008, 47(49), pp. 13103-13114. ISSN 0006-2960. eISSN 1520-4995. Available under: doi: 10.1021/bi801593g

Zusammenfassung

Reported values of the dissociation constant, Kd, of ATP with the E1 conformation of the Na+,K+-ATPase fall in two distinct ranges depending on how it is measured. Equilibrium binding studies yield values of 0.1-0.6 μM, whereas presteady-state kinetic studies yield values of 3-14 μM. It is unacceptable that Kd varies with the experimental method of its determination. Using simulations of the expected equilibrium behavior for different binding models based on thermodynamic data obtained from isothermal titration calorimetry we show that this apparent discrepancy can be explained in part by the presence in presteady-state kinetic studies of excess Mg2+ ions, which compete with the enzyme for the available ATP. Another important contributing factor is an inaccurate assumption in the majority of presteady-state kinetic studies of a rapid relaxation of the ATP binding reaction on the time scale of the subsequent phosphorylation. However, these two factors alone are insufficient to explain the previously observed presteady-state kinetic behavior. In addition one must assume that there are two E1-ATP binding equilibria. Because crystal structures of P-type ATPases indicate only a single bound ATP per R-subunit, the only explanation consistent with both crystal structural and kinetic data is that the enzyme exists as an (αβ)2 diprotomer, with protein-protein interactions between adjacent R-subunits producing two ATP affinities. We propose that in equilibrium measurements the measured Kd is due to binding of ATP to one R-subunit, whereas in presteadystate kinetic studies, the measured apparent Kd is due to the binding of ATP to both R-subunits within the diprotomer.

Fachgebiet (DDC)

570 Biowissenschaften, Biologie

Zitieren

ISO 690

PILOTELLE-BUNNER, Anne, Jacqueline M. MATTHEWS, Flemming CORNELIUS, Hans-Jürgen APELL, Pierre SEBBAN, Ronald J. CLARKE, 2008. ATP Binding Equilibria of the Na+,K+-ATPase. In: Biochemistry. 2008, 47(49), pp. 13103-13114. ISSN 0006-2960. eISSN 1520-4995. Available under: doi: 10.1021/bi801593g

BibTex

@article{PilotelleBunner2008Bindi-6602,
  year={2008},
  doi={10.1021/bi801593g},
  title={ATP Binding Equilibria of the Na+,K+-ATPase},
  number={49},
  volume={47},
  issn={0006-2960},
  journal={Biochemistry},
  pages={13103--13114},
  author={Pilotelle-Bunner, Anne and Matthews, Jacqueline M. and Cornelius, Flemming and Apell, Hans-Jürgen and Sebban, Pierre and Clarke, Ronald J.}
}

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    <dcterms:abstract xml:lang="eng">Reported values of the dissociation constant, Kd, of ATP with the E1 conformation of the Na+,K+-ATPase fall in two distinct ranges depending on how it is measured. Equilibrium binding studies yield values of 0.1-0.6 μM, whereas presteady-state kinetic studies yield values of 3-14 μM. It is unacceptable that Kd varies with the experimental method of its determination. Using simulations of the expected equilibrium behavior for different binding models based on thermodynamic data obtained from isothermal titration calorimetry we show that this apparent discrepancy can be explained in part by the presence in presteady-state kinetic studies of excess Mg2+ ions, which compete with the enzyme for the available ATP. Another important contributing factor is an inaccurate assumption in the majority of presteady-state kinetic studies of a rapid relaxation of the ATP binding reaction on the time scale of the subsequent phosphorylation. However, these two factors alone are insufficient to explain the previously observed presteady-state kinetic behavior. In addition one must assume that there are two E1-ATP binding equilibria. Because crystal structures of P-type ATPases indicate only a single bound ATP per R-subunit, the only explanation consistent with both crystal structural and kinetic data is that the enzyme exists as an (αβ)2 diprotomer, with protein-protein interactions between adjacent R-subunits producing two ATP affinities. We propose that in equilibrium measurements the measured Kd is due to binding of ATP to one R-subunit, whereas in presteadystate kinetic studies, the measured apparent Kd is due to the binding of ATP to both R-subunits within the diprotomer.</dcterms:abstract>
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Universitätsbibliographie

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