Active/Inactive state transitions of the chloroplast F1 ATPase are induced by a slow binding and release of Mg2+. Relationship to catalysis and control of F1 ATPases.

K J Guerrero,Z X Xue,P D Boyer

doi:10.1016/s0021-9258(17)46219-3

K J Guerrero, Z X Xue + Show 1 more

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https://doi.org/10.1016/s0021-9258(17)46219-3

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Abstract

Mg2+ is known to be a potent inhibitor of F1 ATPases from various sources. Such inhibition requires the presence of a tightly bound ADP at a catalytic site. Results with the spinach chloroplast F1 ATPase (CF1) show that the time delays of up to 1 min or more in the induction or the relief of the inhibition are best explained by a slow binding and slow release of Mg2+ rather than by slow enzyme conformational changes. CF1 is known to have multiple Mg2+ binding sites with Kd values in the micromolar range. The inhibitory Mg2+ and ADP can bind independently to CF1. When Mg2+ and ATP are added to the uninhibited enzyme, a relatively fast rate of hydrolysis attained soon after the addition is followed by a much slower steady-state rate. The inhibited steady-state rate results from a slowly attained equilibrium of binding of medium Mg2+. The Kd for the binding of the inhibitory Mg2+ is in the range of 1-8 microM, in the presence or absence of added ATP, as based on the extent of rate inhibition induced by Mg2+. Assessments from 18O exchange experiments show that the binding of Mg2+ is accompanied by a relatively rapid change to an enzyme form that is incapable of hydrolyzing MgATP. When ATP is added to the Mg2+- and ADP-inhibited enzyme, the resulting reactivation can be explained by MgATP binding to an alternate catalytic site which results in a displacement of the tightly bound ADP after a slow release of Mg2+. Both an increase in temperature (to 50 degrees C) and the presence of activating anions such as bicarbonate or sulfite reduce the extent of the Mg2+ inhibition markedly. The activating anions may bind to CF1 in place of Pi near the ADP. Whether the inhibitory Mg2+ binds at catalytic or noncatalytic nucleotide binding sites or at another location is not known. The Mg2(+)- and ADP-induced inhibition appears to be a general property of F1 ATPases, which show considerable differences in affinity for ADP, Mg2+, and Pi. These differences may reflect physiological control functions.

Highlights

Assessments from “0 exchange experiments show that the binding of Mg2+ is accompanied by a relatively rapid change to an enzyme form that is incapable of hydrolyzing MgATP
The results show that Mg” does not require either the presence of medium ATP or ADP or the occurrence of catalysis to be able to bind to ATP-heat-activated chloroplast F1 ATPase (CF1) and to effect the changes required for the transition to the inactive enzyme
The Time Delays for Inhibition and Reactivation of CF, MgATP Hydrolysis Can Be Explained by the Slow Binding and Slow Release of Inhibitory Mp-The results show that the time course of the inhibition of MgATP hydrolysis observed with ATP-heat-activated CFi is strongly dependent on the free Mg2+ concentration

Summary

Introduction

When CFi was exposed to 50 PM Mp in the presence or absence of 60 mM bicarbonate prior to dilution and testing of MgATP hydrolysis, no change was observed in either the time course or the final degree of the inhibition (data not shown). The Time Delays for Inhibition and Reactivation of CF, MgATP Hydrolysis Can Be Explained by the Slow Binding and Slow Release of Inhibitory Mp-The results show that the time course of the inhibition of MgATP hydrolysis observed with ATP-heat-activated CFi is strongly dependent on the free Mg2+ concentration.

Results

Conclusion