Abstract
1. Monovalent-cation [(CH3)4N+, K(I), Na(I)] ATP, 1 mM in nucleotide, in aqueous solutions at pH 7.2, 24 degrees C, generates 2 different 31P NMR spectra, depending upon the salt content of the solution. At salt concentrations below 10 mM, the 31P NMR signals are chemically-shifted upfield (Na salt: alpha, -11.44 delta; beta, -22.91 delta; gamma, -8.36 delta) and the beta- and gamma-groups are broadened (at half-height: alpha, 3.5 Hz; beta, 9.6 Hz; gamma, 69 Hz). Above 10 mM salt, the signals are shifted downfield and are narrow (Na salt: alpha, -11.09 delta, 1.9 Hz; beta, -21.75 delta, 3.3 Hz; gamma, -6.30 delta, 3.9 Hz). 2. The Na-Mg-ATP complex, corresponding to the composition Na6Mg1ATP2, yields a single set of 31P resonances at concentrations of nucleotide of 100 mM, that upon dilution to 0.2 mM, resolve into 2 sets of ATP resonances characterized by low-field and high-field beta- and gamma-group resonance pairs. This set of ATP resonances, in contrast to the resonance set at 100 mM ATP, are broad (100 mM in ATP: alpha, -10.7 delta, 3.7 Hz; beta, -20.1 delta, 15 Hz; gamma, -5.7 delta, 7.3 Hz. 0.2 mM in ATP: alpha, -10.7 delta, 47 Hz; beta, -18.8 and -21.6 delta, 316 and 274 Hz; gamma, -5.5 and -8.7 delta, 460 and 374 Hz). 3. This new data, in combination with data derived from a survey of metal-ion-ATP studies, are interpreted in terms of ATP dimers, incorporating 2 molecules of ATP and 2 metal cations, that exist in water under the physiological conditions of neutral pH, high salt content [135 mM K(I)] and ATP concentrations in the range of 3 mM. 4. A compilation of 31P in vivo and ex vivo data compared to a reference Mg-ATP chemical shift vs Mg/ATP ratio plot indicates that ATP is not fully Mg-saturated in living systems and that 41% exists as the Mg(ATP)2 complex.
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