Lm. Abell et al., EFFECT OF METAL-LIGAND MUTATIONS ON PHOSPHORYL TRANSFER-REACTIONS CATALYZED BY ESCHERICHIA-COLI GLUTAMINE-SYNTHETASE, Biochemistry, 34(51), 1995, pp. 16695-16702
Glutamine synthetase (GS) converts glutamate to glutamine in the prese
nce of ATP and ammonia and requires two divalent metal ions, designate
d n(1) and n(2), for catalysis. The first intermediate, gamma-glutamyl
phosphate, is formed during catalysis by the transfer of the gamma-ph
osphate of ATP to the gamma-carboxylate of glutamate. Efficient phosph
oryl transfer between these two negatively charged moieties is thought
to be mediated by the n(2) metal. To explore the role of the n(2) met
al in catalysis, histidine 269, a ligand to the n(2) metal, was change
d to aspartate, asparagine, glutamate, and glutamine by site-directed
mutagenesis. All of the mutants bind two manganese ions as determined
by EPR titration. The mutations had little effect on the substrate K-m
's except in the case of H269E which exhibited a K-m Glu = 92 mM, a 10
00-fold increase compared to that for WT (K-m Glu = 70 mu M). The abil
ity of these mutants to catalyze phosphoryl transfer to glutamate or t
o the inhibitor phosphinothricin was examined by rapid quench kinetic
experiments. Phosphorylated phosphinothricin was detected by P-31 NMR
and shown to be produced by both mutants and WT. The rate of phosphory
l transfer to PPT for H269E is reduced 100-fold (0.030 s(-1)) compared
to WT (8 s(-1)). The extra negative charge around the n(2) metal ion
contributed by glutamate 269 severely reduces the ability of the n(2)
metal to mediate efficient glutamate binding in the presence of negati
vely charged ATP and weakens the interactions between metal ion and th
e reactants in the transition state, thus resulting in a lower rate of
phosphoryl transfer.