Dc. Carlow et al., ROLE OF GLUTAMATE-104 IN GENERATING A TRANSITION-STATE ANALOG INHIBITOR AT THE ACTIVE-SITE OF CYTIDINE DEAMINASE, Biochemistry, 35(3), 1996, pp. 948-954
The F-19-NMR resonance of 5-[F-19]Fluoropyrimidin-2-one ribonucleoside
moves upfield when it is bound by wild-type cytidine deaminase from E
scherichia coli, in agreement with UV and X-ray spectroscopic indicati
ons that this inhibitor is bound as the rare 3,4-hydrated species 5-fl
uoro-3,4-dihydrouridine, a transition state analogue inhibitor resembl
ing an intermediate in direct water attack on 5-fluorocytidine. Compar
ison of pK(A) values of model compounds indicates that the equilibrium
constant for 3,4-hydration of this inhibitor in free solution is 3.5
x 10(-4) M, so that the corrected dissociation constant of 5-fluoro-3,
4-dihydrouridine from the wild-type enzyme is 3.9 x 10(-11) M. Very di
fferent behavior is observed for a mutant enzyme in which alanine repl
aces Glu-104 at the active site, and k(cat) has been reduced by a fact
or of 10(8). 5-[F-19]Fluoropyrimidin-2-one ribnucleoside is strongly f
luoresce nt, making it possible to observe that the mutant enzyme bind
s this inhibitor even more tightly (K-d = 4.4 x 10(-8) M) than does th
e native enzyme (K-d = 1.1 X 10(-7) M). F-19-NMR indicates, however, I
hat the E104A mutant enzyme binds the inhibitor without modification,
in a form that resembles the substrate in the ground state. These resu
lts are consistent with a major role for Glu-104, not only in stabiliz
ing the ES double dagger complex in the transition state, but also in
destabilizing the ES complex in the ground state.