Characterization of Hydrogen Bonding in the Complex of Adenosine Deaminase with a Transition State Analogue: A Raman Spectroscopic Study

Abstract

The Raman spectra of purine ribonucleoside as well as a stable model compound (1-methoxyl-1,6-dihydropurine ribonucleoside), free in solution and bound into its complex with adenosine deaminase (ADA), have been studied by Raman difference spectroscopy. Using purine riboside analogues labeled with ¹⁵N1 or ¹³C6 and the theoretical frequency normal-mode analyses of these molecules using ab initio quantum mechanic methods, we have positively identified many of the Raman bands in the enzyme-bound inhibitor. The spectrum of the enzyme-bound inhibitor is consistent with the enzyme-catalyzed hydration of the purine base to yield 1-hydroxyl-1,6-dihydropurine ribonucleoside, as suggested earlier by X-ray crystallographic studies. In addition, the Raman data and subsequent vibrational analyses show that the binding-induced Raman spectral changes of the inhibitor can be modeled by the formation of a strong hydrogen bond to its N1−H bond. This hydrogen bond, apparently between the N1−H of the inhibitor and the Oδ1 of Glu217 in ADA, causes a substantial N1−H bending frequency increase of about 50−100 cm^-1 compared to its solution value, and this results in an estimated enthalpy of the hydrogen bond of 4−10 kcal/mol. The relationship of transition state stabilization in the catalytic strategy of this efficient enzyme to such a bonding pattern is discussed.