Phosphoester Hydrolysis and Intramolecular Transesterification of Ribonucleoside 2'- and 3'-Phosphoromonothioate Triesters: Kinetics and Mechanisms for the Reactions of 5'-O-Methyluridine 2'- and 3'-Dimethylphosphoromonothioates.

Abstract

The hydrolytic reactions of the monothioate analogs of 5'-O-methyluridine 2'- and 3'-dimethylphosphates have been followed over a wide acidity range, H(0) = -1.7 ([HCl] = 5 mol L(-)(1)) to pH 9. Two reactions were found to compete: mutual interconversion of the 2'- and 3'-isomers and phosphoester hydrolysis to a mixture of phosphorothioate diesters, viz., the R(P) and S(P) diastereomers of 2',3'-cyclic thiophosphate and 2'/3'-monomethylthiophosphates (i.e., three pairs of diastereomers). No marked desulfurization could be observed. The interconversion and hydrolysis both show first-order dependence of rate on acidity at pH < 0, the isomerization being 3-4 times as fast as the phosphoester hydrolysis. Under less acidic conditions, the hydrolysis remains pH-independent up to pH 7, while the isomerization becomes hydroxide-ion-catalyzed (first-order in [OH(-)]) already at pH 2. The hydrolysis is susceptible to general base catalysis in carboxylic acid buffers, the Brönsted beta value being 0.8. In contrast, no conclusive evidence for buffer-catalyzed isomerization could be obtained. All these reactions are suggested to proceed via a pentacoordinated thiophosphorane intermediate, obtained at pH < 1 by an attack of the neighboring hydroxy function on a protonated (monocationic) thiophosphate group and at pH > 2 by an attack of a deprotonated hydroxy function (oxyanion) on a neutral thiophosphate. The monocationic intermediate (pH < 1) may collapse to hydrolysis and isomerization products without further catalysis (departure of alcohol). The monoanionic thiophosphorane (pH > 2) also gives isomerization products without catalysis (departure of 2'/3'-oxyanion), whereas breakdown to the hydrolysis products needs either a specific or a general acid catalysis process (departure of methanol). Accordingly, the observed general-base-catalyzed hydrolysis most likely consists of consecutive specific base/general acid catalysis. The phosphorothioate triesters studied are, under very acidic conditions, more than 2 orders of magnitude more stable than their oxyphosphate counterparts, whereas the rate-retarding "thio effect" (k(P)(=)(O)/k(P)(=)(S)) is much smaller with the hydroxide ion-catalyzed reactions (ca. 4) and almost negligible with the pH-independent hydrolysis.