The optimal structures, harmonic vibrational frequencies, and incremental association enthalpies for the OH-(H2O)(n)(n = 1-3) clusters have been computed at the MP2/aug-cc-p VDZ level of theory, the first ones reported at the correlated level for the n = 2 and 3 clusters. The incremental association enthalpies at 298 K were estimated at -27.0, -20.1, and -16.9 kcal/mol, respectively, within the error bars of recent experimental measurements for the n = 1, 2, and 3 clusters. Two almost isoenergetic isomers were identified for the n = 3 cluster. Hydrogen bonding between water molecules was found in the n = 3 but not the n = 2 cluster, the structure of which is determined by the strong hydroxide ion-water interaction. Hydration of the hydroxide ion results in a decrease in its bond length with an accompanying increase in the analogous frequency that eventually "scrambles" with the one of the "free" (non-hydrogen bonded) stretches in water. The most active infrared (IR) modes correspond to OH stretches which are hydrogen bonded to the hydroxide ion in the range 2500-3000 cm(-1) in agreement with experimental infrared multiple internal reflectance (IR-MIR) measurements of aqueous hydroxide.