Herein, we present results of a computational study on benzylpenicillin attachment to Lys199 of human serum albumin via an aminolysis reaction. The internal geometry of the reactive part of the system was taken from previous work at the B3LYP/6-31+G* level on the water-assisted aminolysis reaction of a penicillin model compound (Díaz, N.; Suárez, D.; Sordo, T. L. J. Am. Chem. Soc. 2000, 122, 6710--6719). The protein environment around Lys199, the 6-acylamino side chain, and the 2-methyl groups of benzylpenicillin were relaxed by carrying out geometry optimizations with a hybrid QM/MM method (PM3/AMBER). Two different mechanistic routes were explored: a one-step water-assisted process and a carboxylate and water-assisted route in which the beta-lactam carboxylate and the ancillary water molecule mediate the proton transfer from the epsilon-amino group of Lys199 to the beta-lactam leaving N atom. The corresponding energy profiles in the protein combine the B3LYP/6-31+G* and PM3 energies of the reactive subsystem (benzylpenicillin + Lys199 side chain + the ancillary water molecule) and semiempirical PM3 energies of the entire system evaluated with a "divide and conquer" linear-scaling method. It is observed that penicillin haptenation to HSA can proceed through the water-assisted concerted mechanism which is calculated to have a high energy barrier of approximately 38 kcal/mol, in agreement with the experimentally observed slow reaction kinetics.