The alpha-amino acid ester prodrugs of the antitumor agent camptothecin and a more potent, lipophilic silatecan analogue, DB-67, have been shown by NMR spectroscopy and quantitative kinetic analyses to undergo quantitative conversion to their pharmacologically active lactones via a nonenzymatic mechanism that at pH 7.4 is favored over direct hydrolysis. The alternate pathway involves the reversible intramolecular nucleophilic amine attack at the camptothecin E-ring carbonyl to generate a lactam (I) followed by a second intramolecular reaction to produce a bicyclic hemiortho ester (I'). The intermediates were isolated and shown to exist in an apparent equilibrium dominated by the hemiortho ester in DMSO using NMR spectroscopy. The conversion of prodrugs of camptothecin or DB-67 containing either alpha-NH(2) or alpha-NHCH(3) and their corresponding hemiortho esters were monitored versus time in aqueous buffer (pH 3.0 and 7.4) at 37 degrees C, and the kinetic data were fit to a model based on the proposed mechanism. The results indicated that while the prodrugs are relatively stable at pH 3, facile lactone release occurs from both the prodrugs and their corresponding hemiortho ester intermediates under physiological conditions (pH 7.4). The glycinate esters and their hemiortho esters were found to be more cytotoxic than the N-methylglycinates or their corresponding hemiortho ester intermediates in vitro using a human breast cancer cell line (MDA-MB-435S), consistent with their more rapid conversion to active lactone. The pH dependence of the nonenzymatic pathway for conversion of these alpha-amino acid ester prodrugs suggests that they may be useful for tumor-targeting via liposomes, as they can be stabilized in an acidic environment in the core of liposomes and readily convert to the active lactone following their intratumoral release.