The substrate analogue L-aspartate beta-semialdehyde (L-ASA) has been identified as a mechanism-based inactivator of L-aspartase from Escherichia coli. The enzyme catalyzes the deamination of L-ASA to yield fumaric acid semialdehyde (FAA) and NH4+, with the product FAA partitioning between subsequent release or irreversible enzyme inactivation. Complete protection against L-ASA inactivation is observed in the presence of the product fumarate and a divalent metal ion. However, protection against inactivation by the product FAA also requires the presence of an enzyme activator. In addition to functioning as a mechanism-based inactivator, L-ASA has also been shown to serve as an activator of L-aspartase. The mechanism of inactivation by FAA involves the attack of an active site nucleophilic at the alpha-carbon of FAA to yield a stable Michael type enzyme adduct. Subsequent formation of a hydrazone upon treatment of the enzyme adduct with 2,4-dinitrophenylhydrazine confirms the presence of the unreacted aldehydic group of FAA. Examination of a group of product analogues with different substituents has demonstrated a correlation between the electron-withdrawing ability of these functional groups and the rate of inactivation of L-aspartase.