Acid-activatable cysteine proteinases of Dictyostelium discoideum were first identified in spore extracts of strain SG1 using gelatin/SDS/PAGE, followed by acid treatments. Here we utilized the technique of acid activation to identify cryptic cysteine proteinases throughout auto-induced and heat-induced spore germination of D. discoideum strain SG2 and SG1. The major acid-activatable cysteine proteinase identified in SG2 and SG1 spore extracts was ddCP38 (D. discoideum cysteine proteinase with a molecular mass of 38 kDa) and ddCP48, respectively. Further investigation of these enzymes revealed that they were also base deactivatable with a treatment of ammonium chloride directly following acid activation. However, the most intriguing observation was the reversibility of the effects of base deactivation on the enzymes following a second treatment with acetic acid. Thus, we hypothesize that, unlike most mammalian cysteine proteinases which generally require the cleavage of a pro-peptide region for activation, these cysteine proteinases of D. discoideum likely undergo reversible conformational changes between latent and active forms. Moreover, we were able to detect these cryptic cysteine proteinases in the vegetative cells and early aggregates of both strains SG1 and SG2. Studies using 4-[(2S, 3S)-3-carboxyoxiran-2-ylcarbonyl-L-leucylamido]buty lguanidine, a cysteine proteinase inhibitor, revealed that acid activation of a portion of these proteinases was still achievable even after incubation with the inhibitor, further supporting the concept of two stable and reversible conformational arrangements of the enzymes. Thus, we speculate that the pH shuffles that modulate proteinase conformation and activity in vitro may be a reflection of the in vivo regulation of these enzymes via H+-ATPases and ammonia.