Comparative behaviour of calpain and cathepsin B toward peptidyl acyloxymethyl ketones, sulphonium methyl ketones and other potential inhibitors of cysteine proteinases.

Peptidyl acyloxymethyl ketones, previously established as potent inactivators of the lysosomal cysteine proteinase cathepsin B, were evaluated against smooth-muscle calpain, a member of the family of Ca(2+)-dependent cysteine proteinases. Only modest rates of time-dependent inhibition could be achieved, even with peptidyl affinity groups optimized for calpain and linked to a carboxylate leaving group of very low pKa [2,6-(CF3)2PhCOO-, pKa 0.58]. Selective inactivation of cathespin B versus calpain was consistently observed with this type of inhibitor. Examination of other potential inhibitors revealed a rank order of potency against calpain to be: peptidyl sulphonium methyl ketones > fluoromethyl ketones, diazomethyl ketones >> acyloxymethyl ketones, an order which differs sharply from that found for cathespin B.

Irreversible inhibition of transglutaminases by sulfonium methylketones: optimization of specificity and potency with omega-aminoacyl spacers.

Sulfonium methylketones, of structure Cbz-Phe-NH(CH2)nCOCH2S+ (CH3)2, n > 2, are specific and potent inactivators of transglutaminases. The length of the -(CH2)n-spacer moiety, n = 1-5, is a critical determinant for both the specificity and potency of the inactivator. The dipeptidyl analog Cbz-Phe-Gly-(CH2)nS+ (CH3)2, n = 1, is a more powerful inactivator of the thiol proteinase cathepsin B, k/K > 3 x 10(5) M-1 min-1, than of transglutaminases, ki(app)/Ki(app) < 1.5 x 10(4) M-1 min-1. In contrast, the gamma-aminobutyryl analog, n = 3, is a very potent transglutaminase inactivator with ki(app)/Ki(app) = 3.1 x 10(6) M-1 min-1, but does not inactivate cathepsin B. In cell studies, the gamma-aminobutyryl and epsilon-aminohexyl analogs inhibited the transglutaminase-mediated process of ionophore-induced cross-linked envelope formation by human malignant keratinocytes and the order of potency was related to that found for enzyme inhibition. The sulfonium methylketones, in equilibrium with the resonance stabilized ylides, are chemically inert towards glutathione under ambient conditions demonstrating the potential utility of this novel class of transglutaminase inhibitors for the study of enzyme inhibition in cellular environments.

A new class of mechanism-based inhibitors of transglutaminase enzymes inhibits the formation of cross-linked envelopes by human malignant keratinocytes.

A series of tyrosinamidomethyl dihydrohaloisoxazole compounds, designed as mechanism-based inhibitors of bovine epidermal transglutaminase enzyme, was examined for effects on the formation of cross-linked envelopes by human SCC-9 malignant keratinocytes. Compounds inhibited ionophore-induced envelope formation in a manner that reflected their capacity to inhibit transglutaminase activity. Preincubation and inhibitor wash-out studies indicated that the inhibitor must be present at the time of cell activation by ionophore in order to inhibit envelope formation. The stereospecific nature of the inhibitory activity of these compounds on both transglutaminase activity and cross-linked envelope formation makes this class of compounds an important tool in the study of transglutaminase-mediated events at the cellular level.