Abstract

Proteinase inhibitors in the serpin family form complexes with serine proteinases by interactions between the gamma-OH group at serine 195 of the enzyme and a specific peptide bond within the reactive site loop of the inhibitor. However, the type of complex formed (i.e. Michaelis, acyl, or tetrahedral) is unknown. Until now, 13C NMR spectroscopy studies have only been useful in examining complexes formed with either peptide-related or small protein inhibitors, where 13C-labeled amino acids can be inserted semi-synthetically. Recombinant DNA technology has, however, made it possible to specifically enrich larger proteins with 13C. In the case of serpins we have examined the structure of the complex formed between human alpha 1-proteinase inhibitor uniformally labeled with [13C]methionine and porcine pancreatic elastase. 13C NMR spectroscopic studies revealed a large upfield chemical shift of the carbonyl signal of Met-358 upon complex formation suggesting for the first time that a tetrahedral adduct is formed between a serpin inhibitor and a serine proteinase.