A new active-site titrant of serine proteases

High-Throughput Analysis of Enzymatic Hydrolysis of Biodegradable Polyesters by Monitoring Cohydrolysis of a Polyester-Embedded Fluorogenic Probe

Biodegradable polyesters have the potential to replace nondegradable, persistent polymers in numerous applications and thereby alleviate plastic accumulation in the environment. Herein, we present an analytical approach to study enzymatic hydrolysis of polyesters, the key step in their overall biodegradation process. The approach is based on embedding fluorescein dilaurate (FDL), a fluorogenic ester substrate, into the polyester matrix and on monitoring the enzymatic cohydrolysis of FDL to fluorescein during enzymatic hydrolysis of the polyester. We validated the approach against established techniques using FDL-containing poly(butylene adipate) films and Fusarium solani cutinase (FsC). Implemented on a microplate reader platform, the FDL-based approach enabled sensitive and high-throughput analysis of the enzymatic hydrolysis of eight aliphatic polyesters by two fungal esterases (FsC and Rhizopus oryzae lipase) at different temperatures. While hydrolysis rates for both enzymes increased with decreasing differences between the polyester melting temperatures and the experimental temperatures, this trend was more pronounced for the lipase than the cutinase. These trends in rates could be ascribed to a combination of temperature-dependent polyester chain flexibility and accessibility of the enzyme active site. The work highlights the capability of the FDL-based approach to be utilized in both screening and mechanistic studies of enzymatic polyester hydrolysis.

Synthesis of peptidyl methylcoumarin esters as substrates and active-site titrants for the prohormone processing proteases Kex2 and PC2

Peptidyl methylcoumarin amides are well established as model substrates for understanding protease specificity, but the corresponding methylcoumarin esters have attracted scant attention despite their potential utility in active-site titration and mechanistic characterization. We have devised techniques for the synthesis and deprotection of extended peptidyl methylcoumarin esters in good to moderate yields, and we have demonstrated their suitability for steady-state characterization and active-site titration of the Saccharomyces cerevisiae processing protease Kex2. Additionally, we have used one of these compounds to active-site titrate the homologous enzyme PC2, which had not previously been feasible using other types of substrates. These compounds should thus prove widely suitable for use as substrates and active-site titrants not only for proteases of the prohormone processing family but also for a wide range of other serine proteases.

4-alkylidene oxazolones as substrates and inhibitors for sensitive assays of the normality of active sites and the catalytic properties of hydrolases

The suitability of eleven 4-alkylidene oxazolones for the determination of four hydrolases, alpha-chymotrypsin, trypsin, carboxylesterase and leucine aminopeptidase, was tested. The specific activities were in general low compared with those obtained with the classical substrates but the Kmapp values were also small. Hence, the kcat/Kmapp ratios of the oxazolones, the optimal indicator of activity, remained in the usual range. The high differential absorption coefficients of the oxazolones in the UV range render these substrates very suitable for the determination of active site normalities if the solubilities of the acyl enzymes and the magnitudes of the rapid bursts are sufficient. Since some of the oxazolones fluoresce, the sensitivity of the method may be increased up to 1000 x by fluorescence detection. The titrations may be carried out in organic solvents, e.g. dimethyl sulphoxide, which greatly stabilize the hydrolases. The high specificity of the oxazolones permits active site titrations in the presence of other hydrolases.

Aprotinin derivatives with chromophoric leaving groups can be used as highly selective active-site titrants for serine proteinases and permit the determination of kinetic constants of enzyme-inhibitor complexes

This paper reports a novel and valuable approach to active-site titration. The starting substance for the preparation of the active-site titrants is aprotinin (bovine pancreatic trypsin inhibitor) in which the reactive-site peptide bond, Lys15-Ala16, is split. Two cystine disulfide bonds hold together the two peptide chains. The Lys15 of the reactive site is substituted by arginine-, phenylalanine- and valine-4-nitroanilide or by valine-7-amido-4-methylcoumarin. The different incorporated amino acid residues correspond to different specificities against serine proteinases. Serine proteinases with suitable specificity are able to remove 4-nitroaniline or 7-amino-4-methylcoumarin from these aprotinin derivatives while at the same time resynthesis of the reactive-site peptide bond occurs. The proteinase is then trapped in a stable enzyme-inhibitor complex, which prevents the proteinase from releasing further leaving groups. The quantity of 4-nitroaniline or 7-amino-4-methylcoumarin, which can be assayed spectrophotometrically or fluorometrically is equimolar to the quantity of proteinase used and trapped. The aprotinin derivatives with an incorporated Phe15 or Val15 residue are highly specific for chymotrypsin or for elastase from human leukocytes, respectively. The kinetic constants kon and koff of the enzyme-inhibitor complexes, and hence the equilibrium dissociation constants, can be calculated from the respective titration curves.