Serine proteases catalytic activity

Both enzymes have the Asp-His-Ser catalytic side chains, the same as in the serine proteases. The active atoms of this catalytic triad have essentially identical stereochemistry in the serine proteases and in these lipases. The amino acids themselves, however, have quite different conformations and orientations. 

Especially for enzymes, common mechanisms and associated active sites are often observed. This allows searching for appropriate 3D patterns in a database of structures and for checking models to contain such a pattern (for a well known example, see SER-HIS-ASP serine protease catalytic triad [262]). 

Figure 16.21 Structure of one subunit of the core protein of Slndbls virus. The protein has a similar fold to chymotrypsin and other serine proteases, comprising two Greek key motifs separated by an active site cleft. The C-terminus of the protein is bound in the catalytic site, making the coat protein inactive (Adapted from S. Lee et al., Structure 4 531-541, 1996.)...

Until recently, the catalytic role of Asp ° in trypsin and the other serine proteases had been surmised on the basis of its proximity to His in structures obtained from X-ray diffraction studies, but it had never been demonstrated with certainty in physical or chemical studies. As can be seen in Figure 16.17, Asp ° is buried at the active site and is normally inaccessible to chemical modifying reagents. In 1987, however, Charles Craik, William Rutter, and their colleagues used site-directed mutagenesis (see Chapter 13) to prepare a mutant trypsin with an asparagine in place of Asp °. This mutant trypsin possessed a hydrolytic activity with ester substrates only 1/10,000 that of native trypsin, demonstrating that Asp ° is indeed essential for catalysis and that its ability to immobilize and orient His is crucial to the function of the catalytic triad. 

Craik, C. S., et al., 1987. The catalytic role of the active site aspartic acid in serine proteases. 237 909-919. 

Urokinase-type plasminogen activator (uPA, urokinase) is synthesized by endothelial and tumor cells as a single-chain glycoprotein (scuPA) without catalytic activity. When it is converted to a two-chain protein (tcuPA) by plasmin, an active serine protease center develops, which activates plasminogen. Thus, uPA (55 kDa) results in the amplification of fibrinolysis. 

The elucidation of the X-ray structure of chymotrypsin (Ref. 1) and in a later stage of subtilisin (Ref. 2) revealed an active site with three crucial groups (Fig. 7.1)-the active serine, a neighboring histidine, and a buried aspartic acid. These three residues are frequently called the catalytic triad, and are designated here as Aspc Hisc Serc (where c indicates a catalytic residue). The identification of the location of the active-site groups and intense biochemical studies led to several mechanistic proposals for the action of serine proteases (see, for example, Refs. 1 and 2). However, it appears that without some way of translating the structural information to reaction-potential surfaces it is hard to discriminate between different alternative mechanisms. Thus it is instructive to use the procedure introduced in previous chapters and to examine the feasibility of different... 

The considerations presented above were based on the specific assumption that the catalytic reaction of the serine proteases involves mechanism a of Fig. 7.2. However, one can argue that the relevant mechanism is mechanism b (the so-called charge-relay mechanism ). In principle the proper procedure, in case of uncertainty about the actual mechanism, is to perform the calculations for the different alternative mechanisms and to find out which of the calculated activation barriers reproduces the observed one. This procedure, however, can be used with confidence only if the calculations are sufficiently reliable. Fortunately, in many cases one can judge the feasibility of different mechanisms without fully quantitative calculations by a simple conceptual consideration based on the EVB philosophy. To see this point let us consider the feasibility of the charge-relay mechanism (mechanism b) as an alternative to mechanism a. Starting from Fig. 7.2 we note that the energetics of route b can be obtained from the difference between the activation barriers of route b and route a by... 

After the nucleophilic attack by the hydroxyl function of the active serine on the carbonyl group of the lactone, the formation of the acyl-enzyme unmasks a reactive hydroxybenzyl derivative and then the corresponding QM. The cyclic structure of the inhibitor prevents the QM from rapidly diffusing out of the active center. Substitution of a second nucleophile leads to an irreversible inhibition. The second nucleophile was shown to be a histidine residue in a-chymotrypsin28 and in urokinase.39 Thus, the action of a functionalized dihydrocoumarin results in the cross-linking of two of the most important residues of the protease catalytic triad. 

The outstanding inclusion ability and the carboxylic functions of host I raised the idea of co-erystallizing it with imidazole (Im) which, due to its versatile nature 114), is one of the frequently used components in enzyme active sites, generally presented by histidine. Formally, a system made of imidazole and an acid component may mimic two essential components of the so-called catalytic triad of the serine protease family of enzymes the acid function of Aspl02 and the imidazole nucleus of His57 115) (trypsin sequence numbering). The third (albeit essential) component of the triad corresponding to the alcohol function of Seri 95 was not considered in this attempt. This family of enzymes is of prime importance in metabolitic processes. 

The presence of a covalent acyl-enzyme intermediate in the catalytic reaction of the serine proteases made this class of enzymes an attractive candidate for the initial attempt at using subzero temperatures to study an enzymatic mechanism. Elastase was chosen because it is easy to crystallize, diffracts to high resolution, has an active site which is accessible to small molecules diffusing through the crystal lattice, and is stable in high concentrations of cryoprotective solvents. The strategy used in the elastase experiment was to first determine in solution the exact conditions of temperature, organic solvent, and proton activity needed to stabilize an acyl-enzyme intermediate for sufficient time for X-ray data collection, and then to prepare the complex in the preformed, cooled crystal. Solution studies were carried out in the laboratory of Professor A. L. Fink, and were summarized in Section II,A,3. Briefly, it was shown that the chromophoric substrate -carbobenzoxy-L-alanyl-/>-nitrophenyl ester would react with elastase in both solution and in crystals in 70 30 methanol-water at pH 5.2 to form a productive covalent complex. These... 

A sutfonylating agent (abbreviated PMSE) that irreversibly inhibits many serine esterases and serine proteases . Target enzymes usually react with PMSE and related alkylating agents through the activated imidazole group of a histidyl residue that is part of the catalytic triad. 

---