Elastase active serine, mechanism

The /3-lactam structure can also react with active-serine hydrolases other than PBPs and /3-lactamases. It has been shown that appropriately substituted cephalosporins (e.g., 5.18) are potent mechanism-based inactivators of human leukocyte elastase (HLE, EC 3.4.21.37), a serine endopeptidase involved in the pathogenesis of pulmonary emphysema and other connective tissue diseases [57-60]. Subsequent work has demonstrated that substituted /3-lactams such as 5.19 or 5.20 are more stable HLE inhibitors and have improved potencies [61-63]. 

An exceptionally reactive serine residue has been identified in a great number of hydrolase enzymes, e. g., trypsin, subtilisin, elastase, acetylcholine esterase and some lipases. These enzymes appear to hydrolyze their substrates by a mechanism analogous to that of chymotrypsin. Hydrolases such as papain, ficin and bromelain, which are distributed in plants, have a cysteine residue instead of an active serine residue in their active sites. Thus, the transient intermediates are thioesters. 

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... 

The serine proteases are a large family of proteolytic ( enzymes that use the reaction mechanism for nucleophilic catalysis outlined in equations (3) and (4), with a serine residue as the reactive nucleophile. The best known members of the family are three closely related digestive enzymes trypsin, chymotrypsin, and elastase. These enzymes are synthesized in the mammalian pancreas as inactive precursors termed zymogens. They are secreted into the small intestine, where they are activated by proteolytic cleavage in a manner discussed in chapter 9. 

Figure 8 Irreversible inhibitors of proteases. Serine and cysteine proteases can be acylated by aza-peptides, which release an alcohol, but cannot be deacylated due to the relative unreactivity of the (thio) acyl-enzyme intermediate. Reactive carbons, such as the epoxide of E64, can alkylate the thiol of cysteine proteases. Phosphonate inhibitors form covalent bonds with the active site serine of serine proteases. Phosphonates are specific for serine proteases as a result of the rigid and well-defined oxyanion hole of the protease, which can stabilize the resulting negative charge. Mechanism-based inhibitors make two covalent bonds with their target protease. The cephalosporin above inhibits elastase [23]. After an initial acylation event that opens the p-lactam ring, there are a number of isomerization steps that eventually lead to a Michael addition to His57. Therefore, even if the serine is deacylated, the enzyme is completely inactive.

A final group of covalent small-molecule inhibitors of proteases are mechanism-based inhibitors. These inhibitors are enzyme-activated irreversible inhibitors, and they involve a two-hif mechanism that completely inhibits the protease. Some isocoumarins and -lactam derivatives have been shown to be mechanistic inhibitors of serine proteases. A classic example is the inhibition of elastase by several cephalosporin derivatives developed at Merck (Fig. 8). The catalytic serine attacks and opens the -lactam ring of the cephalosporin, which through various isomerization steps, allows for a Michael addition to the active site histidine and the formation of a stable enzyme-inhibitor complex (34). These mechanism-based inhibitors require an initial acylation event to take place before the irreversible inhibitory event. In this way, these small molecules have an analogous mechanism of inhibition to the naturally occurring serpins and a-2-macroglobin, which also act as suicide substrates. 

Understanding how HLE inhibitors work and/or designing new inhibitors requires a model of HLE s active-site and an understanding of its mechanism of action. All serine proteinases share a similar catalytic region and mechanism of action but differ in several amino acids in the extended substrate-binding region. These changes are responsible for the specificity differences between HLE and other serine proteinases. In some cases analysis of the enzyme-inhibitor interactions has only been carried out with other related enzymes, and those results are referenced as appropriate. One closely related enzyme, porcine pancreatic elastase (PPE, EC 3.4.21.36) has... 

Peptidic monohalomethyl ketones inactivate serine proteinases by irreversibly reacting with the active-site histidine [101]. However, because of the reactivity pattern and the mechanism of action shown by these compounds, they are described in this section. Although initially prepared as inhibitors of other proteinases, monohalomethyl ketones contributed to the studies on elastase-ligand interactions. They supplied key data points on (a) the effect of the peptide substrate length on the binding, and (b) the subsite specificity of PPE and HLE. Kinetic evaluation of these compounds indicated a two-step mechanism for enzymatic inhibition (Equation 2.2). 

Proteins can be modified by a group of peptide hydrolyses (peptidases) commonly called proteases (or proteinoses). Based on their ability to hydrolyze specific proteins, proteases are classified as collagenase, keratinase, elastase, etc. On the basis of the pH range over which they are active, they are classified as either acidic, neutral, or alkaline. However, according to their mechanism of action, the Enzyme Commission classifies proteases into the four distinct classes of serine, cysteine, aspartyl, and metalloproteases. Serine proteases, for example, always contain serine residue at their catalytic center, which is essential for the action of proteolysis. 

Figure 25.3 shows the relationship of active site of serine hydrolases. The serine hydrolases include serine proteases, lipases, and PHB depolymerases. A common feature of the serine proteases is the presence of a specific amino acid sequence -Gly-Xl-Ser-X2-Gly-. The catalytic mechanism of these enzymes is very similar and the catalytic center consists of a triad of serine, histidine, and aspartate residues [54]. The serine from this sequence attacks the ester bond nucleophilically [55]. Lipases and PHB depolymerases also have a common amino acid sequence around the active site, -Gly-Xl-Ser-X2-Gly-. These serine hydrolases may share a similar mechanism of substrate hydrolysis [21, 56]. In terms of origin of enzymes, it would be wise to consider that the enzyme had wide substrate specificity initially, and then it started to evolve gradually for each specific substrate. In the case of polyester hydrolysis, lipases showed the widest substrate specificity among serine hydrolases for hydrolysis of various polyesters ranging from a-ester bonds to (o-ester bonds. PHB depolymerases would become more specific for microbial PHB that has / -ester bonds, though it could also hydrolyze other polyesters that have -ester and y-ester bonds. Serine proteases such as proteinase K, subtilisin, a-chymotrypsin, elastase, and trypsin hydrolyze only optically active PLLA with a-ester bonds and various proteins with a-amido bonds. 

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