Serine proteinase

A reaction looked at earlier simulates borate inhibition of serine proteinases.33 Resorufin acetate (234) is proposed as an attractive substrate to use with chymotrypsin since the absorbance of the product is several times more intense than that formed when the more usual /Miitrophcnyl acetate is used as a substrate. The steady-state Acal values are the same for the two substrates, which is expected if the slow deacylation step involves a common intermediate. Experiments show that the acetate can bind to chymotrypsin other than at the active site.210 Brownian dynamics simulations of the encounter kinetics between the active site of an acetylcholinesterase and a charged substrate together with ah initio quantum chemical calculations using the 3-21G set to probe the transformation of the Michaelis complex into a covalently bound tetrahedral intermediate have been carried out.211 The Glu 199 residue located near the enzyme active triad boosts acetylcholinesterase activity by increasing the encounter rate due to the favourable modification of the electric field inside the enzyme and by stabilization of the TS for the first chemical step of catalysis.211 

Enzymes with trypsin like activity have been reported in some bacteria but there is no assurance that they really are trypsin.] 

Alternaria serine proteinase [Fungal proteinase] (3.4.21.16) is produced and catalyzes the reaction Hydrolysis of proteins no clear specificity. Staphylococcal serine proteinase (3.4.21.19) is produced and catalyzes the reaction Preferential specificity Glu-, Asp-. [Isolated from 

Endotoxin (5 mg per kg body weight intraperi-toneally) rapidly increased plasminogen activator release by rat alveolar macrophages (Etoh et al. 1984). There was significant positive correlation between plasminogen activator release by alveolar macrophages and fibrinolytic activity in broncho alveolar lavage fluid. 

In murine C57BL/6 peritoneal macrophages elicited with either proteose-peptone or fresh thiogly-collate, enhancement of the secretion of plasmino- 

Concanavalin A and phorbol myristate acetate greatly increased secretion of rabbit alveolar macrophage plasminogen activator, although the higher concentration of 10.0 pg Con A/ml had an adverse effect on viability (Schuyler and Forman 1984). 

Urokinase produced by alveolar macrophages is operative not only at the alveolitis stage but also later in the fibrotic process, produced by silica particles, supporting the role of urokinase-type plasminogen activator in fibrogenesis (Lardot et al. 1998). 

Asbestos increased urokinase-type plasminogen activator receptor at the surface of rabbit and human mesothelial cells, suggesting that altered expression of this receptor could be involved in asbestos-induced remodelling of the pleural meso-theUum (Perkins et al. 1999). 

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McPhalen, C. A., James, M. N. G. Structural comparison of two serine proteinase-protein inhibitor complexes Eglin-C-Subtilisin Carlsberg and CI-2-subtilisin novo. Biochemistry 27 (1988) 6582-6598... 

Figure 2.19 Organization of polypeptide chains into domains. Small protein molecules like the epidermal growth factor, EGF, comprise only one domain. Others, like the serine proteinase chymotrypsin, are arranged in two domains that are required to form a functional unit (see Chapter 11). Many of the proteins that are involved in blood coagulation and fibrinolysis, such as urokinase, factor IX, and plasminogen, have long polypeptide chains that comprise different combinations of domains homologous to EGF and serine proteinases and, in addition, calcium-binding domains and Kringle domains.

Serine proteinase domains that are homologous to chymotrypsin, which has about 245 amino acids arranged in two domains. 

Serpins inhibit serine proteinases with a spring-loaded safety catch mechanism... 

Figure 6.23 Schematic diagram illustrating the active site loop regions (red) in three forms of the serpins. (a) In the active form the loop protrudes from the main part of the molecuie poised to interact with the active site of a serine proteinase. The first few residues of the ioop form a short p strand inserted between ps and pis of sheet A. (h) As a result of inhibiting proteases, the serpin molecules are cleaved at the tip of the active site ioop region, in the cleaved form the N-terminal part of the loop inserts itself between p strands 5 and 15 and forms a long p strand (red) in the middie of the p sheet, (c) In the most stable form, the latent form, which is inactive, the N-terminai part of the ioop forms an inserted p strand as in the cleaved form and the remaining residues form a ioop at the other end of the p sheet. (Adapted from R.W. Carreii et ai., Structure 2 257-270, 1994.)...

In this chapter we shall illustrate some fundamental aspects of enzyme catalysis using as an example the serine proteinases, a group of enzymes that hydrolyze peptide bonds in proteins. We also examine how the transition state is stabilized in this particular case. 

Serine proteinases cleave peptide bonds by forming tetrahedral transition states... 

The serine proteinases have been very extensively studied, both by kinetic methods in solution and by x-ray structural studies to high resolution. From all these studies the following reaction mechanism has emerged. 

Figure 11.4 Serine proteinases catalyze the hydrolysis of peptide bonds within a polypeptide chain. The bond that is cleaved is called the scissile bond. (Ra) and (Rb)j/ represent polypeptide chains of varying lengths.

Figure 11.6 A schematic view of the presumed binding mode of the tetrahedral transition state intermediate for the deacylation step. The four essential features of the serine proteinases are highlighted in yellow the catalytic triad, the oxyanion hole, the specificity pocket, and the unspecific main-chain substrate binding.

Four important structural features are required for the catalytic action of serine proteinases... 

The serine proteinases have four important structural features that facilitate this mechanism of catalysis (Figure 11.6). 

A closer examination of these essential residues, including the catalytic triad, reveals that they are all part of the same two loop regions in the two domains (Figure 11.10). The domains are oriented so that the ends of the two barrels that contain the Greek key crossover connection (described in Chapter 5) between p strands 3 and 4 face each other along the active site. The essential residues in the active site are in these two crossover connections and in the adjacent hairpin loops between p strands 5 and 6. Most of these essential residues are conserved between different members of the chymotrypsin superfamily. They are, of course, surrounded by other parts of the polypeptide chains, which provide minor modifications of the active site, specific for each particular serine proteinase. 

The serine proteinases all have the same substrate, namely, polypeptide chains of proteins. However, different members of the family preferentially cleave polypeptide chains at sites adjacent to different amino acid residues. The structural basis for this preference lies in the side chains that line the substrate specificity pocket in the different enzymes. 

As these experiments with engineered mutants of trypsin prove, we still have far too little knowledge of the functional effects of single point mutations to be able to make accurate and comprehensive predictions of the properties of a point-mutant enzyme, even in the case of such well-characterized enzymes as the serine proteinases. Predictions of the properties of mutations using computer modeling are not infallible. Once produced, the mutant enzymes often exhibit properties that are entirely surprising, but they may be correspondingly informative. 

Subtilisins are a group of serine proteinases that are produced by different species of bacilli. These enzymes are of considerable commercial interest because they are added to the detergents in washing powder to facilitate removal of proteinaceous stains. Numerous attempts have therefore recently been made to change by protein engineering such properties of the subtilisin molecule as its thermal stability, pH optimum, and specificity. In fact, in 1988 subtilisin mutants were the subject of the first US patent granted for an engineered protein. 

Serine proteinases such as chymotrypsin and subtilisin catalyze the cleavage of peptide bonds. Four features essential for catalysis are present in the three-dimensional structures of all serine proteinases a catalytic triad, an oxyanion binding site, a substrate specificity pocket, and a nonspecific binding site for polypeptide substrates. These four features, in a very similar arrangement, are present in both chymotrypsin and subtilisin even though they are achieved in the two enzymes in completely different ways by quite different three-dimensional structures. Chymotrypsin is built up from two p-barrel domains, whereas the subtilisin structure is of the a/p type. These two enzymes provide an example of convergent evolution where completely different loop regions, attached to different framework structures, form similar active sites. 

Choi, H.-K., et al. Structure of Sindbis virus core protein reveals a chymotrypsin-like serine proteinase and the organization of the virion. Nature 354 37-43, 1991. 

How do the mutations identified by phage display improve binding specificity There is as yet no direct stmctural information on the phage-selected inhibitors however they can be modeled using data from the crystal structures of other Kunitz domains bound to serine proteinases. These studies lead to the conclusion that the mutations identified by phage display improve binding specificity by maximizing complementarity between the... 

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