Chymotrypsin serine

Enzyme inhibitors are often poisonous. For example, diisopropyl-fluorophosphate is a nerve poison because the enzyme acetylcholinesterase has a reactive site serine. Chymotrypsin and acetylcholinesterase are both members of the class of enzymes known as serine esterases, which are all inhibited by diisopropylfluorophosphate. 

Fig. 10.12 Sequence alignment of trypsin, chymotrypsin and thrombin (bovine). The active sites histidine, aspartic acid and serine are highlighted.

Numbering corresponds to chymotrypsin with active serine at 195. 

An example of a pseudoirreversible inhibitor has been demonstrated for chymotrypsin (36). This enzyme is a serine protease, and its mechanism of catalysis may be outlined as follows, where or R2 preferentially is a hydrophobic amino acid residue. 

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. 

Inhibitors as well as substrates bind in this crevice between the domains. From the numerous studies of different inhibitors bound to serine pro-teinases we have chosen as an illustration the binding of a small peptide inhibitor, Ac-Pro-Ala-Pro-Tyr-COOH to a bacterial chymotrypsin (Figure 11.9). The enzyme-peptide complex was formed by adding a large excess of the substrate Ac-Pro-Ala-Pro-Tyr-CO-NHz to crystals of the enzyme. The enzyme molecules within the crystals catalyze cleavage of the terminal amide group to produce the products Ac-Pro-Ala-Pro-Tyr-COOH and NHs. The ammonium ions diffuse away, but the peptide product remains bound as an inhibitor to the active site of the enzyme. 

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. 

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. 

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.)...

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. 

X-ray crystallographic studies of serine protease complexes with transition-state analogs have shown how chymotrypsin stabilizes the tetrahedral oxyanion transition states (structures (c) and (g) in Figure 16.24) of the protease reaction. The amide nitrogens of Ser and Gly form an oxyanion hole in which the substrate carbonyl oxygen is hydrogen-bonded to the amide N-H groups. 

Lesk, A. M., and Fordham, W. D., 1996. Conservation and variability in the structures of serine proteinases of die chymotrypsin family. Journal of Molecular Biology 258 501—537. 

Microbial serine proteases, such as chymotrypsin, catalyse the hydrolysis of N-acetyl-L-amino add esters (Figure A8.ll). 

A beta barrel is a three-dimensional protein fold motif in which beta strands connected by loops form a barrellike structure. For example, this fold motif is found in many proteins of the immunoglobulin family and of the chymotrypsin family of serine proteases. 

Chymase (mast cell protease type II), a chymotrypsin-like protease, is a serine protease found in mucosal mast cells, which catalyzes the conversion of angiotensin I to angiotensin II and of big endothelin 1 (ET1) to ET1 (1-31). 

Chymotrypsin-like proteinases are serine proteinases that recognize pqDtide residues with aromatic side chains (phyenylalanyl or tyrosyl residues) and that effect hydrolysis of the polypeptide chain on the carboxy-terminal side of these residues. Examples of chymotrypsin-like proteinases are chymotrypsin and cathepsin-G. 

For many serine and cysteine peptidases catalysis first involves formation of a complex known as an acyl intermediate. An essential residue is required to stabilize this intermediate by helping to form the oxyanion hole. In cathepsin B a glutamine performs this role and sometimes a catalytic tetrad (Gin, Cys, His, Asn) is referred too. In chymotrypsin, a glycine is essential for stabilizing the oxyanion hole. 

All peptidases within a family will have a similar tertiary structure, and it is not uncommon for peptidases in one family to have a similar structure to peptidases in another family, even though there is no significant sequence similarity. Families of peptidases with similar structures and the same order of active site residues are included in the same clan. A clan name consists of two letters, the first representing the catalytic type as before, but with the extra letter P , and the second assigned sequentially. Unlike families, a clan may contain peptidases of more than one catalytic type. So far this has only been seen for peptidases with protein nucleophiles, and these clans are named with an initial P . Only three such clans are known. Clan PA includes peptidases with a chymotrypsin-like fold, which besides serine peptidases such as chymotrypsin... 

The serine proteases are the most extensively studied class of enzymes. These enzymes are characterized by the presence of a unique serine amino acid. Two major evolutionary families are presented in this class. The bacterial protease subtilisin and the trypsin family, which includes the enzymes trypsin, chymotrypsin, elastase as well as thrombin, plasmin, and others involved in a diverse range of cellular functions including digestion, blood clotting, hormone production, and complement activation. The trypsin family catalyzes the reaction ... 

The actual reaction mechanism is very similar for the different members of the family, but the specificity toward the different side chain, R, differs most strikingly. For example, trypsin cleaves bonds only after positively charged Lys or Arg residues, while chymotrypsin cleaves bonds after large hydrophobic residues. The specificity of serine proteases is usually designated by labeling the residues relative to the peptide bond that is being cleaved, using the notation... 

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... 

Structural analysis of the rhinovirus and the hepatitis A virus 3C proteases (Allaire et al. 1994 Matthews et al. 1994) confirmed earlier predictions that the picomavirus 3C proteases are similar to chymotrypsin-Uke serine proteases in their fold. An important difference is that the serine nucleophile of serine proteases is replaced with a cysteine however, the 3C protease is stracturally distinct from the eukaryotic cysteine protease class of enzymes. 

Allaire M, Chernaia MM, Malcolm BA, James MN (1994) Picomaviral 3C cysteine proteinases have a fold similar to chymotrypsin-Kke serine proteinases. Nature 369 72-76 Altman MD, Nalivaika EA, Prabu-Jeyabalan M, Schiffer CA, Tidor B (2008) Computational design and experimental study of tighter binding peptides to an inactivated mutant of HIV-1 protease. Proteins 70 678-694... 

Catalysis by enzymes that proceeds via a unique reaction mechanism typically occurs when the transition state intermediate forms a covalent bond with the enzyme (covalent catalysis). The catalytic mechanism of the serine protease chymotrypsin (Figure 7-7) illustrates how an enzyme utilizes covalent catalysis to provide a unique reaction pathway. 

Definition of Ej and E2 eonformations of the a subunit of Na,K-ATPase involves identification of cleavage points in the protein as well as association of cleavage with different rates of inactivation of Na,K-ATPase and K-phosphatase activities [104,105]. In the Ei form of Na,K-ATPase the cleavage patterns of the two serine proteases are clearly distinct. Chymotrypsin cleaves at Leu (C3), Fig. 3A, and both Na,K-ATPase and K-phosphatase are inactivated in a monoexponential pattern [33,106]. Trypsin cleaves the E form rapidly at Lys ° (T2) and more slowly at Arg (T3) to produce the characteristie biphasic pattern of inactivation. Localization of these splits was determined by sequencing N-termini of fragments after isolation on high resolution gel filtration columns [107]. 

NS3 is a 631 amino acid protein, and its first 180 amino acids encode a serine protease of the chymotrypsin family (Figure 2.2A). It has a typical chymotrypsin-family fold consisting of two jS-barrels, with catalytic triad residues at the interface. His-57 and Asp-81 are contributed by the N-terminal jS-barrel and Ser-139 from the C-terminal jS-barrel. NS3 and closely related viral proteases are significantly smaller than other members of the chymotrypsin family, and many of the loops normally found between adjacent jS-strands in trypsin proteases are truncated in NS3 [31]. Probably... 

Serine proteases usually show primary specificity (occupation of subsite Si) for positively charged arginine or lysine (trypsin, plasmin, plasminogen activators, thrombin), large hydrophobic side chains of phenylalanine, tyrosine, and tryptophan (chymotrypsin, cathepsin G, chymase, and subtilisin), or small aliphatic side chains (elastases). Nevertheless, there are a large number of variations and in many cases, other subsites like S2 and S3 are more discriminating while maintaining the... 

Bromomethyl-3,4-dibromo-3,4-dihydrocoumarin 1 (Fig. 11.4) and its chloro-methylated analogue 2b rapidly and progressively inactivate a-chymotrypsin and also the activities of a series of trypsin-like proteases. A benzyl substituent characteristic of good substrates of a-chymotrypsin was introduced at the 3-position to make inhibition more selective. This substituted dihydrocoumarin 3 irreversibly inhibited a-chymotrypsin and other proteases. These functionalized six-membered aromatic lactones, and their five- and seven-membered counterparts, 3//-benzofuran-2-ones 2a26 and 4,5-dihydro-3//-benzo[b]oxepin-2-ones 2c,27 were the first efficient suicide inhibitors of serine proteases. Their postulated mechanism of action is shown in Scheme 11.2. 

Finally, coumarin derivatives may act as general inhibitors of serine proteases or as specific inhibitors of human leukocyte elastase, depending on the nature of the substituents, through two distinct mechanisms, suicide substrates (a-chymotrypsin)... 

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