Serine hydrolase mechanism

The mechanism for the lipase-catalyzed reaction of an acid derivative with a nucleophile (alcohol, amine, or thiol) is known as a serine hydrolase mechanism (Scheme 7.2). The active site of the enzyme is constituted by a catalytic triad (serine, aspartic, and histidine residues). The serine residue accepts the acyl group of the ester, leading to an acyl-enzyme activated intermediate. This acyl-enzyme intermediate reacts with the nucleophile, an amine or ammonia in this case, to yield the final amide product and leading to the free biocatalyst, which can enter again into the catalytic cycle. A histidine residue, activated by an aspartate side chain, is responsible for the proton transference necessary for the catalysis. Another important factor is that the oxyanion hole, formed by different residues, is able to stabilize the negatively charged oxygen present in both the transition state and the tetrahedral intermediate. 

Serine Hydrolase Mechanism for the Acylation of Alcohols and Amines... 

Hydrolases possess a common feature for its mechanistic action. Their active site is built around three key amino acid residues, which are histidine (His), serine (Ser), and aspartic acid (Asp) or alternatively glutamic acid (Glu). This site, namely, the catalytic triad, forms a charge-relay network to polarize and activate the nucleophile, allowing the serine hydrolase mechanism to start [19]. This review covers the acylation of alcohols and amines using mainly esters so Figure 9.1 depicts the mechanism for these types of reactions is depicted. 

The mechanism of serine (3-lactamases is similar to that of a general serine hydrolase. Figure 8.14 illustrates the reaction of a serine (3-lac(amasc with another type of (3-lactam antibiotic, a cephalosporin. The active-site serine functions as an attacking nucleophile, forming a covalent bond between the serine side chain oxygen... 

Remarkably, Brassica napus pollen was reported to have a 22 kDa cutinase that cross-reacted with antibodies prepared against F. solani f. pisi cutinase [134]. Although a 22 kDa and a 42 kDa protein that catalyzed hydrolysis of p-nitrophenyl butyrate were found in this pollen, only the former catalyzed cutin hydrolysis. Immunofluorescence microscopic examination suggested that the 22 kDa protein was located in the intine. Since the nature of the catalytic mechanism of this enzyme has not been elucidated, it is not clear whether this represents a serine hydrolase indicating that plants may have serine and thiol cutinases. The role of the pollen enzyme in controlling compatibility remains to be established. 

The previous chapter offered a broad overview of peptidases and esterases in terms of their classification, localization, and some physiological roles. Mention was made of the classification of hydrolases based on a characteristic functionality in their catalytic site, namely serine hydrolases, cysteine hydrolases, aspartic hydrolases, and metallopeptidases. What was left for the present chapter, however, is a detailed presentation of their catalytic site and mechanisms. As such, this chapter serves as a logical link between the preceding overview and the following chapters, whose focus is on metabolic reactions. 

These three catalytic functionalities are similar in practically all hydrolytic enzymes, but the actual functional groups performing the reactions differ among hydrolases. Based on the structures of their catalytic sites, hydrolases can be divided into five classes, namely serine hydrolases, threonine hydrolases, cysteine hydrolases, aspartic hydrolases, and metallohydrolases, to which the similarly acting calcium-dependent hydrolases can be added. Hydrolases of yet unknown catalytic mechanism also exist. 

Fig. 3.3. Major steps in the hydrolase-catalyzed hydrolysis of peptide bonds, taking chymo-trypsin, a serine hydrolase, as the example. Asp102, His57, and Ser195 represent the catalytic triad the NH groups of Ser195 and Gly193 form the oxyanion hole . Steps a-c acylation Steps d-f deacylation. A possible mechanism for peptide bond synthesis by peptidases is represented by the reverse sequence Steps f-a.

Other serine hydrolases such as cholinesterases, carboxylesterases, lipases, and fl-lactamases of classes A, C, and D have a hydrolytic mechanism similar to that of serine peptidases [25-27], The catalytic mechanism also involves an acylation and a deacylation step at a serine residue in the active center (see Fig. 3.3). All serine hydrolases have in common that they are inhibited by covalent attachment of diisopropyl phosphorofluoridate (3.2) to the catalytic serine residue. The catalytic site of esterases and lipases has been less extensively investigated than that of serine peptidases, but much evidence has accumulated that they also contain a catalytic triad composed of serine, histidine, and aspartate or glutamate (Table 3.1). 

The mechanism of hydrolysis of cysteine peptidases, in particular cysteine endopeptidases (EC 3.4.22), shows similarities and differences with that of serine peptidases [2] [3a] [55 - 59]. Cysteine peptidases also form a covalent, ac-ylated intermediate, but here the attacking nucleophile is the SH group of a cysteine residue, or, rather, the deprotonated thiolate group. Like in serine hydrolases, the imidazole ring of a histidine residue activates the nucleophile, but there is a major difference, since here proton abstraction does not appear to be concerted with nucleophilic substitution but with formation of the stable thiolate-imidazolium ion pair. Presumably as a result of this specific activation of the nucleophile, a H-bond acceptor group like Glu or Asp as found in serine hydrolases is seldom present to complete a catalytic triad. For this reason, cysteine endopeptidases are considered to possess a catalytic dyad (i.e., Cys-S plus H-His+). The active site also contains an oxyanion hole where the terminal NH2 group of a glutamine residue plays a major role. 

The hydrolytic mechanism of phospholipase A2 (EC 3.1.1.4) seems to represent a special case compared to serine hydrolases (Fig. 3.14). The active site... 

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]. 

The transesterification of cocaine to cocaethylene is an enzymatic reaction catalyzed by microsomal carboxylesterases and blocked by inhibitors of serine hydrolases [124][125], In Chapt. 3, we have discussed the mechanism of serine hydrolases, showing how a H20 molecule enters the catalytic cycle to hydrolyze the acylated serine residue in the active site of the enzyme. In the case of cocaine, the acyl group is the benzoylecgoninyl moiety (Fig. 7.9,d ), which undergoes esterification with ethanol according to Steps e and/ (Fig. 7.9). 

However, not included in the above mechanisms are other amino acid side-chains at the active site, whose special role will be to help bind the reagents in the required conformation for the reaction to occur. Examples of such interactions are found with acetylcholinesterase and chymotrypsin, representatives of a group of hydrolytic enzymes termed serine hydrolases, in that a specific serine amino acid residue is crucial for the mechanism of action. 

Lipases belong to the subclass of serine hydrolases, and their structure and reaction mechanism are well understood. Their common a/p-hydrolase enzyme fold is characterized by an a-helix that is connected with a sharp turn, referred to as the nucleophilic elbow, to the middle of a P-sheet array. All lipases possess an identical catalytic triad consisting of an Asp or Gin residue, a His and a nucleophilic Ser [14]. The latter residue is located at the nucleophilic elbow and is found in the middle of the highly conserved Gly—AAl—Ser—AA2—Gly sequence in which amino acids AAl and AA2 can vary. The His residue is spatially located at one side of the Ser residue, whereas at the opposite side of the Ser a negative charge can be stabilized in the so-called oxyanion hole by a series of hydrogen bond interactions. The catalytic mechanism of the class of a/P-hydrolases is briefly discussed below using CALB as a typical example, since this is the most commonly applied lipase in polymerization reactions [15]. 

The glycosidases act by two different mechanisms which is revealed by the stereochemistry at the anomeiic centre of the product (McCarter and Withers, 1994). In one type of glycosidases the anomeiic centre is directly attacked by a hydroxide to give a product with inverted stereochemistry at the anomeiic centre. In the other mechanism, the anomeric centre is attacked by the carboxylate group of a glutamic acid residue to form an intermediate in which the carbohydrate moiety is covalently bound to the enzyme similar to in epoxide hydrolases (Figure 2.16) and serine hydrolases. Attack on this intermediate by a nucleophile leads to the net result which is retention of the stereochemistry at the anomeric centre. 

Hu, C.-H. Brinck, T. Hult, K. Ab initio and density functional theory studies of the catalytic mechanism for ester hydrolysis in serine hydrolases, Int. J. Quant. Chem. 1998, 69, 89-103. 

Both AChE and BChE are of the serine hydrolase class, which includes proteases such as trypsin (see PROTEASE inhibitors). Characteristically, such enzymes can be inhibited through covalent linkage of constituent parts of irreversible anticholinesterases such as dyflos (DFP, diisopropylfluorophosphonate). The active site of the enzyme contains a catalytic triad with a glutamate residue, a serine residue and a histidine imidazole ring. The mechanism of the catalysis of break down of AChE has been characterized, and the reaction progresses at a very fast rate. 

Figure 9 Serine hydrolases as targets of ABPP. (a) Catalytic mechanism of peptide substrate cleavage via the action of a catalytic triad, (b) Aryl phosphonate and fluorophosphonate probe scaffolds.

In an attempt to apply this mechanism to a polyester formation and to investigate the single steps involved on a molecular basis one can for instance start with the CALB-phosphonate complex 1LBS [6] as the initial structure, as it is structurally close to the intermediate structure of an acylated Ser10s that certainly has to be passed through during an enzymatic polymerization process. In accordance with the accepted mechanism for serine hydrolases the enzymatic process consists of two mechanistically important steps. These are, in the case of for instance, a potential enzymatic esterification of adipic acid with 1,6-hexanediol ... 

The protein is a 12-stranded anti-parallel p-barrel with amphipathic P-strands traversing the membrane (Fig. 4). The active-site catalytic residues are similar to a classical serine hydrolase triad except that in addition to the serine (Ser-144) and histidine (His-142), there is an asparagine (Asn-156) in place of the expected aspartic acid. Calcium at the active site is predicted to be involved in the reaction mechanism facilitating hydrolysis of the ester. 

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