Lipase, Another Catalytic Triad Mechanism

The mechanism of lipase action can be broken down into the following steps [Pg.266]

adsorption of the lipase to the interface, which is called interfacial activation, and is the big difference between esterases and lipases [Pg.266]

The location of the acyl chain is of primary importance in the binding process because of its size. Due to the movement of lid during interfacial activation, a hydrophobic trench is created between the lid and enzyme surface. The trench size is ideal to accommodate the acyl chain. Interactions between the non-polar residues of the trench and the non-polar acyl chain stabilize the coupling. It has been postulated that the configuration of the trench is responsible for substrate specificity. This hypothesis seems plausible since lipases usually discriminate against certain acyl chain lengths, degrees of unsaturation, and location of double bonds in the chain. Any of these factors could affect the interaction between the acyl chain and the trench. [Pg.267]

The carbonyl group binds to the enzyme near the active site. A pocket is created at the active site that is of the proper size to accommodate the carbonyl group. The carbonyl is also attracted to the pocket, owing to hydrogen bonding with the residues near the catalytic triad. When the carbonyl group is in position near the active site, the chemical reaction can occur. [Pg.267]

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. [Pg.172]

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