Esterases, hydrolytic action

One of the most important hydrolases is acetylcholine esterase (cholinesterase). Acetylcholine is a potent neurotransmitter for voluntary muscle. Nerve impulses travel along neurons to the synaptic cleft, where acetylcholine stored in vesicles is released, carrying the impulse across the synapse to the postsynaptic neuron and propagating the nerve impulse. After the nerve impulse moves on, the action of the neurotransmitter molecules must be stopped by cholinesterase, which hydrolyzes acetylcholine to choline and acetic acid. Some dangerous toxins such as the exotoxin of Clostridium botulinum and saxitoxin interfere with cholinesterase, and many nerve agents such as tabun and sarin act by blocking the hydrolytic action of cholinesterase, see also Enzymes Hydrolysis. 

In accordance with the theory of Yamamoto et ai, nicotine acts in the organism of warm-blooded animals and insects as the mimic of acetylcholine. The nicotinium ion is attached through the positive charge of the pyrrolidine nitrogen atom to the anionic site of the acetylcholine receptor, and then nicotine penetrates in the form of the free base through the synaptic ion barrier. However, nicotine, in contrast to acetylcholine, is not subject to the hydrolytic action of acetylcholine esterase (Yamamoto, 1965 Hamilton, 1963). 

Since the structures of BCNU and its carbamate analog are identical except for the O-for-NH substitution, this position is clearly the key to the extreme biological reactivity of the latter compound. This point is reinforced by the quite similar in vivo elimination rates of the nitroso-nitrogen of BCNC and nitrosocarbaryl despite the differences in their end groups. The observed reactivity of these compoimds may result from the hydrolytic action of esterases, which are known to attack the C—O bond in carbamate insecticides (38). 

Hydrolases. Enzymes catalysing the hydrolytic cleavage ofC —O, C —N and C —C bonds. The systematic name always includes hydrolase but the recommended name is often formed by the addition of ase to the substrate. Examples are esterases, glucosidases, peptidases, proteinases, phospholipases. Other bonds may be cleaved besides those cited, e.g. during the action of sulphatases and phosphatases. 

Although the hydrolysis of esters with lipases and esterases represents the most common process to obtain chiral intermediates for the synthesis of pharmaceuticals, proteases and other hydrolytic enzymes such as epoxide hydrolases and nitrilases have also been used for this purpose. We show here a few representative examples of the action of these biocatalysts that have been recently published. 

The use of enzymes and whole cells as catalysts in organic chemistry is described. Emphasis is put on the chemical reactions and the importance of providing enantiopure synthons. In particular kinetics of resolution is in focus. Among the topics covered are enzyme classification, structure and mechanism of action of enzymes. Examples are given on the use of hydrolytic enzymes such as esterases, proteases, lipases, epoxide hydrolases, acylases and amidases both in aqueous and low-water media. Reductions and oxidations are treated both using whole cells and pure enzymes. Moreover, use of enzymes in sngar chemistiy and to prodnce amino acids and peptides are discnssed. 

Hydrolytic reactions. There are numerous different esterases responsible for the hydrolysis of esters and amides, and they occur in most species. However, the activity may vary considerably between species. For example, the insecticide malathion owes its selective toxicity to this difference. In mammals, the major route of metabolism is hydrolysis to the dicarboxylic acid, whereas in insects it is oxidation to malaoxon (Fig. 5.12). Malaoxon is a very potent cholinesterase inhibitor, and its insecticidal action is probably due to this property. The hydrolysis product has a low mammalian toxicity (see chap. 7). 

Stereospecific Michael addition reactions also may be catalyzed by hydrolytic enzymes (Scheme 2.205). When ot-trifluoromethyl propenoic acid was subjected to the action of various proteases, lipases and esterases in the presence of a nucleophile (NuH), such as water, amines, and thiols, chiral propanoic acids were obtained in moderate optical purity [1513]. The reaction mechanism probably involves the formation of an acyl enzyme intermediate (Sect. 2.1.1, Scheme 2.1). Being an activated derivative, the latter is more electrophilic than the free carboxylate and undergoes an asymmetric Michael addition by the nucleophile, directed by the chiral environment of the enzyme. In contrast to these observations made with crude hydrolase preparations, the rational design of a Michaelase from a lipase-scaffold gave disappointingly low stereoselectivities [1514-1517]. 

---