Carboxylesterases active site

Urinary proteins were analyzed by SDS-polyacrylamide gel electrophoresis (PAGE), and a 70-kDa protein was identified as the major component of cat urine (Fig. 4.1 A). Comparative analysis of urinary proteins in several other mammals such as humans, mice, dogs, and cattle did not detect a 70-kDa protein. Therefore, the 70-kDa protein was purified from cat urine and characterized by biochemical methods (Miyazaki, Kamiie, Soeta, Taira and Yamashita 2003). Analysis of tissue distribution indicated that the 70-kDa protein is expressed in the kidney in a tissue-specific manner and secreted from the proximal straight tubular cells of the kidney into the urine (Fig. 4.IB). A full-length cDNA for a 70-kDa protein was cloned from a cat kidney cDNA library. The cDNA clone encoded a polypeptide of 545 amino acid residues. The deduced amino acid sequence shared 47% identity with cat carboxylesterase (CES, EC 3.1.1.1), and contained both the CES family protein motif (EDCLY) and a conserved active site motif (GESAG) associated with... 

Organophosphates phosphorylate the OH group of the catalytic serine at the active site of B-esterases (see Sect. 3.3). The rate of dephosphorylation of the enzyme is very slow, thus, the organophosphate acts as a mechanism-based inactivator. B-Esterases are classified as carboxylesterases (EC 3.1.1.1). 

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). 

Various esterases exist in mammalian tissues, hydrolyzing different types of esters. They have been classified as type A, B, or C on the basis of activity toward phosphate triesters. A-esterases, which include arylesterases, are not inhibited by phosphotriesters and will metabolize them by hydrolysis. Paraoxonase is a type A esterase (an organophosphatase). B-esterases are inhibited by paraoxon and have a serine group in the active site (see chap. 7). Within this group are carboxylesterases, cholinesterases, and arylamidases. C-esterases are also not inhibited by paraoxon, and the preferred substrates are acetyl esters, hence these are acetylesterases. Carboxythioesters are also hydrolyzed by esterases. Other enzymes such as trypsin and chymotrypsin may also hydrolyze certain carboxyl esters. 

Another important problem is the development of insects resistant to insecticides. This often arises as a result of increased levels of carboxylesterases which hydrolyze both organophosphates and car-baryl.h/1 A mutation that changed a single active site glycine to aspartate in a carboxylesterase of a blowfly changed the esterase to an organophosphorus hydrolase which protected the fly against insecticides.)... 

The active site for human liver carboxylesterase (hCEl) encompasses the three amino acids, serine, glutamic acid, and histidine as shown in Figure 8.3. 

Figure 6. Activity of carboxylesterases measured in the midgut cells and gonads of adult C brunneus from two sites kept for 7 days on D. glomerata with different concentrations of cadmium. Explanations as in Fig. 1.

Mechanisms of Serine Hydrolases. Typical to enzymatic reactions, the enzyme (E) first binds its substrate (S) at the active site as an enzyme-substrate complex (E S). For the formation of the product P, the enzyme-catalyzed reaction then takes place through the mechanism typical of the enzyme. At the active site of serine hydrolases (lipases, carboxylesterases, and serine proteases), the catalytic machinery is called a cataljdic triad consisting of amino acid residues Ser, His, and either Asp or Glu (Fig. 5). In the E S complex, imidazole of His serves as a general acid/base catalyst, catalyzing the addition of the alcoholic hydroxyl of the serine residue to the carbonyl carbon of the acyl donor (R C02R, the first substrate S ). This leads both to the liberation of the first product P (R OH) and to the formation of the so-called acyl-enzyme intermediate. This ester intermediate then reacts with the second substrate (R OH), which leads to the... 

Drugs may also undergo hydrolysis by intestinal esterases (hydrolases), more specifically carboxylesterases (EC 3.1.1.1) in the intestinal lumen and at the brush border membrane [58, 59]. It has been shown that intestinal hydrolase activity in humans was closer to that of the rat than the dog or Caco-2 cells [60]. In these studies, six propranolol ester prodrugs and p-nitrophenylacetate were used as substrates, and the hydrolase activity found was ranked in the order human > rat Caco-2 cells > dog for intestinal microsomes. The rank order in hydrolase activity for the intestinal cytosolic fraction was rat > Caco-2 cells = human > dog. The hydrolase activity towards p-nitrophenylacetate and tenofovir disoproxil has also been reported in various intestinal segments from rats, pigs and humans. The enzyme activity in intestinal homogenates was found to be both site-specific (duodenum > jejunum > ileum > colon) and species-dependent (rat > man > Pig)-... 

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). 

Figure 13.44. Metabolic activation of capecitabine (50), a site-selective multistep prodrug of the antitumor drug 5-fluorouracil (5-FU) (53)Following oral absorption, the prodrug is hydrolyzed by liver carboxylesterase to a carbamic acid that spontaneously decarboxylates to 5 -deow-5-fluorocy-tidine (51). The latter is transformed into 5 -deoxy-5-fluorouridine (52) by cytidine deaminase present in the liver and tumors. The third activation step occurs selectively in tumor cells and involves the transformation to 5-FU (53), catalyzed by thymidine phosphorylase (221).

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