Regulation of two rat liver microsomal carboxylesterase isozymes: species differences, tissue distribution, and the effects of age, sex, and xenobiotic treatment of rats

Species differences for stereoselective hydrolysis of propranolol prodrugs in plasma and liver

Species differences and substrate specificities for the stereoselective hydrolysis of fifteen O-acyl propranolol (PL) prodrugs were investigated in pH 7.4 Tris-HCl buffer and rat and dog plasma and liver subfractions. The (R)-isomers were preferentially converted to propranolol (PL) in both rat and dog plasma with the exception of isovaleryl-PL in rat plasma, although the hydrolytic activities of prodrugs in rat plasma were 5-119-fold greater than those in dog plasma. The prodrugs with promoieties (C(=O)CH(R)CH3) based on propionic acid showed marked preference for hydrolysis of the (R)-enantiomers in plasma from both species (R/S ratio 2.5-18.2). On the other hand, the hepatic hydrolytic activities of prodrugs were greater in dog than rat, especially in cytosolic fractions. The hydrolytic activity was predominantly located in microsomes of the liver in rat, while the cytosol also contributed to hepatic hydrolysis in dog. Hepatic microsomal hydrolysis in dog showed a preference for the (R)-isomers except acetyl- and propionyl-PL. Interestingly, in rat liver all types of prodrugs with substituents of small carbon number showed (S)-preference for hydrolysis. The hydrolyses of (R)- and (S)-isomers of straight chain acyl esters in rat liver microsomes were linearly and parabolically related with the carbon number of substituents, respectively, while these relationships were linear for both isomers in dogs.

Metabolism of ethyl carbamate by pulmonary cytochrome P450 and carboxylesterase isozymes: involvement of CYP2E1 and hydrolase A

The lung is highly susceptible to ethyl carbamate (EC)-induced tumorigenesis. Our goal in this study was to investigate the in vitro isozyme-selective metabolism of EC in lung microsomes by cytochrome P450 and carboxylesterase enzymes. Our results showed that incubations with EC produced significant reduction in p-nitrophenol (PNP) hydroxylation and N-nitrosodimethylamine (NDMA) demethylation; there were no alterations in 7-pentoxyresorufin- and 7-ethoxyresorufin O-dealkylase activities. Reaction of microsomes with an inhibitory CYP2E1 antibody and subsequent reaction with EC abolished the EC-induced diminution in NDMA demethylase activity. Carboxylesterase activity, as assessed by hydrolysis of p-nitrophenyl acetate, was significantly decreased in microsomes incubated with EC. Reactions with EC in conjunction with the carboxylesterase inhibitors, paraoxon (PAX) or phenylmethylsulfonyl fluoride (PMSF), abolished the EC-induced decrease in carboxylesterase activity; PAX is a broad-spectrum carboxylesterase inhibitor, whereas PMSF is a specific inhibitor of hydrolase A, a carboxylesterase isozyme. Incubations of EC in combination with either PAX or PMSF exacerbated the EC-induced reduction in PNP hydroxylase and NDMA demethylase activities. Alterations in immunodetectable CYP2E1 protein levels were not apparent in microsomes incubated with EC alone, but the amounts were decreased in reactions with EC in conjunction with either PAX or PMSF. Immunoblotting with antibodies for the carboxylesterase isozymes, hydrolase A and B, revealed loss of immunodetectable hydrolase A in microsomes incubated with EC, PAX, or PMSF. However, immunodetectable hydrolase B was only decreased in microsomes reacted with PAX but not with PMSF or EC. These findings correlated with our covalent binding data, which showed that levels of binding of [14C-ethyl]EC to lung microsomes were significantly higher in incubations conducted in conjunction with PAX or PMSF, compared with control levels. Antibody inhibition of the CYP2E1 enzyme significantly reduced the extent of binding. Our results demonstrated that EC metabolism in lung microsomes, as estimated from magnitudes of covalent binding, is mediated by the P450 isozyme CYP2E1 and the carboxylesterase isozyme hydrolase A.

Physiologically based modeling of vinyl acetate uptake, metabolism, and intracellular pH changes in the rat nasal cavity

Chronic inhalation exposure to vinyl acetate (VA) causes lesions in the nasal cavity of the rat. This effect appears to be related to tissue exposure to either acetaldehyde (AAld) or acetic acid (AA) metabolites of VA or both. A physiologically based pharmacokinetic model was constructed to describe the deposition of VA in the nasal cavity of the rat and provide estimates of regional tissue exposure to VA, AAld, and AA. Since formation of AA in the nasal tissue should cause intracellular acidification, a submodel which describes free intracellular hydrogen ion concentration and intracellular pH (pHi) changes was linked to the VA model. The dosimetry model was applied to data from a series of experiments designed to measure the uptake and metabolism of VA in the isolated upper respiratory tract of the rat at exposure concentrations ranging from 73 to 2190 ppm. Extraction of VA from the nasal cavity was nonlinear with respect to exposure concentration and ranged from 36 to 94%, with the greatest deposition occurring at the lowest VA concentrations. Pretreatment with bis(p-nitrophenyl)phosphate, an inhibitor of carboxylesterases, significantly reduced fractional deposition of VA compared to naive rats exposed to similar VA concentrations. The best model fits for VA extraction and AAld appearance were achieved when a second carboxylesterase isozyme, with high-affinity characteristics, was included. Simulations of 6-h inhalation exposures to VA predicted that the order of nasal tissue exposures will be to AA > AAld > VA. In addition, based on measured tissue hydrolysis rates, sufficient acid should be formed by the metabolism of VA to cause significant changes in pHi. VA exposures of 200 and 600 ppm were predicted to result in a pHi of less than 7.2 and 6.7, respectively. This model provides nasal dosimetry estimates needed to develop mechanistically based risk assessment approaches for human exposures to VA vapor.

Gender-specific differences in activity and protein levels of cocaine carboxylesterase in rat tissues

The gender-specific differences in the content of cocaine methyl esterase and ethyl transferase activities are examined in rat tissues and related to differences in hydrolase A protein in rat liver, lung, and kidney reported previously. The rat hydrolase A catalyzes the conversion of cocaine to benzoylecgonine and the ethyl transesterification of cocaine to form cocaethylene. An HPLC assay was used to quantitate and compare cocaine esterase activities in male and female rat tissues. The cocaine methyl esterase and ethyl transferase activities are 1.4 to 2.5 fold greater in male than in female liver and slightly greater in female than in male lung. No gender-specific differences were detected in the kidney. Gel electrophoresis was used to separate three non-specific carboxylesterases (hydrolases A, B, and C) in rat tissues and the isoenzymes were visualized with a hydrolase activity stain using 4-methylumbelliferyl acetate as substrate. The activity of cocaine methyl esterase and content of hydrolase A protein are not consistently different in the lung or the kidney of male versus female rats. Activity of hydrolase A in gels of male liver is greater than in female liver. Similarly, the content of the corresponding hydrolase A immunoreactive protein in male liver is 1.6 fold greater than in female liver. In contrast to hydrolase A, hydrolase C activity is greater in gels of female than male liver extracts. The greater content of cocaine methyl esterase and ethyl transferase activity in male versus female rat livers suggests that there may be gender-specific differences in pharmacokinetics of cocaine metabolism and extent of cocaine-induced hepatotoxicity in rats.

Arylacetamide deacetylase activity towards monoacetyldapsone. Species comparison, factors that influence activity, and comparison with 2-acetylaminofluorene and p-nitrophenyl acetate hydrolysis

The deacetylation of monoacetyldapsone (MADDS) was examined in liver microsomes and cytosol from male Sprague-Dawley rats, Golden Syrian hamsters, and Swiss Albino mice. All three rodent species demonstrated greater MADDS deacetylation activity in liver microsomes than in liver cytosol. Further investigations were conducted in hamsters. The velocity of MADDS deacetylation in major organs in the hamster was greatest in the intestine, followed by the liver and kidney. The effect of pretreatment with common inducers on liver microsomal deacetylation activity was also examined in the hamster. Phenobarbital, 100 mg/kg/day x 3 days, did not alter activity, while dexamethasone at the same dose reduced 2-acetylaminofluorene (2-AFF), MADDS, and p-nitrophenyl acetate (NPA) hydrolysis by at least 50%. Due to a previous report that KI activated the deacetylation of an arylacetamide in vitro (Khanna et al., J Pharmacol Exp Ther 262: 1225-1231, 1992), the effects of the halides KF, KCl, KBr and KI on MADDS hydrolysis in vitro were tested. Of the halides studied, only KF altered MADDS hydrolysis, resulting in an almost complete inhibition of deacetylase activity at 50 mM (with the initial concentration of MADDS at 0.6 mM) with an IC50 = 0.16 mM. Cornish-Bowden and Dixon plots indicated that the inhibition exerted by KF was non-competitive. The rank order of inhibitor potencies was constructed using phenylmethylsulfonyl fluoride (PMSF), bis(p-nitrophenyl)phosphate (BNPP), physostigmine, and KF with 2-AFF, MADDS, and NPA as substrates. Different rank order potencies were obtained for each of the substrates tested. The substrates 2-AFF, MADDS, and NPA did not act as competitive inhibitors on the hydrolysis rates of each other. Liver microsomal arylacetamide deacetylase activity was greater in male hamsters than in females with either MADDS or 2-AAF as substrates; however, hydrolysis of NPA was similar in both male and female hamsters. These data support the hypothesis that the enzyme which catalyzes the hydrolysis of MADDS differs from that catalyzing either 2-AAF or NPA hydrolysis.

Debenzoylating and deacetylating activities of rat liver and mammary gland microsomes. Effect of ovariectomy

This study compared the rates of N-deacylations of N-hydroxy-N-2-fluorenylbenzamide (N-OH-2-FBA) with those of its analogue, N-hydroxy-N-2-fluorenylacetamide (N-OH-2-FAA), by the mammary gland (tumor target for both compounds) and the liver of female Sprague-Dawley rats and examined the effect of ovariectomy on these activities. N-Debenzoylation of N-OH-2-FBA was catalyzed by the mammary and liver microsomes of 50-day-old female rats at similar rates (approximately 24 nmol/min/mg). The activity of both tissues increased (up to 1.8 times) after ovariectomy at 42, 32 and, especially, 22 days of age. The rapid hydrolysis appeared to be unique for the benzoyl group since N-OH-2-FAA was deacylated only approximately 0.05 and 0.004 times as fast by the liver and mammary microsomes, respectively, and these low rates were unaffected by ovariectomy. Since such substrate specificity would be of significance in the metabolism of xenobiotics and drug design, esterase activity and its sensitivity to ovariectomy at 22 days of age were examined with several acetylated and benzoylated substrates in the liver and mammary microsomes and compared with those of male liver. Tissues of rats of both sexes had a greater capacity to hydrolyze carboxyl esters than amides. Expect for N-2-fluorenylacetamide (2-FAA) and o-nitrophenylacetate (o-NPA), all substrates were hydrolyzed by liver microsomes of the male up to 3.9 times faster than by those of the female. Microsomes of female liver hydrolyzed acetylated substrates 1.2 to 25 times faster than benzoylated analogues except for N-OH-2-FBA and benzamide. By contrast, mammary gland microsomes hydrolyzed benzoylated compounds 1.4 to 333 times faster except for 2-naphthyl benzoate. Respective rates of hydrolysis of o-NPA by microsomes of liver and mammary gland were 1.7 and 0.6 times those of p-NPA. After ovariectomy, deacylating activities increased (up to 1.6 times) except for those of 2-FAA and acetanilide. All deacylations were > 98% inhibited by 0.1 mM paraoxon, indicating catalysis by serine hydrolases. The results suggest involvement of multiple carboxylesterases and indicate that certain benzoylated xenobiotics may have a greater effect on the mammary gland than acetylated xenobiotics because of their greater vulnerability to hydrolysis by esterases of mammary gland.

Rat serum carboxylesterase. Cloning, expression, regulation, and evidence of secretion from liver

Multiple forms of carboxylesterase have been identified in rat liver, and five carboxylesterases (designated hydrolases A, B, C, S, and egasyn) have been cloned. Hydrolases A, B, C, and egasyn all have a C-terminal consensus sequence (HXEL) for retaining proteins in the endoplasmic reticulum, and these carboxylesterases are found in rat liver microsomes. In contrast, hydrolase S lacks this C-terminal consensus sequence and is presumed to be secreted. In order to test this hypothesis, a polyclonal antibody was raised against recombinant hydrolase S from cDNA-directed expression in Escherichia coli. In addition to hydrolases A, B, and C (57-59 kDa), this antibody recognized a 67-kDa protein in rat liver microsomes and a 71-kDa protein in rat serum. The 71-kDa protein detected in rat serum was also detected in the extracellular medium from primary cultures of rat hepatocytes. Non-denaturing gel electrophoresis with staining for esterase activity showed that a serum carboxylesterase comigrated with the 71-kDa protein. Immunoprecipitation of the 71-kDa enzyme from rat serum decreased esterase activity toward 1-naphthylacetate and para-nitrophenylacetate. The 71-kDa protein immunoprecipitated from rat serum had an N-terminal amino acid sequence identical to that predicted from the cDNA encoding hydrolase S, providing further evidence that hydrolase S is synthesized in and secreted by the liver. The levels of the 67-kDa protein in rat liver microsomes and the levels of the 71-kDa protein in rat serum were co-regulated. Deglycosylation of microsomes and serum converted the 67- and 71-kDa proteins to a 58-kDa peptide, which matches the molecular mass calculated from the cDNA for hydrolase S. These results suggest that the 67-kDa protein in liver microsomes is a precursor form of hydrolase S that undergoes further glycosylation before being secreted into serum. In rats, liver appears to be the only source of hydrolase S because no mRNA encoding hydrolase S could be detected in several extrahepatic tissues. Serum carboxylesterases have been found to play an important role in lipid metabolism and detoxication of organophosphates, therefore, the secretion of hydrolase S and the modulation of its expression by xenobiotics may have physiological as well as toxicological significance.