Hydrolysis of diethyl-p-nitrophenylphosphate and ethyl-p-nitrophenylethylphosphonate by human sera

Inhibition of paraoxonase activity in human liver microsomes by exposure to EDTA, metals and mercurials

Inhibition of paraoxon hydrolase (paraoxonase) activity by 'in vitro' exposure to EDTA, Mg2+, Co2+, Ba2+, La3+, Zn2+, Cu2+, Hg2+, p-hydroxymercuribenzoate (p-OH-MB) and phenyl mercuric acetate (PMA) was investigated in human liver microsomes. Enzyme activity was totally inhibited by 1 mM EDTA in a time-dependent manner, in contrast to previous data obtained in rat liver where an EDTA-resistant fraction was detected. The possible influence of postmortem changes in these results was checked in a parallel experiment using rat livers with different postmortem intervals. From our results the existence in human liver of an EDTA-resistant fraction cannot be discarded. Ba, La and PMA showed immediate inhibition. By contrast the other compounds tested were time-dependent inhibitors. Ba and Zn showed the highest IC50 values. Cu and mercurials (Hg, p-OH-MB, PMA) were the most potent inhibitors of human liver paraoxonase. Kinetic analysis (Lineweaver-Burk and Dixon plots) indicated that different inhibitors exhibit different inhibition patterns: competitive (EDTA, Ba, La, Cu, p-OH-MB and PMA), non competitive (Zn) and mixed (Hg). The pretreatment of sample with dithiothreitol (DTT) protects against the inhibitory effect of mercurials. Furthermore after inhibition by mercurials the activity was restored by DTT. These results confirmed the essential role of the -SH groups to maintain the catalytic activity of paraoxonase and suggest the existence of two types of -SH groups that could differ in their localization.

Purification and characterization of paraoxon hydrolase from rat liver

Paraoxonase (paraoxon hydrolase), an enzyme that hydrolyses paraoxon (O,O-diethyl O-p-nitrophenyl phosphate), is located in mammals primarily in the serum and liver. Although considerable information is available regarding serum paraoxonase, little is known about the hepatic form of this enzyme. The present work represents the first study on the purification of rat liver paraoxonase. This enzyme has been purified 415-fold to apparent homogeneity with a final specific activity of 1370 units/mg using a protocol consisting of five steps: solubilization of the microsomal fraction, hydroxyapatite adsorption, chromatography on DEAE-Sepharose CL-6B, non-specific affinity chromatography on Cibacron Blue 3GA and anion exchange on Mono Q HR 5/5. The presence of Ca2+ and Triton X-100 in the buffers throughout the purification procedure was essential for maintaining enzyme activity. SDS/PAGE of the final preparation indicated a single protein-staining band with an apparent Mr of 45 000. N-terminal and internal amino acid sequences were determined and compared with those of paraoxonases from human and rabbit serum and mouse liver, showing a high similarity. The pH profile showed optimum activity at pH 8.5. The pH stability and heat inactivation of the enzyme were also studied. The Km for liver paraoxonase was 1.69 mM.

Differences in the kinetic properties, effect of calcium and sensitivity to inhibitors of paraoxon hydrolase activity in rat plasma and microsomal fraction from rat liver

The properties of a rat hepatic microsomal enzyme that hydrolyses O,O-diethyl-p-nitrophenylphosphate (paraoxon) were studied and compared to the paraoxon hydrolase activity found in rat plasma. The pH stability for both enzyme activities was optimum between pH 6.0 and 9.0. An overall analysis of the data showed that the microsomal fraction was less resistant to the effect of the pH than plasma. The kinetic constants for heat inactivation evaluated for paraoxonase in rat plasma and liver microsomal fraction indicate that paraoxonase tends to inactivate faster in rat liver microsomes than in rat plasma. The apparent activation energies of the heat inactivation process were 77.7 and 61.1 kcal/mol for rat plasma and microsomal fraction, respectively. Enzyme activity was lost after both dialysis and incubation with EDTA and partially restored by the addition of calcium. In rat plasma samples the requirement for calcium was absolute (essential activator) while in the microsomal fraction the reaction may occur, to a minimum extent, in the absence of the activator (non-essential activator). Calcium restored 85% activity when added immediately after EDTA; restored activity decreased when the time interval between addition of EDTA and calcium was increased. Other metals were not able to restore activity previously inhibited by EDTA or dialysis. The response to several inhibitors (EDTA, Mn, Co, Zn, Ba, Mg, Cu, La, Hg and p-hydroxy-mercuribenzoate) of rat plasma and microsomal fraction was studied, determining the type of inhibition and the inhibition constants. Plasma enzyme was always more resistant than liver sample to the effect of the inhibitors and showed different types of inhibition than the liver microsomal fraction. In general we found more differences than analogies between the rat plasma and liver enzyme which suggests the presence of two enzymes or two different forms of the same enzyme. Furthermore the existence of an EDTA-resistant fraction in rat liver microsomes suggests that more than one enzyme capable of hydrolysing paraoxon is present in the microsomal fraction of rat liver.

Heat inactivation of paraoxonase and arylesterase activities in human and rabbit serum

The heat inactivation of esterases in human and rabbit serum was followed at 50 and 55 degrees C by measuring the decrease of activity with paraoxon, phenylacetate and beta-naphthylacetate as substrates. The rate of inactivation measured with the three substrates was slightly, but significantly different, indicating that the substrates are hydrolysed by different enzymes.

Degradation by rat tissues in vitro of organophosphorus esters which inhibit cholinesterase

Hydrolytic "A"-esterase activities of various tissues of rat (plasma, liver, kidney, brain and intestinal mucosa) against selected OP esters of diverse structure as potential substrates (paraoxon, di-n-propyl paraoxon, di-n-butyl paraoxon, chlorpyrifos oxon, di-(4-phenyl butyl) phosphorofluoridate and the chiral isomers of ethyl 4-nitrophenyl phenylphosphonate) were studied. We have developed a sensitive and widely applicable assay depending on measuring decline in residual inhibitory power of any chosen OP against horse serum cholinesterase: for seven compounds examined so far I50s against BuChE ranged from 0.07 to 70 nM, and it is easy to monitor loss of OP starting from an initial 25 microM concentration. Progressive destruction rates were always highest in liver and plasma with activity sometimes detectable in kidney, brain but not in intestinal mucosa, but the ratios of activity between tissues differed for different substrates. At 25 microM/37 degrees/pH 7.2 hydrolysis rates ranged from 8500 nmol/min/g liver for di-(4-phenylbutyl) phosphorofluoridate down to 0.8 nmol/min for the butyl analogue of paraoxon; the rate for L(-) isomer of EPN oxon (23 nmol/min/g liver) was greater than 2x that for the D(+) isomer and for paraoxon. From our data we conclude that several OP hydrolases exist whose identity may be further characterised by use of selective substrates.

Stereoselective hydrolysis of soman in human plasma and serum

The contribution of various human serum and plasma fractions to the total hydrolysis rate constants of the four isomers of soman is studied. Spontaneous hydrolysis (as measured in buffer) occurs at a faster rate for the C(+)P(+)- and C(-)P(-)-isomers. A stereoselectively catalyzed hydrolysis of soman occurs in serum fractions IV and V (albumin). In fraction V the C(+)P(+)- and C(-)P(-)-isomers are hydrolyzed at a faster rate than their respective epimers, while in fraction IV-1 a stereoselective effect towards C(+)P(+)-soman is found. All the forementioned contributions, however, are negligible in comparison with the stereoselective enzymatic hydrolysis of the P(+)-isomers. The latter reaction is characterized by a significant lowering of the activation energy as compared with the spontaneous hydrolysis of the P(+)-isomers. Such a lowering in activation energy is not found for the hydrolysis of the P(-)-isomers in whole serum or plasma; hence it can be concluded that a phosphorylphosphatase hydrolyzes the P(+)-isomers in a stereoselective way, the P(-)-isomers either not being affected by this (these) enzyme(s) or the mechanism of catalysis being fundamentally different. This conclusion is in agreement with the observations on the influence of Hg2+ on the hydrolysis of soman in serum; the hydrolysis of the P(+)-isomers is significantly inhibited by 1 mM of Hg2+ while the P(-)-hydrolysis is unaffected by this concentration of Hg2+. The action of some potential inhibitors on this phosphorylphosphatase activity was studied. Iodoacetate did not inhibit nor did Ba2+, Sr2+, Co2+ or Mn2+ show a significant effect on the hydrolysis of the P(+)-isomers. On the other hand the hydrolytic activity in serum was nearly completely inhibited by EDTA but restored upon addition of Ca2+. These findings suggest that this enzymatic activity can be classified as an arylesterase (paraoxonase). Finally, the influence of pH on the hydrolytic activity shows a different pattern for C(+)P(+)- and C(-)P(+)-soman, which may suggest that more than one enzyme is involved in the degradation of soman.

Kinetics of heat inactivation of phenyl valerate hydrolases from hen and rat brain

Heat inactivation was studied at 45, 50, 55, and 60 degrees for all of the phenyl valerate hydrolases (PVase), including neurotoxic esterase (NTE) and inhibitor-resistant esterase (IRE), in homogenates of hen or rat brain or in preparations of hen brain microsomal membranes. Hen and rat brain homogenates were prepared in buffer (50 mM Tris/0.20 mM EDTA, pH 8.00, at 25 degrees). Hen brain microsomes were suspended either in buffer or in aqueous dimethyl sulfoxide (DMSO, 40%, w/v), or solubilized either in aqueous Triton X-100 (0.10%, w/v) or in 40% (w/v) DMSO. Enzyme activities were measured at 37 degrees using phenyl valerate as substrate. Each enzyme activity in all of the preparations exhibited biphasic heat inactivation kinetics. Apparent rate constants were calculated for the fast (kf) and slow (ks) reactions, along with the relative amounts of activity in each component (Af, As) expressed as percentages of the total activity. For a given preparation and temperature, respective values of kf or ks were similar for PVase, NTE, and IRE, with a mean kf/ks ratio of 52 across all preparations. Af and As were a function of temperature. Mean values of the apparent activation energies (Ea) for all activities and preparations were 44 and 25 kcal/mol for the fast and slow inactivation reactions respectively. These results indicate that all phenyl valerate hydrolases in hen and rat brain undergo a common heat-induced structural change leading to loss of enzymic activity.

A study of the polymorphism and ethnic distribution differences of human serum paraoxonase

The enzyme serum paraoxonase shows a polymorphism in Europeans which is governed by two alleles. The first allele has a gene frequency plow of 0.716-0.777, and is manifested as a low activity group in homozygotes. More than 50% of all European test subjects can be included in this group. A second allele with a gene frequency qhigh of 0.223-0.284 was found in typical European distributions and is manifested in both the form of a second heterozygotic and a third homozygotic group with high activities. The Hardy-Weinberg rule for a two-allele model is valid for the distribution. The gene frequency plow of the first allele decreases as one moves from Europe in the direction of Africa and Asia. In typical Mongoloid and Negroid collectives, less than 10% of the population can be included in the low-activity group, a group which is not even demonstrable in the Aborigines of Australia. The serum paraoxonase of the Aborigine population shows unimodal distribution. The validity of the Hardy-Weinberg rule for a three-allele model must be rejected in all examined collectives. Human serum paraoxonase shows neither age-related changes in activity nor sex-dependent activity differences.