Quantitation of lead-210 (210Pb) using lead-203 (203Pb) as a "Massless" yield tracer.

Determination of Pb-210 (210Pb) in aqueous solution is a common radioanalytical challenge in environmental science. Widely used methods for undertaking these analyses (e.g., ASTM D7535) rely on the use of stable lead (Pb) as a yield tracer that takes into account losses of 210Pb that inevitably occur during elemental/radiochemical separations of the procedures. Although effective, these methods introduce technical challenges that can be difficult to track and potentially introduce uncertainty that can be difficult to quantify. Examples of these challenges include interference from endogenous stable Pb in complex sample matrices; contamination of stable Pb carrier with 210Pb; and high detection limits due to counting efficiency limitations. We hypothesized that many of these challenges could be avoided by the use of the electron-capture, gamma-emitting isotope, 203Pb as a chemical yield tracer in the analysis of 210Pb. A series of experiments were performed to evaluate the efficacy of 203Pb as a tracer. Four different matrices were analyzed, including a complex matrix (hydraulic-fracturing produced fluids); and samples comprising less complicated matrices (i.e., river water, deionized water, and tap water). Separation techniques and counting methodologies were also compared and optimized. Due to a relatively short-half life (52 h), 203Pb tracer is effectively massless for the purposes of chemical separations, allowing for reduced chromatography column resin bed volumes. Because 203Pb is a gamma emitter (279 keV; 81% intensity), recovery can be determined non-destructively in a variety of matrices, including liquid scintillation cocktail. The use of liquid scintillation as a counting methodology allowed for determination of 210Pb activities via 210Pb or 210Po; and recoveries of greater than 90% are routinely achievable using this approach. The improved method for the analysis of 210Pb in aqueous matrices allows for the analysis of complex matrices, at reduced cost, while providing greater counting flexibility in achieving acceptable detections limits.

Vitamin K-dependent carboxylase: mRNA distribution and effects of vitamin K-deficiency and warfarin treatment.

A cDNA encoding vitamin K-dependent gamma-glutamyl carboxylase was cloned from a human Hep G2 cDNA library. The RNA transcript of the enzyme was found to be widely distributed in various human and rat tissues with liver showing the highest level. The carboxylase transcription in liver was not affected in rats treated with a single dose of warfarin (10 mg/kg) when measured up to 48 hours after the dose, though, at 12 hours, carboxylase activity measured in liver microsomes was elevated 5.4 fold over controls (p < 0.001). In rats fasted for 72 hours there was no affect on transcription in the liver while hepatic carboxylase activity increased 4.1 fold (p < 0.001). These data suggest that the increase in activity of the liver carboxylase in warfarin treated or fasted rats was not regulated by transcription but more likely was due to a posttranscriptional mechanism.

S-methyl-N,N-diethylthiocarbamate sulfoxide and S-methyl-N,N-diethylthiocarbamate sulfone, two candidates for the active metabolite of disulfiram.

The mechanism of action of disulfiram involves inhibition of hepatic aldehyde dehydrogenase (ALDH). Although disulfiram inhibits ALDH in vitro, it is believed that the drug is too short-lived in vivo to inhibit the enzyme directly. The ultimate inhibitor is thought to be a metabolite of disulfiram. In this study, we examined the effects of S-methyl-N,N-diethylthiocarbamate (MeDTC) sulfoxide and S-methyl-N,N-diethylthiocarbamate sulfone (confirmed and proposed metabolites of disulfiram, respectively) on rat liver mitochondrial low K(m) ALDH. MeDTC sulfoxide and MeDTC sulfone, in 10-min incubations with detergent-solubilized mitochondria, inhibited ALDH activity with an IC50 (mean +/- SD) of 0.93 +/- 0.04 and 0.53 +/- 0.11 microM, respectively, compared with 7.4 +/- 1.0 microM for the parent drug disulfiram. Inhibition by MeDTC sulfone and MeDTC sulfoxide, both at 0.6 microM, was time-dependent, following apparent pseudo-first-order kinetics with a t1/2 of inactivation of 3.5 and 8.8 min, respectively. Dilution of ALDH inhibited by either sulfoxide or sulfone did not restore activity, an indication of irreversible inhibition. Addition of glutathione (50 to 1000 microM) to ALDH before the inhibitors did not alter the inhibition by MeDTC sulfoxide. In contrast, the inhibition by MeDTC sulfone was decreased > 10-fold (IC50 = 6.3 microM) by 50 microM of glutathione and almost completely abolished by 500 microM of glutathione. The cofactor NAD, in a concentration-dependent manner, protected ALDH from inhibition by MeDTC sulfoxide and MeDTC sulfone. In incubations with intact mitochondria, the potency of the two compounds was reversed (IC50 of 9.2 +/- 3.6 and 0.95 +/- 0.30 microM for the MeDTC sulfone and sulfoxide, respectively). Our results suggest that MeDTC sulfone is highly reactive with normal cellular constituents (e.g., glutathione), which may protect ALDH from inhibition, unless this inhibitor is formed very near the target enzyme. In contrast, MeDTC sulfoxide is a better candidate for the ultimate active metabolite of disulfiram, because it is more likely to be sufficiently stable to diffuse from a distant site of formation, such as the endoplasmic reticulum, penetrate the mitochondria, and react with ALDH located in the mitochondrial matrix.

Microtiter plate-based determination of multiple concentration-inhibition relationships.

The microtiter plate reader has been used to obtain data on the inhibition of aldehyde dehydrogenase over a wide range of inhibitor concentrations. Multiple reactions can be run simultaneously and assayed rapidly with repetitive determinations of enzyme activity using this technique. The microplate reader allows for the efficient generation of concentration-inhibition curves of excellent precision, using only small amounts of material under uniform experimental conditions. The microplate reader can be very useful for pharmacologic studies which make use of spectrophotometric assays.

S-methyl N,N-diethylthiocarbamate sulfone, a potential metabolite of disulfiram and potent inhibitor of low Km mitochondrial aldehyde dehydrogenase.

Disulfiram inhibits hepatic aldehyde dehydrogenase (ALDH) causing an accumulation of acetaldehyde after ethanol ingestion. It is thought that disulfiram is too short-lived in vivo to directly inhibit ALDH, but instead is biotransformed to reactive metabolites that inhibit the enzyme. S-Methyl N,N-diethylthiocarbamate (MeDTC) sulfoxide has been identified in the blood of animals given disulfiram and is a potent inhibitor of ALDH (Hart and Faiman, Biochem Pharmacol 46: 2285-2290, 1993). MeDTC sulfone is a logical metabolite of MeDTC sulfoxide. Therefore, we investigated the effects of MeDTC sulfone on the activity of rat hepatic low Km mitochondrial ALDH, the major enzyme in the metabolism of acetaldehyde. MeDTC sulfone inhibited the low Km mitochondrial ALDH in vitro with an IC50 of 0.42 +/- 0.04 microM (mean +/- SD, N = 5) compared with disulfiram, which had an IC50 of 7.5 +/- 1.2 microM under the same conditions. The inhibition of ALDH by MeDTC sulfone was time dependent. The decline in ALDH activity followed pseudo first-order kinetics with an apparent half-life of 2.1 min at 0.6 microM MeDTC sulfone. Inhibition of ALDH by MeDTC sulfone was apparently irreversible; dilution of the inhibited enzyme did not restore lost activity. The substrate (acetaldehyde, 80 microM) and cofactor (NAD, 0.5 mM) together completely protected ALDH from inhibition by MeDTC sulfone; substrate alone partially protected the enzyme. Addition of either thiol-containing compound glutathione (GSH) or dithiothreitol (DTT) to MeDTC sulfone before incubation with the enzyme increased the IC50 of MeDTC sulfone by 7- to 14-fold. Neither GSH nor DTT could restore lost ALDH activity after exposure of the enzyme to MeDTC sulfone. Results of these studies indicate that MeDTC sulfone, a potential metabolite of disulfiram, is a potent, irreversible inhibitor of low Km mitochondrial ALDH.

Simultaneous structure-activity determination of disulfiram photolysis products by on-line continuous-flow liquid secondary ion mass spectrometry and enzyme inhibition assay.

Disulfiram (DSF) is used in the treatment of recovering alcoholics and exerts its effect by inhibiting the enzyme aldehyde dehydrogenase (ALDH). We analyzed a mixture of products derived photochemically from DSF with on-line microbore HPLC-continuous-flow liquid secondary ion mass spectrometry (HPLC-CF-LSI-MS). By utilizing the post-HPLC column split of solvent flow, a small proportion (ca. 5%) was sent directly into the mass spectrometer, and the remainder was collected. Simultaneous MS analysis and enzyme inhibition studies on ALDH were then possible. Furthermore, using HPLC-CF-LSI-MS-MS, we were able to structurally characterize an interesting sulfine compound that inhibited ALDH.

Photolysis of sulfiram: a mechanism for its disulfiram-like reaction.

Sulfiram, a drug applied topically to treat scabies, produces effects similar to those of disulfiram after subsequent ingestion of ethanol. Disulfiram, used in aversion therapy in the treatment of alcoholism, inhibits hepatic aldehyde dehydrogenase (ALDH) causing an accumulation of acetaldehyde after ethanol ingestion. The increased tissue levels of acetaldehyde cause a spectrum of undesirable side-effects including flushing, nausea, vomiting, and tachycardia, which are referred to as the disulfiram reaction. Previous studies have shown that in vitro sulfiram is a very weak inhibitor of ALDH, but solutions of sulfiram markedly increase in potency with time. In the present study, fresh solutions of sulfiram were exposed to fluorescent room light under ambient conditions and analyzed at timed intervals by HPLC. At least eight products, including disulfiram, were formed in the light-exposed sulfiram solutions, but not in solutions kept in the dark. Structural characterization of two of the photolysis products was obtained by on-line microbore HPLC-mass spectrometry (mu LC-MS) and on-line microbore HPLC-tandem mass spectrometry (mu LC-MS/MS) using continuous flow-liquid secondary ion mass spectrometry (CF-LSIMS) as the primary ionization method. Sulfiram was converted to disulfiram at an initial rate of 0.7%/hr, and the formation of disulfiram correlated with the increase in ALDH inhibition in vitro. The results of this investigation show that while sulfiram is a weak inhibitor of ALDH in vitro, it is readily photoconverted to disulfiram, a very potent inhibitor of ALDH, which may explain the adverse reaction to ethanol after sulfiram therapy.

Diethyldithiocarbamate S-methylation: evidence for catalysis by human liver thiol methyltransferase and thiopurine methyltransferase.

Disulfiram is used in the treatment of alcoholism to inhibit the enzyme aldehyde dehydrogenase. Disulfiram is rapidly reduced in vivo to form diethyldithiocarbamate (DDC), and DDC can undergo methyl conjugation to form S-methyl-DDC. Human tissues contain two separate genetically regulated enzymes that can catalyze thiol S-methylation. Thiol methyltransferase (TMT) is a microsomal enzyme that preferentially catalyzes, the S-methylation of alipathic sulfhydryl compounds, whereas thiopurine methyltransferase (TPMT) is a cytoplasmic enzyme that preferentially catalyzes the S-methylation of aromatic and heterocyclic sulfhydryl compounds. Our experiments were performed to determine whether human liver microsomal and/or cytosolic preparations could catalyze the S-methylation of DDC, and, if so, to determine whether TMT or TPMT might be the enzymes involved. We found that both human liver microsomes and cytosol could catalyze DDC S-methylation. The microsomal activity displayed biphasic substrate kinetics, with apparent Km values for DDC of 7.9 and 1500 microM for the high- and low-affinity activities, respectively. The high-affinity activity had an apparent Km value for S-adenosyl-L-methionine, the methyl donor for the reaction, of 5.8 microM. The thermal inactivation profile and response to methyltransferase inhibitors of the high-affinity microsomal DDC S-methyltransferase activity were similar to those of human liver microsomal TMT. In addition, TMT activity and the activity catalyzing the S-methylation of DDC were highly correlated in 19 individual liver samples (rs = 0.956; P < .0001). Hepatic cytosolic DDC S-methyltransferase activity had an apparent Km value for DDC of 95 microM. The cytosolic enzyme which catalyzed DDC S-methylation and TPMT activity had similar thermal inactivation profiles, similar patterns of response to methyltransferase inhibitors and the two activities coeluted during ion exchange chromatography. Furthermore, the activities of TPMT and cytosolic DDC S-methyltransferase were highly correlated in 20 individual liver samples (rs = 0.963; P < .0001). These results were compatible with the conclusion that both TMT and TPMT could catalyze the S-methylation of DDC in the human liver. Because the activities of both TMT and TPMT are controlled by inheritance, our observations raise the possibility of pharmacogenetic variation in the biotransformation and therapeutic effect of DDC in humans.

Synthesis of mono- and diglucosiduronates of metabolites of deoxycorticosterone and corticosterone and analysis by a new mass spectrometric technique.

By condensing 3 alpha,21-dihydroxy-5 beta-pregnan-20-one, or its appropriate monoacetate, with methyl 2,3,4-tri-O-acetyl-1-bromo-1-deoxy-alpha-D-glucuronate in the Koenigs-Knorr reaction beta-D-glucosiduronates 10, 4, and 7 were obtained as polyacetate methyl esters. Alkaline hydrolysis of these substances cleaved the ester groups and gave the corresponding steroidal glucosiduronic acids 12, 6 and 8. Upon treatment with diazomethane, these acids produced the equivalent methyl esters. The C-3, the C-21 and the C-3,21 glucosiduronates of 3 alpha,21-dihydroxy-5 beta-pregnan-11,20-dione were prepared by previously reported methods and converted into the corresponding C-20 semicarbazones (14, 20 and 26). With C-20 stabilized by the semicarbazone group against reduction, it was possible to reduce the 11-oxo function in these substances to an 11 beta-hydroxyl group; after removal of the semi-carbazone moiety from these products at pH 2.0, glucosiduronic acids 18, 22 and 28 were obtained. The mass spectra of a representative group of the mono- and diglucosiduronic acids and esters were determined by utilizing fast atom bombardment and monitoring ions in both positive and negative modes of operation.

Chemical synthesis of glucuronidated metabolites of cortisol.

During in vivo metabolism the addition of six atoms of hydrogen to cortisone at the appropriate location and configuration can lead to formation of either 3 alpha,17,20 alpha,21-tetrahydroxy 5 beta-pregnan-11-one (cortolone) or 3 alpha,17,20 beta,21-tetrahydroxy-5 beta-pregnan-11-one (beta-cortolone). Likewise, metabolic reduction of cortisol can lead to formation of either 5 alpha-pregnane-3 alpha,11 beta,17,20 alpha,21-pentol (cortol) or the 20 beta isomer (beta-cortol). This paper describes the chemical syntheses of the C-3 beta-D-glucosiduronates of cortolone, beta-cortolone, cortol and beta-cortol-conjugates which are normal excretory products of man. The foregoing conjugates are characterized as free acids (or salts), as methyl esters and as polyacetate methyl esters.

C-3 glucosiduronates of metabolites of adrenal steroids.

On treatment with methyl 2,3,4-tri-O-acetyl-1-bromo-1-deoxy-alpha-D-glucuronate and silver carbonate, tetrahydrocortisone 21-acetate gave the corresponding 3-glucosiduronate triacetyl methyl ester. This product was converted into the 20-semicarbazone which, by treatment with alkali to hydrolyze the ester functions and acid to hydrolyze the semicarbazone moiety, gave tetrahydrocortisone 3-glucosiduronic acid. The acid was converted into the crystalline barium salt and into the methyl ester. An analogous series of reactions was carried out on tetrahydrocortexolone 21-acetate. Treatment of the 20-semicarbazone of tetrahydrocortisone 3-glucosiduronic acid with potassium borohydride reduced the 11-oxo function to an 11 beta hydroxyl group; acid-catalyzed removal of the semicarbazone group produced tetrahydrocortisol 3-glucosiduronic acid which also was obtained as the barium salt and the methyl ester.

Preparation of 3beta, 16beta-dihydroxyandrost-5-en-17-one: stabilization of its alpha-ketolic group toward alkali by formation of a semicarbazone.

Alkaline hydrolysis of a 16beta-acetoxy-17-oxo steroid is accompanied by almost complete rearrangement of the product to a 16-oxo-17beta-hydroxy steroid. Hydrolysis can be achieved without rearrangement by 1) formation of a C-17 semicarbazone, 2) alkaline removal of the acetate group, and 3) removal of the semicarbazone group in the presence of pyruvic acid-acetic acid. By employing this technique, the title compound was obtained from its diacetate in a yield of 65%.