Project description:This study investigated the enantioselective metabolism of benoxacor, an ingredient of herbicide formulations, in microsomes or cytosol prepared from female or male rat livers. Benoxacor was incubated for ≤30 min with microsomes or cytosol, and its enantioselective depletion was measured using gas chromatographic methods. Benoxacor was depleted in incubations with active microsomes in the presence and absence of NADPH, suggesting its metabolism by hepatic cytochrome P450 enzymes (CYPs) and microsomal carboxylesterases (CESs). Benoxacor was depleted in cytosolic incubations in the presence of glutathione, consistent with its metabolism by glutathione S-transferases (GSTs). The depletion of benoxacor was faster in incubations with cytosol from male than female rats, whereas no statistically significant sex differences were observed in microsomal incubations. The consumption of benoxacor was inhibited by the CYP inhibitor 1-aminobenzotriazole, the CES inhibitor benzil, and the GST inhibitor ethacrynic acid. Estimates of the intrinsic clearance of benoxacor suggest that CYPs are the primary metabolic enzyme responsible for benoxacor metabolism in rats. Microsomal incubations showed an enrichment of the first eluting benoxacor enantiomer (E1-benoxacor). A greater enrichment occurred in incubations with microsomes from female (EF = 0.67 ± 0.01) than male rats (EF = 0.60 ± 0.01). Cytosolic incubations from female rats resulted in enrichment of E1-benoxacor (EF = 0.54 ± 0.01), while cytosolic incubations from male rats displayed enrichment of the second eluting enantiomer (E2-benoxacor; EF = 0.43 ± 0.01). Sex-dependent differences in the metabolism of benoxacor in rats could significantly impact ecological risks and mammalian toxicity. Moreover, changes in the enantiomeric enrichment of benoxacor may be a powerful tool for environmental fate and transport studies.

Project description:1. A new method was used to diminish the autoxidation of GSH. 2. The oxidation of GSH by liver homogenates was studied with regard to concentration of homogenate, concentration of GSH, time, pH and anaerobiosis. 3. GSH was oxidized by recombinations of the supernatant with microsomes and with mitochondria. Each fraction alone caused little oxidation. 4. Proteins in the supernatant were required to obtain the effect, and low-molecular-weight compounds in the same fraction increased its effect. 5. GSH diminished the formation of malonaldehyde in homogenates. 6. GSH prevented a stimulating effect of the supernatant on the formation of malonaldehyde in microsomes and in mitochondria. 7. The malonaldehyde formation in microsomes together with the supernatant did not start until the concentration of endogenous low-molecular-weight thiols had decreased to a low level. 8. It is suggested that part of the oxidation of GSH in homogenates is coupled to a mechanism that counteracts the peroxidation of membrane lipids.

Project description:Sesquiterpenes, 15-carbon compounds formed from three isoprenoid units, are the main components of plant essential oils. Sesquiterpenes occur in human food, but they are principally taken as components of many folk medicines and dietary supplements. The aim of our study was to test and compare the potential inhibitory effect of acyclic sesquiterpenes, trans-nerolidol, cis-nerolidol and farnesol, on the activities of the main xenobiotic-metabolizing enzymes in rat and human liver in vitro. Rat and human subcellular fractions, relatively specific substrates, corresponding coenzymes and HPLC, spectrophotometric or spectrofluorometric analysis of product formation were used. The results showed significant inhibition of cytochromes P450 (namely CYP1A, CYP2B and CYP3A subfamilies) activities by all tested sesquiterpenes in rat as well as in human hepatic microsomes. On the other hand, all tested sesquiterpenes did not significantly affect the activities of carbonyl-reducing enzymes and conjugation enzymes. The results indicate that acyclic sesquiterpenes might affect CYP1A, CYP2B and CYP3A mediated metabolism of concurrently administered drugs and other xenobiotics. The possible drug-sesquiterpene interactions should be verified in in vivo experiments.

Project description:Subcellular fractionation of rat liver. Animals were fed ad libitum and analyzed using the classical de Duve differential centrifugation scheme, with an addition step to create L1 and L2 fractions from the L pellet. Samples were digested with trypsin, labeled using iTRAQ8, pooled, and further fractionated as described in methods and protocols.

Project description:1. The metabolism of [1-14C]palmitate in rat liver was studied in a single-pass perfusion system at concentrations of 0.2 or 1 mM. 2. After the perfusion the liver was homogenized and the floating fat was isolated. The incorporation of [1-14C]palmitate into triacylglycerol in this pool increased 9-fold when the palmitate concentration in the medium was increased from 0.2 to 1 mM. In time studies with 1 mM-[1-14C]palmitate 75% of the total accumulation of triacylglycerol occurred in this pool. Our results support the concept that the floating-fat fraction contains the storage pool of triacylglycerol, i.e. the cytoplasmic lipid droplets. 3. In a particulate preparation consisting mainly of mitochondria and microsomal fraction the incorporation of [1-14C]palmitate into triacylglycerol was proportional to the fatty acid concentration. Triacylglycerol in the perfusate medium and in the particulate fraction was in isotopic equilibrium, which indicates that the particulate fraction contained the precursor pool for secreted triacylglycerol, i.e. the pool in endoplasmic reticulum and Golgi apparatus. 4. The oxidation to labelled water-soluble products and to CO2 was increased 14-fold by the 5-fold increase in palmitate concentration.

Project description:1. The aerobic loss of GSH added to the supernatant fraction from rat liver is much increased by including the microsome fraction, which both inhibits the concurrent reduction of the GSSG formed and also augments the net oxidation rate. 2. Oxidation occurs with a mixture of dialysed supernatant and a protein-free filtrate; the latter is replaceable by hypoxanthine and the former by xanthine oxidase, whereas fractions lacking this enzyme give no oxidation. 3. In all these instances augmentation occurs with microsomes, with fractions having urate oxidase activity and with the purified enzyme; uric acid and microsomes alone also support the oxidation. 4. Evidence implicating additional protein factors is discussed. 5. It is suggested that GSH oxidation by homogenate is linked through glutathione peroxidase to the reaction of endogenous substrate with supernatant xanthine oxidase and of the uric acid formed with peroxisomal urate oxidase.

Project description:A novel, reusable, cofactor-free, and mediator-free human liver microsomal bioreactor constructed on carbon nanostructure electrodes for stereoselective green syntheses of drug metabolites and specialty chemicals is reported here for the first time. Drug metabolites are useful for examining pharmaceutical and pharmacological properties of new drugs under development.

Project description:1. Rat-liver mitochondria showed a decrease in amino acid production after preparation in 0.25m-sucrose containing EDTA (1mm), but an increase in water content. When EDTA was replaced by Mn(2+) (1mm) or succinate (1mm), both amino acid production and water content were lowered, whereas preparation in 0.9% potassium chloride caused an increase in both. 2. Amino acid production by rat-liver homogenates prepared in 0.9% potassium chloride or 0.25m-sucrose was similar (q(amino acid) 0.047 and 0.042 respectively aerobically). After freezing-and-thawing q(amino acid) values were approximately doubled, and approached that of a homogenate prepared in water. 3. All cations tested inhibited amino acid production by mitochondria, Hg(2+) and Zn(2+) being the most effective in tris-hydrochloric acid buffer. In phosphate buffer Mg(2+) and Mn(2+) had no effect. Of the anions tested only pyrophosphate and arsenate had any inhibitory effect at final concn. 1mm. 4. Iodosobenzoate (1mm) and p-chloromercuribenzenesulphonate (1mm) inhibited mitochondrial amino acid production by 70-80%, whereas soya-bean trypsin inhibitor, EDTA and di-isopropyl phosphorofluoridate inhibited by a maximum of 30%. Respiratory inhibitors had no effect. 5. Rat-liver homogenate and subcellular fractions each showed an individual pattern of inhibition when a series of inhibitors was tested. 6. Amino acid production by mitochondria was decreased by up to 50% in the presence of oxidizable substrate, apart from alpha-glycerophosphate and palmitate, which had no effect. CoA stimulated amino acid production in tris-hydrochloric acid but not in phosphate buffer, alpha-oxoglutarate abolishing the stimulation. 7. Cysteine and glutathione stimulated amino acid production by whole mitochondria by 30%, but only reduced glutathione stimulated production in broken mitochondria. 8. Adrenocorticotrophic hormone and growth hormone stimulated mitochondrial amino acid production by 21-24%, whereas insulin inhibited production by 25%. 9. Coupled oxidative phosphorylation increased amino acid production by up to 154% at 25 degrees and 40 degrees . The increase was abolished by 2,4-dinitrophenol. 10. Amino acid incorporation in mitochondria was accompanied by an increase in amino acid production, both being decreased by chloramphenicol. 11. Mitochondrial production of ninhydrin-positive material was increased in the presence of albumin. The biggest increase was noted for the soluble fraction of broken mitochondria. No increase was found in the presence of (14)C-labelled algal protein or denatured mitochondrial protein.

Project description:Although most glycosphingolipids (GSLs) are thought to be located in the outer leaflet of the plasma membrane, recent evidence indicates that GSLs and their precursor, ceramide, are also associated with intracellular organelles and, particularly, mitochondria. GSL biosynthesis starts with the formation of ceramide in the endoplasmic reticulum (ER), which is transported by controversial mechanisms to the Golgi apparatus, where stepwise addition of monosaccharides on to ceramides takes place. We now report the presence of GSL-biosynthetic enzymes in a subcompartment of the ER previously characterized and termed 'mitochondria-associated membrane' (MAM). MAM is a membrane bridge between the ER and mitochondria that is involved in the biosynthesis and trafficking of phospholipids between the two organelles. Using exogenous acceptors coated on silica gel, we demonstrate the presence of ceramide glucosyltransferase (Cer-Glc-T), glucosylceramide galactosyltransferase and sialyltransferase (SAT) activities in the MAM. Estimation of the marker-enzyme activities showed that glycosyltransferase activities could not be ascribed to cross-contamination of MAM by Golgi membranes. Cer-Glc-T was found to have a marked preference for ceramide bearing phytosphingosine as sphingoid base. SAT activities in MAM led to the synthesis of G(M3) ganglioside and small amounts of G(D3). G(M1) was also synthesized along with G(M3) upon incubation of the fraction with exogenous unlabelled G(M3), underlying the presence of other sphingolipid-specific glycosyltransferases in MAM. On the basis of our results, we propose MAM as a privileged compartment in providing GSLs for mitochondria.

Project description:Rat, mouse and human liver microsomes and S9 fractions were analyzed using an optimized method combining ion exchange fractionation of digested peptides, and ultra-high performance liquid chromatography (UHPLC) coupled to high resolution tandem mass spectrometry (HR-MS/MS). The mass spectrometry proteomics data have been deposited to the ProteomeXchange Consortium (http://proteomecentral.proteomexchange.org) via the PRIDE partner repository (Vizcaíno et al., 2013 [1]) with the dataset identifiers PXD000717, PXD000720, PXD000721, PXD000731, PXD000733 and PXD000734. Data related to the peptides (trypsin digests only) were also uploaded to Peptide Atlas (Farrah et al., 2013 [2]) and are available with the dataset identifiers PASS00407, PASS00409, PASS00411, PASS00412, PASS00413 and PASS00414. The present dataset is associated with a research article published in EuPA Open Proteomics [3].