Norman Huebert scite author profile

Metabolic syndrome and T2D produce significant health and economic issues. Many available animal models have monogenic leptin pathway mutations that are absent in the human population. Development of the ZDSD rat model was undertaken to produce a model that expresses polygenic obesity and diabetes with an intact leptin pathway. A lean ZDF rat with the propensity for beta-cell failure was crossed with a polygenetically obese Crl:CD (SD) rat. Offspring were selectively inbred for obesity and diabetes for >30 generations. In the current study, ZDSD rats were followed for 6 months; routine clinical metabolic endpoints were included throughout the study. In the prediabetic metabolic syndrome phase, ZDSD rats exhibited obesity with increased body fat, hyperglycemia, insulin resistance, dyslipidemia, glucose intolerance, and elevated HbA1c. As disease progressed to overt diabetes, ZDSD rats demonstrated elevated glucose levels, abnormal oral glucose tolerance, increases in HbA1c levels, reductions in body weight, increased insulin resistance with decreasing insulin levels, and dyslipidemia. The ZDSD rat develops prediabetic metabolic syndrome and T2D in a manner that mirrors the development of metabolic syndrome and T2D in humans. ZDSD rats will provide a novel, translational animal model for the study of human metabolic diseases and for the development of new therapies.

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Biochemical and clinical effects of γ‐vinyl GABA in patients with epilepsy

Schechter¹,

Hanke²,

Grove³

et al. 1984

Neurology

151

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In a pilot single-blind study, gamma-vinyl GABA, an enzyme-activated irreversible inhibitor of GABA-transaminase (GABA-T), was administered orally to 10 epileptic patients who were refractory to conventional anticonvulsant therapy. Daily doses of 1 g and 2 g for 2 weeks each as add-on therapy were followed by 2 weeks of placebo treatment. CSF obtained from suboccipital and lumbar punctures demonstrated dose-related increases in concentrations of free and total GABA and homocarnosine with treatment, but no changes in 5-hydroxyindoleacetic acid or homovanillic acid levels, indicating effective and selective CNS GABA-T inhibition. These biochemical changes were associated with decreased seizure frequency in seven patients, decreased seizure severity in one, no change in one, and possible worsening in one. gamma-Vinyl GABA may be useful in the therapy of epilepsy.

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Detection of a Novel Reactive Metabolite of Diclofenac: Evidence for Cyp2c9-Mediated Bioactivation via Arene Oxides

Yan

Li²,

Huebert³

et al. 2005

Drug Metab Dispos

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ABSTRACT:A new glutathione adduct (M4) was tentatively identified, likely as 2-hydroxy-3-(glutathione-S-yl)-monoclofenac, using liquid chromatography-tandem mass spectrometry analysis of incubations of diclofenac with human liver microsomes. The same conjugate was not detected in incubations with either rat or monkey liver microsomes. Formation of M4 was mediated specifically by CYP2C9 in human liver microsomes, as evidenced by the following observations: 1) cDNA-expressed CYP2C9-catalyzing formation of M4; 2) inhibition of M4 formation by sulfaphenazole, a CYP2C9-selective inhibitor; and 3) strong correlation between the production of M4 and CYP2C9-mediated tolbutamide 4-hydroxylase activities in a panel of human liver microsome samples. Formation of M4 suggests the existence of a new reactive intermediate as diclofenac-2,3-oxide. A tentative pathway states that diclofenac is oxidized to diclofenac-2,3-oxide that reacts with glutathione (GSH) to form a thioether conjugate at the C-3 position, followed by a concomitant loss of chlorine to give rise to M4. Furthermore, a likely mechanism leading to the formation of diclofenac oxides is rationalized: CYP2C9-catalyzed oxidation at the C-3 position of the dichlorophenyl ring to form a cationic -complex that subsequently results in diclofenac-3,4-oxide and diclofenac-2,3-oxide; the former oxide is converted to 4-hydroxy-diclofenac as a major metabolite and can be trapped by GSH to produce 4-hydroxy-3-glutathione-S-yl diclofenac (M2), whereas the latter oxide forms 3-hydroxy-diclofenac and can be trapped by GSH to produce M4. This mechanism is consistent with the structural modeling of the CYP2C9-diclofenac complex, which reveals that both the C-3 and C-4 of the dichlorophenyl ring are proximate to the heme group.

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Rapid detection and characterization of minor reactive metabolites using stable‐isotope trapping in combination with tandem mass spectrometry

Yan

Maher

Torres

et al. 2005

Rapid Comm Mass Spectrometry

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Stable-isotope trapping combined with mass spectrometry (MS) neutral loss scanning has recently been developed as a high-throughput method for the in vitro screening of major reactive metabolites. In fact, detection and identification of minor reactive metabolites are equally important since the minor metabolites, even though at low levels, may be highly reactive and also play an important role in drug-induced adverse reactions. In this study, 2-acetylthiophene, clozapine, troglitazone and 7-methylindole were selected as model compounds to further validate the advantages of this method for rapid detection and structural characterization of minor glutathione (GSH) adducts derived from reactive metabolites. The utility of the current method was clearly demonstrated by successful identification of novel reactive metabolites at low levels and also minor ones either masked by non-specific responses or co-eluted with other conjugates. In comparison with existing methods, this method is sensitive, efficient, and suitable for rapid screening and more complete profiling of reactive metabolites.

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Metabolism and Bioactivation of 3-Methylindole by Human Liver Microsomes

Yan

Easterwood

Maher

et al. 2006

Chem. Res. Toxicol.

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Metabolism and bioactivation of 3-methylindole (3MI) were investigated in human liver microsomes. The metabolism of two deuterium-labeled analogues of 3MI permitted a relatively unambiguous identification of multiple metabolites and glutathione (GSH) adducts of reactive intermediates. A total of eight oxidized metabolites were detected, five of which were assigned as previously identified 3-methyloxindole, 3-hydroxy-3-methylindolenine, 3-hydroxy-3-methyloxindole, 5-hydroxy-3-methylindole, and 6-hydroxy-3-methylindole. Among the three new metabolites, one was either 4- or 7-OH-3-methylindole, and the other two were derived from additional oxidation on the phenyl ring of 3-methyloxindole. When GSH was added to the microsomal incubations, seven conjugates that had molecular ions corresponding to the incorporation of GSH and an atom of oxygen at m/z 453 (group I) were produced, and two additional conjugates had molecular ions at m/z 437 that corresponded to the incorporation of GSH with no additional oxygen (group II). Two conjugates in group I (m/z 453) were apparently derived by GSH addition to the 5,6-epoxide metabolite of 3-methyloxindole. These two GSH adducts were tentatively identified as 5-(glutathione-S-yl)-3-methyloxindole and 6-(glutathione-S-yl)-3-methyloxindole. The most abundant conjugate in group I was identified as 3-(glutathione-S-yl)-3-methyloxindole, which substantiated the presence of the putative 2,3-epoxy-3-methylindole intermediate. The remaining four adducts in group I were likely formed by conjugation of GSH at different positions of the phenyl ring, possibly via oxidation of 5-hydroxy-3-methylindole and 6-hydroxy-3-methylindole to two very interesting new electrophilic benzoquinone imine intermediates. For the group II conjugates (m/z 437), two isomers were identified as 2-(glutathione-S-yl)-3-methylindole and 3-(glutathione-S-yl-methyl)-indole. The former adduct was primarily derived from the 2,3-epoxide intermediate by thiol conjugation followed by dehydration. The latter adduct was consistent with our previously published work on the dehydrogenation of 3MI. In those studies, we showed that the reactive intermediate, 3-methylenenindolenine, was formed by hydrogen abstraction at the methyl group and was trapped with GSH. The putative dehydrogenation bioactivation mechanism is also substantiated by the finding that CYP2E1 selectively generated 2-(glutathione-S-yl)-3-methylindole but did not produce 3-(glutathione-S-yl-methyl)-indole. In summary, the results not only confirmed the formation of 2,3-epoxide-3-methylindole in human liver microsomes but also suggested that the phenolic metabolites of 3-methylindole were dehydrogenated to previously uncharacterized reactive intermediates.

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Norman Huebert

Characterization of the ZDSD Rat: A Translational Model for the Study of Metabolic Syndrome and Type 2 Diabetes

Biochemical and clinical effects of γ‐vinyl GABA in patients with epilepsy

Detection of a Novel Reactive Metabolite of Diclofenac: Evidence for Cyp2c9-Mediated Bioactivation via Arene Oxides

Rapid detection and characterization of minor reactive metabolites using stable‐isotope trapping in combination with tandem mass spectrometry

Metabolism and Bioactivation of 3-Methylindole by Human Liver Microsomes

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