Browsing by Author "Erickson, Leonard C."

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    A novel fluorometric oligonucleotide assay to measure O 6-methylguanine DNA methyltransferase, methylpurine DNA glycosylase, 8-oxoguanine DNA glycosylase and abasic endonuclease activities: DNA repair status in human breast carcinoma cells overexpressing methylpurine DNA glycosylase
    (2001-04) Kreklau, Emiko L.; Limp-Foster, Melissa; Liu, Naili; Xu, Yi; Kelley, Mark R.; Erickson, Leonard C.
    DNA repair status plays a major role in mutagenesis, carcinogenesis and resistance to genotoxic agents. Because DNA repair processes involve multiple enzymatic steps, understanding cellular DNA repair status has required several assay procedures. We have developed a novel in vitro assay that allows quantitative measurement of alkylation repair via O6‐methylguanine DNA methyltransferase (MGMT) and base excision repair (BER) involving methylpurine DNA glycosylase (MPG), human 8-oxoguanine DNA glycosylase (hOGG1) and yeast and human abasic endonuclease (APN1 and APE/ref-1, respectively) from a single cell extract. This approach involves preparation of cell extracts in a common buffer in which all of the DNA repair proteins are active and the use of fluorometrically labeled oligonucleotide substrates containing DNA lesions specific to each repair protein. This method enables methylation and BER capacities to be determined rapidly from a small amount of starting sample. In addition, the stability of the fluorometric oligonucleotides precludes the substrate variability caused by continual radiolabeling. In this report this technique was applied to human breast carcinoma MDA-MB231 cells overexpressing human MPG in order to assess whether up-regulation of the initial step in BER alters the activity of selected other BER (hOGG1 and APE/ref-1) or direct reversal (MGMT) repair activities.
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    Vincristine Metabolism and the Role of CYP3A5
    (2007-11-16T20:07:34Z) Dennison, Jennifer Bolin; Hall, Stephen D. (Stephen David), 1957-; Kamendulis, Lisa M.; Queener, Sherry F.; Erickson, Leonard C.; Wrighton, Steven A.
    Vincristine is metabolized by the cytochrome P450 3A subfamily of enzymes possibly including CYP3A5, a genetically polymorphic enzyme. The contribution of CYP3A5 to the metabolism of vincristine was quantified by various in vitro models: cDNA-expressed enzymes, human liver microsomes, and human hepatocytes. With these models, the major CYP metabolite of vincristine, M1, was identified and extensively characterized. The rates of M1 formation in the cDNA-expressed enzyme models were at least 7-fold higher with CYP3A5 than CYP3A4; approximately 90% of the hepatic metabolism was predicted to be CYP3A5-mediated. For human liver microsomes with high CYP3A5 expression, the CYP3A5 contribution was substantial, approximately 80%. Human hepatocytes with at least one CYP3A5*1 allele also metabolized vincristine, albeit at a slower rate (10-fold) than human liver microsomes. The CYP3A5 low-expressing hepatocytes did not metabolize vincristine. We conclude that for high CYP3A5 expressers, the majority of the CYP metabolism is mediated by CYP3A5. By in vitro/in vivo scaling with microsomes, the hepatic clearances of high CYP3A5 expressers are predicted to have a 5-fold higher hepatic clearance than low expressers. However, the role of metabolism in the systemic clearance of vincristine is unknown. To study the disposition of vincristine in vivo, a sensitive and selective LC/MS/MS assay was validated for the quantification of vincristine and M1 quantification in human plasma. Vincristine and M1 were identified and quantified in select pediatric plasma and urine samples. For future large-scale clinical studies, the vincristine and M1 concentrations in plasma will be quantified to understand the role of CYP3A5 genotype in vincristine pharmacokinetics. For patients that are CYP3A5 high expressers, the systemic clearance of vincristine may be higher than that of low CYP3A5 expressers. Thus, CYP3A5 genotype may be an important determinant of inter-individual variability in clinical outcomes.