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Piyush M Vyas,
Sanjoy Roychowdhury,
Farah D Khan,
Thomas E Prisinzano,
Jatinder Lamba,
Erin G Schuetz, Joyce Blaisdell,
Joyce A Goldstein,
Kimber L Munson,
Ronald N Hines,
Craig K Svensson
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ABSTRACT: Cutaneous drug reactions (CDRs) are among the most common adverse drug reactions and are responsible for numerous minor to life-threatening complications. Several arylamine drugs, such as sulfamethoxazole (SMX) and dapsone (DDS), undergo bioactivation, resulting in adduction to cellular proteins. These adducted proteins may initiate the immune response that ultimately results in a CDR. Recent studies have demonstrated that normal human epidermal keratinocytes (NHEKs) can bioactivate these drugs, resulting in protein haptenation. We sought to identify the enzyme(s) responsible for this bioactivation in NHEKs. Using immunofluorescence confocal microscopy and an adduct-specific enzyme-linked immunosorbent assay (ELISA), we found that N-acetylation of the primary amine of SMX and DDS markedly reduced the level of protein haptenation in NHEKs. Detection of mRNA and/or protein confirmed the presence of CYP3A4, CYP3A5, and CYP2E1 in NHEKs. In contrast, although a faint band suggestive of CYP2C9 protein was detected in one NHEK sample, a CYP2C9 message was not detectable. We also examined the ability of chemical inhibitors of cytochromes P450 (aminobenzotriazole and 1-dichloroethylene) and cyclooxygenase (indomethacin) to reduce protein haptenation when NHEKs were incubated with SMX or DDS by either confocal microscopy or ELISA. These inhibitors did not significantly attenuate protein adduction with either SMX or DDS, indicating that cytochromes P450 and cyclooxygenase do not play important roles in the bioactivation of these xenobiotics in NHEKs and thus suggesting the importance of other enzymes in these cells.
Journal of Pharmacology and Experimental Therapeutics 11/2006; 319(1):488-96. · 3.83 Impact Factor
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ABSTRACT: CYP2C9 is a clinically important enzyme, responsible for the metabolism of numerous clinically important therapeutic drugs. In the present study, we discovered 38 single nucleotide polymorphisms in CYP2C9 by resequencing of genomic DNA from 92 individuals from three different racial groups. Haplotype analysis predicted that there are at least 21 alleles of CYP2C9 in this group of individuals. Six new alleles were identified that contained coding changes: L19I (CYP2C9*7), R150H (CYP2C9*8), H251R (CYP2C9*9), E272G (CYP2C9*10), R335W(CYP2C9*11) and P489S (CYP2C9*12). When expressed in a bacterial cDNA expression system, several alleles exhibited altered catalytic activity. CYP2C9*11 appeared to be a putative poor metabolizer allele, exhibiting a three-fold increase in the Km and more than a two-fold decrease in the intrinsic clearance for tolbutamide. Examination of the crystal structure of human CYP2C9 reveals that R335 is located in the turn between the J and J' helices and forms a hydrogen-bonding ion pair with D341 from the J' helix. Abolishing this interaction in CYP2C9*11 individuals could destabilize the secondary structure and alter the substrate affinity. This new putative poor metabolizer (PM) allele was found in Africans. A second potentially PM allele CYP2C9*12 found in a racially unidentified sample also exhibited a modest decrease in the Vmax and the intrinsic clearance for tolbutamide in a recombinant system. Further clinical studies are needed to determine the effect of these new polymorphisms on the metabolism of CYP2C9 substrates.
Pharmacogenetics 09/2004; 14(8):527-37.
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ABSTRACT: CYP2C19 is a clinically important enzyme responsible for the metabolism of a number of therapeutic drugs, such as mephenytoin, omeprazole, diazepam, proguanil, propranolol and certain antidepressants. Genetic polymorphisms in this enzyme result in poor metabolizers of these drugs. There are racial differences in the incidence of the poor metabolizer trait, which represents 13-23% of Asians but only 3-5% of Caucasians. In this study, single nucleotide polymorphisms (SNPs) in CYP2C19 were identified by direct sequencing of genomic DNA from 92 individuals from three different racial groups of varied ethnic background, including Caucasians, Asians and blacks. Several new alleles were identified containing the coding changes Arg114 His (CYP2C19*9), Pro227 Leu (CYP2C19*10), Arg150 His (CYP2C19*11), stop491 Cys (CYP2C19*12), Arg410 Cys (CYP2C19*13), Leu17 Pro (CYP2C19*14) and Ile19 Leu (CYP2C19*15). When expressed in a bacterial cDNA expression system, CYP2C19*9 exhibited a modest decrease in the V(max) for 4'-hydroxylation of -mephenytoin, and no alteration in its affinity for reductase. CYP2C19*10 exhibited a dramatically higher K(m) and lower V(max) for mephenytoin. CYP2C19*12was unstable and expressed poorly in a bacterial cDNA expression system. Clinical studies will be required to confirm whether this allele is defective in vivo. CYP2C19*9, CYP2C19*10 and CYP2C19*12 all occurred in African-Americans, or individuals of African descent, and represent new potentially defective alleles of CYP2C19 which are predicted to alter risk of these populations to clinically important drugs.
Pharmacogenetics 01/2003; 12(9):703-11.
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ABSTRACT: CYP2C19 is a clinically important enzyme responsible for the metabolism of a number of therapeutic drugs, such as S-mephenytoin, omeprazole, diazepam, proguanil, propranolol and certain antidepressants. Genetic polymorphisms in this enzyme result in poor metabolizers of these drugs. There are racial differences in the incidence of the poor metabolizer trait, which represents 13-23% of Asians but only 3-5% of Caucasians. In this study, single nucleotide polymorphisms (SNPs) in CYP2C19 were identified by direct sequencing of genomic DNA from 92 individuals from three different racial groups of varied ethnic background, including Caucasians, Asians and blacks. Several new alleles were identified containing the coding changes Arg144His (CYP2C19*9), Pro227Leu (CYP2C19*10), Arg150His (CYP2C19*11), stop491Cys (CYP2C19*12), Arg410Cys (CYP2C19*13), Leu17Pro (CYP2C19*14) and Ile19Leu (CYP2C19*15). When expressed in a bacterial cDNA expression system, CYP2C19*9 exhibited a modest decrease in the Vmax for 4′-hydroxylation of S-mephenytoin, and no alteration in its affinity for reductase. CYP2C19*10 exhibited a dramatically higher Km and lower Vmax for mephenytoin. CYP2C19*12 was unstable and expressed poorly in a bacterial cDNA expression system. Clinical studies will be required to confirm whether this allele is defective in vivo. CYP2C19*9, CYP2C19*10 and CYP2C19*12 all occurred in African-Americans, or individuals of African descent, and represent new potentially defective alleles of CYP2C19 which are predicted to alter risk of these populations to clinically important drugs.
Pharmacogenetics and Genomics 11/2002; 12(9):703-711. · 3.48 Impact Factor
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ABSTRACT: CYP2C19 is a polymorphically expressed cytochrome P450 responsible for the metabolism of several clinically used drugs, including some barbiturates, diazepam, proguanil, propranolol and several proton pump inhibitors. Genetic polymorphism of this enzyme shows marked interracial differences, with the poor metabolizer (PM) phenotype representing 2-5% of Caucasian and 11-23% of Oriental populations. In the present study, CYP2C19 phenotype and genotype were investigated in 107 North-eastern Thai subjects using the omeprazole hydroxylation index (HI) and polymerase chain reaction-restriction fragment length polymorphism technique, respectively. It was found that the distribution of HI in these subjects was bimodal. Seven subjects [6.54%, 95% confidence (CI) 1.86-11.22%] were identified as PM, with an HI > 7. Analysis of CYP2C19 genotypes in these 107 Thai subjects revealed that the allele frequencies for CYP2C19*1, CYP2C19*2 and CYP2C19*3 were 0.71 (95% CI 0.65-0.77), 0.27 (95% CI 0.21-0.33) and 0.02 (95% CI 0.01-0.05), respectively. The PM phenotype and the frequencies of CYP2C19 defective alleles in Thais, particularly CYP2C19*3, were lower than those observed in other Oriental populations. It is noteworthy that there was a case of nonaccordance between phenotype and genotype in one of the PMs. Whether this PM represents a novel defective allele requires further investigation.
Pharmacogenetics 04/2002; 12(3):221-5.
