GENETIC AND METABOLIC CRITERIA FOR THE ASSIGNMENT OF DEBRISOQUINE 4-HYDROXYLATION (CYTOCHROME-P4502D6) PHENOTYPES

被引：111

作者：

DALY, AK ^{[1
]}

ARMSTRONG, M ^{[1
]}

MONKMAN, SC ^{[1
]}

IDLE, ME ^{[1
]}

IDLE, JR ^{[1
]}

机构：

[1] UNIV NEWCASTLE UPON TYNE,SCH MED,DEPT PHARMACOL SCI,PHARMACOGENET RES UNIT,FRAMLINGTON PL,NEWCASTLE TYNE NE2 4HH,ENGLAND

来源：

PHARMACOGENETICS | 1991年 / 1卷 / 01期

关键词：

D O I：

10.1097/00008571-199110000-00006

中图分类号：

Q81 [生物工程学（生物技术）]; Q93 [微生物学];

学科分类号：

071005 ; 0836 ; 090102 ; 100705 ;

摘要：

A randomly selected population of 73 volunteers, together with 22 previously established poor metabolisers of debrisoquine, were phenotyped for their ability to 4-hydroxylate debrisoquine and were also analysed for a number of mutations in the CYP2D6 gene. Genotyping was performed using both restriction fragment length polymorphism with the restriction enzyme Xba I, together with two separate polymerase chain reaction assays. Together, these assays detected 98% of mutant alleles in the poor metaboliser group which corresponded to positive identification of 95% of this group. The most common mutant allele detected as the 29B which comprised 75% of total alleles in the poor metaboliser group, whereas the 29A had a frequency of 0.11. Two other allelic variants, which were detectable by restriction fragment length polymorphism analysis occurred at frequencies of 0.07 and 0.05. In the volunteer group, 2.7% of subjects were genotypically poor metabolisers, 35.6% heterozygous extensive metabolisers and 61.7% homozygous extensive metabolisers. on the basis of the genotyping assays used. A good correlation between debrisoquine metabolic ratio and genotype was obtained particularly for subjects genotyped as homozygous extensive metabolisers.

引用

页码：33 / 41

页数：9

共 30 条

[1] Alvan G., Bechtel P., Iselius L., Gundert-Remy U., Hydroxylation polymorphisms of debrisoquine and mephenytoin in European populations, Eur J Clin Pharmacol, 39, pp. 533-537, (1990)
[2] Ayesh R., Idle J.R., Ritchie J.C., Crothers M.J., Hetzel M.R., Metabolic oxidation phenotypes as markers for susceptibility to lung cancer, Nature, 311, pp. 169-170, (1984)
[3] Blin N., Stafford D.W., A general method for isolation of high molecular DNA from eukaryotes, Nucl Acids Res, 3, pp. 2303-2308, (1976)
[4] Caporaso N., Williams-Pickle L., Bale S., Ayesh R., Hetzel M., Idle J.R., The distributions of debrisoquine metabolic phenotypes and implications for the suggested association with lung cancer risk, Genet Epidem, 6, pp. 517-524, (1989)
[5] Caporaso N., Tucker M.A., Hoover R.N., Hayes R.B., Pickle L.W., Issaq H.J., Muschik G.M., Green-Gallo L., Buivys D., Aisner S., Resau J.H., Trump B.F., Tollerud D., Weston A., Harris C.C., Lung cancer and the debrisoquine metabolic phenotype, J Natl Cancer Inst, 82, pp. 1264-1272, (1990)
[6] Daly A.K., Armstrong M., Idle J.R., Molecular genotyping to predict debrisoquine hydroxylation phenotype, Lancet, 336, pp. 889-890, (1990)
[7] Eichelbaum M., Genetic polymorphism of sparteine/debrisoquine oxidation, ISI Atlas of Science, pp. 243-251, (1988)
[8] Evans D., Harmer D., Downham D.Y., Whibley E.J., Idle J.R., Ritchie J., Smith R.L., The genetic control of sparteine and debrisoquine metabolism in man with new methods of analysing bimodal distributions, J Med Genet, 20, pp. 321-329, (1983)
[9] Evans W.E., Relling M.V., Xba I 16- plus 9-kilobase DNA restriction fragments identify a mutant allele for debrisoquin hydroxylase: Report of a family study, Mol Pharmacol, 37, pp. 639-642, (1990)
[10] Evans D., Mahgoub A., Sloan T.P., Idle J.R., Smith R.L., A family and population study of the genetic polymorphism of debrisoquine in a white British population, J Med Genet, 17, pp. 102-105, (1980)

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