A natural variant of the heme-binding signature (R441C) resulting in complete loss of function of CYP2D6.

A new variant allele CYP2D6*62 (g.4044C>T; R441C) of the drug-metabolizing cytochrome P450 (P450) CYP2D6 was identified in a person with reduced sparteine oxidation phenotype, which was unexpected based on a genetic CYP2D6*1A/*41 background. The recombinantly expressed variant protein had no activity toward propafenone as a result of missing heme incorporation. Sequence alignment revealed that the positively charged R441 residue is part of the heme-binding signature but not strictly conserved among all the P450s. A compilation of described P450 monooxygenase variants revealed that other enzymes can functionally tolerate even nonconservative amino acid changes at the corresponding position (i.e., the invariant cysteine 2). This suggests that heme binding in mammalian P450s depends not only on the integrity of the heme-binding signature but also on other family- and subfamily-specific sequence determinants.

Impaired expression of CYP2D6 in intermediate metabolizers carrying the *41 allele caused by the intronic SNP 2988G>A: evidence for modulation of splicing events.

We investigated the molecular basis for low expression and activity of CYP2D6 associated with the CYP2D6*41 allele in about 10-15% of Caucasians with intermediate metabolizer phenotype. With respect to two previously described polymorphisms in the promoter (-1584C>G) and in intron 6 (2988G>A; c.985+39G>A), the three most frequent functional alleles have the distinct haplotypes 2D6*1[CG], 2D6*2[GG] and 2D6*41[CA], respectively. Reporter gene analyses in transiently transfected HepG2 and Huh7 hepatoma cells did not indicate changes in transcription rate by these polymorphisms. By reverse-transcription polymerase chain reaction analysis of liver RNA of genotyped patients, however, we discovered that the 2988G>A change was associated with increased levels of a nonfunctional splice variant lacking exon 6. Quantification by denaturing high-performance liquid chromatography revealed up to 7.3-fold increased levels of the splice variant and up to 2.9-fold less functional transcript in carriers of 2D6*41, in good concordance with concomitant changes in immunoquantified CYP2D6 protein. Recombinant expression of the entire genomic sequence coding for 2D6*41, 2D6*2 and 2D6*1 alleles but lacking the upstream region in COS-1 and Huh7 cell lines resulted in two-fold to five-fold reduced levels of CYP2D6 mRNA containing exon 6, apoprotein and enzyme activity of 2D6*41. These experiments establish the causal relationship between the intron 6 single-nucleotide polymorphism 2988G>A and the low expression phenotype associated with allele 2D6*41. These data improve the CYP2D6 genotype-phenotype relationship and they demonstrate that major phenotype changes occurring in large population subgroups can be caused by intronic polymorphisms outside of splice site consensus sequences.

A silent mutation (2939G>A, exon 6; CYP2D6*59) leading to impaired expression and function of CYP2D6.

We analyzed CYP2D6 in two individuals characterized by impaired sparteine oxidation (intermediate metabolizer phenotype) and genotype 2D62/4 (1661G>C; 2850C>T; 4180G>C) usually associated with normal function. Full genomic sequencing and haplotype analysis confirmed the previously identified silent mutation 2939G>A in exon 6 (former allele variant 2D62J, now termed 2D659), as well as an additional novel 2291G>A change in intron 4. Transient expression in Huh7 hepatoma cells of the entire CYP2D6 gene of constructs carrying either both or only the 2939G>A change resulted in about three-fold reduced levels of mRNA, immunoreactive 2D6 protein and propafenone hydroxylase activity. These data demonstrate profound effects of a silent mutation on expression and function of CYP2D6, resulting in impaired drug oxidation phenotype. The 2939G>A single nucleotide polymorphism in exon 6 was present heterozygously in two individuals out of 308 (0.65%), corresponding to an allele frequency of 0.3%. Genotyping for this mutation thus improves phenotype-genotype correlation for CYP2D6 and may help to predict adverse drug treatment events.

A novel intronic mutation, 2988G>A, with high predictivity for impaired function of cytochrome P450 2D6 in white subjects.

BACKGROUND: Individuals with the cytochrome P450 (CYP) 2D6 intermediate metabolizer (IM) phenotype have low residual enzyme activity and compose about 10% to 15% of white populations. Their identification is clinically relevant but remains unsatisfactory because of incomplete characterization of the major allele involved, termed CYP2D6*41 (-1584C, R296C, S486T). METHODS: To search for novel mutations, resequencing of the entire CYP2D6 gene was performed in selected individuals. Genotype-phenotype correlation analysis was done in a population sample of 308 white subjects phenotyped with sparteine and previously genotyped for all major alleles. RESULTS: A total of 16 novel polymorphic positions were identified, of which 7 were located within 2.4 kilobases of previously uncharacterized 2D7-2D6 intergenic sequence and 9 were located within intronic regions. The novel mutation 2988G>A in intron 6 appeared to be specifically associated with the IM phenotype. Further analysis in the population sample demonstrated that 2988G>A was strongly linked to allele *41 but not to any other alleles including *1, *2, *2xN, *4, *6, *7, *8, *9, *10, and *35. The overall frequency of the novel polymorphism was 8.4% in the normal white population. Compared with conventionally determined *41, 2988G>A was shown to have improved predictivity for the IM phenotype. With 2988G>A being taken into account, alleles *1, *2, and *35 (-1584G, V11M, R296C, S486T) were found to be phenotypically equivalent. CONCLUSIONS: CYP2D6 genotyping can be considerably simplified by using 2988G>A as a marker for *41 and by omitting genotyping for the functionally equivalent alleles *2 and *35.

Cytochrome P450 2D6: overview and update on pharmacology, genetics, biochemistry.

Of about one dozen human P450 s that catalyze biotransformations of xenobiotics, CYP2D6 is one of the more important ones based on the number of its drug substrates. It shows a very high degree of interindividual variability, which is primarily due to the extensive genetic polymorphism that influences expression and function. This so-called debrisoquine/sparteine oxidation polymorphism has been extensively studied in many different populations and over 80 alleles and allele variants have been described. CYP2D6 protein and enzymatic activity is completely absent in less than 1% of Asian people and in up to 10% of Caucasians with two null alleles, which do not encode a functional P450 protein product. The resulting "poor metabolizer" (PM) phenotype is characterized by the inability to use CYP2D6-dependent metabolic pathways for drug elimination, which affect up to 20% of all clinically used drugs. The consequences are increased risk of adverse drug reactions or lack of therapeutic response. Today, genetic testing predicts the PM phenotype with over 99% certainty. At the other extreme, the "Ultrarapid Metabolizer" (UM) phenotype can be caused by alleles carrying multiple gene copies. "Intermediate Metabolizers" (IM) are severely deficient in their metabolism capacity compared to normal "Extensive Metabolizers" (EM), but in contrast to PMs they express a low amount of residual activity due to the presence of at least one partially deficient allele. Whereas the intricate genetics of the CYP2D6 polymorphism is becoming apparent at ever greater detail, applications in clinical practice are still rare. More clinical studies are needed to show where patients benefit from drug dose adjustment based on their genotype. Computational approaches are used to predict and rationalize substrate specificity and enzymatic properties of CYP2D6. Pharmacophore modeling of ligands and protein homology modeling are two complementary approaches that have been applied with some success. CYP2D6 is not only expressed in liver but also in the gut and in brain neurons, where endogenous substrates with high-turnover have been found. Whether and how brain functions may be influenced by polymorphic expression are interesting questions for the future.