Regulatory polymorphisms and their contribution to interindividual differences in the expression of enzymes influencing drug and toxicant disposition.

The unexpected paucity of human protein encoding genes suggested that polymorphisms altering gene expression might be more important than initially thought. From an evolutionary perspective, traits such as xenobiotic metabolism and transport that require a dynamic response to environmental changes would evolve more efficiently through variation in regulatory sequences versus coding variants. Such variation would be manifest as co-dominant traits and selection pressures would operate more efficiently because of their ability to impact fitness in the heterozygous state. Our current understanding of regulatory polymorphisms impacting drug disposition is reviewed including specific discussion regarding knowledge gaps and future research opportunities.

Identification and functional analysis of common human flavin-containing monooxygenase 3 genetic variants.

Flavin-containing monooxygenases (FMOs) are important for the disposition of many therapeutics, environmental toxicants, and nutrients. FMO3, the major adult hepatic FMO enzyme, exhibits significant interindividual variation. Eighteen FMO3 single-nucleotide polymorphism (SNP) frequencies were determined in 202 Hispanics (Mexican descent), 201 African Americans, and 200 non-Latino whites. Using expressed recombinant enzyme with methimazole, trimethylamine, sulindac, and ethylenethiourea, the novel structural variants FMO3 E24D and K416N were shown to cause modest changes in catalytic efficiency, whereas a third novel variant, FMO3 N61K, was essentially devoid of activity. The latter variant was present at an allelic frequency of 5.2% in non-Latino whites and 3.5% in African Americans, but it was absent in Hispanics. Inferring haplotypes using PHASE, version 2.1, the greatest haplotype diversity was observed in African Americans followed by non-Latino whites and Hispanics. Haplotype 2A and 2B, consisting of a hypermorphic promoter SNP cluster (-2650C>G, -2543T>A, and -2177G>C) in linkage with synonymous structural variants was inferred at a frequency of 27% in the Hispanic population, but only 5% in non-Latino whites and African Americans. This same promoter SNP cluster in linkage with one or more hypomorphic structural variant also was inferred in multiple haplotypes at a total frequency of 5.6% in the African-American study group but less than 1% in the other two groups. The sum frequencies of the hypomorphic haplotypes H3 [15,167G>A (E158K)], H5B [-2650C>G, 15,167G>A (E158K), 21,375C>T (N285N), 21,443A>G (E308G)], and H6 [15,167G>A (E158K), 21,375C>T (N285N)] was 28% in Hispanics, 23% in non-Latino whites, and 24% in African Americans.

Discovery of novel flavin-containing monooxygenase 3 (FMO3) single nucleotide polymorphisms and functional analysis of upstream haplotype variants.

The flavin-containing monooxygenases (FMOs) are important for xenobiotic metabolism. FMO3, the predominant FMO enzyme in human adult liver, exhibits significant interindividual variation that is poorly understood. This study was designed to identify common FMO3 genetic variants and determine their potential for contributing to interindividual differences in FMO3 expression. FMO3 single nucleotide polymorphism (SNP) discovery was accomplished by resequencing DNA samples from the Coriell Polymorphism Discovery Resource. Population-specific SNP frequencies were determined by multiplexed, single-base extension using DNA from 201 Hispanic American (Mexican descent), 201 African American, and 200 White (northern European descent) subjects. Haplotypes were inferred and population frequencies estimated using PHASE version 2.1. Multiple site-directed mutagenesis was used to introduce inferred upstream haplotypes into an FMO3/luciferase construct for functional analysis in HepG2 cells. Sequence analysis revealed seven FMO3 upstream SNPs, 11 exon SNPs, and 22 intron SNPs. Five of the latter fell within consensus splice sites. A g.72G>T variant (E24D) is predicted to impact the structure of the Rossmann fold involved in FAD binding, whereas a g.11177C>A variant (N61K) is predicted to disrupt the secondary structure of a conserved membrane interaction domain. Seven common (>1%) promoter region haplotypes were inferred in one or more of the study populations that differed in estimated frequency among the groups. Haplotype 2 resulted in an 8-fold increase in promoter activity, whereas haplotypes 8 and 15 exhibited a near complete loss of activity. In conclusion, FMO3 promoter haplotype variants modulate gene function and probably contribute to interindividual differences in FMO3 expression.

Molecular mechanisms regulating human CYP4B1 lung-selective expression.

Lung-selective cytochrome P450 expression is well recognized; however, little is known regarding regulatory mechanisms. To address this knowledge gap, transient expression of CYP4B1/luciferase constructs was used to identify a proximal, positively acting regulatory element, position -139 to -45, that functioned in all cells examined; a negatively acting element, position -457 to -216, that only functioned in HepG2 hepatoblastoma cells; and a distal, positively acting element, position -1087 to -1008, that functioned in A549 or BEAS-2B lung-derived cells but not HepG2 cells or 293 kidney-derived cells. Competitive electrophoretic mobility shift assays further localized specific A549, but not HepG2, nuclear protein binding to two sites within the distal element, CYP4B1 position -1052 to -1042 and -1026 to -1008. Several potential lung-selective transcription factor recognition sequences were identified within these elements. However, attempts to identify specific factor(s) were unsuccessful. In contrast, in vitro DNA/protein binding assays combined with transient expression and mutagenesis studies identified two functional Sephadex protein/Krüppel-like factor families of transcription factor sites within the proximal element (position -118 to -114 and position -77 to -73) that bound both Sephadex protein 1 (Sp1) and Sephadex protein 3 (Sp3) in vitro. Furthermore, Sp1-dependent synergistic regulation was observed in A549 cells involving the proximal and distal regulatory elements. Chromatin immunoprecipitation assays demonstrated binding of neither Sp1 nor Sp3 to the CYP4B1 proximal element in human liver tissue, whereas selective Sp1 binding was observed in human lung tissue. Thus, the composite findings are consistent with both the proximal Sp1 elements and the distal regulatory element acting to synergistically control CYP4B1 lung-selective expression.

Two distinct classes of CCAAT box elements that bind nuclear factor-Y/alpha-actinin-4: potential role in human CYP1A1 regulation.

A negative regulatory element (NRE1; position -794 to -774) was previously identified that mediates the downregulation of CYP1A1, including partial suppression of Ah receptor-dependent induction. The CCAAT-box binding protein, nuclear factor-Y (NF-Y), is a component of one of two protein complexes that specifically and competitively bind the CYP1A1 NRE1 in vitro with nearly equal affinity. The second complex involves an unidentified protein(s) called the negative regulatory factor (NRF). Competitive electrophoretic mobility shift assays (EMSA) revealed two distinct classes of NF-Y-binding CCAAT-box elements distinguished by their ability or inability to also bind NRF. To further explore the identity of NRE1-binding proteins, a purification scheme was developed culminating in NRE1-dependent DNA affinity chromatography and sequence analysis. An approximate 106-kDa protein was purified and shown to be alpha-actinin-4 (ACTN4), one of two ubiquitously expressed non-muscle actinins. Electrophoretic mobility shift assays combined with Western blot analysis and co-immunoprecipitation experiments suggested that ACTN4 is associated with the NF-Y complex, but not NRF. Attempts to demonstrate a role for NF-Y/ACTN4 in regulating CYP1A1 expression were unsuccessful, likely due to an inability to significantly change nuclear ACTN4 levels with phosphatidylinositol 3'-kinase agonists and antagonists. However, given ACTN4's known functions and the suspected functions of actin and actin-related proteins in chromatin remodeling and other nuclear events, ACTN4 may assist NF-Y in recruiting chromatin-remodeling complexes or may direct NF-Y/ACTN4-targeted genes to the nuclear matrix and active transcriptional complexes.