CYP2B6
CYP2B6 (cytochrome P450 family 2 subfamily B member 6) is a human enzyme encoded by the CYP2B6 gene on chromosome 19q13.2, belonging to the cytochrome P450 superfamily of monooxygenases that catalyze the oxidation of various substrates.[1] It primarily functions in phase I drug metabolism, contributing to the biotransformation of approximately 8% of clinically used drugs and numerous xenobiotics through reactions such as hydroxylation and demethylation.[2] CYP2B6 is predominantly expressed in the liver, accounting for 2–10% of total hepatic cytochrome P450 content, with lower levels in the intestine, brain, lungs, kidneys, and skin; its expression exhibits up to 100-fold interindividual variability.[1] Key substrates include antiretroviral agents like efavirenz and nevirapine (metabolized to 8-hydroxyefavirenz and 2-hydroxy, 3-hydroxy, and 12-hydroxynevirapine, respectively), the antidepressant and smoking cessation aid bupropion (via hydroxybupropion formation), the anticancer prodrug cyclophosphamide (activated to 4-hydroxycyclophosphamide), opioids such as methadone (N-demethylation), ketamine, artemisinin, tamoxifen, and propofol.[3][2] The enzyme's activity is modulated by over 38 known genetic variants (star alleles), with CYP2B66 (prevalent at 15–60% globally, including rs3745274 and rs2279343) causing reduced or unstable protein function, CYP2B618 (4–12% in African populations, rs28399499) resulting in a nonfunctional enzyme, and CYP2B616 leading to decreased activity; these polymorphisms contribute to 20–250-fold variations in mRNA expression and substrate-specific metabolic differences.[1][3] CYP2B6 is highly inducible by xenobiotics and drugs via nuclear receptors such as constitutive androstane receptor (CAR), pregnane X receptor (PXR), hepatocyte nuclear factor 3β (HNF3β), and estrogen receptor (ER), which can precipitate drug-drug interactions.[2] Clinically, CYP2B6 variants profoundly influence pharmacotherapy; for instance, poor metabolizers (*6 homozygotes) experience elevated efavirenz plasma levels, increasing central nervous system toxicity in HIV patients, while reduced activity enhances cyclophosphamide bioactivation and toxicity in cancer treatment, and alters bupropion efficacy for smoking cessation or methadone dosing in pain management.[1][3] These factors highlight CYP2B6's designation as a very important pharmacogene, guiding personalized medicine approaches to optimize drug dosing and minimize adverse effects.[3]Gene and Protein
Gene Structure and Location
The CYP2B6 gene is located on the long arm of human chromosome 19 at cytogenetic band 19q13.2, within a cluster of cytochrome P450 genes.[4] This gene spans approximately 27 kb of genomic DNA, from position 40,991,282 to 41,018,398 on the reference genome assembly GRCh38.p14 (NC_000019.10), and comprises 9 exons that encode the cytochrome P450 2B6 enzyme.[4] As part of the CYP2B subfamily in the broader cytochrome P450 superfamily, CYP2B6 is arranged in a head-to-tail orientation alongside related genes and pseudogenes in this locus.[5] A notable feature of this genomic region is the proximity of the pseudogene CYP2B7P1, which shares high sequence homology with CYP2B6 and can complicate genotyping efforts due to potential cross-reactivity in assays.[3] This pseudogene, also within the CYP2 gene cluster on 19q13.2, underscores the evolutionary duplication events that shaped the CYP2B subfamily.[5] Evolutionarily, CYP2B6 is conserved across mammalian species, with functional orthologs identified in rodents (e.g., rat Cyp2b1/2b2), lagomorphs (e.g., rabbit Cyp2b4), and other mammals, reflecting shared roles in xenobiotic metabolism despite variations in catalytic specificity. The promoter region of CYP2B6 includes a distal phenobarbital-responsive enhancer module (PBREM) approximately 8.5 kb upstream of the transcription start site, featuring structural elements such as DR4 motifs that serve as binding sites for nuclear receptors like CAR and PXR.[6]Protein Structure and Characteristics
CYP2B6 is a heme-containing enzyme belonging to the cytochrome P450 2B subfamily, characterized by a typical P450 fold that includes a central alpha-helical core with beta-sheets and loops. The protein consists of 491 amino acids and has a molecular weight of approximately 56 kDa.[7][8] This fold features a conserved heme-binding domain coordinated by a cysteine residue (Cys436 in CYP2B6), which anchors the protoporphyrin IX prosthetic group essential for its monooxygenase activity. Additionally, the structure incorporates six substrate recognition sites (SRS1-6), which are variable regions critical for ligand binding and specificity within the CYP2 family.[7][9] High-resolution crystal structures of CYP2B6 have provided detailed insights into its architecture, revealing a compact, closed conformation in ligand-bound states. For instance, the structure of a CYP2B6 variant (K262R) in complex with the inhibitor 4-(4-chlorophenyl)imidazole (PDB ID: 3IBD, resolved at 2.0 Å) demonstrates the enzyme's helical bundle with the heme buried in a hydrophobic pocket, while the I-helix above the heme facilitates oxygen binding.[10][11] More recent structures, such as CYP2B6 (Y226H/K262R) bound to an efavirenz analog (PDB ID: 5WBG, 2.99 Å resolution), highlight dynamic flexibility in peripheral regions like the B/C and F/G loops, which undergo conformational changes to accommodate diverse substrates and contribute to the enzyme's adaptability.[12][13] Homology models based on these structures further emphasize the role of solvent-exposed loops in modulating access to the active site.[14] Post-translational modifications, particularly phosphorylation, regulate CYP2B6 stability and function. Phosphorylation at specific serine and threonine residues leads to decreased enzymatic activity, potentially through altered protein conformation or interactions with regulatory partners.[7][15] These modifications underscore the enzyme's responsiveness to cellular signaling pathways, influencing its overall bioavailability and metabolic efficiency.Expression and Regulation
Tissue Distribution and Localization
CYP2B6 is predominantly expressed in the human liver, where it constitutes approximately 2-10% of the total hepatic cytochrome P450 content, with protein levels ranging from 0.15 to 47 pmol/mg microsomal protein across individuals.[16][17][18] Expression is also detectable in extrahepatic tissues, including the small intestine, brain, lungs, kidney, and skin, though at substantially lower levels than in the liver; for instance, mRNA transcripts have been identified in intestinal enterocytes and pulmonary alveolar macrophages.[19][20] In the brain, CYP2B6 protein is localized to neurons and astrocytes in a region-specific manner, such as in the cerebellum and hippocampus, with higher expression observed in individuals exposed to inducers like alcohol or tobacco.[20] At the subcellular level, CYP2B6 is primarily anchored to the endoplasmic reticulum membrane as a peripheral membrane protein, consistent with its role in xenobiotic metabolism within hepatocytes and other expressing cells.[7][4] Developmentally, CYP2B6 expression is minimal in the fetal liver, with mRNA levels at a geometric mean of 0.58 molecules per 15 ng total RNA and protein at 2.19 pmol/mg, accompanied by negligible enzymatic activity. Postnatally, expression increases markedly, with a approximately 2-fold rise in hepatic protein levels beyond the neonatal period (birth to 30 days), and by 1 year of age, mRNA (geometric mean 961 molecules/15 ng), protein (around 2-5 pmol/mg), and activity (geometric mean 125 pmol/min/mg) approach adult-like values, reflecting maturation of hepatic metabolic capacity.[18][21] This postnatal upregulation contributes to the enzyme's increasing prominence in drug clearance during infancy and childhood.[18]Transcriptional and Post-Transcriptional Regulation
The expression of the CYP2B6 gene is primarily regulated at the transcriptional level through the action of nuclear receptors, notably the constitutive androstane receptor (CAR) and the pregnane X receptor (PXR), which serve as key inducers in response to xenobiotics, along with hepatocyte nuclear factor 3β (HNF3β), estrogen receptor (ER), and glucocorticoid receptor (GR). HNF3β enhances transcription via promoter binding for hepatic specificity, ERα synergizes with CAR for sex-based variability, and GR facilitates CAR/PXR activity. CAR and PXR heterodimerize with the retinoid X receptor (RXR) and bind to specific response elements in the promoter and enhancer regions of the CYP2B6 gene, thereby activating transcription. A critical regulatory element is the phenobarbital-responsive enhancer module (PBREM), a 51-base-pair distal enhancer located approximately 8.3 kb upstream of the transcription start site, which contains direct repeat motifs that facilitate binding by CAR, PXR, and accessory factors such as hepatocyte nuclear factor 4α (HNF4α). This PBREM-mediated activation is synergistically enhanced by transcription factors like early growth response 1 (EGR1), which loops the promoter-enhancer interaction to amplify induction.[22][23][24][2] Environmental and physiological factors further modulate CYP2B6 transcription via these nuclear receptors; for instance, rifampicin acts as a potent PXR agonist, leading to robust induction of CYP2B6 expression in hepatocytes, while components of cigarette smoke, such as polycyclic aromatic hydrocarbons, engage both CAR and PXR pathways to upregulate the gene. Phenobarbital, a classic CAR activator, similarly binds to the PBREM to drive transcription, highlighting the xenobiotic-sensing role of these receptors in adapting to environmental exposures. These mechanisms contribute to tissue-specific expression patterns, with highest induction observed in the liver.[25][20][6] Post-transcriptional regulation of CYP2B6 involves microRNAs (miRNAs) that target the 3'-untranslated region (3'-UTR) of the mRNA, thereby influencing translation and stability. Several miRNAs, including hsa-miR-25-3p, miR-145, miR-194, miR-222, and miR-378, have been identified as negative regulators that suppress CYP2B6 expression by binding to the 3'-UTR and promoting mRNA degradation or translational repression. Conversely, miR-148a-3p exerts a positive effect by stabilizing CYP2B6 mRNA through direct 3'-UTR interaction, enhancing overall protein levels. Additionally, RNA editing enzymes such as adenosine deaminases acting on RNA (ADARs) modulate mRNA stability; knockdown of ADARs reduces CYP2B6 mRNA half-life, underscoring their role in post-transcriptional fine-tuning.[26][27][28][29]Enzymatic Function
Catalytic Mechanism
The catalytic mechanism of CYP2B6 follows the canonical cytochrome P450 monooxygenation cycle, involving sequential steps of substrate binding, electron transfer, oxygen activation, and oxygen insertion into the substrate.[30] In the initial step, the substrate binds to the resting ferric state of the heme iron in the CYP2B6 active site, inducing a conformational change that facilitates the first one-electron reduction by NADPH-cytochrome P450 reductase (POR), converting the heme iron to the ferrous state.[30] Molecular oxygen then binds to the ferrous heme, forming an oxyferrous complex, which receives a second electron from POR (or occasionally cytochrome b5), leading to the formation of a ferric hydroperoxo intermediate.[30] This intermediate undergoes protonation and heterolytic cleavage of the O-O bond, generating the reactive ferryl-oxo species known as Compound I, a high-valent iron(IV)-oxo porphyrin radical cation that serves as the oxygenating agent.[30] The central heme iron, coordinated by a cysteine thiolate ligand, plays a pivotal role in oxygen binding and activation, while POR provides the essential electrons from NADPH, ensuring the redox balance required for catalysis.[30] CYP2B6 exhibits specificity for oxidative reactions including aliphatic and aromatic hydroxylation, N-dealkylation, and epoxidation, mediated by the electrophilic nature of Compound I, which abstracts a hydrogen atom from the substrate to form a carbon-centered radical that recombines with the iron-bound oxygen.[31] For instance, CYP2B6 catalyzes the hydroxylation of bupropion at the benzylic position to form hydroxybupropion, as well as N-dealkylation of substrates like ketamine and efavirenz, and epoxidation of polyunsaturated fatty acid derivatives such as anandamide to epoxyeicosatrienoic acid ethanolamides.[31][7] These reactions highlight CYP2B6's versatility in inserting one oxygen atom from O2 into the substrate while reducing the second to water, with uncoupling events potentially leading to reactive oxygen species like hydrogen peroxide.[30] Kinetic parameters for CYP2B6-mediated reactions vary by substrate but provide insight into its efficiency; for bupropion hydroxylation using recombinant CYP2B6, the Michaelis constant (Km) is approximately 34–46 μM, with maximum velocity (Vmax) ranging from 9.3 to 22.0 pmol/min/pmol enzyme, reflecting stereoselective metabolism favoring the (S)-enantiomer.[32] These values underscore CYP2B6's moderate substrate affinity and catalytic turnover in monooxygenation processes.[32]Primary Substrates and Metabolic Pathways
CYP2B6 contributes to the Phase I metabolism of approximately 2–10% of clinically used drugs, primarily through oxidative reactions that facilitate their clearance and activation.[33] This enzyme plays a significant role in the biotransformation of various xenobiotics, particularly those that are lipophilic and neutral or weakly basic, by catalyzing monooxygenation reactions involving the insertion of an oxygen atom into the substrate.[1] Among the primary exogenous substrates, efavirenz, an antiretroviral agent, undergoes 8-hydroxylation by CYP2B6 to form 8-hydroxyefavirenz, which is the major metabolic pathway accounting for over 80% of its clearance in vivo.[33] Similarly, bupropion, an antidepressant and smoking cessation aid, is metabolized via hydroxylation at the tert-butyl group to hydroxybupropion, the active metabolite responsible for its therapeutic effects.[33] Methadone, a synthetic opioid used for pain management and opioid dependence treatment, is primarily N-demethylated by CYP2B6, with stereoselective preference for the (S)-enantiomer, leading to the formation of the less active EDDP metabolite.[33] Cyclophosphamide, an anticancer prodrug, is activated through 4-hydroxylation by CYP2B6 to 4-hydroxycyclophosphamide, which spontaneously decomposes to the cytotoxic phosphoramide mustard.[33] Endogenous substrates of CYP2B6 include arachidonic acid derivatives, where the enzyme catalyzes epoxidation to form epoxyeicosatrienoic acids that modulate inflammation and vascular tone.[1] Retinoic acid, a key regulator of cell differentiation and embryonic development, is also metabolized by CYP2B6, albeit to a lesser extent compared to other CYPs like CYP3A4 and CYP2C8, through oxidative pathways that contribute to retinoid homeostasis.[34] Additionally, CYP2B6 hydroxylates steroids such as testosterone and estrone, influencing their endocrine functions.[20]Pharmacological Interactions
Inhibitors and Inducers
CYP2B6 activity can be modulated by various pharmacological agents that act as inhibitors or inducers, influencing drug metabolism and potential drug-drug interactions. Inhibitors are classified as reversible (typically competitive) or irreversible (often mechanism-based inactivators), while inducers primarily act through nuclear receptors such as the pregnane X receptor (PXR) or constitutive androstane receptor (CAR).[35] Reversible inhibitors of CYP2B6 include sertraline, a selective serotonin reuptake inhibitor, which competitively binds to the enzyme with an IC50 of 3.2 µM in human liver microsomes.[35] Mechanism-based inactivators, which form covalent adducts leading to irreversible inhibition, are exemplified by clopidogrel (an antiplatelet agent) with an IC50 of 1.1 µM and ticlopidine (another thienopyridine) with an IC50 range of 0.2–0.8 µM; both undergo metabolic activation to reactive metabolites that inactivate the enzyme.[35] These inhibitors demonstrate moderate to high potency, with ticlopidine showing the strongest affinity among the examples. Inducers of CYP2B6 upregulate its expression and activity, often via PXR activation. Rifampicin, a rifamycin antibiotic, is a potent PXR agonist that induces CYP2B6 mRNA and activity in primary human hepatocytes by 7- to 13-fold, though in vivo effects may be more modest (around 2-fold increase in activity).[36] Efavirenz, a non-nucleoside reverse transcriptase inhibitor, exhibits auto-induction of CYP2B6 through CAR/PXR pathways, achieving up to 6.2-fold induction in hepatocyte cultures and approximately 2.3-fold in vivo after repeated dosing, leading to time-dependent increases in its own clearance.[37] These inducers highlight CYP2B6's responsiveness to xenobiotics, with fold-induction varying by model system and exposure duration.[35]| Agent | Type | Mechanism | Potency (IC50 or Fold-Induction) | Source |
|---|---|---|---|---|
| Sertraline | Reversible (competitive) | Competitive binding | IC50 = 3.2 µM | [35] |
| Clopidogrel | Irreversible (mechanism-based) | Covalent adduct formation | IC50 = 1.1 µM | [35] |
| Ticlopidine | Irreversible (mechanism-based) | Covalent adduct formation | IC50 = 0.2–0.8 µM | [35] |
| Rifampicin | Inducer | PXR activation | 7- to 13-fold (hepatocytes) | [36] |
| Efavirenz | Inducer (auto-induction) | CAR/PXR activation | 6.2-fold (hepatocytes); 2.3-fold (in vivo) | [37] |
Drug-Drug Interactions
CYP2B6-mediated drug-drug interactions (DDIs) occur primarily through induction or inhibition of the enzyme, altering the metabolism of co-administered substrates and leading to changes in drug exposure that can affect efficacy and safety. These interactions are particularly relevant for drugs like efavirenz and methadone, where modulation of CYP2B6 activity can result in subtherapeutic concentrations or toxicity. According to FDA classifications, CYP2B6 substrates include efavirenz and bupropion, while rifampin serves as a moderate clinical index inducer, capable of decreasing the area under the curve (AUC) of sensitive substrates by 50-80%.[38] A prominent example is the auto-induction of efavirenz, an antiretroviral primarily metabolized by CYP2B6, which upon multiple dosing induces CYP2B6 expression, thereby increasing its own clearance and reducing plasma concentrations by approximately 20-30% after 2-4 weeks of therapy. This time-dependent decrease in exposure can lead to suboptimal viral suppression if doses are not adjusted, particularly in long-term HIV treatment regimens.[39][40] Another clinically significant interaction involves rifampin, a potent CYP2B6 inducer used in tuberculosis treatment, which accelerates methadone metabolism—a CYP2B6 substrate—resulting in decreased methadone plasma levels by up to 50-75%, often precipitating opioid withdrawal symptoms such as nausea, anxiety, and cravings in patients on maintenance therapy. This interaction is classified as major in severity by regulatory guidelines due to its potential to compromise addiction treatment outcomes.[38][41][42] In HIV populations, CYP2B6 DDIs pose elevated risks, especially in co-infected patients receiving efavirenz-based regimens alongside rifampin for tuberculosis, where induction can reduce efavirenz exposure by approximately 22%, increasing the likelihood of virologic failure and resistance development. To mitigate this, guidelines recommend increasing the efavirenz dose to 800 mg once daily when co-administered with rifampin.[43] To mitigate these interactions, therapeutic drug monitoring (TDM) is recommended for high-risk substrates like efavirenz and methadone, involving plasma level assessments to guide dose adjustments and ensure concentrations remain within therapeutic ranges (e.g., 1-4 mg/L for efavirenz). Clinical protocols emphasize baseline TDM before initiating inducers like rifampin, with follow-up monitoring every 2-4 weeks during co-administration to prevent adverse outcomes.[33][44]Genetic Variation and Clinical Implications
Polymorphisms and Allelic Variants
The CYP2B6 gene exhibits extensive genetic variation, with over 100 single nucleotide polymorphisms (SNPs) identified across its sequence, many of which contribute to functional diversity in enzyme activity.[5] These variations are cataloged using the star (*) allele nomenclature established by the Pharmacogene Variation (PharmVar) Consortium, which defines haplotypes based on combinations of SNPs relative to the reference allele *1.[5] To date, more than 40 distinct star alleles have been characterized, though the majority of pharmacogenetic impact stems from a few common variants.[1] The reference allele *1 represents the wild-type sequence with normal enzymatic function.[5] One major variant is *5, defined by c.1459C>T (p.R487C; rs3211371) in exon 9, which is associated with decreased expression and reduced catalytic activity due to altered protein stability.[5] Another prominent allele, *6, is characterized by two linked SNPs: c.516G>T (p.Q172H; rs3745274) in exon 4 and c.785A>G (p.K262R; rs2279343) in exon 6; the c.516G>T variant introduces a cryptic splice site, leading to aberrant splicing and significantly reduced enzyme activity (typically 20-50% of wild-type levels).[5] The *1/*6 haplotype is among the most common diplotypes observed globally.[5] The *18 allele, defined by c.983T>C (p.I328T; rs28399499), results in a nonfunctional enzyme and is prevalent in African populations (4-12%).[1] Allele frequencies vary markedly by ethnicity, as documented in databases such as PharmGKB and gnomAD (v3.1.2, aggregating data up to 2022 with ongoing updates).[45] The *6 allele occurs at frequencies of 15-30% in Caucasian/European populations and 30-50% in African and African American populations, with intermediate rates (20-35%) in Asian and Latino groups.[5] In contrast, *5 is less frequent overall, ranging from ~10-15% in Europeans and Asians to ~3-5% in Africans.[5] These distributions reflect historical migration patterns and selective pressures, contributing to population-specific pharmacogenetic profiles.[45] Functional classifications of CYP2B6 diplotypes are guided by the Clinical Pharmacogenetics Implementation Consortium (CPIC), which assigns metabolizer phenotypes based on predicted enzyme activity.[46] Poor metabolizers (PM) carry two no-function or decreased-function alleles (e.g., *6/*6 or *5/*6), resulting in negligible activity.[46] Intermediate metabolizers (IM) have one normal-function allele and one decreased-function allele (e.g., *1/*6), yielding moderately reduced activity.[46] Normal metabolizers (NM) possess two normal-function alleles (e.g., *1/*1), while rapid metabolizers (RM) include at least one increased-function allele like *4 (c.785A>G alone; rs2279343), conferring enhanced activity; ultrarapid metabolizers (UM) are rare and typically involve multiple increased-function variants.[46] These categories inform dosing adjustments for CYP2B6 substrates in clinical guidelines.[46]| Star Allele | Defining Variant(s) | Functional Effect | Approximate Global Frequency Range |
|---|---|---|---|
| *1 | None (wild-type) | Normal | 50-70% |
| *5 | c.1459C>T (p.R487C) | Decreased | 5-15% |
| *6 | c.516G>T (p.Q172H); c.785A>G (p.K262R) | Decreased | 20-40% |