Functional assessment of CYP3A4 allelic variants on lidocaine metabolism in vitro.

AIM: Human cytochrome P450 3A4 is the most abundant isoform of P450 enzyme in the liver. It plays an important role in the metabolism of wide variety of xenobiotic and endogenous substrates. So far, there are few reports about the functional characterization of CYP3A4 variants in terms of specific substrates. The aim of this study was to systematically investigate the genetic polymorphisms of 23 CYP3A4 alleles and evaluate their catalytic activities on the metabolism of lidocaine in vitro. METHODS AND
RESULTS: The wild-type and 22 CYP3A4 variants were expressed in Spodoptera frugiperda 21 insect cells. Then the insect microsomes were incubated with the CYP3A4-specific substrate lidocaine. Reactions were performed with 50-3,000 µM for 60 min at 37°C. Lidocaine and its metabolite monoethylglycinexylidide were analyzed by ultra-performance liquid chromatography-tandem mass spectrometry system. Of the 23 CYP3A4 allelic variants tested, 2 variants (CYP3A4*17 and CYP3A4*30) had no detectable enzyme activity; and 5 variants (CYP3A4*2, CYP3A4*5, CYP3A4*9, CYP3A4*16 and CYP3A4*24) showed significantly decreased intrinsic clearance values compared with wild-type CYP3A4*1.
CONCLUSION: As the first study of all these CYP3A4 alleles for lidocaine metabolism, our results in vitro assessment may provide novel insights into the allele-specific and substrate-specific activity of CYP3A4 and may also offer a reference to the personalized treatment of lidocaine in a clinical setting.

Introduction

Lidocaine, which was the first sodium (Na+) channel blocker, is still widely used in clinic as an amide-type local anesthetic agent now.1 It inhibits nerve impulse transmission by blocking the fast voltage-gated Na+ channels in the neuronal cell membrane thereby producing local anesthetic action. Lidocaine has good activity when it is applied to superficial body sites, penetrating mucous membranes to reduce the sensation of pain.2 Additionally, lidocaine is also an antiarrhythmic drug, which is administered intravenously for the prevention and treatment of ventricular arrhythmias in patients with acute myocardial infarction or other cardiac diseases.3 Nowadays, lidocaine is prevailing used in cosmetic plastic surgery under local infiltration anesthesia.4,5

Lidocaine undergoes extensive metabolism in the liver. Monoethylglycinexylidide (MEGX) is the principle metabolite and 3-OH lidocaine is a minor metabolite.6 Based on previous in vitro studies, cytochrome P450 3A4 (CYP3A4) has been regarded as the main CYP isoform responsible for the de-ethylation of lidocaine to its primary metabolite, MEGX.7,8

CYP3A4, as a member of P450 enzyme superfamily, is the most important drug-metabolizing enzyme in human liver and gastrointestinal tract.9 It is well known that CYP3A4 enzyme plays a major role in the oxidative metabolism of ~30%–40% of clinically used drugs, such as certain antibiotics (erythromycin), antiarrhythmics (quinidine), antidepressants (sertraline), Cardiovascular drugs (verapamil) as well as some endogenous steroids (testosterone and estradiol).10,11 The expression of CYP3A4 varies 40-fold in individual human livers,12 which indicates that CYP3A4 is one of the highly polymorphic enzymes. Recently, increasing evidence has shown that genetic polymorphisms of CYP3A4 significantly contribute to the wide inter-individual variability of enzyme activity.13 The enormous variation observed in drug metabolism may result in undesirable adverse side effects or therapeutic failure, thus more attention should be paid to genetic polymorphism of CYP3A4.

To date, 46 different types of CYP3A4 allelic variants have been identified in the Human CYP Allele Nomenclature Committee website (http://www.cypalleles.ki.se/cyp3a4.htm). In our previous study, Hu et al16 sequenced the promoter regions and 13 exon junctions of CYP3A4 in DNA from 1,114 healthy subjects from the southern region of China. Five previously reported alleles (CYP3A4*1G, *4, *5, *18B and *23) were detected.14 In addition, a total of 7 novel exonic variants were also detected and further named as new alleles CYP3A4*28–*34 by the Human CYP Allele Nomenclature Committee. In this study, lidocaine, as a CYP3A4-specific substrate, was used to assess the catalytic activities of wild-type CYP3A4*1 and 22 CYP3A4 alleles found in the Chinese Han population (15 alleles were previously reported, and 7 novel alleles with coding regions were newly found).

Materials and method

Chemicals and materials

Lidocaine was obtained from Shanghai Canspec Scientific Instruments Co., Ltd (Perfemiker, Shanghai, China) and its metabolite MEGX was purchased from Toronto Research Chemicals Inc (Toronto, Ontario, Canada). The reduced nicotinamide adenine dinucleotide phosphate (NADPH) and procaine (internal standard) were obtained from Sigma (St Louis, MO, USA). Cytochrome b5 microsomes were kind gifts from Beijing Hospital.24 Spodoptera frugiperda 21 (Sf21) insect cells, fetal bovine serum, Sf-900™ III SFM insect culture medium, pFastBac Dual vector and Bac-to-Bac Baculovirus Expression System were purchased from Invitrogen (Carlsbad, CA, USA). The CORTECS® ultra-performance liquid chromatography (UPLC)® hydrophilic interaction liquid chromatography (HILIC)® column (2.1×50 mm, 1.6 µM) was obtained from the Waters (Dublin, Ireland). High performance liquid chromatography (HPLC)-grade organic solvents and LC-MS grade acetonitrile were from Merck (Darmstadt, Germany). Ultrapure water was freshly purified by a Milli-Q A10 System (Milli-pore, Billerica, MA, USA). Formic acid (FA, 98% purity) of LC-MS grade was from Sigma-Aldrich (Munich, Germany). All the other chemicals and solvents used were of the analytical grade commercially available.

Construction of the expression vectors

The dual-expression baculovirus vector pFastBac Dual was used to create the intermediate plasmid pFastBac-OR by inserting the CYPOR cDNA into the cloning sites downstream of the P10 promoter. The open reading frame (ORF) fragments for each CYP3A4 variants were constructed by the overlap extension polymerase chain reaction (PCR) amplification method using the primers that are listed in Table 1, and then isolated ORF fragments by PCR amplification using the forward primer 3A4-SALF (5′-ACCAGTCGACATGG CTCTCATCCCAGAC-3′, introducing 1 Sal site) and the reverse primer 3A4-SR (5′-CCAAACTAGTTCAGGCT CCACTTACGGT-3′, introducing 1 Spe site). These full-length PCR products for each of the CYP3A4 variants were digested and ligated to the pFastBac-OR receptor vector to produce the ultimate dual-expression vector pFastBac-OR-CYP3A4. To ensure that no errors were introduced during PCR amplification, all of the cDNA regions were confirmed by sequencing the plasmid constructs using the CEQ DTCS Quick Start Kit (Beckman Coulter, Inc, Brea, CA, USA) on the CEQ 8000 Genetic Analysis System.

Table 1

PCR primers used for the site-mutation of CYP3A4

Variants	cDNA changes	Reverse primer (5′→3′)	Forward primer (5′→3′)
CYP3A4*2 (S222P)	664T>C	CTGTTATTGGGAGAAAGAA	TTCTTTCTCCCAATAACAG
CYP3A4*3 (M445T)	1334T>C	GCAAACCTCGTGCCAATGC	GCATTGGCACGAGGTTTGC
CYP3A4*4 (I118V)	352A>G	CTATAGAGACGGCACTTTT	AAAAGTGCC
CYP3A4*5 (P218R)	653C>G	AGAAAGAATCGATCCAAA	TTTGGATCGATTCTTTCT
CYP3A4*9 (V170I)	508G>A	TCAAGGTGATAGGCTTGCC	GGCAAGCCTATCACCTTGA
CYP3A4*10 (D174H)	520G>C	CAAAGACGTGTTTCAAGGT	ACCTTGAAACACGTCTTTG
CYP3A4*11 (T363M)	1088C>T	AATCTGAGCATTTCATTCA	TGAATGAAATGCTCAGATT
CYP3A4*14 (L15P)	44T>C	ACCAGTCGACATGGCTCTCATCCCAGAC	TTGGCCATGGAAACCTGGCTTCTCCCGGCTG
CYP3A4*15 (R162Q)	485G>A	TCTGCTTCCTGCCTCAGAT	ATCTGAGGCAGGAAGCAGA
CYP3A4*16 (T185S)	554C>G	GATGTGCTACTGATCACAT	ATGTGATCAGTAGCACATC
CYP3A4*17 (F189S)	566T>C	TTCACTCCAGATGATGTGC	GCACATCATCTGGAGTGAA
CYP3A4*18 (L293P)	878T>C	ACGAGCTCCGGATCGGACA	TGTCCGATCCGGAGCTCGT
CYP3A4*19 (P467S)	1399C>T	CTTTACAAGATTTGAAGGA	TCCTTCAAATCTTGTAAAG
CYP3A4*23 (R162W)	484C>T	CTGCTTCCCACCTCAGATT	AATCTGAGGTGGGAAGCAG
CYP3A4*24 (Q200H)	600A>T	AAAGGGGTCATGTGGATTG	CAATCCACATGACCCCTTT
CYP3A4*28 (L22V)	64C>G	ATAGATAGACGAGCACCAG	CTGGTGCTCGTCTATCTAT
CYP3A4*29 (F113I)	337T>A	TTTTCATAATTCCCACTGG	CCAGTGGGAATTATGAAAA
CYP3A4*30 (R130STOP)	388C>T	GCAATGATCATAATCTCTT	AAGAGATTATGATCATTGC
CYP3A4*31 (H324Q)	972C>A	GACATCAGGTTGAGTGGCC	GGCCACTCAACCTGATGTC
CYP3A4*32 (I335T)	1004T>C	ACTGCATCAGTTTCCTCCT	AGGAGGAAACTGATGCAGT
CYP3A4*33 (A370S)	1108G>T	GTCTCATAGAAATTGGGAA	TTCCCAATTTCTATGAGAC
CYP3A4*34 (I427V)	1279A>G	AAGGATCTACGTTGTCCTT	AAGGACAACGTAGATCCTT

Note: The positions where the nucleotides are exchanged are indicated with underlined bold characters.

Expression of CYP3A4 variant proteins in Sf21 insect cells

According to the manufacturer’s procedure, recombinant baculoviruses were effectively generated in Sf21 insect cells. And then Sf21 insect cells were infected with these viruses in Sf-900™ III SFM insect culture medium containing 10% fetal bovine serum, 1× Antibiotic-Antimycotic and 4 µg/mL hemin. Seventy two hours after transfection, the cells were collected and re-suspended with 100 mM phosphate buffer (pH 7.4) containing 1 mM EDTA, 0.25 M sucrose and 0.5 mM phenylmethylsulfonyl fluoride, then the cell suspension was centrifuged at 1,600× g for 5 min. After centrifugation, the pellets were re-suspended and sonicated for 50 s on ice and centrifuged at 14,000× g at 4°C for 20 min to remove the precipitate. The microsomal fraction was prepared by ultracentrifugation at 100,000× g at 4°C for 1 h, and this pellet was re-suspended in stock solution (100 mM KPO4, pH 7.4, containing 20% glycerol) and stored at −80°C before use.

Protein expression levels determination

Difference spectra of microsomal preparations were measured in UV-Visible spectrophotometer (Thermo Scientific, Waltham, MA, USA) with 1-cm optical path cuvettes. Protein concentration was determined by performing Pierce™ BCA protein assay kit (Thermo Scientific). Microsomal preparations, usually containing 2 mg of protein per mL of 0.1 M phosphate buffer (pH 7.0), were placed in both the sample and reference cells. After recording the base-line, CO was carefully bubbled through the sample for about 20 s, and then reduction of samples with a few milligrams of solid Na2S2O4. CYP3A4 expression levels were determined by measured difference spectra.

Conditions for enzymatic activity analysis

The incubation mixture included 5 pmol wild-type CYP3A4*1 or other CYP3A4 mutants, 5 pmol purified cytochrome b5, lidocaine and 100 mmol/L potassium phosphate buffer (pH 7.4). The addition of b5 was to deliver electrons and support CYP3A4 enzymatic activities. Lidocaine was initially prepared in methanol solution and the final concentration of lidocaine in the mixture for kinetic analysis ranged from 50 to 3,000 µM. The reaction was allowed to preincubate for 5 min at 37°C in a Fisher shaking water bath. Then 10 µL 1 mM NADPH, which plays an important role in the delivery of hydrogen, was added to start the reaction at 37°C in a final volume of 200 µL. The mixture was incubated at 37°C for 60 min. Reactions were terminated by cooling to −80°C immediately. Then 50 µL 0.1 M NaOH and 50 µL 500 µg/mL procaine were added to the incubation mixture, followed by the addition of 1 mL acetic ether. The mixture was vortexed for 2 min and centrifuged at 13,000 rpm at 4°C for 10 min, the organic phase was transferred into a clean tube and it was dried under a nitrogen stream. The resulting residue was dissolved in 100 µL mobile phase and 2 µL of the mixture was injected into the UPLC system for analysis. In addition, the experiments were carried out in triplicate and kept parallel, data presented as the mean ± SD. Additionally, in order to ensure that the metabolic reaction is within the linear range of the given incubation time and protein concentration, the incubation conditions have been optimized.

UPLC was performed on a Waters CORTECS UPLC HILIC column (2.1×50 mm, 1.6 µM). The column temperature was maintained at 30°C. The initial mobile phase consisted of 10 mM ammonium formate with 0.125% FA (solvent A) and acetonitrile (solvent B). The isocratic elution with 10% solvent A +90% solvent B was at a flow rate of 0.8 mL/min by injection volume 2 µL. The total run time of the analytes was 2.5 min. Under previously mentioned conditions, lidocaine, MEGX and procaine were well separated and their retention times were 0.519, 0.721 and 0.868 min, respectively. The column eluent was monitored with an ultraviolet detector at wavelength of 210 nm. A 7-point standard curve, which was prepared using spiked incubation samples, was used to quantify MEGX. In addition, testosterone and its metabolite 6β-hydroxy-testosterone were detected by using Agilent 1260 HPLC with an Agilent RRHD Eclipse Plus C18 column (3.0*100 mm, 1.8 µm, Agilent Technologies, Santa Clara, CA, USA). The mobile phases contained 0.05% trifluoroacetic acid in water (A) and 45% acetonitrile (B). We kept flow rate at 0.35 mL/min and carried out an isocratic elution with 55% solvent A and 45% solvent B for 5 min.

Statistical analysis

Michaelis–Menten analysis (substrate vs velocity) was estimated using GraphPad Prism 5 (GraphPad Software Inc., San Diego, CA, USA) by non-linear regression curve fitting. And enzyme kinetic parameters (K and V) for each variant are presented as the mean ± SD of 3 parallel experiments. The intrinsic clearance (C) was determined as the ratio of V/K. Statistical analysis was carried out with the Statistical Package for the Social Sciences (version 17.0; SPSS Inc., Chicago, IL, USA), and 1-way analysis of variance was used for intergroup comparison together with the post hoc Dunnet test to analyze differences in catalytic activity between wild type and other variants. (*P<0.05 represents statistically significant).

Results

To obtain comprehensive data on the enzymatic properties for catalysis of MEGX by all reported CYP3A4 variants in Chinese population, the wild-type CYP3A4*1 and 22 allelic variants of CYP3A4 were assessed in our study. The ratio of V/K represents the intrinsic clearance (C), which can evaluate the enzymatic activity of each CYP3A4 allelic variant as an evaluation criteria. Michaelis–Menten plots of lidocaine for the tested 23 CYP3A4 enzymes are shown in Figure 1, and the corresponding kinetic parameters are summarized in Table 2.

Figure 1

Michaelis–Menten curve of the enzymatic activity of the wild-type and 22 variants toward lidocaine.

Notes: Each point represents the mean ± SD of 3 parallel experiments. The variants with designated allele names have been arranged into 6 groups (A–F).

Abbreviation: MEGX, monoethylglycinexylidide.

Table 2

Kinetic parameters for MEGX activities of wild-type and 22 CYP3A4 allelic variants against lidocaine

Variants	Vmax (pmol/min/pmol P450)	Km (µM)	Intrinsic clearance (Vmax/Km)	Relative clearance (% of wild type)
CYP3A4*1	7,885.00±245.95	471.80±62.71	16.98±1.63	100.00
CYP3A4*2 (S222P)	4,015.00±30.44**	842.03±38.09**	4.73±0.19**	27.93**
CYP3A4*3 (M445T)	11,350.00±153.08**	639.57±24.81*	18.04±0.49	106.61
CYP3A4*4 (I118V)	8,442.00±824.33	542.17±169.20	14.80±3.21	85.95
CYP3A4*5 (P218R)	6,436.00±265.43**	1,103.67±124.03**	5.60±0.41**	32.99**
CYP3A4*9 (V170I)	8,304.00±272.52	713.40±51.53**	11.52±0.47**	67.93**
CYP3A4*10 (D174H)	10,730.00±523.55**	554.43±157.91	19.09±3.96	109.93
CYP3A4*11 (T363M)	27,020.00±2,343.67**	702.57±167.08	36.42±5.47**	213.61**
CYP3A4*14 (L15P)	10,120.00±317.96**	406.63±27.76	25.65±1.00**	151.58**
CYP3A4*15 (R162Q)	10,730.00±683.04**	491.07±41.54	20.87±0.47*	123.27*
CYP3A4*16 (T185S)	6,804.00±202.09**	812.23±56.71**	8.11±0.52**	47.91**
CYP3A4*17 (F189S)	ND	ND	ND	ND
CYP3A4*18 (L293P)	13,470.00±217.79**	493.97±32.27	27.20±1.55**	160.51**
CYP3A4*19 (P467S)	9,887.00±325.53**	466.17±99.43	22.40±4.01	130.35*
CYP3A4*23 (R162W)	10,560.00±195.53**	296.73±4.99**	35.04±0.77**	206.96**
CYP3A4*24 (Q200H)	304.60±10.90**	70.83±40.25**	4.93±2.15**	30.29**
CYP3A4*28 (L22V)	5,224.00±58.29**	290.60±25.19**	17.87±1.73	105.29
CYP3A4*29 (F113I)	7,771.00±344.40	310.00±42.34*	24.08±2.28*	141.84*
CYP3A4*30 (R130STOP)	ND	ND	ND	ND
CYP3A4*31 (H324Q)	7,949.00±99.96	237.30±20.46**	33.58±2.89**	197.87**
CYP3A4*32 (I335T)	8,743.67±482.94**	289.60±46.99**	30.74±5.18**	182.56**
CYP3A4*33 (A370S)	4,865.00±130.48**	328.23±24.17*	14.43±0.70	85.16
CYP3A4*34 (I427V)	12,225.67±1,244.09**	532.50±343.48**	28.15±12.35**	154.49**

Note: Significantly different from wild-type CYP3A4,

P<0.05,

P<0.01.

Abbreviations: MEGX, monoethylglycinexylidide; ND, not determined.

For the Michaelis–Menten kinetic analysis, the kinetic parameters of CYP3A4*17 and CYP3A4*30 could not be determined as no concentration of MEGX was detected, which indicated that CYP3A4*17 and CYP3A4*30 showed extremely low activity or no activity. Except for CYP3A4*17 and CYP3A4*30, almost all allelic variants in Table 2 showed significant alteration in V values compared with the wild-type CYP3A4*1: Only 4 variants CYP3A4*4, CYP3A4*9, CYP3A4*29, and CYP3A4*31 exhibited no statistical difference; 6 variants (CYP3A4*2, CYP3A4*5, CYP3A4*16, CYP3A4*24, CYP3A4*28, and CYP3A4*33) showed mild decrease; and the remaining 10 variants displayed significantly increased V values. Meanwhile, most variants showed obvious changes on K values: 6 variants (CYP3A4*2, CYP3A4*3, CYP3A4*5, CYP3A4*9, CYP3A4*16, and CYP3A4*34) exhibited increased K values with ~1.13–2.34-fold compared with CYP3A4*1 and 7 variants (CYP3A4*23, CYP3A4*24, CYP3A4*28, CYP3A4*29, CYP3A4*31, CYP3A4*32, and CYP3A4*33) decreased to 15.01%–69.57%. As a result, according to intrinsic clearance (V/K) values of MEGX compared with the wild type, CYP3A4 alleles could be classified into 3 categories: ten variants (CYP3A4*11, *14, *15, *18, *19, *23, *29, *31, *32, and *34) exhibited significantly increased intrinsic clearance values (123.27%–213.61% relative clearance); 5 variants (CYP3A4*2, *5, *9, *16, and *24) showed lower intrinsic clearance values than CYP3A4*1 (27.93%–67.93% relative clearance). Another 5 variants (CYP3A4*3, *4, *10, *28, and *33) were without statistical significance.

In addition, to investigate the enzymatic abilities of 23 CYP3A4 variants between different substrate, lidocaine and 1 typical probing substrate for the CYP3A4 enzyme were used in the in vitro functional analysis. As shown in Figure 2, 2 variants, CYP3A4*17 and CYP3A4*30, exhibited extremely low enzymatic activity or null function for both substrates. And 9 variants (CYP3A4*4, CYP3A4*5, CYP3A4*11, CYP3A4*15, CYP3A4*16, CYP3A4*17, CYP3A4*24, CYP3A4*30, and CYP3A4*31) showed similar changed trend of enzymatic activities compared with CYP3A4*1 toward lidocaine and testosterone. Whereas, the remaining CYP3A4 variants, especially CYP3A4*2, CYP3A4*14, CYP3A4*23, CYP3A4*29, CYP3A4*32, and CYP3A4*34, displayed obvious different relative clearance between 2 substrates.

Figure 2

The catalytic activity of expressed CYP3A4 variants toward typical probe substrates testosterone and lidocaine.

Notes: Values were calculated as the percentages of the activities of wild-type protein. Data are presented as the mean ± SD of three independent experiments. *P<0.05; **P<0.01.

Discussion

CYP3A4 exhibits remarkable individual variation in expression levels, which may be caused by genetic, environmental, pathological, hormonal, and dietary factors.15 Increasing evidence suggests that genetic polymorphism is a primary source of inter-individual difference in drug metabolism.14,16 Genetic polymorphism of CYP3A4 can greatly influence the rate of elimination of lidocaine, thereby may result in adverse effects or therapeutic failures. Patients with decreased enzymatic activity are at high risk of undesirable adverse effects such as toxicity and delayed emergence from anesthesia. Therefore, it is of great significance to functionally characterize the enzymatic activity of CYP3A4 variants in the metabolism of lidocaine in vitro.

To better understand the effects of CYP3A4 variants on the metabolism of lidocaine in vitro, we analyzed the wild-type CYP3A4*1 and 22 CYP3A4 variants found in Chinese Han population in detail, of which 7 (CYP3A4*28–*34) were new alleles and another 15 alleles (CYP3A4*2, *3, *4, *5, *9, *10, *11, *14, *15, *16, *17, *18, *19, *23, and *24) had previously been reported. The enzymatic activity of CYP3A4*1 was used as a control group. As a novel allelic variant, the CYP3A4*30 (R130STOP), which contains the premature stop codon, produces a nonfunctional protein with a shorter peptide. As a consequence, the kinetic parameters of CYP3A4*30 could not be detected and it showed no catalytic activity on lidocaine metabolism. Similar to CYP3A4*30, CYP3A4*17 exhibited extremely low enzymatic activity toward lidocaine. According to previous reports, CYP3A4*17 produced an amino acid substitution: F189S in exon 7, and it exhibited decreased catalytic activity compared with the wild type for both testosterone and chlorpyrifos.17,18

Aside from CYP3A4*17 and CYP3A4*30, we found that most of CYP3A4 variants exhibited higher enzymatic activity than wild type, whereas only 5 alleles (CYP3A4*2, *5, *9, *16, and *24) showed a significantly decreased relative clearance compared with CYP3A4*1 (27.93%–67.93%). The results indicate that these alleles could be classified as poor metabolizer alleles for lidocaine. Therefore, patients carrying the CYP3A4*2, *5, *9, *16, *17, *24, or *30 should pay more attention to the dose of lidocaine, in order to avoid lidocaine-induced toxicity or delayed emergence from anesthesia.

Four (CYP3A4*29, *31, *32, and *34) of novel alleles exhibited significantly increased intrinsic clearance value for lidocaine from 141.84% to 197.87% of wild-type CYP3A4*1. CYP3A4*28 showed both lower V and K values so that the intrinsic clearance showed no significant difference to that of the CYP3A4*1. Hu et al found that CYP3A4*28 (L22V), CYP3A4*31 (H324Q) and CYP3A4*32 (I335T) can damage protein function.16 However, as for our result that these alleles exhibited higher catalytic activity than wild type in our study, it may be interpreted that His324 and Ile335 are not involved in the active site for drug-substrate binding according to previously reported crystal structures of the CYP3A4 enzyme.16

CYP3A4*18, contains a nucleotide substitution of T>C at position 878 of the cDNA of CYP3A4 and results in an amino acid change of Leu to Pro at codon 293, is commonly detected in Asians. According to previous study, CYP3A4*18 exhibited increased turnover numbers for testosterone and chlorpyrifos in vitro.17 Similarly, in our study, CYP3A4*18, with a distinctly increased V, showed significantly increased relative clearance compared with CYP3A4*1. These results are consistent with the previous study of testosterone and chlorpyrifos,17 2 typical probing substrates for CYP3A4, thus indicating that our CYP expression and in vitro metabolism system were suitable for analyzing the catalytic activities of the CYP3A4 allelic variants. In addition, CYP3A4*23 was reported by Hu et al for the first time in the Chinese population. In our work, CYP3A4*23 exhibited significantly increased intrinsic clearance value (206.96% of CYP3A4*1) owing to marked increase in V and huge decrease in K.

According to our previous studies, CYP2D6, CYP2C9 and CYP2C19 not only exhibit significant genetic polymorphisms between individuals, but also had substrate-specificity, which show marked differences on the metabolism of various clinical drugs.19–21 Similarly, it has been reported that there is approximately a 10-fold variation in the metabolism of CYP3A4 substrates in vivo, which reveal that CYP3A4 may also exhibit a broad substrate specificity.22,23 However, thus far, few studies have been performed on CYP3A4 genetic polymorphisms in the Chinese Han population and this is the first report of all these alleles for lidocaine metabolism. To better understand the enzymatic characteristics of these CYP3A4 allelic isoforms, testosterone, as a probe substrate of CYP3A4, was also used to detect the catalytic activities of these 23 CYP3A4 variants. Then we compared lidocaine with testosterone (Figure 2), although some CYP3A4 variants exhibited similar pattern for the metabolic activity toward testosterone, most of the variants, especially like CYP3A4*2, CYP3A4*29, CYP3A4*32, CYP3A4*33, and CYP3A4*34 showed different relative activities for the probe drug. These results suggested that CYP3A4 also had substrate-specific alterations in metabolic activity and we infer that amino acid substitution in these sites might have different impacts for different substrate of CYP3A4. Moreover, genetic polymorphism and substrate-specificity of CYP3A4 need further study on daily used drugs in order to help in personalized medicine for patients in a safe and reduced toxicity reaction.

Conclusion

In summary, this study provides functional assessment of 23 CYP3A4 variants on lidocaine metabolism in vitro for the first time. Our data revealed that most of these tested variants exhibited significantly increased catalytic activities toward lidocaine, which may offer a reference to the personalized medication for lidocaine in clinical practice. As the first study of all these alleles on lidocaine metabolism, the research may help to improve our understanding of the polymorphism of CYP3A4; on the other hand, this study could help clinical assessment of the lidocaine metabolism and aid the application of this knowledge in clinical practice. However, further studies are required to examine a wider range of CYP3A4 substrates, including clinically used drugs.