Affiliations of authors: The Breast Cancer Program, Departments of Medicine and Oncology, Lombardi Cancer Center, Georgetown University Medical Center, Washington, DC (VS, MDJ, AN, PB, DFH); and Division of Clinical Pharmacology, Department of Medicine, Indiana University School of Medicine, Indianapolis, IN (JMR, AM, PB, ZD, DAF).
Correspondence to: David A. Flockhart, MD, PhD, Division of Clinical Pharmacology, Indiana University School of Medicine, 1001 West 10th St., Myers Bldg. W7123, Indianapolis, IN 46203 (e-mail: dflockha{at}iupui.edu)
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ABSTRACT |
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INTRODUCTION |
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Although tamoxifen is generally well tolerated, up to 80% of women who take tamoxifen complain of hot flashes and up to 45% of women grade them as severe (2). Thus, the treatment of hot flashes is a common reason for co-prescription of tamoxifen with other drugs. Because exogenous estrogens are not commonly recommended for the treatment of hot flashes in women with breast cancer, other therapies have been sought (7). Several studies have recently demonstrated that the antidepressants of the selective serotonin reuptake inhibitor (SSRI) and the selective norepinephrine reuptake inhibitor (SNRI) classes are effective for the treatment of hot flashes. In separate prospective, randomized, placebo-controlled studies (810), the SNRI venlafaxine and the SSRIs fluoxetine and paroxetine were each associated with a 50%65% reduction in the frequency and severity of hot flashes, whereas the placebo was associated with a 27%38% reduction. Given these recent results, it is likely that the frequency of administering tamoxifen with drugs of the SSRI and SNRI classes will increase.
Tamoxifen, venlafaxine, paroxetine, and fluoxetine are all metabolized by a shared pathway involving the cytochrome P450 enzyme family. In the liver, extensive N-demethylation and 4-hydroxylation of tamoxifen are catalyzed by cytochrome P450 enzymes. Within this family of enzymes, CYP2D6, CYP2C9, and CYP3A4 are thought to be primarily responsible for the metabolism of tamoxifen into its active metabolite 4-hydroxy-tamoxifen (1113). However, the routes of metabolism to other potentially active metabolites such as 4-hydroxy-N-desmethyl tamoxifen have not been characterized (6).
Because venlafaxine, paroxetine, and fluoxetine are all metabolized by CYP2D6 and are potent inhibitors of this enzyme (1420), we hypothesized that SNRIs and SSRIs might alter tamoxifen metabolism by disrupting the conversion of tamoxifen to 4-hydroxy-tamoxifen. To test this hypothesis, we conducted a prospective clinical trial to determine the effect of paroxetine on the pharmacokinetics of tamoxifen and its metabolites in women who were receiving adjuvant tamoxifen therapy for breast cancer. Herein, we report the identification and characterization of a previously unrecognized active metabolite of tamoxifen, 4-hydroxy-N-desmethyl tamoxifen, a metabolite that decreased upon paroxetine coadministration, and which we have named endoxifen.
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SUBJECTS AND METHODS |
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Eligible women included those with a history of breast cancer who had no evidence of disease and who were receiving standard-dose tamoxifen as an adjuvant treatment. The women had to have been taking tamoxifen for at least 4 weeks before starting the study and had to have continued taking tamoxifen throughout the study period between June 1999 and July 2000. For entry into the study, women had to have troublesome hot flashes reported to their primary care physician for which treatment with a non-hormonal agent was appropriate.
Women were excluded from the study if they had been taking other, simultaneous treatments for hot flashes, such as clonidine or herbal supplements, for at least 1 month before enrolling in the study. Although women were permitted to take vitamin E while on the study, they were excluded if they were taking concomitant medications that are known to inhibit CYP2D6 activity, including amiodarone, haloperidol, indinavir, ritonavir, or quinidine, or if they were taking any SSRI other than paroxetine. Women were excluded from the study if they had received cytotoxic chemotherapy, hormonal therapy other than tamoxifen, or radiation therapy for at least 1 month before starting the study. Women were also excluded if they were pregnant or lactating, or had a known allergy or hypersensitivity to paroxetine hydrochloride.
Trial Design
Twelve eligible women were enrolled sequentially between June 1999 and July 2000. Each individual signed an informed consent form. The study was approved by the Georgetown University Medical Center Institutional Review Board. Baseline blood samples were obtained to determine the CYP2D6 genotype and the plasma concentrations of tamoxifen and its metabolites. No selection of patients by genotype was made, and no otherwise eligible patients were excluded on the basis of CYP2D6 genotype. Each woman was administered paroxetine for 4 weeks at a dose of 10 mg/day while continuing tamoxifen at a dose of 20 mg/day. Paroxetine and tamoxifen were both administered by mouth. After 4 weeks of co-prescription of paroxetine and tamoxifen, a second blood sample was collected to measure the plasma concentrations of tamoxifen and its metabolites.
CYP2D6 Genotype
A 5-mL blood sample was collected in a tube containing sodium heparin (standard clinical green-top tube) and stored on ice. Within 1 hour of collection, the sample was centrifuged (1600g for 10 minutes at room temperature), and the buffy coat cell layer was removed. The cells were stored at -20 °C until analysis. CYP2D6 genotype for the *1 (wild-type) or *4, *6, and *8 (variant) alleles was determined using endonuclease-specific mutation analysis, as described previously (20).
Measurement of Plasma Tamoxifen and Metabolite Concentrations
A 10-mL blood sample was collected in a tube containing sodium heparin (standard clinical green-top tube) and stored on ice. Within 1 hour of collection, the plasma was isolated. Tamoxifen and its metabolite concentrations in plasma were determined by using high-performance liquid chromatography with online photocyclization as previously described by Fried and Wainer (21), with minor modifications (22). In brief, this method allows for the rapid extraction and specific detection of tamoxifen and its metabolites on the basis of a technique originally described by Kikuta and Schmid (23) that used a mobile phase of 65% acetonitrile, 35% potassium phosphate (pH 3.0) and eluted the metabolites on a 4.6 x 250 mm 0.5-µm cyanonitrile column (23). This method has been modified to use a novel column-switching technique (21) that allows for high recovery and precise separation of the drug and metabolites. Consistent separation of tamoxifen, N-desmethyl-tamoxifen, 4-hydroxy-tamoxifen, endoxifen, and N-didesmethyl-tamoxifen was achieved using this method. We found that the limits of quantification were 0.5 ng/mL and 0.25 ng/mL for endoxifen and 4-hydroxy-tamoxifen, respectively. The inter- and intra-day coefficients of variation were less than 10% at the midpoint of the standard curves for each metabolite tested.
Synthesis of Endoxifen
Endoxifen was synthesized in our laboratory as described by Ogawa et al. (24), with the modification that 98% [Z]-4-hydroxy-tamoxifen (Sigma, St. Louis, MO) was demethylated to endoxifen. Briefly, 10 mL of anhydrous dioxane was added to 75 mg (180 µmol) of [Z]-4-hydroxy-tamoxifen in a 75-mL stainless steel sample cylinder, and 50 µL (582 µmol) of vinyl chloroformate was then added dropwise. The cylinder was sealed and heated for 5 hours at 135 °C to 145 °C to form a crude mixture. After cooling, the contents of the cylinder were transferred to a round-bottomed flask and evaporated to dryness. For acid-catalyzed removal of the vinyloxycarbonyl group, 20 mL of a solution containing 5% hydrochloric acid in ethanol was added to the flask, and the solution was allowed to reflux for 30 minutes at 80 °C. The contents of the flask were allowed to cool and then were evaporated to dryness. Silica gel (60200 mesh) column (25 x 160 mm) chromatography of this residue with chloroform-methanol-triethylamine (9: 1 : 0.05 v/v/v) gave 20 mg of product that eluted as a single peak on the chromatographic system described above. Synthesized endoxifen was subsequently stored at -80 °C at a concentration of 1 mM in 100% ethanol. The synthesized endoxifen peak consistently co-eluted with a peak that changed during paroxetine administration using the chromatographic method described here and that described by Fried and Wainer (21).
Determination of Metabolite Anti-Proliferative Activity
MCF7 breast cancer cells were obtained from the Tissue Culture Shared Resource at the Lombardi Cancer Center (Georgetown University, Washington, DC) and were routinely cultured in modified Improved Minimum Essential Medium supplemented with 10% fetal calf serum (Life Sciences, Gaithersburg, MD). Estrogen stimulates the growth of MCF7 cells in vitro. To determine whether tamoxifen and its metabolites could inhibit MCF7 cell growth, and to obtain reproducible data, it was necessary to deplete estrogen from the culture medium to make the cells completely dependent on the exogenous estradiol. When cell monolayers were approximately 70% confluent, the culture medium was replaced with an estrogen-depleted medium consisting of phenol red-free modified IMEM supplemented with 10% charcoal-stripped newborn calf serum (estrogen-free medium). To remove any residual estrogen, the monolayer was washed every hour for 5 hours with phenol red-free IMEM and cultured in fresh estrogen-free medium between washes. After the cells were cultured overnight, they were detached from the culture plate with phenol red-free trypsin and counted. Cells were plated into several 96-well plates at a concentration of 1000 cells per well in a total volume of 100 µL in estrogen-free medium. After allowing the cells to attach (approximately 5 hours), 100 µL of medium containing various concentrations of tamoxifen, endoxifen, or 4-hydroxy-tamoxifen, alone or in combination with estradiol (E2) or the vehicle control (ethanol), was added to each well to yield the appropriate concentrations of the various compounds and a final ethanol concentration of 0.1%. On each plate, four wells were treated with 0.2 nM estradiol and four with the vehicle alone (ethanol) as controls to show the baseline growth of the cells in the presence and absence of estradiol, respectively. Four wells per plate were used for each concentration of tamoxifen, endoxifen, or 4-hydroxy-tamoxifen. Several duplicate plates were prepared and, after the cells had grown for the specified times (4, 7, or 10 days), the media were removed and the cells stained with crystal violet (0.52% crystal violet in 25% methanol). The plates were washed with distilled water to remove excess stain and air dried before the bound stain was solubilized by the addition of 100 µL of 100 mM sodium citrate in 50% ethanol. Staining intensity, which is proportional to cell number, was then determined by measuring absorbance at 550 nm. The data are presented as the mean absorbance at 550 nm of replicate wells for each treatment condition and 95% confidence intervals. The experiment was repeated three times. Data from a representative experiment are shown.
Tamoxifen Metabolism in Human Liver Microsomes
Human liver microsomes were prepared as previously described (2527). In brief, tamoxifen (5 µM) or N-desmethyl-tamoxifen (10 µM) substrates were incubated with or without specific inhibitors of individual cytochrome P450 isoforms. The isoform-specific inhibitors used, working concentrations, and the enzymes they specifically inhibit were sulfaphenazole (20 µM) to inhibit CYP2C9, omeprazole (10 µM) to inhibit CYP2C19, quinidine (1 µM) to inhibit CYP2D6, and ketoconazole (1 µM) and troleandomycin (50 µM) to inhibit CYP3A.
Incubations were carried out in human liver microsomes (0.5 mg/mL of protein) in the presence of a reduced nicotinamide adenine dinucleotide phosphate (NADPH)-generating system for 60 minutes at 37 °C, and the rates of formation of N-desmethyl-tamoxifen from tamoxifen and endoxifen from N-desmethyl-tamoxifen were monitored. The reactions were carried out under conditions and concentrations documented to allow the inhibitors to be isoform-specific. Rates of metabolite formation from the test conditions were compared with rates of metabolite formation from control conditions, in which the inhibitors were replaced with appropriate concentrations of ethanol, methanol, or dimethyl sulfoxide as vehicle. Each inhibitor was tested in three different preparations of human liver microsomes (HL2, HK23, and HG23), with the exception of omeprazole, which was tested in only two (HL2 and HK23). The rates of N-desmethyl-tamoxifen and endoxifen formation during incubation with the inhibitors are presented as percent control activity without the inhibitor (mean with 95% confidence intervals; n = 4 or 6 duplicate measurements).
Statistical Analysis
The differences between the plasma concentrations of tamoxifen and its metabolites at baseline and after 4 weeks of tamoxifen and paroxetine were compared using a two-way paired t test. A P value of .05 was considered to be statistically significant. Differences in metabolite concentrations that resulted from in vitro incubations with cytochrome P450 isoform-specific inhibitors were also tested using a two-way paired t test. In a retrospective power analysis using the coefficient of variance of the plasma concentration of endoxifen at baseline and an alpha of .05, we had 80% power to detect a 56% change in endoxifen plasma concentration using a two-tailed t test (Microsoft Excel data analysis toolpack; Microsft, Redmond, WA).
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RESULTS |
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DISCUSSION |
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We have shown in vitro that the primary route of metabolism to endoxifen is via CYP2D6 from N-desmethyl-tamoxifen. The metabolic route from tamoxifen to endoxifen and 4-hydroxy-tamoxifen suggested by our data is illustrated in Fig. 5. The in vitro data suggesting involvement of CYP2D6 in tamoxifen metabolism to endoxifen were confirmed by the clinical data. We demonstrated that paroxetine coadministration was associated with decreased plasma concentrations of endoxifen in women who carry the wild-type CYP2D6 allele and that the concentration of endoxifen during chronic tamoxifen treatment was lower in women who carry a variant CYP2D6 allele than in those who carry the homozygous wild-type genotype. Although women taking paroxetine had a statistically significantly reduced concentration of endoxifen, concentrations of tamoxifen, 4-hydroxy-tamoxifen, and N-desmethyl-tamoxifen did not change.
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Our data indicate that the plasma concentrations of tamoxifen and N-desmethyl-tamoxifen are higher than those of 4-hydroxy-tamoxifen and endoxifen, and that, in women with wild-type CYP2D6, endoxifen concentrations are approximately 14-fold higher than those of 4-hydroxy-tamoxifen. Thus, endoxifen is likely to be at least as important as 4-hydroxy-tamoxifen in mediating tamoxifen activity in women with wild-type CYP2D6. Consequently, these preliminary findings may have clinical implications because endoxifen is as potent as 4-hydroxy-tamoxifen in suppressing growth of estrogen-dependent cultured human breast cancer cells. Further studies are ongoing to carefully characterize the activity and potency of endoxifen in breast cancer cell lines and in vivo tumor models. The relative ratio of endoxifen to other tamoxifen metabolites may also be important to the overall effect of tamoxifen on other parts of the body, such as the central nervous system, the cardiovascular system, the liver, and bone, although our study did not specifically address these tissue-specific effects.
We conclude that tamoxifen metabolism is vulnerable to drug interactions with SSRIs. The women in our clinical trial received paroxetine for tamoxifen-associated hot flashes. Although other medications are available for the treatment of hot flashes, SSRIs are among the most promising nonhormonal pharmacologic interventions (29). SSRIs also improve sleep, libido, and overall quality of life in women with hot flashes (7). More important, paroxetine and other SSRIs are often prescribed for other reasons, such as depression, anxiety, or social phobias, to patients who may be on tamoxifen. If endoxifen is an active metabolite of tamoxifen in vivo, then our study raises the possibility that administration of paroxetine and other SSRIs that interact with CYP2D6 may decrease the antiestrogenic activity of tamoxifen. However, given the increasingly important role of SSRI treatment of hot flashes and depression in breast cancer survivors, this hypothesis requires further clinical testing before definitive recommendations for or against concomitant tamoxifen and SSRI use should be made.
Our results do emphasize the potential importance of pharmacogenetic considerations in the assessment of the efficacy of tamoxifen. Further studies of the activity of endoxifen and larger prospective clinical trials that examine the associations of CYP2D6 genotype and other pharmacogenetic factors with validated clinical outcomes will be required to test the hypothesis that pharmacogenetic testing may be useful before tamoxifen treatment to determine who is best suited for tamoxifen treatment. Similarly, it is not yet clear that patients with low CYP2D6 activity and low endoxifen concentrations will experience less clinical benefit from tamoxifen; further research in this area is now merited. Because there are, as yet, few validated surrogates of clinical outcome in breast cancer, studies that examine the effects of endoxifen concentrations and germline pharmacogenetic genotype on clinical outcome in relatively short-term trials, such as those in the neoadjuvant and metastatic settings, will be important. In addition, the results of this study emphasize that prospective collection of DNA in future trials that use tamoxifen will be critical to any demonstration that a pharmacogenetic test can improve our ability to determine which patients may be vulnerable to harm and which patients may most benefit from tamoxifen treatment.
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NOTES |
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Present address: Vered Stearns, MD, Sidney Kimmel Comprehensive Cancer Center at Johns Hopkins, Baltimore, MD.
Present address: James M. Rae, PhD, University of Michigan Comprehensive Cancer Center, Ann Arbor, MI.
Present address: Pankaj Bhargava, MD, University of Massachusetts Medical Center, Worcester, MA.
Present address: Daniel F. Hayes, MD, University of Michigan Comprehensive Cancer Center, Ann Arbor, MI.
Present address: Zeruesenay Desta, PhD, Division of Clinical Pharmacology, Indiana University School of Medicine, Indianapolis, IN.
Present address: David A. Flockhart, MD, PhD, Division of Clinical Pharmacology, Indiana University School of Medicine, Indianapolis, IN.
Supported in part by Pharmacogenetics Research Network grants U-01 GM61373 and R-01 GM56898 (to D. A. Flockhart), and clinical pharmacology training grant 5T32-GM-08425 (to D. A. Flockhart) from the National Institute of General Medical Sciences, National Institutes of Health, Department of Health and Human Services; by Damon Runyon-Lilly Clinical Investigator Award CI-3 (to V. Stearns) from the Damon Runyon Cancer Research Foundation; and by Fashion Footwear Association of New York/QVC Presents "FFANY Shoes on Sale" (to D. F. Hayes). Drs. Stearns and Hayes have received an investigator-initiated clinical grant for prospective clinical trials of paroxetine from GlaxoSmithKline Pharmaceuticals.
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Manuscript received May 23, 2003; revised September 24, 2003; accepted September 29, 2003.
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