ENANTIOSELECTIVE METABOLISM AND CYTOTOXICITY OF R-IFOSFAMIDE AND S-IFOSFAMIDE BY TUMOR CELL-EXPRESSED CYTOCHROMES P450

Chong-Sheng Chen, Youssef Jounaidi, and David J. Waxman

Division of Cell and Molecular Biology, Department of Biology, Boston University, Boston, Massachusetts

(Received March 22, 2005; accepted May 20, 2005)

Abstract

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The anticancer prodrug ifosfamide (IFA) contains a chiral phosphorousatom and is administered in the clinic as a racemic mixtureof R-IFA and S-IFA. Hepatic cytochrome P450 (P450) enzymes exhibitenantioselective preferences in the metabolism of R-IFA andS-IFA; however, the impact of this selectivity on P450-dependentanticancer activity is not known. Presently, the metabolismand cytotoxicity of R-IFA and S-IFA were determined in 9L gliosarcomaand Chinese hamster ovary tumor cells expressing an IFA-activatingP450 enzyme and by in vitro steady-state kinetic analysis usingcDNA-expressed P450 enzymes. Tumor cells expressing P450 enzymeCYP3A4 were the most sensitive to R-IFA cytotoxicity, whereastumor cells expressing CYP2B1 or CYP2B6 were most sensitiveto cyclophosphamide (CPA), an isomer of IFA. Correspondingly,CYP3A4-expressing cells and cDNA-expressed CYP3A4 metabolizedR-IFA to yield the active, 4-hydroxylated metabolite at a 2-to 3-fold higher rate than they metabolized S-IFA or CPA. CYP2Bcells and cDNA-expressed CYP2B enzymes metabolized CPA almostexclusively by 4-hydroxylation, whereas R-IFA and S-IFA weresubstantially converted to inactive, N-dechloroethylated metabolites.Further investigation revealed that CYP3A1, a rat enzyme, exhibitedsuperior kinetic properties compared with the human enzyme CYP3A4,with R-IFA and S-IFA both metabolized with high catalytic efficiencyby 4-hydroxylation and with a K_m value of 200 µM, $~$ 5-foldlower than CYP3A4. Based on these kinetic parameters and metabolicprofiles, R-IFA is expected to exert greater anticancer activitythan S-IFA or CPA against tumors that express CYP3A enzymes,whereas tumors expressing CYP2B enzymes may be more sensitiveto CPA treatment.

Ifosfamide (IFA) and its structural isomer cyclophosphamide(CPA) are clinically effective anticancer alkylating agent prodrugsused to treat a broad range of neoplasms. Both prodrugs areactivated in the liver by a cytochrome P450-catalyzed 4-hydroxylationreaction. The primary 4-hydroxy metabolite exists in equilibriumwith the ring-opened aldo(iso)phosphamide, which undergoes ß-eliminationto yield the therapeutically active, DNA cross-linking metabolite(iso)phosphoramide mustard and acrolein, a reactive aldehyde(Sladek, 1988

; Zalupski and Baker, 1988

). An alternative, P450-catalyzedN-dechloroethylation reaction inactivates the parent drug andgenerates the neurotoxic and nephrotoxic byproduct chloroacetaldehyde(CAA). Although CPA and IFA are very similar in chemical structureand mechanism of action, they differ strikingly with respectto their pharmacokinetic and pharmacodynamic properties. CPAis metabolized predominantly by 4-hydroxylation, catalyzed byCYP2B and CYP2C enzymes, whereas IFA undergoes extensive N-dechloroethylation,catalyzed by CYP2B and CYP3A enzymes (Huang and Waxman, 1999

;Roy et al., 1999b

; Chen et al., 2004

). The formation of CAAas a major byproduct of IFA N-dechloroethylation is associatedwith the neurotoxicity and urotoxicity seen in patients treatedwith IFA but not in the case of CPA. These side effects canbe controlled by administration of protective agents such assodium 2-mercaptoethanesulfonate (Woodland et al., 2000

IFA is a chiral molecule that contains an asymmetric phosphorusatom and exists in two enantiomeric forms, R-IFA and S-IFA.Studies in experimental animal models and human clinical trialsindicate that the racemic IFA used in the clinic is subjectto enantioselective metabolism, which may lead to distinct efficaciesand toxicity profiles for each enantiomer (Boos et al., 1991;Williams and Wainer, 1999). In clinical studies, S-IFA was foundto be metabolized more rapidly than R-IFA, resulting in a shorterhalf-life, a higher clearance, and a markedly lower recoveryin urine compared with R-IFA (Corlett et al., 1995; Wainer etal., 1996).

IFA N-dechloroethylation is primarily catalyzed by two majorhuman liver P450 enzymes. CYP2B6 metabolizes R-IFA and S-IFAto produce S-N3-deCl-IFA and S-N2-deCl-IFA, respectively, whereasCYP3A4 metabolizes R-IFA to produce R-N2-deCl-IFA and S-IFAto yield R-N3-deCl-IFA (Granvil et al., 1999; Roy et al., 1999a).CYP3A4-dependent R-IFA 4-hydroxylation is typically more rapidthan S-IFA 4-hydroxylation in human liver microsomes, consistentwith the high level of CYP3A4 in human liver (Roy et al., 1999b)and in agreement with pharmacokinetic studies in patients (Williamsand Wainer, 1999). R-IFA and S-IFA can be purified using enantioselectivechromatography, and their application to clinical chemotherapyhas been studied (Wainer, 1993; Wainer and Granvil, 1993). However,characterization of R-IFA and S-IFA metabolism as it impactsthe antitumor activity of each enantiomer at the cellular levelhas not been investigated.

Presently, we investigate the metabolism and cytotoxicity ofR-IFA and S-IFA using tumor cells engineered to express individualCYP2B and CYP3A enzymes in combination with the flavoenzymeP450 reductase (P450R). Our findings reveal that R-IFA displaysgreater cytotoxicity than either S-IFA or CPA toward CYP3A4-expressingtumor cells, whereas S-IFA displays greater activity againstCYP2B-expressing tumor cells. Moreover, in vitro studies usingcDNA-expressed P450s identify the rat enzyme CYP3A1 as a superiorcatalyst of prodrug activation with both R-IFA and S-IFA assubstrates, suggesting the utility of this P450 enzyme for gene-directedenzyme prodrug therapy involving IFA (Chen and Waxman, 2002).These findings are discussed with respect to the impact of tumorcell P450 expression on antitumor activity.

Materials and Methods

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Materials. CPA was purchased from Sigma-Aldrich (St. Louis,MO). CAA in the form of a 50% (w/v) solution in water, 3-aminophenol,semicarbazide, and fetal bovine serum (FBS) were purchased fromAldrich Chemical Co. (Milwaukee, WI). IFA was obtained fromthe Drug Synthesis and Chemistry Branch, National Cancer Institute(Bethesda, MD). Purified R-IFA and S-IFA were provided by Dr.Ben Skead of Cell Tech, Ltd. (Cambridge, UK). 4-OOH-CPA and4-OOH-IFA were provided by Dr. Ulf Niemeyer (Baxter OncologyGmbH, Frankfurt, Germany). Dulbecco's modified Eagle's medium(DMEM) was purchased from Invitrogen (Carlsbad, CA). Supersomescontaining expressed CYP2B and CYP3A enzymes, with coexpressionof P450R and cytochrome b₅, were purchased from BD Gentest Corp.(Woburn, MA). Data were obtained using the following lot numbersfor each Supersome P450 preparation: 2B1, lot 5 and lot 7; 2B6,lot 8; 3A1, lot 6; 3A2, lot 6; 3A4, lot 50; 3A7, lot 1; and3A12, lot 2.

9L Cell Lines Coexpressing P450 and P450R cDNAs. The retroviralplasmid pBabe-puro, which encodes a puromycin resistance gene,was used to clone CYP2B1 and CYP2B6 cDNAs, linked via an IRESsequence to human P450R cDNA, to give a bicistronic CYP2B-IRES-P450Rexpression cassette as described (Jounaidi and Waxman, 2004).The CYP2B6 cDNA used in these studies (GenBank accession no.M29874 [GenBank] ) corresponds to the wild-type (CYP2B6*1) allele, i.e.,Arg22/Lys139/Gln172/Ser259/Lys262/Arg487 (Lang et al., 2001).Transfection of the ecotropic packaging cell line Bosc 23 withthe retroviral plasmids pBabe-CYP2B1-IRES-P450R-puro and pBabe-CYP2B6-IRES-P450R-puro,harvesting of retroviral supernatants, and infection of rat9L gliosarcoma cells were carried out as described (Jounaidiet al., 1998), with the following modifications. Bosc 23 cellswere plated at 2.5 x 10⁶ cells in a 60-mm dish. Fresh culturemedium (4 ml) containing chloroquine (25 µM) was addedto the cells 16 h later. The cells were cotransfected 1 h laterwith 5 µg of retroviral plasmid DNA and 2.5 µg ofthe helper plasmid pKat (Finer et al., 1994) using 9 µlof the cationic liposome Fugene 6 (Roche Diagnostics, Indianapolis,IN) in a total volume of 40 µl of DMEM without FBS. Poolsof 9L cells resistant to 2.5 µg/ml puromycin and expressingP450R in combination with CYP2B1 (9L/2B1-P450R cells) or CYP2B6(9L/2B6-P450R cells) were selected beginning 48 h later overa 2- to 3-day period (Jounaidi and Waxman, 2004). 9L cells infectedwith pBabe-pyro retrovirus, without a P450-IRES-P450R insert,are termed 9L/pBABE cells and were used as a control. The tumorcell line CHO, engineered to express human P450R alone (CHO/P450Rcells) or P450R together with CYP3A4 (CHO/3A4-P450R cells),was that used previously (Lu and Waxman, 2005) and was kindlyprovided by Dr. Thomas H. Friedberg, Biomedical Research Centre,University of Dundee, Dundee, UK (clonal cell line DHR/3A4)(Ding et al., 1997). The 9L and CHO tumor cells used in thisstudy exhibit similar intrinsic sensitivities to activated CPAand IFA (see Table 1). Moreover, similar levels of P450 areexpressed in the 9L/2B-P450R cells (Jounaidi et al., 1998) andin the CHO/3A4-P450R cells (Ding et al., 1997).

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TABLE 1 Cytotoxicity of anticancer prodrugs and their metabolites toward P450-expressing 9L and CHO cells

Data are mean values based on two independent sets of 4-day cytotoxicity assays for each cell line. EC₅₀ values were calculated using the sigmoidal dose-response (variable slope) method of GraphPad Prism software.

Cytotoxicity Assays. The chemosensitivity of P450-expressing9L and CHO cells was determined using a 4-day growth inhibitionassay. Cells were plated in triplicate at 4000 cells per wellof a 48-well plate. After 18 to 24 h of growth, cells were treatedfor 4 days with R-IFA, S-IFA, or CPA at concentrations indicatedin each experiment. The same 4-day growth inhibition assay wasused to evaluate the intrinsic sensitivity of the cells to CAA,a byproduct of IFA and CPA N-dechloroethylation, and to the4-OOH derivatives of IFA and CPA, which decompose in aqueousmedium to yield 4-OH-IFA and 4-OH-CPA, respectively. Cells werestained using a crystal violet/alcohol extraction assay andquantified. Briefly, culture dishes were washed once with phosphate-bufferedsaline, stained with 1.25 g of crystal violet in 500 ml containing50 ml of 37% formaldehyde and 450 ml of methanol, and then washedwith tap water. A₅₉₅ values were determined using a microtiterplate reader. Background absorbance measured for wells containingculture medium alone was subtracted from each value. Data arepresented as mean cell number relative to drug-free controls,with 100% growth inhibition corresponding to 0 net A₅₉₅ and0% growth inhibition corresponding to the A₅₉₅ of the drug-freecontrol cells.

Assay for 4-OH-CPA, 4-OH-IFA, and CAA Released into CultureMedium. 9L and CHO cell lines were seeded in 12-well platesin duplicate at 1 x 10⁵ cells/well in 2 ml of DMEM containing10% FBS (9L cells) or in 2 ml of MEM containing 10% dialyzedFBS (CHO cells). Drugs were added to the cells in 2 ml of DMEM(9L cells) or MEM (CHO cells) without FBS about 20 h later.Cells were cultured for an additional 4 h, at which time duplicatealiquots (200 µl) of culture medium were removed. Onealiquot was immediately derivatized to 1-N⁶-ethenoadenosineby treatment with 20 µl of 250 mM adenosine and 30 µlof 2 M sodium acetate solution (pH 4), and then heated at 80°Cfor 2.5 h (CAA determination) (Huang and Waxman, 1999). Theother aliquot was immediately derivatized to 7-hydroxyquinolineby treatment for 25 min with 100 µl of freshly preparedfluorescent reagent (60 mg of 3-aminophenol and 60 mg of hydroxylamine-HClin 10 ml of 1 N HCl) at 90°C (Bohnenstengel et al., 1997).In some cases, the derivatized samples were stored at –20°Cin the dark prior to HPLC analysis.

Standard curves were generated using CAA (0–5 µM)and 4-OOH-CPA (0–50 µM). Standards were incubatedfor 2 h with 1 x 10⁵ P450-deficient 9L or CHO cells in 2 mlof DMEM (pH 7.2)/well of a 12-well plate to correct for time-and cell-dependent degradation of the metabolites. The 2-h timepoint corresponds to the midpoint of the standard cell culturemetabolite formation assay (4 h; see below) and serves as anestimate of the average time during which metabolites formedover the course of the 4-h incubation period are subject totime-dependent and/or cell-dependent degradation in culturemedium. The recovery of acrolein following a 2-h incubationof 4-OOH-CPA in culture medium was 76 ± 6% (n = 2) (incubationwith 9L/pBabe cells) and 89 ± 10% (n = 4) (incubationwithout cells). The recovery of CAA following a 2-h incubationwith and without 9L/pBabe cells was 63 ± 15% (n = 3)and 95 ± 8% (n = 3), respectively, indicating cell-dependentdegradation of CAA. The accumulation of 4-OH-IFA in culturemedium of 9L/2B1-P450R cells was linear with incubation timesup to 8 h, with a slope of 0.151 nmol/ml/h per 1 x 10⁵ cellsseeded/well. CAA accumulation in the culture medium was linearfor $~$ 2 h (0.164 nmol/ml/h per 1 x 10⁵ cells seeded/well), afterwhich the rate of accumulation slowed down, consistent withthe 9L cell-dependent metabolism of CAA noted above. The yieldsof 4-OH-IFA and CAA increased linearly with 9L/2B1-P450R cellnumber, with slopes of 1.37 ± 0.03 (4-OH-IFA) and 0.97± 0.03 (CAA) nmol of metabolite/ml of medium/1 x 10⁵cells seeded/well. Crystal violet absorbance values (A₅₉₅) werelinearly correlated with cell number from 0.5 x 10⁵ to 6 x 10⁵9L cells/2 ml of culture medium per well of a 12-well plate.The limit of detection in culture medium (twice the backgroundvalue) was 0.15 µM for CAA and 0.5 µM for acrolein.

Metabolism by cDNA-Expressed P450s. Supersomes containing baculovirus-expressedP450s (4 pmol of P450) were added to 75 µl of 100 mM KPibuffer pH 7.4 containing various concentrations of R-IFA, S-IFA,or CPA (50 µM to 10 mM, final substrate concentration).Assay mixtures minus NADPH were preincubated for 4 min at 37°C.Each reaction was initiated by addition of NADPH to 1 mM (finalvolume of 100 µl, containing 75 mM KPi buffer, pH 7.34,0.75 mM EDTA, and 1 mM NADPH). Reactions were incubated for15 min at 37°C and then processed and derivatized for HPLCanalysis (conversion of CAA to 1-N⁶-ethenoadenosine and conversionof acrolein to 7-hydroxyquinoline) (Chen et al., 2004).

HPLC. Analysis of CPA and IFA metabolites was carried out usinga Luna 5-µ C18 (2) HPLC column, 150 x 4.6 mm (Phenomenex,Torrance, CA) (Chen et al., 2004). 7-Hydroxyquinoline was elutedwith 17% methanol in 0.33% phosphoric acid at a flow rate of1 ml/min (t_elution = 3.2 min) and was detected by fluorescenceexcitation at 350 nm and emission at 515 nm. 1-N⁶-Ethenoadenosinewas eluted with 17% methanol in water (t_elution = 7–8min for samples incubated with cells) or 13% methanol in water(t_elution = 8.7–10 min for Supersomes incubations) ata flow rate of 1 ml/min and was detected by fluorescence excitationat 270 nm and emission at 411 nm. Quantification was based onintegrated peak areas calculated using Millennium³² software(Waters, Inc., Milford, MA).

Data Analysis. Data were managed using Microsoft Excel. Databased on metabolism in cell culture were corrected by subtractionof the higher of two measured background activities (culturemedium from cells incubated without drugs, or from drugs incubatedin medium without cells) and then converted to units of metaboliteproduced (nanomoles of 7-hydroxyquinoline or nanomoles of 1-N⁶-ethenoadenosine)per A₅₉₅ (crystal violet staining). Data obtained from in vitrometabolism assays using Supersomes were corrected by subtractingthe highest of three independent background activity values:incubation without NADPH, incubation without drug, and incubationwithout Supersomes. Data were converted to units of nanomolesof metabolite produced per minute per nanomole of P450. Enzymekinetic data were analyzed using Enzyme Kinetics v 0.44 software(Trinity Software, Inc., Boone, NC). Kinetic parameters (K_mand V_max) for each individual experiment, typically based onn = 7 substrate concentrations, were determined by the Eadie-Hofsteemethod. Mean values ± S.D. (n = 3) or mean values ±half the range (n = 2) were determined based on the indicatednumber of independent sets of assays. EC₅₀ values, based onsigmoidal dose-response analysis using a variable slope, weredetermined using GraphPad Prism software (GraphPad Software,San Diego, CA).

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Metabolism of R-IFA, S-IFA, and CPA by P450-Expressing CellLines. The metabolism of R-IFA, S-IFA, and CPA was assayed infive cell lines: 9L gliosarcoma cells expressing either ratCYP2B1 (9L/2B1-P450R cells) or human CYP2B6 (9L/2B6-P450R cells)in combination with P450R, the P450-deficient control cell line9L/pBabe, CHO cells expressing human CYP3A4 with P450R (CHO/3A4-P450Rcells), and a control cell line expressing P450R reductase alone(CHO/P450R cells). Cells were incubated with each prodrug substrateat two concentrations (200 µM and 2 mM), and metabolitesreleased into the culture medium were analyzed and quantifiedby HPLC. All three prodrugs were metabolized by the P450-expressingcell lines but not by the P450-deficient control cells (Fig. 1).CPA was primarily converted to the active, 4-OH metaboliteby both CYP2B-expressing cell lines ( $≥$ 98% of total metabolism)(Fig. 1A). However, this pathway corresponded to only 24 to44% of CPA metabolism in the case of CYP3A4 cells, where N-dechloroethylation(drug inactivation) to yield CAA was the major metabolic reaction(56–76% of total metabolism) (Fig. 1B). With R-IFA andS-IFA as substrates, N-dechloroethylation was the major metabolicpathway for both CYP2B cell lines (up to 74% of total metabolismby 9L/2B1-P450R cells and up to 94% of total metabolism by 9L/2B6-P450Rcells). The CYP3A4 cell line showed clear enantiomeric selectivity,with up to 74% of R-IFA metabolism proceeding via 4-hydroxylation,as compared with 27% in the case of S-IFA. Moreover, the rateof R-IFA 4-hydroxylation by CHO/3A4-P450R cells was 1.5-foldhigher than S-IFA 4-hydroxylation at 2 mM substrate (Fig. 1A),whereas the rate of N-dechloroethylation was 80% lower for R-IFAthan for S-IFA (Fig. 1B). Overall, the rates of IFA 4-hydroxylationwere much higher in the CYP3A4 cells than in either CYP2B cellline.

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FIG. 1. Metabolism of CPA, R-IFA, and S-IFA by 9L/2B1-P450R, 9L/2B6-P450R, and CHO/3A4-P450R cells by 4-hydroxylation (A) and by N-dechloroethylation (B). Cell lines expressing the indicated P450s in combination with P450R were cultured in 12-well plates and incubated for 4 h with each prodrug substrate at 0.2 or 2.0 mM, followed by metabolite derivatization and HPLC analysis. Data were quantified by comparison to standard curves prepared using metabolite standards (4-OOH-CPA or CAA) incubated with P450-deficient cells, as described under Materials and Methods. Data shown are rates of metabolite production over a 4-h period, expressed as nanomoles of metabolite per well, normalized for the cell density of each culture well (A₅₉₅; crystal violet staining intensity) (mean values ± half the range for duplicate determinations). 9L, 9L/pBabe cells; CHO, CHO/P450R cells; *, metabolite is below limit of detection.

Cytotoxicity of R-IFA,S-IFA, and CPA. The cytotoxicity of eachprodrug was evaluated in each of the P450-expressing cell linesusing a 4-day growth inhibition assay (Fig. 2). None of theprodrugs exerted significant cytotoxicity toward the controlcell lines 9L/pBabe and CHO/P450R ("control" curves; Fig. 2),consistent with the inactivity of the parent prodrugs and theabsence of oxazaphosphorine 4-hydroxylase activity in the P450-deficientcells. By contrast, all three prodrugs induced dose-dependentkilling of the three P450-expressing cell lines. The rank orderof cytotoxicity based on EC₅₀ values (Table 1) was CPA >S-IFA > R-IFA for the CYP2B1 and CYP2B6 cells (Fig. 2, A and B),and R-IFA > CPA > S-IFA for the CYP3A4 cells (Fig. 2C).Comparison of the activity profiles of each prodrug revealedthat CPA was most cytotoxic (lowest EC₅₀ value) when activatedby CYP2B1 cells, whereas R-IFA was most active toward CYP3A4cells. These findings are consistent with the high CPA 4-hydroxylaseactivity of the CYP2B1 and CYP2B6 cells and by the high R-IFA4-hydroxylase activity of the CYP3A4 cells (Fig. 1). By contrast,the CYP3A4 cells primarily metabolized S-IFA and CPA by N-dechloroethylation(Fig. 1). Together, these findings indicate that R-IFA is likelyto have a better activity profile than S-IFA or CPA when usedto treat tumors that express CYP3A4, whereas S-IFA is likelyto be more active than R-IFA against tumors that express CYP2B6.

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FIG. 2. Growth inhibitory effects of CPA, R-IFA, and S-IFA toward P450-expressing cell lines. The cytotoxicity of each prodrug was assayed in a 4-day growth inhibition assay carried out using 9L/2B1-P450R cells (A), 9L/2B6-P450R cells (B), and CHO/3A4-P450R cells (C) in comparison to a P450-deficient control cell line (control, 9L/pBabe for panels A and B and CHO/P450R for panel C; control data presented are mean ± S.D. values for n = 3 separate incubations carried out with each prodrug). Cells were seeded in 48-well plates at 4000 cells/well and treated with increasing concentrations of each prodrug (0 to 1 mM, n = 8 concentrations, each done in triplicate) for 4 days as described under Materials and Methods. Data presented are mean ± half-the-range values, with the growth inhibition of the drug-free controls set to 0 (duplicate experiments with n = 3 replicates each).

We next examined the intrinsic sensitivity of 9L cells and CHOcells to the reactive metabolites CAA, 4-OH-CPA, and 4-OH-IFA,with the latter two compounds delivered to the cells as their4-OOH derivatives (Table 1). 9L/pBabe and CHO/P450R cells bothdisplayed high intrinsic sensitivity to 4-OH-CPA (EC₅₀ $~$ 3 µM)and 4-OH-IFA (EC₅₀ $~$ 5 µM). Moreover, CAA was at least ascytotoxic as 4-OH-IFA (EC₅₀ $~$ 2.5–3.2 µM), suggestingthat this reactive aldehyde may contribute to the cytotoxicityof IFA seen in P450 2B6 cells (Fig. 2B), which have very lowIFA 4-hydroxylase activity (Fig. 1A).

Kinetic Analysis of CPA and IFA Metabolism by cDNA-ExpressedP450 Enzymes. Next, we characterized the metabolic profile ofthe three oxazaphosphorine prodrugs using individual P450 enzymesexpressed in a Baculovirus expression system ("Supersomes").Steady-state kinetic analysis (Table 2; Fig. 3) confirmed that4-hydroxylation was the predominant pathway of CPA metabolismcatalyzed by both CYP2B enzymes. The alternative N-dechloroethylationpathway represented only $~$ 4% of CPA metabolism in the case ofCYP2B1 and was undetectable with CYP2B6 (Fig. 3, B and C). Incontrast, R-IFA and S-IFA were metabolized by CYP2B1 by bothpathways, with 4-hydroxylation to N-dechloroethylation productratios of $~$ 1:2.2 for R-IFA and 1:0.8 for S-IFA at V_max. In thecase of CYP2B6, however, IFA 4-hydroxylation was substantiallyreduced, in particular, in the case of the R-enantiomer ( $~$ 3%of total metabolism). Overall, CYP2B1 metabolized all threeprodrugs with an apparent K_m value that was 2- to 4-fold lowerthan that of CYP2B6 for both metabolic pathways (Table 2). CYP2B1and CYP2B6 were both substantially more active catalysts ofCPA 4-hydroxylation than CYP3A4 (Fig. 3A and Table 2).

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TABLE 2 Steady-state kinetic analysis: CPA, R-IFA, and S-IFA metabolism by cDNA-expressed P450s 2B1, 2B6, and 3A4

Data shown are mean ± S.D. values based on n = 3 independent determinations.

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FIG. 3. Catalytic efficiencies for metabolism of CPA, R-IFA, and S-IFA by CYP2B and CYP3A enzymes and percent metabolism via N-dechloroethylation. Data shown are based on the steady-state kinetic analyses determined for the indicated seven cDNA-expressed P450 enzymes and summarized in Tables 2 and 3. Data shown are V_max/K_m values determined by Eadie-Hofstee analysis (mean ± half-the-range for n = 2–3 independent sets of determinations) for 4-hydroxylation (A) and N-dechloroethylation (B) of each prodrug substrate. V_max/K_m values are in units of mol of product/min/mol of P450/mM. C, percentage of total metabolism proceeding via N-dechloroethylation pathway, calculated based on the V_max values for each enzyme, and the metabolic profiles shown in Tables 2 and 3. *, metabolite is below the limit of detection.

With CPA as substrate, CYP3A4 displayed the highest V_max valuefor N-dechloroethylation, $~$ 30-fold greater than that of P4502B1 (Table 2). By contrast, CYP3A4 metabolized R-IFA primarilyby 4-hydroxylation, with R-IFA N-dechloroethylation correspondingto only 29% of total metabolism at V_max. Moreover, the V_maxand catalytic efficiency (V_max/K_m) of R-IFA 4-hydroxylationcatalyzed by CYP3A4 were 2- to 2.5-fold higher than that ofCPA and S-IFA (Table 2 and Fig. 3A). Thus, with R-IFA as substrate,CYP3A4 exhibited the best kinetic profile of all three P450enzymes, namely, high R-IFA 4-hydroxylase activity coupled withrelatively low N-dechloroethylation activity, in agreement withthe cell culture data presented above.

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TABLE 3 Steady-state kinetics analysis: CPA, R-IFA, and S-IFA metabolism by cDNA-expressed P450s 3A1, 3A2, 3A7, and 3A12

Data based on two independent determinations (mean values ± half-the-range).

CYP3A1 Is a High-Efficiency, Low K_m Catalyst of R-IFA and S-IFA4-Hydroxylation. Tumor cells may be sensitized to anticancerprodrugs, such as IFA, by introducing a prodrug-activating P450gene into the tumor, which thereby acquires the capacity forlocalized prodrug activation (Chen and Waxman, 2002

). Thus,CYP3A4 can be used to sensitize P450-deficient tumor cells tothe cytotoxic activity of IFA (Jounaidi et al., 1998

). Presently,we considered the possibility that other CYP3A enzymes mightmetabolize one of the enantiomers of IFA with improved activityor catalytic specificity compared with CYP3A4. Table 3 and Fig. 3present the steady-state kinetic parameters determined formetabolism of CPA, R-IFA, and S-IFA by four other cDNA-expressedCYP3A enzymes: rat CYP3A1, rat CYP3A2, human CYP3A7, and dogCYP3A12. All four CYP3A enzymes preferentially metabolized R-IFAby the 4-hydroxylation pathway to an even greater extent thanseen with CYP3A4 (up to 90% of total metabolism; Fig. 3C). CPAwas preferentially metabolized by N-dechloroethylation by allof the CYP3A enzymes except CYP3A7, which was primarily a 4-hydroxylasewith CPA and with both enantiomers of IFA. However, the overallcatalytic efficiency of CYP3A7 for oxazaphosphorine activationwas greatly reduced by this enzyme's low intrinsic catalyticactivity (V_max $~$ 10–28% that of CYP3A4; Table 3 versusTable 2). CYP3A12 preferentially metabolized S-IFA via N-dechloroethylation,as seen with CYP3A4, whereas CYP3A1, CYP3A2, and CYP3A7 metabolizedS-IFA preferentially by 4-hydroxylation (Fig. 3C). Finally,CYP3A1 displayed K_m values for R- and S-IFA 4-hydroxylationof $~$ 200 µM (Table 3), $~$ 4- to 5-fold lower than the correspondingK_m values of CYP3A4 (Table 2). The high catalytic efficiencyof CYP3A1 for R-IFA and S-IFA 4-hydroxylation (V_max/K_m = 88–135mol/min/mol of P450/µM) compared with six other P450 enzymes(Fig. 3A), coupled with CYP3A1's low K_m value and its low relativerate of N-dechloroethylation (Fig. 3C), evidence the superiorcatalytic properties of this enzyme for IFA activation.

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Discussion
References

The anticancer prodrugs CPA and IFA are actively metabolizedin the liver, which is a major determinant of the pharmacokineticsof prodrug activation and the rate of drug inactivation andelimination from the body. More recent studies have shown thattumor cells also express drug-metabolizing P450 enzymes, includingCYP2B6 (Nakajima et al., 1996; Standop et al., 2003) and CYP3A4(Huang et al., 1996; Murray et al., 1999; Schmidt et al., 2004).The levels of tumor cell P450 are low but may nevertheless bean important factor in the metabolism and activity of theseanticancer agents. Tumor cell-expressed P450 enzymes may potentiallycontribute to drug inactivation leading to drug resistance,in the case of anticancer drugs than are inactivated by P450metabolism and, conversely, may enhance antitumor activity inthe case of P450 prodrugs, as demonstrated for CPA and IFA incultured tumor cells and in tumor xenograft models in vivo (Chenand Waxman, 1995). The studies presented here investigate themetabolism and cytotoxicity of R-IFA, S-IFA, and CPA in tumorcells engineered to express individual CYP2B and CYP3A enzymeswith the goal of identifying P450 prodrug–P450 enzymecombinations that are associated with strong cytotoxic responses.Our findings reveal that tumor cells that express CYP3A4 aremost sensitive to the cytotoxicity of R-IFA, whereas tumor cellsthat express CYP2B enzymes (rat CYP2B1 or human CYP2B6) aremost sensitive to CPA. Moreover, the combination of R-IFA treatmentwith CYP3A4 expression was associated with favorable partitioningof IFA metabolism along the therapeutically important 4-hydroxylation(prodrug activation) pathway at the expense of the alternative,N-dechloroethylation pathway, which inactivates the prodrugand yields the by-product CAA, which has been linked to undesirablehost toxicities, notably neurotoxicity and urotoxicity. Together,these findings suggest that improvement in the effectivenessof oxazaphosphorine therapy may be achieved by individualizingdrug treatment based on the P450 expression profile of eachpatient's tumor, e.g., as assessed by needle biopsy.

Studies using cDNA-expressed enzymes revealed that CPA 4-hydroxylationwas most actively catalyzed by CYP2B1 and CYP2B6, with little(CYP2B1) or no (CYP2B6) N-dechloroethylation activity detected.The overall catalytic efficiency (V_max/K_m) was highest withCYP2B1, largely due to its $~$ 3-fold lower K_m for CPA, and thistranslated into a 2-fold increase in cytotoxicity compared withCYP2B6, as indicated by EC₅₀ values (Table 1). CYP3A4 preferentiallymetabolized CPA by N-dechloroethylation ( $~$ 75% of total metabolism),with the catalytic efficiency for the 4-hydroxylation reactionbeing only 15 to 30% that of CYP2B1 and CYP2B6 (Fig. 3A). However,with R-IFA as substrate, CYP3A4 exhibited high 4-hydroxylaseactivity, coupled with a comparatively low N-dechloroethylationactivity. CYP3A4 is a major catalyst of IFA metabolism in humanliver microsomes (Chang et al., 1993; Walker et al., 1994) andthe most abundant cytochrome P450 enzyme in human liver. Thepresent findings suggest that the anticancer activity of racemicIFA, as used in the clinic, is in large part due to R-IFA, insofaras S-IFA is primarily metabolized by N-dechloroethylation, catalyzedby CYP3A4 and CYP2B6 (Fig. 3C). These findings support the useof R-IFA in place of racemic IFA or its S-enantiomer, as proposedby Williams and Wainer (1999) based on the more extensive 4-hydroxylationof R-IFA than S-IFA seen in pharmacokinetic studies (Waineret al., 1994) and by the finding that the N-dechloroethylationof R-IFA is less extensive than that of S-IFA in incubationswith human liver microsomes (Roy et al., 1999a).

CYP3A4 can be used in a P450-based enzyme prodrug therapy tosensitize tumor cells to racemic IFA and, to a lesser extent,CPA (Jounaidi et al., 1998). Analysis of R-IFA and S-IFA metabolismcatalyzed by a panel of cDNA-expressed CYP3A enzymes revealedthat the rat enzyme CYP3A1 exhibits superior catalytic activitycompared with four other CYP3A enzymes, including CYP3A4. CYP3A1exhibited high intrinsic 4-hydroxylase activity, minimal N-dechloroethylationactivity (11% of total metabolism at V_max), and a comparativelylow K_m value compared with the other CYP3A enzymes examined,indicating that this P450 may be useful in combination withR-IFA or S-IFA in clinical trials of this P450-based cancertherapy (Lohr et al., 2003; Braybrooke et al., 2005). CYP3A12,which is expressed in dog liver, exhibited a preferential 4-hydroxylationof R-IFA compared with S-IFA; however, CYP3A12 suffered froma high K_m value and low catalytic efficiency for R-IFA 4-hydroxylationcompared with CYP3A1. CYP3A5, like CYP3A4, also exhibits a preferencefor 4-hydroxylation of R-IFA compared with S-IFA (Roy et al.,1999a). Another human liver enzyme, CYP3A7, exhibited the lowestcatalytic activity of all five CYP3A enzymes toward both enantiomersof IFA.

CAA, a byproduct of oxazaphosphorine metabolism, displayed appreciablecytotoxic activity in cell culture (EC₅₀ $~$ 2.5 µM, comparedwith EC₅₀ values of 3–5 µM for the 4-hydroxy derivativesof CPA and IFA; Table 1), in agreement with earlier studiesin various tumor cell lines (Brueggemann et al., 2002). However,CAA is not generally regarded as an active, therapeutic metaboliteof IFA or CPA. CAA exhibits some antitumor activity in vivo,albeit substantially less than that of 4-OH-IFA (Borner et al.,2000). Of note, we observed that the rate of 4-hydroxylationof R-IFA by CYP2B6-expressing 9L gliosarcoma cells was 5-foldlower than that of 9L cells expressing CYP2B1, yet in growthinhibition assays, the CYP2B6 cells showed sensitivity to R-IFAcomparable with that of CYP2B1 cells. This discrepancy suggeststhat at least a portion of the cytotoxic activity of R-IFA (andalso S-IFA) is due to the formation of CAA via N-dechloroethylationin the case of the CYP2B6 cells.

Given the host toxicities that are widely believed to be linkedto CAA exposure, decreasing N-dechloroethylation through theuse of R-IFA may result in an increase in therapeutic index.Further study is required to determine whether R-IFA treatmentin vivo leads to enhanced R-IFA metabolism ("autoinduction"),via increased expression of CYP3A4 (Chang et al., 1997), ashas been seen with racemic IFA (Kerbusch et al., 2001). It willalso be important to determine whether R-IFA treatment is associatedwith antiangiogenic activity similar to that seen when CPA isadministered repeatedly in low doses using metronomic (Man etal., 2002) or antiangiogenic treatment schedules (Browder etal., 2000). This latter approach is highly effective when appliedto CPA in the context of prodrug-activation gene therapy usingCYP2B6 (Jounaidi and Waxman, 2001). Based on the present findings,this latter strategy may also be implemented by targeted deliveryof CYP3A1 to tumors in situ in combination with R-IFA treatment.The low K_m value for IFA exhibited by CYP3A1 compared with CYP3A4may provide the opportunity to shift prodrug activation fromthe liver to the tumor, thereby increasing the antitumor effectand potentially reducing host toxicity.

Footnotes

Supported in part by National Institutes of Health Grant CA49248(to D.J.W.).

Article, publication date, and citation information can be foundat http://dmd.aspetjournals.org.

doi:10.1124/dmd.105.004788.

ABBREVIATIONS: IFA, ifosfamide; CPA, cyclophosphamide; P450,cytochrome P450; CAA, chloroacetaldehyde; deCl, N-dechloroethylation;P450R, P450 reductase; FBS, fetal bovine serum; DMEM, Dulbecco'smodified Eagle's medium; IRES, internal ribosome entry site;CHO, Chinese hamster ovary; MEM, minimal essential medium; HPLC,high-performance liquid chromatography.

Address correspondence to: Dr. David J. Waxman, Department of Biology, Boston University, 5 Cummington Street, Boston, MA 02215. E-mail: djw{at}bu.edu

References

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Abstract
Materials and Methods
Results
Discussion
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