ACYL-COENZYME A FORMATION OF SIMVASTATIN IN MOUSE LIVER PREPARATIONS

Chunze Li, Raju Subramanian¹, Sean Yu, and Thomayant Prueksaritanont

Department of Drug Metabolism, Merck Research Laboratories, West Point, Pennsylvania

(Received August 3, 2005; accepted October 21, 2005)

Abstract

Top
Abstract
Materials and Methods
Results
Discussion
References

Formation of an acyl-CoA thioester has been proposed, but notdirectly demonstrated, to be a key step in mediating both lactonizationand atypical ß-oxidation of 3-hydroxy-3-methylglutaryl-CoAreductase inhibitors. Here, we describe studies to characterizeformation of acyl-CoA thioesters in vitro in mouse liver preparationsusing the hydroxy acid form of simvastatin (SVA) as a modelsubstrate. With an optimized chromatography method, three newproducts were detected in addition to the dehydration product(P1) and the lactone form of simvastatin, which have been characterizedpreviously (Prueksaritanont et al., 2001). Based on high-pressureliquid chromatography analysis, UV spectroscopy, mass spectrometry,and NMR spectral characterization, two metabolites were identifiedas acyl-CoA thioester conjugates of SVA and P1, respectively,whereas the third metabolite (M1) was confirmed to be the L-ß-hydroxyisomer of simvastatin. M1 was probably formed by stereospecifichydration, a previously reported reaction, and subsequent lactonizationof P1-S-acyl CoA. Among all the mouse liver subcellular fractions,microsomes exhibited the highest capacity to catalyze the CoASH-dependentmetabolism of SVA, whereas such activity was totally absentin cytosol. Together, these results provide direct experimentalevidence that SVA (and conceivably other statins as well) isable to form an acyl-CoA thioester, possibly by microsomal long-chainacyl-CoA synthetase(s), leading to formation of two parallelmetabolic pathways, one resulting in the two diastereomers ofstatin lactones (simvastatin and M1) and the other to the ß-oxidationpathway of statin hydroxy acids.

3-Hydroxy-3-methylglutaryl-coenzyme A (HMG-CoA) reductase inhibitors(statins) are a well established class of drugs used widelyin the treatment of hypercholesterolemia due to their tolerability,proven efficacy, and convenient administration. Except for simvastatinand lovastatin, all current statins are administered as thepharmacologically active hydroxy acid form. Simvastatin andlovastatin are administered as inactive lactones, which uponhydrolysis to their respective hydroxy acids (SVA and LVA),serve as potent competitive inhibitors of HMG-CoA reductase,the rate-limiting enzyme in de novo cholesterol biosynthesis(Duggan and Vickers, 1990

All statins, with the exception of pravastatin (Hatanaka, 2000)and the recently approved rosuvastatin (Martin et al., 2000),are extensively metabolized before elimination (Reinoso et al.,2002). The common metabolic pathways of these statins includecytochrome P450-mediated oxidative metabolism (Igel et al.,2001), acyl glucuronidation (Prueksaritanont et al., 2002a,b),and ß-oxidation (Reinoso et al., 2002). Like the acylglucuronidation, the ß-oxidation occurs at the dihydroxyheptanoic or heptenoic acid side chain, a structural featurecommon to all statin hydroxy acids (SVA structure, as an example,is shown in Fig. 1). The pentanoic and/or propanoic acid productscorresponding to one and/or two cycles of ß-oxidation,respectively, have been reported to occur exclusively in rodentsfollowing lovastatin, simvastatin, and cerivastatin administrationand predominantly so for other statins (Vickers et al., 1990;Halpin et al., 1993; Boberg et al., 1998; Reinoso et al., 2002).Acyl-CoA thioesters of these statin hydroxy acids have beenproposed to be the key intermediates for the formation of theseß-oxidation metabolites (Fig. 1). Evidence that supportsthis proposal, however, is very limited. Recent studies in ourlaboratory have provided some evidence that formation of theß-oxidation products of SVA in vitro in mouse liverpreparations was mediated by CoASH-dependent enzyme(s) (Prueksaritanontet al., 2001). Unfortunately, acyl-CoA thioesters of SVA andits ß-oxidation intermediates were not detected inthe study. Therefore, the present studies were undertaken, usingan in vitro approach and SVA as a model substrate, to characterizethe formation of these acyl-CoA thioester intermediates in mouseliver subcellular fractions and to provide support for the mechanismof the ß-oxidation of statins proposed by Halpin etal. (1993). Here, we demonstrate that acyl-CoA conjugates ofSVA and its dehydration product (P1) were formed in vitro inmouse liver preparations and were primarily catalyzed by microsomalenzymes. Additionally, the findings of CoASH-dependent formationof simvastatin and its diastereomer M1 substantiate the mechanismproposed previously for the in vivo lactonization of statinhydroxy acids (Duggan and Vickers, 1990).

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FIG. 1. Proposed pathway for CoASH-dependent metabolism of SVA.

	Materials and Methods

Top Abstract Materials and Methods Results Discussion References

Materials. Simvastatin and SVA were synthesized at Merck ResearchLaboratories (Rahway, NJ). Triton X-100, CoASH, ATP, and palmitoyl-S-acylcoenzyme A (PA-CoA) were obtained from Sigma-Aldrich (St. Louis,MO). [1-¹⁴C]Palmitic acid and [1-¹⁴C]octanoic acid were obtainedfrom GE Healthcare (Little Chalfont, Buckinghamshire, UK) andAmerican Radiolabeled Chemicals, Inc. (St. Louis, MO), respectively.All other agents were of analytical or HPLC grade.

Animals. All animal studies were approved by the Merck ResearchLaboratories Institutional Animal Care and Use Committee. Tenmale CD-1 mice (25–40 g) were obtained from Charles RiverLaboratories (Wilmington, MA). Following cervical dislocation,livers were quickly removed, weighed, and washed with 1.15%potassium chloride. The livers were homogenized in 4 volumesof ice-cold medium containing 250 mM sucrose, 10 mM HEPES, and1 mM EDTA. The liver subcellular fractions were prepared bydifferential centrifugation as described previously with minormodifications (Bjorge and Baillie, 1991). In brief, liver homogenateswere centrifuged first at 600g for 10 min to remove nuclei andcell debris. The supernatant (S0.6) was centrifuged at 3300gfor a further 10 min to sediment the heavy mitochondria (MT-H).The resulting supernatant (S3) was then centrifuged at 27,000gfor 10 min to obtain the light mitochondria fraction (MT-L).The corresponding supernatant (S27) was finally centrifugedat 100,000g for 1 h to prepare the liver microsomes. The residuesupernatant was taken as the cytosolic fraction. The purityof each of the fractions was assessed by the activity of theirrespective marker enzymes: catalase for peroxisomes (Baudhuinet al., 1964), cytochrome c oxidase for mitochondria (Sellingeret al., 1960), lactate dehydrogenase for cytosol (Volkl andFahimi, 1985), and NADPH-cytochrome c reductase for microsomes(Beaufay et al., 1974).

In Vitro Metabolism. Incubations of SVA (100 µM) withmouse liver subcellular fractions (1.5 mg/ml) were carried outin triplicate in 150 mM Tris-HCl buffer (pH 8.0) containing0.05% Triton X-100, 1.2 mM CoASH, 10 mM MgCl₂, and 5 mM ATPin a final volume of 0.2 ml. After a 3-min preincubation, reactionswere initiated by the addition of ATP and incubated for up to60 min at 37°C. The reactions were terminated at appropriatetime intervals by the addition of 120 µl of ice-cold acetonitrile.After centrifugation at 10,000g for 10 min, the supernatantwas analyzed immediately by HPLC or LC-MS with an autosamplerset at 5°C to minimize any degradation that might have occurredduring the sample handling and analysis. Preliminary stabilitystudies showed that SVA-S-acyl coenzyme A (SVA-CoA) and itssubsequent metabolites were stable under the conditions describedabove. Control experiments included incubation mixtures withone or more components missing.

Incubations with [1-¹⁴C]palmitic acid (50 µM) and [1-¹⁴C]octanoicacid (50 µM) were performed under the same conditionsas described above for SVA, except that the mixtures contained0.025 mg/ml mouse liver subcellular fractions for palmitic acidand 0.125 mg/ml for octanoic acid, and were incubated for 5min. Under such incubation conditions, the formation of PA-CoAand octanoyl-S-acyl coenzyme A (OA-CoA) was linear with incubationtime and protein concentration.

For isolation and purification of metabolites of SVA, large-scaleincubations of SVA (500 µM) were carried out with mouseliver microsomes (1.5 mg/ml), CoASH (1.2 mM), and ATP (5 mM)for 40 min in a final volume of 12 ml for the isolation of SVA-CoAand P1-S-acyl coenzyme A (P1-CoA) or for 3 h in a final volumeof 60 ml for M1. The incubation mixtures were terminated withhalf a volume of acetonitrile and loaded onto C₁₈ solid-phaseextraction cartridges (Oasis HLB SPE cartridge; Waters Corporation,Milford, MA), which were pre-equilibrated with water and acetonitrile.The acyl-CoA thioesters containing fractions were eluted with70% acetonitrile, whereas M1-containing fraction was elutedwith 90% acetonitrile. The resulting solid-phase eluates wereevaporated to dryness, reconstituted in 5 to 10 ml of the mobilephase (20% acetonitrile in 10 mM ammonium acetate buffer, pH= 7), and isolated by preparative HPLC as described below. Thepurified metabolites were characterized by NMR spectroscopy.

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FIG. 2. Representative HPLC-UV profiles of SVA metabolites in incubations with mouse liver S0.6 (A), microsomes (B), and cytosol (C). Incubations were carried out at 37°C for 20 min using mouse liver subcellular fractions (1.5 mg/ml) and SVA (100 µM) with 1.2 mM CoASH and 5 mM ATP.

Analytical Methods. SVA and its metabolites were analyzed usingpublished HPLC methods with some modifications (Prueksaritanontet al., 1999

). In brief, samples held in an autosampler (setat 5°C) were chromatographed on a C₁₈ Zorbax column (150x 4.6 mm, 5 µm; Agilent Technologies, Palo Alto, CA) witha linear gradient of acetonitrile and 10 mM ammonium acetate(pH 7). The eluates were monitored by UV absorption at 240 and260 nm. Due to the unavailability of authentic standards forSVA-CoA and P1-CoA, the concentrations of these metabolitesin the in vitro incubation mixtures were estimated using standardcurves for PA-CoA at 260 nm, assuming similar extinction coefficientsbetween SVA-CoA (or P1-CoA) and PA-CoA. Evidence that supportsthe assumption includes the observations that SVA, P1, and palmiticacid all had minimal UV absorption at 260 nm, whereas the correspondingacyl-CoA thioesters and free CoASH exhibited maximal UV absorptionat 260 nm. In addition, PA-CoA was selected because of its similarHPLC retention time to SVA-CoA and P1-CoA under the HPLC conditionsdescribed above. Quantification of P1 and M1 in the in vitroincubations was accomplished using standard curves for SVA andsimvastatin, respectively, assuming identical extraction recoveriesand extinction coefficients at their maximal UV absorption at240 nm.

Metabolite isolation was accomplished by semipreparative HPLC(Waters) coupled with a fraction collector (Foxy 200; ISCO,Inc., Lincoln, NE). The reconstituted reaction mixtures wereseparated on a Luna C₁₈(2) column (250 x 10 mm, 5 µm;Phenomenex, Torrance, CA) with a 40-min gradient from 80% A(10% methanol in 10 mM ammonium acetate, pH 7) to 70% B (90%acetonitrile in water). Fractions corresponding to the peaksfor the SVA metabolites were collected according to UV absorbanceat 260 nm for SVA-CoA and P1-CoA and 240 nm for M1.

Analysis of PA-CoA and OA-CoA in mouse liver preparations wasperformed on a Hypersil BDS C₈ column (150 x 4.6 mm, 5 µm;Thermo Electron Corporation, Waltham, MA) with a linear gradientof acetonitrile and 25 mM ammonium acetate (pH 7). The acyl-CoAthioesters were monitored by UV absorption at 260 nm and byan on-line IN/US ß-RAM radioactivity detector (IN/USSystems, Tampa, FL).

LC-MS analysis was conducted on a Finnigan MAT LCQ ion trapmass spectrometer (Thermo Electron Corporation), interfacedwith a PerkinElmer HPLC system (PerkinElmer Life and AnalyticalSciences, Boston, MA) equipped with two Series 200 micropumpsand an autosampler set at 5°C. LC-MS and LC-MS/MS experimentswere carried out using electrospray ionization in the negativeion mode (for SVA, P1, SVA-CoA, and P1-CoA) or positive ionmode (for lactones simvastatin and M1). The electrospray ionizationvoltage was set at 3.5 kV, with the heated capillary temperatureheld at 175°C. A C₁₈ Zorbax column (150 x 4.6 mm, 5 µm;Agilent Technologies) was used for chromatographic separationand was eluted at 1.0 ml/min with a gradient of 10 mM ammoniumacetate (pH 7) in water with 10% methanol (A) and 90% acetonitrilein water (B). The initial mobile phase consisted of 15% B, whichremained unchanged for 5 min and increased linearly to 70% Bover 22 min, then to 90% over 1 min, and held for 5 min. One-fifthof the flow was directed into the mass spectrometer, and theremainder was used for UV detection at 240 nm.

Accurate mass measurements were conducted on a Micromass Q-TOF(quadrupole time-of-flight) II mass spectrometer (Waters) operatedin the positive electrospray ionization mode with a LockSprayreference sprayer. The source and desolvation gas temperatureswere set at 80°C and 180°C, respectively. The capillaryvoltage, cone voltage, and collision energies were 2.5 kV, 25V, and 15 V, respectively. The instrument was calibrated byinfusing aqueous 0.01% phosphoric acid solution through a syringepump at 5 µl/min prior to the experiment. The same calibrationsolution was used as the lock mass in the sample analysis. Thechromatographic conditions used in Q-TOF experiments were thesame as described above.

NMR studies were performed at 10°C for CoASH and acyl-CoAthioesters and at 25°C for the SVA, simvastatin, and M1samples. All NMR data were collected either on a 500- or 600-MHzspectrometer (Varian Inc., Palo Alto, CA), both equipped witha 5-mm HCN Cold Probe (Varian Inc.). The HPLC isolates or theauthentic standard(s) were dissolved in $~$ 160 µl of CD₃OD[except for CoASH, where 10% D₂O (v/v) was added to promotesolubility] and transferred to 3-mm tubes. 1D ¹H, 2D ¹H-¹H correlation,2D ¹H-¹³C one-bond, and multiple-bond correlation data setswere acquired for all samples and used to elucidate the structures.

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FIG. 3. MS/MS spectra of SVA-CoA (A) and P1-CoA (B) and tentative assignments of the fragment ions.

	Results

Top Abstract Materials and Methods Results Discussion References

Metabolite Identification. Figure 2, A and B, illustrates typicalHPLC chromatograms derived from incubations of mouse liver subcellularfractions (S0.6 and microsomes) with SVA in the presence ofCoASH and ATP. Five metabolites (designated as SVA-CoA, P1-CoA,P1, M1, and simvastatin) were detected by UV absorption at 240nm. P1, M1, and simvastatin exhibited UV absorption spectrasimilar to SVA, whereas SVA-CoA and P1-CoA had UV absorptionpeak at 260 nm (characteristics for CoASH) in addition to thewell characterized UV peak for SVA at 240 nm. P1, which gavea deprotonated ion [M – H]^– at m/z 417, has beenidentified previously by NMR as the dehydration product of SVA(Prueksaritanont et al., 2001

). The product, which eluted lastin the chromatogram, was identified as the simvastatin lactonebased on the identical HPLC retention time and UV spectrum comparedwith the authentic standard. Except for a small amount of simvastatin(<0.1% of initial concentration), the remaining four SVAmetabolites were not detectable in incubations with mouse livercytosol (Fig. 2C) and control incubations that lacked liverprotein, ATP, or CoASH. The results suggested that formationof SVA-CoA, P1-CoA, P1, and M1 was mediated by CoASH- and ATP-dependentenzyme(s), whereas simvastatin was formed by both enzymatic(by CoASH- and ATP-dependent enzymes) and chemical (to a lesserextent) processes under the conditions described under Materialsand Methods.

The mass spectrum of SVA-CoA showed a prominent [M – H]^–ion at m/z 1184.4, 749 (CoASH – H₂O) mass units higherthan the [M – H]^– ion of SVA. MS/MS fragmentationof m/z 1184.4 showed peaks indicative of a CoASH moiety attachedto SVA, including ions at m/z 766.2 ([CoAS]^–), m/z 426.1([adenosine diphosphate]^–), m/z 408.2 ([adenosine diphosphate– H₂O]^–), m/z 1104.5 ([SVA-CoA – H₂PO₃]),m/z 1086.5 ([SVA-CoA – dimethyl-oxobutyl]^–), m/z1049.4 ([SVA-CoA – adenine – 2H]^–), and m/z837.4 ([SVA-CoA – adenosine monophosphate – 2H]^–)(Fig. 3A). NMR studies with the isolated metabolite confirmedit to be an acyl-CoA conjugate of SVA with a thioester bondbetween SVA and CoASH. The combined NMR data clearly showedthat the SVA and CoASH moieties were fully intact in the adductspectrum. The methylene group, labeled 3, in the SVA portionof the adduct appeared at ${delta}$ _H 2.71, 2.77 ppm/ ${delta}$ _C 50.8 ppm (Table 1).The ß-methylene group, labeled a', of the mercaptoethylaminesubunit in CoASH appeared at ${delta}$ _H 3.00 ppm/ ${delta}$ _C 27.9 ppm (Table 1).A 2 D ¹H-¹³C multibond correlation (a select expansion of thespectrum displayed in Fig. 4) was observed from both methyleneprotons 3 and a' to the carbonyl carbon 2 (at 197.9 ppm) inthe SVA heptanoic acid side chain. Therefore, the combined NMRdata showed that the sulfur of the CoASH was conjugated to theacyl carbon 2 of the heptanoic acid side chain in SVA.

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TABLE 1 ¹H and ¹³C chemical shifts of SVA, simvastatin, and CoASH-dependent SVA metabolites

All chemical shifts are referenced to CD₂HOD peak set at ${delta}$ _H 3.30/ ${delta}$ _C 47.9 ppm. The decalin ring and the dimethyl butanoic acid moieties are unchanged in all structures, and their chemical shifts in all structures were practically identical to previously published data on SVA (Prueksaritanont et al., 2001).

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FIG. 4. Select expansion of a 2D ¹H-¹³C multibond correlation NMR spectrum of SVA-CoA. Labels are shown in Fig. 1.

The identification of P1-CoA was based on UV, MS, MS/MS, andNMR spectra. P1-CoA gave rise to a deprotonated ion [M –H]^– at m/z 1166.4, 749 (CoASH – H₂O) mass unitshigher than the [M – H]^– ion of P1 and 18 mass unitsless than that of SVA-CoA thioester (m/z 1184.4), suggestingpossible dehydration of SVA-CoA. Consistently, the MS/MS spectrumof P1-CoA displayed a family of product ions, including ionsm/z 1086.5 ([P1-CoA – H₂PO₃]^–), m/z 1068.5 ([P1-CoA– dimethyl-oxobutyl]^–), m/z 1031.4 ([P1-CoA –adenine – 2H]^–), and m/z 819.4 ([P1-CoA –adenosine monophosphate – 2H]^–) (Fig. 3B), whichwere all 18 mass units less than the corresponding fragmentions of SVA-CoA. In addition, the product ions at m/z 426.1and 408.2, corresponding to adenosine diphosphate and its dehydrationions, remained the same as those of SVA-CoA, indicating thatthe adenosine phosphate moiety was intact (Fig. 3B). NMR datasupported that P1-CoA was an acyl-CoA conjugate of P1 with athioester bond between P1 and CoASH. The combined NMR data conclusivelyindicated that the P1 and CoASH moieties were intact. The protonshifts of P1 moiety were similar to the previously publisheddata on P1, the dehydration metabolite of SVA (Prueksaritanontet al., 2001). Alkene carbons 3 and 4 in the P1 moiety appearedat ${delta}$ _H 6.22 ppm/ ${delta}$ _C 129.9 ppm and ${delta}$ _H 6.90 ppm/ ${delta}$ _C 142.6 ppm, respectively(Table 1). The ß-methylene group, labeled a', of themercaptoethylamine subunit in CoASH appeared at ${delta}$ _H 3.04 ppm/ ${delta}$ _C27.6 ppm (Table 1). A common 2 D ¹H-¹³C multibond correlationwas observed from the protons 3 and 4 of P1 moiety and methyleneprotons a' to the carbonyl carbon 2 at 190.0 ppm (not shown).Therefore, NMR data conclusively indicated the site of CoASHsulfur conjugation to be at the acyl carbon 2 of P1 moiety.

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FIG. 5. Proposed fragmentation pathway for simvastatin and M1. The accurate mass measurement data are summarized in Table 2.

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TABLE 2 Observed and calculated m/z values of the most abundant fragment ions in the MS/MS spectra of simvastatin standard and M1

The calculated values and formulas are based on the fragmentation assigned in Fig. 5. The MS/MS spectra were obtained using a Micromass Q-TOF mass spectrometer (see text for details).

M1 was identified as L-ß-hydroxy isomer of simvastatinbased on UV, accurate MS, MS/MS, and NMR spectra. Accurate massmeasurements by a Q-TOF instrument revealed that the [M + H]⁺of simvastatin standard and M1 were at m/z 419.2788 and 419.2804,respectively, which were all within 2.2 ppm of the calculatedmass of [simvastatin + H]⁺. In the high-resolution MS/MS experiment,the residual parent ion signal was used as the internal lockmass. MS/MS spectra of simvastatin and M1 exhibited almost identicalfragmentation patterns except for the relative intensities offragment ions (not shown). The observed and calculated m/z valuesof the most abundant fragment ions of simvastatin and M1 areshown in Table 2, which confirmed the fragmentation pathwayproposed in Fig. 5. Therefore, high-resolution MS data stronglysuggested that simvastatin and M1 were positional isomers. TheNMR data on M1 was consistent with a chiral center inversionat carbon 4, which is part of the six-member lactone ring. ¹Hchemical shifts of simvastatin standard and M1 are shown inTable 1. Comparing the two 1D ¹H NMR spectra, the spectral changeswere observed for protons in the six-member lactone ring. TheCHOH methine protons, labeled 4 and 6, appeared at 4.24 and4.61 ppm, respectively, in simvastatin (Table 1). In contrast,H4 and H6 were overlapped and appeared at 4.19 ppm in the M1spectrum (Table 1). The methine carbons at 4 and 6 were resolvedin the 2D ¹H-¹³C one-bond correlation spectrum of M1 at 62.8and 77.8 ppm, respectively (not shown).

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FIG. 6. Time-dependent formation of SVA metabolites following incubations with mouse liver S0.6 (A) and microsomes (B). Incubations were carried out in triplicate at 37°C using mouse liver subcellular fractions (1.5 mg/ml) and SVA (100 µM) with 1.2 mM CoASH and 5 mM ATP. Values represent means ± S.D. from triplicate incubations.

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FIG. 7. Mouse liver subcellular distribution of enzyme activity responsible for the formation of PA-CoA (A), OA-CoA (B), and CoA-dependent metabolism of SVA (C). Incubations of SVA (100 µM) with mouse liver subcellular fractions (1.5 mg/ml) were carried out in triplicate at 37°C for 20 min in 150 mM Tris-HCl buffer (pH 8.0) containing 1.2 mM CoASH and 5 mM ATP. Incubations with [1-¹⁴C]palmitic acid (50 µM) and [1-¹⁴C]octanoic acid (50 µM) were performed under the same conditions as described above for SVA, except that the mixtures contained 0.025 mg/ml of mouse liver subcellular fractions for palmitic acid and 0.125 mg/ml for octanoic acid and were incubated for 5 min. Values represent means ± S.D. from triplicate incubations.

Metabolism of SVA in Mouse Liver Subcellular Fractions. Time-dependentstudies with mouse liver S0.6 showed that formation of SVA-CoAand P1-CoA increased rapidly during the first 10 to 20-min incubationsand then decreased steadily thereafter, whereas formation ofP1, M1, and simvastatin seemed to increase gradually with incubationtime (Fig. 6A). In addition to mouse liver S0.6, CoASH-dependentmetabolism of SVA was also observed in incubations with othermouse liver subcellular fractions, including mitochondria (MT-Hand MT-L) and microsomes (Fig. 7C). The identities and puritiesof these subcellular fractions were confirmed by marker enzymeanalysis (Table 3). Among all the mouse subcellular fractions,microsomes exhibited the highest capability to catalyze CoASH-dependentmetabolism of SVA on a per-milligram-of-protein basis, whereascytosol was totally incapable of catalyzing the reaction (Figs.2C and 7C). As illustrated in Figs. 2B and 6B, incubations ofSVA with mouse liver microsomes produced significantly higherlevels of SVA-CoA and P1-CoA thioesters (approximately 5- to7-fold higher after 20-min incubations) than that of mouse liverS0.6. Consistently, the lactonization products simvastatin andM1 were also found to be approximately 5- to 7-fold higher after1-h incubations with mouse liver microsomes than the correspondingincubations with S0.6. These results provided additional supportfor the acyl-CoA thioester-dependent mechanism proposed previouslyfor the lactonization of the hydroxy acid forms of statins observedin vivo (Duggan and Vickers, 1990

). Interestingly, P1 levelsin microsomes were not significantly more than in S0.6.

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TABLE 3 Marker enzyme activities in mouse liver subcellular fractions

Units for catalase and lactate dehydrogenase are micromoles per minute per milligram of protein; units for cytochrome c oxidase and cytochrome c reductase are nanomoles per minute per milligram of protein. Values represent means ± S.D. from triplicate incubations.

Due to the apparent subsequent metabolism of SVA-CoA in mouseliver preparations, the sum of the five metabolites (SVA-CoA,P1-CoA, P1, M1, and simvastatin) was used to compare the ratesof CoASH-dependent metabolism of SVA in mouse liver subcellularfractions. Preliminary studies showed that CoASH-dependent metabolismof SVA was linear with time up to 30 min and with mouse liverS0.6 up to 3 mg/ml. As shown in Fig. 7C and Table 3, the rateof CoASH-dependent metabolism of SVA in mouse liver subcellularfractions seemed to correlate well with that of acyl-CoA formationof palmitic acid (a substrate for long-chain acyl-CoA synthetase)(Fig. 7A) and the activity of cytochrome c reductase, a markerenzyme for microsomes, but not with the rate of acyl-CoA formationof octanoic acid (a substrate for medium-chain acyl-CoA synthetase)(Fig. 7B) and the activities of marker enzymes for other subcellularfractions. These observations clearly indicated that acyl-CoAformation of SVA is catalyzed preferentially by microsomal enzyme(s).

Discussion

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Abstract
Materials and Methods
Results
Discussion
References

The present studies provide direct experimental evidence forthe formation of acyl-CoA thioester of SVA in vitro in mouseliver preparations. Using the HPLC methods described above,acyl-CoA thioester intermediates of SVA were completely resolvedfrom other peaks present following incubations with mouse liverpreparations. Under such HPLC conditions optimized for acyl-CoAthioesters, we were able to isolate and fully characterize theseacyl-CoA thioester intermediates by LC-MS/MS and NMR analysis.The optimized HPLC method also provides a possible explanationfor the reason why the CoA thioester conjugates of SVA werenot observed in our previous studies with mouse liver preparations(Prueksaritanont et al., 2001). Preliminary studies showed thatSVA-CoA and P1-CoA were sensitive to pH of mobile phase anddid not chromatograph well under acidic conditions, such as0.1% formic acid, the condition used in our previous studies(Prueksaritanont et al., 2001). Similar observations were alsomade for other xenobiotic acyl-CoA thioesters, such as 2-phenylpropionyl-S-acylCoA (Li et al., 2002), 2,4-dichlorophenoxyacetyl-S-acyl CoA(Li et al., 2003), and naproxen-S-acyl CoA (Olsen et al., 2002).Recently, Sidenius el al. (2004) reported several LC chromatographicmethods developed for analysis of acyl-CoA thioesters of eightstructurally diverse carboxylic acids, including ibuprofen,clofibric acid, indomethacin, fenbufen, tolmetin, salicylicacid, 2-phenoxypropionic, and 4-chloro-2-methyl-phenoxyaceticacid. Notably, the pH of mobile phases used for the eight acyl-CoAthioesters were all between 6 and 7.

As pointed out by Halpin et al. (1993), ß-oxidationof fatty acids requires that hydroxylated intermediates be inthe L-configuration, whereas in the case of statins, both the4- and 6-hydroxyl groups on the side chain possess the D-configurationrequired for pharmacological activity (Fig. 1). An epimerizationto L-configuration has been proposed to be an essential stepfor D-ß-hydroxyacyl CoA thioester to enter the ß-oxidationcycles (Halpin et al., 1993) (Fig. 1). Recent in vitro studieswith SVA provided evidence supporting that epimerization ofD-ß-hydroxy statin acyl CoA proceeded via the dehydrationat the ${alpha}$ and ß carbons with respect to the carboxycarbon to give a trans-enoyl-CoA, followed by stereospecifichydration of the unsaturated acyl-CoA to give rise to the L-ß-hydroxyisomer (Prueksaritanont et al., 2001) (Fig. 1). However, thecorresponding dehydration (P1) and stereospecific rehydration(P2, L,D-dihydroxy isomer of SVA) intermediates were detectedonly in their free acid forms (Prueksaritanont et al., 2001).Under the current HPLC conditions, we were able to detect theacyl-CoA thioester of the dehydration product, namely P1-CoA,in addition to its free acid form P1. However, the peak correspondingto acyl-CoA thioester of P2 (P2-S-acyl coenzyme A, P2-CoA) wasnot observed in the present study. The reason for this remainsunclear. It is possible that formation of P2-CoA is low undercurrent incubation conditions and could not be detected by HPLCanalysis.

In addition to mediating the ß-oxidation of statins,the bioactivated acyl-CoA thioesters have been hypothesizedto be a key intermediate for the formation of statin lactones(Duggan and Vickers, 1990). The hypothesis has been substantiatedby recent findings of CoASH-dependent formation of simvastatinlactone in vitro in mouse liver preparations (Prueksaritanontet al., 2001). Similar observations on simvastatin formationwere also made in the present study. In addition to simvastatin,we found a new lactone metabolite of SVA, M1 (L-ß-hydroxyisomer of simvastatin), possibly formed by lactonization ofP2-CoA, and its structure has been identified definitively (Fig. 1).Our finding that the extent of formation of simvastatinand M1 increased when the corresponding acyl-CoA formation (SVA-CoAand P1-CoA) increased (Fig. 6) provides additional evidencethat the lactonization of the statin hydroxy acids (SVA andP2) could be mediated by acyl-CoA thioesters via an intramolecularacylation. Considering the well documented interconversion betweenSVA and simvastatin, it is anticipated that interconversionbetween P2 and M1 might also exist (Fig. 1). Both P2 and M1are pharmacologically inactive, and the relevance of the invitro formation of M1 to in vivo situation is currently unclear.The formation of M1 has not been reported in vivo followingadministration of SVA or simvastatin to humans and animals.This might be partly due to the chromatographic conditions usedin the previous in vivo studies, which were not optimized forthe detection of M1. It is also possible that formation of M1is relatively low in vivo if the subsequent ß-oxidationof P2-CoA is more favorable than the corresponding lactonizationprocess (Fig. 1).

In agreement with previous data (Krisans et al., 1980; Knightsand Drogemuller, 2000), our study showed that long-chain acyl-CoAsynthetase (measured by PA-CoA synthetase) was primarily localizedin microsomes and to a lesser extent in mitochondria (MT-H andMT-L) (Fig. 7A), whereas medium-chain acyl-CoA synthetase (measuredby OA-CoA synthetase) was mainly located in mitochondria (MT-Hand MT-L) (Fig. 7B), which further confirmed the purity of subcellularfractions obtained. Studies with these subcellular fractionsrevealed that CoASH-dependent SVA metabolism occurred preferentiallyin microsomes and to a lesser extent in mitochondria (MT-H andMT-L) with no activity observed in cytosol (Fig. 7C). This distributionof activity correlated well with that of long-chain acyl-CoAsynthetase but not with that of medium-chain acyl-CoA synthetase,suggesting the potential involvement of long-chain acyl-CoAsynthetase in the acyl-CoA formation of SVA. This observationwas further supported by our preliminary studies that showedthat CoASH-dependent metabolism of SVA was effectively inhibitedby palmitic acid and triacsin C (10 µM), a potent andselective inhibitor for long-chain acyl-CoA synthetase (Vesseyet al., 2004). In contrast, the enzymes potentially involvedin the hydrolysis of SVA-CoA and P1-CoA were still poorly understood.It seemed that other subcellular fractions (e.g., mitochondriaand cytosol), in addition to microsomes, might contribute significantlyto the hydrolysis of P1-CoA, based on the fact that P1 levelswere not significantly increased when the corresponding P1-CoAwas increased by 5- to 7-fold in liver microsomes compared withliver S0.6 (Fig. 6). This observation is consistent with theprevious reports on the wide subcellular distribution of acyl-CoAhydrolases (Urrea and Bronfman, 1996; Garras et al., 1997).

It is noteworthy that formation of statin acyl-CoA thioestersis not expected to be unique for SVA. Other statin hydroxy acids,including cerivastatin and atorvastatin, which all share thecommon D,D-dihydroxy acid side chain, undergo ß-oxidationand, therefore, are anticipated to be able to form the acyl-CoAthioesters. In fact, our preliminary studies with cerivastatinand atorvastatin showed that acyl-CoA thioesters of these statinacids were readily detectable in vitro in mouse liver preparations.Additionally, consistent with the in vivo observations on theß-oxidation of statins (Reinoso et al., 2002), speciesdifferences in the formation of acyl-CoA thioesters were alsoobserved in our preliminary studies, which showed that acyl-CoAthioesters of statin hydroxy acids, including SVA, cerivastatin,and atorvastatin, were detectable only with liver preparationsfrom mice and rats but not from dogs and humans. However, suchmarked species differences were not observed in vivo for theformation of statin lactones. Significant lactone formationwas reported to occur in vivo following administration of SVAor cerivastatin to dogs and of cerivastatin and atorvastatinto humans (Vickers et al., 1990; Boberg et al., 1998; Kantolaet al., 1998, 1999) in addition to rodents, suggesting thatmore than one metabolic pathway might contribute to the formationof statin lactones. In fact, a recent study showed that acylglucuronides also mediated the lactone formation (Prueksaritanontet al., 2002a). Quantitatively, there seem to be differencesin the relative contribution of these two metabolic pathwaysto the lactone formation of different statins in different species.In rodents, acyl-CoA pathway is most likely to contribute significantlyto the formation of statin lactones based on the fact that ß-oxidationof statins has been shown to be a major pathway in these species(Reinoso et al., 2002). Conversely, in dogs, acyl glucuronidationseems to play a more important role in the lactonization ofstatins than acyl-CoA formation; statins have been shown toundergo significant acyl glucuronidation and minimal ß-oxidationin vivo in dogs (Vickers et al., 1990; Boberg et al., 1998;Black et al., 1999; Prueksaritanont et al., 2002a). Unfortunately,such a conclusion could not be readily drawn in humans due tolimited in vivo data. Nevertheless, based on the findings onacyl glucuronidation in human liver preparations in vitro andin animals in vitro and in vivo (Prueksaritanont et al., 2002a),it is anticipated that acyl glucuronidation plays a role inthe lactonization of statin acids in vivo in humans.

In conclusion, this was the first study to demonstrate the formationof acyl-CoA thioesters of SVA and subsequent metabolites invitro in mouse liver preparations. Our results support the hypothesisthat ß-oxidation occurs as a consequence of acyl-CoAthioester formation, possibly by microsomal long-chain acyl-CoAsynthetase(s) and subsequent epimerization. Additionally, thepresent studies also provide evidence that formation of thesethioesters contributes, at least in part, to interconversionbetween SVA and its diastereomer and between these hydroxy acidsand their corresponding lactones. Similar observations are alsoanticipated with other hydroxy acid forms of statins (and theirdiastereomers) and the corresponding lactones.

Acknowledgments

We thank Scott Fauty and Todd Killino for mouse liver preparationsand Dr. Don Slaughter for critical review of the manuscript.

Footnotes

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

doi:10.1124/dmd.105.006650.

ABBREVIATIONS: HMG-CoA, 3-hydroxy-3-methylglutaryl-coenzymeA; SVA, hydroxy acid form of simvastatin; LVA, hydroxy acidform of lovastatin; PA-CoA, palmitoyl-S-acyl coenzyme A; MT-H,heavy mitochondria; MT-L, light mitochondria; HPLC, high-pressureliquid chromatography; LC-MS, liquid chromatography-mass spectrometry;SVA-CoA, SVA-S-acyl coenzyme A; OA-CoA, octanoyl-S-acyl coenzymeA; P1-CoA, S-acyl coenzyme A of P1 metabolite; P2-CoA, S-acylcoenzyme A of P2 metabolite; MS/MS, tandem mass spectrometry;Q-TOF, quadrupole time-of-flight.

¹ Current affiliation: Amgen Inc., Thousand Oaks, CA.

Address correspondence to: Dr. Chunze Li, Department of Drug Metabolism, Merck Research Laboratories, WP 75-100, P. O. Box 4, West Point, PA 19486. E-mail: chunze_li{at}merck.com.

References

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Abstract
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Discussion
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