J. Vervoort

Phase II Metabolism of Hesperetin by Individual UDP-Glucuronosyltransferases and Sulfotransferases and Rat and Human Tissue Samples

Phase II metabolism by UDP-glucuronosyltransferases (UGTs) and sulfotransferases (SULTs) is the predominant metabolic pathway during the first-pass metabolism of hesperetin (4′-methoxy-3′,5,7-trihydroxyflavanone). In the present study, we have determined the kinetics for glucuronidation and sulfonation of hesperetin by 12 individual UGT and 12 individual SULT enzymes as well as by human or rat small intestinal, colonic, and hepatic microsomal and cytosolic fractions. Results demonstrate that hesperetin is conjugated at positions 7 and 3′ and that major enzyme-specific differences in kinetics and regioselectivity for the UGT and SULT catalyzed conjugations exist. UGT1A9, UGT1A1, UGT1A7, UGT1A8, and UGT1A3 are the major enzymes catalyzing hesperetin glucuronidation, the latter only producing 7-O-glucuronide, whereas UGT1A7 produced mainly 3′-O-glucuronide. Furthermore, UGT1A6 and UGT2B4 only produce hesperetin 7-O-glucuronide, whereas UGT1A1, UGT1A8, UGT1A9, UGT1A10, UGT2B7, and UGT2B15 conjugate both positions. SULT1A2 and SULT1A1 catalyze preferably and most efficiently the formation of hesperetin 3′-O-sulfate, and SULT1C4 catalyzes preferably and most efficiently the formation of hesperetin 7-O-sulfate. Based on expression levels SULT1A3 and SULT1B1 also will probably play a role in the sulfo-conjugation of hesperetin in vivo. The results help to explain discrepancies in metabolite patterns determined in tissues or systems with different expression of UGTs and SULTs, e.g., hepatic and intestinal fractions or Caco-2 cells. The incubations with rat and human tissue samples support an important role for intestinal cells during first-pass metabolism in the formation of hesperetin 3′-O-glucuronide and 7-O-glucuronide, which appear to be the major hesperetin metabolites found in vivo.

19F NMR study on the biodegradation of fluorophenols by various Rhodococcus species

Of all NMR observable isotopes 19F is the one perhaps most convenient for studies on biodegradation of environmental pollutants. The reasons underlying this potential of 19F NMR are discussed and illustrated on the basis of a study on the biodegradation of fluorophenols by four Rhodococcus strains. The results indicate marked differences between the biodegradation pathways of fluorophenols among the various Rhodococcus species. This holds not only for the level and nature of the fluorinated biodegradation pathway intermediates that accumulate, but also for the regioselectivity of the initial hydroxylation step. Several of the Rhodococcus species contain a phenol hydroxylase that catalyses the oxidative defluorination of ortho-fluorinated di- and trifluorophenols. Furthermore, it is illustrated how the 19F NMR technique can be used as a tool in the process of identification of an accumulated unknown metabolite, in this case most likely 5-fluoromaleylacetate. Altogether, the 19F NMR technique proved valid to obtain detailed information on the microbial biodegradation pathways of fluorinated organics, but also to provide information on the specificity of enzymes generally considered unstable and, for this reason, not much studied so far.

Development of a 19F-n.m.r. method for studies on the in vivo and in vitro metabolism of 2-fluoroaniline

1. A 19F-n.m.r. method has been developed for study of the metabolism of 2-fluoroaniline both after in vivo exposure of rats and in in vitro model systems. 2. From the 19F-n.m.r. spectrum of the 24 h urine it was calculated that over 90% of the dose was excreted within 24 h. The metabolic pattern showed that 85% of the metabolites were para-hydroxylated, 72% sulphated, 13% glucuronidated and 29% N-acetylated, 4-amino-3-fluorophenyl sulphate being the main urinary metabolite (53%). 3. In vitro studies of phase I metabolism of 2-fluoroaniline with rat liver microsomes was representative for the in vivo metabolism as hydroxylation in both systems was observed only at the para-position. 4. Phase I+II metabolism was studied in vitro in either isolated rat hepatocytes in suspension or in a 1 h recirculating liver perfusion system. In both these in vitro systems para-hydroxylation, N-acetylation, sulphation and glucuronidation of 2-fluoroaniline were observed. The ratio between glucuronidation and sulphation was dependent on sulphate availability. 5. Of the in vitro systems tested, hepatocytes in Krebs Ringer (sulphate limited) medium was the best model for in vivo metabolism. 6. The detection limit for fluoro-containing metabolites in this 19F-n.m.r. method was 1 MicroM for an overnight run using a Bruker CXP 300 spectrometer. From this it can be concluded that 19F-n.m.r. urine analysis is a useful tool in biomonitoring studies. For 2-fluoroaniline the method appears to be more sensitive than currently available h.p.l.c./t.l.c. methods. In addition, concentration of urine samples can result in either lower detection limits, or in shorter times needed for n.m.r. data acquisition. 7. N-acetylation is known to show genetic polymorphism. Therefore, the 19F-n.m.r. method, detecting all 2-fluoroaniline metabolites, has the additional advantage of eliminating the risk of obtaining false negatives for fast acetylators.

Study on the regioselectivity and mechanism of the aromatic hydroxylation of monofluoroanilines.

The in vitro and in vivo metabolism of monofluoroanilines was investigated. Special attention was focused on the regioselectivity of the aromatic hydroxylation by cytochromes P-450 and the mechanism by which this reaction might proceed. The results clearly demonstrate that the in vitro and in vivo regioselectivity of the aromatic hydroxylation by cytochromes P-450 is dependent on the fluoro-substituent pattern of the aromatic aniline-ring. Results from experiments with liver microsomes from differently pretreated rats demonstrate that the observed regioselectivity for the aromatic hydroxylation is not predominantly determined by the active site of the cytochromes P-450. To investigate the underlying reason for the observed regioselectivity, semi-empirical molecular orbital calculations were performed. Outcomes of these calculations show that neither the frontier orbital densities of the LUMO/LUMO + 1 (lowest unoccupied molecular orbital) of the monofluoroanilines nor the spin-densities in their NH. radicals can explain the observed regioselectivities. The frontier orbital densities of the HOMO/HOMO - 1 (highest occupied molecular orbital) of the monofluoroanilines however, qualitatively correlate with the regioselectivity of the aromatic hydroxylation. Based on these results it is concluded that the cytochrome P-450 dependent aromatic hydroxylation of monofluoroanilines does not proceed by hydrogen or electron abstraction from the aniline substrate to give an aniline-NH. radical. The results rather suggest that cytochrome P-450 catalyzed aromatic hydroxylation of monofluoroanilines proceeds by an electrophilic attack of the (FeO)3+ species of cytochrome P-450 on a specific carbon atom of the aromatic aniline-ring.

Differential substrate behaviour of phenol and aniline derivatives during conversion by horseradish peroxidase

For the first time saturating overall k(cat) values for horseradish peroxidase (HRP) catalysed conversion of phenols and anilines are described. These k(cat) values correlate quantitatively with calculated ionisation potentials of the substrates. The correlations for the phenols are shifted to higher k(cat) values at similar ionisation potentials as compared to those for anilines. (1)H-NMR T(1) relaxation studies, using 3-methylphenol and 3-methylaniline as the model substrates, revealed smaller average distances of the phenol than of the aniline protons to the paramagnetic Fe(3+) centre in HRP. This observation, together with a possibly higher extent of deprotonation of the phenols than of the anilines upon binding to the active site of HRP, may contribute to the relatively higher HRP catalysed conversion rates of phenols than of anilines.

Identification of fluoropyrogallols as new intermediates in biotransformation of monofluorophenols in Rhodococcus opacus 1cp.

ABSTRACT The transformation of monofluorophenols by whole cells ofRhodococcus opacus 1cp was investigated, with special emphasis on the nature of hydroxylated intermediates formed. Thin-layer chromatography, mass spectrum analysis, and 19F nuclear magnetic resonance demonstrated the formation of fluorocatechol and trihydroxyfluorobenzene derivatives from each of three monofluorophenols. The 19F chemical shifts and proton-coupled splitting patterns of the fluorine resonances of the trihydroxyfluorobenzene products established that the trihydroxylated aromatic metabolites contained hydroxyl substituents on three adjacent carbon atoms. Thus, formation of 1,2,3-trihydroxy-4-fluorobenzene (4-fluoropyrogallol) from 2-fluorophenol and formation of 1,2,3-trihydroxy-5-fluorobenzene (5-fluoropyrogallol) from 3-fluorophenol and 4-fluorophenol were observed. These results indicate the involvement of fluoropyrogallols as previously unidentified metabolites in the biotransformation of monofluorophenols in R. opacus1cp.

Bioactivation of 4-fluorinated anilines to benzoquinoneimines as primary reaction products

Metabolism and bioactivation of fluoroanilines was studied both in vitro in microsomal systems and in vivo. 4-Fluoroaniline and pentafluoroaniline and their non-para fluorinated analogues were used as the model compounds. Special attention was focussed on bioactivation to reactive benzoquinoneimines. Cytochrome P-450 dependent monooxygenation at a non-fluorinated para position in (fluoro)aniline derivatives proceeds by formation of the para hydroxylated derivative as the primary metabolite. Monooxygenation at a fluorinated para position in an aniline derivative, however, proceeds by formation of fluoride anion and the reactive benzoquinoneimine as primary reaction products. Thus, for fluoroanilines with a fluorine substituent at the para position bioactivation to the reactive benzoquinoneimine can be a direct result of the cytochrome P-450 dependent conversion. In systems containing NAD(P)H and/or other reducing equivalents part of the benzoquinoneimine can be chemically reduced to give the corresponding 4-hydroxyaniline. In vivo this reduced form of the metabolite can be sulphated or glucuronidated and excreted into urine. The results obtained point to increased chances of bioactivation for aniline derivatives with a fluorinated para position as compared to their non-para fluorinated analogues, both in vitro but also in vivo.

Computer calculation-based quantitative structure-activity relationships for the oxidation of phenol derivatives by horseradish peroxidase compound II.

Abstract The second-order rate constants for the oxidation of a series of phenol derivatives by horseradish peroxidase compound II were compared to computer-calculated chemical parameters characteristic for this reaction step. The phenol derivatives studied were phenol, 4-chlorophenol, 3-hydroxyphenol, 3-methylphenol, 4-methylphenol, 4-hydroxybenzoate, 4-methoxyphenol and 4-hydroxybenzaldehyde. Assuming a reaction of the phenolic substrates in their non-dissociated, uncharged forms, clear correlations (r = 0.977 and r = 0.905) were obtained between the natural logarithm of the second-order rate constants (ln kapp and ln k2 respectively) for their oxidation by compound II and their calculated ionisation potential, i.e. minus the energy of their highest occupied molecular orbital [E(HOMO)]. In addition to this first approach in which the quantitative structure-activity relationship (QSAR) was based on a calculated frontier orbital parameter of the substrate, in a second and third approach the relative heat of formation (ΔΔHF) calculated for the process of one-electron abstraction and H• abstraction from the phenol derivatives was used as a parameter. Plots of the natural logarithms of the second-order rate constants (kapp and k2) for the reaction and the calculated ΔΔHF values for the process of one-electron abstraction also provide clear QSARs with correlation coefficients of –0.968 and –0.926 respectively. Plots of the natural logarithms of the second-order rate constants (kapp and k2) for the reaction and the calculated ΔΔHF values for the process of H• abstraction provide QSARs with correlation coefficients of –0.989 and –0.922 respectively. Since both mechanisms considered, i.e. initial electron abstraction versus initial H• abstraction, provided clear QSARs, the results could not be used to discriminate between these two possible mechanisms for phenol oxidation by horseradish peroxidase compound II. The computer calculation-based QSARs thus obtained for the oxidation of the various phenol derivatives by compound II from horseradish peroxidase indicate the validity of the approaches investigated, i.e. both the frontier orbital approach and the approach in which the process is described by calculated relative heats of formation. The results also indicate that outcomes from computer calculations on relatively unrelated phenol derivatives can be reliably compared to one another. Furthermore, as the actual oxidation of peroxidase substrates by compound II is known to be the rate-limiting step in the overall catalysis by horseradish peroxidase, the QSARs of the present study may have implications for the differences in the overall rate of substrate oxidation of the phenol derivatives by horseradish peroxidase.

Different metabolic pathways of 2,5-difluoronitrobenzene and 2,5-difluoroaminobenzene compared to molecular orbital substrate characteristics

The in vivo metabolite patterns of 2,5-difluoroaminobenzene and of its nitrobenzene analogue, 2,5-difluoronitrobenzene, were determined using 19F NMR analysis of urine samples. Results obtained demonstrate significant differences between the biotransformation patterns of these two analogues. For the aminobenzene, cytochrome P450 catalysed aromatic hydroxylation presents the main metabolic pathway. 2,5-Difluoronitrobenzene was predominantly metabolised through glutathione conjugation leading to excretion of 5-fluoro-2-(N-acetylcysteinyl)-nitrobenzene and fluoride anions, and, to a minor extent, through cytochrome P450 catalysed hydroxylation and nitroreduction. Pretreatment of the rats with various inducers of cytochrome P450 enzymes, known also to influence glutathione S-transferase enzyme patterns, followed by exposure to the 2,5-difluoroamino- or 2,5-difluoronitrobenzene, generally resulted in metabolite patterns that varied only to a small (< or = 12%) extent. Based on these results it was concluded that the biotransformation enzyme pattern is not the predominant factor in determining the metabolic route of these two model compounds. Additional in vitro microsomal and cytosolic incubations with 2,5-difluoroaminobenzene and 2,5-difluoronitrobenzene qualitatively confirmed the in vivo results. NADPH/oxygen supported microsomal cytochrome P450 catalysed hydroxylation was observed only for 2,5-difluoroaminobenzene whereas cytosolic GSH conjugation occurred only in incubations with 2,5-difluoronitrobenzene as the substrate. Outcomes from molecular orbital calculations provided a working hypothesis that can explain the difference in metabolic pathways of the nitro- and aminobenzene derivative on the basis of their chemical characteristics. This hypothesis states that the chances for a nitro- or aminobenzene derivative to enter either a cytochrome P450 or a glutathione conjugation pathway are determined by the relative energy levels of the frontier orbitals of the compounds. The aminobenzene derivative has relatively high energy molecular orbitals leading to an efficient reaction of its highest occupied molecular orbital (HOMO) with the singly occupied molecular orbital of the cytochrome P450 (FeO)3+ intermediate, but a low reactivity of its lowest unoccupied molecular orbital (LUMO) with the HOMO of glutathione. The nitrobenzene, on the other hand, has molecular orbitals of relatively low energy, explaining the efficient interaction, and, thus, reaction between its LUMO and the HOMO electrons of glutathione, but resulting in low reactivity with the SOMO electron of the cytochrome P450 (FeO)3+ reaction intermediate.

IN VITRO METABOLISM OF 5-FLUORO-2-GLUTATHIONYL-NITROBENZENE BY KIDNEY PROXIMAL TUBULAR CELLS STUDIED BY 19F-NMR

Proximal tubular biotransformation of the glutathionyl (GSH) conjugate derived from 2,5-difluoronitrobenzene (5-fluoro-2-glutathionyl-nitrobenzene) was studied by means of 19F-NMR. This method allows a direct and specific detection of the fluorinated metabolites formed, at a detection limit of 1 microM for an overnight NMR run. Incubation of a monolayer of LLCPK1 cells with 100 microM 5-fluoro-2-glutathionyl-nitrobenzene for 24 h showed that these cells metabolize this GSH conjugate into the corresponding cysteinylglycyl and cysteine conjugate. The expected N-acetylcysteine conjugate however was not formed as an endproduct. Additional experiments demonstrated the absence of N-acetyltransferase activity in LLCPK1 cell lysates incubated with FCysNB and also the rapid loss of this activity in isolated renal proximal tubular cells (RPT): freshly isolated RPT cells do convert FCysNB to FNAcNB as major metabolite but, upon cultivation, quickly lose this capacity. Since uptake of FCysNB might also be a limiting factor, we investigated transport of FCysNB from the apical to the basolateral side of the culture RPT cells. No indication for such transport was obtained. Thus, the absence of mercapturic acid formation in LLCPK1 cells and cultured RPT cells is the results of a decline in N-acetyltransferase activity and perhaps a deficient cellular uptake of the cysteine conjugate.