Effects of CYP inhibitors on precocene I metabolism and toxicity in rat liver slices.

We present a comprehensive in vitro approach to assessing metabolism-mediated hepatotoxicity using male Sprague-Dawley rat liver slices incubated with the well characterized hepatotoxicant, precocene I, and inhibitors of cytochrome P450 (CYP) enzymes. This approach combines liquid chromatography mass spectrometry (LC MS) detection methods with multiple toxicity endpoints to enable identification of critical metabolic pathways for hepatotoxicity. The incubations were performed in the absence and presence of the non-specific CYP inhibitor, 1-aminobenzotriazole (ABT) and isoform-specific inhibitors. The metabolite profile of precocene I in rat liver slices shares some features of the in vivo profile, but also had a major difference in that epoxide dihydrodiol hydrolysis products were not observed to a measurable extent. As examples of our liver slice metabolite identification procedure, a minor glutathione adduct and previously unreported 7-O-desmethyl and glucuronidated metabolites of precocene I are reported. Precocene I induced hepatocellular necrosis in a dose- and time-dependent manner. ABT decreased the toxicity of precocene I, increased exposure to parent compound, and decreased metabolite levels in a dose-dependent manner. Of the isoform-specific CYP inhibitors tested for an effect on the precocene I metabolite profile, only tranylcypromine was noticeably effective, indicating a role of CYPs 2A6, 2C9, 2Cl9, and 2E1. With respect to toxicity, the order of CYP inhibitor effectiveness was ABT>diethyldithiocarbamate∼tranylcypromine>ketoconazole. Furafylline and sulfaphenazole had no effect, while quinidine appeared to augment precocene I toxicity. These results suggest that rat liver slices do not reproduce the reported in vivo biotransformation of precocene I and therefore may not be an appropriate model for precocene I metabolism. However, these results provide an example of how small molecule manipulation of CYP activity in an in vitro model can be used to confirm metabolism-mediated toxicity.

A non-acidic sulfaphenazole analog demonstrating high intrinsic clearance and selectivity by canine CYP2C21.

In contrast to human CYP2C9, non-human CYP2C enzymes do not appear to preferentially bind and metabolize anionic drugs. Using analogs of sulfaphenazole, the effect of an acidic sulfonamide group on apparent affinity and turnover rates was characterized with canine CYP2C21. Blocking the sulfonamide with a methyl group increased the intrinsic clearance by CYP2C21 > 100-fold and decreased K(m). Furthermore, CYP2C21 demonstrated selectivity for formation of the benzylic hydroxylation product and a high estimated f(m,CYP) value. The findings suggest that canine CYP2C21, unlike human CYP2C9, does not derive ligand binding affinity from an anion binding interaction with sulfaphenazole analogs.

Visible spectra of type II cytochrome P450-drug complexes: evidence that "incomplete" heme coordination is common.

The visible spectrum of a ligand-bound cytochrome P450 is often used to determine the nature of the interaction between the ligand and the P450. One particularly characteristic form of spectra arises from the coordination of nitrogen-containing ligands to the P450 heme iron. These type II ligands tend to be inhibitors because they stabilize the low reduction potential P450 and prevent oxygen binding to the heme. Yet, several type II ligands containing aniline, imidazole, and triazole moieties are also known to be substrates of P450, although P450 binding spectra are not often scrutinized to make this distinction. Therefore, the three nitrogenous ligands aniline, imidazole, and triazole were used as binding spectra standards with purified human CYP3A4 and CYP2C9, because their small size should not present any steric limitations in their accessing the heme prosthetic group. Next, the spectra of P450 with drugs containing the three nitrogenous groups were collected for comparison. The absolute spectra demonstrated that the red-shift of the low-spin Soret band is mostly dependent on the electronic properties of the nitrogen ligand since they tended to match their respective standards, aniline, imidazole, and triazole. On the other hand, difference spectra seemed to be more sensitive to the steric properties of the ligand because they facilitated comparison of the spectral amplitudes achieved with the drugs versus those with the standard nitrogen ligands. Therefore, difference spectra may help reveal "weak" coordination to the heme that results from suboptimal orientation or ligand binding to more remote locations within the P450 active sites.

Interaction of new sulfaphenazole derivatives with human liver cytochrome p450 2Cs: structural determinants required for selective recognition by CYP 2C9 and for inhibition of human CYP 2Cs.

A series of new derivatives of sulfaphenazole (SPA), in which the NH(2) and phenyl substituents of SPA are replaced by various groups or in which the sulfonamide function of SPA is N-alkylated, were synthesized in order to further explore CYP 2C9 active site and to determine the structural factors explaining the selectivity of SPA for CYP 2C9 within the human P450 2C subfamily. Compounds in which the NH(2) group of SPA was replaced with R(1) = CH(3), Br, CH = CH(2), CH(2)CH = CH(2), and CH(2)CH(2)OH exhibited a high affinity for CYP 2C9, as shown by the dissociation constant of their CYP 2C9 complexes, K(s), which was determined by difference visible spectroscopy (K(s) between 0.1 and 0.4 microM) and their constant of CYP 2C9 inhibition (K(i) between 0.3 and 0.6 microM). This indicates that the CYP 2C9-iron(III)-NH(2)R bond previously described to exist in the CYP 2C9-SPA complex does not play a key role in the high affinity of SPA for CYP 2C9. Compounds in which the phenyl group of SPA was replaced with various aryl or alkyl R(2) substituents only exhibited a high affinity for CYP 2C9 if R(2) is a freely rotating and sufficiently electron-rich aryl substituent. Finally, compounds resulting from a N-alkylation of the SPA sulfonamide function (R(3) = CH(3), C(2)H(5), or C(3)H(7)) did not retain the selective inhibitory properties of SPA toward CYP 2C9. However, they are reasonably good inhibitors of CYP 2C8 and CYP 2C18 (IC(50) approximately 20 microM). These data allow one to better understand the structural factors that are important for selective binding in the CYP 2C9 active site. They also provide us with clues towards new selective inhibitors of CYP 2C8 and CYP 2C18.

A refined 3-dimensional QSAR of cytochrome P450 2C9: computational predictions of drug interactions.

A ligand-based model is reported that predicts the Ki values for cytochrome P450 2C9 (CYP2C9) inhibitors. This CoMFA model was used to predict the affinity of 14 structurally diverse compounds not in the training set and appears to be robust. The mean error of the predictions is 6 microM. The experimentally measured Ki values of the 14 compounds range from 0.1 to 48 microM. Leave-one-out cross-validated partial least-squares gives a q2 value of between 0.6 and 0.8 for the various models which indicates internal consistency. Random assignment of biological data to structure leads to negative q2 values. These models are useful in that they establish a pharmacophore for binding to CYP2C9 that can be tested with site-directed mutagenesis. These models can also be used to screen for potential drug interactions and to design compounds that will not bind to this enzyme with high affinity.

Identification of amino acid substitutions that confer a high affinity for sulfaphenazole binding and a high catalytic efficiency for warfarin metabolism to P450 2C19.

Human cytochrome P450s 2C9 and 2C19 metabolize many important drugs including tolbutamide, phenytoin, and (S)-warfarin. Although they differ at only 43 of 490 amino acids, sulfaphenazole (SFZ) is a potent and selective inhibitor of P450 2C9 with an IC50 and a spectrally determined binding constant, KS, of <1 microM. P450 2C19 is not affected by SFZ at concentrations up to 100 microM. A panel of CYP2C9/2C19 chimeric proteins was constructed in order to identify the sequence differences that underlie this difference in SFZ binding. Replacement of amino acids 227-338 in 2C19 with the corresponding region of 2C9 resulted in high-affinity SFZ binding (KS approximately 4 microM) that was not seen when a shorter fragment of 2C9 was substituted (227-282). However, replacement of amino acids 283-338 resulted in extremely low holoenzyme expression levels in Escherichia coli, indicating protein instability. A single mutation, E241K, which homology modeling indicated would restore a favorable charge pair interaction between K241 in helix G and E288 in helix I, led to successful expression of this chimera that exhibited a KS < 10 microM for SFZ. Systematic replacement of the remaining differing amino acids revealed that two amino acid substitutions in 2C19 (N286S, I289N) confer high-affinity SFZ binding (KS < 5 microM). When combined with a third substitution, E241K, the resulting 2C19 triple mutant exhibited a high cataltyic efficiency for warfarin metabolism with the relaxed stereo- and regiospecificity of 2C19 and a lower KM for (S)-warfarin metabolism (<10 microM) typical of 2C9.

The substrate binding site of human liver cytochrome P450 2C9: an NMR study.

Purified recombinant human liver cytochrome P450 2C9 was produced, from expression of the corresponding cDNA in yeast, in quantities large enough for UV-visible and 1H NMR experiments. Its interaction with several substrates (tienilic acid and two derivatives, lauric acid and diclofenac) and with a specific inhibitor, sulfaphenazole, was studied by UV-visible and 1H NMR spectroscopy. At 27 degrees C, all those substrates led to an almost complete conversion of CYP 2C9 to high-spin (S = 5/2) CYP 2C9-substrate complexes characterized by a Soret peak at 390 nm; their KD values varied between 1 and 42 microM. On the contrary, sulfaphenazole led to a low-spin (S = 1/2) CYP 2C9 complex upon binding of its NH2 group to CYP 2C9 iron. Interactions of the five substrates with the enzyme were studied by paramagnetic relaxation effects of CYP 2C9-iron(III) on the 1H NMR spectrum of each substrate. Distances between the heme iron atom and substrate protons were calculated from the NMR data, and the orientation of the substrate relative to iron was determined from those distances. Finally, a model for substrate positioning in the CYP 2C9 active site was constructed by molecular modeling studies under the constraint of the iron-proton distances. It points out two structural characteristics for a compound to be selectively recognized by CYP 2C9: (i) the presence of an anionic site able to establish an ionic bond with a putative cationic residue of the protein and (ii) the presence of an hydrophobic zone between the substrate hydroxylation site and the anionic site. Sulfaphenazole was easily included in that model; its very high affinity for CYP 2C9 is due to a third structural feature, the presence of its NH2 function which binds to CYP 2C9 iron.

Interaction of sulfaphenazole derivatives with human liver cytochromes P450 2C: molecular origin of the specific inhibitory effects of sulfaphenazole on CYP 2C9 and consequences for the substrate binding site topology of CYP 2C9.

The effects of sulfaphenazole, 1, on typical activities catalyzed by human cytochromes P450 of the 1A, 3A, and 2C subfamilies expressed in yeast were studied. 1 acts as a strong, competitive inhibitor of CYP 2C9 (K(i) = 0.3 +/- 0.1 microM); it is much less potent toward CYP 2C8 and 2C18 (K(i) = 63 and 29 microM, respectively) and fails to inhibit CYP 1A1, 1A2, 3A4, and 2C19. From difference visible spectroscopy experiments using microsomes of yeast expressing various human P450s, 1 selectively interacts only with CYP 2C9 with the appearance of a peak at 429 nm as expected for the formation of a P450 Fe(III)-nitrogenous ligand complex (Ks = 0.4 +/- 0.1 microM). Comparative studies of the spectral interaction and inhibitory effects of twelve compounds related to 1 with CYP 2C9 showed that the aniline function of 1 is responsible for the formation of the iron-nitrogen bond of the 429 nm-absorbing complex and is necessary for the inhibitory effects of 1. The study of two new compounds synthesized during this work, in which the N-phenyl group of 1 was replaced with either an ethyl group or a 3,4-dichlorophenyl group, showed that the presence of an hydrophobic substituent at position 1 of the pyrazole function of 1 is required for a strong interaction with CYP 2C9. A model for the binding of 1 in the CYP 2C9 active site is proposed; that takes into account three major interactions that should be at the origin of the high-affinity and specific inhibitory effects of 1 toward CYP 2C9: (i) the binding of its nitrogen atom to CYP 2C9 iron, (ii) an ionic interaction of its SO2N- anionic site with a cationic residue of CYP 2C9, and (iii) an interaction of its N-phenyl group with an hydrophobic part of the protein active site.

Interaction of human liver cytochromes P450 in vitro with LY307640, a gastric proton pump inhibitor.

The interactions in vitro of LY307640 with the cytochromes P450 (P450s) were studied using human liver microsomes, specific inhibitors of the P450s, and cDNA expressed enzymes. The kinetics of formation of the two major oxidative metabolites, desmethyl LY307640 and LY307640 sulfone, were determined using two human liver microsomal samples. The kinetic data indicated that high and low affinity sites were present for the production of both metabolites of LY307640. The Km(apparent) and Vmax(apparent) for desmethyl LY307640 formation by microsomes from human liver E (HL-E) for the high affinity site were 18.8 +/- 4.4 microM and 402 +/- 52 pmol product/min/mg protein. The high affinity site Km(apparent) and Vmax(apparent) for LY307640 sulfone formation by microsomes from HL-E were 4.4 +/- 2.1 microM and 81.8 +/- 18 pmol product/min/mg protein. The rates of desmethyl LY307640 and LY307640 sulfone formation by the high affinity site were determined using 14 human liver microsomal samples characterized for P450 marker catalytic activities and immunoquantified levels of the P450s. Rates of formation of desmethyl LY307640 significantly correlated with the immunoquantified levels of CYP 2C19 and the ability of the microsomes to 4'-hydroxylate S-mephenytoin. LY307640 sulfone formation significantly correlated with the immunoquantified levels of CYP 3A and the ability of the microsomes to 1'-hydroxylate midazolam. Inhibition studies and use of expressed cytochrome P450 systems confirmed the correlation data demonstrating that CYP 2C19 catalyzed the formation of desmethyl LY307640 and CYP 3A and catalyzed LY307640 sulfone formation. Further, LY307640 competitively inhibited S-mephenytoin 4'-hydroxylation and midazolam 1'-hydroxylation as did the structurally related compound, omeprazole. For the inhibition of S-mephenytoin 4'-hydroxylation and midazolam 1'-hydroxylation, LY307640 had higher Ki(apparent) values than that of omeprazole. These studies demonstrate that the high affinity enzymes which catalyze the formation of the desmethyl and sulfone metabolites of LY307640 are, respectively, CYP 2C19 and CYP 3A. In addition, the inhibition data suggest that LY307640 has less potential to inhibit the metabolism of CYP 2C19 substrates compared to omeprazole, and that LY307640 and omeprazole have a similarly low potential to inhibit the metabolism of CYP 3A substrates.

N2-glucuronidation and N4-acetylation of sulphaphenazole by the turtle Pseudemys scripta elegans.

After an oral dose of 100 mg of sulphaphenazole, the turtle Pseudemys scripta elegans excretes 27% of the compound unchanged and 3.8% as N4-acetylsulphaphenazole. The expected glucuronide conjugate, sulphaphenazole-N2-glucuronide, is not formed and excreted.

Selective inhibition of drug oxidation after simultaneous administration of two probe drugs, antipyrine and tolbutamide.

The effects of sulphaphenazole, cimetidine and primaquine on the disposition of antipyrine and tolbutamide in healthy volunteers have been investigated. The model substrates were administered simultaneously in order more clearly to define any selective effects of the potential inhibitors. Sulphaphenazole produced a significant increase in the half-life of tolbutamide (7.10 to 21.50 h) and a corresponding decrease in its clearance (0.260 to 0.084 ml.min-1.kg-1). Clearance to hydroxytolbutamide (OHTOL) and carboxytolbutamide (COOHTOL) was also significantly decreased. In contrast, sulphaphenazole had no effect on the disposition of antipyrine. Administration of cimetidine did not significantly alter the disposition of either model drug. However, a 1.6-times higher dose of cimetidine did increase the half lives both of tolbutamide and antipyrine (6.21 to 9.04 h and 14.2 to 19.2 h, respectively) and decrease their clearance (0.226 to 0.148 and 0.50 to 0.31 ml.min-1 kg-1, respectively). Clearance to OHTOL and hydroxymethylantipyrine (HMA) was reduced. A single dose of primaquine had no demonstrable effect on tolbutamide disposition whereas the half-life of antipyrine was increased (12.1 to 15.0 h) and its clearance decreased (0.63 to 0.38 ml.min-1.kg-1). The partial clearance to HMA, 4-hydroxyantipyrine (OHA) and norantipyrine (NORA) was also significantly reduced. The two main inferences are first, that tolbutamide and antipyrine are metabolised by different forms of cytochrome P-450, and second that a battery of model substrates is needed to investigate the inhibitory effects of a drug in man.

The effect of displacement from protein binding on serum and tissue fluid levels of cephazolin.

Displacement of cephazolin, a highly protein-bound beta-lactam antibiotic, by sulpha-phenazole was studied in vitro and in vivo. In vitro, the sulphonamide was effective in displacing the antibiotic from its binding sites at the concentration 100--1000 mumol 1(-1). In vivo, both the serum and the tissue fluid concentration of free cephazolin increased significantly in rats concomitantly treated with sulphaphenazole.

The effect of protein-binding on the excretion of three sulphonamide preparations in the milk of dairy cows, examined by chemical and microbiological methods.

The relationship between the protein-binding of sulphonamides and their excretion in the milk of dairy cows was studied using three preparations commercially available in Finland. After a preparations containing sulfadiazine and sulfadimidine was given intravenously to dairy cows the drugs were excreted into milk to a greater extent than in the case of sulfamethoxypyridazine and especially of sulfaphenazole given similarly. An inverse relationship was found between the degree of protein-binding in the serum and the excretion into milk. The antimicrobially active concentrations of sulphonamides in serum and milk persisted for less than 24 hours when the doses recommended by the manufacturers were used. From a pharmacological point of view the sulfadiazine-sulfadimidine combination seems to be the drug of choice. Although no traces of sulphonamides were detected 48 hours after the dosing, the question of milk residues could not be answered because the minimum detection level of the methods used in the study was approximately 1 microgram/ml. The IDF standard method for the detection of penicillin in milk is not suitable for the detection of sulphonamide residues in milk.