Genetically-determined interaction between propafenone and low dose quinidine: role of active metabolites in modulating net drug effect.

1. Quinidine is a potent inhibitor of the genetically-determined debrisoquine 4-hydroxylation. Oxidation reactions of several other drugs, including the 5-hydroxylation of the new antiarrhythmic drug propafenone, depend on the isozyme responsible for debrisoquine 4-hydroxylation. 2. The effect of quinidine on the debrisoquine phenotype-dependent 5-hydroxylation and the pharmacological activity of propafenone was studied in seven 'extensive' metabolizers and two 'poor' metabolizers of the drug receiving propafenone for the treatment of ventricular arrhythmias. 3. In patients with the extensive metabolizer phenotype, quinidine increased mean steady-state plasma propafenone concentrations more than two fold, from 408 +/- 351 (mean +/- s.d.) to 1096 +/- 644 ng ml-1 (P less than 0.001), decreased 5-hydroxypropafenone concentrations from 242 +/- 196 to 125 +/- 97 ng ml-1 (P less than 0.02) and reduced propafenone oral clearance by 58 +/- 23%. 4. Despite these changes in plasma concentrations, electrocardiographic intervals and arrhythmia frequency were unaltered by quinidine coadministration, indicating that 5-hydroxypropafenone contributes to the pharmacologic effects of propafenone therapy in extensive metabolizers. 5. In contrasts, plasma concentrations of propafenone and 5-hydroxypropafenone remained unchanged in the two patients with the poor metabolizer phenotype. 6. Biotransformation of substrates for the debrisoquine pathway can be markedly perturbed by even low doses of quinidine; interindividual variability in drug interactions may have a genetic component.     

Disposition of oral and intravenous pravastatin in MRP2-deficient TR- rats.

The aim of this study was to characterize the role of the efflux transporter Mrp2 (Abcc2) in the pharmacokinetics of orally and intravenously administered pravastatin in rats. Eight Mrp2-deficient TR- rats and eight wild-type rats were given an oral dose of 20 mg/kg pravastatin. Four TR- animals and four wild-type animals were studied after intravenous administration of pravastatin (5 mg/kg). The TR(-) rats showed a 6.1-fold higher mean area under the plasma concentration-time curve (AUC) of pravastatin (p < 0.001) after oral administration and a 4.7-fold higher AUC (p < 0.01) after intravenous administration of pravastatin as compared with the wild-type animals. The mean systemic (total) clearance of pravastatin was 4.6-fold higher (39.2 versus 8.50 l/h/kg, p < 0.001) and the mean V 4.3-fold higher (14.1 versus 3.29 l/kg, p < 0.01) in the wild-type rats. The mean renal clearance of pravastatin in the TR(-) rats was 16.5-fold increased as compared with the wild-type animals (0.695 versus 0.042 l/h/kg, p < 0.05). The increased systemic exposure to oral pravastatin in the TR- rats was associated with a greater inhibitory effect on 3-hydroxy-3-methylglutaryl CoA reductase, as shown by smaller lathosterol to cholesterol concentration ratios. These results suggest that the reduced biliary pravastatin excretion in the Mrp2-deficient TR- rats is partly compensated for by increased urinary excretion of pravastatin. Furthermore, intestinal Mrp2 does not appear to play a major role in the oral absorption of pravastatin in normal rats.     

Cytochromes of the P450 2C subfamily are the major enzymes involved in the O-demethylation of verapamil in humans

The calcium channel blocker verapamil [2,8-bis-(3,4-dimethoxyphenyl)-6-methyl-2-isopropyl-6-azaoctanitrile] undergoes extensive biotransformation in man. We have previously demonstrated cytochrome P450 (CYP) 3A4 and 1A2 to be the enzymes responsible for verapamil N-dealkylation (formation of D-617 [2-(3,4-dimethoxyphenyl)-5-methylamino-2-isopropylvaleronitrile]), and verapamil N-demethylation (formation of norverapamil [2,8-bis(3,4-dimethoxyphenyl)-2-isopropyl-6-azaoctanitrile]), while there was no involvement of CYP3A4 and CYP1A2 in the third initial metabolic step of verapamil, which is verapamil O-demethylation. This pathway yields formation of D-703 [2-(4-hydroxy-3-methoxyphenyl)-8-(3,4-dimethoxyphenyl)-6-methyl-2-isopropyl-6-azaoctanitrile] and D-702 [2-(3,4-dimethoxyphenyl)-8-(4-hydroxy-3-methoxyphenyl)6-methyl-2-isopropyl-6-azaoctanitrile]. The enzymes catalyzing verapamil O-demethylation have not been characterized so far. We have therefore identified and characterized the enzymes involved in verapamil O-demethylation in humans by using the following in vitro approaches: (I) characterization of O-demethylation kinetics in the presence of the microsomal fraction of human liver, (II) inhibition of verapamil O-demethylation by specific antibodies and selective inhibitors and (111) investigation of metabolite formation in microsomes obtained from yeast strain Saccharomyces cerevisiae W(R), that was genetically engineered for stable expression of human CYP2C8, 2C9 and 2C18.In human liver microsomes (n=4), the intrinsic clearance (CL_int), as derived from the ratio of V _max/K_m, was significantly higher for O-demethylation to D-703 compared to formation of D-702 following incubation with racemic verapamil (13.9±1.0 vs 2.4±0.6 ml^*min^{-1 *}g^-1 mean±SD; p<0.05), S-Verapamil (16.8±3.3 vs 2.2±1.2 ml^* mini^*g^-1, p<0.05) and R-verapamil (12.1±2.9 vs 3.6 ±1.3 ml^*min^{-1 *} g^-1; p<0.05), thus indicating regioselectivity of verapamil O-demethylation process. The CL_int of D-703 formation in human liver microsomes showed a modest but significant degree of stereo selectivity (p<0.05) with a S/R-ratio of 1.41±0.17. Anti-LKM2 (anti-liver/kidney microsome) autoantibodies (which inhibit CYP2C9 and 2C19) and sulfaphenazole (a specific CYP2C9 inhibitor) reduced the maximum rate of formation of D-703 by 81.5±4.5% and 45%, that of D-702 by 52.7±7.5% and 72.5%, respectively. Both D-703 and D-702 were formed by stably expressed CYP2C9 and CYP2C18, whereas incubation with CYP2C8 selectively yielded D-703.In conclusion, our results show that enzymes of the CYP2C subfamily are mainly involved in verapamil O-demethylation. Verapamil therefore has the potential to interact with other drugs which inhibit or induce these enzymes.     

Temporomandibular joint arthrography following surgical treatment of internal derangements

Arthrograms of the temporomandibular joint were obtained in 20 symptomatic joints that had previous reconstructive arthroplasty with disk repositioning because of internal derangements. Preoperative arthrograms were available for comparison in 18 joints. Symptoms resulting in a postoperative arthrogram included pain, limited ability to open the mouth, and clicking of the joints. Postoperative arthrographic findings included limited anterior translation of the condyle (90%), irregularity in outline of the intraarticular contrast agent (60%), a conical configuration of the posterior recess (25%), decreased size of the joint (28%), anterior displacement of the meniscus (25%), and perforated meniscus (15%). Many of these findings may have resulted from fibrosis and scarring, which may be a response to intraarticular bleeding. The mechanism by which the fibrosis causes the postsurgical arthrographic features is discussed.     

Cross-linking of surface IgM or IgD causes differential biological effects in spite of overlap in tyrosine (de)phosphorylation profile.

Although displaying similar amounts of surface IgM and IgD, ECH 408-1 cells only succumb to apoptosis after cross-linking of IgM (not IgD), suggesting that different signaling pathways couple to both receptors. Immunoprecipitation studies revealed the presence of several proteins selectively associated with IgM and IgD, thus ruling out that the lack of inhibitory signaling mediated by IgD might be due to membrane expression in the absence of associated proteins belonging to the B cell receptor complex. 32P metabolic labeling and immunoprecipitation studies demonstrated that IgM and IgD are associated with phosphoproteins of 32-33 kDa in an isotype-specific fashion. Kinetic analyses of tyrosine kinase activity showed that cross-linking of surface IgM or IgD resulted in the rapid (1-3 min) phosphorylation of several protein substrates on tyrosine residues, followed by a dephosphorylation step. Isotype-specific changes of the phosphorylation status specifically affected molecules in the 32-33 kDa range, i.e. IgM (not IgD) cross-linking affected a approximately 32-kDa protein, whereas IgD (not IgM) cross-linking induced phosphorylation of a protein exhibiting a slightly lower mobility (33 kDa). These results suggest that isotype-specific immunoglobulin-associated molecules could be involved in the second messenger cascade leading to different biological effects upon IgM and IgD cross-linking.     

T-lymphocyte subsets in the embryonic spleen undergoing a graft-versus-host reaction.

Allogeneic immunocompetent T cells injected into chicken embryos induce a graft-versus-host reaction (GVHR) whose most prominent manifestation is splenic hyperplasia. The highly inbred CC and CB strains of chickens used here are, respectively, homozygous for the B4 or B12 MHC haplotypes. By means of a panel of immunological reagents, including alloantisera and monoclonal antibodies against public domains of the T-cell receptor, CD4, CD8, and the inducible interleukin-2-receptor light chain (CD25), it is shown that the bulk of cells in the enlarged spleen are of host origin and do not express markers typical of mature T or B lymphocytes. Among recipient splenocytes, the quantitatively most important population consists of TCR alpha beta-TCR gamma delta- CD4-CD8+CD25+ (TCR0) lymphocytes. Donor cells encountered in the spleen prevalently exhibit a TCR alpha beta+CD4+CD8-CD25+ phenotype and proliferate in vivo. The data demonstrate that nonspecific host and potentially specific donor-derived cellular elements contribute to splenomegaly.     

Linomide,a novel immunomodulator that prevents death in four models of septic shock

Intravenous injections of 50 μ.g Staphylococcus aureus enterotoxin B (SEB) or bacterial lipopolysaccharide (LPS) are lethal, provided that mice are simultaneously sensitized with either N-galactosamine (GalN) or the anti-glucocorticoid RU-38486. Similar to the synthetic glucocorticoid (GC) receptor agonist dexamethasone, pharmacological doses of the immunomodulator linomide (quinoline-3-carboxamide) prevent death in all four models of lethal septic shock (LPS + GalN, LPS + RU-38486, SEB + GalN, and SEB + RU-38486) and inhibit the secretion of tumor necrosis factor, one of the major intermediate effector molecules of SEB and LPS toxicity. In this system, cyclosporine A (CsA), although effective in suppressing SEB toxicity, fails to counteract the lethal effect of LPS. This observation, together with the fact that linomide acts in the presence of excess amounts of GC receptor antagonist, indicates that linomide functions in a different way to that of known immunosuppressive agents like CsA and GC.     

Apoptosis and apoptosis-associated perturbations of peripheral blood lymphocytes during HIV infection: comparison between AIDS patients and asymptomatic long-term non-progressors

This study was designed to compare the degree of lymphocyte apoptosis and Fas-Fas ligand (FasL) expression in AIDS patients and long-term non-progressors (LTNPs) and correlate these parameters with apoptosis-associated perturbations in lymphocyte function. LTNPs had a lower frequency of apoptotic CD4+ and CD8+ T cells compared with subjects with AIDS. This correlated with a lower frequency of cells expressing Fas and FasL. The frequency of selected lymphocyte populations exhibiting a disrupted mitochondrial transmembrane potential (DeltaPsim) and increased superoxide generation was lower in LTNPs than in patients with AIDS; these abnormalities were associated with lower levels of caspase-1 activation in LTNPs. The results indicate a significantly reduced level of apoptosis and apoptosis-associated parameters in LTNPs than in patients developing AIDS. Based on these findings, a crucial role for mitochondria can be predicted in the process of lymphocyte apoptosis during the evolution of AIDS.     

Expansion and clonal deletion of peripheral T cells induced by bacterial superantigen is independent of the interleukin-2 pathway

Injection of the bacterial superantigen Staphylococcus aureus enterotoxin B (SEB) into mice provokes a rapid expansion and subsequent contraction of the pool of SEB-reactive T cells bearing T cell receptor (TcR) V_β8 gene products. Given that interleukin 2 (IL-2) stimulates proliferation, abolishes anergy, and counteracts apoptotic cell death in T cells in vitro, we tested whether the IL-2 synthesis inhibitor cyclosporin A (CsA) or a vaccinia virus recombinant releasing high amounts of human IL-2 modulate SEB responses in vivo. Surprisingly, neither IL-2 nor CsA were able to change the in vivo kinetics and magnitude of SEB-induced expansion, unresponsiveness to SEB, and peripheral clonal deletion of T cells expressing products of the SEB-reactive TcR V_β8 gene family. In accord with these in vivo observations, IL-2 is incapable of reversing “anergy” and apoptotic cell death of V_β8⁺ SEB-reactive T cells isolated from SEB-primed mice in vitro. Accordingly, upon SEB injection V_β8⁺ T cells expand rapidly, without expressing IL-2 receptor (IL-2R)α chains in vivo, although SEB induces IL-2R α in vitro. Altogether, these results indicate that the IL-2/IL-2R-mediated pathway is not involved in T cell repertoire modulation by bacterial superantigens. Moreover, the data suggest that unresponsiveness of V_β8⁺ T cells from SEB-primed mice is not a reversible process, but involves an unreversible commitment to programmed cell death. Absence or presence of IL-2 responsiveness could be a hallmark to distinguish truly reversible anergy and peripheral clonal deletion.     

Impact of P450 genetic polymorphism on the first-pass extraction of cardiovascular and neuroactive drugs

This review highlights the present knowledge on the CYP2D6 (sparteine/debrisoquine) and the CYP2C19 (mephenytoin) polymorphisms. The relevant mutations at genomic level affecting protein expression and function and consequences for first-pass metabolism and effects of cardiovascular and neuroactive drugs are highlighted. In vitro techniques for identification of metabolic steps catalyzed by polymorphic enzymes will be discussed as well as drug-drug interactions related to CYP2D6 and CYP2C19. The importance of the CYP2D6 polymorphism arises from the fact that this enzyme, which is involved in metabolism of more than 50 drugs, is not active in about 8% of a Caucasian population. This group is named poor metabolizers in contrast to the remainder of the population called extensive metabolizers. Depending on the pharmacokinetic and pharmacodynamic properties of the administered drug and its metabolites elevated concentrations of the parent compound can result in an increased risk of toxicity or loss of therapeutic effects in poor metabolizers. On the other hand ultrarapid metabolizers of CYP2D6 might require higher doses than recommended in order to achieve therapeutic drug levels. Moreover, consequences of polymorphic CYP2C19 expression, which is not active in 20% of Orientals and 3% of Caucasians, for drug disposition will be outlined.