The transcriptional response of human macrophages to murabutide reflects a spectrum of biological effects for the synthetic immunomodulator.

The synthetic immunomodulator murabutide (MB) presents multiple biological activities with minimal toxicity in animals and in man. Although MB is known to target cells of the reticuloendothelial system and to regulate cytokine synthesis, the molecular mechanisms underlying several of its biological effects are still largely unknown. In an effort to define cellular factors implicated in the immunomodulatory and HIV-suppressive activities of MB, we have undertaken profiling the regulated expression of genes in human monocyte-derived macrophages (MDM) following a 6-h stimulation with this synthetic glycopeptide. Oligonucleotide microarray analysis was performed on RNA samples of differentiated MDM from four separate donors, using probe sets corresponding to 1081 genes. We have identified, in a reproducible fashion, the enhanced expression of 40 genes and the inhibition of 16 others in MB-treated MDM. These regulated genes belonged to different families of immune mediators or their receptors, transcription factors and kinases, matrix proteins and their inhibitors, ion channels and transporters, and proteins involved in cell metabolic pathways. Additional verification of the regulated expression of selected genes was carried out using Northern blots or the quantification of released proteins in MDM cultures. The profile of MB-regulated genes in MDM provides a molecular basis for some of its previously reported biological activities, and reveals new set of genes targeted by the immunomodulator suggesting potential application in novel therapeutic indications.

CYP2E1 degradation by in vitro reconstituted systems: role of the molecular chaperone hsp90.

One major mode of regulation of cytochrome P450 2E1 (CYP2E1) is at the posttranscriptional level, since many low-molecular-weight compounds stabilize the enzyme against proteolysis by the proteasome complex. In an in vitro system containing human liver microsomes, degradation of CYP2E1 in the microsomes required addition of the human liver cytosol fraction in a reaction sensitive to inhibitors of the proteasome complex. It is not clear how CYP2E1 in the microsomal membrane becomes accessible to the cytosolic proteasome. Since molecular chaperones play a role in protein folding and degradation, the possible role of heat shock proteins in CYP2E1 degradation by this reconstituted system was evaluated. Degradation of CYP2E1 required ATP; ATP-gammaS, a nonhydrolyzable analogue of ATP, did not catalyze CYP2E1 degradation by the cytosol fraction, indicating that ATP hydrolysis is required. Geldanamycin, a specific inhibitor of hsp90, inhibited the degradation of microsomal CYP2E1 by the cytosol fraction. Control experiments indicated that geldanamycin was not a substrate/ligand of CYP2E1 nor did it prevent microsomal lipid peroxidation, a process which increases CYP2E1 turnover. Inhibition by geldanamycin was prevented by molybdate. Both of these compounds have been shown to promote alterations in hsp90 structure and to modulate hsp90-protein interactions. The proteasome activity in the cytosol, as assayed by the cleavage of a fluorogenic peptide, was enhanced when ATP was added and inhibited by 30-40% by geldanamycin, effects that are similar, although less pronounced, to the degradation of CYP2E1 by the cytosol. Purified 20S proteasome could catalyze degradation of CYP2E1; however, in an assay using equal peptidase activity, the cytosol fraction was much more effective than the 20S proteasome in promoting CYP2E1 degradation. Immunodepletion of hsp90 from the cytosol resulted in prevention of the degradation of CYP2E1, a reaction that was reversed by the addition of pure hsp90 to this cytosol. These results suggest that in addition to the proteasome, the cytosol fraction contains other factors that modulate the efficiency of CYP2E1 degradation. The sensitivity to geldanamycin and molybdate and the immunodepletion experiments suggest that hsp90 is one of these factors that interact with CYP2E1 and/or with the proteasome to promote the degradation of this microsomal P450.

NADPH-dependent microsomal electron transfer increases degradation of CYP2E1 by the proteasome complex: role of reactive oxygen species.

Increased levels of cytochrome P450 2E1 (CYP2E1) produced by low-molecular-weight compounds is mostly due to stabilization of the enzyme against proteolytic degradation. CYP2E1, in the absence of substrate or ligand, normally has a short half-life, but the factors which regulate CYP2E1 turnover or trigger its rapid degradation are not known. Since CYP2E1 is active in producing reactive oxygen species, experiments were carried out to evaluate whether reactive oxygen species modulated the degradation of CYP2E1. CYP2E1 present in human liver microsomes was very stable. Addition of the cytosol fraction produced degradation of CYP2E1, and this was enhanced when NADPH was present in the reaction system. Antioxidants or iron chelators which prevent lipid peroxidation, prevented the degradation of CYP2E1 by the cytosolic fraction. Similarly, diphenyleneiodonium chloride, which inhibits NADPH-dependent electron transfer, prevented the degradation of CYP2E1, as did 4-methylpyrazole, a ligand which increases the level of CYP2E1. If microsomes were first incubated with NADPH for 30 min, followed by the addition of these agents, there was no protection against CYP2E1 degradation. Lactacystin, an inhibitor of the proteasome, decreased the degradation of CYP2E1. In intact HepG2 cells transduced to express CYP2E1, proteasome inhibitors elevated steady-state levels of CYP2E1. Steady-state levels of CYP2E1 were increased by about 50% when the cells were incubated with trolox. Trolox decreased the rate of loss of CYP2E1 protein when the cells were treated with cycloheximide. These results suggest that NADPH-dependent production of reactive oxygen species may result in oxidative modification of CYP2E1, followed by rapid degradation of the labilized CYP2E1 by the proteasome complex. It is interesting to speculate that one consequence of the high rates of production of reactive oxygen species by CYP2E1 is its own labilization and subsequent rapid degradation, and this may be a regulatory mechanism to prevent high levels of the enzyme from accumulating within the cell.

Noninvolvement of CYP2E1 in the (omega-1)-hydroxylation of fatty acids in rat kidney microsomes.

Pyrazole, acetone, and ethanol are known to induce cytochrome P450 2E1 (CYP2E1) and fatty acid (omega-1)-hydroxylation in rat liver microsomes. However, the nature of the P450 enzyme involved in this (omega-1)-hydroxylation has not been clearly established in extrahepatic tissues such as kidney. Four enzymatic activities (hydroxylations of chlorzoxazone, 4-nitrophenol, and two fatty acids) were assayed in kidney microsomal preparations of rats treated with CYP2E1 inducers. Per os treatment resulted in large increases (threefold to fivefold) in the chlorzoxazone and 4-nitrophenol hydroxylations, and up to a ninefold increase when ethanol was administered by inhalation. However, neither the omega-hydroxylation nor the (omega-1)-hydroxylation of fatty acids was modified. Immunoinhibition specific to CYP2E1 did not significantly decrease the omega and (omega-1)-lauric acid hydroxylations, while the polyclonal anti-CYP4A1 antibody inhibited in part both the omega- and (omega-1)-hydroxylations. Chemical inhibitions using either CYP2E1 competitive inhibitors (such as chlorzoxazone, DMSO, and ethanol) or P450 mechanism-based inhibitors (such as diethyldithiocarbamate and 17-octadecynoic acid) led to a partial inhibition of the hydroxylations. All these results suggest that fatty acid (omega-1)-hydroxylation, a highly specific probe for CYP2E1 in rat and human liver microsomes, is not mediated by CYP2E1 in rat kidney microsomes. In contrast to liver, where two different P450 enzymes are involved in fatty acid omega- and (omega-1)-hydroxylations, the same P450 enzyme, mainly a member of the CYP4A family, was involved in both hydroxylations in rat renal microsomes.

Both cytochromes P450 2E1 and 3A are involved in the O-hydroxylation of p-nitrophenol, a catalytic activity known to be specific for P450 2E1.

4-Nitrophenol 2-hydroxylation activity was previously shown to be mainly catalyzed by P450 2E1 in animal species and humans. As this chemical compound is widely used as an in vitro probe for P450 2E1, this study was carried out to test its catalytic specificity. First, experiments were carried out on liver microsomes and hepatocyte cultures of rat treated with different inducers. Liver microsomes from pyrazole- and dexamethasone-treated rats hydroxylated p-nitrophenol with a metabolic rate increased by 2.5- and 2.7-fold vs control. Dexamethasone treatment increased the hepatic content of P450 3A but not that of P450 2E1. Two specific inhibitors of P450 3A catalytic activities, namely, ketoconazole and troleandomycin (TAO), inhibited up to 50% of 4-nitrophenol hydroxylation in dexamethasone-treated rats but not in controls. Hepatocyte cultures from dexamethasone-treated rats transformed p-nitrophenol into 4-nitrocatechol 7.8 times more than controls. This catalytic activity was inhibited by TAO. Similarly, hepatocyte cultures from pyrazole-treated rats hydroxylated p-nitrophenol with a metabolic ratio increased by about 8-fold vs control. This reaction was inhibited by diethyl dithiocarbamate and dimethyl sulfoxide, both inhibitors of P450 2E1. Second, the capability of human P450s other than P450 2E1 to catalyze the formation of 4-nitrocatechol was examined in a panel of 13 human liver microsomes. Diethyl dithiocarbamate and ketoconazole reduced 4-nitrophenol hydroxylase activity by 77% (+/- 11) and 13% (+/- 16), respectively. Furthermore, the residual activity following diethyl dithiocarbamate inhibition was significantly correlated with seven P450 3A4 catalytic activities. Finally, the use of human cell lines genetically engineered for expression of human P450s demonstrated that P450 2E1 and 3A4 hydroxylated 4-nitrophenol with turnovers of 19.5 and 1.65 min-1, respectively. In conclusion, P450 3A may make a significant contribution to 4-nitrophenol hydroxylase activity in man and rat.

Induction of liver and kidney CYP1A1/1A2 by caffeine in rat.

Caffeine metabolism by hepatic microsomal P450 enzymes is well documented in experimental animals and humans. However, its induction effect on P450 enzymes has not been thoroughly studied. In a preliminary experiment, the time-dependent incubation of 1 mM caffeine with rat hepatocyte culture resulted in an increase of its own metabolic rate. The dose-dependent expression of rat hepatic and renal cytochromes (CYP) 1A1/1A2 was then investigated after per os administration of caffeine. P450 expression was monitored by using specific enzymatic activities and Northern blot analysis. Caffeine caused a dose-dependent elevation of hepatic CYP1A1/1A2 activities in microsomal preparations, which ranged from 1.7- to 6-fold for ethoxyresorufin O-deethylase and 3- to 8.9-fold for methoxy-resorufin O-demethylase according to the dose regimen of 50 and 150 mg caffeine/kg/day for 3 days, respectively. Northern blot analysis demonstrated that caffeine treatment increased liver CYP1A1 and CYP1A2 mRNA levels over the dose regimen of 50-150 mg caffeine/kg/day for 3 days, respectively. The result of this study demonstrates that caffeine increases its own metabolism in a dose-dependent manner and induces CYP1A1/1A2 expression through either transcriptional activation or mRNA stabilization.

P450 2E1 expression in liver, kidney, and lung of rats treated with single or combined inducers.

Ethanol consumption combined with smoking increase the risk of cancer in many tissues. Such a mechanism implies the involvement of cytochrome P450 alcohol (CYP2E1), which is regulated by numerous xenobiotics. The combination of P450 2E1 inducers (acetone or pyridine) and 3-methylcholanthrene during rat treatment was shown to decrease the liver P450 2E1 content while it enhanced its expression in kidney. It is suggested that this differential tissue response helps explain the organotropy of nitrosamine carcinogenicity.

Effect of the length of alkyl chain on the cytochrome P450 dependent metabolism of N-diakylnitrosamines.

Liver microsomes from control and treated rats (P4501A, 2B, 2E1-induced) metabolize at variable metabolic rates eight N-nitroso-di-n-alkylamines, including five symmetrical (N-nitroso-dimethyl, -diethyl, -dipropyl, -dibutyl and -diamyl-amines) and four asymmetrical (N-nitrosomethylethyl, methylpropyl, methylbutyl, and methylamyl-amines), into aldehydes. Thus, the longer the alkyl chain of symmetrical N-nitrosamines, the smaller was the metabolic rate of the corresponding aldehyde formation. The chain length of the alkyl group of N-nitroso-methylalkylamines modified the oxidation of the alkyl moiety: the oxidation by CYP2E1 decreased as the n-alkyl chain length increased and conversely for the oxidation by CYP1A and CYP2B. Finally, the longer the n-alkyl chain length of asymmetrical N-nitrosamines, the greater was the oxidation of methyl groups.

CYP1A2 and 2E1 expression in rat liver treated with combined inducers (3-methylcholanthrene and ethanol).

The effects of combined ethanol and 3-methylcholanthrene treatment on rat hepatic cytochrome CYP1A2 and CYP2E1 expression were evaluated. Such a treatment attempts to mimic the simultaneous consumption of ethanol and cigarette smoke. Treatments involving 3-methylcholanthrene and combined ethanol + 3-methylcholanthrene decreased both CYP2E1 expression at the mRNA level (0.6 and 0.4 fold versus controls, respectively) and protein level (0.6 and 0.9 fold versus controls, respectively), while dramatically increasing CYP1A2 expression. Furthermore, combined treatment provokes a synergistic induction of CYP1A2 expression as determined by its catalytic activity and protein content.

Interaction between two probes used for phenotyping cytochromes P4501A2 (caffeine) and P4502E1 (chlorzoxazone) in humans.

The first steps in the metabolism of caffeine and chlorzoxazone are primarily catalysed by CYP1A2 and CYP2E1, respectively. Accordingly, these compounds have been developed as metabolic probes for non-invasive phenotyping of these two P450s. Their specificities, however, have been shown to overlap. In this study, 140 mg of caffeine and 500 mg of chlorzoxazone were administered alone or together in 16 healthy subjects under standardized conditions. The metabolites of these two probes were measured in the blood and also in the urine for caffeine. CYP1A2 activity was determined either by the paraxanthine/caffeine ratio in the blood or by the usual caffeine metabolic ratio in the urine. The CYP2E1 activity was determined by the 6-OH-chlorzoxazone/chlorzoxazone ratio in blood. CYP1A2 activities measured in blood and urine were highly significantly correlated. CYP2E1 activity was not modified when chlorzoxazone was given together with caffeine. In contrast, an inhibition of CYP1A2 by chlorzoxazone was demonstrated by a 16% decrease in the caffeine metabolic ratio in urine when both caffeine and chlorzoxazone were given together. Under the same conditions, the paraxanthine/caffeine ratio in plasma also decreased by about 20%. These results were confirmed in vitro by the incubation of 1 mM caffeine with human hepatic liver microsomes in the presence of 0.4 mM chlorzoxazone. The overall metabolism of caffeine decreased by 38% compared to controls incubated without chlorzoxazone.(ABSTRACT TRUNCATED AT 250 WORDS)

Caffeine increases its own metabolism through cytochrome P4501A induction in rats.

Caffeine is one of the most widely used - and maybe abused - xenobiotic compounds in the world. If numerous pharmacological properties of caffeine have been reported, the effects of caffeine treatment on the hepatic drug-metabolizing enzyme system have been scarcely studied. Pretreatment of rats for 3 days with 150 mg/kg/day of caffeine dramatically increased P4501A and P4502B dependent catalytic activities determined in vitro. Furthermore, N-demethylations and C-8 oxidation of caffeine were increased by about 2 fold by caffeine treatment. Immunoblot analysis demonstrated that the liver contents of P4501A2 and P4502B1/2B2, known to be involved in these monooxygenase activities, increased also by about 2 fold. Cytochrome P4503A1 and 2E1 were not modified. Taken together, there data suggest that caffeine increases its own metabolism through P4501A induction.

Evidence that cytochrome P450 2E1 is involved in the (omega-1)-hydroxylation of lauric acid in rat liver microsomes.

The present study examined changes in hepatic CYP2E1 content and (omega-1)-hydroxylation of lauric acid in rats treated with pyridine, pyrazole, acetone, ethanol and 3-methylcholanthrene. The (omega-1)-hydroxylase activity was strongly correlated with chlorzoxazone 6-hydroxylation (r = 0.76) and 4-nitrophenol-hydroxylase (r = 0.91). Both these activities are carried out by CYP2E1. (omega-1) hydroxylase activity was inhibited by ethanol (Ki = 3.5 mM), dimethylsulfoxide and diethyldithiocarbamate. Furthermore, polyclonal antibody directed against rat CYP2E1 inhibited (omega-1)-hydroxylation by more than 90% while it had no effect on the omega-hydroxylation. These results suggest that the (omega-1)-hydroxylation of lauric acid is mediated principally by the CYP2E1 enzyme in rat liver microsomes.

Both cytochromes P450 2E1 and 1A1 are involved in the metabolism of chlorzoxazone.

Chlorzoxazone, a centrally acting muscle relaxant, was previously shown to be hydroxylated on carbon 6 specifically by cytochrome P450 2E1. Accordingly, this drug has been proposed as a potential noninvasive in-vivo probe for screening the hepatic P450 2E1 activity. This study was carried out to test the specificity of such a substrate when first experiments conducted by using human hepatocyte cultures showed that the chlorzoxazone 6-hydroxylation activity increased after 3-methylcholanthrene treatment of cells. Indeed, the ability of both rat and human hepatocytes to metabolize chlorzoxazone significantly increased after treatments by 3-methylcholanthrene alone or plus ethanol, suggesting the involvement of P450 1A enzymes in this oxidative reaction. Identical results were obtained by in-vivo treatment of rats with four inducers of P450 1A enzymes, namely, beta-naphthoflavone, isosafrole, Arochlor 1254, and 3-methylcholanthrene. Furthermore, the chlorzoxazone 6-hydroxylation activity was inhibited by both alpha-naphthoflavone and dimethyl sulfoxide, both known to inhibit P450 1A and P450 2E1 activities, respectively. Finally, the use of yeasts genetically engineered for expression of human P450 1A1, 1A2, 2C9, and 3A4 demonstrated that P450 1A1 was significantly involved in this catalytic activity. In conclusion, these results taken together suggest that chlorzoxazone should be used with precaution as in-vivo tool for evaluating P450 2E1. However, the relative Km of P450 1A1 and 2E1 for chlorzoxazone and, on the other hand, the relative levels of these two enzymes in the human liver suggest that P450 2E1 would generally be the major form metabolizing chlorzoxazone in-vivo.