Leucopenia resulting from a drug interaction between azathioprine or 6-mercaptopurine and mesalamine, sulphasalazine, or balsalazide.

AIM: We evaluated the effect of coadministration of sulphasalazine, mesalamine, and balsalazide on the pharmacokinetics and pharmacodynamics of azathioprine and 6-mercaptopurine. METHODS: Thirty four patients with Crohn's disease receiving azathioprine or 6-mercaptopurine were enrolled in an eight week non-randomised parallel group drug interaction study and treated with mesalamine 4 g/day, sulphasalazine 4 g/day, or balsalazide 6.75 g/day. The primary outcome measure was the occurrence of clinically important leucopenia during the study, defined separately as total leucocyte counts < 3.0 x 10(9)/l and < or = 3.5 x 10(9)/l. Whole blood 6-thioguanine nucleotide concentrations were determined. RESULTS: Three patients could not be evaluated for the primary outcome measure. In the remaining 31 patients, the frequency of total leucocyte counts < 3.0 and < or = 3.5 were: 1/10 and 5/10 in the mesalamine group; 1/11 and 6/11 in the sulphasalazine group; and 0/10 and 2/10 in the balsalazide group. There were significant increases in mean whole blood 6-thioguanine nucleotide concentrations from baseline at most time points in the mesalamine and sulphasalazine groups but not in the balsalazide group. CONCLUSIONS: In patients with Crohn's disease receiving azathioprine or 6-mercaptopurine, coadministration of mesalamine, sulphasalazine, and possibly balsalazide results in an increase in whole blood 6-thioguanine nucleotide concentrations and a high frequency of leucopenia.

Measurement of thiopurine methyltransferase activity and azathioprine metabolites in patients with inflammatory bowel disease.

BACKGROUND: Measurement of 6-thioguanine nucleotide concentrations may be useful for optimising treatment with azathioprine and 6-mercaptopurine. METHODS: We conducted a study of 170 patients with inflammatory bowel disease treated with azathioprine or 6-mercaptopurine to determine the relationship between 6-thioguanine nucleotide concentrations and both disease activity, as measured by the inflammatory bowel disease questionnaire (active disease < 170, remission > or = 170) and leucopenia. Blood was submitted for whole blood 6-thioguanine nucleotide concentration and leucocyte count. RESULTS: Mean (SD) inflammatory bowel disease questionnaire score was 176 (32). There was no correlation between inflammatory bowel disease questionnaire scores and 6-thioguanine nucleotide concentrations (r(s) = -0.09, p = 0.24). Median 6-thioguanine nucleotide concentrations in 56 patients with active disease and 114 patients in remission were similar (139 v 131 pmol/8 x 10(8) red blood cells; p = 0.26). There was no correlation between 6-thioguanine nucleotide concentrations and leucocyte counts. CONCLUSIONS: In patients with inflammatory bowel disease treated with azathioprine or 6-mercaptopurine, 6-thioguanine nucleotide concentrations did not correlate with disease activity, as measured by the inflammatory bowel disease questionnaire, or leucocyte count. These findings are discrepant with most previous studies, possibly due to selection of responding patients who tolerated the medications. A prospective, randomised, dose optimisation trial using 6-thioguanine nucleotide concentrations is warranted.

Improved methods for determining the concentration of 6-thioguanine nucleotides and 6-methylmercaptopurine nucleotides in blood.

The conversion of the cytotoxic and immunosuppressive 6-mercaptopurine (6MP) to the active 6-thioguanine nucleotides (6TGN) is necessary for clinical efficacy of 6MP and its prodrug azathioprine. Another metabolite, 6-methylmercaptopurine nucleotide (6MMPN), is formed via a competing pathway by thiopurine methyl transferase. The concentrations of 6TGN and 6MMPN are measured in washed erythrocytes as a surrogate to the intracellular levels of these metabolites in the target tissues. Analysis of 6TGN and 6MMPN in multi-center clinical studies is more complicated because of the requirement to wash erythrocytes. In this investigation, we found no differences in the concentrations of 6TGN and 6MMPN in blood versus washed erythrocytes in samples obtained from patients taking therapeutic doses of oral 6MP or azathioprine for inflammatory bowel disease. We concluded that whole blood could be used for the analysis of these analytes, thus saving sample preparation time. We also found that the erythrocyte 6TGN concentration in blood at ambient temperature declined 2-4% per day, a loss that can be avoided by shipping blood samples frozen. The loss of 6TGN in blood stored at approximately -80 degrees C was 1% after 1 week and 12% after 24 weeks, indicating the analyte was moderately stable. 6MMPN in blood did not significantly change after 24 weeks of storage at approximately -80 degrees C. In addition, the sensitivity of the 6TGN assay was improved by modifying the HPLC conditions, which made the method more suitable for quantifying low levels of 6TGN in human intestinal biopsy samples and blood.

Overview--in vitro inhibition of aldehyde dehydrogenase by disulfiram and metabolites.

Disulfiram (DSF) has found extensive use in the aversion therapy treatment of recovering alcoholics. It is known that DSF or a metabolite irreversibly inhibits aldehyde dehydrogenase (ALDH). However, the actual mechanism of inhibition is still not known. In this work we describe the in vitro interactions of DSF, as well as a principal metabolite S-methyl-N,N-diethylthiocarbamoyl sulfoxide (MeDTC-SO), with both recombinant rat liver mitochondrial monomeric ALDH (rmALDH) and homotetrameric rmALDH. We show that DSF directly inhibits rmALDH (IC(50)=36.4 microM) by inducing the formation of an intramolecular disulfide bond. We also demonstrate by HPLC-MS analysis of a Glu-C digest of DSF-treated rmALDH that the intramolecular disulfide bridge formed involves two of the three cysteines located at the active site of the enzyme. Using a combination of HPLC-MS and HPLC-MS/MS, we further show that the electrophilic metabolite MeDTC-SO also inhibits rmALDH (IC(50)=4.62 microM). We isolate and identify a carbamoylated peptide at Cys(302) with the sequence FNQGQC(301)C(302)C(303). Hence we show that MeDTC-SO exhibits its inhibitory effect by covalently modifying the -SH side-chain of Cys(302), present at the active site rmALDH. Finally we show using SEC-MS that both DSF and MeDTC-SO do not prevent formation of the homotetramer of rmALDH, but inhibit the enzyme by acting directly at the active site of specific monomers of rmALDH.

In vivo inhibition of aldehyde dehydrogenase by disulfiram.

Disulfiram (DSF) has found extensive use in the aversion therapy treatment of recovering alcoholics. Although it is known to irreversibly inhibit hepatic aldehyde dehydrogenase (ALDH), the specific mechanism of in vivo inhibition of the enzyme by the drug has not yet been determined. In this report, we demonstrate a novel, but simple and rapid method for structurally characterizing in vivo derived protein-drug adducts by linking on-line sample processing to HPLC-electrospray ionization mass spectrometry (HPLC-MS) and HPLC-tandem mass spectrometry (HPLC-MS/MS). Employing this approach, rats were administered DSF, and their liver mitochondria were isolated and solubilized. Both native and in vivo DSF-treated mitochondrial ALDH (rmALDH) were purified in one-step with an affinity cartridge. The in vivo DSF-treated rmALDH showed 77% inhibition in enzyme activity as compared to that of the control. Subsequently, the control and DSF-inhibited rmALDH were both subjected to HPLC-MS analyses. We were able to detect two adducts on DSF-inhibited rmALDH as indicated by the mass increases of approximately 71 and approximately 100 Da. To unequivocally determine the site and structure of these adducts, on-line pepsin digestion-HPLC-MS and HPLC-MS/MS were performed. We observed two new peptides at MH(+)=973.7 and 1001.8 in the pepsin digestion of DSF-inhibited enzyme. These two peptides were subsequently subjected to HPLC-MS/MS for sequence determination. Both peptides possessed the sequence FNQGQC(301)C(302)C(303), derived from the enzyme active site region, and were modified at Cys(302) by N-ethylcarbamoyl (+71 Da) and N-diethylcarbamoyl (+99 Da) adducts. These findings indicated that N-dealkylation may be an important step in DSF metabolism, and that the inhibition of ALDH occurred by carbamoylation caused by one of the DSF metabolites, most likely S-methyl-N,N-diethylthiocarbamoyl sulfoxide (MeDTC-SO).

Determination of in vivo adducts of disulfiram with mitochondrial aldehyde dehydrogenase.

Extensive use for disulfiram (DSF) has been found in the aversion therapy treatment of recovering alcoholics. Although it is known to irreversibly inhibit hepatic aldehyde dehydrogenase (ALDH), the specific mechanism of in vivo inhibition of the enzyme by the drug has not been determined yet. We have demonstrated in this report a novel, but simple and rapid method for structurally characterizing in vivo derived protein-drug adducts by linking on-line sample processing to HPLC-electrospray ionization mass spectrometry (HPLC-MS) and HPLC-tandem mass spectrometry (HPLC-MS/MS). Employing this approach, rats were administered DSF, and their liver mitochondria were isolated and solubilized. Both native and in vivo DSF-treated mitochondrial ALDH (mALDH) were purified in one step with an affinity cartridge. The in vivo DSF-treated mALDH showed 77% inhibition in enzyme activity as compared with that of the control. Subsequently, the control and DSF-inhibited mALDH were both subjected to HPLC-MS analyses. We were able to detect two adducts on DSF-inhibited mALDH, as indicated by the mass increases of approximately 71 and approximately 100 Da. To unequivocally determine the site and structure of these adducts, on-line pepsin digestion-HPLC-MS and HPLC-MS/MS were performed. We observed two new peptides at MH(+) = 973.7 and MH(+) = 1001.8 in the pepsin digestion of DSF-inhibited enzyme. These two peptides were subsequently subjected to HPLC-MS/MS for sequence determination. Both peptides possessed the sequence FNQGQC(301)C(302)C(303), derived from the enzyme active site region, and were modified at Cys(302) by N-ethylcarbamoyl (+71 Da) and N-diethylcarbamoyl (+99 Da) adducts. These findings indicated that N-dealkylation may be an important step in DSF metabolism, and that the inhibition of ALDH occurred by carbamoylation caused by one of the DSF metabolites, most likely S-methyl-N,N-diethylthiocarbamoyl sulfoxide (MeDTC-SO). Finally, there was no evidence of the presence of an intramolecule disulfide bridge modification on the peptide FNQGQCCC.

Metabolism of a disulfiram metabolite, S-methyl N,N-diethyldithiocarbamate, by flavin monooxygenase in human renal microsomes.

S-Methyl N,N-diethyldithiocarbamate (MeDDC), a metabolite of the alcohol deterrent disulfiram, is converted to MeDDC sulfine and then S-methyl N,N-diethylthiocarbamate sulfoxide, the proposed active metabolite in vivo. Several isoforms of CYP450 and to a lesser extent flavin monooxygenase (FMO) metabolize MeDDC in the liver. The human kidney contains FMO1 and several isoforms of CYP450, including members of the CYP3A, CYP4A, CYP2B, and CYP4F subfamilies. In this study the metabolism of MeDDC by the human kidney was examined, and the enzymes responsible for this metabolism were determined. MeDDC was incubated with human renal microsomes from five donors or with insect microsomes containing human FMO1, CYP4A11, CYP3A4, CYP3A5, or CYP2B6. MeDDC sulfine was formed at 5 microM MeDDC by renal microsomes at a rate of 210 +/- 50 pmol/min/mg of microsomal protein (mean +/- S.D., n = 5) and by FMO1 at 7.6 +/- 0.2 nmol/min/nmol (n = 3). Oxidation of 5 microM MeDDC was negligible by all CYP450 tested (< or =0.03 nmol/min/nmol). Inhibition of FMO by methimazole or heat diminished MeDDC sulfine formation 75 to 89% in renal microsomes. Inhibition of CYP450 in renal microsomes by N-benzylimidazole or antibody to the CYP450 NADPH reductase had no effect on MeDDC sulfine production. Benzydamine N-oxidation, a probe for FMO activity, correlated with MeDDC sulfine formation in renal microsomes (r = 0.951, p = 0.013). The K(M) values for MeDDC sulfine formation by renal microsomes and recombinant human FMO1 were 11 and 15 microM, respectively. These results demonstrate a role for the kidney and FMO1 in the metabolism of MeDDC in humans.

Effect of enzyme inhibitors on protein quaternary structure determined by on-line size exclusion chromatography-microelectrospray ionization mass spectrometry.

Aldehyde dehydrogenases (ALDH) are a family of enzymes primarily involved in the oxidation of various aldehydes. Most ALDH enzymes derived from mammalian sources have been shown to exist as homotetramers, consisting of four identical subunits of approximately 54 kDa. The presence of the homotetramer appears to be necessary for enzyme activity. In this study, recombinant rat liver mitochondrial ALDH (rmALDH) was inhibited in vitro with four different inhibitors, namely, disulfiram (MW, 296.5), prunetin (MW, 284.3), benomyl (MW, 290.3), and N-tosyl-L-phenylalanine chloromethyl ketone (TPCK) (MW, 351.8). Subsequently, inhibited rmALDH was analyzed by a novel approach of on-line size exclusion chromatography-microelectrospray ionization-mass spectrometry (SEC-muESI-MS) to examine the noncovalent quaternary structural stability of the inhibited enzyme. Analysis of native rmALDH by SEC-muESI-MS revealed predominantly the homotetramer (Mr = approximately 217,457 Da, +/- 0.01%) with some in-source, skimmer-induced dissociation to afford monomer (Mr = approximately 54,360 Da, +/- 0.01%). Both disulfiram and prunetin inhibited rmALDH by >70% and >90%, respectively, but did not disrupt the quaternary structure of rmALDH. Furthermore, there was no detectable change within experimental error (+/- 0.01%) of the disulfiram or the prunetin homotetramers (Mr = approximately 217,448 Da and Mr = approximately 217,446 Da). This may possibly indicate that inhibition occurred via formation of intramolecular disulfide bond at the enzyme active site, or weak affinity noncovalent binding. In contrast, benomyl-inhibited rmALDH homotetramer (>90% inhibition) exhibited a Mr = approximately 217,650 Da (+/- 0.01%) corresponding to two butylcarbamoyl adducts on two of the four enzyme subunits. The skimmer-induced monomer afforded a mixture of unmodified rmALDH (Mr = approximately 54,365 Da, +/- 0.01%) and butylcarbamoylated enzyme (Mr = approximately 54,459 Da, +/- 0.01%). Finally, TPCK (>90% inhibition) modified all four subunits of rmALDH to give Mr = approximately 218,646 Da (+/- 0.01%). In all four cases while significant enzyme inhibition occurred, no destabilization of the quaternary complex was detected.

Drug-grapefruit juice interactions.

Grapefruit juice, a beverage consumed in large quantities by the general population, is an inhibitor of the intestinal cytochrome P-450 3A4 system, which is responsible for the first-pass metabolism of many medications. Through the inhibition of this enzyme system, grapefruit juice interacts with a variety of medications, leading to elevation of their serum concentrations. Most notable are its effects on cyclosporine, some 1,4-dihydropyridine calcium antagonists, and some 3-hydroxy-3-methylglutaryl coenzyme A reductase inhibitors. In the case of some drugs, these increased drug concentrations have been associated with an increased frequency of dose-dependent adverse effects. The P-glycoprotein pump, located in the brush border of the intestinal wall, also transports many cytochrome P-450 3A4 substrates, and this transporter also may be affected by grapefruit juice. This review discusses the proposed mechanisms of action and the medications involved in drug-grapefruit juice interactions and addresses the clinical implications of these interactions.

Rat liver constitutive and phenobarbital-inducible cytosolic aldehyde dehydrogenases are highly homologous proteins that function as distinct isozymes.

Rat liver contains two class 1 aldehyde dehydrogenases (ALDHs): a constitutive isozyme (ALDH1) and a phenobarbital-inducible isozyme (ALDH-PB). Defining characteristics of mammalian class 1 ALDHs include a homotetrameric structure, high expression in liver, sensitivity to the inhibitor disulfiram, and high activity for the oxidation of retinal. It is often presumed that ALDH-PB is the rat ortholog of mammalian ALDH1, and the identity of rat ALDH-PB is commonly interchanged with ALDH1. In this study, we characterized recombinant rat liver cytosolic ALDH1 and ALDH-PB. Previous reports indicate that ALDH-PB is a homodimer; however, we found by mass spectrometry and gel electrophoresis that it is a homotetramer. ALDH1 mRNA was highly expressed in untreated rat liver, while ALDH-PB had very weak expression, in contrast to a previous report that ALDH-PB mRNA is expressed in untreated rat liver. Rat liver ALDH1 had a high affinity for retinal (K(m) = 0.6 microM), while no oxidation by ALDH-PB could be detected with 20 microM retinal. ALDH1 was more efficient at oxidizing acetaldehyde, propionaldehyde, and benzaldehyde and was more sensitive to disulfiram inhibition. We conclude that rat liver ALDH1 is the ortholog of mammalian liver ALDH1. Furthermore, despite a high level of sequence identity and classification as a class 1 ALDH, ALDH-PB does not function like ALDH1. ALDH-PB is not merely an inducible ALDH1 isozyme; it is a distinct ALDH isozyme.

Role of disulfiram in the in vitro inhibition of rat liver mitochondrial aldehyde dehydrogenase.

The alcohol aversion therapy drug disulfiram has been shown to inhibit hepatic aldehyde dehydrogenase (ALDH), one of the key enzymes involved in ethanol metabolism. It is believed by some that disulfiram could be one of the active inhibitors in vivo. However, the actual interaction between disulfiram and ALDH remains ambiguous. We report here that when disulfiram inhibited recombinant rat liver mitochondrial ALDH (rlmALDH) in vitro, no significant molecular mass increase was detected during the first 30 min as determined by on-line HPLC-electrospray ionization mass spectrometry (LC-MS). This indicated that the inhibition in vitro was not caused directly by covalent adduct formation on the enzyme. We subsequently subjected both control and disulfiram-inhibited rlmALDH to Glu-C proteolytic digestion. LC-MS analysis of the Glu-C digestion of disulfiram-inhibited enzyme revealed that one peptide of M(r) = 4821, which contained the putative active site of the enzyme, exhibited a mass decrease of 2 amu as compared with the same peptide found in the Glu-C digestion of the control (M(r) = 4823). We believe that the loss of 2 amu indicated that inhibition of rlmALDH in vitro was due to formation of an intramolecular disulfide bond between two of the three adjacent cysteines in the active site, possibly via a very rapid and unstable mixed disulfide interchange reaction. Further confirmation of the intramolecular disulfide bond formation came from the fact that by adding dithiothreitol (DTT) we were able to recover partial enzyme activity. In addition, the peptide of M(r) = 4821 observed in the Glu-C digestion of the disulfiram-treated ALDH reverted to M(r) = 4823 after treatment with DTT, which indicated that the disulfide bond was reduced. We, thereby, conclude that disulfiram inhibited rlmALDH by forming an intramolecular disulfide, possibly via a fast intermolecular disulfiram interchange reaction.

Methylphenidate: its pharmacology and uses.

Methylphenidate is a commonly used medication in the United States. This central nervous system stimulant has a mechanism of action distinct from that of amphetamine. The Food and Drug Administration has approved methylphenidate for the treatment of attention-deficit/hyperactivity disorder and narcolepsy. Treatment with methylphenidate has been advocated in patients with traumatic brain injury and stroke, cancer patients, and those with human immunodeficiency virus infection. Placebo-controlled trials have documented its efficacy as an adjunctive agent in the treatment of depression and pain. This article reviews the current understanding of the mechanism of action and efficacy of methylphenidate in various clinical conditions.

Identification of the protein-drug adduct formed between aldehyde dehydrogenase and S-methyl-N,N-diethylthiocarbamoyl sulfoxide by on-line proteolytic digestion high performance liquid chromatography electrospray ionization mass spectrometry.

Disulfiram has been used clinically as an aversion therapy treatment for recovering alcoholics. One of its metabolites, S-methyl-N, N-diethylthiocarbamoyl sulfoxide (MeDTC-SO), is currently believed by some to be the active metabolite in vivo. We demonstrate in this report that MeDTC-SO is a potent irreversible inhibitor of recombinant rat liver mitochondrial aldehyde dehydrogenase (rlmALDH), the enzyme responsible for oxidizing acetaldehyde formed during ethanol metabolism. Recombinant rlmALDH was inhibited by MeDTC-SO after in vitro incubation with an IC(50) = 4.62 microM. The inhibition of rlmALDH was found to be accompanied by a concomitant increase of approximately 100 Da to the molecular mass of the native enzyme as determined by on-line high performance liquid chromatography (HPLC) electrospray ionization mass spectrometry (LC/MS), indicating that a covalent modification has occurred. To determine the site and structure of this covalent adduct, we developed a novel approach to characterize specific protein-drug interactions by linking a proteolytic enzyme digestion cartridge on-line with LC/MS. The on-line pepsin digestion LC/MS of MeDTC-SO-inhibited rlmALDH revealed an ion at MH(2)(2+) = 500.9, which was not present in the pepsin digestion of the non-inhibited enzyme. This peptide was tentatively attributed to the putative active site peptide (FNQGQC(301)C(302)C(303)) plus the adduct. This peptide was subjected to analysis by LC/MS/MS, which allowed us to determine that the covalent modification was associated with a single carbamoyl adduct at Cys-302, which has been shown to be the active site nucleophile of the enzyme.

Clinical outcome and pharmacokinetics after addition of low-dose cyclosporine to methotrexate: a case study of five patients with treatment-resistant inflammatory bowel disease.

INTRODUCTION: This study reports the clinical outcome, toxicity, and methotrexate pharmacokinetics after the addition of low-dose cyclosporine to methotrexate in patients with ulcerative colitis or Crohn's disease. METHODS: Three patients with steroid-refractory ulcerative colitis and two patients with steroid refractory Crohn's disease who failed monotherapy with subcutaneous methotrexate 25 mg/week for 16 weeks were treated with the combination of methotrexate and low-dose oral cyclosporine (3 mg/kg/day) for an additional 16 weeks. Clinical response was measured with the Inflammatory Bowel Disease Questionnaire (IBDQ) score. Concentrations of erythrocyte methotrexate, plasma methotrexate, and plasma 7-hydroxymethotrexate were also determined. RESULTS: Both patients with Crohn's disease withdrew from the study for toxicity (headaches, seizure). The three patients with ulcerative colitis experienced clinical improvement with a mean increase in the IBDQ score from 164 to 190 points, p = 0.01. The mean serum creatinine in the three patients who completed the study increased from 0.9 mg/dL at baseline to 1.2 mg/dL at week 16. p = 0.04. One patient developed hypertension. There was no significant change from baseline in the concentrations of erythrocyte methotrexate, plasma methotrexate, and plasma 7-hydroxymethotrexate. CONCLUSIONS: Combination therapy with methotrexate and low-dose oral cyclosporine did not alter methotrexate pharmacokinetics and resulted in high rates of cyclosporine-associated toxicity.

Intravenous azathioprine in severe ulcerative colitis: a pilot study.

OBJECTIVE: Azathioprine use in acute ulcerative colitis has been limited by its perceived long onset of action. The aim of this study was to determine the safety and clinical effect of an i.v. loading dose of azathioprine in the setting of severe steroid refractory ulcerative colitis. METHODS: Nine hospitalized patients with severe steroid refractory ulcerative colitis were enrolled. Patients 1-3 received 20 mg/kg i.v. azathioprine over 36 h. Patients 4-6 received 40 mg/kg i.v. azathioprine over 36 h. Patients 7-9 received 40 mg/kg i.v. azathioprine as three 8-h infusions over 3 days. Clinical remission was defined as steroid withdrawal and an Ulcerative Colitis Disease Activity Index score of 0. The Inflammatory Bowel Disease Questionnaire was obtained at each visit. White blood cell concentrations and erythrocyte concentrations of 6-thioguanine were obtained. RESULTS: Five of nine patients (56%) had a response and avoided colectomy. Three of nine patients (33%) met the definition for clinical remission. Response was seen within 4 wk. The mean 6-thioguanine concentration for those five patients at 12 wk after infusion was 148.2 pmol/8 x 10(8). Two patients had transient leukopenia and one had transient hepatotoxicity. CONCLUSIONS: Intravenous azathioprine appears to be safe and of clinical benefit in inducing response and avoiding colectomy in severe steroid refractory ulcerative colitis. Data from an i.v. azathioprine trial in Crohn's disease suggests oral dosing alone may obtain the same results. The role of oral dosing alone in severe ulcerative colitis and the role of azathioprine metabolite levels in monitoring efficacy should be investigated further.

A randomized dose-response and pharmacokinetic study of methotrexate for refractory inflammatory Crohn's disease and ulcerative colitis.

BACKGROUND AND AIMS: The optimum initial dose of methotrexate for steroid-requiring inflammatory bowel disease is not known. AIM: To compare directly the efficacy and toxicity of methotrexate 15 and 25 mg/week, and to explore the value of methotrexate blood levels as predictors of outcome. METHODS: A 16-week randomized single-blind comparison of subcutaneous methotrexate 15 or 25 mg/week was performed in 32 patients with steroid-requiring Crohn's disease or ulcerative colitis. Patients who did not respond to methotrexate 15 mg/week were further studied for an additional 16 weeks on methotrexate 25 mg/week. Blood was drawn every 2 weeks for methotrexate levels. RESULTS: After 16 weeks, 17% of patients in each group achieved remission; 39% of patients randomized to 15 mg/week and 33% of patients randomized to 25 mg/week improved (P=N.S. ). Clinical status improved in four out of 11 patients after methotrexate dose escalation from 15 to 25 mg/week. Toxicity was not different between the treatment groups. Methotrexate blood levels did not predict efficacy or toxicity. CONCLUSIONS: For induction of remission in steroid-requiring inflammatory bowel disease, subcutaneous methotrexate at initial doses of 15 and 25 mg/week are equally efficacious. At these doses, response is not associated with blood methotrexate concentrations.

Inhibition of interleukin-1-stimulated NF-kappaB RelA/p65 phosphorylation by mesalamine is accompanied by decreased transcriptional activity.

Nuclear factor kappaB (NF-kappaB) is an inducible transcription factor that regulates genes important in immunity and inflammation. The activity of NF-kappaB is highly regulated: transcriptionally active NF-kappaB proteins are sequestered in the cytoplasm by inhibitory proteins, IkappaB. A variety of extracellular signals, including interleukin-1 (IL-1), activate NF-kappaB by inducing phosphorylation and degradation of IkappaB, allowing nuclear translocation and DNA binding of NF-kappaB. Many of the stimuli that activate NF-kappaB by inducing IkappaB degradation also cause phosphorylation of the NF-kappaB RelA (p65) polypeptide. The transactivating capacity of RelA is positively regulated by phosphorylation, suggesting that in addition to cytosolic sequestration by IkappaB, phosphorylation represents another mechanism for control of NF-kappaB activity. In this report, we demonstrate that mesalamine, an anti-inflammatory aminosalicylate, dose-dependently inhibits IL-1-stimulated NF-kappaB-dependent transcription without preventing IkappaB degradation or nuclear translocation and DNA binding of the transcriptionally active NF-kappaB proteins, RelA, c-Rel, or RelB. Mesalamine was found to inhibit IL-1-stimulated RelA phosphorylation. These data suggest that pharmacologic modulation of the phosphorylation status of RelA regulates the transcriptional activity of NF-kappaB, independent of nuclear translocation and DNA binding. These findings highlight the importance of inducible phosphorylation of RelA in the control of NF-kappaB activity.

Plasma and rectal adenosine in inflammatory bowel disease: effect of methotrexate.

In animal models, the antiinflammatory mechanism of action of methotrexate has been attributed to elevation of the extracellular concentration of the endogenous autocoid, adenosine. Our goal was to determine if methotrexate elevates adenosine concentrations in plasma and at the site of disease in patients with inflammatory bowel disease. In 10 patients with Crohn's disease or ulcerative colitis, rectal adenosine and plasma adenosine concentrations were measured before and immediately after a subcutaneous injection of methotrexate, 15 or 25 mg. The mean predose rectal adenosine concentration of 2.4 mumol/l was not significantly different from the postdose concentration of 2.1 mumol/l, p = 0.17, (paired two-tailed t test). Rectal adenosine concentration tended to correlate with rectal endoscopic disease activity, r = 0.59, p = 0.067 (Spearman rank order correlation). After methotrexate injection, neither the mean daily plasma adenosine concentration, nor the plasma adenosine at any individual time point, were significantly different from preinjection values. In patients with inflammatory bowel disease, an injection of methotrexate in the clinically effective dose range does not raise rectal or plasma adenosine concentrations. A role for adenosine as the mediator of the antiinflammatory action of methotrexate is not supported.

Roles of FMO and CYP450 in the metabolism in human liver microsomes of S-methyl-N,N-diethyldithiocarbamate, a disulfiram metabolite.

BACKGROUND: The conversion of S-methyl-N,N-diethyldithiocarbamate (MeDDC) to MeDDC sulfine is the first step after methylation in the metabolic pathway of disulfiram, an alcohol deterrent, to its ultimate active metabolite. Various isoforms of CYP450 have recently been shown to catalyze this reaction, but the involvement of flavin monooxygenase (FMO) in this metabolism in humans has not been evaluated. In this study we examined the ability of recombinant human FMO3 in insect microsomes to metabolize MeDDC, and investigated the relative roles of FMO and CYP450 in the metabolism of MeDDC in human liver microsomes. METHODS: HPLC-mass spectrometry was used to identify the products of MeDDC formed by human liver microsomes and by recombinant human FMO3. MeDDC metabolism in human liver microsomes was studied by using either heat inactivation to inhibit FMO, or N-benzylimidazole (NBI) or antibodies to the CYP450 NADPH reductase to inhibit CYP450. RESULTS: We confirmed by HPLC-mass spectrometry that MeDDC sulfine was the major product of MeDDC formed by human liver microsomes and by FMO3. Recombinant FMO3 was an efficient catalyst for the formation of MeDDC sulfine (5.3+/-0.2 nmol/min/mg, mean+/-SEM, n = 6). Inhibition studies showed MeDDC was metabolized primarily by CYP450 in human liver microsomes at pH 7.4, with a 10% contribution from FMO (total microsomal activity 3.1+/-0.2, n = 17). In the course of this work, methyl p-tolyl sulfide (MTS), sulfoxidation of which is used by some investigators as a specific probe for FMO activity, was found to be a substrate for both FMO and CYP450 in human liver microsomes. CONCLUSIONS: Our results prove that MeDDC sulfine is the major product of MeDDC oxidation in human liver microsomes, MeDDC is a good substrate for human FMO3, and MeDDC is metabolized in human liver microsomes primarily by CYP450. We also showed that use of MTS sulfoxidation as an indicator of FMO activity in microsomes is valid only in the presence of a CYP450 inhibitor, such as NBI.

Lack of effect of intravenous administration on time to respond to azathioprine for steroid-treated Crohn's disease. North American Azathioprine Study Group.

BACKGROUND & AIMS: Azathioprine is effective for Crohn's disease but acts slowly. A loading dose may decrease the time to response. METHODS: A placebo-controlled study was conducted in patients with active Crohn's disease despite prednisone treatment. Patients were randomized to a 36-hour infusion of azathioprine, 40 mg/kg (51 patients), or placebo (45 patients) followed by oral azathioprine, 2 mg/kg, for 16 weeks. Prednisone was tapered over 5 weeks. The primary outcome measure was complete remission at week 8, defined by discontinuation of prednisone and a Crohn's Disease Activity Index of