Bioactivation of Trimethoprim to Protein-Reactive Metabolites in Human Liver Microsomes.

The formation of drug-protein adducts via metabolic activation and covalent binding may stimulate an immune response or may result in direct cell toxicity. Protein covalent binding is a potentially pivotal step in the development of idiosyncratic adverse drug reactions (IADRs). Trimethoprim (TMP)-sulfamethoxazole (SMX) is a combination antibiotic that commonly causes IADRs. Recent data suggest that the contribution of the TMP component of TMP-SMX to IADRs may be underappreciated. We previously demonstrated that TMP is bioactivated to chemically reactive intermediates that can be trapped in vitro by N-acetyl cysteine (NAC), and we have detected TMP-NAC adducts (i.e., mercapturic acids) in the urine of patients taking TMP-SMX. However, the occurrence and extent of TMP covalent binding to proteins was unknown. To determine the ability of TMP to form protein adducts, we incubated [(14)C]TMP with human liver microsomes in the presence and absence of NADPH. We observed protein covalent binding that was NADPH dependent and increased with incubation time and concentration of both protein and TMP. The estimated covalent binding was 0.8 nmol Eq TMP/mg protein, which is comparable to the level of covalent binding for several other drugs that have been associated with covalent binding-induced toxicity and/or IADRs. NAC and selective inhibitors of CYP2B6 and CYP3A4 significantly reduced TMP covalent binding. These results demonstrate for the first time that TMP bioactivation can lead directly to protein adduct formation, suggesting that TMP has been overlooked as a potential contributor of TMP-SMX IADRs.

Red blood cell folate concentrations and polyglutamate distribution in juvenile arthritis: predictors of folate variability.

OBJECTIVE: Methotrexate (MTX) has several enzymatic targets in the folate pathway. To better understand the variability in response to MTX, we characterized the interindividual variability of intracellular folate pools in children with juvenile arthritis (JA) and determined clinical and genetic contributors to this variability. STUDY DESIGN: This exploratory single-center cross-sectional study evaluated 93 patients with JA not currently receiving MTX. Whole blood, plasma, and erythrocyte folate concentrations were determined after deconjugation and analyzed through reversed-phase separation and stable isotope dilution tandem mass spectrometry. Folate polyglutamates were measured in red blood cell lysates using an ion-pair reversed phase chromatography tandem mass spectrometry method. RESULTS: Intracellular concentrations of 5-methyl-tetrahydrofolate (5-CH3-THF) and 5,10-methenyl-tetrahydrofolate varied approximately 20-fold and 80-fold, respectively. The polyglutamated forms of 5-CH3-THF as a percentage of total 5-CH3-THF (5-CH3-THFGlun) were also measured. Hierarchical clustering of 5-CH3-THFGlun revealed two groups, each with two distinct clusters. There was an inverse relationship between 5-CH3-THFGlun chain length and plasma 5-CH3-THF concentrations. A subgroup of patients with a historical intolerance to MTX had significantly lower cellular folate concentrations (P<0.0001). In univariate analyses, clinical variables including sex, age, and folate supplementation in addition to variations in MTHFR, MTR, and SLC25A32 were associated with differential intracellular folate redox concentrations. Multivariate analysis further supported the association of single nucleotide polymorphisms in SLC25A32, MTHFR, and MTR with variability in intracellular 5-CH3-THF and 5,10-methenyl-tetrahydrofolate concentrations, respectively. CONCLUSION: Measurement of intracellular folate isoforms may contribute toward a better understanding of individual MTX effects in JA. Clinical variables in addition to genotypic differences beyond MTHFR may additionally explain differential intracellular folate concentrations and variable responses to MTX.

Vitamin D related genes in lung development and asthma pathogenesis.

BACKGROUND: Poor maternal vitamin D intake is a risk factor for subsequent childhood asthma, suggesting that in utero changes related to vitamin D responsive genes might play a crucial role in later disease susceptibility. We hypothesized that vitamin D pathway genes are developmentally active in the fetal lung and that these developmental genes would be associated with asthma susceptibility and regulation in asthma. METHODS: Vitamin D pathway genes were derived from PubMed and Gene Ontology surveys. Principal component analysis was used to identify characteristic lung development genes. RESULTS: Vitamin D regulated genes were markedly over-represented in normal human (odds ratio OR 2.15, 95% confidence interval CI: 1.69-2.74) and mouse (OR 2.68, 95% CI: 2.12-3.39) developing lung transcriptomes. 38 vitamin D pathway genes were in both developing lung transcriptomes with >63% of genes more highly expressed in the later than earlier stages of development. In immortalized B-cells derived from 95 asthmatics and their unaffected siblings, 12 of the 38 (31.6%) vitamin D pathway lung development genes were significantly differentially expressed (OR 3.00, 95% CI: 1.43-6.21), whereas 11 (29%) genes were significantly differentially expressed in 43 control versus vitamin D treated immortalized B-cells from Childhood Asthma Management Program subjects (OR 2.62, 95% CI: 1.22-5.50). 4 genes, LAMP3, PIP5K1B, SCARB2 and TXNIP were identified in both groups; each displays significant biologic plausibility for a role in asthma. CONCLUSIONS: Our findings demonstrate a significant association between early lung development and asthma-related phenotypes for vitamin D pathway genes, supporting a genomic mechanistic basis for the epidemiologic observations relating maternal vitamin D intake and childhood asthma susceptibility.