Identification of fungal dihydrouracil-oxidase genes by expression in Saccharomyces cerevisiae.

Analysis of predicted fungal proteomes revealed a large family of sequences that showed similarity to the Saccharomyces cerevisiae Class-I dihydroorotate dehydrogenase Ura1, which supports synthesis of pyrimidines under aerobic and anaerobic conditions. However, expression of codon-optimised representatives of this gene family, from the ascomycete Alternaria alternata and the basidiomycete Schizophyllum commune, only supported growth of an S. cerevisiae ura1Δ mutant when synthetic media were supplemented with dihydrouracil. A hypothesis that these genes encode NAD(P)+-dependent dihydrouracil dehydrogenases (EC 1.3.1.1 or 1.3.1.2) was rejected based on absence of complementation in anaerobic cultures. Uracil- and thymine-dependent oxygen consumption and hydrogen-peroxide production by cell extracts of S. cerevisiae strains expressing the A. alternata and S. commune genes showed that, instead, they encode active dihydrouracil oxidases (DHO, EC1.3.3.7). DHO catalyses the reaction dihydrouracil + O2 → uracil + H2O2 and was only reported in the yeast Rhodotorula glutinis (Owaki in J Ferment Technol 64:205-210, 1986). No structural gene for DHO was previously identified. DHO-expressing strains were highly sensitive to 5-fluorodihydrouracil (5F-dhu) and plasmids bearing expression cassettes for DHO were readily lost during growth on 5F-dhu-containing media. These results show the potential applicability of fungal DHO genes as counter-selectable marker genes for genetic modification of S. cerevisiae and other organisms that lack a native DHO. Further research should explore the physiological significance of this enigmatic and apparently widespread fungal enzyme.

Functional characterization of 21 allelic variants of dihydropyrimidinase.

Dihydropyrimidinase (DHP, EC 3.5.2.2), encoded by the gene DPYS, is the second enzyme in the catabolic pathway of pyrimidine and of fluoropyrimidine drugs such as 5-fluorouracil, which are commonly used in anticancer treatment; DHP catalyzes the hydrolytic ring opening of dihydrouracil and dihydro-5-fluorouracil. DPYS mutations are known to contribute to interindividual variations in the toxicity of fluoropyrimidine drugs, but the functional characterization of DHP allelic variants remains inadequate. In this study, in vitro analysis was performed on 22 allelic variants of DHP by transiently expressing wild-type DHP and 21 DHP variants in 293FT cells and characterizing their enzymatic activities by using dihydrouracil and dihydro-5-fluorouracil as substrates. DHP expression levels and oligomeric forms were determined using immunoblotting and blue native PAGE, respectively, and the stability of the DHP variants was assessed by examining the proteins in variant-transfected cells treated with cycloheximide or bortezomib. Moreover, three kinetic parameters, Km, Vmax, and intrinsic clearance (Vmax/Km), for the hydrolysis of dihydrouracil and dihydro-5-fluorouracil were determined. We found that 5/21 variants showed significantly decreased intrinsic clearance as compared to wild-type DHP, and that 9/21 variants were expressed at low levels and were inactive due to proteasome-mediated degradation. The band patterns observed in the immunoblotting of blue native gels corresponded to DHP activity, and, notably, 18/21 DHP variants exhibited decreased or null enzymatic activity and these variants also showed a drastically reduced ability to form large oligomers. Thus, detection of DPYS genetic polymorphisms might facilitate the prediction severe adverse effects of fluoropyrimidine-based treatments.

Urine Pyrimidine Metabolite Determination by HPLC Tandem Mass Spectrometry.

Pyrimidine diseases result from deficiencies in pyrimidine de novo synthesis, degradation, and salvage pathways. Enzymatic deficiencies in pyrimidine catabolism lead to mitochondrial neurogastrointestinal encephalopathy (MNGIE), pyrimidinuria, dihydropyrimidinuria, ureidopropionic aciduria, and other disorders. While MNGIE presents with gastrointestinal dysmotility, cachexia, and leukoencephalopathy, pyrimidinuria and dihydropyrimidinuria may show symptoms of epilepsy, autism, mental retardation, and dysmorphic features. The application of HPLC-MS/MS facilitates rapid screening of pyrimidine metabolites. Here we describe an LCMS method for determination of uracil, thymine, thymidine, dihydrouracil, and dihydrothymine that are diagnostic biomarkers of MNGIE, pyrimidinuria, and dihydropyrimidinuria.

Towards a test to predict 5-fluorouracil toxicity: Pharmacokinetic data for thymine and two sequential metabolites following oral thymine administration to healthy adult males.

The fluoropyrimidine drugs 5-fluorouracil and its oral prodrug capecitabine remain first line therapy for solid tumours of the neck, breast and colon. However, significant and unpredictable toxicity affects about 10-25% of patients depending upon the mode of 5-fluorouracil delivery. The pharmacokinetics of thymine (5-methyluracil) may provide an approach for screening for 5-fluorouracil toxicity, based on the rationale that thymine is a close structural analogue of 5-fluorouracil and is catabolized by the same enzymatic pathway. Oral thymine loading tests were performed on 12 healthy volunteers. Each subject was given a single oral dose of 250mg thymine in capsule form. Blood, urine and saliva samples were collected pre-dose and up to 5h post-dose. Concentrations of thymine, and its catabolites dihydrothymine and ß-ureidoisobutyrate were analysed by HPLC-tandem mass spectrometry in plasma, urine and saliva. The pharmacokinetic data of healthy volunteers were analysed assuming a non-compartmental model. Thymine peaked quickly (30-45min) in plasma to a maximum concentration of 170±185µg/L (mean±SD). Clearance was high (mean 57.9L/h/kg) exceeding normal human liver blood flow, suggesting low systemic bioavailability; urinary recovery of the thymine dose was low (<1%). Apparent formation rate-limited kinetics were observed for dihydrothymine, and the plasma concentration of dihydrothymine was consistently 10-fold higher than that of thymine. Plasma ß-ureidoisobutyrate concentrations, on the other hand, were similar to that of thymine. Genotyping confirmed that pathological mutations of the DPYD gene were absent. The urinary excretion ratio of thymine/dihydrothymine was informative of the maximum concentration. Saliva thymine was highly variable. These data are potentially useful as a basis for developing of a screening procedure to prospectively identify patients who are at risk of toxicity from fluoropyrimidine drugs.