Metabolism of 5-fluorouracil to an N-cholyl-2-fluoro-beta-alanine conjugate: previously unrecognized role for bile acids in drug conjugation.

Recently we demonstrated clinically significant levels of a previously unrecognized metabolite of the anticancer drug 5-fluorouracil (FUra) in bile of cancer patients. In the present study, reanalysis of bile from these patients demonstrated the presence of not one but two previously unrecognized metabolites. The major unrecognized metabolite was purified by reversed-phase HPLC, after which its molecular weight was determined by fast-atom-bombardment mass spectrometry to be 497. The similarity in HPLC retention times and molecular weights of this FUra derivative and the bile acids N-cholylglycine (Mr 465) and N-cholyltaurine (Mr 515), along with the structural similarity of the FUra catabolite 2-fluoro-beta-alanine and the amino acids glycine and taurine, led to the hypothesis that this metabolite could be a conjugate of 2-fluoro-beta-alanine and cholic acid. This hypothesis was tested and confirmed by hydrolyzing the purified metabolite by cholylglycine hydrolase after which: 2-fluoro-beta-alanine was demonstrated by using a sensitive HPLC technique capable of resolving all of the known putative FUra metabolites, and unconjugated cholic acid was identified by both GC and GC-MS. Additionally, chemically synthesized N-cholyl-2-fluoro-beta-alanine was shown to cochromatograph on HPLC and TLC with the purified biliary metabolite. In summary, this study demonstrates a unique, so far as we know, pathway of drug metabolism in man in which an amino acid drug metabolite is conjugated with cholic acid and eliminated into the bile. Furthermore, the finding that 2-fluoro-beta-alanine is conjugated to bile acids may provide some insight into the mechanism of cholestasis that is frequently observed after administration of fluoropyrimidine by hepatic arterial infusion.

Clinical pharmacokinetics of 5-fluorouracil and its metabolites in plasma, urine, and bile.

Kinetics of 5-fluorouracil (FUra) and FUra metabolites in plasma and urine were investigated in 10 cancer patients following i.v. bolus administration of 500 mg/m2 FUra with 600 microCi of [6-3H]FUra. Biliary excretion was examined in two patients with external biliary catheters. Quantitation of unchanged drug and metabolites was assessed by a highly specific high-performance liquid chromatographic method. FUra plasma levels declined rapidly with an apparent elimination half-life of 12.9 +/- 7.3 min. Dihydrofluorouracil was detected within 5 min in most patients, demonstrating rapid catabolism and reached maximum peak levels of 23.7 +/- 9.9 microM at approximately 60 min. The apparent elimination half-life of dihydrofluorouracil (61.9 +/- 39.0 min) was consistently greater than that of the unchanged drug. The apparent elimination half-lives of the subsequent metabolites alpha-fluoro-beta-ureidopropionic acid and alpha-fluoro-beta-alanine were prolonged with values of 238.9 +/- 175.4 min and 1976 +/- 358 min, respectively. Approximately 60-90% of the administered dose was excreted in urine within 24 h, primarily as alpha-fluoro-beta-alanine. Biliary excretion accounted for 2-3% of total administered radioactivity. The major fraction of this radioactivity eluted on high-performance liquid chromatography as a previously unrecognized FUra metabolite. Analysis of its structure is currently ongoing in our laboratory. In conclusion, this study provides the first comprehensive analysis of the formation and excretion of FUra metabolites in plasma, urine, and bile following i.v. bolus administration of FUra in humans.

Acute leukemias associated with the 4;11 chromosome translocation have rearranged immunoglobulin heavy chain genes.

Studies of acute leukemia with the 4;11 translocation have yielded conflicting results regarding the lineage of the cell of origin in this disease. To investigate this issue further, we have examined the state of immunoglobulin genes in tumor cells from two affected patients, immunophenotyped their leukemic cells using a number of monoclonal antibody reagents with specificities for lymphoid or myelomonocytic antigens, and examined the malignant cells by electron microscopy. DNA was extracted from leukemic bone marrow cells and hybridized with radiolabeled DNA fragment probes specific for the constant region of immunoglobulin heavy chain and kappa and lambda light chain genes. Autoradiographs revealed rearrangement of both allelic heavy chain genes, but a germline configuration of light chain genes in both cases. Surface marker analysis showed that blasts from both patients expressed HLA-DR and the myeloid antigens Leu-M1, 1C2, 2D1, and 4B3, but lacked common acute lymphocytic leukemia antigen or T antigens. Furthermore, they did not have sheep erythrocyte receptors nor did they express surface or cytoplasmic immunoglobulin or B cell precursor determinants. Electron microscopy analysis showed that blast cells from patient 1 exhibited numerous monoribosomes, polyribosomes, and isolated strands of rough endoplasmic reticulum in their cytoplasm. These ultrastructural features are characteristic for both common acute lymphocytic leukemia and pre-B-ALL cells, but not for T-ALL or acute myelogenous leukemia cells. Peroxidase was undetectable in cells from both patients. Our study suggests that this disorder represents a unique subtype of leukemia. The cell of origin may be an early B cell progenitor that shares certain surface antigens with myeloid cells or a stem cell with the potential for both lymphoid and myelomonocytic differentiation.