Three Faces of Mercaptopurine Cytotoxicity In Vitro: Methylation, Nucleotide Homeostasis, and Deoxythioguanosine in DNA

Mercaptopurine (MP) is a cytotoxic thiopurine important for the treatment of cancer and autoimmune diseases. MP and other thiopurine drugs undergo extensive intracellular metabolism, but the mechanisms of action are poorly characterized. In particular, it is unknown how different metabolites contrib...

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Bibliographic Details
Published inDrug metabolism and disposition Vol. 46; no. 8; pp. 1191 - 1199
Main Authors Coulthard, Sally A, McGarrity, Sarah, Sahota, Kalvin, Berry, Philip, Redfern, Chris P F
Format Journal Article
LanguageEnglish
Published United States American Society for Pharmacology and Experimental Therapeutics, Inc 01.08.2018
Subjects
6-Mercaptopurine
Autoimmune diseases
Biochemistry
Cancer
Cytotoxicity
Demethylation
Deoxyribonucleic acid
Disruption
DNA
DNA methylation
Drug metabolism
Guanosine
Homeostasis
Liquid chromatography
Mass spectrometry
Mass spectroscopy
Medical treatment
Metabolism
Metabolites
Nucleotides
Phosphates
Toxicity
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Summary:Mercaptopurine (MP) is a cytotoxic thiopurine important for the treatment of cancer and autoimmune diseases. MP and other thiopurine drugs undergo extensive intracellular metabolism, but the mechanisms of action are poorly characterized. In particular, it is unknown how different metabolites contribute to cytotoxicity and incorporation of thiopurine bases into DNA. The aim of this study was to ask whether cytotoxicity results from the incorporation of thioguanosine nucleotides into DNA, an alternative thiopurine metabolite, or a combination of factors. Therefore, we measured the cytotoxicity, metabolism, and incorporation of thioguanosine into DNA in response to MP or MP metabolites. Thiopurine metabolites varied in cytotoxicity, with methyl-thioinosine-mono-phosphate and thioguanosine-tri-phosphate the most toxic, and the methyl-thioguanosine nucleotides the least. We show, using liquid chromatography-tandem mass spectrometry, how different metabolites may perturb biochemical pathways, particularly disrupting guanosine nucleotide homeostasis, that may contribute to the mechanism of action of thiopurines. Although there was no correlation between metabolite cytotoxicity and the levels of 6-methylthioinosine-mono-phosphate or thioguanosine incorporation into DNA as individual factors, a combined analysis suggested that these factors together had a major influence on cytotoxicity. This study emphasizes the importance of enzymes of nucleotide homeostasis, methylation, and demethylation in thiopurine effects. These results will facilitate the development of dynamic biochemical models of thiopurine biochemistry that will improve our understanding of mechanisms of action in relevant target tissues.
ISSN:0090-9556
1521-009X
DOI:10.1124/dmd.118.081844