John A. Duley

Genetic basis of inosine triphosphate pyrophosphohydrolase deficiency.

Abstract. Inosine triphosphate pyrophosphohydrolase (ITPase) deficiency is a common inherited condition characterized by the abnormal accumulation of inosine triphosphate (ITP) in erythrocytes. The genetic basis and pathological consequences of ITPase deficiency are unknown. We have characterized the genomic structure of the ITPA gene, showing that it has eight exons. Five single nucleotide polymorphisms were identified, three silent (138G→A, 561G→A, 708G→A) and two associated with ITPase deficiency (94C→A, IVS2+21A→C). Homozygotes for the 94C→A missense mutation (Pro32 to Thr) had zero erythrocyte ITPase activity, whereas 94C→A heterozygotes averaged 22.5% of the control mean, a level of activity consistent with impaired subunit association of a dimeric enzyme. ITPase activity of IVS2+21A→C homozygotes averaged 60% of the control mean. In order to explore further the relationship between mutations and enzyme activity, we examined the association between genotype and ITPase activity in 100 healthy controls. Ten subjects were heterozygous for 94C→A (allele frequency: 0.06), 24 were heterozygotes for IVS2+21A→C (allele frequency: 0.13) and two were compound heterozygous for these mutations. The activities of IVS2+21A→C heterozygotes and 94C→A/IVS2+21A→C compound heterozygotes were 60% and 10%, respectively, of the normal control mean, suggesting that the intron mutation affects enzyme activity. In all cases when ITPase activity was below the normal range, one or both mutations were found. The ITPA genotype did not correspond to any identifiable red cell phenotype. A possible relationship between ITPase deficiency and increased drug toxicity of purine analogue drugs is proposed.

Thiopurine methyltransferase activity and the use of azathioprine in inflammatory bowel disease

Background : Azathioprine therapy is discontinued in one‐third of patients with inflammatory bowel disease because of toxicity or a lack of clinical response. Patients with thiopurine methyltransferase (TPMT) deficiency are intolerant to azathioprine, whilst carriers are at increased risk of side‐effects.

THE IMPORTANCE OF THIOPURINE METHYLTRANSFERASE ACTIVITY FOR THE USE OF AZATHIOPRINE IN TRANSPLANT RECIPIENTS

The immunosuppressive efficacy of azathioprine is related to its rapid metabolism in vivo to 6-mercaptopurine (6MP), with subsequent conversion to thioguanine nucleotides by an anabolic route involving hypoxanthine-guanine phosphoribosyltransferase. Two alternative catabolic routes exist: oxidation to 6-thiouric acid via xanthine oxidase and methylation to 6-methylmercaptopurine via the enzyme thiopurine methyltransferase (TPMT). Catabolism via either route would restrict formation of the active metabolites.We analyzed TPMT activity in erythrocyte lysates of 25 controls, 25 uremic patients on dialysis, and 68 transplanted patients. Median activity was lower in controls (31.0 pmol/hr/mg Hb, range 16.2–43.0) and transplanted patients receiving only cyclosporine and prednisolone (31.7 pmol/hr/mg Hb, range 12.7–43.5) than in the azathioprine treated group, (36.1 pmol/hr/mg Hb, range 16.1–71.3), or the uremic group on dialysis, (35.5 pmol/hr/mg Hb, range 18.6–62.6) suggesting that both azathioprine and uremia induce the enzyme, but CsA does not.

Uridine and its nucleotides: biological actions, therapeutic potentials

There are many disorders of pyrimidine metabolism and those that involve an alteration in uridine metabolism have neurological and systemic effects, which provide insights into the biological activity of uridine and its analogues. Studies of the metabolism and actions of pyrimidines have uncovered a wealth of information on how these endogenous metabolites modulate cell physiology. In this article, the roles for the pyrimidine nucleoside uridine and its nucleotide derivatives in the regulation of a number of biological systems are examined and benefits of further studies are outlined. An understanding of how uridine and its nucleotides modulate such vastly complicated biological systems should ultimately lead to the development of new ways for modulating human physiology in both normal and diseased states. Likely targets for therapy include the respiratory, circulatory, reproductive, and nervous systems, and the treatment of cancer and HIV infection.

Prospective evaluation of the pharmacogenetics of azathioprine in the treatment of inflammatory bowel disease

Background  One‐third of patients with inflammatory bowel disease (IBD) receiving azathioprine (AZA) withdraw treatment due to side effects or lack of clinical response.

Low‐dose azathioprine or mercaptopurine in combination with allopurinol can bypass many adverse drug reactions in patients with inflammatory bowel disease

Aliment Pharmacol Ther 31, 640–647

Thiopurine methyltransferase: should it be measured before commencing thiopurine drug therapy?

Thiopurines [azathioprine (AZA), 6-mercaptopurine (6-MP) and thioguanine (6-TG)] have a well-established role as immunosuppressive agents in a variety of chronic inflammatory conditions, haematological neoplasia and in transplant rejection. Despite good overall clinical response rates, particularly when used as steroid sparing agents, adverse effects are a limiting problem leading to withdrawal in up to a quarter of patients. Severe myelosuppression is the most serious toxicity occurring early or occasionally later during treatment. An understanding of the competing pathways involved in the metabolism of thiopurines has important implications for predicting some of the more severe toxicity seen with these drugs. Thiopurine methyl transferase (TPMT) is an enzyme catalysing the methylation of 6-MP, competing with xanthine oxidase (XO) and hypoxanthine guanine phosphoribosyl transferase (HGPRT) to determine the amount of 6-MP metabolised to cytotoxic thioguanine nucleotides. Allelic polymorphisms in the TPMT gene predict the activity of the enzyme such that 1 in 10 of the population are heterozygous and have approximately 50% of normal activity, whilst 1 in 300 are completely deficient. As a result, these individuals are at high risk of severe myelosuppression. Conversely, individuals with very high levels of TPMT activity are hyper-methylators in whom clinical response is less likely. Prior knowledge of TPMT status avoids exposure of individuals with zero TPMT to potentially fatal treatment with AZA or 6-MP and provides one of the best examples of predictive pharmacogenetics in therapeutics. This article reviews literature on the role of TPMT measurement prior to treatment with thiopurines and provides some guidance to the use of TPMT as a guide to tailoring thiopurine therapy.

Long‐term outcome of using allopurinol co‐therapy as a strategy for overcoming thiopurine hepatotoxicity in treating inflammatory bowel disease

Background  Hepatotoxicity results in the withdrawal of thiopurines drugs, azathioprine (AZA) and mercaptopurine (MP), in up to 10% of patients with inflammatory bowel disease. Our group previously demonstrated that allopurinol with AZA/ciclosporin/steroid ‘triple therapy’ improved renal graft survival.

Thiopurine therapies : Problems, complexities, and progress with monitoring thioguanine nucleotides

Metabolism of thiopurine drugs-azathioprine, 6-mercaptopurine, and 6-thioguanine-has provided a powerful pharmacogenetic model incorporating polymorphism of the enzyme thiopurine methyltransferase (TPMT) and the primary active metabolite, thioguanine nucleotide (TGN). However, a sense of uncertainty about the usefulness of TGNs and other thiopurine metabolites has appeared. This review critically appraises the basis of thiopurine metabolism and reveals the problems and complexities in TGN research. Erythrocyte TGN is used in transplantation medicine and in chronic inflammatory conditions such as Crohns disease, as a “surrogate” pharmacokinetic parameter for TGN in the target cells: leukocytes or bone marrow. It is not generally appreciated that erythrocytes do not express the enzyme IMP dehydrogenase and cannot convert mercaptopurine to TGN, which explains some of the confusion in interpretation of erythrocyte TGN measurements. TGN routinely measured in erythrocytes derives from hepatic metabolism. Another concern is that TGN are not generally assayed directly: most methods assay the thiopurine bases. Ion-exchange HPLC and enzymatic conversion of TGNs to nucleosides have been used to overcome this, and may reveal undisclosed roles for an unusual cytotoxic nucleotide, thio-inosine triphosphate, and methylated thiopurines. There appear to be additional interactions between xanthine oxidase and TPMT, and folate and TPMT, that could predict leukopenia. Difficult questions remain to be answered, which may be assisted by technological advances. Prospective TGN studies, long overdue, are at last revealing clearer results.

Novel pharmacogenetic markers for treatment outcome in azathioprine-treated inflammatory bowel disease

Background  Azathioprine (AZA) pharmacogenetics are complex and much studied. Genetic polymorphism in TPMT is known to influence treatment outcome. Xanthine oxidase/dehydrogenase (XDH) and aldehyde oxidase (AO) compete with TPMT to inactivate AZA.