Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:2.1.1.67 (thiopurine methyltransferase)
 551 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Pharmacogenetics has emerged as a novel and challenging area of interest in oncology. Cancer chemotherapy is characterized by major intersubject variability in tumor responses and host toxicity. This variation may be caused by genetic differences in the enzymes involved in the metabolism of anticancer agents. Anticancer agents, such as 6-mercaptopurine, 5-fluorouracil, and irinotecan, have a narrow therapeutic index that can sometimes result in severe life-threatening toxicities. The impact of polymorphisms in metabolizing enzymes (thiopurine S-methyltransferase, dihydropyrimidine dehydrogenase, and uridine diphosphate glucuronosyltransferase) that participate significantly in the disposition of these anticancer agents is discussed.
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PMID:Inherited variations in drug-metabolizing enzymes: significance in clinical oncology. 1067 43

Thiopurine drugs are used to treat patients with neoplasia and autoimmune disease as well as transplant recipients. These agents are metabolized, in part, by S-methylation catalyzed by thiopurine methyltransferase (TPMT). The discovery nearly two decades ago that levels of TPMT activity in human tissues are controlled by a common genetic polymorphism led to one of the best examples of the potential importance of pharmacogenetics for clinical medicine. Specifically, it is now known that patients with inherited very low levels of TPMT activity are at greatly increased risk for thiopurine-induced toxicity such as myelosuppression when treated with standard doses of these drugs, while subjects with very high activity may be undertreated. Furthermore, recent reports indicate that TPMT may be the target for clinically significant drug interactions and that this common genetic polymorphism might be a risk factor for the occurrence of therapy-dependent secondary leukemia. In parallel with these clinical reports, the molecular basis for the TPMT polymorphism has been determined as a result of cloning and characterization of the human TPMT cDNA and gene. Those advances led to the description and characterization of a series of single nucleotide polymorphisms that result in low levels of enzyme activity as well as a polymorphic variable number tandem repeat within the 5'-flanking region of the TPMT gene that may "modulate" level of enzyme activity. As a result of these observations, the TPMT genetic polymorphism represents a model system for the way in which basic pharmacogenetic information is developed and applied to clinical medicine.
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PMID:Thiopurine pharmacogenetics: clinical and molecular studies of thiopurine methyltransferase. 1125 60

The purine analogues 6-mercaptopurine (6-MP) and azathioprine have been found to be safe and efficacious in both inducing remission of Crohn's disease in adults and maintaining remission in adults and children. In addition, steroid-sparing effects are demonstrable in trials of both adults and children with Crohn's disease. Anecdotal reports of adults and very limited data from children also suggest that azathioprine and 6-MP might help prevent postoperative recurrence of Crohn's disease. Regarding safety, adults and children reported similar rates of adverse effects from the use of these agents: reported adverse effects in adults included significant infection (7.4%), pancreatitis (3.3%), neoplasm (3.1%), bone marrow suppression (2.0%), allergy (2.0%), and drug-induced hepatitis (0.3%). Most studies also suggest there is little, if any, probability that immunomodulatory therapy might increase the risk of malignancy in patients with Crohn's disease. Data are too limited to guide clinical decisions on how long immunomodulatory therapy should be continued, whether it is safe to take azathioprine and 6-MP during pregnancy, and whether men can take these agents at the time of conception. Although 6-MP and azathioprine have been used safely for over 30 years, the recent commercial availability of thiopurine methyltransferase (TPMT) genotype/phenotype testing and 6-MP metabolite testing offers the promise of limiting potential toxicity even more. As a result, these agents will continue to play a central therapeutic role for all clinicians caring for children or adults with Crohn's disease.
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PMID:Therapeutic efficacy and safety of 6-mercaptopurine and azathioprine in patients with Crohn's disease. 1268 86

The goal of chemotherapy is the elimination of tumor cells from the host. This is achieved by the use of therapeutic agents that are often more harmful to normal tissues than to the targeted tumor. Many chemotherapeutic agents are designed to damage cell replication machinery either directly at the level of DNA or indirectly, by inhibiting enzymes involved with DNA repair and synthesis. Novel therapeutic agents that exert their effects at signal transduction pathways have advanced chemotherapy; however, a role for the classic chemotherapeutic agents remains. These classic agents are associated with tumor cell resistance, toxicity, and occasionally secondary neoplasia. Current practices for the dosing of therapeutic agents rely on height and body surface measurements or drug monitoring and Bayesian adaptive control. Pharmacogenetics is emerging as an alternate approach to managing chemotherapy that may prevent undertreatment while avoiding overtreatment and associated toxicities. By determining the polymorphic genetic makeup of the host and, in some instances, the altered genetic expression of the tumor, chemotherapy can be tailored for interindividual response and toxicity avoidance. Chemotherapy is particularly applicable to the pharmacogenetic approach to tailored therapy for a number of reasons. The margin of safety is low with chemotherapeutic agents. Some drugs require biotransformation for activation. Drug activation correlates with toxicity. The pathways of drug clearance or inactivation exhibit polymorphic differences. Interindividual, race-specific, and age-related responses to chemotherapeutic agents are common. Last, drug resistance can be inherent to the tumor as a result of the suppression of apoptosis. Variations in response and toxicity to a specific drug can be caused by alterations in drug-metabolizing enzymes or receptor expression. These effects can be classed as pharmacokinetic and pharmacogenetic differences. Some of the genes known to display polymorphic differences include FLT3 receptor tyrosine kinase, FCG3RA IgG FC receptor, thymidylate synthase, methylenetetrahydrofolate reductase, thiopurine S-methyltransferase, dihydropyrimidine dehydrogenase, aldehyde dehydrogenase, glutathione S-transferase, uridine diphosphate glyuronosyl transferases, N-acetyl transferases, cytochrome P450, and the DNA repair enzymes XPD and XRCC1. To be successful a pharmacogenetic approach to individualized chemotherapy must selectively take advantage of a determination of direct enzyme activity, gene expression, and genotype.
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PMID:Pharmacogenetics in cancer chemotherapy: balancing toxicity and response. 1522 71

Interindividual differences in tumor response and normal tissue toxicities are consistently observed with most chemotherapeutic agents or regimens. While many clinical variables have been associated with drug responses (e.g., age, gender, diet, drug-drug interactions), inherited variations in drug disposition (metabolism and transport) genes and drug target genes also likely contribute to the observed variability in cancer treatment outcome. Pharmacogenomic studies aim to elucidate the genetic bases for interindividual differences and to use such genetic information to predict the safety, toxicity, and/or efficacy of drugs. There exist several clinically relevant examples of the utility of pharmacogenomics that associate specific genetic polymorphisms in drug metabolizing enzymes (e.g., TPMT, UGT1A1, DPD), drug transporters (MDR1), and drug target enzymes (TS) with clinical outcomes in patients treated with commonly prescribed chemotherapy drugs, such as 5-fluorouracil and irinotecan (Camptosar; Pfizer Pharmaceuticals; New York, NY http://www.pfizer.com). Techniques to discover and evaluate the functional significance of these polymorphisms have evolved in recent years and may soon be applied to clinical practice and clinical trials of currently prescribed anticancer drugs as well as new therapeutic agents. This review discusses the current and future applications of pharmacogenomics in clinical cancer therapy and cancer drug development.
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PMID:Cancer pharmacogenomics: powerful tools in cancer chemotherapy and drug development. 1570 12

To identify gene(s) targeted by 6p22 genomic gain, present in more than 50% retinoblastoma tumors, we used real-time RT-PCR to quantify the expression of seven genes in normal human retina and retinoblastoma. Six genes are located in the quantitative multiplex PCR-defined 0.6 Mb minimal region of gain at 6p22 (DEK, AOF1, TPMT, NHLRC1, KIF13A, and NUP153), and E2F3 is 2 Mb away from the minimal region of gain on 6p22. E2F3, DEK, KIF13A, and NUP153 were most frequently overexpressed in retinoblastoma with 6p genomic gain, compared with the normal adult human retina. E2F3 and DEK mRNA levels were increased in all human tumors showing 6p22 gain, as well as in mouse retinoblastoma induced by SV40 large T antigen expression in developing retina, compared with the normal controls (adult human retina and 7-day-old mouse retina, respectively). Only DEK showed statistically significant correlation of expression and genomic copy number (P = 0.019). E2F3 and DEK, but not NUP153, showed developmental regulation. E2F3 and DEK mRNA overexpression was always associated with protein overexpression, determined by immunoblotting or immunofluorescent staining of primary tumors, relative to the adjacent normal retina. E2F3 was strongly expressed in actively proliferating cells, while DEK was overexpressed in all tumor cells. Taking into account the proliferation-promoting role of E2F3, implication of E2F3 in bladder and prostate cancer, and the translocation and overexpression of DEK in leukemia, we conclude that either DEK or E2F3 (or both) are targeted by the 6p22 gain in retinoblastoma.
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PMID:Expression analysis of 6p22 genomic gain in retinoblastoma. 1618 Feb 35

Drug metabolism enzymes (DME) play a significant role in drug detoxification and activation, which exert important effect on drug efficacy and sensitivity to toxicity. There is difference in expression and activity of DME between in tumor tissue and in non-tumor tissue. DME related with tumor chemotherapy are cytochrome P450 (CYP), glutathione-S-transferase (GST), uridine diphospho-glucuronosyltransferase (UGT), thiopurine methyltransferase (TPMT) and dihydropyrimidine dehydrogenase (DPD). The enzymes above are inducible and genetic polymorphic, thus with variable activity in individuals.
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PMID:[Cancer chemotherapy and drug metabolism enzyme]. 1640 65

Current choice of cancer therapy is usually empirical and relies mainly on the statistical prediction of the treatment success. Molecular research provides some opportunities to personalize antitumor treatment. For example, life-threatening toxic reactions can be avoided by the identification of subjects, who carry susceptible genotypes of drug-metabolizing genes (e.g. TPMT, UGT1A1, MTHFR, DPYD). Tumor sensitivity can be predicted by molecular portraying of targets and other molecules associated with drug response. Tailoring of antiestrogen and trastuzumab therapy based on hormone and HER2 receptor status has already become a classical example of customized medicine. Other predictive markers have been identified both for cytotoxic and for targeted therapies, and include, for example, expression of TS, TP, DPD, OPRT, ERCC1, MGMT, TOP2A, class III beta-tubulin molecules as well as genomic alterations of EGFR, KIT, ABL oncogenes.
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PMID:Molecular-based choice of cancer therapy: realities and expectations. 1730 83

There is wide variability in the response of individuals to standard doses of drug therapy. This is an important problem in clinical practice, where it can lead to therapeutic failures or adverse drug events. Polymorphisms in genes coding for metabolizing enzymes and drug transporters can affect drug efficacy and toxicity. Pharmacogenomics aims to identify individuals predisposed to high risk of toxicity and low response from standard doses of anticancer drugs. This chapter focuses on the clinical significance of polymorphisms in drug-metabolizing enzymes and drug transporters in influencing efficacy and toxicity of anticancer therapy. The most important examples to demonstrate the influence of pharmacogenomics on anticancer therapy are thiopurine methyltransferase (TPMT), UGT (uridine diphosphate glucuronosyltransferase) 1A1*28, and DPD (dihydropyrimidine dehydrogenase) *2A, respectively, for 6-mercaptopurine, irinotecan, and 5-fluorouracil therapy. However, in most other anticancer therapies no clear association has been found for polymorphisms in drug-metabolizing enzymes and drug transporters and pharmacokinetics or pharmacodynamics of anticancer drugs. Evaluation of different regimens and tumor types showed that polymorphisms can have different, sometimes even contradictory, pharmacokinetic and pharmacodynamic effects in different tumors in response to different drugs. The clinical application of pharmacogenomics in cancer treatment therefore requires more detailed information regarding the different polymorphisms in drug-metabolizing enzymes and drug transporters. A greater understanding of complexities in pharmacogenomics is needed before individualized therapy can be applied on a routine basis.
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PMID:Pharmacogenomics of drug-metabolizing enzymes and drug transporters in chemotherapy. 1837 Feb 31

Although the use of concomitant immunosuppressants (IS) with biologics has been demonstrated to reduce the immunogenicity of chimeric (infliximab), humanized (natalizumab), human (adalimumab) antibodies and antibody fragments (certolizumab pegol), to date concomitant IS with biologics has not impacted on the short or intermediate responses in the treatment of Crohn's disease in most induction and maintenance trials. The optimal strategy to reduce antibodies to infliximab is to use an induction and maintenance strategy rather than episodic therapy. Any potential benefit of concomitant IS use with biologic agents needs to be balanced against the risk of combination therapy including serious infections and the risk of neoplasia. The discovery of genetic polymorphism for production of thiopurine methyltransferase (TPMT), a key enzyme in the metabolism of thiopurine antimetabolites, has made it possible to rationalize therapy in terms of patient and dosage selection. TPMT screening prior to initiation of thiopurine antimetabolites is currently recommended to avoid treating patients with low or absent TPMT activity with potentially toxic doses of thiopurines. Routine monitoring of blood counts and liver enzymes is recommended even in individuals with normal TPMT activity. The ability to monitor thiopurine metabolites may make it possible to optimize therapeutic response by guiding clinicians on dose escalation.
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PMID:Conventional treatment in inflammatory bowel disease--recent trends. Immunosuppressants and biologic agents: should they or need they be used together? How to use immunosuppressive therapy better (and safer) tomorrow? 2011 43


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