EC:2.1.1.67 - FACTA Search

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)

Therapeutic drug monitoring is not routinely used for cytotoxic agents. There are several reasons, but one major drawback is the lack of established therapeutic concentration ranges. Combination chemotherapy makes the establishment of therapeutic ranges for individual drugs difficult, the concentration-effect relationship for a single drug may not be the same as that when the drug is used in a drug combination. Pharmacokinetic optimization protocols for many classes of cytotoxic compounds exist in specialized centres, and some of these protocols are now part of large multicentre trials. Nonetheless, methotrexate is the only agent which is routinely monitored in most treatment centres. An additional factor, especially in antimetabolite therapy, is the existence of pharmacogenetic enzymes which play a major role in drug metabolism. Monitoring of therapy could include assay of phenotypic enzyme activities or genotype in addition to, or instead of, the more traditional measurement of parent drug or drug metabolites. The cytotoxic activities of mercaptopurine and fluorouracil are regulated by thiopurine methyltransferase (TPMT) and dihydropyrimidine dehydrogenase (DPD), respectively. Lack of TPMT functional activity produces life-threatening mercaptopurine myelotoxicity. Very low DPD activity reduces fluorouracil breakdown producing severe cytotoxicity. These pharmacogenetic enzymes can influence the bioavailability, pharmacokinetics, toxicity and efficacy of their substrate drugs.
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PMID:Therapeutic drug monitoring of antimetabolic cytotoxic drugs. 1019 Jun 47

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

Clinical and other aspects of pharmacogenetics and pharmacogenomics are discussed. Pharmacogenetics is the study of the impact of heritable traits on pharmacology and toxicology. An extension of pharmacogenetics is the discovery that genetic polymorphisms have the potential to affect a drug's action. The interplay of genotype and drug efficacy has been defined as pharmacogenomics. For most drugs, variations in patient response have until recently been considered a result of pharmacokinetic rather than pharmacodynamic differences. However, it now seems that pharmacodynamic variability in humans is large, reproducible, and usually more pronounced than pharmacokinetic variability. Some examples of the impact of pharmacogenomics on pharmacokinetics involve cytochrome P-450 isoenzymes, dihydropyrimidine dehydrogenase, and thiopurine methyltransferase; some examples of the impact on pharmacodynamics involve cholesteryl ester transfer protein, angiotensin-converting enzyme, and serotonin transporter. There are no specific statistical techniques for analyzing data from pharmacogenomic clinical trials. However, a tabulated relationship for the determination of the maximum possible gain in response rate for the highest-responding genotypic subgroup of patients is provided as an aid to determining whether it is worth having a pharmacogenomic strategy for a given drug. Ethical issues in pharmacogenomics tend to be based on the general concern that the ability to diagnose a genetic disorder before any treatment is available does more harm than good to the patient. Pharmacogenomic approaches to drug discovery and delivery have been recognized by FDA. Pharmacogenomics cannot improve the efficacy of a given drug, but it helps in selecting patients who are likely to respond well. Pharmacogenomics provides a view of drug behavior and sensitivity useful to improving the efficacy of drug development and utilization.
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PMID:Clinical trials in pharmacogenetics and pharmacogenomics: methods and applications. 1084 May 30

This article reviews the clinical relevance of pharmacogenetics in cancer chemotherapy, with emphasis on drugs for which genetic differences in enzyme metabolism have been demonstrated to affect patient outcome. About 10% of children with leukaemia are intolerant to mercaptopurine (6-mercaptopurine) because of genetic defects in mercaptopurine inactivation by thiopurine S-methyltransferase. However, mercaptopurine dose intensity, a critical factor for outcome in patients deficient in thiopurine S-methyltransferase, can be maintained by means of thiopurine S-methyltransferase phenotyping or genotyping. Patients with reduced fluorouracil (5-fluorouracil) catabolism are more likely to be exposed to severe toxicity. The measurement of dihydropyrimidine dehydrogenase activity in patients cannot be considered fully predictive, and the role of dihydropyrimidine dehydrogenase gene variants in this syndrome has yet to be clarified. With regard to irinotecan, patients with Gilbert's syndrome phenotype have reduced inactivation of the active topoisomerase I inhibitor 7-ethyl-10-hydroxycamptothecin (SN-38) caused by a mutation in the UDP-glucuronosyltransferase 1A1 gene promoter. This subset of patients is more likely to be exposed to irinotecan toxicity and could be identified by genotyping for gene promoter variants. Finally, the experience with amonafide represents a model for dose individualization approaches that use simple phenotypic probes.
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PMID:Pharmacogenetics: a tool for individualizing antineoplastic therapy. 1110 31

Therapeutic drug monitoring is not routinely used for cytotoxic agents. There are several reasons, but one major drawback is the lack of established therapeutic concentration ranges. Combination chemotherapy makes the establishment of therapeutic ranges for individual drugs difficult, the concentration-effect relationship for a single drug may not be the same as when that drug is used in a drug combination. Pharmacokinetic optimization protocols for many classes of cytotoxic compounds exist in specialized centres, and some of these protocols are now part of large multicentre trials. Nonetheless, methotrexate is the only agent which is routinely monitored in most treatment centres. An additional factor, especially in antimetabolite therapy, is the existence of pharmacogenetic enzymes which play a major role in drug metabolism. Monitoring of therapy could include assay of phenotypic enzyme activities or genotype in addition to, or instead, the more traditional measurement of parent drug or drug metabolites. The cytotoxic activities of mercaptopurine and fluorouracil are regulated by thiopurine methyltransferase (TPMT) and dihydropyrimidine dehydrogenase (DPD), respectively. Lack of TPMT functional activity produces life-threatening mercaptopurine myelotoxicity. Very low DPD activity reduces fluorouracil breakdown producing severe cytotoxicity. These pharmacogenetic enzymes can influence the bioavailability, pharmacokinetics, toxicity and efficacy of their substrate drugs.
...
PMID:Therapeutic drug monitoring of cytotoxic drugs. 1156 55

Interindividual variability in the efficacy and toxicity of drug therapy is associated with polymorphisms in genes encoding drug-metabolizing enzymes, transporters, or drug targets. Pharmacogenetics aims to identify individuals predisposed to high risk of toxicity from conventional doses of cancer chemotherapeutic agents. We review the role of genetic polymorphisms in UGT1A1 and TPMT, as well as mutations in DPD, in influencing drug disposition and toxicity. Recent studies show that pharmacogenetic determinants may also influence treatment outcomes. We discuss the clinical significance of polymorphisms in TS, MTHFR, and FCGR3A, as well as the polymorphic DNA repair genes XPD and XRCC1, in influencing response to chemotherapy and survival outcomes. Finally, the potential implications of transporter pharmacogenetics in influencing drug bioavailability are addressed.
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PMID:Pharmacogenetics in cancer treatment. 1252 81

Dose adjustment of drug administration for each patient has been performed based on counts of some factors such as body surface area, age of the patient, performance status, renal and/or liver function. Pharmacokinetic and pharmacodynamic analyses have been investigated by measuring the plasma concentration of a drug and observing the drug effects. However, prior to drug administration it is difficult to predict unexpected, severe drug toxicity, which depends on the individual differences among patients. Recent progress in human genome analysis has been providing tools for new approaches to disease treatment based on individual differences using genetic information. This review focuses on the drug metabolizing enzyme and its genetic polymorphisms in cancer chemotherapy. We describe the recent findings on pharmacogenomics between toxicity and the genetic polymorphisms of the thiopurine methyltransferase (TPMT) gene, dihydropyrimidine dehydrogenase (DPYD) gene, methylenetetrahydrofolate reductase (MTHFR) gene, and uridine diphosphate glucuronosyltransferase (UGT1A1 and UGT1A7) gene. We need to accumulate clinical data based on the variation of genetic profiling as well as pharmacogenetic information. Such data will help tailor cancer chemotherapy to an individual's predisposition in the near future.
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PMID:[Pharmacogenomic approaches for prevention of drug toxicity in cancer chemotherapy]. 1266 88

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

Several proofs of principle have established that pharmacogenetic testing for mutations altering expression and functions of genes associated with drug disposition and response can decrease the "trial-and-error" dosing and reduce the risk of adverse drug reactions. These proofs of principle include thiopurine methyltransferase and thiopurine therapy, dihydropyrimidine dehydrogenase/thymidylate synthase and 5-fluorouracil therapy, folate enzyme MTHFR and methotrexate therapy, UGT1A1 and irinotecan therapy and CYP450 2C9 and S-warfarin therapy. These evidences advocate for the prospective identification of mutations associated with drug response, serious adverse reactions and treatment failure. More recent evidence with the HLA basis of hypersensitivity to the retroviral agent abacavir demonstrates the potential of pharmacogenetic testing and its pharmacoeconomic implications. With the convergence of rising drug costs and evidence supporting the clinical benefits of pharmacogenetic testing, it will be important to demonstrate the improved net health outcomes attributed to the additional costs for this testing.
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PMID:Pharmacogenetic testing: proofs of principle and pharmacoeconomic implications. 1582 47

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