Thiopurine S-methyltransferase phenotype-genotype correlation in children with acute lymphoblastic leukemia

Thiopurine S-methyltransferase (TPMT) is an enzyme that catalyzes the S-methylation of thiopurine drugs such as 6-mercaptopurine, 6-thioguanine, and azathioprine. TPMT activity exhibits an interindividual variability mainly as a result of genetic polymorphism. Patients with intermediate or deficient TPMT activity are at risk for toxicity after receiving standard doses of thiopurine drugs. The aim of this study was to determine the TPMT genotype and phenotype (activity) and investigate the correlation between TPMT genotype and enzyme activity in 43 Polish children receiving 6-MP during maintenance therapy in course of acute lymphoblastic leukemia (ALL), in 16 children with ALL at diagnosis and 39 healthy controls. TPMT activity was measured in RBC by HPLC method. Patients were genotyped for TPMT *2, *3A and *3C variant allelesusing PCR-RFLP and allele-specific PCR methods. In the group of children with ALL during maintenance therapy, median TPMT activity (29.3 nmol 6-mMP g(-1) Hb h(-1)) was significantly higher compared to the group of children with ALL at diagnosis (20.6 nmol 6-mMP g(-1) Hb h(-1), p = 0.0028), as well as to the control group (22.8 nmol 6-mMP g(-1) Hb h(-1), p = 0.0002). Percentages of individuals heterozygous for TPMT variant allele in respective groups were: 9.3, 6.2 and 15.5% (p > 0.05). In all the study groups heterozygous patients manifested a significantly lower TPMT activity as compared to the wild type homozygotes (16.7 +/- 2.1 vs. 31.2 +/- 6.8 nmol 6-mMP g(-1) Hb h(-1), p = 0.002, in children during maintenance therapy, 11.9 +/- 2.7 vs. 24.6 +/- 9.5, p = 0.0003, in the combined group of children with ALL at diagnosis and controls). The results present that commencement of the thiopurine therapy caused an increase in the TPMT activity in RBCs by approximately 20%. All patients heterozygous for the TPMT variant allele revealed decreased TPMT activity compared to TPMT wild-type patients. Since decreased TPMT activity is associated with higher risk for toxicity after receiving standard doses of thiopurine drugs, pretreatment determination of TPMT status, with phenotypic or genetic assay, should be performed routinely, also in Poland.     

Thiopurine S-methyltransferase pharmacogenetics: genotype to phenotype correlation in the Slovenian population

The toxicity of thiopurine drugs has been correlated to the activity of thiopurine S-methyltransferase (TPMT), whose interindividual variation is a consequence of genetic polymorphisms. We have herein investigated the relevance of some genetic markers for the prediction of thiopurine-related toxicities and to determine the genotype to phenotype correlation in the Slovenian population. The most prevalent mutant allele in the Slovenian population is TPMT*3A (4.1%), followed by TPMT*3C (0.5) and TPMT*3B (0.3), while the TPMT*2 allele was not found in any of the examined samples. TPMT enzyme activity distribution in the subgroup sample was bimodal and as such correlated with genetic data. Using a cutoff value of 9.82 pmol/10(7) RBC per h, the genetic data correctly predicted TPMT enzyme activity in 91.6% of the examined individuals. Pharmacogenetic TPMT analyses have therefore proved to have significant clinical implications for prediction of individuals' responses to treatment with thiopurine drugs in order to avoid possible life-threatening therapy-related toxicities.     

Thiopurine S-methyltransferase genetic polymorphism in the Thai population

AIMS: To determine the incidence of the thiopurine S-methyltransferase (TPMT) genetic polymorphism in the Thai population. METHODS: Genomic DNAs were isolated from peripheral blood leucocytes of 200 healthy Thais. The frequencies of five allelic variants of the TPMT gene, TPMT*2, *3A, *3B, *3C and *6 were determined using allele specific polymerase chain reaction (PCR) or PCR-Restriction fragment length polymorphism technique. RESULTS: Of the 200 Thai subjects participating in this study, 181 subjects (90.5%) were homozygous for TPMT*1, 18 subjects (9.0%) were heterozygous for TPMT*1/*3C. Only one subject (0.5%) was homozygous for TPMT*3C. The frequency of TPMT*3C mutant allele was 0.050. CONCLUSIONS: Although the TPMT*3C is the most prevalent mutant allele in Asian populations, the frequency of this defective allele is significantly higher in Thais than has been reported in other Asian populations.     

Thiopurine S-methyltransferase as a target for drug interactions

Objective The present study was undertaken to investigate the possible effects of various agents on thiopurine methyltransferase (TPMT) activity in red blood cells (RBCs) from patients with chronic inflammatory bowel disease (IBD).Methods In three groups of patients with very high, normal and intermediate TPMT activity (each n=6), the inhibitory potential of furosemide, piretanide, azathioprine (AZA) and testosterone was assessed by ex vivo measurements of TPMT activity in RBCs. From individual concentration–response curves, IC₅₀ values have been determined.Results Independent of the basal TPMT activity, lowest IC₅₀ values were calculated for furosemide (15–19 M), followed by testosterone (30–72 M), piretanide (300–313 M) and AZA (430–532 M). Compared with reported plasma concentration achieved during treatment, only furosemide would have the potential to inhibit TPMT also in vivo, whereas the IC₅₀ values of the other agents are far above the corresponding plasma levels.Conclusions Our ex vivo study revealed that only furosemide has the potential to inhibit TPMT activity in patients with IBD. This possibility should be taken into consideration if the diuretic and AZA or 6-mercaptopurine are coadministered. However, the extrapolation to the clinical setting remains open.     

Thiopurine S-methyltransferase pharmacogenetics: variant allele functional and comparative genomics

Thiopurine S-methyltransferase (TPMT) catalyses the S-methylation of thiopurine drugs. Genetic polymorphisms for TPMT are a major factor responsible for large individual variations in thiopurine toxicity and therapeutic effect. The present study investigated the functional effects of human TPMT variant alleles that alter the encoded amino acid sequence of the enzyme, TPMT*2, *3A, *3B, *3C and *5 to *13. After expression in COS-1 cells and correction for transfection efficiency, allozymes encoded by these alleles displayed levels of activity that varied from virtually undetectable (*3A,*3B and *5) to 98% (*7) of that observed for the wild-type allele. Although some allozymes had significant elevations in apparent Km values for 6-mercaptopurine and S-adenosyl-L-methionine (i.e. the two cosubstrates for the reaction), the level of enzyme protein was the major factor responsible for variation in activity. Quantitative Western blot analysis demonstrated that the level of enzyme protein correlated closely with level of activity for all allozymes except TPMT*5. Furthermore, protein levels correlated with rates of TPMT degradation. TPMT amino acid sequences were then determined for 16 non-human mammalian species and those sequences (plus seven reported previously, including two nonmammalian vertebrate species) were used to determine amino acid sequence conservation. Most human TPMT variant allozymes had alterations of residues that were highly conserved during vertebrate evolution. Finally, a human TPMT homology structural model was created on the basis of a Pseudomonas structure (the only TPMT structure solved to this time), and the model was used to infer the functional consequences of variant allozyme amino acid sequence alterations. These studies indicate that a common mechanism responsible for alterations in the activity of variant TPMT allozymes involves alteration in the level of enzyme protein due, at least in part, to accelerated degradation.     

Comprehensive analysis of thiopurine S-methyltransferase phenotype-genotype correlation in a large population of German-Caucasians and identification of novel TPMT variants

The thiopurine S-methyltransferase (TPMT) genetic polymorphism has a significant clinical impact on the toxicity of thiopurine drugs. It has been proposed that the identification of patients who are at high risk for developing toxicity on the basis of genotyping could be used to individualize drug treatment. In the present study, phenotype-genotype correlation of 1214 healthy blood donors was investigated to determine the accuracy of genotyping for correct prediction of different TPMT phenotypes. In addition, the influence of gender, age, nicotine and caffeine intake was examined. TPMT red blood cell activity was measured in all samples and genotype was determined for the TPMT alleles *2 and *3. Discordant cases between phenotype and genotype were systematically sequenced. A clearly defined trimodal frequency distribution of TPMT activity was found with 0.6% deficient, 9.9% intermediate and 89.5% normal to high methylators. The frequencies of the mutant alleles were 4.4% (*3A), 0.4% (*3C) and 0.2% (*2). All seven TPMT deficient subjects were homozygous or compound heterozygous carriers for these alleles. In 17 individuals with intermediate TPMT activity discordant to TPMT genotype, four novel variants were identified leading to amino acid changes (K119T, Q42E, R163H, G71R). Taking these new variants into consideration, the overall concordance rate between TPMT genetics and phenotypes was 98.4%. Specificity, sensitivity and the positive and negative predictive power of the genotyping test were estimated to be higher than 90%. Thus, the results of this study provide a solid basis to predict TPMT phenotype in a Northern European Caucasian population by molecular diagnostics.     

Thiopurine S-methyltransferase pharmacogenetics: chaperone protein association and allozyme degradation

Thiopurine S-methyltransferase (TPMT) catalyses the S-methylation of thiopurine drugs such as 6-mercaptopurine. A common genetic polymorphism for TPMT is associated with large individual variations in thiopurine drug toxicity and therapeutic efficacy. TPMT*3A, the most common variant allele in Caucasians, has two alterations in amino acid sequence, resulting in striking decreases in TPMT protein levels. This phenomenon results, in part, from rapid degradation through a ubiquitin-proteasome-mediated process. We set out to test the hypothesis that chaperone proteins might be involved in targeting TPMT for degradation. As a first step, hsp90, hsp70 and the cochaperone hop were immunoprecipitated from a rabbit reticulocyte lysate (RRL) that included radioactively labelled *3A and wild-type TPMT. TPMT*3A was much more highly associated with all three chaperones than was the wild-type enzyme. The RRL was also used to confirm the accelerated degradation of *3A compared to wild-type TPMT. Treatment of RRL with the hsp90 inhibitor geldanamycin resulted in enhanced association of hsp90 with wild-type TPMT, an observation that correlated with accelerated ubiquitin-dependent degradation of wild-type TPMT. Geldanamycin treatment of COS-1 cells transfected with FLAG-tagged wild-type also resulted in a time and geldanamycin concentration-dependent decrease in TPMT activity and protein, which was compatible with results obtained in the RRL. These observations indicate that TPMT is a client protein for hsp90 and suggest that chaperone proteins, especially hsp90, are involved in targeting both TPMT*3A and, in the presence of geldanamycin, the wild-type allozyme for degradation. Therefore, chaperone proteins play an important mechanistic role in this clinically significant example of pharmacogenetic variation in drug metabolism.     

广东连南汉族和瑶族儿童硫嘌呤甲基转移酶研究

目的本文对硫嘌呤甲基转移酶(Thiopurine S-methyltransferase,TPMT)在广东连南地区健康汉族儿童(n=87)和瑶族儿童(n=1 26)中的活性分布和4种常见TPMT基因突变的等位基因频率进行研究.方法采用高效液相色谱法测定红细胞的TPMT活性;采用等位基因特异性的PCR(allelespecific PCR,ASPCR)方法和限制性片断长度多态性(PCR-restrictionfragmentlength polymorphism,RFLP)的方法检测TPMT*2(G238C)、TPMT*3A(A719G/G460A)、TPMT*3B(G460A)和TPMT*3C(A719G)的等位基因频率.结果健康汉族儿童和瑶族儿童的TPMT活性都呈正态分布,活性的平均值分别为13.01±2.80U.ml-1pRBC和13.54±3.89U.ml-1 pRBC,两者的差异无显著性.在健康汉族儿童中只找到1例TPMT*3C杂合子(该汉族儿童的TPMT活性为12.36U.ml-1 pRBC),没有找到TPMT*2、TPMT*3A和TPMT*3B,汉族儿童总的TPMT基因突变频率是0.6%.在健康瑶族儿童中没有找到这几种突变.结论广东连南地区汉族和瑶族儿童TPMT的活性分布和总的TPMT基因突变频率没有显著性差异.     

Thiopurine S-methyltransferase pharmacogenetics: autophagy as a mechanism for variant allozyme degradation

OBJECTIVE: Thiopurine S-methyltransferase (TPMT)*3A is degraded much more rapidly than is the 'wild-type' enzyme through a ubiquitin-proteasome-dependent process. It also forms aggresomes, suggesting a possible dynamic balance between degradation and aggregation. We set out to identify genes encoding proteins participating in these processes. METHODS: Green fluorescent protein tagged TPMT*3A was expressed in a Saccharomyces cerevisiae gene deletion library, and flow cytometry was used to screen for cells with high fluorescence intensity, indicating the loss of a gene essential for TPMT*3A degradation. RESULTS: Twenty-four yeast genes were identified in functional categories that included ubiquitin-dependent protein degradation, vesicle trafficking, and vacuolar degradation. The presence of genes encoding proteins involved in vesicular transport and vacuolar degradation suggested a possible role in TPMT*3A degradation for autophagy--a process not previously identified as a pharmacogenomic mechanism. In support of that hypothesis, TPMT*3A aggregates increased dramatically in mutants for vacuolar protease and autophagy-related genes. Furthermore, TPMT*3A expression in human cells induced autophagy, and small interfering RNA-mediated knockdown of ATG7, an autophagy-related human protein, enhanced TPMT*3A aggregation but not that of TPMT*3C or wild-type TPMT, indicating that autophagy contributes to TPMT*3A degradation in mammalian cells. We also demonstrated that UBE2G2, the human homologue of the E2 ubiquitin-conjugating enzyme identified during the yeast genetic screen, was involved in TPMT*3A degradation in human cells. CONCLUSION: These results indicate that autophagy should be considered among mechanisms responsible for the effects of pharmacogenetically significant polymorphisms that alter encoded amino acids.     

Thiopurine S-methyltransferase activity in three major Asian populations: a population-based study in Singapore

Objective The distribution of thiopurine methyltransferase (TPMT) activity in Asian populations has not been well documented. We studied the TPMT phenotype in three major Asian ethnic groups in Singapore, namely the Chinese (Ch), Malays (Mal) and Indians (Ind), with the aim of carrying out a comprehensive survey of the distribution of TPMT activity in Asians. Methods A radiochemical assay was used to measure the enzymatic activity of TPMT in the red blood cells (RBCs) of 479 healthy adults (Ch = 153, Mal = 163 and Ind = 163). Cut-off points for intermediate TPMT activity were validated using a receiver operating curve (ROC) analysis. PCR-based methods were used to screen for the TPMT*3C, TPMT*3A and TPMT*6 variants. Results The histogram of the combined population cohort showed a bimodal distribution of TPMT activity, with no subject having low TPMT activity (<5 units). In total, TPMT variants were detected in 14 subjects (*1/*3C in 13 subjects; *1/*3A in one subject). We observed significant inter-ethnic differences in terms of TPMT activity (p < 0.001), with the Malays showing a higher median activity than the Chinese or Indians (17.8 units vs 16.4 units). The Malays also showed a higher methylation rate – with a cut-off point for intermediate TPMT activity of 11.3 units – than the Chinese (9.9 units) or Indians (9.4 units). A high phenotype–genotype correlation of >97% was observed in all three races. We also genotyped 418 childhood leukaemias. The combined analysis of subjects participating in this and a previous study – 1585 subjects – showed that 4.7% of Chinese (n = 30/644), 4.4% of Malays (n =  24/540) and 2.7% of Indians (n = 11/401) were heterozygous at the TPMT gene locus. Conclusion This is the first comprehensive TPMT phenotype and genotype study in Asian populations, particularly in the Malays and Indians.     

Thiopurine S-methyltransferase pharmacogenetics: Functional characterization of a novel rapidly degraded variant allozyme

A novel human thiopurine S-methyltransferase (TPMT) variant allele, (319 T > G, 107Tyr > Asp, *27), was identified in a Thai renal transplantation recipient with reduced erythrocyte TPMT activity. The TPMT*27 variant allozyme showed a striking decrease in both immunoreactive protein level and enzyme activity after transient expression in a mammalian cell line. We set out to explore the mechanism(s) responsible for decreased expression of this novel variant of an important drug-metabolizing enzyme. We observed accelerated degradation of TPMT*27 protein in a rabbit reticulocyte lysate. TPMT*27 degradation was slowed by proteasome inhibition and involved chaperone proteins—similar to observations with regard to the degradation of the common TPMT*3A variant allozyme. TPMT*27 aggresome formation was also observed in transfected mammalian cells after proteasome inhibition. Inhibition of autophagy also decreased TPMT*27 degradation. Finally, structural analysis and molecular dynamics simulation indicated that TPMT*27 was less stable than was the wild type TPMT allozyme. In summary, TPMT*27 serves to illustrate the potential importance of protein degradation - both proteasome and autophagy-mediated degradation - for the pharmacogenetic effects of nonsynonymous SNPs.     

Pharmacogenetics as a Molecular Basis for Individualized Drug Therapy: The Thiopurine S-methyltransferase Paradigm

Genetic polymorphism of drug metabolizing enzymes can be the major determinant of inter-individual differences in drug disposition and effects. In this mini-review, the evolution of pharmacogenetic studies, from the recognition of phenotypic polymorphisms to the discovery of genetic mutations responsible for these inherited traits, is illustrated by the genetic polymorphism of thiopurine S-methyltransferase (TPMT). TPMT, which exhibits autosomal co-dominant polymorphism, plays an important role in metabolism of the antileukemic and immunosuppressive medications, mercaptopurine, thioguanine, and azathioprine. The genetic polymorphism of TPMT activity in humans was first reported in 1980, and in the last five years the genetic basis for this polymorphism has been elucidated. Isolation and cloning of mutant alleles from humans with TPMT deficiency has identified the major mutant alleles, established the basis for loss of TPMT activity and permitted development of PCR-based genotyping assays to make a molecular diagnosis of TPMT-deficiency and heterozygosity. These studies illustrate the potential clinical benefits of elucidating the molecular basis of inherited differences in drug metabolism and disposition, and future automation of molecular diagnostics will make it feasible to more precisely select the optimal drug and dosage for individual patients.Supported in part by the following NIH grants: R37 CA36401, R01 CA78224, and Cancer Center CORE grant CA21765, by a Center of Excellence grant from the State of Tennessee, and by American Lebanese Syrian Associated Charities.     

Thiopurine S-methyltransferase (TPMT) genotype does not predict adverse drug reactions to thiopurine drugs in patients with inflammatory bowel disease

BACKGROUND: Azathioprine and mercaptopurine (MP) are well established treatments for inflammatory bowel disease but they have severe adverse effects that prevent their use in some patients. The likelihood and type of adverse effect may relate to thiopurine methyltransferase (TPMT) enzyme activity and genotype. AIM: To compare the TPMT genotype frequencies in patients with inflammatory bowel disease who have had severe adverse effects to those who tolerate azathioprine or MP (controls). METHODS: Patients with inflammatory bowel disease who had been treated with azathioprine or MP in Christchurch between 1996 and 2002 were identified. Patients with adverse effects, and controls, were invited to provide a peripheral blood sample for analysis of TPMT genotype. The genotype frequencies were then compared between the two groups. RESULTS: Fifty-six patients were identified with adverse effects requiring cessation of therapy, of which 50 were genotyped. Reactions included allergic-type (25%), hepatitis (33%), nausea/vomiting (14%), bone marrow suppression (10%), pancreatitis (6%) and other (12%). Five of 50 patients with reactions had TPMT genotype *1/*3, one had *3/*3, and the rest had the wildtype genotype *1/*1. The patient with genotype *3/*3 had severe pancytopenia requiring hospitalization. Three of 50 controls had the *1/*3 genotype and the rest were *1/*1. CONCLUSIONS: The TPMT allele frequency in our population with inflammatory bowel disease is similar to that reported elsewhere. There was a slight trend for more frequent TPMT mutations in the patients with adverse reactions, but this was not statistically significant. Most patients with reactions did not have gene mutations.     

Thiopurine S-methyltransferase activity in human erythrocytes: a new HPLC method using 6-thioguanine as substrate

Objectives: To develop a non-radioactive assay to measure thiopurine S-methyltransferase (TPMT) activity. The assay was used to study the distribution of TPMT activity in a healthy German population. Methods: The assay is based on the conversion of 6-thioguanine (6-TG) to 6-methylthioguanine (6-MTG) using non-radiolabelled S-adenosyl-l-methionine (SAM) as the methyl donor. At the end of the incubation period (60 min) 6-MTG is extracted into chloroform/2-propanol and quantitated by reversed-phase high-performance liquid chromatography (HPLC) with fluorescence detection at Ex 315 nm and Em 390 nm. Results and discussion: The method is rapid, sensitive and reproducible, with an interassay CV of 6.7% (quality control sample with TPMT activity of 43 nmol 6-MTG · g⁻¹ Hb · h⁻¹) and thus suitable for routine monitoring of TPMT activity. The TPMT activity of 219 healthy German blood donors showed the known trimodal distribution with a range from 1.3 to 68.3 nmol 6-MTG · g⁻¹ Hb · h⁻¹ with a median value of 38.8 nmol 6-MTG · g⁻¹ Hb · h⁻¹. When the cut-off value for intermediate to high activity was set at 23.5 nmol 6-MTG · g⁻¹ Hb · h⁻¹, 14.1% belonged to the group with intermediate and 83.6% to the group with high TPMT activity. Five individuals had a very low TPMT activity of <2 nmol 6-MTG · g⁻¹ Hb · h⁻¹. Genetic analysis revealed that these persons were found either homozygote for the variant allele *3A (n=3) or they were compound heterozygotes for the variant alleles *3A/*3C (n=2). With these alleles for low TPMT activity they would run an increased risk of myelosuppression in case of treatment with standard doses of thiopurine drugs. Received: 30 September 1997 / Accepted in revised form: 17 January 1998     

Thiopurine methyltransferase genotype distribution in patients with Crohn's disease

BACKGROUND: Inter-individual response to azathioprine is partly due to inter-individual variation in the thiopurine methyltransferase (TPMT) activity. The TPMT genotype, which reflects the TPMT activity, has previously been studied in healthy Caucasians, with the most common variant allele being TPMT*3A. TPMT genotyping in adult patients with Crohn's disease has never been performed systematically. AIM: To determine the TPMT genotype distribution in adult patients with Crohn's disease. METHODS: One hundred and twenty randomly selected Danish patients (64 females and 56 males) with azathioprine-dependent Crohn's disease were included, and a polymerase chain reaction assay was used for TPMT genotyping. The patients were genotyped for the low-level genotype G460-->A and A719-->G transitions. RESULTS: One hundred and nine patients (90.3%; 95% confidence interval, 84.1-95.3) had a wild-type/ wild-type genotype, whereas 10 patients (8.3%; 95% confidence interval, 4.1-14.8) had one non-functional mutant allele and one patient (0.8%; 95% confidence interval, 0.02-4.6) had two non-functional mutant alleles. Only the TPMT*3A variant allele was found. CONCLUSIONS: The study showed a TPMT genotype distribution amongst adult Danish patients with Crohn's disease which was similar to the distribution of TPMT variant alleles normally found in healthy Caucasians.     

Acetylator status and N-acetyltransferase 2 gene polymorphisms; phenotype-genotype correlation with the sulfamethazine test

N-acetyltransferase 2 (NAT2) catalyzes the bioactivation and/or detoxification of drugs and carcinogens. The aim of this study was to establish the correlation between the NAT2 genotype and the acetylating phenotype in a Mexican population using sulfamethazine as a probe. From a total of 122 individuals, 73 (59.8%) were slow and 49 (40.2%) were fast acetylators. Eleven individuals (9%) had the wild-type genotype (NAT2*4/NAT2*4). The most frequent genotype was NAT2*4/NAT2*5B observed in 20.66% of individuals. In conclusion, our results show that an accurate prediction of the acetylation phenotype by genotyping can be achieved in around half of the population. Further studies with a larger number of individuals are required to establish correlations between phenotype and genotype in half of that patients having a genotype combined with slow/rapid alleles.     

Analysis of ITPA phenotype-genotype correlation in the Bulgarian population revealed a novel gene variant in exon 6

Mutations in the inosine triphosphate pyrophosphohydrolase (ITPA) gene causing enzyme deficiency were shown to have pharmacogenetic implications in azathioprine-induced adverse drug reactions. The distribution of ITPA activity as well as the types and the frequencies of gene variants associated with a lower enzyme activity were determined in healthy volunteers from a Bulgarian population. The ITPA activity was measured in 185 erythrocyte samples by an established high-performance liquid chromatography procedure. All samples were genotyped for 94C > A, IVS2 + 21A > C, and IVS2 + 68T > C/G by real-time polymerase chain reaction with hybridization probes. The ITPA activity ranged from 7.5 to 587.8 micromoL IMP/(g Hb x h) with a median value of 162.9 micromoL IMP/(g Hb x h). The enzyme activity showed significant differences between females and males (P = 0.006) with 17% higher values in men than women. Mutant allele frequencies were 0.038 (94C > A) and 0.130 (IVS2 + 21A > C). Mutations at IVS2 + 68 were not identified. Using a cutoff at 75 micromoL IMP/(g Hb x h) phenotyping detected all heterozygous carriers of 94C > A, two compound heterozygotes, all IVS2 + 21A > C homozygotes and 12.5% of IVS2 + 21A > C heterozygous cases. A novel frameshift mutation 359_366dupTCAGCACC in exon 6 was found in a subject with reduced enzyme activity of 61.2 micromoL IMP/(g Hb x h). The interindividual variability in ITPA activity among the Bulgarian population resembles the distribution of enzyme activity in other whites, although the observed median activity was approximately 25% lower in the Bulgarians [163 vs 219 micromoL IMP/(g Hb x h)]. The most common mutant allele IVS2 + 21A > C showed a similar frequency like in other white populations, whereas the 94C > A mutation was less frequently observed compared with other whites. Heterozygosity for the novel gene variant 359_366dupTCAGCACC was associated with 30% enzyme activity of the wild-type median value. The role of this rare variant for the thiopurine intolerance is not explored. These data further extend the knowledge for ITPA heterogeneity in whites.     

Thiopurine Treatment in Inflammatory Bowel Disease

Clinical Pharmacokinetics -