Specimen Collection

8 mL EDTA Blood

Requires 2x 4mL EDTA tubes:

• One for measuring TPMT and haematocrit.
• The second for genotyping either if initially requested or later if the activity level is low, or if the lab is called within 2 weeks of receiving the samples (consent should be obtained from the patient or family prior to genotyping. It is the responsibility of the clinician to obtain this).
• TPMT genotype is performed in children, even if only phenotype is written on the request form, as genotype has greater reliability in identification of TPMT variants. The laboratory will assume consent for genotyping has been obtained.

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Download: GHSNZ consent form for TPMT genotyping - GHSNZ consent form for TMPT.pdf

Reference Intervals

Reference TPMT activity >= 4.4 nmol/h/mL RBC

Borderline 4.4-4.6 nmol/h/mL

High likelihood of homozygous variant <=2.6 nmol/h/mL

UoM = 13%

Turnaround Time: Between 3 days and 1 week

TPMT activity assay is performed twice weekly.

If a sample requires further genetic testing it will be subject to the turnaround times of the genetics department and requires appropriate consent.

See also TGN (Thioguanine) entry in Testguide.

Turnaround Time: Between 3 days and 1 week

TPMT activity assay is performed twice weekly.

If a sample requires further genetic testing it will be subject to the turnaround times of the genetics department.

Diagnostic Use and Interpretation

Azathioprine (Imuran) and 6-mercaptopurine (6-MP) are thiopurine drugs used to treat some types of leukaemia and some of rheumatological, gastroenterological, dermatological and neurological diseases in which the immune system is thought to play a role.

These drugs are potentially toxic. They are metabolised to 6-thioguanine nucleotides (6-TGN), which are the active metabolites. They are also inactivated in part by S-methylation, by the action of the cytosolic enzyme thiopurine methyl transferase (TPMT). For a diagram of metabolic conversion pathways, see TGN entry in Testguide.

Low TPMT activity reduces the conversion of 6MP to 6MMP (an inactive metabolite), and increases the relative conversion of 6MP to 6TGNs, the active metabolites. 6-TGNs are also metabolised by TPMT enzyme, which additionally leads to higher active 6TGN levels in TPMT deficient patients.

TPMT is distributed in all tissues, but has no known natural substrate. Almost all TPMT activity in blood is present in red cells, and must be released by lysing the cells and measuring enzyme activity prior to analysis of the product (6MMP) using HPLC (high pressure liquid chromatography). The result is then adjusted using the haematocrit.

TPMT enzyme activity is genetically determined. Loss-of-function variants in TPMT gene cause low TPMT activity. This is inherited as a monogenic, autosomal co-dominant trait.

Testing for TPMT activity is recommended in all patients prior to starting a thiopurine drug ^1-3 . The most well established and important reason, and the primary benefit recognised in international guidelines, is to identify individuals who are homozygous or compound heterozygous carriers of inactivating/low activity TPMT alleles (i.e. carry two inactivating alleles). Such patients are classified to be poor metabolisers. Their prevalence is estimated to be 1 in 300. These patients have an extremely high concentration of 6-TGN if given a standard dose of thiopurine drugs and are at risk of rapid and severe bone marrow toxicity with leukopaenia. Alternative non-thiopurine therapy should be considered in this group of patients. If thiopurine drugs are used, they should be started at 10% of target dose. ²

Individuals who are heterozygous (carriers) for an inactivating TPMT allele (i.e. carry one inactivating allele plus one normal wild type allele) are classified as intermediate metabolisers. Approximately 10% of patients are in this category.

TPMT activity in homozygous and heterozygous carriers of TPMT variant alleles.

Over 90% of homozygous or compound heterozygous variant carriers have significantly reduced TPMT activity at or below 2.6 nmol/h/mL. Conversely less than 2.5% of heterozygote carriers (who possess at least one wild type TPMT gene) have TPMT below this threshold. If not already requested, targeted genetic analysis of key exons in the TPMT gene should be performed on samples with TPMT activity in this range (<2.6ng/mL/hr). Consent is required.

The large majority of heterozygous variant carriers (who also carry one normal allele) have TPMT activity in the range 2.7-4.3 nmol/h/mL (intermediate metabolisers). Note, however, that correlation between genotype and phenotype is imperfect and there is significant overlap between heterozygote carriers and wild type patients. About 2/3 of patients in this range are variant carriers, but 1/3 prove to be "wild type" (with no low activity variants) on genotyping. Less than 10% of homozygous or compound heterozygous deficient patients have activity in this range . Genotyping is not automatically performed in this group, although can be separately requested.

Heterozygote carriers of variants are at increased risk of myelosuppression at standard doses of thiopurine drugs. Knowledge of the TPMT activity is useful in establishing the correct dose in such patients. Starting at 33-50% of target dose has been recommended in ?intermediate metabolisers. ^2,3

Genetic TPMT Analysis (Genotyping)

In addition to patients found to have TPMT activity at or below 2.6 nmol/h/mL, genotyping is recommended on all children under 17 years, and is performed on all requests. It is also performed in patients with PCV <0.35, because measuring TPMT activity (phenotype) is less reliable in these patients, and genotype has been found to be a better predictor of 6TG accumulation during chemotherapy (see below) ⁶ .

The genetic analysis performed at LabPlus covers the targeted region containing the three single nucleotide variants of the common inactivating TPMT alleles (TPMT*2/*3A/*3B/*3C) which account for over 90% of low activity phenotypes. Sometimes additional rare variants found in the sequenced exons may be identified, however other rare variants may still not be found ⁵ . Since genotyping does not identify all potential activity variants, it is not a completely reliable substitute for initial enzyme analysis in every case.

Please note that, as with any genetic test, there is the possibility of identifying sequence variants of uncertain significance (VUS). These can't be used to support informed decision making in clinical management, so can lead to residual uncertainty.

Regardless of initial testing, all patients on TGN treatment require close monitoring.

Important note on consent for genetic testing:

Genetic testing requires specific consent from the patient. This is taken as given by the clinician at the time of genotype request, or if reflex genotyping is required. It is the responsibility of the clinician to discuss and consent the patient when discussing TPMT phenotyping.

TPMT Measurement in Children

TPMT levels in "wild type" children are slightly higher than adults, however the difference is not sufficiently great to affect interpretive cutoffs used ⁷ . However, in children with ALL treated by thiopurines there can be disease- and treatment-related effects. Older red cells, which tend to predominate with bone marrow failure at diagnosis, have lower TPMT than young red cells, so TPMT activity may be initially reduced and can rise as bone marrow activity improves with treatment ⁶ .

For this reason documentation of TPMT genotype is recommended before starting treatment and is performed on all requests for TPMT analysis in children.

Important note on consent for genetic testing in children (<18 years):

Genetic testing requires consent from the parents/legal guardians. This is taken as given by the clinician at the time of genotype request, or if reflex genotyping is required. It is the responsibility of the clinician to discuss and consent the family when discussing TPMT phenotyping.

Monitoring of patients on treatment

Routine monitoring of FBC, LFT and TDM of thiopurine drug metabolites (TGN's) is recommended for all patients on thiopurine drugs, regardless of enzyme activity. NZ Gastroenterology Society recommendations are for FBC, LFT weekly for a month, monthly for two months, then every 3 months if on stable dose, with ongoing monitoring for adverse effects ³ . Please also see 6-Thioguanine Nucleotides.

Sulfasalazine (Pentasa) treatment can be associated with a reduction in TPMT activity. Discontinuation of treatment can therefore lead to a modest increase in activity and fall in TGN levels.

Drugs and conditions leading to an increased proportion of young red cells, e.g. haemolysis, chronic blood loss, stem cell transplant, and responses to AZA or 6MP treamtent, can lead to a rise in TPMT activity.

Note that high TPMT does not necessarily predict a high level of MMP, and does not reliably predict a high MMP/TGN ratio (sometimes called a "shunting effect" and associated with reduced efficacy despite increasing TGN dose). This is because there are likely to be other additional "shunting" mechanisms leading to reduced efficacy, and it is still necessary to monitor TGN levels in patients on treatment. See also TGN entry in Testguide.

Please refer to the guidelines in the references for the details of dosage adjustments.

Recent Transfusion

TPMT activity is affected by red cell transfusion within the previous 3 months. This must be considered when interpreting TPMT activity results. Blood samples for TPMT activity should be taken prior to any transfusions or after 3 months, with careful dose escalation ³ . For post-transfusion samples earlier than this, TPMT genetic analysis can be arranged with the laboratory.

References

1. Relling MV et al. Clinical Pharmacogenetics Implementation Consortium Guideline for Thiopurine Dosing Based on TPMT and NUDT15 Genotypes: 2018 Update. Clin Pharmacol Ther. 2019;105(5):1095-1105. [https://cpicpgx.org/guidelines/guideline-for-thiopurines-and-tpmt/]
2. Lennard L. Implementation of TPMT testing. Br J Clin Pharmacol. 2014;77:704-14.
3. Khan A et al. New Zealand Society of Gastroenterology Guidelines on Therapeutic Drug Monitoring in Inflammatory Bowel Disease. N Z Med J. 2019;132(1491):46-62.

4. Feuerstein JD, et al. American Gastroenterological Association Institute Guideline on Therapeuric drug monitoring in inflammatory bowel disease. Gastroenterology 2017; 153(3): 827-34.

5. CPIC Guideline for Thiopurines and TPMT and NUDT15 CPIC (cpicpgx.org)

6. Lennard L. et al. Thiopurine methyltransferase genotype-phenotype discordance and thiopurine active metabolite formation in childhood acute lymphoblastic leukaemia. Br. J. Clin. Pharmacol. 2012; 76(1): 125-136.

7. Serpe L, et al. Thiopurine S-methyltransferase pharmacogenetics in a large-scale healthy Italian-Caucasian population: differences in enzyme activity. Pharmacogenomics 2009; 10(11): 1753-65

Contact Information

Emails to chemicalpathologist@adhb.govt.nz will receive priority attention from the on-call chemical pathologist.

If the query concerns a specific patient please include the NHI number in your email.

If email is not a suitable option, please contact the on-call chemical pathologist via Lablink (Auckland City Hospital ext. 22000 or 09-3078995).

Individual chemical pathologists may be contacted but will not be available at all times.

After-hours : contact Lablink (Auckland City Hospital ext. 22000 or 09-3078995) or hospital operator for on duty staff after hours.

Dr Samarina Musaad (Clinical Lead) : SamarinaM@adhb.govt.nz ext. 22402

Dr Cam Kyle: CampbellK@adhb.govt.nz ext 22052

Dr Weldon Chiu: WeldonC@adhb.govt.nz ext. 23427

Dr Campbell Heron: CHeron@adhb.govt.nz ext. 23427

Dr Sakunthala Jayasinghe: Sakunthala@adhb.govt.nz ext. 23427

Specimen Transport Instructions for Referring Laboratories

Instructions for Referral to LabPlus
Aliquot Instructions	2 x 4 mL EDTA Whole blood. Fridge
Aliquot Transport	4 C

Last updated at 15:26:00 06/01/2025