Thiamine-responsive Megaloblastic Anemia: Identification of Novel Compound Heterozygotes and Mutation Update

Overview

Journal J Pediatr

Specialty Pediatrics

Date 2009 Aug 1

PMID 19643445

Citations 28

Authors

Anke K Bergmann

Inderneel Sahai

Jill F Falcone

Judy Fleming

Adam Bagg

Caterina Borgna-Pignati

Robin Casey

Luca Fabris

Elizabeth Hexner

Lulu Mathews

Maria Leticia Ribeiro

Klaas J Wierenga

Ellis J Neufeld

Affiliations

Soon will be listed here.

Abstract

Objective: To determine causative mutations and clinical status of 7 previously unreported kindreds with TRMA syndrome, (thiamine-responsive megaloblastic anemia, online Mendelian inheritance in man, no. 249270), a recessive disorder of thiamine transporter Slc19A2.

Study Design: Genomic DNA was purified from blood, and SLC19A2 mutations were characterized by sequencing polymerase chain reaction-amplified coding regions and intron-exon boundaries of all probands. Compound heterozygotes were further analyzed by sequencing parents, or cloning patient genomic DNA, to ascertain that mutations were in trans.

Results: We detected 9 novel SLC19A2 mutations. Of these, 5 were missense, 3 were nonsense, and 1 was insertion. Five patients from 4 kindreds were compound heterozygotes, a finding not reported previously for this disorder, which has mostly been found in consanguineous kindreds.

Conclusion: SLC19A2 mutation sites in TRMA are heterogeneous; with no regional "hot spots." TRMA can be caused by heterozygous compound mutations; in these cases, the disorder is found in outbred populations. To the extent that heterozygous patients were ascertained at older ages, a plausible explanation is that if one or more allele(s) is not null, partial function might be preserved. Phenotypic variability may lead to underdiagnosis or diagnostic delay, as the average time between the onset of symptoms and diagnosis was 8 years in this cohort.

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