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Prepublished online as a Blood First Edition Paper on July 5, 2002; DOI 10.1182/blood-2002-05-1405.
FOCUS ON HEMATOLOGY
From the Department of Haematology, Belfast City
Hospital; Department of Haematology, Royal Victoria Hospital, Belfast;
and Departments of Medical Genetics and Haematology, Queen's
University, Belfast, Northern Ireland.
In 1943, the first description of familial idiopathic
methemoglobinemia in the United Kingdom was reported in 2 members of one family. Five years later, Quentin Gibson (then of Queen's University, Belfast, Ireland) correctly identified the pathway involved
in the reduction of methemoglobin in the family, thereby describing the
first hereditary trait involving a specific enzyme deficiency.
Recessive congenital methemoglobinemia (RCM) is caused by a deficiency
of reduced nicotinamide adenine dinucleotide (NADH)-cytochrome b5
reductase. One of the original propositi with the type 1 disorder has
now been traced. He was found to be a compound heterozygote harboring 2 previously undescribed mutations in exon 9, a point mutation Gly873Ala
predicting a Gly291Asp substitution, and a 3-bp in-frame
deletion of codon 255 (GAG), predicting loss of glutamic acid. A
brother and a surviving sister are heterozygous; each bears one of the
mutations. Thirty-three different mutations have now been recorded
for RCM. The original authors' optimism that RCM would provide
material for future genetic studies has been amply justified.
(Blood. 2002;100:3447-3449) In an era dominated by functional genomics, it is
salutary to reflect that the first hereditary disorder involving an
enzyme deficiency was discovered just over half a century ago by
Quentin Gibson.1 In 1943, Dr James Deeny, a general
practitioner, described 2 brothers, Russell and Fred Martin from
Banbridge in Northern Ireland, who had a blue appearance.2
When Russell was treated with vitamin C, he turned pink, and Dr Deeny
assumed that he had corrected an underlying heart condition. However,
the cardiologists in Belfast were more skeptical and were unable to
find any abnormality in either brother. The conundrum attracted the
attention of the physiologist Henry Barcroft, who carried out a
detailed study of Dr Deeny's cases during treatment and found raised
levels of methemoglobin in 2 members of the Martin
family.3 Gibson correctly defined the pathway involved in
the reduction of methemoglobin in the family, and, in so doing, he
described the first hereditary trait involving a specific enzyme
deficiency.1
The disorder recessive congenital methemoglobinemia (RCM; McKusick no.
250 800) is caused by a deficiency of reduced nicotinamide adenine
dinucleotide (NADH)-cytochrome b5 reductase (cytb5r: E.C.1.6.2.2). Two
forms of cytb5r are known, a soluble form and a membrane-bound form,
and are localized in different cellular compartments. The soluble form
is present mainly in red cells4 and is involved in the
reduction of methemoglobin.5 The membrane-bound form is
found mainly in the endoplasmic reticulum and outer mitochondrial membrane,6 where it participates in the desaturation and
elongation of fatty acids and in the biosynthesis of cholesterol and
P-450-mediated drug metabolism. The cytb5r gene is 31-kb
long, contains 9 exons, and has been localized to chromosome 22q
13-qter. Both forms of the enzyme are generated from tissue-specific
alternative transcripts (Figure 1), which
give rise to the 275-amino acid soluble form7 and the
300-amino acid membrane-bound form. They have an identical hydrophilic
catalytic domain but differ at the N-termini, where the membrane-bound
form has 25 additional hydrophobic amino acids. There are 2 distinct
clinical forms of cytb5r deficiency. Type 1 is characterized clinically
by a single symptom, cyanosis, and biochemically by a deficiency of the
red cell-soluble form of the enzyme.8 In type 2, cyanosis
is accompanied by severe mental retardation and neurologic impairment
involving the soluble and the membrane-bound forms of the
enzyme.9
We were curious to know the actual mutations involved in
Gibson's landmark discovery, and eventually we had the opportunity to analyze blood from one of the propositi, Fred, who had emigrated to
Australia in 1968, and from 2 surviving siblings.
Case history
Polymerase chain reaction amplification of genomic DNA
RNA isolation, cDNA synthesis, and cloning
Sequencing PCR products were purified using Concert Rapid PCR Purification System (Life Technologies) and were sequenced using ABI Prism BigDye Terminator Cycle Sequencing Ready Reaction Kit Version on ABI 3100 DNA Genetic Analyzer (Applied Biosytems, Warrington, United Kingdom).
The cytb5r activity, measured using the NADH-ferricyanide
method,10 was less than 0.1 IU/g hemoglobin in FM,
6.37 IU/g hemoglobin in BM, and 7.75 IU/g hemoglobin in EH (normal
range, 11.51-29.9 IU/g hemoglobin). These results suggested
that BM and EH were heterozygote carriers of a cyt5r mutation. DNA
sequencing of PCR products of the 9 exons revealed 2 mutations in exon
9 of FM, one in each allele. The first was a point mutation of G to A
at codon 291, which would cause a change of glycine to aspartic acid. The second was a 3-bp in-frame deletion resulting in the loss of codon
255 and the deletion of glutamic acid. Each sibling carries one
mutation In the late 1940s, when Gibson was investigating methemoglobinemia, Warburg and his colleagues11 had just shown that sugar is oxidized to pyruvate as methemoglobin is reduced to hemoglobin in intact red cells. It was also known that methylene blue accelerates the rate of reduction of methemoglobin. Gibson1 showed that methylene blue could reduce methemoglobin in the patients' red cells, but incubation of the cells with sugar alone had little effect. He postulated that these patients had an enzymatic defect. Later he showed that iodoacetic acid, an inhibitor of glyceraldehyde-3-phosphate-dehydrogenase, inhibited the reduction of methemoglobin when sugar, but not lactate, was added as substrate, and he deduced that the proposed enzyme defect affected the reaction between Coenzyme I (ie, NAD) and methemoglobin. This deduction was confirmed in many subsequent investigations. An intriguing account of this early work has been recorded by Gibson.12 These 2 hitherto unidentified mutations in the family originally
studied by Gibson bring to 33 the number of different mutations described in patients with RCM (Figure
3). Previously, 15 mutations had been
associated with the type 1 disorder13-20 and 16 with type 2 RCM.17,20-27 Mutations have been found in all exons but
1 and 1S. Mutations that cause exon skipping and those predicted to give truncated proteins with severe impairment of function have been
described only in type 2, except in one child in whom neurologic abnormalities were not observed at the age of 1 year.19
Because the structure of cytb5r has recently been resolved by x-ray
crystallography,28 it is possible to interpret the effects of mutations on enzyme function. Although the 2 novel exon 9 mutations are located outside the FAD and NADH binding sites, each would be
expected to have a deleterious effect on enzyme activity (Figure 4). Loss of E255 would affect the packed
hydrophobic environment formed by I177, L206, A208, T237, M256, M278,
and C283, and the presence of aspartic acid at codon 291 instead of the
nonpolar glycine would also lead to perturbation of the secondary
structure.
In 1943, Deeny et al2 reported the first case of RCM in the United Kingdom, and it was hoped that the mode of inheritance would be defined and the genetic basis of the disorder established. More than 40 years later the cytb5r gene was cloned, thereby allowing the genetic basis of the disorder to be defined. It took another 20 years for the mutations in the original family to be identified.
We thank Dr Quentin Gibson for making available his original notebooks and the propositi's sister, EH, for providing family histories.
Submitted May 14, 2002; accepted June 18, 2002.
Prepublished online as Blood First Edition Paper, July 5, 2002; DOI 10.1182/blood-2002-05-1405.
Supported by the Northern Ireland Leukaemia Research Fund.
Reprints: Melanie J. Percy, Department of Hematology, Floor C, Belfast City Hospital, Lisburn Road, Belfast, BT9 7AB, Northern Ireland; e-mail: melanie.percy{at}bll.n-i.nhs.uk.
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Top
Abstract
Introduction
one of the original propositi (#6, FM) who has RCM
type 1, a brother (#3, BM), and a sister (#5, EH). Unfortunately,
during the course of this study, both Fred Martin and his brother BM
died.
