Jaszczuk I, Schlotawa L, Dierks T, Ohlenbusch A, Koppenhöfer
D, Babicz M, Lejman M, Radhakrishnan K, Ługowska A. Expanding the genetic
cause of multiple sulfatase deficiency: A novel SUMF1 variant in a patient
displaying a severe late infantile form of the disease. Mol Genet Metab. 2017
Jul;121(3):252-258.
Abstract
Multiple sulfatase deficiency (MSD) is a rare inherited
metabolic disease caused by defective cellular sulfatases. Activity of
sulfatases depends on post-translational modification catalyzed by
formylglycine-generating enzyme (FGE), encoded by the SUMF1 gene. SUMF1
pathologic variants cause MSD, a syndrome presenting with a complex phenotype.
We describe the first Polish patient with MSD caused by a yet undescribed
pathologic variant c.337G>A [p.Glu113Lys] (i.e. p.E113K) in heterozygous
combination with the known deletion allele c.519+5_519+8del
[p.Ala149_Ala173del]. The clinical picture of the patient initially suggested
late infantile metachromatic leukodystrophy, with developmental delay followed
by regression of visual, hearing and motor abilities as the most apparent
clinical symptoms. Transient signs of ichthyosis and minor dysmorphic features
guided the laboratory workup towards MSD. Since MSD is a rare disease and there
is a variable clinical spectrum, we thoroughly describe the clinical outcome of
our patient. The FGE-E113K variant, expressed in cell culture, correctly
localized to the endoplasmic reticulum but was retained intracellularly in
contrast to the wild type FGE. Analysis of FGE-mediated activation of steroid
sulfatase in immortalized MSD cells revealed that FGE-E113K exhibited only
approx. 15% of the activity of wild type FGE. Based on the crystal structure we
predict that the exchange of glutamate-113 against lysine should induce a
strong destabilization of the secondary structure, possibly affecting the
folding for correct disulfide bridging between C235-C346 as well as distortion
of the active site groove that could affect both the intracellular stability as
well as the activity of FGE. Thus, the novel variant of the SUMF1 gene obviously
results in functionally impaired FGE protein leading to a severe late infantile
type of MSD.
Miskin C, Melvin JJ, Legido A, Wenger DA, Harasink SM,
Khurana DS. A Patient With Atypical Multiple Sulfatase Deficiency. Pediatr Neurol.
2016 Apr;57:98-100.
Abstract
BACKGROUND:
Multiple sulfatase deficiency is an autosomal recessive
lysosomal storage disorder characterized by the absence of several sulfatases
and resulting from mutations in the gene encoding the human C
(alpha)-formylglycine-generating enzyme. There have been a variety of
biochemical and clinical presentations reported in this disorder.
PATIENT DESCRIPTION:
We present a 4-year-old girl with clinical findings of
microcephaly, spondylolisthesis and neurological regression without ichthyosis,
coarse facies, and organomegaly.
RESULTS:
The child's magnetic resonance imaging demonstrated confluent
white matter abnormalities involving the periventricular and deep cerebral
white matter with the U-fibers relatively spared. Biochemical testing showing
low arylsulfatase A levels were initially thought to be consistent with a
diagnosis of metachromatic leukodystrophy. The diagnosis of multiple sulfatase
deficiency was pursued when genetic testing for metachromatic leukodystrophy
was negative.
CONCLUSION:
This child illustrates the clinical heterogeneity of
multiple sulfatase deficiency and that this disorder can occur without the
classic clinical features.
Sabourdy F, Mourey L, Le Trionnaire E, Bednarek N, Caillaud C,
Chaix Y, Delrue MA, Dusser A, Froissart R, Garnotel R, Guffon N, Megarbane
A, Ogier de Baulny H, Pédespan JM, Pichard S, Valayannopoulos V, Verloes A, Levade
T. Natural disease history and characterisation of SUMF1 molecular defects in
ten unrelated patients with multiple sulfatase deficiency. Orphanet J Rare Dis.
2015 Mar 15;10:31.
Abstract
BACKGROUND:
Multiple sulfatase deficiency is a rare inherited metabolic
disorder caused by mutations in the SUMF1 gene. The disease remains poorly
known, often leading to a late diagnosis. This study aimed to provide improved
knowledge of the disease, through complete clinical, biochemical, and molecular
descriptions of a cohort of unrelated patients. The main objective was to identify
prognostic markers, both phenotypic and genotypic, to accelerate the diagnosis
and improve patient care.
METHODS:
The phenotypes of ten unrelated patients were fully
documented at the clinical and biochemical levels. The long-term follow-up of
each patient allowed correlations of the phenotypes to the disease outcomes.
Each patient's molecular defects were also identified. Site-directed
mutagenesis was used to individually express the mutants and assess their
stability. Characterisation of the protein mutants was completed by in silico
analyses based on sequence comparisons and structural models.
RESULTS:
The most severe cases were characterised by the presence of
non-neurological symptoms as well as the occurrence of psychomotor regression
before 2 years of age. Nine novel SUMF1 mutations were identified. Clinically
severe forms were often associated with SUMF1 mutations that strongly affected
the protein stability and/or catalytic function as predicted from in silico and
western blot analyses.
CONCLUSIONS:
This detailed clinical description and follow-up of a cohort
of patients, together with the molecular characterisation of their underlying
defects, contribute to improved knowledge of multiple sulfatase deficiency.
Predictors of a bad prognosis were the presence of several non-neurological
symptoms and the onset of psychomotor regression before 2 years of age. No
strict correlation existed between in vitro residual sulfatase activity and
disease severity. Genotype-phenotype correlations related to previously
reported mutants were strengthened. These and previous observations allow not
only improved prediction of the disease outcome but also provision of
appropriate care for patients, in the expectation of specific treatment
development.
See: http://childnervoussystem.blogspot.com/2016/09/multiple-sulfatase-deficiency.html
http://childnervoussystem.blogspot.com/2015/05/caringbridge.html
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