A Rare Genetic Disorder in Juvenile Diabetes: Wolfram Syndrome - Case Report
幼年糖尿病中一種罕見遺傳病：Wolfram綜合徵 - 病例報導
Wolfram syndrome is a hereditary autosomal recessive disease with an estimated prevalence of 1/550,000 in children. The mutations of the Wolfram syndrome 1 gene, which encodes Wolframin are responsible for the majority of cases of Wolfram syndrome. In this case report, a 16-year-old young man with a medical history of diabetes mellitus and bilateral blindness secondary to optic atrophy presented with severe hyperglycaemia without ketoacidosis. Polyuria secondary to partial neurologic diabetes insipidus, primary hypogonadism and bilateral sensorineural hearing loss were also identified. The genetic diagnosis of Wolfram syndrome was ultimately confirmed through genetic studies of patient and his mother. With the knowledge of Wolfram syndrome being a rare genetic disorder causing juvenile non-autoimmune diabetes, the early diagnosis is imperative to provide proper early managements. With genetic analysis of patient with suspected features, the early diagnosis becomes an achievable reality.
Keyword : Juvenile diabetes; Optic atrophy; Wolfram syndrome
Wolfram syndrome, a rare hereditary autosomal recessive disease, also called DIDMOAD because of its clinical features of diabetes insipidus (DI), diabetes mellitus (DM), optic atrophy and deafness.1 The prevalence of the syndrome in the UK is estimated to be 1/770,000.1 The estimated prevalence in children has been reported to be around 1/500,000.2 The median age at death of Wolfram syndrome patients was 30 years (range 25-49) and these patients usually die as a result of central respiratory failure.1 The mutations of the Wolfram syndrome 1 (WFS1) gene, mapped on chromosome 4p16.13 are responsible for the majority of Wolfram syndrome. Another new locus, Wolfram syndrome 2 (WFS2) gene, mapped on chromosome 4q22-q24 was identified by El-Shanti et al in 2000.4
A juvenile male patient was diagnosed with type 1 DM at age of 10 years and was treated with human regular insulin and human isophane insulin. He had progressive visual impairment since age of 8 years and optic atrophy was diagnosed at age of 11 years. He had total blindness since age of 14 years. He presented to a local hospital at age of 16 years with hyperglycaemia (Glucose 959 mg/dl 53.23 mmol/L) without ketoacidosis. His BMI was 18.8 kg/m2 (height 158 cm, weight 47 kg). The HbA1c was 14.5%. His fasting C-Peptide was 0.49 ng/ml indicating an insulin deficiency. After his blood glucose had been under control, he still suffered from polyuria (urine volume over 5000 ml/day). The water deprivation test revealed partial neurologic DI (urine osmolality increased from 481 to 589 mOsm/kg after subcutaneous injection of 2 microgram desmopressin). The MRI of the pituitary fossa revealed unremarkable change in the pituitary gland (Figure 1A). The sex hormone levels at age of 17 years disclosed primary hypogonadism (FSH 59 mIU/mL, LH 39.93 mIU/mL, Testosterone 171.96 ng/dL 5.96 nmol/L). An image of ocular fundus examination showed bilateral optic disc pallor, indicating optic atrophy (Figure 1B). An audiogram at age of 18 years revealed bilateral sensorineural hearing loss (Figure 1C).
His severe hyperglycaemia without the presence of ketoacidosis and blindness secondary to optic atrophy raise a query regarding his previous diagnosis of type 1 DM. His clinical features, including DI, DM, optic atrophy and hearing impairment, suggested the possibility of Wolfram syndrome.
The genetic studies for WFS1 gene of patient and his mother showed that patient had a mutation Q667X5 in one allele and a novel mutation A370fsX445 inherited from his mother in another allele (Figure 2). The mutation (Gln→X) at amino acid residue 667 in exon 8 predicted a protein product with the majority of the carboxy tail deleted. The insertion mutation, inherited from his mother, came from 11 base pairs (CGGACAGCAAG) insertion in exon 8, which caused a frameshift at codon 370 and lead to premature termination at codon 445, resulting in a complete absence of the carboxy tail of the WFS1 protein. The result of molecular study confirmed the diagnosis of Wolfram syndrome.
Wolfram syndrome is a hereditary neurodegenerative disease. Non-autoimmune DM usually presents at average age of 6 years (range 3 weeks to 16 years). Optic atrophy presents at a median age of 10 years (range 6 weeks to 19 years) with reduced visual acuity leading to blindness in most of the patients. Neurologic DI occurred at average age of 15.5 years and sensorineural deafness develops in the second decade (average age of 16 years).1
This patient was previously diagnosed with type 1 DM. His low fasting C-Peptide indicated an insulin deficiency. His HbA1c (14.5%) revealed a poorly controlled DM. It is well known that patients with poorly controlled auto-immune type 1 diabetes are prone to ketoacidosis. This patient's presentation of severe hyperglycaemia without the presence of ketoacidosis and the molecular evidence of Wolfram syndrome led to revision of the patient's diagnosis of DM. In the UK nationwide study, C-peptide assays showed insulin deficiency and all of the patients assessed for antibodies to glutamic acid decarboxylase were negative.1 This patient's clinical course and the evidence from the UK study alert clinicians on the possible diagnosis of Wolfram syndrome in juvenile patients with features of non-autoimmune insulin-deficient DM.
Poorly controlled diabetes are complicated with multiorgan disorders, such as nephropathy, retinopathy, neuropathy and vasculopathy. However, some monogenetic diseases, such as maternally inherited diabetes and deafness (MIDD), Alstrome syndrome and Wolfram syndrome, always associate with diabetes and also present with multiorgan involvement. It is important to distinguish these monogenetic diabetes from type 1 and type 2 diabetes because the optimal treatment and risk for complications varies with the underlying genetic defect. The molecular diagnosis of Wolfram syndrome reminds us the spectrum of this disorder. For earlier detection of central respiratory failure to prevent the early death of this syndrome, the respiratory condition of patients with Wolfram syndrome should be closely monitored.
The WFS1 gene is expressed in a variety of tissues, including heart, brain, placenta, lung, liver, skeletal muscle, kidney and pancreas6 and encodes Wolframin, a transmembrane protein with 890-aminoacid long.7 Wolframin is a membrane protein localised in the endoplasmic reticulum8 and plays a role in the regulation of the ionised Ca concentration in the endoplasmic reticulum.9 Other research findings showed that the WFS1 gene regulates endoplasmic reticulum stress signaling.10 Mutations in WFS1 gene and dysfunction of Wolframin contribute to the clinical features of Wolfram syndrome.
Genetic analysis for patient's father was not performed because we cannot obtain sample from his father. The mutation Q667X in one allele could be inherited from his father or get from sporadic mutation.
Wolfram syndrome is a rare genetic disorder in juvenile non-autoimmune diabetes. Its clinical features (the acronym DIDMOAD) are clues for early suspicion of this diagnosis. The screening for features of Wolfram syndrome is imperative, especially when patient has juvenile diabetes associated with optic atrophy. With the universal availability of molecular analysis, the early genetic diagnosis of Wolfram syndrome becomes an achievable reality.
Declaration of Interest
The authors declare that there are no conflicts of interest.
1. Barrett TG, Bundey SE, Macleod AF. Neurodegeneration and diabetes: UK nationwide study of Wolfram (DIDMOAD) syndrome. Lancet 1995;346:1458-63.
2. Kumar S. Wolfram syndrome: important implications for pediatricians and pediatric endocrinologists. Pediatr Diabetes 2010;11:28-37.
3. Inoue H, Tanizawa Y, Wasson J, et al. A gene encoding a transmembrane protein is mutated in patients with diabetes mellitus and optic atrophy (Wolfram syndrome). Nat Genet 1998;20:143-8.
4. El-Shanti H, Lidral AC, Jarrah N, Druhan L, Ajlouni K. Homozygosity mapping identifies an additional locus for Wolfram syndrome on chromosome 4q. Am J Hum Genet 2000;66:1229-36.
5. Hardy C, Khanim F, Torres R, et al. Clinical and molecular genetic analysis of 19 Wolfram syndrome kindreds demonstrating a wide spectrum of mutations in WFS1. Am J Hum Genet 1999;65:1279-90.
6. Strom TM, Hortnagel K, Hofmann S, et al. Diabetes insipidus, diabetes mellitus, optic atrophy and deafness (DIDMOAD) caused by mutations in a novel gene (wolframin) coding for a predicted transmembrane protein. Hum Mol Genet 1998;7:2021-8.
7. Hofmann S, Philbrook C, Gerbitz KD, Bauer MF. Wolfram syndrome: structural and functional analyses of mutant and wild-type wolframin, the WFS1 gene product. Hum Mol Genet 2003;12:2003-12.
8. Takeda K, Inoue H, Tanizawa Y, et al. WFS1 (Wolfram syndrome 1) gene product: predominant subcellular localization to endoplasmic reticulum in cultured cells and neuronal expression in rat brain. Hum Mol Genet 2001;10:477-84.
9. Takei D, Ishihara H, Yamaguchi S, et al. WFS1 protein modulates the free Ca(2+) concentration in the endoplasmic reticulum. FEBS Lett. 2006;580:5635-40.
10. Fonseca SG, Ishigaki S, Oslowski CM, et al. Wolfram syndrome 1 gene negatively regulates ER stress signaling in rodent and human cells. J Clin Invest 2010;120:744-55.
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