Doga Turkkahraman

Permanent neonatal diabetes mellitus caused by a novel homozygous (T168A) glucokinase (GCK) mutation: initial response to oral sulphonylurea therapy.

OBJECTIVE To evaluate the clinical response to sulphonylurea treatment in a child with a homozygous T168A GCK (glucokinase) mutation, causing permanent neonatal diabetes mellitus (PNDM). STUDY DESIGN Oral glibenclamide was given for 3 months. Pancreatic beta cell function was assessed by a glucagon stimulation test. Mutant and wild-type (WT) GCK were characterized. RESULTS Sulphonylurea treatment resulted in a 12-fold increase in basal and stimulated C-peptide levels. HbA1c levels were reduced from 9.4% to 8.1% on a reduced insulin dose (0.85 to 0.60 U/kg/day). Mutant T168A-GST-GCK showed reduced kinetic activity (0.02 fold) compared to WT. CONCLUSIONS Sulphonylureas can close the adenosine triphosphate (ATP)-sensitive potassium channel and elicit insulin secretion, but the ATP generated from metabolism is insufficient to fully restore insulin secretory capacity. Nonetheless, sulphonylurea treatment should be tried in patients with GCK-PNDM, particularly those with mutations resulting in less severe kinetic defects, in whom improved glycemic control may be obtained with lower doses of insulin.

Bone metabolism markers and bone mineral density in children with neurofibromatosis type-1

Some experimental studies suggested that there may be a bone formation defect rather than a disorder in bone resorption in patients NF1. The aim of this study was to determine bone mineral density (BMD) with dual-energy X-ray absorptiometry (DEXA) and investigate specific bone formation and bone resorption and bone turnover markers in children with NF1. Thirty-two children and adolescents (16 boys, 16 girls; 16 prepubertal, 16 pubertal) with NF1 were recruited. Their age ranged from 3 to 17 years. They were compared with matched healthy children. Dual-energy X-ray absorptiometry were applied to 26 patients and 27 controls. Nine of 32 subjects with NF1 had a skeletal abnormality. BMD of the lumbar spine, and femoral neck in NF1 patients significantly decreased compared to that of healthy subjects. They were also significantly decreased in pubertal patients when compared to pubertal controls and in prepubertal patients when compared to prepubertal controls. Patients with skeletal abnormalities were found to have significantly lower level of osteocalcin when compared to patients without skeletal abnormality. Other biochemical markers did not exhibit any difference between the groups. In conclusion, our findings suggest that bone formation markers rather than DEXA could be good predictors of skeletal abnormalities among NF1 patients. However, in our study the number of the NF1 patients with skeletal abnormality and the number of bone formation markers studied were all limited. It is appropriate to perform larger studies with other bone formation markers beside osteocalcin.

CTLA-4 (+49A/G) Polymorphism and Type-1 Diabetes in Turkish Children

Objective: To evaluate the contribution of cytotoxic T-Iymphocyte antigen-4 (CTLA-4)+49A/G polymorphism to the susceptibility to type-1 diabetes (T1D) in Turkish children. Methods: A case-control study was designed to include 91 Turkish children with T1D and 99 healthy controls. CTLA-4 (+99A/G) gene polymorphism typing was done by PCR amplification followed by restriction fragment length polymorphism method. Results: The genotype and allele frequencies of the CTLA-4 (+99A/G) polymorphism in patients with T1D were not different from those in the controls (p>0.05). The allele frequency of G was 36.2% in patients with T1D, and 31.8% in controls (p>0.05). Additionally, this polymorphism was not associated with the clinical and laboratory characteristics of the patients with T1D (p>0.05). Conclusions: Our case-control study suggests that the CTLA-4 (+99A/G) gene polymorphism is not associated with T1D in the Turkish population. Conflict of interest:None declared.

Successful Granulocyte Colony-stimulating Factor Treatment of Relapsing Candida albicans Meningoencephalitis Caused by CARD9 Deficiency.

Caspase-associated recruitment domain-9 (CARD9) deficiency is an autosomal-recessive primary immunodeficiency with genetic defects in Th17 immunity marked by susceptibility to recurrent and invasive Candida infections. We present a case of relapsing Candida albicans meningoencephalitis over 1-year period despite appropriate antifungal therapy. We detected a homozygous p.Q295X mutation in CARD9 as well as a defective interleukin-17 and interferon gamma synthesis in Enzyme-Linked ImmunoSpot tests. We achieved complete clinical remission, and improvement of interleukin-17 secretion with subcutaneous granulocyte colony-stimulating factor) treatment.

Phenotypic severity of homozygous GCK mutations causing neonatal or childhood-onset diabetes is primarily mediated through effects on protein stability

Mutations in glucokinase (GCK) cause a spectrum of glycemic disorders. Heterozygous loss-of-function mutations cause mild fasting hyperglycemia irrespective of mutation severity due to compensation from the unaffected allele. Conversely, homozygous loss-of-function mutations cause permanent neonatal diabetes requiring lifelong insulin treatment. This study aimed to determine the relationship between in vitro mutation severity and clinical phenotype in a large international case series of patients with homozygous GCK mutations. Clinical characteristics for 30 patients with diabetes due to homozygous GCK mutations (19 unique mutations, including 16 missense) were compiled and assigned a clinical severity grade (CSG) based on birth weight and age at diagnosis. The majority (28 of 30) of subjects were diagnosed before 9 months, with the remaining two at 9 and 15 years. These are the first two cases of a homozygous GCK mutation diagnosed outside infancy. Recombinant mutant GCK proteins were analyzed for kinetic and thermostability characteristics and assigned a relative activity index (RAI) or relative stability index (RSI) value. Six of 16 missense mutations exhibited severe kinetic defects (RAI ≤ 0.01). There was no correlation between CSG and RAI (r2 = 0.05, P = 0.39), indicating that kinetics alone did not explain the phenotype. Eighty percent of the remaining mutations showed reduced thermostability, the exceptions being the two later-onset mutations which exhibited increased thermostability. Comparison of CSG with RSI detected a highly significant correlation (r2 = 0.74, P = 0.002). We report the largest case series of homozygous GCK mutations to date and demonstrate that they can cause childhood-onset diabetes, with protein instability being the major determinant of mutation severity.

Analysis of TPO gene in Turkish children with iodide organification defect: identification of a novel mutation

The objective was to determine molecular genetic analysis of the TPO gene in Turkish children with iodide organification defect (IOD). Patients with a diagnosis of primary hypothyroidism were evaluated. Subjects having a definite diagnosis of autoimmune thyroiditis, thyroid gland dysplasia and, or iodine deficiency were excluded. A total of 10 patients from nine unrelated Turkish families, with an unknown etiology of hypothyroidism, and with a presumptive diagnosis of IOD were included in the study. A perchlorate discharge test (PDT) was performed to all subjects, and sequence analysis of TPO gene was applied in patients with a positive PDT. Five out of 10 patients have a total IOD, while the five remaining patients have a partial IOD according to PDT results. In two sisters, one has a partial and the other one has a total IOD a novel homozygous nonsense p.Q315X mutation was found in exon 8. Additionally, a previously known homozygous missense p.R314W mutation was detected in the same exon in another patient with a total IOD. No TPO gene mutation was detected in any of the seven remaining patients. Two different TPO gene mutations were found to be responsible for IOD in two unrelated Turkish families from the same ethnic background. More subjects should be screened for detecting the prevalence and spectrum profile of TPO mutations in our population that might be helpful for understanding the pathophysiology of congenital hypothyroidism.

Wolcott-Rallison syndrome due to a novel mutation (R491X) in EIF2AK3 gene.

Wolcott-Rallison syndrome (WRS) is a rare autosomal recessive disordercharacterized by early-onset diabetes, spondyloepiphyseal dysplasia,tendency to skeletal fractures secondary to osteopenia, and growthretardation. Mutations in the eukaryotic translation initiation factor 2αkinase (EIF2AK3)gene are responsible for this disorder. Here, wedescribe a boy with neonatal diabetes, diagnosed at 2 months of age,who developed severe growth retardation and a skeletal fracture duringthe follow-up period. The patient’s skeletal X-ray revealed findings ofskeletal dysplasia. A clinical diagnosis of WRS was confirmed by theidentification of a novel homozygous nonsense mutation (R491X) in exon9 of the EIF2AK3 gene. The aim of this report is to raise the awarenessfor Wolcott-Rallison syndrome in cases presenting with isolatedneonatal diabetes. This patient demonstrates that the other findings ofthis syndrome might be obscured by a diagnosis of isolated neonataldiabetes. Conflict of interest:None declared.

A novel DAX-1 mutation presented with precocious puberty and hypogonadotropic hypogonadism in different members of a large pedigree.

Abstract Patients with DAX-1 gene mutations on chromosome Xp21 usually present with adrenal hypoplasia congenita and hypogonadotropic hypogonadism. Yet, neither correlation between the type of mutation and the age of onset of the disease nor mechanism of the mutation on puberty is fully understood. Here, we report a novel non-sense p.Gln208X mutation in the amino terminal domain of the DAX-1 gene observed in a large family with three boys presenting with adrenal manifestations at different ages. Furthermore, two boys developed spontaneous puberty that failed to progress at similar ages, whereas the other boy developed precocious puberty at 10 month of age. The unique structure of the DAX-1 gene may explain this phenotypic variability. However, more studies are needed to understand the role of the DAX-1 gene on development of the adrenal gland and hypothalamus-pituitary-gonadal axis.

Final diagnosis in children with subclinical hypothyroidism and mutation analysis of the thyroid peroxidase gene (TPO).

AIM To determine the final diagnosis of patients with subclinical hypothyroidism (SCH), and to perform mutation screening of the thyroid peroxidase gene (TPO). METHODS Infants with SCH without an identified etiology were included in the study. Patients with thyroid dysgenesis were excluded. Children > or = 2 years of age, and still on L-thyroxine (LT4) treatment underwent a diagnostic algorithm. After LT4 was discontinued for 4 weeks, thyroid function tests (TFT) were obtained. A perchlorate discharge test (PDT) was performed in patients with normal thyroid ultrasound but abnormal TFT. Sequence analysis of TPO was studied in all children who underwent a PDT. RESULTS Forty-eight patients (23 males and 25 females) completed the trial. Among these children, 19 (39.5%) had transient SCH, and 29 (60.5%) had permanent SCH. Among patients with permanent SCH, 19 had thyroid hypoplasia, six had partial iodide organification defect with positive PDT, and four had other dyshormonogenesis with negative PDT. Mean LT4 dose before the medication ceased was 1.2 +/- 0.5 microg/kg/day in transient cases, and 1.7 +/- 0.4 in those with permanent SCH (p < 0.05). No TPO mutation was detected. However, in five patients, seven different previously known TPO polymorphisms were detected: c.102C > G, L4L; > A, A576A; c.2088C > T, D666D; c.2263A > C, T725P; c.2630 T >C, V847A. CONCLUSIONS LT4 treatment should be stopped after the age of 2 years in infants with SCH without a definite pathology of the thyroid gland to exclude cases with transient hypothyroidism. Additionally, we should consider particularly thyroid gland hypoplasia, and also partial defects in iodide organification in infants with SCH.

Clinical and molecular genetic analysis in three children with Wolfram Syndrome: a novel WFS1 mutation (c.2534T>A).

Wolfram syndrome (WS) is an autosomal recessive disorder caused by mutations in WFS1 gene. The clinical features include diabetes insipidus, diabetes mellitus (DM), optic atrophy, deafness, and other variable clinical manifestations. In this paper, we present the clinical and genetic characteristics of 3 WS patients from 3 unrelated Turkish families. Clinical characteristics of the patients and the age of onset of symptoms were quite different in each pedigree. The first two cases developed all symptoms of the disease in their first decade of life. The heterozygous father of case 2 was symptomatic with bilateral deafness. The first ocular finding of one patient (patient 3) was bilateral cataract which was accompanying DM as a first feature of the syndrome. In this patient’s family, there were two members with features suggestive of WS. Previously known homozygous mutations, c.460+1G>A in intron 4 and c.1885C>T in exon 8, were identified in these cases. A novel homozygous c.2534T>A mutation was also detected in the exon 8 of WFS1 gene. Because of the rarity and heterogeneity of WS, detection of specific and nonspecific clinical signs including ocular findings and family history in non-autoimmune, insulinopenic diabetes cases should lead to a tentative diagnosis of WS. Genetic testing is required to confirm the diagnosis.