Eighteen-years follow-up of congenital hypothyroidism by TSHR gene p.Arg109Gln and p.Arg450His variants.

Congenital hypothyroidism (CH) is a common heterogeneous endocrine disorder. The thyroid-stimulating hormone receptor gene (TSHR) is one of the major candidate genes associated with CH. Studies have investigated the possible correlations between the specific clinical features and the presence of TSHR variants. However, only a few reports have focused on the long-term follow-up of patients with CH. Here we present a case of CH-associated TSHR p.Arg109Gln and p.Arg450His rare compound heterozygous variants, with a follow-up performed until adolescence. The patient had high serum TSH levels during newborn screening. Oral administration of levothyroxine (l-T4) was initiated at 1 month of age. The ultrasonogram revealed normal thyroid morphology and blood flow. Reduced uptake of I-123 and negative perchlorate test was observed. A small amount of l-T4 remained needed although l-T4 could be steadily reduced by puberty. The patient was diagnosed with orthotopic, nongoitrous, and permanent CH. He had no nonclassical TSH resistance. Patients with the TSHR p.Arg109Gln compound heterozygous variant exhibit permanent CH with high TSH levels and normal or slightly lower fT4 levels. In the future, genotype identification could help predict the long-term prognosis and reduce the requirement for detailed examinations. More case studies are needed to determine the relationship between genetic variants and clinical features in CH.

Idiopathic central precocious puberty with Prader-Willi syndrome: pubertal development with discontinuation of gonadotropin-releasing hormone analog.

Summary: Prader-Willi syndrome (PWS) is a genetic imprinting disorder that is characterized by obesity, short stature, and hypogonadism. Hypogonadism is characterized by normal luteinizing hormone (LH), high follicle-stimulating hormone (FSH), low testosterone, low inhibin B, and relatively low anti-Müllerian hormone (AMH). Only a few cases of central precocious puberty (CPP) have been reported in PWS, and follow-up for CPP with PWS is not established. Hence, we present a boy with PWS accompanied by CPP. Gonadotropin-releasing hormone analog (GnRHa) therapy was started at 7 years of age, CPP was adequately arrested, and GnRHa therapy was discontinued at 11.3 years of age. Growth hormone (GH) therapy was started at 12 years of age due to inadequate growth. He grew close to his final height, and his testes developed with normal LH, increased FSH, normal testosterone, and reduced AMH corresponding to puberty at 13.5 years of age. The features of 16 patients with PWS with CPP, including our patient, were summarized. Out of seven male patients, five were treated with GnRHa, as well as four out of nine female patients. Out of 16 patients, 6 were assessed with pubertal development over 13 years of age. Pubertal development was considered to be restored in four patients who had GnRHa therapy discontinuation. We should carefully follow-up on pubertal development in CPP. GnRHa therapy is useful for adequate puberty blockage, and pubertal development could be restored with GnRHa therapy discontinuation. Learning points: Pubertal development in Prader-Willi syndrome (PWS) varies from hypogonadism to precocious puberty. Pubertal development assessment based on clinical features and hormone levels is needed in central precocious puberty (CPP) treatment with PWS. Gonadotropin-releasing hormone analog (GnRHa) therapy is useful for CPP with PWS, and pubertal development can be restored with GnRHa therapy discontinuation.

Screening of frequent variants associated with congenital hypothyroidism: a comparison with next generation sequencing.

Congenital hypothyroidism (CH) is considered the most common congenital endocrine disorder of genetic origin. Next generation sequencing (NGS) is the standard method for identifying genetic mutations, but it is an expensive and complex technique. Therefore, we propose to use Sanger sequencing to identify selected variants of the four most common CH-causative genes: DUOX2, TG, TSHR, and PAX8. To analyze the performance of Sanger sequencing, we compared its variant detection ability with that of a CH NGS panel containing 53 genes. We performed Sanger sequencing of selected variants and panel NGS analysis of 25 Japanese patients with CH. Sanger sequencing identified nine variants in seven patients, while NGS identified 24 variants in 14 patients. Of these, eight, five, eight, two, and one were found to be potentially pathogenic in DUOX2, TSHR, TG, UBR1, and TPO genes, respectively. The percentage of detectable variants using Sanger sequencing compared with NGS was 37.5% (9/24 variants), whereas the percentage of detectable cases carrying variants using Sanger sequencing compared with NGS was 50% (7/14 patients). We proposed a system for screening commonly identified CH-related variants by Sanger sequencing. Sanger sequencing could therefore identify about a third of CH-causative variants, so is considered an effective and efficient form of pre-screening before NGS.

Incidence of childhood type 1 diabetes mellitus in Yamanashi Prefecture, Japan, 1986-2018.

Introduction: Several studies have examined the incidence of childhood T1DM in Japan from the 1970s onwards, but none have been long-term studies using registration data. We estimate the incidence of childhood type 1 diabetes mellitus (T1DM) from 1986 to 2018 in Yamanashi Prefecture, Japan. Methods: We began a population-based, long-term study of childhood T1DM in 1986 involving every hospital paediatrics department in Yamanashi Prefecture. In the Prefecture, every child newly diagnosed with T1DM is referred to a hospital, and therefore, almost 100% of new patients aged <15 years are registered. We calculated the incidence of T1DM among children aged <15 years from 1986 to 2018. All cases met the Japan Diabetes Society diagnostic criteria and were tested for T1DM-related autoantibodies whenever possible. Results: Ninety-nine patients (44 boys and 55 girls) were newly diagnosed with T1DM. The annual incidence among 5- to 9-year-olds increased by 5.35% over the study period (95% confidence interval 2.34%-8.35%, p = .0005), and there was a trend towards increasing 3-year incidence (15.52% increase, p = .0516). There were also trends towards increasing annual and 3-year incidence among 0- to 14-year-olds. However, there were no changes over time in annual or 3-year incidence in the 0-4 year or 10-14 year age groups. Conclusions: The incidence of T1DM in Yamanashi Prefecture increased among children aged 0-14 years over the study period, with the most significant increase occurring among 5- to 9-year-olds. These data suggest that the number of children aged <15 years with T1DM is gradually increasing in one of the local prefectures in Japan, Yamanashi Prefecture and that the age of onset is decreasing.

Role of counterregulatory hormones for glucose metabolism in children and adolescents with type 1 diabetes.

To elucidate the mechanism of insulin resistance due to insulin counterregulatory hormones (ICRHs) and evaluate ICRH secretion kinetics, ICRH concentrations were measured and correlated with blood glucose levels in 28 type 1 diabetic patients. Blood glucose was measured before bedtime. Early morning urine samples were collected the next morning before insulin injection and breakfast. Fasting blood glucose, cortisol, glucagon and HbA1c levels were measured. Growth hormone (GH), adrenaline, cortisol and C-peptide levels in morning urine samples were measured; SD scores were calculated for urine GH. The laboratory values (mean ± SD) were as follows; HbA1c of 8.1% ± 1.4%; pre-bedtime glucose of 203 ± 105 mg/dl; fasting blood glucose of 145 ± 87 mg/dl; serum cortisol of 21.6 ± 5.5 µg/dl; plasma glucagon of 98 ± 41 pg/ml; urinary GH, 27.2 ± 13.0 ng/gCr; urinary cortisol of 238 ± 197 ng/gCr; and urinary Adrenaline of 22.9 ± 21.0 ng/gCr. The mean urinary GH SD score was increased (+1.01 ± 0.70; p=0.000); the mean plasma glucagon lebel (98 ± 41 pg/ml) was not. Fasting blood glucose was positively correlated with plasma glucagon (R=0.378, p=0.0471) and negatively correlated with urinary cortisol (R=-0.476, p=0.010). Urinary adrenaline correlated positively with urinary GH (R=0.470, p=0.013) and urinary cortisol (R=0.522, p=0.004). In type 1 diabetes, GH, glucagon and cortisol hypersecretion may contribute to insulin resistance, but the mechanism remains unclear.