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Врожденный гипотиреоз - гетерогенная группа заболеваний, объединенных общим признаком - снижением функции щитовидной железы (ЩЖ) к моменту рождения. 80-85% случаев заболевания обусловлены различными вариантами нарушения органогенеза ЩЖ. На сегодняшний день в литературе описано 5 генов: i>TSHR, PAX8, FOXE1, NKX2-1, NKX2-5,/i> задействованных в патогенезе дисгенезии щитовидной железы. Цель. Оценить частоту мутаций в генах i>TSHR, PAX8, FOXE1, NKX2-1, NKX2-5/i> среди пациентов с тяжелым врожденным гипотиреозом. Методы. В исследование включен 161 пациент с врожденным гипотиреозом (64 мальчика, 97 девочек) с уровнем тиреотропного гормона по данным скрининга или ретестирования более 90 мМЕ/л. При ультразвуковом исследовании ЩЖ у 138 обследуемых диагностированы различные варианты дисгенезии, у 23 пациентов объем железы соответствовал нормальным значениям относительно площади поверхности тела. Для молекулярно-генетического анализа применялся метод высокопроизводительного параллельного секвенирования. Секвенирование осуществлялось на полупроводниковом секвенаторе PGM (Ion Torrent, Life Technologies, США) с использованием панели праймеров “Гипотиреоз” (Custom DNA Panel). Оценка патогенности мутаций осуществлялась согласно последним международным рекомендациям (ACMG, 2015). Результаты. Мутации в генах, приводящие к дисгенезии щитовидной железы, были выявлены у 13 пациентов (8,1%, 13/161): i>TSHR/i>, i>n/i> = 6; i>NKX2-1/i>, i>n/i> = 3; i>NKX2-5/i>, i>n/i> = 1; i>PAX8/i>, i>n/i> = 3; i>FOXE1/i>, i>n/i> = 0. Заключение. Мутации в генах, обусловливающие развитие дисгенезии щитовидной железы, являются редкой патологией. Среди наших пациентов наибольшее количество мутаций выявлено в гене i>TSHR/i>.
Ключевые слова:
дисгенезия, высокопроизводительное параллельное секвенирование, врожденный гипотиреоз, thyroid dysgenesis, next generation sequencing, congenital hypothyroidism
Литература:
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Congenital hypothyroidism is a heterogeneous group of diseases, which is manifested by loss of function of the thyroid gland that affects infants from birth. 80-85% of cases are due to different types of thyroid dysgenesis. 5 genes have been described that are involved in the pathogenesis of thyroid dysgenesis: i>TSHR, PAX8, FOXE1, NKX2-1, NKX2-5/i>. Aims. To evaluate the prevalence of mutations in the genes i>TSHR, PAX8, FOXE1, NKX2-1, NKX2-5/i> among patients with severe congenital hypothyroidism. Materials and methods. 161 patients (64 boys, 97 girls) with congenital hypothyroidism (TSH levels at neonatal screening or retesting greater than 90 mU/l) were included in the study. 138 subjects had different variants of thyroid dysgenesis, and 23 patients had normal volume of the gland. A next generation sequencing was used for molecular-genetic analysis. Sequencing was performed using PGM semiconductor sequencer (Ion Torrent, Life Technologies, USA) and a panel “Hypothyroidism” (Custom DNA Panel). Assessment of the pathogenicity of sequence variants were carried out according to the latest international guidelines (ACMG, 2015). Results. 13 patients had variants in thyroid dysgenesis genes (8,1%, 13/161): i>TSHR/i>, i>n/i> = 6; i>NKX2-1/i>, i>n/i> = 3; i>NKX2-5/i>, i>n/i> = 1; i>PAX8/i>, i>n/i> = 3; i>FOXE1/i>, i>n/i> = 0. Conclusions. Mutations in thyroid dysgenesis genes are a rare pathology. The majority of variants among our patients were identified in i>TSHR/i>.
Keywords:
дисгенезия, высокопроизводительное параллельное секвенирование, врожденный гипотиреоз, thyroid dysgenesis, next generation sequencing, congenital hypothyroidism
