Nicholas Adeline K, Serra Eva G, Cangul Hakan, Alyaarubi Saif, Ullah Irfan, Schoenmakers Erik, Deeb Asma, Habeb Abdelhadi M, Almaghamsi Mohammad, Peters Catherine, Nathwani Nisha, Aycan Zehra, Saglam Halil, Bober Ece, Dattani Mehul, Shenoy Savitha, Murray Philip G, Babiker Amir, Willemsen Ruben, Thankamony Ajay, Lyons Greta, Irwin Rachael, Padidela Raja, Tharian Kavitha, Davies Justin H, Puthi Vijith, Park Soo-Mi, Massoud Ahmed F, Gregory John W, Albanese Assunta, Pease-Gevers Evelien, Martin Howard, Brugger Kim, Maher Eamonn R, Chatterjee V Krishna K, Anderson Carl A, Schoenmakers Nadia
University of Cambridge Metabolic Research Laboratories (A.K.N., E.S., G.L., V.K.K.C., N.S.), Wellcome Trust-Medical Research Council Institute of Metabolic Science, Addenbrooke's Hospital, Cambridge, United Kingdom; Department of Human Genetics (E.G.S., C.A.A.), The Wellcome Trust Sanger Institute, Hinxton, Cambridge, United Kingdom; Research Centre for Regenerative and Restorative Medicine (H.C.), Department of Medical Genetics Istanbul Medipol University, Kavacık, Istanbul, Turkey; Pediatric Endocrine Unit (S.A., I.U.), Department of Child Health, Sultan Qaboos University Hospital, Muscat, Oman; Paediatric Endocrinology Department (A.D.), Mafraq Hospital, AbuDhabi, United Arab Emirates; Pediatric Department Prince Mohamed Bin Abdulaziz Hospital (A.M.H.), Madinah, Kingdom of Saudi Arabia; Department of Paediatrics (M.A.), Madina Maternity & Children's Hospital Madina Munawara, Saudi Arabia; 8. Department of Endocrinology (C.P.), Great Ormond St Hospital for Children, London, United Kingdom; Department of Paediatrics (N.N.), Luton and Dunstable University Hospital, Luton, United Kingdom; Division of Paediatric Endocrinology (Z.A.), Dr Sami Ulus Woman Health and Children Research Hospital Ankara, Turkey; Department of Paediatric Endocrinology (H.S.), Uludağ University, School of Medicine Bursa, Turkey; Department of Paediatric Endocrinology (E.B.), Dokuz Eylül University, Faculty of Medicine Izmir, Turkey; Developmental Endocrinology Research Group (M.D.), Section of Genetics and Epigenetics in Health and Disease, Genetics and Genomic Medicine Programme, University College London Institute of Child Health, London, United Kingdom; Department of Paediatrics (S.S.), Leicester Royal infirmary, Leicester United Kingdom; Centre for Paediatrics and Child Health (P.G.M.), Institute of Human Development University of Manchester, and Royal Manchester Children's Hospital, Manchester, United Kingdom; Paediatric Endocrinology Division (A.B.), College of Medicine, King Saud University and King Saud University Medical City, Riyadh, Saudi Arabia; Department of Paediatrics (R.W., A.T.), University of Cambridge, Cambridge Biomedical Campus, Cambridge, United Kingdom; W Midlands Regional Genetics Laboratory (R.I.), Birmingham Women's Hospital NHS Foundation Trust, Birmingham, United Kingdom; Department of Paediatric Endocrinology (R.P.), Central Manchester University Hospitals NHS Foundation Trust, Manchester, United Kingdom; Department of Paediatrics (K.T.), Diana Princess of Wales Hospital, Grimsby, United Kingdom; Department of Paediatric Endocrinology (J.H.D.), University Hospital Southampton, Southampton, United Kingdom; Department of Paediatrics (V.P.), Peterborough and Stamford Hospitals NHS Foundation Trust, Peterborough, United Kingdom; Department of Clinical Genetics (S.-M.P.), Cambridge University Hospitals NHS Foundation Trust, Cambridge United Kingdom; London N W Healthcare NHS Trust (A.F.M.), Harrow, Middlesex, United Kingdom; Division of Population Medicine (J.W.G.), School of Medicine, Cardiff University, Heath Park Cardiff, UK; Department of Paediatric Endocrinology (A.A.), St George's University Hospitals NHS Foundation Trust, London, United Kingdom; Centre for Endocrinology (E.P.-G.), William Harvey Research Institute, Queen Mary University London and Children's Hospital, Barts Health NHS Trust, London, United Kingdom; Department of Medical Genetics (H.M., K.B., E.R.M.), University of Cambridge and NIHR Cambridge Biomedical Research Centre, Cambridge, United Kingdom.
J Clin Endocrinol Metab. 2016 Dec;101(12):4521-4531. doi: 10.1210/jc.2016-1879. Epub 2016 Aug 15.
Lower TSH screening cutoffs have doubled the ascertainment of congenital hypothyroidism (CH), particularly cases with a eutopically located gland-in-situ (GIS). Although mutations in known dyshormonogenesis genes or TSHR underlie some cases of CH with GIS, systematic screening of these eight genes has not previously been undertaken.
Our objective was to evaluate the contribution and molecular spectrum of mutations in eight known causative genes (TG, TPO, DUOX2, DUOXA2, SLC5A5, SLC26A4, IYD, and TSHR) in CH cases with GIS. Patients, Design, and Setting: We screened 49 CH cases with GIS from 34 ethnically diverse families, using next-generation sequencing. Pathogenicity of novel mutations was assessed in silico.
PATIENTS, DESIGN, AND SETTING: We screened 49 CH cases with GIS from 34 ethnically diverse families, using next-generation sequencing. Pathogenicity of novel mutations was assessed in silico.
Twenty-nine cases harbored likely disease-causing mutations. Monogenic defects (19 cases) most commonly involved TG (12), TPO (four), DUOX2 (two), and TSHR (one). Ten cases harbored triallelic (digenic) mutations: TG and TPO (one); SLC26A4 and TPO (three), and DUOX2 and TG (six cases). Novel variants overall included 15 TG, six TPO, and three DUOX2 mutations. Genetic basis was not ascertained in 20 patients, including 14 familial cases.
The etiology of CH with GIS remains elusive, with only 59% attributable to mutations in TSHR or known dyshormonogenesis-associated genes in a cohort enriched for familial cases. Biallelic TG or TPO mutations most commonly underlie severe CH. Triallelic defects are frequent, mandating future segregation studies in larger kindreds to assess their contribution to variable phenotype. A high proportion (∼41%) of unsolved or ambiguous cases suggests novel genetic etiologies that remain to be elucidated.
降低促甲状腺激素(TSH)筛查临界值使先天性甲状腺功能减退症(CH)的确诊率翻倍,尤其是异位甲状腺原位(GIS)病例。尽管已知的激素合成障碍基因或促甲状腺激素受体(TSHR)的突变是一些GIS型CH病例的病因,但此前尚未对这八个基因进行系统筛查。
我们的目的是评估八个已知致病基因(TG、TPO、DUOX2、DUOXA2、SLC5A5、SLC26A4、IYD和TSHR)的突变在GIS型CH病例中的作用及分子谱。患者、设计与研究地点:我们采用二代测序技术对来自34个不同种族家庭的49例GIS型CH病例进行了筛查。通过计算机模拟评估新突变的致病性。
患者、设计与研究地点:我们采用二代测序技术对来自34个不同种族家庭的49例GIS型CH病例进行了筛查。通过计算机模拟评估新突变的致病性。
29例携带可能致病的突变。单基因缺陷(19例)最常见于TG(12例)、TPO(4例)、DUOX2(两例)和TSHR(1例)。10例携带三等位基因(双基因)突变:TG和TPO(1例);SLC26A4和TPO(3例),以及DUOX2和TG(6例)。新变异总体包括15个TG突变、6个TPO突变和3个DUOX2突变。20例患者(包括14例家族性病例)未确定遗传基础。
GIS型CH的病因仍然不明,在一个富含家族性病例的队列中,只有59%可归因于TSHR或已知的激素合成障碍相关基因的突变。双等位基因TG或TPO突变是严重CH最常见的病因。三等位基因缺陷很常见,这就要求未来在更大的家族中进行分离研究,以评估它们对可变表型的影响。高比例(约41%)的未解决或不明确病例提示仍有待阐明的新遗传病因。
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