186例矮小症患者遗传学检测结果分析

doi:10.12372/jcp.2022.21e1673

摘要/Abstract

摘要：

目的探讨儿童矮小症的遗传学病因。方法选取2017年1月—2020年10月因生长缓慢就诊的矮小症患儿为研究对象。行矮小相关基因的全外显子测序,对发现的可能的染色体片段拷贝数变异者进一步完善基因芯片检查,比较基因检测阳性与阴性组之间临床表型差异。结果共纳入186例矮小症患儿,中位年龄7.3（5.1~9.1）岁,男103例、女83例。共检测出69例阳性结果,阳性检出率37.1%。其中54例通过全外显子基因测序诊断,15例通过染色体微阵列分析诊断。二元logistic回归分析显示,特殊面容和骨骼发育异常是儿童矮小症基因检测结果阳性发生的预测因素（P均<0.05）。结论全外显子测序是检测儿童矮小症遗传病因的有效技术手段,伴有特殊面容和/或骨骼发育异常的患儿更可能检测到遗传病因。

关键词: 矮小症, 遗传病因, 基因型, 临床表型, 儿童

Abstract:

Objective To explore the genetic etiology of short stature in children. Methods This study selected children with short stature who were treated for growth disorder from January 2017 to October 2020. The whole exome sequencing (WES) was performed to identify potential genetic etiologies, and the possible copy number variants of chromosome fragments were further improved by chromosomal microarray analysis (CMA), and the clinical phenotypic differences between gene test positive and negative groups were compared. Results A total of 186 children with short stature were included, with a median age of 7.3 (5.1-9.1) years, including 103 boys and 83 girls. A total of 69 cases of positive results were detected, with a positive rate of 37.1%. Fifty-four were tested by WES and 15 by CMA. Binary logistic regression analysis showed facial dysmorphism or skeletal abnormalities were predictors of positive gene detection results in children with short stature (all P<0.05). Conclusion Whole exome sequencing is an effective technique to detect the genetic etiology of short stature in children, and Patients with facial dysmorphism and/or skeletal abnormalities are more likely to have a known genetic etiology.

Key words: short stature, genetic etiology, genotype, phenotype, child

王莉莉, 吴海瑛, 谢蓉蓉, 王凤云, 陈婷, 陈秀丽, 孙辉, 王晓艳, 张丹丹, 陈临琪. 186例矮小症患者遗传学检测结果分析[J]. 临床儿科杂志, 2022, 40(5): 349-354.

WANG Lili, WU Haiying, XIE Rongrong, WANG Fengyun, CHEN Ting, CHEN Xiuli, SUN Hui, WANG Xiaoyan, ZHANG Dandan, CHEN Linqi. Analysis of genetic test results in 186 cases with short stature[J]. Journal of Clinical Pediatrics, 2022, 40(5): 349-354.

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参考文献 23

[1]	Argente J. Challenges in the management of short stature[J]. Horm Res Paediatr, 2016, 85(1): 2-10. doi: 10.1159/000442350
[2]	中华医学会儿科学分会内分泌遗传代谢学组. 矮身材儿童诊治指南[J]. 中华儿科杂志, 2008, (6): 428-430.
[3]	Grunauer M, Jorge AAL. Genetic short stature[J]. Growth Horm IGF Res, 2018, 38: 29-33. doi: 10.1016/j.ghir.2017.12.003
[4]	Zhou E, Hauser BR, Jee YH. Genetic evaluation in children with short stature[J]. Curr Opin Pediatr, 2021, 33(4): 458-463. doi: 10.1097/MOP.0000000000001033
[5]	Hirschhorn JN, Lettre G. Progress in genome-wide association studies of human height[J]. Horm Res, 2009, 71(Suppl 2): 5-13.
[6]	Hauer NN, Popp B, Schoeller E, et al. Clinical relevance of systematic phenotyping and exome sequencing in patients with short stature[J]. Genet Med, 2018, 20(6): 630-638. doi: 10.1038/gim.2017.159
[7]	Vasques GA, Andrade NLM, Jorge AAL. Genetic causes of isolated short stature[J]. Arch Endocrinol Metab, 2019, 63(1): 70-78. doi: 10.20945/2359-3997000000105
[8]	Collett-Solberg PF, Ambler G, Backeljauw PF, et al. Diagnosis, genetics, and therapy of short stature in children: a Growth Hormone Research Society International Perspective[J]. Horm Res Paediatr, 2019, 92(1): 1-14.
[9]	Wit JM, Oostdijk W, Losekoot M, et al. Mechanisms in endocrinology: novel genetic causes of short stature[J]. Eur J Endocrinol, 2016, 174(4): R145-R173. doi: 10.1530/EJE-15-0937
[10]	HHagenäs L, Hertel T. Skeletal dysplasia, growth hormone treatment and body proportion: comparison with other syndromic and non-syndromic short children[J]. Horm Res, 2003, 60(Suppl 3): 65-70.
[11]	de Bruin C, Dauber A. Insights from exome sequencing for endocrine disorders[J]. Nat Rev. Endocrinol, 2015, 11(8): 455-464. doi: 10.1038/nrendo.2015.72
[12]	Andrade AC, Jee YH, Nilsson O. New genetic diagnoses of short stature provide insights into local regulation of childhood growth[J]. Horm Res Paediatr, 2017, 88(1): 22-37. doi: 10.1159/000455850
[13]	Wang SR, Carmichael H, Andrew SF, et al. Large-scale pooled next-generation sequencing of 1077 genes to identify genetic causes of short stature[J]. J Clin Endocrinol Metab, 2013, 98(8): E1428-E1437. doi: 10.1210/jc.2013-1534
[14]	David A, Hwa V, Metherell LA, et al. Evidence for a continuum of genetic, phenotypic, and biochemical abnormalities in children with growth hormone insensitivity[J]. Endocr Rev, 2011, 32(4): 472-497. doi: 10.1210/er.2010-0023
[15]	Baron J, Sävendahl L, De Luca F, et al. Short and tall stature: a new paradigm emerges[J]. Nat Rev Endocrinol, 2015, 11(12): 735-746. doi: 10.1038/nrendo.2015.165
[16]	Nilsson O, Marino R, De Luca F, et al. Endocrine regulation of the growth plate[J]. Horm Res, 2005, 64(4): 157-165. pmid: 16205094
[17]	Nilsson O, Guo MH, Dunbar N, et al. Short stature, accelerated bone maturation, and early growth cessation due to heterozygous aggrecan mutations[J]. J Clin Endocrinol Metab, 2014, 99(8): E1510-E1518. doi: 10.1210/jc.2014-1332
[18]	Song SH, Balce GC, Agashe MV, et al. New proposed clinico-radiologic and molecular criteria in hypochondroplasia: FGFR 3 gene mutations are not the only cause of hypochondroplasia[J]. Am J Med Genet A, 2012, 158A(10): 2456-2462. doi: 10.1002/ajmg.a.35564
[19]	Low K, Ashraf T, Canham N, et al. Clinical and genetic aspects of KBG syndrome[J]. Am J Med Genet A, 2016, 170(11): 2835-2846. doi: 10.1002/ajmg.a.37842
[20]	Dauber A, Rosenfeld RG, Hirschhorn JN. Genetic evaluation of short stature[J]. J Clin Endocrinol Metab, 2014, 99(9): 3080-3092. doi: 10.1210/jc.2014-1506
[21]	Huang Z, Sun Y, Fan Y, et al. Genetic evaluation of 114 chinese short stature children in the next generation era: a single center study[J]. Cell Physiol Biochem, 2018, 49(1): 295-305. doi: 10.1159/000492879 pmid: 30138938
[22]	Sisley S, Trujillo MV, Khoury J, et al. Low incidence of pathology detection and high cost of screening in the evaluation of asymptomatic short children[J]. J Pediatr, 2013, 163(4): 1045-1051. doi: 10.1016/j.jpeds.2013.04.002
[23]	Plachy L, Strakova V, Elblova L, et al. High prevalence of growth plate gene variants in children with familial short stature treated with GH[J]. J Clin Endocrinol Metab, 2019, 104(10): 4273-4281. doi: 10.1210/jc.2018-02288 pmid: 30753492

项目	阳性组(n=69)	阴性组(n=117)	χ²值	P
身高标准差			5.72	0.017
-3SD~-2SD	41(59.4)	89(76.1)
<-3SD	28(40.6)	28(23.9)
矮小家族史	15(21.7)	70(59.8)	25.38	<0.001
骨骼发育异常	31(44.9)	20(17.1)	16.90	<0.001
特殊面容	32(46.4)	20(17.1)	18.48	<0.001
先天性心脏发育异常	15(21.7)	10(8.5)	6.49	0.011
SGA	9(13.0)	17(14.5)	0.08	0.830
伴有异常表型个数			31.73	<0.001
无	6(8.7)	57(48.7)
1个	28(40.6)	31(26.5)
>1个	35(50.7)	29(24.8)

组别	例数	基因阳性n(%)]	χ²值	P
身高标准差			7.25	0.023
-3SD~-2SD	66	8(12.1)
-4SD~-3SD	13	4(30.8)
<-4SD	6	3(50.0)
是否伴异常表型			11.05	0.001
仅有矮小家族史	63	6(9.5)
矮小家族史伴异常表型	22	9(40.9)

项目	回归系数	标准误	χ²值	OR (95%CI)	P
严重矮小	0.56	0.37	2.26	1.74(0.85~3.60)	0.133
先天性心脏发育异常	0.70	0.50	1.96	2.02(0.76~5.38)	0.161
骨骼发育异常	1.41	0.42	11.35	4.10(1.80~9.32)	0.001
特殊面容	1.16	0.43	7.33	3.19(1.38~7.41)	0.007
矮小家族史	-0.64	0.44	2.12	0.53(0.22~1.25)	0.145
常量	-1.35	0.42	10.52	0.26	0.001