切换至 "中华医学电子期刊资源库"
高级检索
中华眼科医学杂志(电子版)

中华眼科医学杂志(电子版) ›› 2024, Vol. 14 ›› Issue (06) : 363 -367. doi: 10.3877/cma.j.issn.2095-2007.2024.06.008

综述

先天性眼球震颤相关致病基因及分子遗传学的研究进展
周楚仪1, 王乐今1,()   
  1. 1.100044 北京大学人民医院眼科
  • 收稿日期:2024-11-08 出版日期:2024-12-28
  • 通信作者: 王乐今
  • 基金资助:
    国家自然科学基金项目(81470665)2018年首都卫生科研专项批准项目(2018-2Z-4086)

Advance on pathogenic genes and molecular genetics of congenital nystagmus

Chuyi Zhou1, Lejin Wang1,()   

  1. 1.Department of Ophthalmology,Peking University People's Hospital,Beijing 100044,China;Beijing Key Laboratory of Ocular Disease and Optometry Science,Peking University People's Hospital,Beijng 100044,China
  • Received:2024-11-08 Published:2024-12-28
  • Corresponding author: Lejin Wang
全文 ( ) 下载PDF ( ) 导出引用
引用本文:

周楚仪, 王乐今. 先天性眼球震颤相关致病基因及分子遗传学的研究进展[J/OL]. 中华眼科医学杂志(电子版), 2024, 14(06): 363-367.

Chuyi Zhou, Lejin Wang. Advance on pathogenic genes and molecular genetics of congenital nystagmus[J/OL]. Chinese Journal of Ophthalmologic Medicine(Electronic Edition), 2024, 14(06): 363-367.

先天性眼球震颤(CN)是一种以眼球不自主运动为特征的眼球运动功能障碍性疾病,通常在出生后6个月内发现。该病可能与遗传性视网膜病(IRD)所致的知觉缺陷有关,也可能为特发性。CN作为多种疾病的常见表型,其致病基因及遗传模式也复杂多样,临床上常难以作出准确的分子学诊断。近年来,随着新一代高通量测序技术的发展,IRD致病基因的检出率显著提高,基因疗法的研究也取得了令人瞩目的成果。因此,总结整合CN及与其相关IRD的基因型及表型的关联尤为重要。本文笔者基于国内外最新研究进展,系统总结了CN相关的致病基因、遗传方式及其分子机制,旨在为该病的诊断、发病机制和治疗提供新的研究思路与参考。

关键词: 先天性眼球震颤, 基因型, 表型, 遗传性视网膜病

Congenital nystagmus(CN)is a type of ocular motor disorder characterized by involuntary oscillation of eyes,typically occurred in the first six months of life.It can be related to the sensory disorder result by inherited retinal disease,or be idiopathic.As a common phenotype of many disease,the genetic complexity and diverse inheritance pattern of CN present a great challenge of monogenic diagnosis.Recent development of next-generation sequencing technologies significantly enhanced the identification of pathogenic genes,while the gene therapy has made a great progress.Therefore,it is crucial to summarize the genotype and phenotype association of CN and its related inherited retinal diseases.The identified genes and the underlying molecular mechanisms linked to CN,drawing upon the latest findings from international research were systematically reviewed in the paper,aiming to provide novel insights and a comprehensive reference for improving the diagnosis,classification,and treatment of CN.

Key words: Congenital nystagmus, Genotype, Phenotype, Inherited retinal disease
图1 先天性眼球震颤常见基因型-表型参考图[21]
[1]
Brodsky MC,Dell'Osso LF.A unifying neurologic mechanism for infantile nystagmus[J].JAMA Ophthalmology,2014,132(6):761-768.
[2]
Papageorgiou E,McLean RJ,Gottlob I.Nystagmus in childhood[J].Pediatr Neonatol,2014,55(5):341-351.
[3]
布娟,王乐今.新时期再审识先天性眼球震颤[J/OL].中华眼科医学杂志(电子版),2013,3(2):74-78.
[4]
Dawar B,Kuht HJ,Han J,et al.Clinical utility gene card for FRMD7-related infantile nystagmus[J].Eur J Hum Genet,2021,29(10):1584-1588.
[5]
Tarpey P,Thomas S,Sarvananthan N,et al.Mutations in FRMD7,a newly identified member of the FERM family,cause X-linked idiopathic congenital nystagmus[J].Nat Genet,2006,38(11):1242-1244.
[6]
Mervyn G.Thomas,Moira Crosier,Susan Lindsay,et al.The clinical and molecular genetic features of idiopathic infantile periodic alternating nystagmus[J].Brain,2011,134(3):892-902.
[7]
Watkins RJ,Patil R,Goult BT,et al.A novel interaction between FRMD7 and CASK:evidence for a causal role in idiopathic infantile nystagmus[J],Hum Mol Genet,2013,22(10):2105-2118.
[8]
Jiang L,Li Y,Yang K,et al.FRMD7 Mutations Disrupt the Interaction with GABRA2 and May Result in Infantile Nystagmus Syndrome[J].Invest Ophthalmol Vis Sci,2020,61(5):41.
[9]
Kerrison JB,Vagefi MR,Barmada MM,et al.Congenital motor nystagmus linked to Xq26-q27[J].Am JHum Genet,1999,64(2):600-607.
[10]
Zhang Q,Xiao X,Li S,et al.FRMD7 mutations in Chinese families with X-linked congenital motor nystagmus[J].Molec.Vis,2007,(13):1375-1378.
[11]
He X,Gu F,Wang Z,et al.A novel frameshift mutation in FRMD7 causing X-linked idiopathic congenital nystagmus[J].Genet,2008,(12):607-613.
[12]
Tarpey PS,Smith R,Pleasance E,et al.A systematic,large-scale resequencing screen of X-chromosome coding exons in mental retardation[J].Nat Genet,2009,41(5):535-543.
[13]
Moon D,Park HW,Surl D,et al.Precision Medicine through Next-Generation Sequencing in Inherited Eye Diseases in a Korean Cohort[J].Genes(Basel),2021,13(1):27.
[14]
Weisschuh N,Mazzola P,Zuleger T,et al.Diagnostic genome sequencing improves diagnostic yield[J].J Med Genet,2024,61(2):186-195.
[15]
Narang A,Uppilli B,Vivekanand A,et al.Frequency spectrum of rare and clinically relevant markers in multiethnic Indian populations(ClinIndb):A resource for genomic medicine in India[J].Hum Mutat,2020,41(11):1833-1847.
[16]
Rim JH,Lee ST,Gee HY,et al.Accuracy of Next-Generation Sequencing for Molecular Diagnosis in Patients with Infantile Nystagmus Syndrome[J].JAMA Ophthalmology,2017,135(12):1376-1385.
[17]
Huang L,Zhou Y,Chen W,et al.Correlations of FRMD7 gene mutations with ocular oscillations[J].Sci Rep,2022,12(1):9914.
[18]
Wang F,Guan H,Liu W,et al.Next-generation sequencing identifies a novel frameshift variant in FRMD7 in a Chinese family with idiopathic infantile nystagmus[J].J Clin Lab Anal,2020,34(1):23012.
[19]
Wang XF,Chen H,Huang PJ,et al.Genotype-Phenotype Analysis and Mutation Spectrum in a Cohort of Chinese Patients with Congenital Nystagmus[J].Front Cell Dev Biol,2021(9):627295.
[20]
Zi F,Li Z,Cheng W,et al.Novel mutations of the X-linked genes associated with early-onset high myopia in five Chinese families[J].BMCMed Genomics,2023,16(1):223.
[21]
Thomas MG,Maconachie G,Hisaund M,et al.FRMD7-Related Infantile Nystagmus[M].Seattle:University of Washington,2009.
[22]
Bakker R,Wagstaff EL,Kruijt CC,et al.The retinal pigmentation pathway in human albinism:Not so black and white[J].Prog Retin Eye Res,2022,91:101091.
[23]
Ghosh A,Sonavane U,Andhirka SK,et al.Structural insights into human GPCR protein OA1:a computational perspective[J].J Mol Model,2012:18(5):2117-2133.
[24]
Palmisano I,Bagnato P,Palmigiano A,et al.The ocular albinism type 1 protein,an intracellular G protein-coupled receptor,regulates melanosome transport in pigment cells[J].Hum Mol Genet,2008,17:3487-3501.
[25]
Bueschbell B,Manga P,Schiedel AC.The Many Faces of GProtein-Coupled Receptor 143,an Atypical Intracellular Receptor[J].Front Mol Biosci,2022,9:873777.
[26]
Liu JY,Ren X,Yang X,et al.Identification of a novel GPR143 mutation in a large Chinese family with congenital nystagmus as the most prominent and consistent manifestation[J].JHum Genet,2007,52(6):565-570.
[27]
Zhou P,Wang Z,Zhang J,et al.Identification of a novel GPR143 deletion in a Chinese family with X-linked congenital nystagmus[J].Mol Vis,2008,14:1015-1019.
[28]
Huang L,Xu B,Li N.Differences of ocular oscillations and neuroretinal structures in patients with nystagmus caused by GPR143 and FRMD7 gene variants[J].Indian J Ophthalmol,2024,72(3):509-513.
[29]
Waldner DM,Bech-Hansen NT,Stell WK.Channeling Vision:CaV1.4-A Critical Link in Retinal Signal Transmission[J].Biomed Res Int,2018:7272630.
[30]
Maddox JW,Ordemann GJ,de la Rosa Vázquez JAM,et al.A nonconducting role of the Cav1.4 Ca2+channel drives homeostatic plasticity at the cone photoreceptor synapse[J].Elife,2024,13:94908.
[31]
Katta M,de Guimaraes TAC,Fujinami-Yokokawa Y,et al.Congenital stationary night blindness: structure, function and genotype-phenotype correlations in a cohort of 122 patients[J].Ophthalmol Retina,2024,8(9):932-941.
[32]
Bech-Hansen NT,Naylor MJ,Maybaum TA,et al.Loss-of-function mutations in a calcium-channel alpha1-subunit gene in Xp11.23 cause incomplete X-linked congenital stationary night blindness[J].Nat Genet,1998,19(3):264-267.
[33]
Boycott KM,Maybaum TA,Naylor MJ,et al.A summary of 20 CACNA1F mutations identified in 36 families with incomplete Xlinked congenital stationary night blindness,and characterization of splice variants[J].Hum Genet,2001,108(2):91-97.
[34]
Nakamura M,Ito S,Piao C-H,et al.Retinal and optic disc atrophy associated with a CACNA1Fmutation in a Japanese family[J].Arch.Ophthal,2003,121:1028-1033.
[35]
Wyględowska-Promieńska D,Šwierczyńska M,Špiewak D,et al.Aland Island Eye Disease with Retinoschisis in the Clinical Spectrum of CACNA1F-Associated Retinopathy-A Case Report[J].Int J Mol Sci,2024,25(5):2928.
[36]
Scanga HL,Liasis A,Pihlblad MS,et al.NYX-related congenital stationary night blindness in two siblings due to probable maternal germline mosaicism[J].Ophthalmic Genet,2021,42(5):588-592.
[37]
Bech-Hansen NT,Naylor MJ,Maybaum TA,et al.Mutations in NYX,encoding the leucine-rich proteoglycan nyctalopin,cause Xlinked complete congenital stationary night blindness[J].Nat Genet,2000,26(3):319-323.
[38]
Duda T,Venkataraman,V,Goraczniak,R,et al.K.Functional consequences of a rod outer segment membrane guanylate cyclase(ROS-GC1)gene mutation linked with Leber's congenital amaurosis[J].Biochemistry,1999,38:509-515.
[39]
Camuzat A,Rozet J-M,Dollfus H,et al.Evidence of genetic heterogeneity of Leber's congenital amaurosis(LCA)and mapping of LCA1 to chromosome17p13[J].Hum Genet,1996,97:798-801.
[40]
Perrault I,Rozet J-M,Gerber S,et al.Spectrum of retGC1 mutations in Leber's congenital amaurosis[J].Europ J Hum Genet,2000,8:578-582.
[41]
Gong X, Hertle RW.Infantile nystagmus syndrome-associated inherited retinal diseases[J].Life(Basel),2024,14(11):1356.
[42]
Mikula Mrstakova S,Kozmik Z.Genetic analysis of medaka fish illuminates conserved and divergent roles of Pax6 in vertebrate eye development[J].Front Cell Dev Biol,2024,12:1448773.
[43]
Masse K,Bhamra S,Eason R,et al.Purine-mediated signaling triggers eye development[J].Nature,2007,449(7165):1058-1062.
[44]
Jordan T,Hanson I,Zaletayev D,et al.The human PAX6 gene is mutated in two patients with aniridia[J].Nature Genet,1992,1:328-332.
[45]
Glaser T,Jepeal L,Edwards JG,et al.PAX6 gene dosage effect in a family with congenital cataracts,aniridia,anophthalmia and central nervous system defects[J].Nature Genet,1994,7:463-471.
[46]
Vincent MC,Gallai R,Olivier D,et al.Variable phenotype related to a novel PAX 6 mutation(IVS4+5G-to-C)in a family presenting congenital nystagmus and foveal hypoplasia[J].Am.J.Ophthal,2004,138:1016-1021.
[47]
Jiang Y,Yi Z,Zheng Y,et al.The systemic genotype-phenotype characterization of PAX6-related eye disease in 164 chinese families[J].Invest Ophthalmol Vis Sci,2024,65(10):46.
[48]
Lamb TD,Pugh EN.Phototransduction,dark adaptation,and rhodopsin regeneration the proctor lecture[J].Invest Ophthalmol Vis Sci,2006,47(12):5137-5152.
[49]
Genead MA,Fishman GA,Rha J,et al.Photoreceptor structure and function in patients with congenital achromatopsia[J].Invest Ophthalmol Vis Sci,2011,52(10):7298-7308.
[50]
Kohl S,Baumann B,Broghammer M,et al.Mutations in the CNGB3 gene encoding the beta-subunit of the cone photoreceptor cGMP-gated channel are responsible for achromatopsia(ACHM3)linked to chromosome8q21[J].Hum Mol Genet,2000,9(14):2107-2116.
[51]
Wiszniewski W,Lewis RA,Lupski JR.Achromatopsia:the CNGB3 p.T383fsX mutation results fromafounder effect and isresponsible for the visual phenotype in the original report of uniparental disomy 14[J].Hum Genet,2007,121(3-4):433-439.
[52]
Schapira AH.Mitochondrial disease[J].Lancet,2006,368(9529):70-82.
[53]
Servidei S.Mitochondrial encephalo myopathies:gene mutation[J].Neuromuscul Disord,2004,14(1):107-116.
[54]
Yu-Wai-Man P,Newman NJ,Biousse V,et al.Five-year outcomes of lenadogene nolparvovec gene therapy in leber hereditary optic neuropathy[J].JAMA Ophthalmol,2024,12:5375.
[55]
Nakaso K,Adachi Y,Fusayasu E,et al.Leber's hereditary optic neuropathy with olivocerebellar degeneration due to G11778A and T3394C mutations in the mitochondrial DNA[J].J Clin Neurol,2012,8(3):230-234.
[56]
Grönlund MA,Honarvar AK,Andersson S,et al.Ophthalmological findings in children and young adults with genetically verified mitochondrial disease[J].Br J Ophthalmol,2010,94(1):121-127.
[1] 张刚, 秦勇, 黄超, 薛震, 吕松岑. 基于骨关节炎软骨细胞表型转化的新兴治疗靶点[J/OL]. 中华关节外科杂志(电子版), 2024, 18(03): 352-362.
[2] 刘洋, 盛赵莹, 孙琳琳. 白细胞介素6启动子通过调控人端粒酶逆转录酶减轻细胞炎症和DNA损伤[J/OL]. 中华危重症医学杂志(电子版), 2024, 17(02): 104-110.
[3] 张禾璇, 杨雪, 王侣金, 李林洁, 刘兴宇. 新生儿葡萄糖-6-磷酸脱氢酶缺乏症筛查及基因突变特征分析[J/OL]. 中华妇幼临床医学杂志(电子版), 2024, 20(02): 200-208.
[4] 张雪灵, 陈玮彬, 魏雯硕, 陈明, 诸宏伟. 努南综合征的临床特点与治疗效果分析[J/OL]. 中华妇幼临床医学杂志(电子版), 2024, 20(02): 192-199.
[5] 李维, 莫俊俏. 儿童呼吸道耐药流感嗜血杆菌基因型鉴定及耐药分析对抗菌药物治疗选择的意义[J/OL]. 中华实验和临床感染病杂志(电子版), 2023, 17(05): 315-323.
[6] 胡思平, 熊性宇, 徐航, 杨璐. 衰老相关分泌表型因子在前列腺癌发生发展中的作用机制[J/OL]. 中华腔镜泌尿外科杂志(电子版), 2024, 18(05): 425-434.
[7] 沈琪乐, 赵勤华, 宫素岗, 刘锦铭, 王岚, 邱宏玲. COPD 稳定期患者血清CC16 蛋白表达与肺功能、肺气肿表型的关系分析[J/OL]. 中华肺部疾病杂志(电子版), 2024, 17(05): 690-695.
[8] 张宪超, 张实. 基于转录组数据分析识别脓毒症肺炎免疫表型[J/OL]. 中华肺部疾病杂志(电子版), 2023, 16(06): 761-765.
[9] 张智, 董志伟, 徐祖鑫, 姜莉鑫, 张玉辉, 顾国利. Peutz-Jeghers综合征基因型研究及临床诊治进展[J/OL]. 中华结直肠疾病电子杂志, 2024, 13(01): 6-13.
[10] 卢斌, 张天琪, 徐烨, 刘方奇. 中国人群经典型家族性腺瘤性息肉病的临床、病理和分子特征[J/OL]. 中华结直肠疾病电子杂志, 2024, 13(01): 38-44.
[11] 杨长沅, 凌曦淘, 丘伽美, 段若兰, 李琴, 林玉婕, 秦新东, 侯海晶, 卢富华, 苏国彬. 慢性肾脏病患者衰弱的筛查/评估工具研究进展[J/OL]. 中华肾病研究电子杂志, 2023, 12(04): 229-233.
[12] 李程, 齐展, 古力娜, 兰天琪, 贾艳峰, 李莉, 施维, 魏爱华, 白大勇. 白化病儿童视功能特征及其评估方法的临床研究[J/OL]. 中华眼科医学杂志(电子版), 2023, 13(06): 338-343.
[13] 胡杰, 蔡国龙. 脓毒症合并低心功能指数患者PiCCO参数的聚类分析[J/OL]. 中华重症医学电子杂志, 2024, 10(01): 25-30.
[14] 吴蓉菊, 向平超. COPD频繁急性加重表型与炎性因子相关性研究[J/OL]. 中华临床医师杂志(电子版), 2023, 17(09): 939-947.
[15] 李佳佳, 李凌华, 吕诗韵, 冯凯, 刘琳珊, 钟海丹, 颜婵, 刘聪. 广州市病毒学抑制失败HIV/AIDS患者的耐药特征及影响因素分析[J/OL]. 中华卫生应急电子杂志, 2024, 10(04): 207-212.
阅读次数
全文


摘要

版权所有 中华医学会 中华医学电子音像出版社有限责任公司  京ICP备14006079号-1  网络出版服务许可证:(署)网出证(京)字第075号