Missense Mutations in MAB21L1: Causation of Novel Autosomal Dominant Ocular BAMD Syndrome

Purpose Biallelic MAB21L1 variants have been reported to cause autosomal recessive cerebellar, ocular, craniofacial, and genital syndrome (COFG), whereas only five heterozygous pathogenic variants have been suspected to cause autosomal dominant (AD) microphthalmia and aniridia in eight families. This study aimed to report an AD ocular syndrome (blepharophimosis plus anterior segment and macular dysgenesis [BAMD]) syndrome based on clinical and genetic findings from patients with monoallelic MAB21L1 pathogenic variants in our cohort and reported cases. Methods Potential pathogenic variants in MAB21L1 were detected from a large in-house exome sequencing dataset. Ocular phenotypes of the patients with potential pathogenic variants in MAB21L1 were summarized, and the genotype-phenotype correlation was analyzed through a comprehensive literature review. Results Three heterozygous missense variants in MAB21L1, predicted to be damaging, were detected in 5 unrelated families, including c.152G>T in 2, c.152G>A in 2, and c.155T>G in one. All were absent from gnomAD. The variants were de novo in two families, transmitted from affected parents to offspring in two families, and with an unknown origin in the other family, demonstrating strong evidence of AD inheritance. All patients revealed similar BAMD phenotypes, including blepharophimosis, anterior segment dysgenesis, and macular dysgenesis. Genotype-phenotype analysis suggested that patients with monoallelic MAB21L1 missense variants had only ocular anomalies (BAMD), whereas patients with biallelic variants presented both ocular and extraocular symptoms. Conclusions Heterozygous pathogenic variants in MAB21L1 account for a new AD BAMD syndrome, which is completely different from COFG caused by homozygous variants in MAB21L1. Nucleotide c.152 is likely a mutation hot spot, and the encoded residue of p.Arg51 might be critical for MAB21L1.

[1]  J. Marsh,et al.  Monoallelic variants resulting in substitutions of MAB21L1 Arg51 Cause Aniridia and microphthalmia , 2022, PloS one.

[2]  K. Shirahige,et al.  MAB21L1 modulates gene expression and DNA metabolic processes in the lens placode , 2021, Disease models & mechanisms.

[3]  L. Reis,et al.  Identification of missense MAB21L1 variants in microphthalmia and aniridia , 2021, Human mutation.

[4]  Brian J. Nguyen,et al.  “Blepharophimosis‐plus” syndromes: Frequency of systemic genetic disorders that also include blepharophimosis , 2021, Clinical & experimental ophthalmology.

[5]  E. Sorokina,et al.  Genetic disruption of zebrafish mab21l1 reveals a conserved role in eye development and affected pathways , 2021, Developmental dynamics : an official publication of the American Association of Anatomists.

[6]  Xueshan Xiao,et al.  An Ophthalmic Targeted Exome Sequencing Panel as a Powerful Tool to Identify Causative Mutations in Patients Suspected of Hereditary Eye Diseases , 2019, Translational vision science & technology.

[7]  R. Holt,et al.  Genetics of anophthalmia and microphthalmia. Part 1: Non-syndromic anophthalmia/microphthalmia , 2019, Human Genetics.

[8]  J. Sowden,et al.  Genes and pathways in optic fissure closure. , 2017, Seminars in cell & developmental biology.

[9]  K. Chow,et al.  Generation and characterization of pathogenic Mab21l2(R51C) mouse model , 2018, Genesis.

[10]  Kiely N. James,et al.  MAB21L1 loss of function causes a syndromic neurodevelopmental disorder with distinctive cerebellar, ocular, craniofacial and genital features (COFG syndrome) , 2018, Journal of Medical Genetics.

[11]  J. Rivière,et al.  Autosomal recessive truncating MAB21L1 mutation associated with a syndromic scrotal agenesis , 2017, Clinical genetics.

[12]  Xueshan Xiao,et al.  X-linked heterozygous mutations in ARR3 cause female-limited early onset high myopia , 2016, Molecular vision.

[13]  G. Witte,et al.  Structural and biochemical characterization of the cell fate determining nucleotidyltransferase fold protein MAB21L1 , 2016, Scientific Reports.

[14]  D. Horn,et al.  A Novel Oculo-Skeletal syndrome with intellectual disability caused by a particular MAB21L2 mutation. , 2015, European journal of medical genetics.

[15]  L. Reis,et al.  Conserved genetic pathways associated with microphthalmia, anophthalmia, and coloboma. , 2015, Birth defects research. Part C, Embryo today : reviews.

[16]  Hui Jiang,et al.  Mutation analysis in 129 genes associated with other forms of retinal dystrophy in 157 families with retinitis pigmentosa based on exome sequencing , 2015, Molecular vision.

[17]  Bale,et al.  Standards and Guidelines for the Interpretation of Sequence Variants: A Joint Consensus Recommendation of the American College of Medical Genetics and Genomics and the Association for Molecular Pathology , 2015, Genetics in Medicine.

[18]  A. Kariminejad,et al.  Mutations in MAB21L2 Result in Ocular Coloboma, Microcornea and Cataracts , 2015, PLoS genetics.

[19]  Xueshan Xiao,et al.  Evaluation of 12 myopia-associated genes in Chinese patients with high myopia. , 2015, Investigative ophthalmology & visual science.

[20]  Gunnar Houge,et al.  Monoallelic and biallelic mutations in MAB21L2 cause a spectrum of major eye malformations. , 2014, American journal of human genetics.

[21]  Marco Biasini,et al.  SWISS-MODEL: modelling protein tertiary and quaternary structure using evolutionary information , 2014, Nucleic Acids Res..

[22]  V. Hornung,et al.  cGAS produces a 2′-5′-linked cyclic dinucleotide second messenger that activates STING , 2013, Nature.

[23]  Roger A. Jones,et al.  Cyclic [G(2′,5′)pA(3′,5′)p] Is the Metazoan Second Messenger Produced by DNA-Activated Cyclic GMP-AMP Synthase , 2013, Cell.

[24]  D. Fitzpatrick,et al.  Clinical and mutation analysis of 51 probands with anophthalmia and/or severe microphthalmia from a single center , 2013, Molecular genetics & genomic medicine.

[25]  T. Haremaki,et al.  Xmab21l3 mediates dorsoventral patterning in Xenopus laevis , 2012, Mechanisms of Development.

[26]  Dean Y. Li,et al.  ABCB6 mutations cause ocular coloboma. , 2012, American journal of human genetics.

[27]  Amy E Taylor,et al.  Anophthalmos, microphthalmos, and typical coloboma in the United Kingdom: a prospective study of incidence and risk. , 2011, Investigative ophthalmology & visual science.

[28]  Q. Kong,et al.  Mitochondrial DNA haplogroup distribution in Chaoshanese with and without myopia , 2010, Molecular vision.

[29]  J. Furtado,et al.  Iris coloboma, blepharophimosis, arachnodactyly, joint contractures: Beals syndrome and Van den Ende-Gupta syndrome phenotypic similarities. , 2009, Clinical dysmorphology.

[30]  D. Fitzpatrick,et al.  Anophthalmia and microphthalmia , 2007, Orphanet journal of rare diseases.

[31]  R. Hennekam,et al.  Mutations in STRA6 cause a broad spectrum of malformations including anophthalmia, congenital heart defects, diaphragmatic hernia, alveolar capillary dysplasia, lung hypoplasia, and mental retardation. , 2007, American Journal of Human Genetics.

[32]  Y. Gillerot,et al.  Blepharophimosis‐mental retardation (BMR) syndromes: A proposed clinical classification of the so‐called Ohdo syndrome, and delineation of two new BMR syndromes, one X‐linked and one autosomal recessive , 2006, American journal of medical genetics. Part A.

[33]  J. Johnston,et al.  Case reports of oculofaciocardiodental syndrome with unusual dental findings , 2005 .

[34]  J. Zizka,et al.  Association of oesophageal atresia, anophthalmia and renal duplex , 2004, European Journal of Pediatrics.

[35]  H. Koseki,et al.  Cell-autonomous involvement of Mab21l1 is essential for lens placode development , 2003, Development.

[36]  K. Chow,et al.  Depletion of Mab21l1 and Mab21l2 messages in mouse embryo arrests axial turning, and impairs notochord and neural tube differentiation. , 2002, Teratology.

[37]  H. Campbell,et al.  National study of microphthalmia, anophthalmia, and coloboma (MAC) in Scotland: investigation of genetic aetiology , 2002, Journal of medical genetics.

[38]  L. Dandona,et al.  Visual acuity in children with coloboma: clinical features and a new phenotypic classification system. , 2000, Ophthalmology.

[39]  L. Dandona,et al.  Regional variation in blindness in children due to microphthalmos, anophthalmos and coloboma , 2000, Ophthalmic epidemiology.

[40]  M. Rocchi,et al.  Two murine and human homologs of mab-21, a cell fate determination gene involved in Caenorhabditis elegans neural development. , 1999, Human molecular genetics.

[41]  E. Boncinelli,et al.  Mab21, the mouse homolog of a C. elegans cell-fate specification gene, participates in cerebellar, midbrain and eye development , 1998, Mechanisms of Development.

[42]  T. Crow,et al.  cDNA cloning of a human homologue of the Caenorhabditis elegans cell fate-determining gene mab-21: expression, chromosomal localization and analysis of a highly polymorphic (CAG)n trinucleotide repeat. , 1996, Human molecular genetics.

[43]  L. R. Lee,et al.  Blepharophimosis syndrome: association with colobomatous microphthalmos. , 1995, Australian and New Zealand journal of ophthalmology.

[44]  S. W. Emmons,et al.  Pattern formation in the nematode epidermis: determination of the arrangement of peripheral sense organs in the C. elegans male tail. , 1991, Development.

[45]  A. H. Weiss,et al.  Simple microphthalmos. , 1989, Archives of ophthalmology.

[46]  D. Hu Prevalence and mode of inheritance of major genetic eye diseases in China. , 1987, Journal of Medical Genetics.

[47]  M. Hayden,et al.  Ethical issues in preclinical testing in Huntington disease: response to Margery Shaw's invited editorial comment. , 1987, American journal of medical genetics.