Your search keyword '"Vestibular Diseases genetics"' showing total 8 results

1. DNA methylation profiling in Kabuki syndrome: reclassification of germline KMT2D VUS and sensitivity in validating postzygotic mosaicism.

Author

Niceta M, Ciolfi A, Ferilli M, Pedace L, Cappelletti C, Nardini C, Hildonen M, Chiriatti L, Miele E, Dentici ML, Gnazzo M, Cesario C, Pisaneschi E, Baban A, Novelli A, Maitz S, Selicorni A, Squeo GM, Merla G, Dallapiccola B, Tumer Z, Digilio MC, Priolo M, and Tartaglia M

Subjects

Humans, Male, Female, Child, Child, Preschool, Adolescent, Germ-Line Mutation, Infant, Phenotype, Adult, Vestibular Diseases genetics, Vestibular Diseases diagnosis, Face abnormalities, Hematologic Diseases genetics, Hematologic Diseases diagnosis, Mosaicism, Abnormalities, Multiple genetics, Abnormalities, Multiple diagnosis, DNA Methylation, DNA-Binding Proteins genetics, Neoplasm Proteins genetics

Abstract

Autosomal dominant Kabuki syndrome (KS) is a rare multiple congenital anomalies/neurodevelopmental disorder caused by heterozygous inactivating variants or structural rearrangements of the lysine-specific methyltransferase 2D (KMT2D) gene. While it is often recognizable due to a distinctive gestalt, the disorder is clinically variable, and a phenotypic scoring system has been introduced to help clinicians to reach a clinical diagnosis. The phenotype, however, can be less pronounced in some patients, including those carrying postzygotic mutations. The full spectrum of pathogenic variation in KMT2D has not fully been characterized, which may hamper the clinical classification of a portion of these variants. DNA methylation (DNAm) profiling has successfully been used as a tool to classify variants in genes associated with several neurodevelopmental disorders, including KS. In this work, we applied a KS-specific DNAm signature in a cohort of 13 individuals with KMT2D VUS and clinical features suggestive or overlapping with KS. We succeeded in correctly classifying all the tested individuals, confirming diagnosis for three subjects and rejecting the pathogenic role of 10 VUS in the context of KS. In the latter group, exome sequencing allowed to identify the genetic cause underlying the disorder in three subjects. By testing five individuals with postzygotic pathogenic KMT2D variants, we also provide evidence that DNAm profiling has power to recognize pathogenic variants at different levels of mosaicism, identifying 15% as the minimum threshold for which DNAm profiling can be applied as an informative diagnostic tool in KS mosaics., (© 2024. The Author(s), under exclusive licence to European Society of Human Genetics.)

Published

2024

2. Using deep-neural-network-driven facial recognition to identify distinct Kabuki syndrome 1 and 2 gestalt.

Author

Rouxel F, Yauy K, Boursier G, Gatinois V, Barat-Houari M, Sanchez E, Lacombe D, Arpin S, Giuliano F, Haye D, Rio M, Toutain A, Dieterich K, Brischoux-Boucher E, Julia S, Nizon M, Afenjar A, Keren B, Jacquette A, Moutton S, Jacquemont ML, Duflos C, Capri Y, Amiel J, Blanchet P, Lyonnet S, Sanlaville D, and Genevieve D

Subjects

Face abnormalities, Humans, Mutation, Abnormalities, Multiple diagnosis, Abnormalities, Multiple genetics, Facial Recognition, Hematologic Diseases diagnosis, Hematologic Diseases genetics, Vestibular Diseases diagnosis, Vestibular Diseases genetics

Abstract

Kabuki syndrome (KS) is a rare genetic disorder caused by mutations in two major genes, KMT2D and KDM6A, that are responsible for Kabuki syndrome 1 (KS1, OMIM147920) and Kabuki syndrome 2 (KS2, OMIM300867), respectively. We lack a description of clinical signs to distinguish KS1 and KS2. We used facial morphology analysis to detect any facial morphological differences between the two KS types. We used a facial-recognition algorithm to explore any facial morphologic differences between the two types of KS. We compared several image series of KS1 and KS2 individuals, then compared images of those of Caucasian origin only (12 individuals for each gene) because this was the main ethnicity in this series. We also collected 32 images from the literature to amass a large series. We externally validated results obtained by the algorithm with evaluations by trained clinical geneticists using the same set of pictures. Use of the algorithm revealed a statistically significant difference between each group for our series of images, demonstrating a different facial morphotype between KS1 and KS2 individuals (mean area under the receiver operating characteristic curve = 0.85 [p = 0.027] between KS1 and KS2). The algorithm was better at discriminating between the two types of KS with images from our series than those from the literature (p = 0.0007). Clinical geneticists trained to distinguished KS1 and KS2 significantly recognised a unique facial morphotype, which validated algorithm findings (p = 1.6e-11). Our deep-neural-network-driven facial-recognition algorithm can reveal specific composite gestalt images for KS1 and KS2 individuals., (© 2021. The Author(s), under exclusive licence to European Society of Human Genetics.)

Published

2022

3. Homozygote loss-of-function variants in the human COCH gene underlie hearing loss.

Author

Danial-Farran N, Chervinsky E, Nadar-Ponniah PT, Cohen Barak E, Taiber S, Khayat M, Avraham KB, and Shalev SA

Subjects

Cell Line, Frameshift Mutation, Hearing Loss, Sensorineural genetics, Humans, Pedigree, Vestibular Diseases genetics, Extracellular Matrix Proteins genetics, Hearing Loss genetics, Homozygote

Abstract

Since 1999, the COCH gene encoding cochlin, has been linked to the autosomal dominant non-syndromic hearing loss, DFNA9, with or without vestibular abnormalities. The hearing impairment associated with the variants affecting gene function has been attributed to a dominant-negative effect. Mutant cochlin was seen to accumulate intracellularly, with the formation of aggregates both inside and outside the cells, in contrast to the wild-type cochlin that is normally secreted. While additional recessive variants in the COCH gene (DFNB110) have recently been reported, the mechanism of the loss-of-function (LOF) effect of the COCH gene product remains unknown. In this study, we used COS7 cell lines to investigate the consequences of a novel homozygous frameshift variant on RNA transcription, and on cochlin translation. Our results indicate a LOF effect of the variant and a major decrease in cochlin translation. This data have a dramatic impact on the accuracy of genetic counseling for both heterozygote and homozygote carriers of LOF variants in COCH.

Published

2021

4. Patients with a Kabuki syndrome phenotype demonstrate DNA methylation abnormalities.

Author

Sobreira N, Brucato M, Zhang L, Ladd-Acosta C, Ongaco C, Romm J, Doheny KF, Mingroni-Netto RC, Bertola D, Kim CA, Perez AB, Melaragno MI, Valle D, Meloni VA, and Bjornsson HT

Subjects

Abnormalities, Multiple diagnosis, Case-Control Studies, Child, Female, Hematologic Diseases diagnosis, Histone-Lysine N-Methyltransferase genetics, Humans, Loss of Function Mutation, Male, Myeloid-Lymphoid Leukemia Protein genetics, Vestibular Diseases diagnosis, Abnormalities, Multiple genetics, DNA Methylation, Face abnormalities, Hematologic Diseases genetics, Phenotype, Vestibular Diseases genetics

Abstract

Kabuki syndrome is a monogenic disorder caused by loss of function variants in either of two genes encoding histone-modifying enzymes. We performed targeted sequencing in a cohort of 27 probands with a clinical diagnosis of Kabuki syndrome. Of these, 12 had causative variants in the two known Kabuki syndrome genes. In 2, we identified presumptive loss of function de novo variants in KMT2A (missense and splice site variants), a gene that encodes another histone modifying enzyme previously exclusively associated with Wiedermann-Steiner syndrome. Although Kabuki syndrome is a disorder of histone modification, we also find alterations in DNA methylation among individuals with a Kabuki syndrome diagnosis relative to matched normal controls, regardless of whether they carry a variant in KMT2A or KMT2D or not. Furthermore, we observed characteristic global abnormalities of DNA methylation that distinguished patients with a loss of function variant in KMT2D or missense or splice site variants in either KMT2D or KMT2A from normal controls. Our results provide new insights into the relationship of genotype to epigenotype and phenotype and indicate cross-talk between histone and DNA methylation machineries exposed by inborn errors of the epigenetic apparatus.

Published

2017

5. Progressive hearing loss and vestibular dysfunction caused by a homozygous nonsense mutation in CLIC5.

Author

Seco CZ, Oonk AM, Domínguez-Ruiz M, Draaisma JM, Gandía M, Oostrik J, Neveling K, Kunst HP, Hoefsloot LH, del Castillo I, Pennings RJ, Kremer H, Admiraal RJ, and Schraders M

Subjects

Adolescent, Cell Line, Child, Chloride Channels metabolism, Deafness diagnosis, Deafness genetics, Female, Humans, Infant, Male, Microfilament Proteins metabolism, Nonsense Mediated mRNA Decay, Pedigree, RNA, Messenger genetics, RNA, Messenger metabolism, Vestibular Diseases diagnosis, Chloride Channels genetics, Codon, Nonsense, Homozygote, Microfilament Proteins genetics, Vestibular Diseases genetics

Abstract

In a consanguineous Turkish family diagnosed with autosomal recessive nonsyndromic hearing impairment (arNSHI), a homozygous region of 47.4 Mb was shared by the two affected siblings on chromosome 6p21.1-q15. This region contains 247 genes including the known deafness gene MYO6. No pathogenic variants were found in MYO6, neither with sequence analysis of the coding region and splice sites nor with mRNA analysis. Subsequent candidate gene evaluation revealed CLIC5 as an excellent candidate gene. The orthologous mouse gene is mutated in the jitterbug mutant that exhibits progressive hearing impairment and vestibular dysfunction. Mutation analysis of CLIC5 revealed a homozygous nonsense mutation c.96T>A (p.(Cys32Ter)) that segregated with the hearing loss. Further analysis of CLIC5 in 213 arNSHI patients from mostly Dutch and Spanish origin did not reveal any additional pathogenic variants. CLIC5 mutations are thus not a common cause of arNSHI in these populations. The hearing loss in the present family had an onset in early childhood and progressed from mild to severe or even profound before the second decade. Impaired hearing is accompanied by vestibular areflexia and in one of the patients with mild renal dysfunction. Although we demonstrate that CLIC5 is expressed in many other human tissues, no additional symptoms were observed in these patients. In conclusion, our results show that CLIC5 is a novel arNSHI gene involved in progressive hearing impairment, vestibular and possibly mild renal dysfunction in a family of Turkish origin.

Published

2015

6. How genetically heterogeneous is Kabuki syndrome?: MLL2 testing in 116 patients, review and analyses of mutation and phenotypic spectrum.

Author

Banka S, Veeramachaneni R, Reardon W, Howard E, Bunstone S, Ragge N, Parker MJ, Crow YJ, Kerr B, Kingston H, Metcalfe K, Chandler K, Magee A, Stewart F, McConnell VP, Donnelly DE, Berland S, Houge G, Morton JE, Oley C, Revencu N, Park SM, Davies SJ, Fry AE, Lynch SA, Gill H, Schweiger S, Lam WW, Tolmie J, Mohammed SN, Hobson E, Smith A, Blyth M, Bennett C, Vasudevan PC, García-Miñaúr S, Henderson A, Goodship J, Wright MJ, Fisher R, Gibbons R, Price SM, C de Silva D, Temple IK, Collins AL, Lachlan K, Elmslie F, McEntagart M, Castle B, Clayton-Smith J, Black GC, and Donnai D

Subjects

Cohort Studies, Face abnormalities, Female, Humans, Sequence Analysis, DNA, Abnormalities, Multiple genetics, DNA-Binding Proteins genetics, Genetic Heterogeneity, Hematologic Diseases genetics, Mutation, Neoplasm Proteins genetics, Phenotype, Vestibular Diseases genetics

Abstract

MLL2 mutations are detected in 55 to 80% of patients with Kabuki syndrome (KS). In 20 to 45% patients with KS, the genetic basis remains unknown, suggesting possible genetic heterogeneity. Here, we present the largest yet reported cohort of 116 patients with KS. We identified MLL2 variants in 74 patients, of which 47 are novel and a majority are truncating. We show that pathogenic missense mutations were commonly located in exon 48. We undertook a systematic facial KS morphology study of patients with KS at our regional dysmorphology meeting. Our data suggest that nearly all patients with typical KS facial features have pathogenic MLL2 mutations, although KS can be phenotypically variable. Furthermore, we show that MLL2 mutation-positive KS patients are more likely to have feeding problems, kidney anomalies, early breast bud development, joint dislocations and palatal malformations in comparison with MLL2 mutation-negative patients. Our work expands the mutation spectrum of MLL2 that may help in better understanding of this molecule, which is important in gene expression, epigenetic control of active chromatin states, embryonic development and cancer. Our analyses of the phenotype indicates that MLL2 mutation-positive and -negative patients differ systematically, and genetic heterogeneity of KS is not as extensive as previously suggested. Moreover, phenotypic variability of KS suggests that MLL2 testing should be considered even in atypical patients.

Published

2012

7. CHARGE syndrome: an update.

Author

Sanlaville D and Verloes A

Subjects

Central Nervous System Diseases congenital, Choanal Atresia genetics, Coloboma genetics, Craniofacial Abnormalities genetics, Female, Growth Disorders congenital, Growth Disorders genetics, Heart Defects, Congenital genetics, Holoprosencephaly genetics, Humans, Male, Pregnancy, Prenatal Diagnosis, Syndrome, Vestibular Diseases congenital, Vestibular Diseases genetics, Abnormalities, Multiple genetics, Chromosome Disorders genetics, DNA Helicases genetics, DNA-Binding Proteins genetics, Mutation genetics

Abstract

CHARGE syndrome is a rare, usually sporadic autosomal dominant disorder due in 2/3 of cases to mutations within the CHD7 gene. The clinical definition has evolved with time. The 3C triad (Coloboma-Choanal atresia-abnormal semicircular Canals), arhinencephaly and rhombencephalic dysfunctions are now considered the most important and constant clues to the diagnosis. We will discuss here recent aspects of the phenotypic delineation of CHARGE syndrome and highlight the role of CHD7 in its pathogeny. We review available data on its molecular pathology as well as cytogenetic and molecular evidences for genetic heterogeneity within CHARGE syndrome.

Published

2007

8. Mutations in the COCH gene are a frequent cause of autosomal dominant progressive cochleo-vestibular dysfunction, but not of Meniere's disease.

Author

Usami S, Takahashi K, Yuge I, Ohtsuka A, Namba A, Abe S, Fransen E, Patthy L, Otting G, and Van Camp G

Subjects

Adult, DNA Mutational Analysis, Deafness genetics, Exons, Extracellular Matrix Proteins, Genes, Dominant, Humans, Japan, Middle Aged, Models, Molecular, Pedigree, Point Mutation, Protein Binding, Protein Structure, Tertiary, Vertigo genetics, Hearing Loss, Sensorineural genetics, Meniere Disease genetics, Mutation, Proteins genetics, Vestibular Diseases genetics

Abstract

The COCH gene is the only gene identified in man that causes autosomal dominantly inherited hearing loss associated with vestibular dysfunction. The condition is rare and only five mutations have been reported worldwide. All affected families showed a similar progressive hearing loss and vestibular dysfunction. Since Meniere's disease-like symptoms have also been described in some families, it was suggested that COCH mutations might be present in some patients diagnosed with Meniere's disease. In this study, using a Japanese population, we performed a COCH mutation analysis in 23 patients from independent families with autosomal dominant hearing impairment, four of whom reported vestibular symptoms, and also in 20 Meniere's patients. While a new point mutation, A119 T, was found in a patient with autosomal dominant hearing loss and vestibular symptoms, no mutations were found in the Meniere's patients. Like all other previously identified COCH mutations, the mutation identified here is a missense mutation located in the FCH domain of the protein. The current mutation is located in close spatial proximity to W117, in which a mutation (W117R) had previously been associated with autosomal dominant hearing loss. Model building suggests that, like the W117R mutation, the A119 T mutation does not affect the structural integrity of the FCH domain, but may interfere with the interaction with a yet unknown binding partner. We conclude that mutations in the COCH gene are responsible for a significant fraction of patients with autosomal dominantly inherited hearing loss accompanied by vestibular symptoms, but not for dominant hearing loss without vestibular dysfunction, or sporadic Meniere's disease.

Published

2003