Abstract
Congenital cataract disease is a clinically and genetically heterogeneous lens disorder. The purpose of this study was to identify the genetic defects and to investigate the relationships between disease-causing genes and lens morphology in congenital cataracts. Patients were given a physical examination and their blood samples were collected for DNA extraction. Mutation analysis was performed by direct sequencing of the following candidate genes: CRYGC, CRYGD, CRYGS, GJA8, GJA3 and CRYAA. Mutational analysis of CRYGD identified a recurrent (p.P24T) mutation in two unrelated families with congenital coralliform cataracts and three novel (p.Q101X, p.E104fsX4 and p.E135X) mutations in three families with congenital nuclear cataracts. The p.E135X mutation is a de novo mutation. Haplotype analysis showed patients inherited the same CRYGD allele originated from father. The p.E135X mutation seen in two siblings suggests a mechanism of gonadal mosaicism in the father.
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Introduction
Congenital cataracts are common and cause approximately one third of infant blindness occurring in approximately 1–6 of every 10,000 live births. One quarter of congenital cataract disease cases are hereditary1,2,3,4.
Congenital cataract disease is a clinically and genetically heterogeneous lens disorder. Cataracts that are phenotypically identical can result from mutations at different genetic loci and can have different inheritance patterns. Conversely, cataracts with dissimilar phenotypes may result from mutations in a single gene or gene family. It is believed that the type of genetic mutation is related to the morphology of the cataract5. To date, about 40 genetic loci have been linked to congenital cataracts and 26 genes have been cloned and sequenced, including crystallins, connexins, heat shock transcription factor-4, aquaporin-0 and beaded filament structural protein-25.
In this study, we collected information on five families with congenital cataracts. In the follow-up genetic study, we identified four mutations in the CRYGD that is responsible for the disease.
Results
Clinical findings
Patients suffering from bilateral cataracts were diagnosed at childhood in all five families. Two families afflicted with congenital coralliform cataracts were enrolled in the Jiangxi province and the Hebei province respectively in this study. Three families afflicted with congenital nuclear cataracts had completed cataract operation in all patients. None of the participants had any other related ophthalmic syndromes.
Mutation analysis
By directly sequencing the coding region of CRYGD, we identified a recurrent (p.P24T) mutation in two unrelated families with congenital coralliform cataracts and three novel (p.Q101X, p.E104fsX4 and p.E135X) mutations in three families with congenital nuclear cataracts (Figs 1 and 2). The p.E135X mutation was identified in two affected individuals but was not found in their parents in family ZSY. These mutations were not found in healthy relatives or the 100 control populations from the same ethnic background.
Paternity testing and haplotype analysis
Paternity testing confirmed that the parents of the patients are biological parents in family ZSY. Haplotype analysis showed that two patients inherited the same CRYGD allele from their father (Fig. 3).
Discussion
Twenty mutations in CRYGD have previously been reported (three in our study) (Table 1)6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,21,22. In the present study, we identified three novel mutations in CRYGD, which are predicted to cause premature stop codon and lead to the deletion of the C-terminal of protein.
CRYGD composes of two similar domains, in which each domain composes of two similar motifs. Each motif, about forty amino acid residues long, is folded in a distinctive ‘Greek key’ pattern. The missing residues at the C-terminus influence the folding of the Greek key motif (GKM) and then affect the biological functions of the protein.
Coralliform cataracts are a special form of congenital cataracts. Several studies have shown that mutations in the CRYGD gene can result in congenital coralliform cataracts and the P24T mutation of CRYGD has been reported in multiple cases8. In the two autosomal dominant congenital coralliform cataract pedigrees in this study, we identified a recurrent P24T mutation. According to the reported pedigrees, most of the congenital coralliform cataracts resulted from CRYGD mutations. This information indicates that the coralliform phenotype and the CRYGD gene are closely related. Our results support the idea that virulence genes and lens morphology are related23,24,25,26,27,28,29. Results of biophysical analysis have shown that the P24T mutant protein has a significantly lower solubility than wild-type human γD crystalline30,31.
The p.E135X mutation in family ZSY was found in two patients, but the mutation was not observed in the parents of either patient. The haplotype analysis showed that the father shares the common chromosome fragment with the children, indicating that the fathers are in a state of gonadal mosaicism32.
Methods
Patients and clinical data
Families enrolled in this study were from the Inner Mongolia Autonomous Region, Jiangxi province, Hebei province and Shandong province of China. All patients had undergone cataract surgery. Clinical examination, peripheral blood collection and DNA extraction were performed in the Department of Ophthalmology at the Peking Union Medical College Hospital. This study followed the tenets of the Declaration of Helsinki and was approved by the Ethics Committee of the Peking Union Medical College Hospital. The methods were carried out in accordance with the approved guidelines. Written informed consent was obtained from all participants. Clinical data for these subjects was collected through detailed ocular examinations. In addition, physical examinations were performed to exclude systemic diseases.
Mutation analysis
CRYGC, CRYGD, CRYGS, GJA8, GJA3 and CRYAA were selected as candidate genes. All coding exons for these genes were amplified by polymerase chain reaction (PCR) using a set of previously described paired primers. The PCR products were sequenced using an ABI3730 Automated Sequencer (PE Biosystems, Foster City, CA, USA).
Paternity testing and haplotype analysis
GoldeneyeTM20A was used to mark up the allele in different chromosomes in members of the family ZSY. Markers surrounding the gene and inside the gene were analysed to determine the haplotype of the ZSY family.
Additional Information
How to cite this article: Yang, G. et al. Novel mutations in CRYGD are associated with congenital cataracts in Chinese families. Sci. Rep. 6, 18912; doi: 10.1038/srep18912 (2016).
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Contributions
Study design G.X.Y. and J.L.Z. Collected the samples and performed the experiments G.X.Y., W.L.Z., Z.M.C. and Z.Q.L. Data interpretation and analysis: G.X.Y. Wrote the manuscript: G.X.Y. All authors have read and approved the final manuscript.
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Yang, G., Chen, Z., Zhang, W. et al. Novel mutations in CRYGD are associated with congenital cataracts in Chinese families. Sci Rep 6, 18912 (2016). https://doi.org/10.1038/srep18912
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DOI: https://doi.org/10.1038/srep18912
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