A Novel Gap Junction Alpha 8 (GJA8) Mutation Associated with a Congenital Cataract Patient in Pakistan
A Novel Gap Junction Alpha 8 (GJA8) Mutation Associated with a Congenital Cataract Patient in Pakistan
Ayesha Zahid, Ammara Muazzam, Sidra Mustafa, Saba Irshad*, Malik Siddique Mahmood and Rehman Shahzad
Institute of Biochemistry and Biotechnology, University of the Punjab-54590, Lahore, Pakistan
ABSTRACT
Cataracts are principal cause of visual impairments among people, although ocular surgery can reestablish vision in such patients but genetic researches have validated that, mutations in GJA8 are coherent source of lens opaqueness and inappropriate growth of fiber cells. In the present study, a novel G to C substitution (1104G>C) (pE368Q) was screened by PCR-SSCP in exon 2 of GJA8 and this tansversion altered exceedingly conserved glutamic acid to glutamine at site which was involved in coding of ASF1 like histone chaperone. Further presumption based on structural and functional analysis of mutated protein was anticipated by bioinformatics tools, which manifest mild changes in overall charge but altered post translational modifications in a way which might have a deleterious effect on ion channels anatomy and on the whole, pave ways to the genesis of cataract.
Article Information
Received 08 February 2017
Revised 14 March 2017
Accepted 25 March 2017
Available online 12 July 2017
Authors’ Contribution
AZ did the experimental work. SM helped in blood sampling. AM wrote the article. MSM helped in bioinformatics analysis. RS submitted sequence to NCBI. SI supervised the work.
Key words
Congenital cataracts, GJA8, Mutation screening, PCR-SSCP.
DOI: http://dx.doi.org/10.17582/journal.pjz/2017.49.4.1365.1372
* Corresponding author: [email protected]
0030-9923/2017/0004-1365 $ 9.00/0
Copyright 2017 Zoological Society of Pakistan
INTRODUCTION
Congenital cataract is one of the pre-eminent sources of visual impairment among children and reported for one tenth instance of visual loses in them (Lambert and Drack, 1996; Wang et al., 2011). It affects 0.6-6 out of 10,000 infants in developed countries and 5-15 per 15,000 in developing countries (Francis et al., 2000; Reddy et al., 2004; Holmes et al., 2003; Apple et al., 2000). It can occur in solitary or in compound state which affected miscellaneous tissues (Hu et al., 2010). Not all the congenital cataract cases are genetic, only 50% are which have multiple geneses; they may be autosomal dominant, autosomal recessive and X-linked (Vanita et al., 2009).
At present congenital cataract is associated with mutation in more than 18 known genes that include; FTL, CRYGC, CRYBB2, CRYBA1, EPHA2, CRYAB, CHMP4B. GJA8. GJA3, CRYGD, DMPK, MIP, BFSP2, PITX3, CTDP1, SIL1, RAB3GAP1, RAB3GAP2, RAB 18, GJA1, RECQL4, DHCR7,CRYBB3, NDP and NHS, located at divergent chromosomes (Xu and Traboulsi, 2014; Chen et al., 2015). One half of the mutations are associated with genes that code for crytallins, while a quarter with genes that encoded connexin and remaining to other genes that encrypted chromatin modifying protein-4B, beaded heat shock transcription factor-4, filament structural proteins-2, lens intrinsic membrane protein 2, avian musculoaponeurotic fibrosarcoma, paired-like homeodomain transcription factor-3, Eph-receptor type-A2 and major intrinsic protein or aquaporin-0 (Hejtmancik, 2008; Huang and He, 2010).
Cataract exhibits a variety of morphologies that comprises anterior polar, pyramidal, anterior lenticonus, cortical lamellar, fetal nuclear, posterior polar, posterior lentiglobus, posterior subcapsular, persistent fetal vasculature (PFV) and traumatic disruption of lens. It is important to identify the proper morphology that disclosed its etiology and ultimate possible prognosis and cure (Wilson, 2015). Lens cells in eye, accomplished intracellular communication via an immense network of gap junctions formed by the structural proteins belongs to connexin family, to permit the trafficking of ions and small solutes of size < 1 kDa (Girelli et al., 2001). Connexin 50 (GJA8, Cx50) and Connexin 46 (GJA3, Cx46) together build up the gap junctions. At present nearly 34 different mutations have been specified in GJA8 gene and most of the reported mutations were missense (Sarkar et al., 2014).
Here, we detect a novel mutation in Cx50 (GJA8) gene in one of the congenital cataract patient, in Pakistan, by the use of PCR-SSCP. This may help to comprehend the role of this mutation in the prognosis of disease.
Materials and methods
Sample collection
After receiving the ethical approval from hospital authorities and patients, 27 clinically diagnosed congenital cataract cases with age ranges from 1-8 years old, were selected for the study from different parts of Punjab province, at Children Hospital, Lahore Pakistan. These congenital cataract cases had no other ocular or systemic abnormalities. The complete history of the patients was taken by knowing the status of affected patients. A total of 27 age-matched normal individuals without any ocular or systemic abnormalities were certain as control.
DNA Isolation and PCR amplification
DNA isolation of controls and patients samples was performed using the standard protocol (Miller et al., 1988). DNA spectrometry was used for quantitative analysis of isolated genomic DNA and agarose gel electrophoresis (with 1% agarose) was used for qualitative analysis. The GJA8 exon 2 was amplified in congenital cataract patients and controls. PCR amplification was performed for all the primer sets (Table I) in a 25 µl volume mixture containing 20 mM of each primer, 100 ng of genomic DNA, 1 unit of Taq polymerase, 10 mM of dNTPs and 10 X PCR buffer. PCR condition was set with an initial denaturation for 10 min at 94 °C, followed by 35 cycles of denaturation for 45 seconds at 94 °C, annealing for 45 seconds at 58 °C and extension for 45 seconds at 72 °C with a final extension for 10 min at 72 °C. Amplified PCR product was observed on 1.5% agarose gel.
Table I.- Sequence of the Oligonucleotide primers (Kumar et al., 2011).
Gene |
Sequences |
Tm (oC) |
GJA8-(1)-F | 5′-TATGGGCGACTGGAGTTTCCT-3′ |
57.8 |
GJA8-(1)-R |
5′-CTCCATGCGGACGTAGTGCAC-3′ |
61.7 |
GJA8-(2)-F |
5′-CTCTGGGTGCTGCAGATCATC-3′ |
59.8 |
GJA8-(2)-R |
5′-CACAGAGGCCACAGACAACAT-3′ |
57.8 |
GJA8-(3)-F |
5′-CACTACTTCCTGTACGGGTTC-3′ |
57.8 |
GJA8-(3)-R |
5′-CTCTTGGTAGCCCCGGGACAA-3′ |
61.7 |
GJA8-(4)-F |
5′-GTCTCCTCCATCCAGAAAGCC-3′ |
59.8 |
GJA8-(4)-R |
5′-TCATACGGTTAGATCGTCTGA-3′ |
53.9 |
SSCP and sequence analysis
Single stranded polyacrylamide gel analysis with 8% polyacrylamide was done to identify novel mutations in GJA8 gene. Amplified products were purified by using Fermentas GeneJET Gel Extraction Kit (#K0691, #K0692). Purified products were sequenced by First Base Laboratories (Sdn Bhd No. 7-1 to 7-3, Jalan SP 2/7, Taman Serdang Perdana, Seksyen 2, 43300 Seri Kembangan, Selangor, Malaysia). Sequencing results were analyzed by using BLAST and Clustal Omega.
Bioinformatics analysis
I-TASSER, was used for the prediction of secondary structure of wild type protein along with its prophesized 3-D structure, by using 10 most appropriate threading templates, which have been nominated on the basis of their Z-score. PROVE and ERRAT were used for the authentication of anticipated structure. Ramachandran plot of wild type protein was also plotted for the estimation of energetically stable amino acids. SWISS MODEL was used for the assessment of superimposed structure of wild type and mutated proteins for the scrutiny of possible structural variations. Stability of wild-type, as well as the mutated model, is calculated by FoldX software.
Functional analysis
Functional analysis of modified protein was done by using online tools HOPE and MutPred.
Results
Clinical assessment
The cataract cases included in this study had no consanguineous marriage or any other family history. Total 27 congenital cataract cases with age group ranges from 1-8 years old, were included in this study. Most of them were infants. In the following study, 17 cases were male and 10 were female. The time of onset of disease was the age when it was first observed or detected by parents and doctors at the Ophthalmology section of Children Hospital, Lahore.
Mutational analysis
Genomic DNA was isolated according to standard procedure. The standard PCR, with all primer sets was performed for affected and control samples. The amplified products were run on 8% SSCP-PAGE for analyses of their banding pattern. SSCP-PAGE results showed that polymorphism exists in the amplified region of exon 2 of GJA8 in one of the patient (Fig. 1). PCR product of patient sample which showed mobility was sequenced for further analysis.
Sequence analysis
Sequence of normal individual matched perfectly with the reported sequence of GJA8 exon 2 which was retrieved from NCBI (GenBank NG_016242.1) (Fig. 2).
This reported sequence was also compared with the sequence of patient sample, which displayed a single nucleotide variation in the coding region of GJA8 exon 2 at nucleotide 1104 (Highlighted in Figures 3 and 4). Amino acid sequence alignment of patient sample with reported sequence revealed that a novel 1104G>C (pE368Q) (GenBank KY556641) point mutation that substitutes glutamic acid, at position 368 with glutamine in patient sample A14 (Fig. 5). Substitution of glutamic acid to glutamine at position 368 in GJA8 exon 2 is a novel mutation as it is not previously reported.
Bioinformatics analysis
I-TASSER anticipated secondary structure of the wild type GJA8 protein. Secondary structure of wild type protein from amino acid 360 to 380 is presented in Figure 6.
Glutamic acid at point 368 is involved in formation of coiled secondary structure with a total conf. score of 7. Five 3-D models of wild type GJA8 protein on the basis of energy and functional annotation were projected by I-TASSER. PROVE and ERRAT has verified one out of five predicted models of the I-TASSER by giving overall quality factor of 89.880 (Fig. 7). Ramachandran Plot of wild type GJA8 indicates that maximum residues fall in “Highly allowed region” and few in forbidden region (Fig. 8). Superimposed model of wild type and mutated GJA8 was prophesied by SWISS MODEL (Fig. 9), shows no major effect of mutation on protein structure. Stability of wild-type protein is 541.85 kcal/mol and 1104G>C (pE368Q) mutation imparts protein a little stable confirmation that is 539.13 kcal/mol. So the energy difference between mutated and wild type protein is -2.72 kcal/mol.
Functional analysis
Impact of mutation on the function of GJA8 protein was determined by online tool HOPE. Each amino acid has its own precise individuality which is allocated by presence of specific charge, size of side chain and hydrophobicity assessment. Conversion of glutamic acid to glutamine neutralizes the negative charge of amino acid at position 368; this loss of charge will affect its interaction with other amino acids and neighboring molecules. Gain and loss of function was estimated by MutPred which provide imperative analysis of mutated residue. This mutation would result in increased number of mutated GJA8 sheets, besides this gain of glycosylation at lys371, gain of methylation at lys371, loss of ubiquitination at lys363 and loss of loop are ultimate consequences of this mutation.
Discussion
In vertebrates the crystalline lens is a biconvex transparent structure, which helps light to focus on the retina. The disruption of proteins results in opacification of the lens, which can result in blindness. The lens consists of: the lens capsule, the epithelial cells and the lens fibres (Beyer et al., 2013). Cells present on the surface of lens are metabolically active and sustain cell to cell correspondence to perpetuate transparency of lens (Hejtmancik, 2008). Gap junctions, made up of connexons; sustain the integral function of cells by permitting communication between them. Each connexon comprises a pairs of Connexin43, 46 and 50 subunits (Santana and Waiswo, 2011; Beyer and Berthoud, 2014). They adhere to cell surface; provide anchorage to extracellular matrix, sandwiched between neighboring cells. This facilitates passage of solutes, ions and molecules between cells to maintain proper functioning of avascular organ (Beyer and Berthoud, 2014).
Connexin50 has vast chronicles of reported mutations. At present 34 mutations have been identified which lead to different morphological states (Chen et al., 2015; Sellitto et al., 2004). These mutation lead to modify secondary and tertiary structure of coded proteins, which ultimately stemmed in its misfolding, unfolding or aggregation (Raju and Abraham, 2011). GJA8 gene code for connexin-50, its expression is exceedingly high in fiber cells, and crucial for maintenance of lens appropriate structure and function (Rong et al., 2002).
Recently, GJA8 gene was knocked down in a rabbit model by aid of CRISPR/Cas9 system at zygote level which revealed the significance of GJA8 in perpetuation of lens normal phenotype (Yuan et al., 2016). GJA8-/+ mice disclosed phenotype analogous to humans. This revealed the prominence of GJA8 in preservation of eye standard anatomy and precision of CRISPR/Cas9 system as gene editing toll (Yuan et al., 2016).
To acknowledge above data, we screen GJA8 gene of 27 cataract patients with no family history of cataract, a subtle 1104G>C (pE368Q) (GenBank KY556641) transversion that substitutes glutamic acid to glutamine was identified at exon 2 of GJA8 gene in one of the patient, which revealed that glutamic acid at position 368 in normal GJA8 protein was changed to glutamine, which is highlighted in Figure 6. Contemporarily missense mutations at 264C>A, 131T>C and 829C > T, in the coding region of GJA8, cause p.P88T, p.V44A and p.H277Y alterations identified respectively in recent years (Ge et al., 2014; Zhu et al., 2015; Chen et al., 2015).
Glutamic acid is a negatively charged amino acid whereas glutamine is neutral. Glutamic acid is decidedly conserved amino acid at this point which accentuate on its functional significance. Amino acid extant from 334 to 385 codes for a chaperon named as “ASF1 like histone chaperone” which implicate proper folding of protein to facilitate its regular action. Substitution of negatively charged amino acid with neutral interrupts its interaction with neighboring molecules but have no inauspicious effect on the overall structure of mutated GJA8 protein.
Energetically mutated GJA8 is immensely stable in comparison to wild type GJA8 with an energy difference of -2.72 kcal/mol. Although functional analysis exhibit miscellaneous posttranslational deformities, which lead to, gain of glycosylation and loss of ubiquitination at some peculiar amino acid residues. Besides this, loss of loop at the site of mutation and increase in number of sheets in overall structure of protein might disrupt systematic folding of protein, which ultimately misfold it and disorder the ordered association of lens cells, which might lead to cloudiness of lens.
Conclusion
Mutational screening of GJA8 gene showed substitution of glutamic acid to glutamine at codon position 368 in the coding region of GJA8 exon 2, which is a novel mutation. The extent to which this change interferes with the normal functioning of the protein is not yet known, although it is hypothesized that this region codes for a chaperone which is actually meant for proper folding of protein. Disruption in charge, at extremely conserved site may disturb its tertiary structure to the extent of genesis of cataract. Further functional analysis of this mutation on fiber cell development would illuminate our knowledge with the reasons involved in disruption of ion channels and metabolic inequity in these cells, so that we can get a better view of this communal pathogenesis of lens and this would finally pave paths to enterprise possible genetic and physical therapies.
Acknowledgment
We are thankful to all the patients and their family members for the gratitude support. The research was supported financially by the University of the Punjab, Lahore.
Statement of conflict of interest
Authors have declared no conflict of interest.
References
Apple, D.J., Ram, J., Foster, A. and Peng, Q., 2000. Elimination of cataract blindness: a global perspective entering the new millennium. Surv. Ophthalmol., 45: 1-196.
Beyer, E.C. and Berthoud, V.M., 2014, Connexin hemichannels in the lens. Front. Physiol., 5: 20. https://doi.org/10.3389/fphys.2014.00020
Beyer, E.C., Ebihara, L. and Berthoud, V.M., 2013. Connexin mutants and cataracts. Front. Pharmacol., 15: 4-43. https://doi.org/10.3389/fphar.2013.00043
Chen, C., Sun, Q., Gu, M., Liu, K., Sun, Y. and Xu, X., 2015. A novel Cx50 (GJA8) p.H277Y mutation associated with autosomal dominant congenital cataract identified with targeted next-generation sequencing. Graefes Arch. clin. exp. Ophthalmol., 253: 915-924. https://doi.org/10.1007/s00417-015-3019-x
Francis, P.J., Berry, V., Bhattacharya, S.S. and Moore, A.T., 2000. The genetics of childhood cataract. J. med Genet., 37: 481-488. https://doi.org/10.1136/jmg.37.7.481
Ge, X.L., Zhang, Y., Wu, Y., Jineng, L.V., Zhang, W., Jin, Z.B. and Gu, F., 2014. Identification of a novel GJA8 (Cx50) point mutation causes human dominant congenital cataracts. Sci. Rep., 4: 4121. https://doi.org/10.1038/srep04121
Girelli, D., Bozzini, C., Zecchina, G., Tinazzi, E., Bosio, S., Piperno, A. and Corrocher, R., 2001. Clinical, biochemical and molecular findings in a series of families with hereditary hyperferritinaemia–cataract syndrome. Br. J. Haematol., 115: 334-340. https://doi.org/10.1046/j.1365-2141.2001.03116.x
Hejtmancik, J.F., 2008. Congenital cataracts and their molecular genetics. Semin. Cell dev. Biol., 19: 134–149. https://doi.org/10.1016/j.semcdb.2007.10.003
Holmes, J.M., Leske, D.A., Burke, J.P. and Hodge, D.O., 2003. Birth prevalence of visually significant infantile cataract in a defined U.S. population. Ophthal. Epidemiol., 10: 67–74. https://doi.org/10.1076/opep.10.2.67.13894
Hu, S., Wang, B., Zhou, Z., Zhou, G., Wang, J., Ma, X. and Qi, Y., 2010. A novel mutation in GJA8 causing congenital cataract-microcornea syndrome in a Chinese pedigree. Mol. Vis., 16: 1585–1592.
Huang, B. and He, W., 2010. Molecular characteristics of inherited congenital cataracts. Eur. J. med. Genet., 53: 347–357. https://doi.org/10.1016/j.ejmg.2010.07.001
Kumar, M., Agarwal, T., Khokhar, S., Kaur, P., Roy, T.S. and Dada, R., 2011. Mutation screening and genotype phenotype correlation of α-crystallin, γ-crystallin, and GJA8 gene in congenital cataract. Mol. Vis., 17: 693-707. http://www.molvis.org/molvis/v17/a79
Lambert, S.R. and Drack, A.V., 1996. Infantile cataracts. Surv. Ophthalmol., 40: 427-458. https://doi.org/10.1016/S0039-6257(96)82011-X
Liang, C., Liang, H., Yang, Y., Ping, L. and Jie, Q., 2015. Mutation analysis of two families with inherited congenital cataracts. Mol. med. Rep., 12: 3469-3475. https://doi.org/10.3892/mmr.2015.3819
Miller, S.A., Dykes, D.D. and Polesky, H.F., 1988. A simple salting out procedure for extracting DNA from human nucleated cells. Nucl. Acids Res., 16: 1215. https://doi.org/10.1093/nar/16.3.1215
Raju, I. and Abraham, E.C., 2011. Congenital cataract causing mutants of alphaA-crystallin/sHSP form aggregates and aggresomes degraded through ubiquitin-proteasome pathway. PLoS One, 6: 1-10. https://doi.org/10.1371/journal.pone.0028085
Reddy, M.A., Francis, P.J., Berry, V., Bhattacharya, S.S. and Moore, A.T., 2004. Molecular genetic basis of inherited cataract and associated phenotypes. Surv. Ophthalmol., 49: 300–315. https://doi.org/10.1016/j.survophthal.2004.02.013
Rong, P., Wang, X., Niesman, I., Wu, Y., Benedetti, L.E., Dunia, I., Levy, E. and Gong, X., 2002. Disruption of Gja8 (alpha8 connexin) in mice leads to microphthalmia associated with retardation of lens growth and lens fiber maturation. Development, 129: 167–174.
Santana, A. and Waiswo, M., 2011. The genetic and molecular basis of congenital cataract. Arq. Bras. Oftalmol., 74: 136–142. https://doi.org/10.1590/S0004-27492011000200016
Sarkar, D., Ray, K. and Sengupta, M., 2014. Structure-function correlation analysis of connexin50 missense mutations causing congenital cataract: electrostatic potential alteration could determine intracellular trafficking fate of mutants. BioMed. Res. Int., 2014: Article ID 673895. https://doi.org/10.1155/2014/673895
Sellitto, C., Li, L. and White, T,W., 2004. Connexin50 is essential for normal postnatal lens cell proliferation. Invest. Ophthalmol. Vis. Sci., 45: 3196–3202. https://doi.org/10.1167/iovs.04-0194
Vanita, V., Singh, J. R., Singh, D., Varon, R. and Sperling, K., 2009. Novel mutation in the γ-S crystallin gene causing autosomal dominant cataract. Mol. Vis., 15: 476–481.
Wang, K.J., Wang, S., Cao, N.Q., Yan, Y.B. and Zhu S.Q., 2011. A novel mutationin CRYBB1 associated with congenital cataract-microcornea syndrome: the p.Ser129Arg mutation destabilizes the βB1/βA3-crystallin heteromer but not theβ B1-crystallin homomer. Hum. Mutat., 32: 2050–2060. https://doi.org/10.1002/humu.21436
Wilson, M.E., 2015. Pediatric cataracts: Overview. American Academy of Ophthamology.
Xu, L.T. and Traboulsi, E.I., 2014. Genetics of congenital cat2aracts. In: Pediatric cataract surgery (eds. M.E. Wilson and R.H. Trivedi), Lippincott Walters Kluwer, Philadelphia, USA, pp. 1-8.
Yuan, L., Sui, T., Chen, M., Deng, J., Huang, Y., Zeng, J. and Lai, L. 2016. CRISPR/Cas9-mediated GJA8 knockout in rabbits recapitulates human congenital cataracts. Sci. Rep., 6: 22024. https://doi.org/10.1038/srep22024
Zhang, Y., Stokes, N., Jia, B., Fan, S. and Gu, M., 2014. Towards ultra-thin plasmonic silicon wafer solar cells with minimized efficiency loss. Sci. Rep., 4: 4939. https://doi.org/10.1038/srep04939
Zhu, Y., Yu, H., Wang, W., Gong, X. and Yao, K., 2015. Correction: A novel GJA8 mutation (p. V44A) causing autosomal dominant congenital cataract. PLoS One, 10: 5. https://doi.org/10.1371/journal.pone.0125949
To share on other social networks, click on any share button. What are these?