Your search keyword '"Hosseini, S Mohsen"' showing total 8 results

1. Genome-wide association meta-analysis highlights light-induced signaling as a driver for refractive error.

Author

Tedja MS, Wojciechowski R, Hysi PG, Eriksson N, Furlotte NA, Verhoeven VJM, Iglesias AI, Meester-Smoor MA, Tompson SW, Fan Q, Khawaja AP, Cheng CY, Höhn R, Yamashiro K, Wenocur A, Grazal C, Haller T, Metspalu A, Wedenoja J, Jonas JB, Wang YX, Xie J, Mitchell P, Foster PJ, Klein BEK, Klein R, Paterson AD, Hosseini SM, Shah RL, Williams C, Teo YY, Tham YC, Gupta P, Zhao W, Shi Y, Saw WY, Tai ES, Sim XL, Huffman JE, Polašek O, Hayward C, Bencic G, Rudan I, Wilson JF, Joshi PK, Tsujikawa A, Matsuda F, Whisenhunt KN, Zeller T, van der Spek PJ, Haak R, Meijers-Heijboer H, van Leeuwen EM, Iyengar SK, Lass JH, Hofman A, Rivadeneira F, Uitterlinden AG, Vingerling JR, Lehtimäki T, Raitakari OT, Biino G, Concas MP, Schwantes-An TH, Igo RP Jr, Cuellar-Partida G, Martin NG, Craig JE, Gharahkhani P, Williams KM, Nag A, Rahi JS, Cumberland PM, Delcourt C, Bellenguez C, Ried JS, Bergen AA, Meitinger T, Gieger C, Wong TY, Hewitt AW, Mackey DA, Simpson CL, Pfeiffer N, Pärssinen O, Baird PN, Vitart V, Amin N, van Duijn CM, Bailey-Wilson JE, Young TL, Saw SM, Stambolian D, MacGregor S, Guggenheim JA, Tung JY, Hammond CJ, and Klaver CCW

Subjects

Adult, Asian People genetics, Blindness genetics, Blindness metabolism, Female, Gene Expression Regulation, Genetic Predisposition to Disease, Genome-Wide Association Study methods, Humans, Male, Myopia genetics, Polymorphism, Single Nucleotide, Refractive Errors metabolism, Retina metabolism, Retinal Pigment Epithelium metabolism, Signal Transduction, White People genetics, Refractive Errors genetics

Abstract

Refractive errors, including myopia, are the most frequent eye disorders worldwide and an increasingly common cause of blindness. This genome-wide association meta-analysis in 160,420 participants and replication in 95,505 participants increased the number of established independent signals from 37 to 161 and showed high genetic correlation between Europeans and Asians (>0.78). Expression experiments and comprehensive in silico analyses identified retinal cell physiology and light processing as prominent mechanisms, and also identified functional contributions to refractive-error development in all cell types of the neurosensory retina, retinal pigment epithelium, vascular endothelium and extracellular matrix. Newly identified genes implicate novel mechanisms such as rod-and-cone bipolar synaptic neurotransmission, anterior-segment morphology and angiogenesis. Thirty-one loci resided in or near regions transcribing small RNAs, thus suggesting a role for post-transcriptional regulation. Our results support the notion that refractive errors are caused by a light-dependent retina-to-sclera signaling cascade and delineate potential pathobiological molecular drivers.

Published

2018

2. Childhood gene-environment interactions and age-dependent effects of genetic variants associated with refractive error and myopia: The CREAM Consortium.

Author

Fan Q, Guo X, Tideman JW, Williams KM, Yazar S, Hosseini SM, Howe LD, Pourcain BS, Evans DM, Timpson NJ, McMahon G, Hysi PG, Krapohl E, Wang YX, Jonas JB, Baird PN, Wang JJ, Cheng CY, Teo YY, Wong TY, Ding X, Wojciechowski R, Young TL, Pärssinen O, Oexle K, Pfeiffer N, Bailey-Wilson JE, Paterson AD, Klaver CC, Plomin R, Hammond CJ, Mackey DA, He M, Saw SM, Williams C, and Guggenheim JA

Subjects

Adolescent, Age of Onset, Child, Female, Gene-Environment Interaction, Genetic Predisposition to Disease, Genome-Wide Association Study, Humans, Longitudinal Studies, Male, Asian People genetics, Myopia genetics, Polymorphism, Single Nucleotide, Refractive Errors genetics, White People genetics

Abstract

Myopia, currently at epidemic levels in East Asia, is a leading cause of untreatable visual impairment. Genome-wide association studies (GWAS) in adults have identified 39 loci associated with refractive error and myopia. Here, the age-of-onset of association between genetic variants at these 39 loci and refractive error was investigated in 5200 children assessed longitudinally across ages 7-15 years, along with gene-environment interactions involving the major environmental risk-factors, nearwork and time outdoors. Specific variants could be categorized as showing evidence of: (a) early-onset effects remaining stable through childhood, (b) early-onset effects that progressed further with increasing age, or (c) onset later in childhood (N = 10, 5 and 11 variants, respectively). A genetic risk score (GRS) for all 39 variants explained 0.6% (P = 6.6E-08) and 2.3% (P = 6.9E-21) of the variance in refractive error at ages 7 and 15, respectively, supporting increased effects from these genetic variants at older ages. Replication in multi-ancestry samples (combined N = 5599) yielded evidence of childhood onset for 6 of 12 variants present in both Asians and Europeans. There was no indication that variant or GRS effects altered depending on time outdoors, however 5 variants showed nominal evidence of interactions with nearwork (top variant, rs7829127 in ZMAT4; P = 6.3E-04).

Published

2016

3. Meta-analysis of gene-environment-wide association scans accounting for education level identifies additional loci for refractive error.

Author

Fan Q, Verhoeven VJ, Wojciechowski R, Barathi VA, Hysi PG, Guggenheim JA, Höhn R, Vitart V, Khawaja AP, Yamashiro K, Hosseini SM, Lehtimäki T, Lu Y, Haller T, Xie J, Delcourt C, Pirastu M, Wedenoja J, Gharahkhani P, Venturini C, Miyake M, Hewitt AW, Guo X, Mazur J, Huffman JE, Williams KM, Polasek O, Campbell H, Rudan I, Vatavuk Z, Wilson JF, Joshi PK, McMahon G, St Pourcain B, Evans DM, Simpson CL, Schwantes-An TH, Igo RP, Mirshahi A, Cougnard-Gregoire A, Bellenguez C, Blettner M, Raitakari O, Kähönen M, Seppala I, Zeller T, Meitinger T, Ried JS, Gieger C, Portas L, van Leeuwen EM, Amin N, Uitterlinden AG, Rivadeneira F, Hofman A, Vingerling JR, Wang YX, Wang X, Tai-Hui Boh E, Ikram MK, Sabanayagam C, Gupta P, Tan V, Zhou L, Ho CE, Lim W, Beuerman RW, Siantar R, Tai ES, Vithana E, Mihailov E, Khor CC, Hayward C, Luben RN, Foster PJ, Klein BE, Klein R, Wong HS, Mitchell P, Metspalu A, Aung T, Young TL, He M, Pärssinen O, van Duijn CM, Jin Wang J, Williams C, Jonas JB, Teo YY, Mackey DA, Oexle K, Yoshimura N, Paterson AD, Pfeiffer N, Wong TY, Baird PN, Stambolian D, Wilson JE, Cheng CY, Hammond CJ, Klaver CC, Saw SM, Rahi JS, Korobelnik JF, Kemp JP, Timpson NJ, Smith GD, Craig JE, Burdon KP, Fogarty RD, Iyengar SK, Chew E, Janmahasatian S, Martin NG, MacGregor S, Xu L, Schache M, Nangia V, Panda-Jonas S, Wright AF, Fondran JR, Lass JH, Feng S, Zhao JH, Khaw KT, Wareham NJ, Rantanen T, Kaprio J, Pang CP, Chen LJ, Tam PO, Jhanji V, Young AL, Döring A, Raffel LJ, Cotch MF, Li X, Yip SP, Yap MK, Biino G, Vaccargiu S, Fossarello M, Fleck B, Yazar S, Tideman JW, Tedja M, Deangelis MM, Morrison M, Farrer L, Zhou X, Chen W, Mizuki N, Meguro A, and Mäkelä KM

Subjects

Asian People genetics, Gene Expression Profiling, Humans, Polymorphism, Single Nucleotide genetics, White People genetics, Educational Status, Environment, Genetic Loci, Genetic Predisposition to Disease, Genome-Wide Association Study, Refractive Errors genetics

Abstract

Myopia is the most common human eye disorder and it results from complex genetic and environmental causes. The rapidly increasing prevalence of myopia poses a major public health challenge. Here, the CREAM consortium performs a joint meta-analysis to test single-nucleotide polymorphism (SNP) main effects and SNP × education interaction effects on refractive error in 40,036 adults from 25 studies of European ancestry and 10,315 adults from 9 studies of Asian ancestry. In European ancestry individuals, we identify six novel loci (FAM150B-ACP1, LINC00340, FBN1, DIS3L-MAP2K1, ARID2-SNAT1 and SLC14A2) associated with refractive error. In Asian populations, three genome-wide significant loci AREG, GABRR1 and PDE10A also exhibit strong interactions with education (P<8.5 × 10(-5)), whereas the interactions are less evident in Europeans. The discovery of these loci represents an important advance in understanding how gene and environment interactions contribute to the heterogeneity of myopia.

Published

2016

4. Nine loci for ocular axial length identified through genome-wide association studies, including shared loci with refractive error.

Author

Cheng CY, Schache M, Ikram MK, Young TL, Guggenheim JA, Vitart V, MacGregor S, Verhoeven VJ, Barathi VA, Liao J, Hysi PG, Bailey-Wilson JE, St Pourcain B, Kemp JP, McMahon G, Timpson NJ, Evans DM, Montgomery GW, Mishra A, Wang YX, Wang JJ, Rochtchina E, Polasek O, Wright AF, Amin N, van Leeuwen EM, Wilson JF, Pennell CE, van Duijn CM, de Jong PT, Vingerling JR, Zhou X, Chen P, Li R, Tay WT, Zheng Y, Chew M, Burdon KP, Craig JE, Iyengar SK, Igo RP Jr, Lass JH Jr, Chew EY, Haller T, Mihailov E, Metspalu A, Wedenoja J, Simpson CL, Wojciechowski R, Höhn R, Mirshahi A, Zeller T, Pfeiffer N, Lackner KJ, Bettecken T, Meitinger T, Oexle K, Pirastu M, Portas L, Nag A, Williams KM, Yonova-Doing E, Klein R, Klein BE, Hosseini SM, Paterson AD, Makela KM, Lehtimaki T, Kahonen M, Raitakari O, Yoshimura N, Matsuda F, Chen LJ, Pang CP, Yip SP, Yap MK, Meguro A, Mizuki N, Inoko H, Foster PJ, Zhao JH, Vithana E, Tai ES, Fan Q, Xu L, Campbell H, Fleck B, Rudan I, Aung T, Hofman A, Uitterlinden AG, Bencic G, Khor CC, Forward H, Pärssinen O, Mitchell P, Rivadeneira F, Hewitt AW, Williams C, Oostra BA, Teo YY, Hammond CJ, Stambolian D, Mackey DA, Klaver CC, Wong TY, Saw SM, and Baird PN

Subjects

Adolescent, Adult, Aged, Asian People, Axial Length, Eye pathology, Eye Proteins metabolism, Female, Gene Expression, Genome-Wide Association Study, Humans, Male, Middle Aged, Polymorphism, Single Nucleotide, Refractive Errors ethnology, Refractive Errors pathology, Signal Transduction, White People, Axial Length, Eye metabolism, Eye Proteins genetics, Genetic Loci, Genetic Predisposition to Disease, Refractive Errors genetics

Abstract

Refractive errors are common eye disorders of public health importance worldwide. Ocular axial length (AL) is the major determinant of refraction and thus of myopia and hyperopia. We conducted a meta-analysis of genome-wide association studies for AL, combining 12,531 Europeans and 8,216 Asians. We identified eight genome-wide significant loci for AL (RSPO1, C3orf26, LAMA2, GJD2, ZNRF3, CD55, MIP, and ALPPL2) and confirmed one previously reported AL locus (ZC3H11B). Of the nine loci, five (LAMA2, GJD2, CD55, ALPPL2, and ZC3H11B) were associated with refraction in 18 independent cohorts (n = 23,591). Differential gene expression was observed for these loci in minus-lens-induced myopia mouse experiments and human ocular tissues. Two of the AL genes, RSPO1 and ZNRF3, are involved in Wnt signaling, a pathway playing a major role in the regulation of eyeball size. This study provides evidence of shared genes between AL and refraction, but importantly also suggests that these traits may have unique pathways., (Copyright © 2013 The American Society of Human Genetics. Published by Elsevier Inc. All rights reserved.)

Published

2013

5. Genome-wide meta-analyses of multiancestry cohorts identify multiple new susceptibility loci for refractive error and myopia.

Author

Verhoeven VJ, Hysi PG, Wojciechowski R, Fan Q, Guggenheim JA, Höhn R, MacGregor S, Hewitt AW, Nag A, Cheng CY, Yonova-Doing E, Zhou X, Ikram MK, Buitendijk GH, McMahon G, Kemp JP, Pourcain BS, Simpson CL, Mäkelä KM, Lehtimäki T, Kähönen M, Paterson AD, Hosseini SM, Wong HS, Xu L, Jonas JB, Pärssinen O, Wedenoja J, Yip SP, Ho DW, Pang CP, Chen LJ, Burdon KP, Craig JE, Klein BE, Klein R, Haller T, Metspalu A, Khor CC, Tai ES, Aung T, Vithana E, Tay WT, Barathi VA, Chen P, Li R, Liao J, Zheng Y, Ong RT, Döring A, Evans DM, Timpson NJ, Verkerk AJ, Meitinger T, Raitakari O, Hawthorne F, Spector TD, Karssen LC, Pirastu M, Murgia F, Ang W, Mishra A, Montgomery GW, Pennell CE, Cumberland PM, Cotlarciuc I, Mitchell P, Wang JJ, Schache M, Janmahasatian S, Igo RP Jr, Lass JH, Chew E, Iyengar SK, Gorgels TG, Rudan I, Hayward C, Wright AF, Polasek O, Vatavuk Z, Wilson JF, Fleck B, Zeller T, Mirshahi A, Müller C, Uitterlinden AG, Rivadeneira F, Vingerling JR, Hofman A, Oostra BA, Amin N, Bergen AA, Teo YY, Rahi JS, Vitart V, Williams C, Baird PN, Wong TY, Oexle K, Pfeiffer N, Mackey DA, Young TL, van Duijn CM, Saw SM, Bailey-Wilson JE, Stambolian D, Klaver CC, and Hammond CJ

Subjects

Alcohol Oxidoreductases genetics, Asian People genetics, Bone Morphogenetic Protein 2 genetics, Genetic Predisposition to Disease, Homeodomain Proteins genetics, Humans, KCNQ Potassium Channels genetics, Laminin genetics, Receptors, AMPA genetics, Risk Factors, Serine Proteases genetics, Trans-Activators genetics, White People genetics, Genome-Wide Association Study, Myopia genetics, Refractive Errors genetics

Abstract

Refractive error is the most common eye disorder worldwide and is a prominent cause of blindness. Myopia affects over 30% of Western populations and up to 80% of Asians. The CREAM consortium conducted genome-wide meta-analyses, including 37,382 individuals from 27 studies of European ancestry and 8,376 from 5 Asian cohorts. We identified 16 new loci for refractive error in individuals of European ancestry, of which 8 were shared with Asians. Combined analysis identified 8 additional associated loci. The new loci include candidate genes with functions in neurotransmission (GRIA4), ion transport (KCNQ5), retinoic acid metabolism (RDH5), extracellular matrix remodeling (LAMA2 and BMP2) and eye development (SIX6 and PRSS56). We also confirmed previously reported associations with GJD2 and RASGRF1. Risk score analysis using associated SNPs showed a tenfold increased risk of myopia for individuals carrying the highest genetic load. Our results, based on a large meta-analysis across independent multiancestry studies, considerably advance understanding of the mechanisms involved in refractive error and myopia.

Published

2013

6. Childhood gene-environment interactions and age-dependent effects of genetic variants associated with refractive error and myopia: The CREAM Consortium

Author

Fan, Qiao, Guo, Xiaobo, Tideman, J Willem L, Williams, Katie M, Yazar, Seyhan, Hosseini, S Mohsen, Howe, Laura D, Pourcain, Beaté St, Evans, David M, Timpson, Nicholas J, McMahon, George, Hysi, Pirro G, Krapohl, Eva, Wang, Ya Xing, Jonas, Jost B, Baird, Paul Nigel, Wang, Jie Jin, Cheng, Ching-Yu, Teo, Yik-Ying, Wong, Tien-Yin, Ding, Xiaohu, Wojciechowski, Robert, Young, Terri L, Pärssinen, Olavi, Oexle, Konrad, Pfeiffer, Norbert, Bailey-Wilson, Joan E, Paterson, Andrew D, Klaver, Caroline CW, Plomin, Robert, Hammond, Christopher J, Mackey, David A, He, Mingguang, Saw, Seang-Mei, Williams, Cathy, Guggenheim, Jeremy A, CREAM Consortium, Hosseini, S Mohsen [0000-0003-3626-9928], and Apollo - University of Cambridge Repository

Subjects

Male, Adolescent, Refractive Errors, Polymorphism, Single Nucleotide, Article, White People, Asian People, Myopia, Humans, Female, Gene-Environment Interaction, Genetic Predisposition to Disease, Longitudinal Studies, Age of Onset, Child, Genome-Wide Association Study

Abstract

Myopia, currently at epidemic levels in East Asia, is a leading cause of untreatable visual impairment. Genome-wide association studies (GWAS) in adults have identified 39 loci associated with refractive error and myopia. Here, the age-of-onset of association between genetic variants at these 39 loci and refractive error was investigated in 5200 children assessed longitudinally across ages 7-15 years, along with gene-environment interactions involving the major environmental risk-factors, nearwork and time outdoors. Specific variants could be categorized as showing evidence of: (a) early-onset effects remaining stable through childhood, (b) early-onset effects that progressed further with increasing age, or (c) onset later in childhood (N = 10, 5 and 11 variants, respectively). A genetic risk score (GRS) for all 39 variants explained 0.6% (P = 6.6E-08) and 2.3% (P = 6.9E-21) of the variance in refractive error at ages 7 and 15, respectively, supporting increased effects from these genetic variants at older ages. Replication in multi-ancestry samples (combined N = 5599) yielded evidence of childhood onset for 6 of 12 variants present in both Asians and Europeans. There was no indication that variant or GRS effects altered depending on time outdoors, however 5 variants showed nominal evidence of interactions with nearwork (top variant, rs7829127 in ZMAT4; P = 6.3E-04).

Published

2016

7. Nine loci for ocular axial length identified through genome-wide association studies, including shared loci with refractive error

Author

Cheng, Ching-Yu, Schache, Maria, Ikram, M Kamran, Young, Terri L, Guggenheim, Jeremy A, Vitart, Veronique, MacGregor, Stuart, Verhoeven, Virginie JM, Barathi, Veluchamy A, Liao, Jiemin, Hysi, Pirro G, Bailey-Wilson, Joan E, St Pourcain, Beate, Kemp, John P, McMahon, George, Timpson, Nicholas J, Evans, David M, Montgomery, Grant W, Mishra, Aniket, Wang, Ya Xing, Wang, Jie Jin, Rochtchina, Elena, Polasek, Ozren, Wright, Alan F, Amin, Najaf, van Leeuwen, Elisabeth M, Wilson, James F, Pennell, Craig E, van Duijn, Cornelia M, de Jong, Paulus TVM, Vingerling, Johannes R, Zhou, Xin, Chen, Peng, Li, Ruoying, Tay, Wan-Ting, Zheng, Yingfeng, Chew, Merwyn, Consortium for Refractive Error and Myopia, Burdon, Kathryn P, Craig, Jamie E, Iyengar, Sudha K, Igo, Robert P, Lass, Jonathan H, Fuchs' Genetics Multi-Center Study Group, Chew, Emily Y, Haller, Toomas, Mihailov, Evelin, Metspalu, Andres, Wedenoja, Juho, Simpson, Claire L, Wojciechowski, Robert, Höhn, René, Mirshahi, Alireza, Zeller, Tanja, Pfeiffer, Norbert, Lackner, Karl J, Wellcome Trust Case Control Consortium 2, Bettecken, Thomas, Meitinger, Thomas, Oexle, Konrad, Pirastu, Mario, Portas, Laura, Nag, Abhishek, Williams, Katie M, Yonova-Doing, Ekaterina, Klein, Ronald, Klein, Barbara E, Hosseini, S Mohsen, Paterson, Andrew D, Diabetes Control and Complications Trial/Epidemiology of Diabetes Interventions, and Complications Research Group, Makela, Kari-Matti, Lehtimaki, Terho, Kahonen, Mika, Raitakari, Olli, Yoshimura, Nagahisa, Matsuda, Fumihiko, Chen, Li Jia, Pang, Chi Pui, Yip, Shea Ping, Yap, Maurice KH, Meguro, Akira, Mizuki, Nobuhisa, Inoko, Hidetoshi, Foster, Paul J, Zhao, Jing Hua, Vithana, Eranga, Tai, E-Shyong, Fan, Qiao, Xu, Liang, Campbell, Harry, Fleck, Brian, Rudan, Igor, Aung, Tin, Hofman, Albert, Uitterlinden, André G, Bencic, Goran, Khor, Chiea-Chuen, Forward, Hannah, Pärssinen, Olavi, and Mitchell, Paul

Subjects

Adult, Male, Adolescent, Gene Expression, Eye, Medical and Health Sciences, White People, Asian People, Clinical Research, Genetics, Humans, 2.1 Biological and endogenous factors, Genetic Predisposition to Disease, Axial Length, Polymorphism, Aetiology, Eye Proteins, Eye Disease and Disorders of Vision, Aged, Genetics & Heredity, Consortium for Refractive Error and Myopia, Wellcome Trust Case Control Consortium 2, Human Genome, Single Nucleotide, Middle Aged, Biological Sciences, and Complications Research Group, Refractive Errors, Fuchs' Genetics Multi-Center Study Group, Genetic Loci, Female, Diabetes Control and Complications Trial/Epidemiology of Diabetes Interventions, Signal Transduction, Genome-Wide Association Study

Abstract

Refractive errors are common eye disorders of public health importance worldwide. Ocular axial length (AL) is the major determinant of refraction and thus of myopia and hyperopia. We conducted a meta-analysis of genome-wide association studies for AL, combining 12,531 Europeans and 8,216 Asians. We identified eight genome-wide significant loci for AL (RSPO1, C3orf26, LAMA2, GJD2, ZNRF3, CD55, MIP, and ALPPL2) and confirmed one previously reported AL locus (ZC3H11B). Of the nine loci, five (LAMA2, GJD2, CD55, ALPPL2, and ZC3H11B) were associated with refraction in 18 independent cohorts (n = 23,591). Differential gene expression was observed for these loci in minus-lens-induced myopia mouse experiments and human ocular tissues. Two of the AL genes, RSPO1 and ZNRF3, are involved in Wnt signaling, a pathway playing a major role in the regulation of eyeball size. This study provides evidence of shared genes between AL and refraction, but importantly also suggests that these traits may have unique pathways.

Published

2013

8. Genome-Wide Meta-Analysis of Myopia and Hyperopia Provides Evidence for Replication of 11 Loci.

Author

Simpson, Claire L., Wojciechowski, Robert, Oexle, Konrad, Murgia, Federico, Portas, Laura, Li, Xiaohui, Verhoeven, Virginie J. M., Vitart, Veronique, Schache, Maria, Hosseini, S. Mohsen, Hysi, Pirro G., Raffel, Leslie J., Cotch, Mary Frances, Chew, Emily, Klein, Barbara E. K., Klein, Ronald, Wong, Tien Yin, van Duijn, Cornelia M., Mitchell, Paul, and Saw, Seang Mei

Subjects

MYOPIA, HYPEROPIA, REFRACTIVE errors, GENOMES, META-analysis, HUMAN genetics, GENETIC epidemiology

Abstract

Refractive error (RE) is a complex, multifactorial disorder characterized by a mismatch between the optical power of the eye and its axial length that causes object images to be focused off the retina. The two major subtypes of RE are myopia (nearsightedness) and hyperopia (farsightedness), which represent opposite ends of the distribution of the quantitative measure of spherical refraction. We performed a fixed effects meta-analysis of genome-wide association results of myopia and hyperopia from 9 studies of European-derived populations: AREDS, KORA, FES, OGP-Talana, MESA, RSI, RSII, RSIII and ERF. One genome-wide significant region was observed for myopia, corresponding to a previously identified myopia locus on 8q12 (p = 1.25×10−8), which has been reported by Kiefer et al. as significantly associated with myopia age at onset and Verhoeven et al. as significantly associated to mean spherical-equivalent (MSE) refractive error. We observed two genome-wide significant associations with hyperopia. These regions overlapped with loci on 15q14 (minimum p value = 9.11×10−11) and 8q12 (minimum p value 1.82×10−11) previously reported for MSE and myopia age at onset. We also used an intermarker linkage- disequilibrium-based method for calculating the effective number of tests in targeted regional replication analyses. We analyzed myopia (which represents the closest phenotype in our data to the one used by Kiefer et al.) and showed replication of 10 additional loci associated with myopia previously reported by Kiefer et al. This is the first replication of these loci using myopia as the trait under analysis. “Replication-level” association was also seen between hyperopia and 12 of Kiefer et al.'s published loci. For the loci that show evidence of association to both myopia and hyperopia, the estimated effect of the risk alleles were in opposite directions for the two traits. This suggests that these loci are important contributors to variation of refractive error across the distribution. [ABSTRACT FROM AUTHOR]

Published

2014