Your search keyword '"Haarman, Annechien E.G."' showing total 18 results

1. Identification of Rare Variants Involved in High Myopia Unraveled by Whole Genome Sequencing

Author

Haarman, Annechien E.G., Klaver, Caroline C.W., Tedja, Milly S., Roosing, Susanne, Astuti, Galuh, Gilissen, Christian, Hoefsloot, Lies H., van Tienhoven, Marianne, Brands, Tom, Magielsen, Frank J., Eussen, Bert H.J.F.M.M., de Klein, Annelies, Brosens, Erwin, and Verhoeven, Virginie J.M.

Published

2023

2. A new polygenic score for refractive error improves detection of children at risk of high myopia but not the prediction of those at risk of myopic macular degeneration

Author

Bailey-Wilson, Joan E., Baird, Paul N., Barathi, Veluchamy A., Biino, Ginevra, Burdon, Kathryn P., Campbell, Harry, Chen, Li Jia, Cheng, Ching-Yu, Chew, Emily Y., Craig, Jamie E., Deangelis, Margaret M., Delcourt, Cécile, Ding, Xiaohu, Fan, Qiao, Fossarello, Maurizio, Foster, Paul J., Gharahkhani, Puya, Guggenheim, Jeremy A., Guo, Xiaobo, Haarman, Annechien E.G., Haller, Toomas, Hammond, Christopher J., Han, Xikun, Hayward, Caroline, He, Mingguang, Hewitt, Alex W., Hoang, Quan, Hysi, Pirro G., Iglesias, Adriana I., Igo, Robert P., Iyengar, Sudha K., Jonas, Jost B., Kähönen, Mika, Kaprio, Jaakko, Khawaja, Anthony P., Klein, Barbara E., Lass, Jonathan H., Lee, Kris, Lehtimäki, Terho, Lewis, Deyana, Li, Qing, Li, Shi-Ming, Lyytikäinen, Leo-Pekka, MacGregor, Stuart, Mackey, David A., Martin, Nicholas G., Meguro, Akira, Metspalu, Andres, Middlebrooks, Candace, Miyake, Masahiro, Mizuki, Nobuhisa, Musolf, Anthony, Nickels, Stefan, Oexle, Konrad, Pang, Chi Pui, Pärssinen, Olavi, Paterson, Andrew D., Pfeiffer, Norbert, Polasek, Ozren, Rahi, Jugnoo S., Raitakari, Olli, Rudan, Igor, Sahebjada, Srujana, Saw, Seang-Mei, Simpson, Claire L., Stambolian, Dwight, Tai, E-Shyong, Tedja, Milly S., Tideman, J. Willem L., Tsujikawa, Akitaka, van Duijn, Cornelia M., Verhoeven, Virginie J.M., Vitart, Veronique, Wang, Ningli, Wang, Ya Xing, Wedenoja, Juho, Wei, Wen Bin, Williams, Cathy, Williams, Katie M., Wilson, James F., Wojciechowski, Robert, Yam, Jason C.S., Yamashiro, Kenji, Yap, Maurice K.H., Yazar, Seyhan, Yip, Shea Ping, Young, Terri L., Zhou, Xiangtian, Allen, Naomi, Aslam, Tariq, Atan, Denize, Barman, Sarah, Barrett, Jenny, Bishop, Paul, Black, Graeme, Bunce, Catey, Carare, Roxana, Chakravarthy, Usha, Chan, Michelle, Chua, Sharon, Cipriani, Valentina, Day, Alexander, Desai, Parul, Dhillon, Bal, Dick, Andrew, Doney, Alexander, Egan, Cathy, Ennis, Sarah, Foster, Paul, Fruttiger, Marcus, Gallacher, John, Garway-Heath, David, Gibson, Jane, Gore, Dan, Guggenheim, Jeremy, Hammond, Chris, Hardcastle, Alison, Harding, Simon, Hogg, Ruth, Hysi, Pirro, Keane, Pearse A., Khaw, Peng Tee, Khawaja, Anthony, Lascaratos, Gerassimos, Littlejohns, Thomas, Lotery, Andrew, Luthert, Phil, MacGillivray, Tom, Mackie, Sarah, McGuinness, Bernadette, McKay, Gareth, McKibbin, Martin, Mitry, Danny, Moore, Tony, Morgan, James, Muthy, Zaynah, O'Sullivan, Eoin, Owen, Chris, Patel, Praveen, Paterson, Euan, Peto, Tunde, Petzold, Axel, Pontikos, Nikolas, Rahi, Jugnoo, Rudnicka, Alicja, Self, Jay, Sergouniotis, Panagiotis, Sivaprasad, Sobha, Steel, David, Stratton, Irene, Strouthidis, Nicholas, Sudlow, Cathie, Tapp, Robyn, Thaung, Caroline, Thomas, Dhanes, Trucco, Emanuele, Tufail, Adnan, Vernon, Stephen, Viswanathan, Ananth, Williams, Katie, Woodside, Jayne, Yates, Max, Yip, Jennifer, Zheng, Yalin, Clark, Rosie, Lee, Samantha Sze-Yee, Du, Ran, Wang, Yining, Kneepkens, Sander C.M., Charng, Jason, Huang, Yu, Hunter, Michael L., Jiang, Chen, Tideman, J.Willem L., Melles, Ronald B., Klaver, Caroline C.W., Choquet, Hélène, and Ohno-Matsui, Kyoko

Published

2023

3. Rare variant analyses across multiethnic cohorts identify novel genes for refractive error

Author

Musolf, Anthony M., Haarman, Annechien E.G., Luben, Robert N., Ong, Jue Sheng, Patasova, Karina, Trapero, Rolando Hernandez, Marsh, Joseph, Jain, Ishika, Jain, Riya, Wang, Paul Zhiping, Lewis, Deyana D., Tedja, Milly S., Iglesias, Adriana I., Li, Hengtong, Cowan, Cameron S., Baird, Paul Nigel, Veluchamy, Amutha Barathi, Burdon, Kathryn P., Campbell, Harry, Chen, Li Jia, Cheng, Ching Yu, Chew, Emily Y., Craig, Jamie E., Cumberland, Phillippa M., Deangelis, Margaret M., Delcourt, Cécile, Ding, Xiaohu, Evans, David M., Fan, Qiao, Fossarello, Maurizio, Foster, Paul J., Gharahkhani, Puya, Guggenheim, Jeremy A., Guo, Xiaobo, Han, Xikun, He, Mingguang, Hewitt, Alex W., Hoang, Quan V., Iyengar, Sudha K., Jonas, Jost B., Kähönen, Mika, Kaprio, Jaakko, Klein, Barbara E., Lass, Jonathan H., Wang, Ya Xing, van Duijn, Cornelia M., Verhoeven, Virginie J.M., Klaver, Caroline C.W., Bailey-Wilson, Joan E., Musolf, Anthony M., Haarman, Annechien E.G., Luben, Robert N., Ong, Jue Sheng, Patasova, Karina, Trapero, Rolando Hernandez, Marsh, Joseph, Jain, Ishika, Jain, Riya, Wang, Paul Zhiping, Lewis, Deyana D., Tedja, Milly S., Iglesias, Adriana I., Li, Hengtong, Cowan, Cameron S., Baird, Paul Nigel, Veluchamy, Amutha Barathi, Burdon, Kathryn P., Campbell, Harry, Chen, Li Jia, Cheng, Ching Yu, Chew, Emily Y., Craig, Jamie E., Cumberland, Phillippa M., Deangelis, Margaret M., Delcourt, Cécile, Ding, Xiaohu, Evans, David M., Fan, Qiao, Fossarello, Maurizio, Foster, Paul J., Gharahkhani, Puya, Guggenheim, Jeremy A., Guo, Xiaobo, Han, Xikun, He, Mingguang, Hewitt, Alex W., Hoang, Quan V., Iyengar, Sudha K., Jonas, Jost B., Kähönen, Mika, Kaprio, Jaakko, Klein, Barbara E., Lass, Jonathan H., Wang, Ya Xing, van Duijn, Cornelia M., Verhoeven, Virginie J.M., Klaver, Caroline C.W., and Bailey-Wilson, Joan E.

Abstract

Refractive error, measured here as mean spherical equivalent (SER), is a complex eye condition caused by both genetic and environmental factors. Individuals with strong positive or negative values of SER require spectacles or other approaches for vision correction. Common genetic risk factors have been identified by genome-wide association studies (GWAS), but a great part of the refractive error heritability is still missing. Some of this heritability may be explained by rare variants (minor allele frequency [MAF] ≤ 0.01.). We performed multiple gene-based association tests of mean Spherical Equivalent with rare variants in exome array data from the Consortium for Refractive Error and Myopia (CREAM). The dataset consisted of over 27,000 total subjects from five cohorts of Indo-European and Eastern Asian ethnicity. We identified 129 unique genes associated with refractive error, many of which were replicated in multiple cohorts. Our best novel candidates included the retina expressed PDCD6IP, the circadian rhythm gene PER3, and P4HTM, which affects eye morphology. Future work will include functional studies and validation. Identification of genes contributing to refractive error and future understanding of their function may lead to better treatment and prevention of refractive errors, which themselves are important risk factors for various blinding conditions.

Published

2023

4. A new polygenic score for refractive error improves detection of children at risk of high myopia but not the prediction of those at risk of myopic macular degeneration

Author

Clark, Rosie, primary, Lee, Samantha Sze-Yee, additional, Du, Ran, additional, Wang, Yining, additional, Kneepkens, Sander C.M., additional, Charng, Jason, additional, Huang, Yu, additional, Hunter, Michael L., additional, Jiang, Chen, additional, Tideman, J.Willem L., additional, Melles, Ronald B., additional, Klaver, Caroline C.W., additional, Mackey, David A., additional, Williams, Cathy, additional, Choquet, Hélène, additional, Ohno-Matsui, Kyoko, additional, Guggenheim, Jeremy A., additional, Bailey-Wilson, Joan E., additional, Baird, Paul N., additional, Barathi, Veluchamy A., additional, Biino, Ginevra, additional, Burdon, Kathryn P., additional, Campbell, Harry, additional, Chen, Li Jia, additional, Cheng, Ching-Yu, additional, Chew, Emily Y., additional, Craig, Jamie E., additional, Deangelis, Margaret M., additional, Delcourt, Cécile, additional, Ding, Xiaohu, additional, Fan, Qiao, additional, Fossarello, Maurizio, additional, Foster, Paul J., additional, Gharahkhani, Puya, additional, Guo, Xiaobo, additional, Haarman, Annechien E.G., additional, Haller, Toomas, additional, Hammond, Christopher J., additional, Han, Xikun, additional, Hayward, Caroline, additional, He, Mingguang, additional, Hewitt, Alex W., additional, Hoang, Quan, additional, Hysi, Pirro G., additional, Iglesias, Adriana I., additional, Igo, Robert P., additional, Iyengar, Sudha K., additional, Jonas, Jost B., additional, Kähönen, Mika, additional, Kaprio, Jaakko, additional, Khawaja, Anthony P., additional, Klein, Barbara E., additional, Lass, Jonathan H., additional, Lee, Kris, additional, Lehtimäki, Terho, additional, Lewis, Deyana, additional, Li, Qing, additional, Li, Shi-Ming, additional, Lyytikäinen, Leo-Pekka, additional, MacGregor, Stuart, additional, Martin, Nicholas G., additional, Meguro, Akira, additional, Metspalu, Andres, additional, Middlebrooks, Candace, additional, Miyake, Masahiro, additional, Mizuki, Nobuhisa, additional, Musolf, Anthony, additional, Nickels, Stefan, additional, Oexle, Konrad, additional, Pang, Chi Pui, additional, Pärssinen, Olavi, additional, Paterson, Andrew D., additional, Pfeiffer, Norbert, additional, Polasek, Ozren, additional, Rahi, Jugnoo S., additional, Raitakari, Olli, additional, Rudan, Igor, additional, Sahebjada, Srujana, additional, Saw, Seang-Mei, additional, Simpson, Claire L., additional, Stambolian, Dwight, additional, Tai, E-Shyong, additional, Tedja, Milly S., additional, Tideman, J. Willem L., additional, Tsujikawa, Akitaka, additional, van Duijn, Cornelia M., additional, Verhoeven, Virginie J.M., additional, Vitart, Veronique, additional, Wang, Ningli, additional, Wang, Ya Xing, additional, Wedenoja, Juho, additional, Wei, Wen Bin, additional, Williams, Katie M., additional, Wilson, James F., additional, Wojciechowski, Robert, additional, Yam, Jason C.S., additional, Yamashiro, Kenji, additional, Yap, Maurice K.H., additional, Yazar, Seyhan, additional, Yip, Shea Ping, additional, Young, Terri L., additional, Zhou, Xiangtian, additional, Allen, Naomi, additional, Aslam, Tariq, additional, Atan, Denize, additional, Barman, Sarah, additional, Barrett, Jenny, additional, Bishop, Paul, additional, Black, Graeme, additional, Bunce, Catey, additional, Carare, Roxana, additional, Chakravarthy, Usha, additional, Chan, Michelle, additional, Chua, Sharon, additional, Cipriani, Valentina, additional, Day, Alexander, additional, Desai, Parul, additional, Dhillon, Bal, additional, Dick, Andrew, additional, Doney, Alexander, additional, Egan, Cathy, additional, Ennis, Sarah, additional, Foster, Paul, additional, Fruttiger, Marcus, additional, Gallacher, John, additional, Garway-Heath, David, additional, Gibson, Jane, additional, Gore, Dan, additional, Guggenheim, Jeremy, additional, Hammond, Chris, additional, Hardcastle, Alison, additional, Harding, Simon, additional, Hogg, Ruth, additional, Hysi, Pirro, additional, Keane, Pearse A., additional, Khaw, Peng Tee, additional, Khawaja, Anthony, additional, Lascaratos, Gerassimos, additional, Littlejohns, Thomas, additional, Lotery, Andrew, additional, Luthert, Phil, additional, MacGillivray, Tom, additional, Mackie, Sarah, additional, McGuinness, Bernadette, additional, McKay, Gareth, additional, McKibbin, Martin, additional, Mitry, Danny, additional, Moore, Tony, additional, Morgan, James, additional, Muthy, Zaynah, additional, O'Sullivan, Eoin, additional, Owen, Chris, additional, Patel, Praveen, additional, Paterson, Euan, additional, Peto, Tunde, additional, Petzold, Axel, additional, Pontikos, Nikolas, additional, Rahi, Jugnoo, additional, Rudnicka, Alicja, additional, Self, Jay, additional, Sergouniotis, Panagiotis, additional, Sivaprasad, Sobha, additional, Steel, David, additional, Stratton, Irene, additional, Strouthidis, Nicholas, additional, Sudlow, Cathie, additional, Tapp, Robyn, additional, Thaung, Caroline, additional, Thomas, Dhanes, additional, Trucco, Emanuele, additional, Tufail, Adnan, additional, Vernon, Stephen, additional, Viswanathan, Ananth, additional, Williams, Katie, additional, Woodside, Jayne, additional, Yates, Max, additional, Yip, Jennifer, additional, and Zheng, Yalin, additional

Published

2023

5. The Role of GJD2(Cx36) in Refractive Error Development

Author

van der Sande, Emilie, Haarman, Annechien E.G., Quint, Wim H., Tadema, Kirke C.D., Meester-Smoor, Magda A., Kamermans, Maarten, de Zeeuw, Chris I., Klaver, Caroline C.W., Winkelman, Beerend H.J., Iglesias, Adriana I., van der Sande, Emilie, Haarman, Annechien E.G., Quint, Wim H., Tadema, Kirke C.D., Meester-Smoor, Magda A., Kamermans, Maarten, de Zeeuw, Chris I., Klaver, Caroline C.W., Winkelman, Beerend H.J., and Iglesias, Adriana I.

Abstract

Refractive errors are common eye disorders characterized by a mismatch between the focal power of the eye and its axial length. An increased axial length is a common cause of the refractive error myopia (nearsightedness). The substantial increase in myopia prevalence over the last decades has raised public health concerns because myopia can lead to severe ocular complications later in life. Genomewide association studies (GWAS) have made considerable contributions to the understanding of the genetic architecture of refractive errors. Among the hundreds of genetic variants identified, common variants near the gap junction delta-2 (GJD2) gene have consistently been reported as one of the top hits. GJD2 encodes the connexin 36 (Cx36) protein, which forms gap junction channels and is highly expressed in the neural retina. In this review, we provide current evidence that links GJD2(Cx36) to the development of myopia. We summarize the gap junctional communication in the eye and the specific role of GJD2(Cx36) in retinal processing of visual signals. Finally, we discuss the pathways involving dopamine and gap junction phosphorylation and coupling as potential mechanisms that may explain the role of GJD2(Cx36) in refractive error development.

Published

2022

6. Whole exome sequence analysis in 51 624 participants identifies novel genes and variants associated with refractive error and myopia

Author

Guggenheim, Jeremy A., Clark, Rosie, Cui, Jiangtian, Terry, Louise, Patasova, Karina, Haarman, Annechien E.G., Musolf, Anthony M., Verhoeven, Virginie J.M., Klaver, Caroline C.W., Bailey-Wilson, Joan E., Hysi, Pirro G., Williams, Cathy, Guggenheim, Jeremy A., Clark, Rosie, Cui, Jiangtian, Terry, Louise, Patasova, Karina, Haarman, Annechien E.G., Musolf, Anthony M., Verhoeven, Virginie J.M., Klaver, Caroline C.W., Bailey-Wilson, Joan E., Hysi, Pirro G., and Williams, Cathy

Abstract

Refractive errors are associated with a range of pathological conditions, such as myopic maculopathy and glaucoma, and are highly heritable. Studies of missense and putative loss of function (pLOF) variants identified via whole exome sequencing (WES) offer the prospect of directly implicating potentially causative disease genes. We performed a genome-wide association study for refractive error in 51 624 unrelated adults, of European ancestry, aged 40-69 years from the UK and genotyped using WES. After testing 29 179 pLOF and 495 263 missense variants, 1 pLOF and 18 missense variants in 14 distinct genomic regions were taken forward for fine-mapping analysis. This yielded 19 putative causal variants of which 18 had a posterior inclusion probability >0.5. Of the 19 putative causal variants, 12 were novel discoveries. Specific variants were associated with a more myopic refractive error, while others were associated with a more hyperopic refractive error. Association with age of onset of spectacle wear (AOSW) was examined in an independent validation sample (38 100 early AOSW cases and 74 243 controls). Of 11 novel variants that could be tested, 8 (73%) showed evidence of association with AOSW status. This work identified COL4A4 and ATM as novel candidate genes associated with refractive error. In addition, novel putative causal variants were identified in the genes RASGEF1, ARMS2, BMP4, SIX6, GSDMA, GNGT2, ZNF652 and CRX. Despite these successes, the study also highlighted the limitations of community-based WES studies compared with high myopia case-control WES studies.

Published

2022

7. Association analyses of rare variants identify two genes associated with refractive error

Author

Patasova, Karina, Haarman, Annechien E.G., Musolf, Anthony M., Mahroo, Omar A., Rahi, Jugnoo S., Falchi, Mario, Verhoeven, Virginie J.M., Bailey-Wilson, Joan E., Klaver, Caroline C.W., Duggal, Priya, Klein, Alison, Guggenheim, Jeremy A., Hammond, Chris J., Hysi, Pirro G., Patasova, Karina, Haarman, Annechien E.G., Musolf, Anthony M., Mahroo, Omar A., Rahi, Jugnoo S., Falchi, Mario, Verhoeven, Virginie J.M., Bailey-Wilson, Joan E., Klaver, Caroline C.W., Duggal, Priya, Klein, Alison, Guggenheim, Jeremy A., Hammond, Chris J., and Hysi, Pirro G.

Abstract

Purpose Genetic variants identified through population-based genome-wide studies are generally of high frequency, exerting their action in the central part of the refractive error spectrum. However, the power to identify associations with variants of lower minor allele frequency is greatly reduced, requiring considerable sample sizes. Here we aim to assess the impact of rare variants on genetic variation of refractive errors in a very large general population cohort. Methods Genetic association analyses of non-cyclopaedic autorefraction calculated as mean spherical equivalent (SPHE) used whole-exome sequence genotypic information from 50,893 unrelated participants in the UK Biobank of European ancestry. Gene-based analyses tested for association with SPHE using an optimised SNP-set kernel association test (SKAT-O) restricted to rare variants (minor allele frequency < 1%) within protein-coding regions of the genome. All models were adjusted for age, sex and common lead variants within the same locus reported by previous genome-wide association studies. Potentially causal markers driving association at significant loci were elucidated using sensitivity analyses by sequentially dropping the most associated variants from gene-based analyses. Results We found strong statistical evidence for association of SPHE with the SIX6 (p-value = 2.15 x 10-10, or Bonferroni-Corrected p = 4.41x10-06) and the CRX gene (p-value = 6.65 x 10-08, or Bonferroni-Corrected p = 0.001). The SIX6 gene codes for a transcription factor believed to be critical to the eye, retina and optic disc development and morphology, while CRX regulates photoreceptor specification and expression of over 700 genes in the retina. These novel associations suggest an important role of genes involved in eye morphogenesis in refractive error. Conclusion The results of our study support previous research highlighting the importance of rare variants to the genetic risk of refractive error. We explain some of the

Published

2022

8. Whole exome sequencing of known eye genes reveals genetic causes for high myopia

Author

Haarman, Annechien E.G., Thiadens, Alberta A.H.J., van Tienhoven, Marianne, Loudon, Sjoukje E., de Klein, J. E.M.M.Annelies, Brosens, Erwin, Polling, Jan Roelof, van der Schoot, Vyne, Bouman, Arjan, Kievit, Anneke J.A., Hoefsloot, Lies H., Klaver, Caroline C.W., Verhoeven, Virginie J.M., Haarman, Annechien E.G., Thiadens, Alberta A.H.J., van Tienhoven, Marianne, Loudon, Sjoukje E., de Klein, J. E.M.M.Annelies, Brosens, Erwin, Polling, Jan Roelof, van der Schoot, Vyne, Bouman, Arjan, Kievit, Anneke J.A., Hoefsloot, Lies H., Klaver, Caroline C.W., and Verhoeven, Virginie J.M.

Abstract

High myopia [refractive error ≤ -6 diopters (D)] is a heterogeneous condition, and without clear accompanying features, it can be difficult to pinpoint a genetic cause. This observational study aimed to evaluate the utility of whole exome sequencing (WES) using an eye disorder gene panel in European patients with high myopia. Patients with high myopia were recruited by ophthalmologists and clinical geneticists. Clinical features were categorized into isolated high myopia, high myopia with other ocular involvement or with systemic involvement. WES was performed and an eye disorder gene panel of ~500 genes was evaluated. Hundred and thirteen patients with high myopia [mean (SD) refractive error - 11.8D (5.2)] were included. Of these, 53% were children younger than 12 years of age (53%), 13.3% were aged 12-18 years and 34% were adults (aged > 18 years). Twenty-three out of 113 patients (20%) received a genetic diagnosis of which 11 patients displayed additional ocular or systemic involvement. Pathogenic variants were identified in retinal dystrophy genes (e.g. GUCY2D and CACNA1F), connective tissue disease genes (e.g. COL18A1 and COL2A1), non-syndromic high myopia genes (ARR3), ocular development genes (e.g. PAX6) and other genes (ASPH and CNNM4). In 20% of our high myopic study population, WES using an eye gene panel enabled us to diagnose the genetic cause for this disorder. Eye genes known to cause retinal dystrophy, developmental or syndromic disorders can cause high myopia without apparent clinical features of other pathology.

Published

2022

9. Early onset X-linked female limited high myopia in three multigenerational families caused by novel mutations in the ARR3 gene

Author

van Mazijk, Ralph, Haarman, Annechien E.G., Hoefsloot, Lies H., Polling, Jan R., van Tienhoven, Marianne, Klaver, Caroline C.W., Verhoeven, Virginie J.M., Loudon, Sjoukje E., Thiadens, Alberta A.H.J., Kievit, Anneke J.A., van Mazijk, Ralph, Haarman, Annechien E.G., Hoefsloot, Lies H., Polling, Jan R., van Tienhoven, Marianne, Klaver, Caroline C.W., Verhoeven, Virginie J.M., Loudon, Sjoukje E., Thiadens, Alberta A.H.J., and Kievit, Anneke J.A.

Abstract

This study describes the clinical spectrum and genetic background of high myopia caused by mutations in the ARR3 gene. We performed an observational case series of three multigenerational families with high myopia (SER≤−6D), from the departments of Clinical Genetics and Ophthalmology of a tertiary Dutch hospital. Whole-exome sequencing (WES) with a vision-related gene panel was performed, followed by a full open exome sequencing. We identified three Caucasian families with high myopia caused by three different pathogenic variants in the ARR3 gene (c.214C>T, p.Arg72*; c.767+1G>A; p.?; c.848delG, p.(Gly283fs)). Myopia was characterized by a high severity (<−8D), an early onset (<6 years), progressive nature, and a moderate to bad atropine treatment response. Remarkably, a female limited inheritance pattern was present in all three families accordant with previous reports. The frequency of a pathogenic variant in the ARR3 gene in our diagnostic WES cohort was 5%. To conclude, we identified three families with early onset, therapy-resistant, high myopia with a female-limited inheritance pattern, caused by a mutation in the ARR3 gene. The singular mode of inheritance might be explained by metabolic interference due to X-inactivation. Identification of this type of high myopia will improve prompt myopia treatment, monitoring, and genetic counseling.

Published

2022

10. Whole exome sequence analysis in 51 624 participants identifies novel genes and variants associated with refractive error and myopia

Author

Guggenheim, Jeremy A, Clark, Rosie, Cui, Jiangtian, Terry, Louise, Patasova, Karina, Haarman, Annechien E.G, Musolf, Anthony M, Verhoeven, Virginie J M, Klaver, Caroline C W, Bailey-Wilson, Joan E, Hysi, Pirro G, Williams, Cathy E M, Ophthalmology, Clinical Genetics, and Epidemiology

Subjects

Adult, Pore Forming Cytotoxic Proteins, General Medicine, Refractive Errors, Sensory disorders Donders Center for Medical Neuroscience [Radboudumc 12], Neoplasm Proteins, Exome Sequencing, Genetics, Myopia, Humans, Exome, Molecular Biology, Genetics (clinical), Genome-Wide Association Study

Abstract

Contains fulltext : 251578.pdf (Publisher’s version ) (Open Access) Refractive errors are associated with a range of pathological conditions, such as myopic maculopathy and glaucoma, and are highly heritable. Studies of missense and putative loss of function (pLOF) variants identified via whole exome sequencing (WES) offer the prospect of directly implicating potentially causative disease genes. We performed a genome-wide association study for refractive error in 51 624 unrelated adults, of European ancestry, aged 40-69 years from the UK and genotyped using WES. After testing 29 179 pLOF and 495 263 missense variants, 1 pLOF and 18 missense variants in 14 distinct genomic regions were taken forward for fine-mapping analysis. This yielded 19 putative causal variants of which 18 had a posterior inclusion probability >0.5. Of the 19 putative causal variants, 12 were novel discoveries. Specific variants were associated with a more myopic refractive error, while others were associated with a more hyperopic refractive error. Association with age of onset of spectacle wear (AOSW) was examined in an independent validation sample (38 100 early AOSW cases and 74 243 controls). Of 11 novel variants that could be tested, 8 (73%) showed evidence of association with AOSW status. This work identified COL4A4 and ATM as novel candidate genes associated with refractive error. In addition, novel putative causal variants were identified in the genes RASGEF1, ARMS2, BMP4, SIX6, GSDMA, GNGT2, ZNF652 and CRX. Despite these successes, the study also highlighted the limitations of community-based WES studies compared with high myopia case-control WES studies.

Published

2022

11. IMI 2021 yearly digest

Author

Jong, Monica, Jonas, Jost B., Wolffsohn, James S., Berntsen, David A., Cho, Pauline, Clarkson-Townsend, Danielle, Flitcroft, Daniel I., Gifford, Kate L., Haarman, Annechien E.G., Pardue, Machelle T., Richdale, Kathryn, Sankaridurg, Padmaja, Tedja, Milly S., Wildsoet, Christine F., Bailey-Wilson, Joan E., Guggenheim, Jeremy A., Hammond, Christopher J., Kaprio, Jaakko, MacGregor, Stuart, Mackey, David A., Musolf, Anthony M., Klaver, Caroline C.W., Verhoeven, Virginie J.M., Vitart, Veronique, Smith, Earl L., Jong, Monica, Jonas, Jost B., Wolffsohn, James S., Berntsen, David A., Cho, Pauline, Clarkson-Townsend, Danielle, Flitcroft, Daniel I., Gifford, Kate L., Haarman, Annechien E.G., Pardue, Machelle T., Richdale, Kathryn, Sankaridurg, Padmaja, Tedja, Milly S., Wildsoet, Christine F., Bailey-Wilson, Joan E., Guggenheim, Jeremy A., Hammond, Christopher J., Kaprio, Jaakko, MacGregor, Stuart, Mackey, David A., Musolf, Anthony M., Klaver, Caroline C.W., Verhoeven, Virginie J.M., Vitart, Veronique, and Smith, Earl L.

Abstract

PURPOSE. The International Myopia Institute (IMI) Yearly Digest highlights new research considered to be of importance since the publication of the first series of IMI white papers. METHODS. A literature search was conducted for articles on myopia between 2019 and mid-2020 to inform definitions and classifications, experimental models, genetics, interventions, clinical trials, and clinical management. Conference abstracts from key meetings in the same period were also considered. RESULTS. One thousand articles on myopia have been published between 2019 and mid-2020. Key advances include the use of the definition of premyopia in studies currently under way to test interventions in myopia, new definitions in the field of pathologic myopia, the role of new pharmacologic treatments in experimental models such as intraocular pressure-lowering latanoprost, a large meta-analysis of refractive error identifying 336 new genetic loci, new clinical interventions such as the defocus incorporated multisegment spectacles and combination therapy with low-dose atropine and orthokeratology (OK), normative standards in refractive error, the ethical dilemma of a placebo control group when myopia control treatments are established, reporting the physical metric of myopia reduction versus a percentage reduction, comparison of the risk of pediatric OK wear with risk of vision impairment in myopia, the justification of preventing myopic and axial length increase versus quality of life, and future vision loss. CONCLUSIONS. Large amounts of research in myopia have been published since the IMI 2019 white papers were released. The yearly digest serves to highlight the latest research and advances in myopia.

Published

2021

12. Update and guidance on management of myopia. European Society of Ophthalmology in cooperation with International Myopia Institute

Author

Németh, János, Tapasztó, Beáta, Aclimandos, Wagih A., Kestelyn, Philippe, Jonas, Jost B., De Faber, Jan Tjeerd H.N., Januleviciene, Ingrida, Grzybowski, Andrzej, Nagy, Zoltán Zsolt, Pärssinen, Olavi, Guggenheim, Jeremy A., Allen, Peter M., Baraas, Rigmor C., Saunders, Kathryn J., Flitcroft, Daniel Ian, Gray, Lyle S., Polling, Jan Roelof, Haarman, Annechien E.G., Tideman, J. Willem L., Wolffsohn, James Stuart, Wahl, Siegfried, Mulder, Jeroen A., Smirnova, Irina Yurievna, Formenti, Marino, Radhakrishnan, Hema, Resnikoff, Serge, Németh, János, Tapasztó, Beáta, Aclimandos, Wagih A., Kestelyn, Philippe, Jonas, Jost B., De Faber, Jan Tjeerd H.N., Januleviciene, Ingrida, Grzybowski, Andrzej, Nagy, Zoltán Zsolt, Pärssinen, Olavi, Guggenheim, Jeremy A., Allen, Peter M., Baraas, Rigmor C., Saunders, Kathryn J., Flitcroft, Daniel Ian, Gray, Lyle S., Polling, Jan Roelof, Haarman, Annechien E.G., Tideman, J. Willem L., Wolffsohn, James Stuart, Wahl, Siegfried, Mulder, Jeroen A., Smirnova, Irina Yurievna, Formenti, Marino, Radhakrishnan, Hema, and Resnikoff, Serge

Abstract

The prevalence of myopia is increasing extensively worldwide. The number of people with myopia in 2020 is predicted to be 2.6 billion globally, which is expected to rise up to 4.9 billion by 2050, unless preventive actions and interventions are taken. The number of individuals with high myopia is also increasing substantially and pathological myopia is predicted to become the most common cause of irreversible vision impairment and blindness worldwide and also in Europe. These prevalence estimates indicate the importance of reducing the burden of myopia by means of myopia control interventions to prevent myopia onset and to slow down myopia progression. Due to the urgency of the situation, the European Society of Ophthalmology decided to publish this update of the current information and guidance on management of myopia. The pathogenesis and genetics of myopia are also summarized and epidemiology, risk factors, preventive and treatment options are discussed in details.

Published

2021

13. Myopic presentation of central serous chorioretinopathy

Author

Ravenstijn, Monica, Van Dijk, Elon H.C., Haarman, Annechien E.G., Kaden, Talia R., Vermeer, Koenraad A., Boon, Camiel J.F., Yannuzzi, Lawrence A., Klaver, Caroline C.W., Yzer, Suzanne, Ravenstijn, Monica, Van Dijk, Elon H.C., Haarman, Annechien E.G., Kaden, Talia R., Vermeer, Koenraad A., Boon, Camiel J.F., Yannuzzi, Lawrence A., Klaver, Caroline C.W., and Yzer, Suzanne

Abstract

Purpose: To increase insight into the myopic presentation of central serous chorioretinopathy (CSC) by comparing a large group of myopic patients with CSC with reference groups with only one of the diagnoses. Methods: Myopic patients with CSC (spherical equivalent #23D, n = 46), emmetropic patients with CSC (spherical equivalent 20.5 to 0.5 D, n = 83), and myopic, non-CSC patients (n = 50) were included in this multicenter cross-sectional study. Disease characteristics and imaging parameters, such as subfoveal choroidal thickness and indocyanine green angiography patterns, were compared between cases and reference groups. Results: In myopic patients with CSC, median subfoveal choroidal thickness (286 mm [IQR 226-372 mm]) was significantly thicker than subfoveal choroidal thickness in myopic, non-CSC patients (200 mm [IQR 152-228 mm], P , 0.001) but thinner than emmetropic patients with CSC (452 mm [IQR 342-538 mm], P , 0.001). They also had pachyvessels in 70% of the eyes comparable with emmetropic CSC (76%, P = 0.70). Choroidal hyperpermeability was frequently present on indocyanine green angiography in both myopic and emmetropic CSC eyes. Need for treatment, treatment success, and recurrence rate were not significantly different between CSC groups. Conclusion: Myopic CSC presents with similar imaging and clinical characteristics as emmetropic CSC, apart from their thinner choroids. Keeping in mind the structural changes of myopia, other imaging characteristics could aid the diagnostic process.

Published

2021

14. Design, implementation and initial findings of COVID-19 research in the Rotterdam Study:leveraging existing infrastructure for population-based investigations on an emerging disease

Author

Licher, Silvan, Terzikhan, Natalie, Splinter, Marije J., Velek, Premysl, van Rooij, Frank J.A., Heemst, Jolande Verkroost van, Haarman, Annechien E.G., Thee, Eric F., Geurts, Sven, Mens, Michelle M.J., van der Schaft, Niels, de Feijter, Maud, Pardo, Luba M., Kieboom, Brenda C.T., Ikram, M. Arfan, Licher, Silvan, Terzikhan, Natalie, Splinter, Marije J., Velek, Premysl, van Rooij, Frank J.A., Heemst, Jolande Verkroost van, Haarman, Annechien E.G., Thee, Eric F., Geurts, Sven, Mens, Michelle M.J., van der Schaft, Niels, de Feijter, Maud, Pardo, Luba M., Kieboom, Brenda C.T., and Ikram, M. Arfan

Abstract

The Rotterdam Study is an ongoing prospective, population-based cohort study that started in 1989 in the city of Rotterdam, the Netherlands. The study aims to unravel etiology, preclinical course, natural history and potential targets for intervention for chronic diseases in mid-life and late-life. It focuses on cardiovascular, endocrine, hepatic, neurological, ophthalmic, psychiatric, dermatological, otolaryngological, locomotor, and respiratory diseases. In response to the COVID-19 pandemic, a substudy was designed and embedded within the Rotterdam Study. On the 20th of April, 2020, all living non-institutionalized participants of the Rotterdam Study (n = 8732) were invited to participate in this sub-study by filling out a series of questionnaires administered over a period of 8 months. These questionnaires included questions on COVID-19 related symptoms and risk factors, characterization of lifestyle and mental health changes, and determination of health care seeking and health care avoiding behavior during the pandemic. As of May 2021, the questionnaire had been sent out repeatedly for a total of six times with an overall response rate of 76%. This article provides an overview of the rationale, design, and implementation of this sub-study nested within the Rotterdam Study. Finally, initial results on participant characteristics and prevalence of COVID-19 in this community-dwelling population are shown.

Published

2021

15. Phenotypic consequences of the GJD2 risk genotype in myopia development

Author

Haarman, Annechien E.G., Enthoven, Clair A., Tedja, Milly S., Polling, Jan R., Tideman, Willem J.L., Keunen, Jan E.E., Boon, Camiel J.F., Felix, Janine F., Raat, H., Geerards, Annette J.M., Luyten, Gregorius P.M., van Rijn, Gwyneth A., Verhoeven, Virginie J.M., Klaver, Caroline C.W., Haarman, Annechien E.G., Enthoven, Clair A., Tedja, Milly S., Polling, Jan R., Tideman, Willem J.L., Keunen, Jan E.E., Boon, Camiel J.F., Felix, Janine F., Raat, H., Geerards, Annette J.M., Luyten, Gregorius P.M., van Rijn, Gwyneth A., Verhoeven, Virginie J.M., and Klaver, Caroline C.W.

Abstract

PURPOSE. To study the relatively high effect of the refractive error gene GJD2 in human myopia, and to assess its relationship with refractive error, ocular biometry and lifestyle in various age groups. METHODS. The population-based Rotterdam Study (RS), high myopia case-control study MYopia STudy, and the birth-cohort study Generation R were included in this study. Spherical equivalent (SER), axial length (AL), axial length/corneal radius (AL/CR), vitreous depth (VD), and anterior chamber depth (ACD) were measured using standard ophthalmologic procedures. Biometric measurements were compared between GJD2 (rs524952) genotype groups; education and environmental risk score (ERS) were calculated to estimate gene-environment interaction effects, using the Synergy index (SI). RESULTS. RS adults carrying two risk alleles had a lower SER and longer AL, ACD and VD (AA versus TT, 0.23D vs. 0.70D; 23.79 mm vs. 23.52 mm; 2.72 mm vs. 2.65 mm; 16.12 mm vs. 15.87 mm; all P < 0.001). Children carrying two risk alleles had larger AL/CR at ages 6 and 9 years (2.88 vs. 2.87 and 3.00 vs. 2.96; all P < 0.001). Education and ERS both negatively influenced myopia and the biometric outcomes, but gene-environment interactions did not reach statistical significance (SI 1.25 [95% confidence interval {CI}, 0.85–1.85] and 1.17 [95% CI, 0.55–2.50] in adults and children). CONCLUSIONS. The elongation of the eye caused by the GJD2 risk genotype follows a dose-response pattern already visible at the age of 6 years. These early effects are an example of how a common myopia gene may drive myopia.

Published

2021

16. Association of Rhegmatogenous Retinal Detachment Incidence with Myopia Prevalence in the Netherlands

Author

MS Oogheelkunde, Infection & Immunity, Van Leeuwen, Redmer, Haarman, Annechien E.G., Van De Put, Mathijs A.J., Klaver, Caroline C.W., Los, Leonoor I., MS Oogheelkunde, Infection & Immunity, Van Leeuwen, Redmer, Haarman, Annechien E.G., Van De Put, Mathijs A.J., Klaver, Caroline C.W., and Los, Leonoor I.

Published

2021

17. Evidence That Emmetropization Buffers Against Both Genetic and Environmental Risk Factors for Myopia

Author

Pozarickij, Alfred, primary, Enthoven, Clair A., additional, Ghorbani Mojarrad, Neema, additional, Plotnikov, Denis, additional, Tedja, Milly S., additional, Haarman, Annechien E.G., additional, Tideman, J. Willem L., additional, Polling, Jan Roelof, additional, Northstone, Kate, additional, Williams, Cathy, additional, Klaver, Caroline C. W., additional, and Guggenheim, Jeremy A., additional

Published

2020

18. The genetics of myopia

Author

Tedja, Milly S., Haarman, Annechien E.G., Meester-Smoor, Magda A., Verhoeven, Virginie J.M., Klaver, Caroline C.W., MacGregor, Stuart, Tedja, Milly S., Haarman, Annechien E.G., Meester-Smoor, Magda A., Verhoeven, Virginie J.M., Klaver, Caroline C.W., and MacGregor, Stuart

Abstract

Myopia is the most common eye condition worldwide and its prevalence is increasing. While changes in environment, such as time spent outdoors, have driven myopia rates, within populations myopia is highly heritable. Genes are estimated to explain up to 80% of the variance in refractive error. Initial attempts to identify myopia genes relied on family studies using linkage analysis or candidate gene approaches with limited progress. More genome-wide association study (GWAS) approaches have taken over, ultimately resulting in the identification of hundreds of genes for refractive error and myopia, providing new insights into its molecular machinery. These studies showed myopia is a complex trait, with many genetic variants of small effect influencing retinal signaling, eye growth and the normal process of emmetropization. The genetic architecture and its molecular mechanisms are still to be clarified and while genetic risk score prediction models are improving, this knowledge must be expanded to have impact on clinical practice.

Published

2019