Your search keyword '"Tienhoven, M. van"' showing total 16 results

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

Author

Haarman, A.E.G., Klaver, C.C.W., Tedja, M.S., Roosing, S., Astuti, G.D., Gilissen, C., Hoefsloot, L.H., Tienhoven, M. van, Brands, T., Magielsen, F.J., Eussen, B.H., Klein, A., Brosens, E., Verhoeven, V.J.M., Haarman, A.E.G., Klaver, C.C.W., Tedja, M.S., Roosing, S., Astuti, G.D., Gilissen, C., Hoefsloot, L.H., Tienhoven, M. van, Brands, T., Magielsen, F.J., Eussen, B.H., Klein, A., Brosens, E., and Verhoeven, V.J.M.

Abstract

01 december 2023, Contains fulltext : 293290.pdf (Publisher’s version ) (Open Access), PURPOSE: Myopia (nearsightedness) is a condition in which a refractive error (RE) affects vision. Although common variants explain part of the genetic predisposition (18%), most of the estimated 70% heritability is missing. Here, we investigate the contribution of rare genetic variation because this might explain more of the missing heritability in the more severe forms of myopia. In particular, high myopia can lead to blindness and has a tremendous impact on a patient and at the societal level. The exact molecular mechanisms behind this condition are not yet completely unraveled, but whole genome sequencing (WGS) studies have the potential to identify novel (rare) disease genes, explaining the high heritability. DESIGN: Cross-sectional study performed in the Netherlands. PARTICIPANTS: We investigated 159 European patients with high myopia (RE > -10 diopters). METHODS: We performed WGS using a stepwise filtering approach and burden analysis. The contribution of common variants was calculated as a genetic risk score (GRS). MAIN OUTCOME MEASURES: Rare variant burden, GRS. RESULTS: In 25% (n = 40) of these patients, there was a high (> 75th percentile) contribution of common predisposing variants; that is, these participants had higher GRSs. In 7 of the remaining 119 patients (6%), deleterious variants in genes associated with known (ocular) disorders, such as retinal dystrophy disease (prominin 1 [PROM1]) or ocular development (ATP binding cassette subfamily B member 6 [ABCB6], TGFB induced factor homeobox 1 [TGIF1]), were identified. Furthermore, without using a gene panel, we identified a high burden of rare variants in 8 novel genes associated with myopia. The genes heparan sulfate 6-O-sulfotransferase 1 (HS6ST1) (proportion in study population vs. the Genome Aggregation Database (GnomAD) 0.14 vs. 0.03, P = 4.22E-17), RNA binding motif protein 20 (RBM20) (0.15 vs. 0.06, P = 4.98E-05), and MAP7 domain containing 1 (MAP7D1) (0.19 vs. 0.06, P = 1.16E-10) were involved

Published

2023

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

Author

Mazijk, R. van, Haarman, A.E.G., Hoefsloot, L.H., Polling, J.R., Tienhoven, M. van, Klaver, C.C.W., Verhoeven, V.J.M., Loudon, S.E., Thiadens, A.A.H.J., Kievit, A.J., Mazijk, R. van, Haarman, A.E.G., Hoefsloot, L.H., Polling, J.R., Tienhoven, M. van, Klaver, C.C.W., Verhoeven, V.J.M., Loudon, S.E., Thiadens, A.A.H.J., and Kievit, A.J.

Abstract

Item does not contain fulltext, 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

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

Author

Mazijk, R. van, Haarman, A.E.G., Hoefsloot, L.H., Polling, J.R., Tienhoven, M. van, Klaver, C.C.W., Verhoeven, V.J.M., Loudon, S.E., Thiadens, A.A.H.J., Kievit, A.J., Mazijk, R. van, Haarman, A.E.G., Hoefsloot, L.H., Polling, J.R., Tienhoven, M. van, Klaver, C.C.W., Verhoeven, V.J.M., Loudon, S.E., Thiadens, A.A.H.J., and Kievit, A.J.

Abstract

Contains fulltext : 249568.pdf (Publisher’s version ) (Open Access), 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

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

Author

Haarman, A.E.G., Thiadens, A., Tienhoven, M. van, Loudon, S.E., Klein, J., Brosens, E., Polling, J.R., Schoot, V. van der, Bouman, A., Kievit, A.J., Hoefsloot, L.H., Klaver, C.C.W., Verhoeven, V.J.M., Haarman, A.E.G., Thiadens, A., Tienhoven, M. van, Loudon, S.E., Klein, J., Brosens, E., Polling, J.R., Schoot, V. van der, Bouman, A., Kievit, A.J., Hoefsloot, L.H., Klaver, C.C.W., and Verhoeven, V.J.M.

Abstract

Item does not contain fulltext, 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

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

Author

Mazijk, R. van, Haarman, A.E.G., Hoefsloot, L.H., Polling, J.R., Tienhoven, M. van, Klaver, C.C.W., Verhoeven, V.J.M., Loudon, S.E., Thiadens, A.A.H.J., Kievit, A.J., Mazijk, R. van, Haarman, A.E.G., Hoefsloot, L.H., Polling, J.R., Tienhoven, M. van, Klaver, C.C.W., Verhoeven, V.J.M., Loudon, S.E., Thiadens, A.A.H.J., and Kievit, A.J.

Abstract

Contains fulltext : 249568.pdf (Publisher’s version ) (Open Access), 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

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

Author

Haarman, A.E.G., Thiadens, A., Tienhoven, M. van, Loudon, S.E., Klein, J., Brosens, E., Polling, J.R., Schoot, V. van der, Bouman, A., Kievit, A.J., Hoefsloot, L.H., Klaver, C.C.W., Verhoeven, V.J.M., Haarman, A.E.G., Thiadens, A., Tienhoven, M. van, Loudon, S.E., Klein, J., Brosens, E., Polling, J.R., Schoot, V. van der, Bouman, A., Kievit, A.J., Hoefsloot, L.H., Klaver, C.C.W., and Verhoeven, V.J.M.

Abstract

Contains fulltext : 282474.pdf (Publisher’s version ) (Open Access), 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

7. The Affect of Fashion. An Exploration of Affective Method

Author

Tienhoven, M. van, Smelik, A.M., Tienhoven, M. van, and Smelik, A.M.

Abstract

Item does not contain fulltext, Fashion enchants, engrosses, caresses, itches, restrains, liberates, enfolds, reveals, protects and provokes. This article researches fashion’s ability to affect and vice versa, how humans are affected by fashion. The first part introduces the main tenets of affect theory, while the second part of the article focuses on the pragmatics of affective method. We understand affect as both an autonomous force and as a neuro-biological bodily response to a trigger that offsets feelings and emotions. To practically engage with affective experiences and the bodily sensations, feelings and emotions they evoke, we use Laura U. Marks’ affective analysis (2018) as a method. We describe our experiments with this affective method using two case studies: a couture dress designed by Dutch fashion designer Jan Taminiau; and a simple T-shirt produced for fast fashion giant Primark. The case studies illustrate the affective qualities of fashion by researching embodied responses, feelings and emotions. The affective method aims to circumvent representation by focusing on the body and how it relates to what fashion can ‘do’. It also allows for a sustained focus on the materiality of the fashion object itself. The article argues that affective method is a valuable and compelling tool that can break open material fashion research, by foregrounding the embodied experiences, feelings and emotions that play a key role in our relationship with fashion.

Published

2021

8. The Affect of Fashion. An Exploration of Affective Method

Author

Tienhoven, M. van, Smelik, A.M., Tienhoven, M. van, and Smelik, A.M.

Abstract

Contains fulltext : 245975.pdf (Publisher’s version ) (Closed access), Fashion enchants, engrosses, caresses, itches, restrains, liberates, enfolds, reveals, protects and provokes. This article researches fashion’s ability to affect and vice versa, how humans are affected by fashion. The first part introduces the main tenets of affect theory, while the second part of the article focuses on the pragmatics of affective method. We understand affect as both an autonomous force and as a neuro-biological bodily response to a trigger that offsets feelings and emotions. To practically engage with affective experiences and the bodily sensations, feelings and emotions they evoke, we use Laura U. Marks’ affective analysis (2018) as a method. We describe our experiments with this affective method using two case studies: a couture dress designed by Dutch fashion designer Jan Taminiau; and a simple T-shirt produced for fast fashion giant Primark. The case studies illustrate the affective qualities of fashion by researching embodied responses, feelings and emotions. The affective method aims to circumvent representation by focusing on the body and how it relates to what fashion can ‘do’. It also allows for a sustained focus on the materiality of the fashion object itself. The article argues that affective method is a valuable and compelling tool that can break open material fashion research, by foregrounding the embodied experiences, feelings and emotions that play a key role in our relationship with fashion.

Published

2021

9. The Affect of Fashion. An Exploration of Affective Method

Author

Tienhoven, M. van, Smelik, A.M., Tienhoven, M. van, and Smelik, A.M.

Abstract

Contains fulltext : 245975.pdf (Publisher’s version ) (Closed access), Fashion enchants, engrosses, caresses, itches, restrains, liberates, enfolds, reveals, protects and provokes. This article researches fashion’s ability to affect and vice versa, how humans are affected by fashion. The first part introduces the main tenets of affect theory, while the second part of the article focuses on the pragmatics of affective method. We understand affect as both an autonomous force and as a neuro-biological bodily response to a trigger that offsets feelings and emotions. To practically engage with affective experiences and the bodily sensations, feelings and emotions they evoke, we use Laura U. Marks’ affective analysis (2018) as a method. We describe our experiments with this affective method using two case studies: a couture dress designed by Dutch fashion designer Jan Taminiau; and a simple T-shirt produced for fast fashion giant Primark. The case studies illustrate the affective qualities of fashion by researching embodied responses, feelings and emotions. The affective method aims to circumvent representation by focusing on the body and how it relates to what fashion can ‘do’. It also allows for a sustained focus on the materiality of the fashion object itself. The article argues that affective method is a valuable and compelling tool that can break open material fashion research, by foregrounding the embodied experiences, feelings and emotions that play a key role in our relationship with fashion.

Published

2021

10. The Affect of Fashion. An Exploration of Affective Method.

Author

Tienhoven, M. van and Tienhoven, M. van

Subjects

Critical Humanities., Europe in a Changing World.

Published

2021

11. Next-generation sequencing-based genome diagnostics across clinical genetics centers: implementation choices and their effects

Author

Vrijenhoek, T., Kraaijeveld, K., Elferink, M., Ligt, J. de, Kranendonk, E., Santen, G., Nijman, IJ, Butler, D., Claes, G., Costessi, A., Dorlijn, W., Eyndhoven, W. van, Halley, D.J., Hout, M.C. van den, Hove, S. van, Johansson, L.F., Jongbloed, J.D., Kamps, R., Kockx, C.E., Koning, B. de, Kriek, M., Deprez, R.L., Lunstroo, H., Mannens, M., Mook, O.R., Nelen, M.R., Ploem, C., Rijnen, M., Saris, J.J., Sinke, R., Sistermans, E., Slegtenhorst, M. van, Sleutels, F., Stoep, N. van der, Tienhoven, M. van, Vermaat, M., Vogel, M., Waisfisz, Q., Weiss, J.M., Wijngaard, A. van den, Workum, W. van, IJntema, H., Zwaag, B. van der, van, I.W.F., Dunnen, J.T. den, Veltman, J.A., Hennekam, R., Cuppen, E., Vrijenhoek, T., Kraaijeveld, K., Elferink, M., Ligt, J. de, Kranendonk, E., Santen, G., Nijman, IJ, Butler, D., Claes, G., Costessi, A., Dorlijn, W., Eyndhoven, W. van, Halley, D.J., Hout, M.C. van den, Hove, S. van, Johansson, L.F., Jongbloed, J.D., Kamps, R., Kockx, C.E., Koning, B. de, Kriek, M., Deprez, R.L., Lunstroo, H., Mannens, M., Mook, O.R., Nelen, M.R., Ploem, C., Rijnen, M., Saris, J.J., Sinke, R., Sistermans, E., Slegtenhorst, M. van, Sleutels, F., Stoep, N. van der, Tienhoven, M. van, Vermaat, M., Vogel, M., Waisfisz, Q., Weiss, J.M., Wijngaard, A. van den, Workum, W. van, IJntema, H., Zwaag, B. van der, van, I.W.F., Dunnen, J.T. den, Veltman, J.A., Hennekam, R., and Cuppen, E.

Abstract

Item does not contain fulltext

Published

2015

12. Next-generation sequencing-based genome diagnostics across clinical genetics centers: implementation choices and their effects

Author

Vrijenhoek, T., Kraaijeveld, K., Elferink, M., Ligt, J. de, Kranendonk, E., Santen, G., Nijman, IJ, Butler, D., Claes, G., Costessi, A., Dorlijn, W., Eyndhoven, W. van, Halley, D.J., Hout, M.C. van den, Hove, S. van, Johansson, L.F., Jongbloed, J.D., Kamps, R., Kockx, C.E., Koning, B. de, Kriek, M., Deprez, R.L., Lunstroo, H., Mannens, M., Mook, O.R., Nelen, M.R., Ploem, C., Rijnen, M., Saris, J.J., Sinke, R., Sistermans, E., Slegtenhorst, M. van, Sleutels, F., Stoep, N. van der, Tienhoven, M. van, Vermaat, M., Vogel, M., Waisfisz, Q., Weiss, J.M., Wijngaard, A. van den, Workum, W. van, IJntema, H., Zwaag, B. van der, van, I.W.F., Dunnen, J.T. den, Veltman, J.A., Hennekam, R., Cuppen, E., Vrijenhoek, T., Kraaijeveld, K., Elferink, M., Ligt, J. de, Kranendonk, E., Santen, G., Nijman, IJ, Butler, D., Claes, G., Costessi, A., Dorlijn, W., Eyndhoven, W. van, Halley, D.J., Hout, M.C. van den, Hove, S. van, Johansson, L.F., Jongbloed, J.D., Kamps, R., Kockx, C.E., Koning, B. de, Kriek, M., Deprez, R.L., Lunstroo, H., Mannens, M., Mook, O.R., Nelen, M.R., Ploem, C., Rijnen, M., Saris, J.J., Sinke, R., Sistermans, E., Slegtenhorst, M. van, Sleutels, F., Stoep, N. van der, Tienhoven, M. van, Vermaat, M., Vogel, M., Waisfisz, Q., Weiss, J.M., Wijngaard, A. van den, Workum, W. van, IJntema, H., Zwaag, B. van der, van, I.W.F., Dunnen, J.T. den, Veltman, J.A., Hennekam, R., and Cuppen, E.

Abstract

Item does not contain fulltext

Published

2015

13. Next-generation sequencing-based genome diagnostics across clinical genetics centers: implementation choices and their effects

Author

Vrijenhoek, T., Kraaijeveld, K., Elferink, M., Ligt, J. de, Kranendonk, E., Santen, G., Nijman, IJ, Butler, D., Claes, G., Costessi, A., Dorlijn, W., Eyndhoven, W. van, Halley, D.J., Hout, M.C. van den, Hove, S. van, Johansson, L.F., Jongbloed, J.D., Kamps, R., Kockx, C.E., Koning, B. de, Kriek, M., Deprez, R.L., Lunstroo, H., Mannens, M., Mook, O.R., Nelen, M.R., Ploem, C., Rijnen, M., Saris, J.J., Sinke, R., Sistermans, E., Slegtenhorst, M. van, Sleutels, F., Stoep, N. van der, Tienhoven, M. van, Vermaat, M., Vogel, M., Waisfisz, Q., Weiss, J.M., Wijngaard, A. van den, Workum, W. van, IJntema, H., Zwaag, B. van der, van, I.W.F., Dunnen, J.T. den, Veltman, J.A., Hennekam, R., Cuppen, E., Vrijenhoek, T., Kraaijeveld, K., Elferink, M., Ligt, J. de, Kranendonk, E., Santen, G., Nijman, IJ, Butler, D., Claes, G., Costessi, A., Dorlijn, W., Eyndhoven, W. van, Halley, D.J., Hout, M.C. van den, Hove, S. van, Johansson, L.F., Jongbloed, J.D., Kamps, R., Kockx, C.E., Koning, B. de, Kriek, M., Deprez, R.L., Lunstroo, H., Mannens, M., Mook, O.R., Nelen, M.R., Ploem, C., Rijnen, M., Saris, J.J., Sinke, R., Sistermans, E., Slegtenhorst, M. van, Sleutels, F., Stoep, N. van der, Tienhoven, M. van, Vermaat, M., Vogel, M., Waisfisz, Q., Weiss, J.M., Wijngaard, A. van den, Workum, W. van, IJntema, H., Zwaag, B. van der, van, I.W.F., Dunnen, J.T. den, Veltman, J.A., Hennekam, R., and Cuppen, E.

Abstract

Item does not contain fulltext

Published

2015

14. NPHP4 variants are associated with pleiotropic heart malformations.

Author

French, V.M., Laar, I.M. van de, Wessels, M.W., Rohe, C., Roos-Hesselink, J.W., Wang, G., Frohn-Mulder, I.M., Severijnen, L.A., Graaf, B.M. de, Schot, R., Breedveld, G., Mientjes, E., Tienhoven, M. van, Jadot, E., Jiang, Z., Verkerk, A., Swagemakers, S., Venselaar, H., Rahimi, Z., Najmabadi, H., Meijers-Heijboer, H., Graaff, E. de, Helbing, W.A., Willemsen, R., Devriendt, K., Belmont, J.W., Oostra, B.A., Amack, J.D., Bertoli-Avella, A.M., French, V.M., Laar, I.M. van de, Wessels, M.W., Rohe, C., Roos-Hesselink, J.W., Wang, G., Frohn-Mulder, I.M., Severijnen, L.A., Graaf, B.M. de, Schot, R., Breedveld, G., Mientjes, E., Tienhoven, M. van, Jadot, E., Jiang, Z., Verkerk, A., Swagemakers, S., Venselaar, H., Rahimi, Z., Najmabadi, H., Meijers-Heijboer, H., Graaff, E. de, Helbing, W.A., Willemsen, R., Devriendt, K., Belmont, J.W., Oostra, B.A., Amack, J.D., and Bertoli-Avella, A.M.

Abstract

Item does not contain fulltext, RATIONALE: Congenital heart malformations are a major cause of morbidity and mortality, especially in young children. Failure to establish normal left-right (L-R) asymmetry often results in cardiovascular malformations and other laterality defects of visceral organs. OBJECTIVE: To identify genetic mutations causing cardiac laterality defects. METHODS AND RESULTS: We performed a genome-wide linkage analysis in patients with cardiac laterality defects from a consanguineous family. The patients had combinations of defects that included dextrocardia, transposition of great arteries, double-outlet right ventricle, atrioventricular septal defects, and caval vein abnormalities. Sequencing of positional candidate genes identified mutations in NPHP4. We performed mutation analysis of NPHP4 in 146 unrelated patients with similar cardiac laterality defects. Forty-one percent of these patients also had laterality defects of the abdominal organs. We identified 8 additional missense variants that were absent or very rare in control subjects. To study the role of nphp4 in establishing L-R asymmetry, we used antisense morpholinos to knockdown nphp4 expression in zebrafish. Depletion of nphp4 disrupted L-R patterning as well as cardiac and gut laterality. Cardiac laterality defects were partially rescued by human NPHP4 mRNA, whereas mutant NPHP4 containing genetic variants found in patients failed to rescue. We show that nphp4 is involved in the formation of motile cilia in Kupffer's vesicle, which generate asymmetrical fluid flow necessary for normal L-R asymmetry. CONCLUSIONS: NPHP4 mutations are associated with cardiac laterality defects and heterotaxy. In zebrafish, nphp4 is essential for the development and function of Kupffer's vesicle cilia and is required for global L-R patterning.

Published

2012

15. NPHP4 variants are associated with pleiotropic heart malformations.

Author

French, V.M., Laar, I.M. van de, Wessels, M.W., Rohe, C., Roos-Hesselink, J.W., Wang, G., Frohn-Mulder, I.M., Severijnen, L.A., Graaf, B.M. de, Schot, R., Breedveld, G., Mientjes, E., Tienhoven, M. van, Jadot, E., Jiang, Z., Verkerk, A., Swagemakers, S., Venselaar, H., Rahimi, Z., Najmabadi, H., Meijers-Heijboer, H., Graaff, E. de, Helbing, W.A., Willemsen, R., Devriendt, K., Belmont, J.W., Oostra, B.A., Amack, J.D., Bertoli-Avella, A.M., French, V.M., Laar, I.M. van de, Wessels, M.W., Rohe, C., Roos-Hesselink, J.W., Wang, G., Frohn-Mulder, I.M., Severijnen, L.A., Graaf, B.M. de, Schot, R., Breedveld, G., Mientjes, E., Tienhoven, M. van, Jadot, E., Jiang, Z., Verkerk, A., Swagemakers, S., Venselaar, H., Rahimi, Z., Najmabadi, H., Meijers-Heijboer, H., Graaff, E. de, Helbing, W.A., Willemsen, R., Devriendt, K., Belmont, J.W., Oostra, B.A., Amack, J.D., and Bertoli-Avella, A.M.

Abstract

Item does not contain fulltext, RATIONALE: Congenital heart malformations are a major cause of morbidity and mortality, especially in young children. Failure to establish normal left-right (L-R) asymmetry often results in cardiovascular malformations and other laterality defects of visceral organs. OBJECTIVE: To identify genetic mutations causing cardiac laterality defects. METHODS AND RESULTS: We performed a genome-wide linkage analysis in patients with cardiac laterality defects from a consanguineous family. The patients had combinations of defects that included dextrocardia, transposition of great arteries, double-outlet right ventricle, atrioventricular septal defects, and caval vein abnormalities. Sequencing of positional candidate genes identified mutations in NPHP4. We performed mutation analysis of NPHP4 in 146 unrelated patients with similar cardiac laterality defects. Forty-one percent of these patients also had laterality defects of the abdominal organs. We identified 8 additional missense variants that were absent or very rare in control subjects. To study the role of nphp4 in establishing L-R asymmetry, we used antisense morpholinos to knockdown nphp4 expression in zebrafish. Depletion of nphp4 disrupted L-R patterning as well as cardiac and gut laterality. Cardiac laterality defects were partially rescued by human NPHP4 mRNA, whereas mutant NPHP4 containing genetic variants found in patients failed to rescue. We show that nphp4 is involved in the formation of motile cilia in Kupffer's vesicle, which generate asymmetrical fluid flow necessary for normal L-R asymmetry. CONCLUSIONS: NPHP4 mutations are associated with cardiac laterality defects and heterotaxy. In zebrafish, nphp4 is essential for the development and function of Kupffer's vesicle cilia and is required for global L-R patterning.

Published

2012

16. NPHP4 variants are associated with pleiotropic heart malformations.

Author

French, V.M., Laar, I.M. van de, Wessels, M.W., Rohe, C., Roos-Hesselink, J.W., Wang, G., Frohn-Mulder, I.M., Severijnen, L.A., Graaf, B.M. de, Schot, R., Breedveld, G., Mientjes, E., Tienhoven, M. van, Jadot, E., Jiang, Z., Verkerk, A., Swagemakers, S., Venselaar, H., Rahimi, Z., Najmabadi, H., Meijers-Heijboer, H., Graaff, E. de, Helbing, W.A., Willemsen, R., Devriendt, K., Belmont, J.W., Oostra, B.A., Amack, J.D., Bertoli-Avella, A.M., French, V.M., Laar, I.M. van de, Wessels, M.W., Rohe, C., Roos-Hesselink, J.W., Wang, G., Frohn-Mulder, I.M., Severijnen, L.A., Graaf, B.M. de, Schot, R., Breedveld, G., Mientjes, E., Tienhoven, M. van, Jadot, E., Jiang, Z., Verkerk, A., Swagemakers, S., Venselaar, H., Rahimi, Z., Najmabadi, H., Meijers-Heijboer, H., Graaff, E. de, Helbing, W.A., Willemsen, R., Devriendt, K., Belmont, J.W., Oostra, B.A., Amack, J.D., and Bertoli-Avella, A.M.

Abstract

Item does not contain fulltext, RATIONALE: Congenital heart malformations are a major cause of morbidity and mortality, especially in young children. Failure to establish normal left-right (L-R) asymmetry often results in cardiovascular malformations and other laterality defects of visceral organs. OBJECTIVE: To identify genetic mutations causing cardiac laterality defects. METHODS AND RESULTS: We performed a genome-wide linkage analysis in patients with cardiac laterality defects from a consanguineous family. The patients had combinations of defects that included dextrocardia, transposition of great arteries, double-outlet right ventricle, atrioventricular septal defects, and caval vein abnormalities. Sequencing of positional candidate genes identified mutations in NPHP4. We performed mutation analysis of NPHP4 in 146 unrelated patients with similar cardiac laterality defects. Forty-one percent of these patients also had laterality defects of the abdominal organs. We identified 8 additional missense variants that were absent or very rare in control subjects. To study the role of nphp4 in establishing L-R asymmetry, we used antisense morpholinos to knockdown nphp4 expression in zebrafish. Depletion of nphp4 disrupted L-R patterning as well as cardiac and gut laterality. Cardiac laterality defects were partially rescued by human NPHP4 mRNA, whereas mutant NPHP4 containing genetic variants found in patients failed to rescue. We show that nphp4 is involved in the formation of motile cilia in Kupffer's vesicle, which generate asymmetrical fluid flow necessary for normal L-R asymmetry. CONCLUSIONS: NPHP4 mutations are associated with cardiac laterality defects and heterotaxy. In zebrafish, nphp4 is essential for the development and function of Kupffer's vesicle cilia and is required for global L-R patterning.

Published

2012