An international collaborative family-based whole genome quantitative trait linkage scan for myopic refractive error

PURPOSE: To investigate quantitative trait loci linked to refractive error, we performed a genome-wide quantitative trait linkage analysis using single nucleotide polymorphism markers and family data from five international sites. METHODS: Genomic DNA samples from 254 families were genotyped by the...

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Autores principales: Abbott, Diana, Li, Yi-Ju, Guggenheim, Jeremy A., Metlapally, Ravikanth, Malecaze, Francois, Calvas, Patrick, Rosenberg, Thomas, Paget, Sandrine, Zayats, Tetyana, Mackey, David A., Feng, Sheng, Young, Terri L.
Formato: Online Artículo Texto
Lenguaje:English
Publicado: Molecular Vision 2012
Materias:
Research Article
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3324362/
https://www.ncbi.nlm.nih.gov/pubmed/22509102
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author Abbott, Diana
Li, Yi-Ju
Guggenheim, Jeremy A.
Metlapally, Ravikanth
Malecaze, Francois
Calvas, Patrick
Rosenberg, Thomas
Paget, Sandrine
Zayats, Tetyana
Mackey, David A.
Feng, Sheng
Young, Terri L.
author_facet Abbott, Diana
Li, Yi-Ju
Guggenheim, Jeremy A.
Metlapally, Ravikanth
Malecaze, Francois
Calvas, Patrick
Rosenberg, Thomas
Paget, Sandrine
Zayats, Tetyana
Mackey, David A.
Feng, Sheng
Young, Terri L.
author_sort Abbott, Diana
collection PubMed
description PURPOSE: To investigate quantitative trait loci linked to refractive error, we performed a genome-wide quantitative trait linkage analysis using single nucleotide polymorphism markers and family data from five international sites. METHODS: Genomic DNA samples from 254 families were genotyped by the Center for Inherited Disease Research using the Illumina Linkage Panel IVb. Quantitative trait linkage analysis was performed on 225 Caucasian families and 4,656 markers after accounting for linkage disequilibrium and quality control exclusions. Two refractive quantitative phenotypes, sphere (SPH) and spherical equivalent (SE), were analyzed. The SOLAR program was used to estimate identity by descent probabilities and to conduct two-point and multipoint quantitative trait linkage analyses. RESULTS: We found 29 markers and 11 linkage regions reaching peak two-point and multipoint logarithms of the odds (LODs)>1.5. Four linkage regions revealed at least one LOD score greater than 2: chromosome 6q13–6q16.1 (LOD=1.96 for SPH, 2.18 for SE), chromosome 5q35.1–35.2 (LOD=2.05 for SPH, 1.80 for SE), chromosome 7q11.23–7q21.2 (LOD=1.19 for SPH, 2.03 for SE), and chromosome 3q29 (LOD=1.07 for SPH, 2.05 for SE). Among these, the chromosome 6 and chromosome 5 regions showed the most consistent results between SPH and SEM. Four linkage regions with multipoint scores above 1.5 are near or within the known myopia (MYP) loci of MYP3, MYP12, MYP14, and MYP16. Overall, we observed consistent linkage signals across the SPH and SEM phenotypes, although scores were generally higher for the SEM phenotype. CONCLUSIONS: Our quantitative trait linkage analyses of a large myopia family cohort provided additional evidence for several known MYP loci, and identified two additional potential loci at chromosome 6q13–16.1 and chromosome 5q35.1–35.2 for myopia. These results will benefit the efforts toward determining genes for myopic refractive error.
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spelling pubmed-33243622012-04-16 An international collaborative family-based whole genome quantitative trait linkage scan for myopic refractive error Abbott, Diana Li, Yi-Ju Guggenheim, Jeremy A. Metlapally, Ravikanth Malecaze, Francois Calvas, Patrick Rosenberg, Thomas Paget, Sandrine Zayats, Tetyana Mackey, David A. Feng, Sheng Young, Terri L. Mol Vis Research Article PURPOSE: To investigate quantitative trait loci linked to refractive error, we performed a genome-wide quantitative trait linkage analysis using single nucleotide polymorphism markers and family data from five international sites. METHODS: Genomic DNA samples from 254 families were genotyped by the Center for Inherited Disease Research using the Illumina Linkage Panel IVb. Quantitative trait linkage analysis was performed on 225 Caucasian families and 4,656 markers after accounting for linkage disequilibrium and quality control exclusions. Two refractive quantitative phenotypes, sphere (SPH) and spherical equivalent (SE), were analyzed. The SOLAR program was used to estimate identity by descent probabilities and to conduct two-point and multipoint quantitative trait linkage analyses. RESULTS: We found 29 markers and 11 linkage regions reaching peak two-point and multipoint logarithms of the odds (LODs)>1.5. Four linkage regions revealed at least one LOD score greater than 2: chromosome 6q13–6q16.1 (LOD=1.96 for SPH, 2.18 for SE), chromosome 5q35.1–35.2 (LOD=2.05 for SPH, 1.80 for SE), chromosome 7q11.23–7q21.2 (LOD=1.19 for SPH, 2.03 for SE), and chromosome 3q29 (LOD=1.07 for SPH, 2.05 for SE). Among these, the chromosome 6 and chromosome 5 regions showed the most consistent results between SPH and SEM. Four linkage regions with multipoint scores above 1.5 are near or within the known myopia (MYP) loci of MYP3, MYP12, MYP14, and MYP16. Overall, we observed consistent linkage signals across the SPH and SEM phenotypes, although scores were generally higher for the SEM phenotype. CONCLUSIONS: Our quantitative trait linkage analyses of a large myopia family cohort provided additional evidence for several known MYP loci, and identified two additional potential loci at chromosome 6q13–16.1 and chromosome 5q35.1–35.2 for myopia. These results will benefit the efforts toward determining genes for myopic refractive error. Molecular Vision 2012-03-26 /pmc/articles/PMC3324362/ /pubmed/22509102 Text en Copyright © 2012 Molecular Vision. http://creativecommons.org/licenses/by/3.0/ This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
spellingShingle Research Article
Abbott, Diana
Li, Yi-Ju
Guggenheim, Jeremy A.
Metlapally, Ravikanth
Malecaze, Francois
Calvas, Patrick
Rosenberg, Thomas
Paget, Sandrine
Zayats, Tetyana
Mackey, David A.
Feng, Sheng
Young, Terri L.
An international collaborative family-based whole genome quantitative trait linkage scan for myopic refractive error
title An international collaborative family-based whole genome quantitative trait linkage scan for myopic refractive error
title_full An international collaborative family-based whole genome quantitative trait linkage scan for myopic refractive error
title_fullStr An international collaborative family-based whole genome quantitative trait linkage scan for myopic refractive error
title_full_unstemmed An international collaborative family-based whole genome quantitative trait linkage scan for myopic refractive error
title_short An international collaborative family-based whole genome quantitative trait linkage scan for myopic refractive error
title_sort international collaborative family-based whole genome quantitative trait linkage scan for myopic refractive error
topic Research Article
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3324362/
https://www.ncbi.nlm.nih.gov/pubmed/22509102
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