The Genetic Architecture of a Congenital Heart Defect Is Related to Its Fitness Cost

The Genetic Architecture of a Congenital Heart Defect Is Related to Its Fitness Cost

In newborns, severe congenital heart defects are rarer than mild ones. This epidemiological relationship between heart defect severity and incidence lacks explanation. Here, an analysis of ~10,000 <i>Nkx2-5</i><sup>+/−</sup> mice from two inbred strain crosses illustrates the...

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Main Authors: Ehiole Akhirome, Suk D. Regmi, Rachel A. Magnan, Nelson Ugwu, Yidan Qin, Claire E. Schulkey, James M. Cheverud, Patrick Y. Jay
Format: Article
Language:English
Published: MDPI AG 2021-08-01
Series:Genes
Subjects:
congenital heart defects
quantitative trait loci
modifier genes
genetic epistasis
Online Access:https://www.mdpi.com/2073-4425/12/9/1368
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spelling doaj-e8d8dd38cbd14c9398caca17839fd7292021-09-26T00:13:13ZengMDPI AGGenes2073-44252021-08-01121368136810.3390/genes12091368The Genetic Architecture of a Congenital Heart Defect Is Related to Its Fitness CostEhiole Akhirome0Suk D. Regmi1Rachel A. Magnan2Nelson Ugwu3Yidan Qin4Claire E. Schulkey5James M. Cheverud6Patrick Y. Jay7Department of Pediatrics, Washington University School of Medicine, St. Louis, MO 63110, USADepartment of Pediatrics, Washington University School of Medicine, St. Louis, MO 63110, USADepartment of Pediatrics, Washington University School of Medicine, St. Louis, MO 63110, USADepartment of Pediatrics, Washington University School of Medicine, St. Louis, MO 63110, USADepartment of Pediatrics, Washington University School of Medicine, St. Louis, MO 63110, USADepartment of Pediatrics, Washington University School of Medicine, St. Louis, MO 63110, USADepartment of Biology, Loyola University Chicago, Chicago, IL 60660, USADepartment of Pediatrics, Washington University School of Medicine, St. Louis, MO 63110, USAIn newborns, severe congenital heart defects are rarer than mild ones. This epidemiological relationship between heart defect severity and incidence lacks explanation. Here, an analysis of ~10,000 <i>Nkx2-5</i><sup>+/−</sup> mice from two inbred strain crosses illustrates the fundamental role of epistasis. Modifier genes raise or lower the risk of specific defects via pairwise (G×G<i><sub>Nkx</sub></i>) and higher-order (G×G×G<i><sub>Nkx</sub></i>) interactions with <i>Nkx2-5</i>. Their effect sizes correlate with the severity of a defect. The risk loci for mild, atrial septal defects exert predominantly small G×G<i><sub>Nkx</sub></i> effects, while the loci for severe, atrioventricular septal defects exert large G×G<i><sub>Nkx</sub></i> and G×G×G<i><sub>Nkx</sub></i> effects. The loci for moderately severe ventricular septal defects have intermediate effects. Interestingly, G×G×G<i><sub>Nkx</sub></i> effects are three times more likely to suppress risk when the genotypes at the first two loci are from the same rather than different parental inbred strains. This suggests the genetic coadaptation of interacting G×G×G<i><sub>Nkx</sub></i> loci, a phenomenon that Dobzhansky first described in <i>Drosophila</i>. Thus, epistasis plays dual roles in the pathogenesis of congenital heart disease and the robustness of cardiac development. The empirical results suggest a relationship between the fitness cost and genetic architecture of a disease phenotype and a means for phenotypic robustness to have evolved.https://www.mdpi.com/2073-4425/12/9/1368congenital heart defectsquantitative trait locimodifier genesgenetic epistasis
collection DOAJ
language English
format Article
sources DOAJ
author Ehiole Akhirome
Suk D. Regmi
Rachel A. Magnan
Nelson Ugwu
Yidan Qin
Claire E. Schulkey
James M. Cheverud
Patrick Y. Jay
spellingShingle Ehiole Akhirome
Suk D. Regmi
Rachel A. Magnan
Nelson Ugwu
Yidan Qin
Claire E. Schulkey
James M. Cheverud
Patrick Y. Jay
The Genetic Architecture of a Congenital Heart Defect Is Related to Its Fitness Cost
Genes
congenital heart defects
quantitative trait loci
modifier genes
genetic epistasis
author_facet Ehiole Akhirome
Suk D. Regmi
Rachel A. Magnan
Nelson Ugwu
Yidan Qin
Claire E. Schulkey
James M. Cheverud
Patrick Y. Jay
author_sort Ehiole Akhirome
title The Genetic Architecture of a Congenital Heart Defect Is Related to Its Fitness Cost
title_short The Genetic Architecture of a Congenital Heart Defect Is Related to Its Fitness Cost
title_full The Genetic Architecture of a Congenital Heart Defect Is Related to Its Fitness Cost
title_fullStr The Genetic Architecture of a Congenital Heart Defect Is Related to Its Fitness Cost
title_full_unstemmed The Genetic Architecture of a Congenital Heart Defect Is Related to Its Fitness Cost
title_sort genetic architecture of a congenital heart defect is related to its fitness cost
publisher MDPI AG
series Genes
issn 2073-4425
publishDate 2021-08-01
description In newborns, severe congenital heart defects are rarer than mild ones. This epidemiological relationship between heart defect severity and incidence lacks explanation. Here, an analysis of ~10,000 <i>Nkx2-5</i><sup>+/−</sup> mice from two inbred strain crosses illustrates the fundamental role of epistasis. Modifier genes raise or lower the risk of specific defects via pairwise (G×G<i><sub>Nkx</sub></i>) and higher-order (G×G×G<i><sub>Nkx</sub></i>) interactions with <i>Nkx2-5</i>. Their effect sizes correlate with the severity of a defect. The risk loci for mild, atrial septal defects exert predominantly small G×G<i><sub>Nkx</sub></i> effects, while the loci for severe, atrioventricular septal defects exert large G×G<i><sub>Nkx</sub></i> and G×G×G<i><sub>Nkx</sub></i> effects. The loci for moderately severe ventricular septal defects have intermediate effects. Interestingly, G×G×G<i><sub>Nkx</sub></i> effects are three times more likely to suppress risk when the genotypes at the first two loci are from the same rather than different parental inbred strains. This suggests the genetic coadaptation of interacting G×G×G<i><sub>Nkx</sub></i> loci, a phenomenon that Dobzhansky first described in <i>Drosophila</i>. Thus, epistasis plays dual roles in the pathogenesis of congenital heart disease and the robustness of cardiac development. The empirical results suggest a relationship between the fitness cost and genetic architecture of a disease phenotype and a means for phenotypic robustness to have evolved.
topic congenital heart defects
quantitative trait loci
modifier genes
genetic epistasis
url https://www.mdpi.com/2073-4425/12/9/1368
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