Powerful decomposition of complex traits in a diploid model
link https://doi.org/10.1038/ncomms13311account_box Hallin, Johanaccount_box Maertens, Kasparaccount_box Young, Alexander I.account_box Zackrisson, Martinaccount_box Salinas, Franciscoaccount_box Parts, Leopoldaccount_box Warringer, Jonasaccount_box Liti, Gianni
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Explaining trait differences between individuals is a core and challenging aim of life sciences. Here, we introduce a powerful framework for complete decomposition of trait variation into its underlying genetic causes in diploid model organisms. We sequence and systematically pair the recombinant gametes of two intercrossed natural genomes into an array of diploid hybrids with fully assembled and phased genomes, termed Phased Outbred Lines (POLs). We demonstrate the capacity of this approach by partitioning fitness traits of 6,642 Saccharomyces cerevisiae POLs across many environments, achieving near complete trait heritability and precisely estimating additive (73%), dominance (10%), second (7%) and third (1.7%) order epistasis components. We map quantitative trait loci (QTLs) and find nonadditive QTLs to outnumber (3:1) additive loci, dominant contributions to heterosis to outnumber overdominant, and extensive pleiotropy. The POL framework offers the most complete decomposition of diploid traits to date and can be adapted to most model organisms.
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| Autor | Hallin, Johan Maertens, Kaspar Young, Alexander I. Zackrisson, Martin Salinas, Francisco Parts, Leopold Warringer, Jonas Liti, Gianni |
| Título | Powerful decomposition of complex traits in a diploid model |
| Revista | NATURE COMMUNICATIONS |
| ISSN | 2041-1723 |
| Volumen | 7 |
| Fecha de publicación | 2016 |
| Resumen | Explaining trait differences between individuals is a core and challenging aim of life sciences. Here, we introduce a powerful framework for complete decomposition of trait variation into its underlying genetic causes in diploid model organisms. We sequence and systematically pair the recombinant gametes of two intercrossed natural genomes into an array of diploid hybrids with fully assembled and phased genomes, termed Phased Outbred Lines (POLs). We demonstrate the capacity of this approach by partitioning fitness traits of 6,642 Saccharomyces cerevisiae POLs across many environments, achieving near complete trait heritability and precisely estimating additive (73%), dominance (10%), second (7%) and third (1.7%) order epistasis components. We map quantitative trait loci (QTLs) and find nonadditive QTLs to outnumber (3:1) additive loci, dominant contributions to heterosis to outnumber overdominant, and extensive pleiotropy. The POL framework offers the most complete decomposition of diploid traits to date and can be adapted to most model organisms. |
| Derechos | acceso abierto |
| Agencia financiadora | Labex SIGNALIFE European Regional Development Fund through the BioMedIT project CONICYT/FONDECYT MN-FISB Swedish Research Council Research Council of Norway Marie Curie International Outgoing Fellowship Wellcome Trust Estonian Research Council ATIP-Avenir (CNRS/INSERM) ARC FP7-PEOPLE-CIG ANR Canceropole PACA DuPont Young Professor Award ANR (Labex SIGNALIFE) Becas Chile |
| DOI | 10.1038/ncomms13311 |
| Editorial | NATURE PUBLISHING GROUP |
| Enlace | |
| Id de publicación en Pubmed | MEDLINE:27804950 |
| Id de publicación en WoS | WOS:000386681200001 |
| Paginación | 9 páginas |
| Palabra clave | SACCHAROMYCES-CEREVISIAE MISSING HERITABILITY GENETIC INTERACTIONS QUANTITATIVE TRAITS POPULATION GENOMICS VARIANCE-COMPONENTS YEAST POPULATION HETEROSIS EVOLUTION GROWTH |
| Tema ODS | 03 Good Health and Well-being |
| Tema ODS español | 03 Salud y bienestar |
| Tipo de documento | artículo |