QTL analysis reveals the genetic architecture of domestication traits in Crisphead lettuce

QTL analysis reveals the genetic architecture of domestication traits in Crisphead lettuce

The genetic architecture of crop domestication is generally characterized by three trends: relatively few genomic regions with major QTL effects are involved, QTL are often clustered, and alleles derived from the crop do not always contribute to the crop phenotype. We have investigated the genetic architecture of lettuce using a recombinant inbred line population from a cross between a crop Lactuca sativa (‘Salinas’) and its wild relative L. serriola. Few genomic regions with major QTL, plus various intermediate QTL, largely control the transition from wild to cultivated Crisphead lettuce. Allelic effects of all major QTL were in the expected direction, but there were intermediate QTL where the crop contributed to the wild phenotype and vice versa. We found two main regions with clusters of QTL, one on linkage group 3, where the crop allele induced lower seed output, another on linkage group 7, where the crop allele caused a delay in flowering time. Potentially, knowledge of genetic changes due to the domestication could be relevant for the chance that a transgene inserted in a crop genome will spread to wild relatives due to hitchhiking effects. If a transgene would be inserted in one of these regions, background selection on the crop alleles may lead to a reduced fitness of hybrids with the transgene. QTL research on the effects of domestication genes can thus indicate regions in the crop genome that are less likely to introgress, although these still need to be verified under field conditions.

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Bibliographic Details
Main Authors: Hartman, Y., Hooftman, D.A.P., Schranz, M.E., van Tienderen, P.H.
Format: Article/Letter to editor biblioteca
Language:English
Subjects:arabidopsis-thaliana, crop domestication, evolution, lactuca-serriola asteraceae, loci, marker-assisted selection, plant domestication, sativa l., sunflower, wild,
Online Access:https://research.wur.nl/en/publications/qtl-analysis-reveals-the-genetic-architecture-of-domestication-tr
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spelling dig-wur-nl-wurpubs-4312012025-01-10 Hartman, Y. Hooftman, D.A.P. Schranz, M.E. van Tienderen, P.H. Article/Letter to editor Genetic Resources and Crop Evolution 60 (2013) 4 ISSN: 0925-9864 QTL analysis reveals the genetic architecture of domestication traits in Crisphead lettuce 2013 The genetic architecture of crop domestication is generally characterized by three trends: relatively few genomic regions with major QTL effects are involved, QTL are often clustered, and alleles derived from the crop do not always contribute to the crop phenotype. We have investigated the genetic architecture of lettuce using a recombinant inbred line population from a cross between a crop Lactuca sativa (‘Salinas’) and its wild relative L. serriola. Few genomic regions with major QTL, plus various intermediate QTL, largely control the transition from wild to cultivated Crisphead lettuce. Allelic effects of all major QTL were in the expected direction, but there were intermediate QTL where the crop contributed to the wild phenotype and vice versa. We found two main regions with clusters of QTL, one on linkage group 3, where the crop allele induced lower seed output, another on linkage group 7, where the crop allele caused a delay in flowering time. Potentially, knowledge of genetic changes due to the domestication could be relevant for the chance that a transgene inserted in a crop genome will spread to wild relatives due to hitchhiking effects. If a transgene would be inserted in one of these regions, background selection on the crop alleles may lead to a reduced fitness of hybrids with the transgene. QTL research on the effects of domestication genes can thus indicate regions in the crop genome that are less likely to introgress, although these still need to be verified under field conditions. en application/pdf https://research.wur.nl/en/publications/qtl-analysis-reveals-the-genetic-architecture-of-domestication-tr 10.1007/s10722-012-9937-0 https://edepot.wur.nl/240568 arabidopsis-thaliana crop domestication evolution lactuca-serriola asteraceae loci marker-assisted selection plant domestication sativa l. sunflower wild Wageningen University & Research
institution WUR NL
collection DSpace
country Países bajos
countrycode NL
component Bibliográfico
access En linea
databasecode dig-wur-nl
tag biblioteca
region Europa del Oeste
libraryname WUR Library Netherlands
language English
topic arabidopsis-thaliana
crop domestication
evolution
lactuca-serriola asteraceae
loci
marker-assisted selection
plant domestication
sativa l.
sunflower
wild
arabidopsis-thaliana
crop domestication
evolution
lactuca-serriola asteraceae
loci
marker-assisted selection
plant domestication
sativa l.
sunflower
wild
spellingShingle arabidopsis-thaliana
crop domestication
evolution
lactuca-serriola asteraceae
loci
marker-assisted selection
plant domestication
sativa l.
sunflower
wild
arabidopsis-thaliana
crop domestication
evolution
lactuca-serriola asteraceae
loci
marker-assisted selection
plant domestication
sativa l.
sunflower
wild
Hartman, Y.
Hooftman, D.A.P.
Schranz, M.E.
van Tienderen, P.H.
QTL analysis reveals the genetic architecture of domestication traits in Crisphead lettuce
description The genetic architecture of crop domestication is generally characterized by three trends: relatively few genomic regions with major QTL effects are involved, QTL are often clustered, and alleles derived from the crop do not always contribute to the crop phenotype. We have investigated the genetic architecture of lettuce using a recombinant inbred line population from a cross between a crop Lactuca sativa (‘Salinas’) and its wild relative L. serriola. Few genomic regions with major QTL, plus various intermediate QTL, largely control the transition from wild to cultivated Crisphead lettuce. Allelic effects of all major QTL were in the expected direction, but there were intermediate QTL where the crop contributed to the wild phenotype and vice versa. We found two main regions with clusters of QTL, one on linkage group 3, where the crop allele induced lower seed output, another on linkage group 7, where the crop allele caused a delay in flowering time. Potentially, knowledge of genetic changes due to the domestication could be relevant for the chance that a transgene inserted in a crop genome will spread to wild relatives due to hitchhiking effects. If a transgene would be inserted in one of these regions, background selection on the crop alleles may lead to a reduced fitness of hybrids with the transgene. QTL research on the effects of domestication genes can thus indicate regions in the crop genome that are less likely to introgress, although these still need to be verified under field conditions.
format Article/Letter to editor
topic_facet arabidopsis-thaliana
crop domestication
evolution
lactuca-serriola asteraceae
loci
marker-assisted selection
plant domestication
sativa l.
sunflower
wild
author Hartman, Y.
Hooftman, D.A.P.
Schranz, M.E.
van Tienderen, P.H.
author_facet Hartman, Y.
Hooftman, D.A.P.
Schranz, M.E.
van Tienderen, P.H.
author_sort Hartman, Y.
title QTL analysis reveals the genetic architecture of domestication traits in Crisphead lettuce
title_short QTL analysis reveals the genetic architecture of domestication traits in Crisphead lettuce
title_full QTL analysis reveals the genetic architecture of domestication traits in Crisphead lettuce
title_fullStr QTL analysis reveals the genetic architecture of domestication traits in Crisphead lettuce
title_full_unstemmed QTL analysis reveals the genetic architecture of domestication traits in Crisphead lettuce
title_sort qtl analysis reveals the genetic architecture of domestication traits in crisphead lettuce
url https://research.wur.nl/en/publications/qtl-analysis-reveals-the-genetic-architecture-of-domestication-tr
work_keys_str_mv AT hartmany qtlanalysisrevealsthegeneticarchitectureofdomesticationtraitsincrispheadlettuce
AT hooftmandap qtlanalysisrevealsthegeneticarchitectureofdomesticationtraitsincrispheadlettuce
AT schranzme qtlanalysisrevealsthegeneticarchitectureofdomesticationtraitsincrispheadlettuce
AT vantienderenph qtlanalysisrevealsthegeneticarchitectureofdomesticationtraitsincrispheadlettuce
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