Strawberry phenotypic plasticity in flowering time is driven by the interaction between genetic loci and temperature

Abstract Flowering time (FT), which determines when fruits or seeds can be harvested, is subject to phenotypic plasticity, that is, the ability of a genotype to display different phenotypes in response to environmental variation. Here, we investigated how the environment affects the genetic architec...

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Published in	Journal of experimental botany Vol. 75; no. 18; pp. 5923 - 5939
Main Authors	Prohaska, Alexandre, Petit, Aurélie, Lesemann, Silke, Rey-Serra, Pol, Mazzoni, Luca, Masny, Agnieszka, Sánchez-Sevilla, José F, Potier, Aline, Gaston, Amèlia, Klamkowski, Krzysztof, Rothan, Christophe, Mezzetti, Bruno, Amaya, Iraida, Olbricht, Klaus, Denoyes, Béatrice
Format	Journal Article
Language	English
Published	UK Oxford University Press 27.09.2024
Subjects	Flowers - genetics Flowers - growth & development Flowers - physiology Fragaria - genetics Fragaria - growth & development Fragaria - physiology Gene-Environment Interaction Phenotype Photoperiod Quantitative Trait Loci Research Papers Temperature strawberry phenotypic plasticity quantitative trait locus (QTL) flowering time QTL-by-environment interaction (QEI) Genotype×environment interaction (G×E)
Online Access	Get full text
ISSN	0022-0957 1460-2431 1460-2431
DOI	10.1093/jxb/erae279

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Abstract	Abstract Flowering time (FT), which determines when fruits or seeds can be harvested, is subject to phenotypic plasticity, that is, the ability of a genotype to display different phenotypes in response to environmental variation. Here, we investigated how the environment affects the genetic architecture of FT in cultivated strawberry (Fragaria × ananassa) and modifies its quantitative trait locus (QTL) effects. To this end, we used a bi-parental segregating population grown for 2 years at widely divergent latitudes (five European countries) and combined climatic variables with genomic data (Affymetrix SNP array). Examination, using different phenological models, of the response of FT to photoperiod, temperature, and global radiation indicated that temperature is the main driver of FT in strawberry. We next characterized in the segregating population the phenotypic plasticity of FT by using three statistical approaches that generated plasticity parameters including reaction norm parameters. We detected 25 FT QTLs summarized as 10 unique QTLs. Mean values and plasticity parameter QTLs were co-localized in three of them, including the major 6D_M QTL whose effect is strongly modulated by temperature. The design and validation of a genetic marker for the 6D_M QTL offers great potential for breeding programs, for example selecting early-flowering strawberry varieties well adapted to different environmental conditions. Temperature is the main driver of phenotypic plasticity of flowering time in strawberry, rather than photoperiod and global radiation, and a genetic marker for a major temperature-sensitive QTL was identified.
AbstractList	Abstract Flowering time (FT), which determines when fruits or seeds can be harvested, is subject to phenotypic plasticity, that is, the ability of a genotype to display different phenotypes in response to environmental variation. Here, we investigated how the environment affects the genetic architecture of FT in cultivated strawberry (Fragaria × ananassa) and modifies its quantitative trait locus (QTL) effects. To this end, we used a bi-parental segregating population grown for 2 years at widely divergent latitudes (five European countries) and combined climatic variables with genomic data (Affymetrix SNP array). Examination, using different phenological models, of the response of FT to photoperiod, temperature, and global radiation indicated that temperature is the main driver of FT in strawberry. We next characterized in the segregating population the phenotypic plasticity of FT by using three statistical approaches that generated plasticity parameters including reaction norm parameters. We detected 25 FT QTLs summarized as 10 unique QTLs. Mean values and plasticity parameter QTLs were co-localized in three of them, including the major 6D_M QTL whose effect is strongly modulated by temperature. The design and validation of a genetic marker for the 6D_M QTL offers great potential for breeding programs, for example selecting early-flowering strawberry varieties well adapted to different environmental conditions. Temperature is the main driver of phenotypic plasticity of flowering time in strawberry, rather than photoperiod and global radiation, and a genetic marker for a major temperature-sensitive QTL was identified. Flowering time (FT), which determines when fruits or seeds can be harvested, is subject to phenotypic plasticity, that is, the ability of a genotype to display different phenotypes in response to environmental variation. Here, we investigated how the environment affects the genetic architecture of FT in cultivated strawberry (Fragaria × ananassa) and modifies its quantitative trait locus (QTL) effects. To this end, we used a bi-parental segregating population grown for 2 years at widely divergent latitudes (five European countries) and combined climatic variables with genomic data (Affymetrix SNP array). Examination, using different phenological models, of the response of FT to photoperiod, temperature, and global radiation indicated that temperature is the main driver of FT in strawberry. We next characterized in the segregating population the phenotypic plasticity of FT by using three statistical approaches that generated plasticity parameters including reaction norm parameters. We detected 25 FT QTLs summarized as 10 unique QTLs. Mean values and plasticity parameter QTLs were co-localized in three of them, including the major 6D_M QTL whose effect is strongly modulated by temperature. The design and validation of a genetic marker for the 6D_M QTL offers great potential for breeding programs, for example selecting early-flowering strawberry varieties well adapted to different environmental conditions.Flowering time (FT), which determines when fruits or seeds can be harvested, is subject to phenotypic plasticity, that is, the ability of a genotype to display different phenotypes in response to environmental variation. Here, we investigated how the environment affects the genetic architecture of FT in cultivated strawberry (Fragaria × ananassa) and modifies its quantitative trait locus (QTL) effects. To this end, we used a bi-parental segregating population grown for 2 years at widely divergent latitudes (five European countries) and combined climatic variables with genomic data (Affymetrix SNP array). Examination, using different phenological models, of the response of FT to photoperiod, temperature, and global radiation indicated that temperature is the main driver of FT in strawberry. We next characterized in the segregating population the phenotypic plasticity of FT by using three statistical approaches that generated plasticity parameters including reaction norm parameters. We detected 25 FT QTLs summarized as 10 unique QTLs. Mean values and plasticity parameter QTLs were co-localized in three of them, including the major 6D_M QTL whose effect is strongly modulated by temperature. The design and validation of a genetic marker for the 6D_M QTL offers great potential for breeding programs, for example selecting early-flowering strawberry varieties well adapted to different environmental conditions. Flowering time (FT), which determines when fruits or seeds can be harvested, is subject to phenotypic plasticity, that is, the ability of a genotype to display different phenotypes in response to environmental variation. Here, we investigated how the environment affects the genetic architecture of FT in cultivated strawberry (Fragaria × ananassa) and modifies its quantitative trait locus (QTL) effects. To this end, we used a bi-parental segregating population grown for 2 years at widely divergent latitudes (five European countries) and combined climatic variables with genomic data (Affymetrix SNP array). Examination, using different phenological models, of the response of FT to photoperiod, temperature, and global radiation indicated that temperature is the main driver of FT in strawberry. We next characterized in the segregating population the phenotypic plasticity of FT by using three statistical approaches that generated plasticity parameters including reaction norm parameters. We detected 25 FT QTLs summarized as 10 unique QTLs. Mean values and plasticity parameter QTLs were co-localized in three of them, including the major 6D_M QTL whose effect is strongly modulated by temperature. The design and validation of a genetic marker for the 6D_M QTL offers great potential for breeding programs, for example selecting early-flowering strawberry varieties well adapted to different environmental conditions. Flowering time (FT), which determines when fruits or seeds can be harvested, is subject to phenotypic plasticity, that is, the ability of a genotype to display different phenotypes in response to environmental variation. Here, we investigated how the environment affects the genetic architecture of FT in cultivated strawberry ( Fragaria × ananassa ) and modifies its quantitative trait locus (QTL) effects. To this end, we used a bi-parental segregating population grown for 2 years at widely divergent latitudes (five European countries) and combined climatic variables with genomic data (Affymetrix SNP array). Examination, using different phenological models, of the response of FT to photoperiod, temperature, and global radiation indicated that temperature is the main driver of FT in strawberry. We next characterized in the segregating population the phenotypic plasticity of FT by using three statistical approaches that generated plasticity parameters including reaction norm parameters. We detected 25 FT QTLs summarized as 10 unique QTLs. Mean values and plasticity parameter QTLs were co-localized in three of them, including the major 6D_M QTL whose effect is strongly modulated by temperature. The design and validation of a genetic marker for the 6D_M QTL offers great potential for breeding programs, for example selecting early-flowering strawberry varieties well adapted to different environmental conditions. Temperature is the main driver of phenotypic plasticity of flowering time in strawberry, rather than photoperiod and global radiation, and a genetic marker for a major temperature-sensitive QTL was identified.
Author	Olbricht, Klaus Amaya, Iraida Mezzetti, Bruno Prohaska, Alexandre Rothan, Christophe Klamkowski, Krzysztof Denoyes, Béatrice Gaston, Amèlia Potier, Aline Petit, Aurélie Rey-Serra, Pol Sánchez-Sevilla, José F Mazzoni, Luca Masny, Agnieszka Lesemann, Silke
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Keywords	strawberry phenotypic plasticity quantitative trait locus (QTL) flowering time QTL-by-environment interaction (QEI) Genotype×environment interaction (G×E)
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Snippet	Abstract Flowering time (FT), which determines when fruits or seeds can be harvested, is subject to phenotypic plasticity, that is, the ability of a genotype... Flowering time (FT), which determines when fruits or seeds can be harvested, is subject to phenotypic plasticity, that is, the ability of a genotype to display...
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StartPage	5923
SubjectTerms	Flowers - genetics Flowers - growth & development Flowers - physiology Fragaria - genetics Fragaria - growth & development Fragaria - physiology Gene-Environment Interaction Phenotype Photoperiod Quantitative Trait Loci Research Papers Temperature
Title	Strawberry phenotypic plasticity in flowering time is driven by the interaction between genetic loci and temperature
URI	https://www.ncbi.nlm.nih.gov/pubmed/38938160 https://www.proquest.com/docview/3073232483 https://pubmed.ncbi.nlm.nih.gov/PMC11427845
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