Genetic and phenotypic associations between root architecture, arbuscular mycorrhizal fungi colonisation and low phosphate tolerance in strawberry (Fragaria × ananassa)

Genetic and phenotypic associations between root architecture, arbuscular mycorrhizal fungi colonisation and low phosphate tolerance in strawberry (Fragaria × ananassa)

Background: Phosphate is an essential plant macronutrient required to achieve maximum crop yield. Roots are able to uptake soil phosphate from the immediate root area, thus creating a nutrient depletion zone. Many plants are able to exploit phosphate from beyond this root nutrient depletion zone through symbiotic association with Arbuscular Mycorrhizal Fungi (AMF). Here we characterise the relationship between root architecture, AMF association and low phosphate tolerance in strawberries. The contrasting root architecture in the parental strawberry cultivars 'Redgauntlet' and 'Hapil' was studied through a mapping population of 168 progeny. Low phosphate tolerance and AMF association was quantified for each genotype to allow assessment of the phenotypic and genotypic relationships between traits. Results: A "phosphate scavenging" root phenotype where individuals exhibit a high proportion of surface lateral roots was associated with a reduction in root system size across genotypes. A genetic correlation between "root system size" traits was observed with a network of pleiotropic QTL found to represent five "root system size" traits. By contrast, average root diameter and the distribution of roots appeared to be under two discrete methods of genetic control. A total of 18 QTL were associated with plant traits, 4 of which were associated with solidity that explained 46% of the observed variation. Investigations into the relationship between AMF association and root architecture found that a higher root density was associated with greater AMF colonisation across genotypes. However, no phenotypic correlation or genotypic association was found between low phosphate tolerance and the propensity for AMF association, nor root architectural traits when plants are grown under optimal nutrient conditions. Conclusions: Understanding the genetic relationships underpinning phosphate capture can inform the breeding of strawberry varieties with better nutrient use efficiency. Solid root systems were associated with greater AMF colonisation. However, low P-tolerance was not phenotypically or genotypically associated with root architecture traits in strawberry plants. Furthermore, a trade-off was observed between root system size and root architecture type, highlighting the energetic costs associated with a "phosphate scavenging" root architecture.

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Main Authors: Cockerton, Helen Maria, Li, Bo, Stavridou, Eleftheria, Johnson, Abigail, Karlström, Amanda, Armitage, Andrew Douglas, Martinez-Crucis, Ana, Galiano-Arjona, Lorena, Harrison, Nicola, Barber-Pérez, Nuria, Cobo-Medina, Magdalena, Harrison, Richard Jonathan
Format: Article/Letter to editor biblioteca
Language:English
Subjects:AMF, Image analysis, Length distribution, Macronutrients, Network, QTL, Rhizotron, Solidity, Symbiont, Trade-off,
Online Access:https://research.wur.nl/en/publications/genetic-and-phenotypic-associations-between-root-architecture-arb
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spelling dig-wur-nl-wurpubs-6049372024-12-04 Cockerton, Helen Maria Li, Bo Stavridou, Eleftheria Johnson, Abigail Karlström, Amanda Armitage, Andrew Douglas Martinez-Crucis, Ana Galiano-Arjona, Lorena Harrison, Nicola Barber-Pérez, Nuria Cobo-Medina, Magdalena Harrison, Richard Jonathan Article/Letter to editor BMC Plant Biology 20 (2020) ISSN: 1471-2229 Genetic and phenotypic associations between root architecture, arbuscular mycorrhizal fungi colonisation and low phosphate tolerance in strawberry (Fragaria × ananassa) 2020 Background: Phosphate is an essential plant macronutrient required to achieve maximum crop yield. Roots are able to uptake soil phosphate from the immediate root area, thus creating a nutrient depletion zone. Many plants are able to exploit phosphate from beyond this root nutrient depletion zone through symbiotic association with Arbuscular Mycorrhizal Fungi (AMF). Here we characterise the relationship between root architecture, AMF association and low phosphate tolerance in strawberries. The contrasting root architecture in the parental strawberry cultivars 'Redgauntlet' and 'Hapil' was studied through a mapping population of 168 progeny. Low phosphate tolerance and AMF association was quantified for each genotype to allow assessment of the phenotypic and genotypic relationships between traits. Results: A "phosphate scavenging" root phenotype where individuals exhibit a high proportion of surface lateral roots was associated with a reduction in root system size across genotypes. A genetic correlation between "root system size" traits was observed with a network of pleiotropic QTL found to represent five "root system size" traits. By contrast, average root diameter and the distribution of roots appeared to be under two discrete methods of genetic control. A total of 18 QTL were associated with plant traits, 4 of which were associated with solidity that explained 46% of the observed variation. Investigations into the relationship between AMF association and root architecture found that a higher root density was associated with greater AMF colonisation across genotypes. However, no phenotypic correlation or genotypic association was found between low phosphate tolerance and the propensity for AMF association, nor root architectural traits when plants are grown under optimal nutrient conditions. Conclusions: Understanding the genetic relationships underpinning phosphate capture can inform the breeding of strawberry varieties with better nutrient use efficiency. Solid root systems were associated with greater AMF colonisation. However, low P-tolerance was not phenotypically or genotypically associated with root architecture traits in strawberry plants. Furthermore, a trade-off was observed between root system size and root architecture type, highlighting the energetic costs associated with a "phosphate scavenging" root architecture. en text/html https://research.wur.nl/en/publications/genetic-and-phenotypic-associations-between-root-architecture-arb 10.1186/s12870-020-02347-x https://edepot.wur.nl/581473 AMF Image analysis Length distribution Macronutrients Network QTL Rhizotron Solidity Symbiont Trade-off https://creativecommons.org/licenses/by/4.0/ 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 AMF
Image analysis
Length distribution
Macronutrients
Network
QTL
Rhizotron
Solidity
Symbiont
Trade-off
AMF
Image analysis
Length distribution
Macronutrients
Network
QTL
Rhizotron
Solidity
Symbiont
Trade-off
spellingShingle AMF
Image analysis
Length distribution
Macronutrients
Network
QTL
Rhizotron
Solidity
Symbiont
Trade-off
AMF
Image analysis
Length distribution
Macronutrients
Network
QTL
Rhizotron
Solidity
Symbiont
Trade-off
Cockerton, Helen Maria
Li, Bo
Stavridou, Eleftheria
Johnson, Abigail
Karlström, Amanda
Armitage, Andrew Douglas
Martinez-Crucis, Ana
Galiano-Arjona, Lorena
Harrison, Nicola
Barber-Pérez, Nuria
Cobo-Medina, Magdalena
Harrison, Richard Jonathan
Genetic and phenotypic associations between root architecture, arbuscular mycorrhizal fungi colonisation and low phosphate tolerance in strawberry (Fragaria × ananassa)
description Background: Phosphate is an essential plant macronutrient required to achieve maximum crop yield. Roots are able to uptake soil phosphate from the immediate root area, thus creating a nutrient depletion zone. Many plants are able to exploit phosphate from beyond this root nutrient depletion zone through symbiotic association with Arbuscular Mycorrhizal Fungi (AMF). Here we characterise the relationship between root architecture, AMF association and low phosphate tolerance in strawberries. The contrasting root architecture in the parental strawberry cultivars 'Redgauntlet' and 'Hapil' was studied through a mapping population of 168 progeny. Low phosphate tolerance and AMF association was quantified for each genotype to allow assessment of the phenotypic and genotypic relationships between traits. Results: A "phosphate scavenging" root phenotype where individuals exhibit a high proportion of surface lateral roots was associated with a reduction in root system size across genotypes. A genetic correlation between "root system size" traits was observed with a network of pleiotropic QTL found to represent five "root system size" traits. By contrast, average root diameter and the distribution of roots appeared to be under two discrete methods of genetic control. A total of 18 QTL were associated with plant traits, 4 of which were associated with solidity that explained 46% of the observed variation. Investigations into the relationship between AMF association and root architecture found that a higher root density was associated with greater AMF colonisation across genotypes. However, no phenotypic correlation or genotypic association was found between low phosphate tolerance and the propensity for AMF association, nor root architectural traits when plants are grown under optimal nutrient conditions. Conclusions: Understanding the genetic relationships underpinning phosphate capture can inform the breeding of strawberry varieties with better nutrient use efficiency. Solid root systems were associated with greater AMF colonisation. However, low P-tolerance was not phenotypically or genotypically associated with root architecture traits in strawberry plants. Furthermore, a trade-off was observed between root system size and root architecture type, highlighting the energetic costs associated with a "phosphate scavenging" root architecture.
format Article/Letter to editor
topic_facet AMF
Image analysis
Length distribution
Macronutrients
Network
QTL
Rhizotron
Solidity
Symbiont
Trade-off
author Cockerton, Helen Maria
Li, Bo
Stavridou, Eleftheria
Johnson, Abigail
Karlström, Amanda
Armitage, Andrew Douglas
Martinez-Crucis, Ana
Galiano-Arjona, Lorena
Harrison, Nicola
Barber-Pérez, Nuria
Cobo-Medina, Magdalena
Harrison, Richard Jonathan
author_facet Cockerton, Helen Maria
Li, Bo
Stavridou, Eleftheria
Johnson, Abigail
Karlström, Amanda
Armitage, Andrew Douglas
Martinez-Crucis, Ana
Galiano-Arjona, Lorena
Harrison, Nicola
Barber-Pérez, Nuria
Cobo-Medina, Magdalena
Harrison, Richard Jonathan
author_sort Cockerton, Helen Maria
title Genetic and phenotypic associations between root architecture, arbuscular mycorrhizal fungi colonisation and low phosphate tolerance in strawberry (Fragaria × ananassa)
title_short Genetic and phenotypic associations between root architecture, arbuscular mycorrhizal fungi colonisation and low phosphate tolerance in strawberry (Fragaria × ananassa)
title_full Genetic and phenotypic associations between root architecture, arbuscular mycorrhizal fungi colonisation and low phosphate tolerance in strawberry (Fragaria × ananassa)
title_fullStr Genetic and phenotypic associations between root architecture, arbuscular mycorrhizal fungi colonisation and low phosphate tolerance in strawberry (Fragaria × ananassa)
title_full_unstemmed Genetic and phenotypic associations between root architecture, arbuscular mycorrhizal fungi colonisation and low phosphate tolerance in strawberry (Fragaria × ananassa)
title_sort genetic and phenotypic associations between root architecture, arbuscular mycorrhizal fungi colonisation and low phosphate tolerance in strawberry (fragaria × ananassa)
url https://research.wur.nl/en/publications/genetic-and-phenotypic-associations-between-root-architecture-arb
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