Hydraulic processes in roots and the rhizosphere pertinent to increasing yield of water-limited grain crops: a critical review

Highlight A review of the role of roots in extracting water from the soil with regard to amount and timing leading to maximal grain yield, and of the various mechanisms underlying this. Abstract To a first-order approximation, the yield of a water-limited grain crop depends (i) on how much water is...

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Published inJournal of experimental botany Vol. 69; no. 13; pp. 3255 - 3265
Main Authors Ahmed, Mutez Ali, Passioura, John, Carminati, Andrea
Format Journal Article
LanguageEnglish
Published UK Oxford University Press 06.06.2018
Subjects
aboveground biomass
canopy
filling period
flowering
grain crops
grain yield
growing season
harvest index
leaves
mucilages
rhizosphere
roots
seasonal variation
soil
transpiration
water supply
root signals
root architecture
mucilage
drought
Aquaporins
root hydraulics
root hairs
root-soil interface
root anatomy
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Abstract Highlight A review of the role of roots in extracting water from the soil with regard to amount and timing leading to maximal grain yield, and of the various mechanisms underlying this. Abstract To a first-order approximation, the yield of a water-limited grain crop depends (i) on how much water is available to the crop and (ii) on how crop water use is partitioned during the growing season. The latter determines the harvest index of the crop, that is, the proportion of the crop's above ground biomass that is converted into grain, which is typically optimal if about 30% of the seasonal available water supply is used during flowering and grain filling. Here, we review the role of roots in extracting water from the soil in both the amount and the timing that may lead to maximal grain yield, and the various mechanisms underlying this activity. These include architectural and anatomical traits; the biophysics of water movement from soil through roots to the leaves including especially the properties of and processes within the interface between roots and soil and the role of mucilage therein; and the physiological role of the roots in influencing the growth and transpiration of the crop canopy, which can optimize the seasonal pattern of water use. These various properties and mechanisms are discussed in the context of improving grain yield in strongly water-limited, especially semiarid, environments.
AbstractList A review of the role of roots in extracting water from the soil with regard to amount and timing leading to maximal grain yield, and of the various mechanisms underlying this.HIGHLIGHTA review of the role of roots in extracting water from the soil with regard to amount and timing leading to maximal grain yield, and of the various mechanisms underlying this.
A review of the role of roots in extracting water from the soil with regard to amount and timing leading to maximal grain yield, and of the various mechanisms underlying this.
Highlight A review of the role of roots in extracting water from the soil with regard to amount and timing leading to maximal grain yield, and of the various mechanisms underlying this. Abstract To a first-order approximation, the yield of a water-limited grain crop depends (i) on how much water is available to the crop and (ii) on how crop water use is partitioned during the growing season. The latter determines the harvest index of the crop, that is, the proportion of the crop's above ground biomass that is converted into grain, which is typically optimal if about 30% of the seasonal available water supply is used during flowering and grain filling. Here, we review the role of roots in extracting water from the soil in both the amount and the timing that may lead to maximal grain yield, and the various mechanisms underlying this activity. These include architectural and anatomical traits; the biophysics of water movement from soil through roots to the leaves including especially the properties of and processes within the interface between roots and soil and the role of mucilage therein; and the physiological role of the roots in influencing the growth and transpiration of the crop canopy, which can optimize the seasonal pattern of water use. These various properties and mechanisms are discussed in the context of improving grain yield in strongly water-limited, especially semiarid, environments.
To a first-order approximation, the yield of a water-limited grain crop depends (i) on how much water is available to the crop and (ii) on how crop water use is partitioned during the growing season. The latter determines the harvest index of the crop, that is, the proportion of the crop’s above ground biomass that is converted into grain, which is typically optimal if about 30% of the seasonal available water supply is used during flowering and grain filling. Here, we review the role of roots in extracting water from the soil in both the amount and the timing that may lead to maximal grain yield, and the various mechanisms underlying this activity. These include architectural and anatomical traits; the biophysics of water movement from soil through roots to the leaves including especially the properties of and processes within the interface between roots and soil and the role of mucilage therein; and the physiological role of the roots in influencing the growth and transpiration of the crop canopy, which can optimize the seasonal pattern of water use. These various properties and mechanisms are discussed in the context of improving grain yield in strongly water-limited, especially semiarid, environments.
Author Passioura, John
Ahmed, Mutez Ali
Carminati, Andrea
Author_xml – sequence: 1
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  surname: Ahmed
  fullname: Ahmed, Mutez Ali
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  organization: Chair of Soil Physics, University of Bayreuth, Bayreuth, Germany
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  surname: Passioura
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  surname: Carminati
  fullname: Carminati, Andrea
  organization: Chair of Soil Physics, University of Bayreuth, Bayreuth, Germany
BackLink https://www.ncbi.nlm.nih.gov/pubmed/29767797$$D View this record in MEDLINE/PubMed
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Copyright The Author(s) 2018. Published by Oxford University Press on behalf of the Society for Experimental Biology. All rights reserved. For permissions, please email: journals.permissions@oup.com 2018
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Issue 13
Keywords root signals
root architecture
mucilage
drought
Aquaporins
root hydraulics
root hairs
root-soil interface
root anatomy
Language English
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Snippet Highlight A review of the role of roots in extracting water from the soil with regard to amount and timing leading to maximal grain yield, and of the various...
A review of the role of roots in extracting water from the soil with regard to amount and timing leading to maximal grain yield, and of the various mechanisms...
To a first-order approximation, the yield of a water-limited grain crop depends (i) on how much water is available to the crop and (ii) on how crop water use...
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SubjectTerms aboveground biomass
canopy
filling period
flowering
grain crops
grain yield
growing season
harvest index
leaves
mucilages
rhizosphere
roots
seasonal variation
soil
transpiration
water supply
Title Hydraulic processes in roots and the rhizosphere pertinent to increasing yield of water-limited grain crops: a critical review
URI https://www.ncbi.nlm.nih.gov/pubmed/29767797
https://www.proquest.com/docview/2039872867
https://www.proquest.com/docview/2400472613
Volume 69
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