Plant root growth, architecture and function

Angela Hodge; Graziella Berta; Claude Doussan; Francisco Merchan; Martin Crespi

doi:10.1007/s11104-009-9929-9

Plant root growth, architecture and function

Angela Hodge
, Graziella Berta
, Claude Doussan
, Francisco Merchan
, Martin Crespi

Research output: Contribution to journal › Review article › peer-review

Abstract

Without roots there would be no rhizosphere and no rhizodeposition to fuel microbial activity. Although microorganisms may view roots merely as a source of carbon supply this belies the fascinating complexity and diversity of root systems that occurs despite their common function. Here, we examine the physiological and genetic determinants of root growth and the complex, yet varied and flexible, root architecture that results. The main functions of root systems are also explored including how roots cope with nutrient acquisition from the heterogeneous soil environment and their ability to form mutualistic associations with key soil microorganisms (such as nitrogen fixing bacteria and mycorrhizal fungi) to aid them in their quest for nutrients. Finally, some key biotic and abiotic constraints on root development and function in the soil environment are examined and some of the adaptations roots have evolved to counter such stresses discussed.

Original language	English
Pages (from-to)	153-187
Number of pages	35
Journal	Plant and Soil
Volume	321
Issue number	1-2
DOIs	https://doi.org/10.1007/s11104-009-9929-9
Publication status	Published - 2009
Externally published	Yes

Keywords

Abiotic and biotic stresses
Auxin
Root architecture
Root systems
Soil heterogeneity
Soil microorganisms (including nitrogen-fixing bacteria and mycorrhizal fungi)

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10.1007/s11104-009-9929-9

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abstract = "Without roots there would be no rhizosphere and no rhizodeposition to fuel microbial activity. Although microorganisms may view roots merely as a source of carbon supply this belies the fascinating complexity and diversity of root systems that occurs despite their common function. Here, we examine the physiological and genetic determinants of root growth and the complex, yet varied and flexible, root architecture that results. The main functions of root systems are also explored including how roots cope with nutrient acquisition from the heterogeneous soil environment and their ability to form mutualistic associations with key soil microorganisms (such as nitrogen fixing bacteria and mycorrhizal fungi) to aid them in their quest for nutrients. Finally, some key biotic and abiotic constraints on root development and function in the soil environment are examined and some of the adaptations roots have evolved to counter such stresses discussed.",

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T1 - Plant root growth, architecture and function

AU - Hodge, Angela

AU - Berta, Graziella

AU - Doussan, Claude

AU - Merchan, Francisco

AU - Crespi, Martin

PY - 2009

Y1 - 2009

N2 - Without roots there would be no rhizosphere and no rhizodeposition to fuel microbial activity. Although microorganisms may view roots merely as a source of carbon supply this belies the fascinating complexity and diversity of root systems that occurs despite their common function. Here, we examine the physiological and genetic determinants of root growth and the complex, yet varied and flexible, root architecture that results. The main functions of root systems are also explored including how roots cope with nutrient acquisition from the heterogeneous soil environment and their ability to form mutualistic associations with key soil microorganisms (such as nitrogen fixing bacteria and mycorrhizal fungi) to aid them in their quest for nutrients. Finally, some key biotic and abiotic constraints on root development and function in the soil environment are examined and some of the adaptations roots have evolved to counter such stresses discussed.

AB - Without roots there would be no rhizosphere and no rhizodeposition to fuel microbial activity. Although microorganisms may view roots merely as a source of carbon supply this belies the fascinating complexity and diversity of root systems that occurs despite their common function. Here, we examine the physiological and genetic determinants of root growth and the complex, yet varied and flexible, root architecture that results. The main functions of root systems are also explored including how roots cope with nutrient acquisition from the heterogeneous soil environment and their ability to form mutualistic associations with key soil microorganisms (such as nitrogen fixing bacteria and mycorrhizal fungi) to aid them in their quest for nutrients. Finally, some key biotic and abiotic constraints on root development and function in the soil environment are examined and some of the adaptations roots have evolved to counter such stresses discussed.

KW - Abiotic and biotic stresses

KW - Auxin

KW - Root architecture

KW - Root systems

KW - Soil heterogeneity

KW - Soil microorganisms (including nitrogen-fixing bacteria and mycorrhizal fungi)

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U2 - 10.1007/s11104-009-9929-9

DO - 10.1007/s11104-009-9929-9

M3 - Review article

SN - 0032-079X

VL - 321

SP - 153

EP - 187

JO - Plant and Soil

JF - Plant and Soil

IS - 1-2

ER -

Plant root growth, architecture and function

Abstract

Keywords

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