Maize responds to low shoot P concentration by altering root morphology rather than increasing root exudation

Background and aims Alterations in root growth and rhizosphere processes in maize (Zea mays L.) occur under phosphorus (P) deficiency, but the dynamics of root morphological and physiological modifications with increasing shoot P concentration remain unclear. This study investigated root responses t...

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Published in	Plant and soil Vol. 416; no. 1/2; pp. 377 - 389
Main Authors	Wen, Zhihui, Li, Haigang, Shen, Jianbo, Rengel, Zed
Format	Journal Article
Language	English
Published	Cham Springer 01.07.2017 Springer International Publishing Springer Nature B.V
Subjects	Acid phosphatase Acidification Biomass Biomedical and Life Sciences Concentration gradient Corn Ecology Environmental aspects enzyme activity Exudation fine roots Life Sciences Morphology Phosphorus Phosphorus (Nutrient) Physiological aspects physiological response Physiological responses Physiology Plant development Plant growth Plant Physiology Plant Sciences Plant-soil relationships Planting Regular Article Rhizosphere root growth Roots (Botany) soil Soil Science & Conservation Zea mays Rhizosphere processes Phosphorus deficiency Root exudation Root growth
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Abstract	Background and aims Alterations in root growth and rhizosphere processes in maize (Zea mays L.) occur under phosphorus (P) deficiency, but the dynamics of root morphological and physiological modifications with increasing shoot P concentration remain unclear. This study investigated root responses to a wide gradient in shoot P status. Methods A range of maize shoot P concentrations (1.0–4.0 mg g−1) was established using controlled pot experiment with eleven rates of P supply from 0 to 1200 mg P kg−1 soil. Root morphology and rhizosphere processes were characterized 28 days after planting. Results Maize reached maximum biomass at shoot P concentration of 2.7 mg g−1. Root morphological responses (i.e. total root length, specific root length and proportion of fine roots) showed a strong increasing trend with decreasing shoot P concentration (1.1–1.3 mg g−1), but they decreased when shoot P concentration was extremely low (below 1.1 mg g−1). In contrast, with increasing shoot P concentration, root morphological responses decreased, but root physiological responses (rhizosphere acidification, acid phosphatase activity and carboxylate exudation in the rhizosphere) were enhanced, and no decrease was noted even at high shoot P concentration (4.0 mg g−1) corresponding to excess P supply. Conclusions Increasing maize shoot P concentration induced a decrease in root morphological responses and an enhancement in root exudation, with maize response to P deficiency being dependent on root morphological rather than physiological traits.
AbstractList	Alterations in root growth and rhizosphere processes in maize (Zea mays L.) occur under phosphorus (P) deficiency, but the dynamics of root morphological and physiological modifications with increasing shoot P concentration remain unclear. This study investigated root responses to a wide gradient in shoot P status. A range of maize shoot P concentrations (1.0-4.0 mg g.sup.-1) was established using controlled pot experiment with eleven rates of P supply from 0 to 1200 mg P kg.sup.-1 soil. Root morphology and rhizosphere processes were characterized 28 days after planting. Maize reached maximum biomass at shoot P concentration of 2.7 mg g.sup.-1. Root morphological responses (i.e. total root length, specific root length and proportion of fine roots) showed a strong increasing trend with decreasing shoot P concentration (1.1-1.3 mg g.sup.-1), but they decreased when shoot P concentration was extremely low (below 1.1 mg g.sup.-1). In contrast, with increasing shoot P concentration, root morphological responses decreased, but root physiological responses (rhizosphere acidification, acid phosphatase activity and carboxylate exudation in the rhizosphere) were enhanced, and no decrease was noted even at high shoot P concentration (4.0 mg g.sup.-1) corresponding to excess P supply. Increasing maize shoot P concentration induced a decrease in root morphological responses and an enhancement in root exudation, with maize response to P deficiency being dependent on root morphological rather than physiological traits. Background and aims Alterations in root growth and rhizosphere processes in maize (Zea mays L.) occur under phosphorus (P) deficiency, but the dynamics of root morphological and physiological modifications with increasing shoot P concentration remain unclear. This study investigated root responses to a wide gradient in shoot P status. Methods A range of maize shoot P concentrations (1.0-4.0 mg g-1) was established using controlled pot experiment with eleven rates of P supply from 0 to 1200 mg P kg-1 soil. Root morphology and rhizosphere processes were characterized 28 days after planting. Results Maize reached maximum biomass at shoot P concentration of 2.7 mg g-1. Root morphological responses (i.e. total root length, specific root length and proportion of fine roots) showed a strong increasing trend with decreasing shoot P concentration (1.1-1.3 mg g-1), but they decreased when shoot P concentration was extremely low (below 1.1 mg g-1). In contrast, with increasing shoot P concentration, root morphological responses decreased, but root physiological responses (rhizosphere acidification, acid phosphatase activity and carboxylate exudation in the rhizosphere) were enhanced, and no decrease was noted even at high shoot P concentration (4.0 mg g-1) corresponding to excess P supply. Conclusions Increasing maize shoot P concentration induced a decrease in root morphological responses and an enhancement in root exudation, with maize response to P deficiency being dependent on root morphological rather than physiological traits. Background and aims Alterations in root growth and rhizosphere processes in maize (Zea mays L.) occur under phosphorus (P) deficiency, but the dynamics of root morphological and physiological modifications with increasing shoot P concentration remain unclear. This study investigated root responses to a wide gradient in shoot P status. Methods A range of maize shoot P concentrations (1.0-4.0 mg g.sup.-1) was established using controlled pot experiment with eleven rates of P supply from 0 to 1200 mg P kg.sup.-1 soil. Root morphology and rhizosphere processes were characterized 28 days after planting. Results Maize reached maximum biomass at shoot P concentration of 2.7 mg g.sup.-1. Root morphological responses (i.e. total root length, specific root length and proportion of fine roots) showed a strong increasing trend with decreasing shoot P concentration (1.1-1.3 mg g.sup.-1), but they decreased when shoot P concentration was extremely low (below 1.1 mg g.sup.-1). In contrast, with increasing shoot P concentration, root morphological responses decreased, but root physiological responses (rhizosphere acidification, acid phosphatase activity and carboxylate exudation in the rhizosphere) were enhanced, and no decrease was noted even at high shoot P concentration (4.0 mg g.sup.-1) corresponding to excess P supply. Conclusions Increasing maize shoot P concentration induced a decrease in root morphological responses and an enhancement in root exudation, with maize response to P deficiency being dependent on root morphological rather than physiological traits. Background and aims Alterations in root growth and rhizosphere processes in maize (Zea mays L.) occur under phosphorus (P) deficiency, but the dynamics of root morphological and physiological modifications with increasing shoot P concentration remain unclear. This study investigated root responses to a wide gradient in shoot P status. Methods A range of maize shoot P concentrations (1.0–4.0 mg g−1) was established using controlled pot experiment with eleven rates of P supply from 0 to 1200 mg P kg−1 soil. Root morphology and rhizosphere processes were characterized 28 days after planting. Results Maize reached maximum biomass at shoot P concentration of 2.7 mg g−1. Root morphological responses (i.e. total root length, specific root length and proportion of fine roots) showed a strong increasing trend with decreasing shoot P concentration (1.1–1.3 mg g−1), but they decreased when shoot P concentration was extremely low (below 1.1 mg g−1). In contrast, with increasing shoot P concentration, root morphological responses decreased, but root physiological responses (rhizosphere acidification, acid phosphatase activity and carboxylate exudation in the rhizosphere) were enhanced, and no decrease was noted even at high shoot P concentration (4.0 mg g−1) corresponding to excess P supply. Conclusions Increasing maize shoot P concentration induced a decrease in root morphological responses and an enhancement in root exudation, with maize response to P deficiency being dependent on root morphological rather than physiological traits. BACKGROUND AND AIMS: Alterations in root growth and rhizosphere processes in maize (Zea mays L.) occur under phosphorus (P) deficiency, but the dynamics of root morphological and physiological modifications with increasing shoot P concentration remain unclear. This study investigated root responses to a wide gradient in shoot P status. METHODS: A range of maize shoot P concentrations (1.0–4.0 mg g⁻¹) was established using controlled pot experiment with eleven rates of P supply from 0 to 1200 mg P kg⁻¹ soil. Root morphology and rhizosphere processes were characterized 28 days after planting. RESULTS: Maize reached maximum biomass at shoot P concentration of 2.7 mg g⁻¹. Root morphological responses (i.e. total root length, specific root length and proportion of fine roots) showed a strong increasing trend with decreasing shoot P concentration (1.1–1.3 mg g⁻¹), but they decreased when shoot P concentration was extremely low (below 1.1 mg g⁻¹). In contrast, with increasing shoot P concentration, root morphological responses decreased, but root physiological responses (rhizosphere acidification, acid phosphatase activity and carboxylate exudation in the rhizosphere) were enhanced, and no decrease was noted even at high shoot P concentration (4.0 mg g⁻¹) corresponding to excess P supply. CONCLUSIONS: Increasing maize shoot P concentration induced a decrease in root morphological responses and an enhancement in root exudation, with maize response to P deficiency being dependent on root morphological rather than physiological traits. Background and aims Alterations in root growth and rhizosphere processes in maize ( Zea mays L.) occur under phosphorus (P) deficiency, but the dynamics of root morphological and physiological modifications with increasing shoot P concentration remain unclear. This study investigated root responses to a wide gradient in shoot P status. Methods A range of maize shoot P concentrations (1.0–4.0 mg g −1 ) was established using controlled pot experiment with eleven rates of P supply from 0 to 1200 mg P kg −1 soil. Root morphology and rhizosphere processes were characterized 28 days after planting. Results Maize reached maximum biomass at shoot P concentration of 2.7 mg g −1 . Root morphological responses (i.e. total root length, specific root length and proportion of fine roots) showed a strong increasing trend with decreasing shoot P concentration (1.1–1.3 mg g −1 ), but they decreased when shoot P concentration was extremely low (below 1.1 mg g −1 ). In contrast, with increasing shoot P concentration, root morphological responses decreased, but root physiological responses (rhizosphere acidification, acid phosphatase activity and carboxylate exudation in the rhizosphere) were enhanced, and no decrease was noted even at high shoot P concentration (4.0 mg g −1 ) corresponding to excess P supply. Conclusions Increasing maize shoot P concentration induced a decrease in root morphological responses and an enhancement in root exudation, with maize response to P deficiency being dependent on root morphological rather than physiological traits.
Audience	Academic
Author	Wen, Zhihui Li, Haigang Shen, Jianbo Rengel, Zed
Author_xml	– sequence: 1 givenname: Zhihui surname: Wen fullname: Wen, Zhihui – sequence: 2 givenname: Haigang surname: Li fullname: Li, Haigang – sequence: 3 givenname: Jianbo surname: Shen fullname: Shen, Jianbo – sequence: 4 givenname: Zed surname: Rengel fullname: Rengel, Zed
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Copyright	Springer Science+Business Media New York 2017 Springer International Publishing Switzerland 2017 COPYRIGHT 2017 Springer Plant and Soil is a copyright of Springer, 2017.
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Keywords	Rhizosphere processes Phosphorus deficiency Root exudation Root growth
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PublicationSubtitle	An International Journal on Plant-Soil Relationships
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Publisher	Springer Springer International Publishing Springer Nature B.V
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Snippet	Background and aims Alterations in root growth and rhizosphere processes in maize (Zea mays L.) occur under phosphorus (P) deficiency, but the dynamics of root... Background and aims Alterations in root growth and rhizosphere processes in maize ( Zea mays L.) occur under phosphorus (P) deficiency, but the dynamics of... Alterations in root growth and rhizosphere processes in maize (Zea mays L.) occur under phosphorus (P) deficiency, but the dynamics of root morphological and... BACKGROUND AND AIMS: Alterations in root growth and rhizosphere processes in maize (Zea mays L.) occur under phosphorus (P) deficiency, but the dynamics of...
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SubjectTerms	Acid phosphatase Acidification Biomass Biomedical and Life Sciences Concentration gradient Corn Ecology Environmental aspects enzyme activity Exudation fine roots Life Sciences Morphology Phosphorus Phosphorus (Nutrient) Physiological aspects physiological response Physiological responses Physiology Plant development Plant growth Plant Physiology Plant Sciences Plant-soil relationships Planting Regular Article Rhizosphere root growth Roots (Botany) soil Soil Science & Conservation Zea mays
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Title	Maize responds to low shoot P concentration by altering root morphology rather than increasing root exudation
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