Localized and Moderate Phosphorus Application Improves Plant Growth and Phosphorus Accumulation in <i>Rosa multiflora</i> Thunb. ex Murr. via Efficient Root System Development

Localized and Moderate Phosphorus Application Improves Plant Growth and Phosphorus Accumulation in <i>Rosa multiflora</i> Thunb. ex Murr. via Efficient Root System Development

Roots have high plasticity with the ability to adapt to heterogeneous nutrient distribution, but little is known about the effects of phosphorus (P) supply methods and levels on <i>Rosa multiflora</i> Thunb. ex Murr. root growth and nutrient accumulation. A pot study was conducted with t...

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Main Authors: Qinghua Ma, Lin Chen, Manyi Du, Yongan Zhang, Yaoxiang Zhang
Format: Article
Language:English
Published: MDPI AG 2020-05-01
Series:Forests
Subjects:
phosphorus
heterogeneous
moderate
nutrient uptake
efficient root systems
Online Access:https://www.mdpi.com/1999-4907/11/5/570
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spelling doaj-d5eada705bab4e339054b6350cc4ca342020-11-25T03:04:06ZengMDPI AGForests1999-49072020-05-011157057010.3390/f11050570Localized and Moderate Phosphorus Application Improves Plant Growth and Phosphorus Accumulation in <i>Rosa multiflora</i> Thunb. ex Murr. via Efficient Root System DevelopmentQinghua Ma0Lin Chen1Manyi Du2Yongan Zhang3Yaoxiang Zhang4Experimental Centre of Forestry in North China, Chinese Academy of Forestry, Beijing 102300, ChinaExperimental Centre of Forestry in North China, Chinese Academy of Forestry, Beijing 102300, ChinaExperimental Centre of Forestry in North China, Chinese Academy of Forestry, Beijing 102300, ChinaExperimental Centre of Forestry in North China, Chinese Academy of Forestry, Beijing 102300, ChinaExperimental Centre of Forestry in North China, Chinese Academy of Forestry, Beijing 102300, ChinaRoots have high plasticity with the ability to adapt to heterogeneous nutrient distribution, but little is known about the effects of phosphorus (P) supply methods and levels on <i>Rosa multiflora</i> Thunb. ex Murr. root growth and nutrient accumulation. A pot study was conducted with two P supply methods (mixed and localized application) and three levels (P-deficient, P-moderate and P-adequate). The results showed that with localized application, P-deficient and P-moderate treatments significantly improved total root length, total surface area, total length of fine roots, shoot DW and total P accumulation in <i>Rosa multiflora</i> compared with their respective mixed application at 45 days after being transplanted (DAT) and 92 DAT; for P-adequate supply, the same trends were observed at 45 DAT, but not at 92 DAT. At 92 DAT, with localized application, when P levels increased from P-deficient to P-moderate, total P accumulation increased by 43.3%; but when P levels increased from P-moderate to P-adequate, no effect was observed. Furthermore, higher P accumulation in leaves was observed in localized P-moderate condition; decreased P uptake per root dry weight and greater root/shoot ratio were observed in localized P-adequate at 92 DAT. Total P accumulation was positively correlated with total root length and root surface area (<i>R<sup>2</sup></i>: 0.68~0.94). There was a significant interaction effect among treatment days, P supply methods and levels (<i>p</i> ≤ 0.05) on shoot DW, root DW, root/shoot ratio and total P accumulation. These findings indicated that localized and moderate P supply appear efficient for improving <i>R. multiflora</i> growth and P accumulation via efficient root system development.https://www.mdpi.com/1999-4907/11/5/570phosphorusheterogeneousmoderatenutrient uptakeefficient root systems
collection DOAJ
language English
format Article
sources DOAJ
author Qinghua Ma
Lin Chen
Manyi Du
Yongan Zhang
Yaoxiang Zhang
spellingShingle Qinghua Ma
Lin Chen
Manyi Du
Yongan Zhang
Yaoxiang Zhang
Localized and Moderate Phosphorus Application Improves Plant Growth and Phosphorus Accumulation in <i>Rosa multiflora</i> Thunb. ex Murr. via Efficient Root System Development
Forests
phosphorus
heterogeneous
moderate
nutrient uptake
efficient root systems
author_facet Qinghua Ma
Lin Chen
Manyi Du
Yongan Zhang
Yaoxiang Zhang
author_sort Qinghua Ma
title Localized and Moderate Phosphorus Application Improves Plant Growth and Phosphorus Accumulation in <i>Rosa multiflora</i> Thunb. ex Murr. via Efficient Root System Development
title_short Localized and Moderate Phosphorus Application Improves Plant Growth and Phosphorus Accumulation in <i>Rosa multiflora</i> Thunb. ex Murr. via Efficient Root System Development
title_full Localized and Moderate Phosphorus Application Improves Plant Growth and Phosphorus Accumulation in <i>Rosa multiflora</i> Thunb. ex Murr. via Efficient Root System Development
title_fullStr Localized and Moderate Phosphorus Application Improves Plant Growth and Phosphorus Accumulation in <i>Rosa multiflora</i> Thunb. ex Murr. via Efficient Root System Development
title_full_unstemmed Localized and Moderate Phosphorus Application Improves Plant Growth and Phosphorus Accumulation in <i>Rosa multiflora</i> Thunb. ex Murr. via Efficient Root System Development
title_sort localized and moderate phosphorus application improves plant growth and phosphorus accumulation in <i>rosa multiflora</i> thunb. ex murr. via efficient root system development
publisher MDPI AG
series Forests
issn 1999-4907
publishDate 2020-05-01
description Roots have high plasticity with the ability to adapt to heterogeneous nutrient distribution, but little is known about the effects of phosphorus (P) supply methods and levels on <i>Rosa multiflora</i> Thunb. ex Murr. root growth and nutrient accumulation. A pot study was conducted with two P supply methods (mixed and localized application) and three levels (P-deficient, P-moderate and P-adequate). The results showed that with localized application, P-deficient and P-moderate treatments significantly improved total root length, total surface area, total length of fine roots, shoot DW and total P accumulation in <i>Rosa multiflora</i> compared with their respective mixed application at 45 days after being transplanted (DAT) and 92 DAT; for P-adequate supply, the same trends were observed at 45 DAT, but not at 92 DAT. At 92 DAT, with localized application, when P levels increased from P-deficient to P-moderate, total P accumulation increased by 43.3%; but when P levels increased from P-moderate to P-adequate, no effect was observed. Furthermore, higher P accumulation in leaves was observed in localized P-moderate condition; decreased P uptake per root dry weight and greater root/shoot ratio were observed in localized P-adequate at 92 DAT. Total P accumulation was positively correlated with total root length and root surface area (<i>R<sup>2</sup></i>: 0.68~0.94). There was a significant interaction effect among treatment days, P supply methods and levels (<i>p</i> ≤ 0.05) on shoot DW, root DW, root/shoot ratio and total P accumulation. These findings indicated that localized and moderate P supply appear efficient for improving <i>R. multiflora</i> growth and P accumulation via efficient root system development.
topic phosphorus
heterogeneous
moderate
nutrient uptake
efficient root systems
url https://www.mdpi.com/1999-4907/11/5/570
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