AUTHOR=Wang Rui , Shi Weiming , Li Yilin 

TITLE=Link Between Aeration in the Rhizosphere and P-Acquisition Strategies: Constructing Efficient Vegetable Root Morphology

JOURNAL=Frontiers in Environmental Science

VOLUME=10

YEAR=2022

URL=https://www.frontiersin.org/journals/environmental-science/articles/10.3389/fenvs.2022.906893

DOI=10.3389/fenvs.2022.906893

ISSN=2296-665X

ABSTRACT=<p>Excessive application of phosphate fertilizer is common in vegetable fields and causes deterioration of the rhizosphere environment, that is, the soil oxygen (O<sub>2</sub>) environment, which further constrains root morphology construction and limits vegetable yield. Nevertheless, the interaction between root morphology and the response of the rhizosphere O<sub>2</sub> environment to vegetable P utilization has rarely been reported. Therefore, we carried out an experiment applying different concentrations of O<sub>2</sub> generator, 10%, 30%, 50%, and 80% urea hydrogen peroxide (as pure nitrogen) instead of urea as a top dressing in the rhizosphere, to study the effect on root morphology and P adsorption, and its mechanism. We found that there were O<sub>2</sub>-deficient and P-deficient zones in the rhizosphere, and oxygenation could alleviate the rhizosphere O<sub>2</sub> and P consumption in roots. The rhizosphere O<sub>2</sub> concentration was maintained at approximately 250.6 μmol L<sup>−1</sup>, which significantly promoted total root length, root volume, average diameter, and root activity by 29.0%, 30.9%, 3.9%, and 111.2%, respectively. Oxygenation promoted organic P mineralization and increased the Olsen-P content in the rhizosphere. The characteristics of root morphology and increased available P in the rhizosphere jointly contributed to high P absorption and utilization, and the P use efficiency was improved by 9.3% and the shoot P accumulation by 10.9% in the 30% urea hydrogen peroxide treatment compared with CK. Moreover, this treatment also improved yield and quality, including vitamin C and the soluble sugar content. However, at a still higher O<sub>2</sub> concentration (260.8 μmol L<sup>−1</sup>), vegetable growth exhibited O<sub>2</sub> damage, resulting in reduced yield and quality. Our study provided new insights into constructing efficient root morphology by regulating the rhizosphere O<sub>2</sub> environment to improve vegetable yield and quality, as well as to increase P use efficiency in vegetable fields.</p>