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Understanding interaction effect of arbuscular mycorrhizal fungi in rice under elevated carbon dioxide conditions.

Identifieur interne : 000286 ( Main/Exploration ); précédent : 000285; suivant : 000287

Understanding interaction effect of arbuscular mycorrhizal fungi in rice under elevated carbon dioxide conditions.

Auteurs : Periyasamy Panneerselvam [Inde] ; Sowarnalisha Sahoo [Inde] ; Ansuman Senapati [Inde] ; Upendra Kumar [Inde] ; Debasis Mitra [Inde] ; Chidambaranathan Parameswaran [Inde] ; Annamalai Anandan [Inde] ; Anjani Kumar [Inde] ; Afrin Jahan [Inde] ; Amaresh Kumar Nayak [Inde]

Source :

RBID : pubmed:31613012

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English descriptors

Abstract

Arbuscular mycorrhizal fungi (AMF), particularly the Glomerales group, play a paramount role in plant nutrient uptake, and abiotic and biotic stress management in rice, but recent evidence revealed that elevated CO2 concentration considerably reduces the Glomerales group in soil. In view of this, the present study was initiated to understand the interaction effect of native Glomerales species application in rice plants (cv. Naveen) under elevated CO2 concentrations (400 ± 10, 550 ± 20, and 700 ± 20 ppm) in open-top chambers. Three different modes of application of the AMF inoculum were evaluated, of which, combined application of AMF at the seedling production and transplanting stages showed increased AMF colonization, which significantly improved grain yield by 25.08% and also increased uptake of phosphorus by 18.2% and nitrogen by 49.5%, as observed at 700-ppm CO2 concentration. Organic acids secretion in rice root increased in AMF-inoculated plants exposed to 700-ppm CO2 concentration. To understand the overall effect of CO2 elevation on AMF interaction with the rice plant, principal component and partial least square regression analysis were performed, which found both positive and negative responses under elevated CO2 concentration.

DOI: 10.1002/jobm.201900294
PubMed: 31613012


Affiliations:

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Le document en format XML

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<div type="abstract" xml:lang="en">Arbuscular mycorrhizal fungi (AMF), particularly the Glomerales group, play a paramount role in plant nutrient uptake, and abiotic and biotic stress management in rice, but recent evidence revealed that elevated CO
<sub>2</sub>
concentration considerably reduces the Glomerales group in soil. In view of this, the present study was initiated to understand the interaction effect of native Glomerales species application in rice plants (cv. Naveen) under elevated CO
<sub>2</sub>
concentrations (400 ± 10, 550 ± 20, and 700 ± 20 ppm) in open-top chambers. Three different modes of application of the AMF inoculum were evaluated, of which, combined application of AMF at the seedling production and transplanting stages showed increased AMF colonization, which significantly improved grain yield by 25.08% and also increased uptake of phosphorus by 18.2% and nitrogen by 49.5%, as observed at 700-ppm CO
<sub>2</sub>
concentration. Organic acids secretion in rice root increased in AMF-inoculated plants exposed to 700-ppm CO
<sub>2</sub>
concentration. To understand the overall effect of CO
<sub>2</sub>
elevation on AMF interaction with the rice plant, principal component and partial least square regression analysis were performed, which found both positive and negative responses under elevated CO
<sub>2</sub>
concentration.</div>
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concentration considerably reduces the Glomerales group in soil. In view of this, the present study was initiated to understand the interaction effect of native Glomerales species application in rice plants (cv. Naveen) under elevated CO
<sub>2</sub>
concentrations (400 ± 10, 550 ± 20, and 700 ± 20 ppm) in open-top chambers. Three different modes of application of the AMF inoculum were evaluated, of which, combined application of AMF at the seedling production and transplanting stages showed increased AMF colonization, which significantly improved grain yield by 25.08% and also increased uptake of phosphorus by 18.2% and nitrogen by 49.5%, as observed at 700-ppm CO
<sub>2</sub>
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<sub>2</sub>
concentration. To understand the overall effect of CO
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<sub>2</sub>
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