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Enabling Biological Nitrogen Fixation for Cereal Crops in Fertilized Fields.

Authors :
Wen A
Havens KL
Bloch SE
Shah N
Higgins DA
Davis-Richardson AG
Sharon J
Rezaei F
Mohiti-Asli M
Johnson A
Abud G
Ane JM
Maeda J
Infante V
Gottlieb SS
Lorigan JG
Williams L
Horton A
McKellar M
Soriano D
Caron Z
Elzinga H
Graham A
Clark R
Mak SM
Stupin L
Robinson A
Hubbard N
Broglie R
Tamsir A
Temme K
Source :
ACS synthetic biology [ACS Synth Biol] 2021 Dec 17; Vol. 10 (12), pp. 3264-3277. Date of Electronic Publication: 2021 Dec 01.
Publication Year :
2021

Abstract

Agricultural productivity relies on synthetic nitrogen fertilizers, yet half of that reactive nitrogen is lost to the environment. There is an urgent need for alternative nitrogen solutions to reduce the water pollution, ozone depletion, atmospheric particulate formation, and global greenhouse gas emissions associated with synthetic nitrogen fertilizer use. One such solution is biological nitrogen fixation (BNF), a component of the complex natural nitrogen cycle. BNF application to commercial agriculture is currently limited by fertilizer use and plant type. This paper describes the identification, development, and deployment of the first microbial product optimized using synthetic biology tools to enable BNF for corn ( Zea mays ) in fertilized fields, demonstrating the successful, safe commercialization of root-associated diazotrophs and realizing the potential of BNF to replace and reduce synthetic nitrogen fertilizer use in production agriculture. Derived from a wild nitrogen-fixing microbe isolated from agricultural soils, Klebsiella variicola 137-1036 ("Kv137-1036") retains the capacity of the parent strain to colonize corn roots while increasing nitrogen fixation activity 122-fold in nitrogen-rich environments. This technical milestone was then commercialized in less than half of the time of a traditional biological product, with robust biosafety evaluations and product formulations contributing to consumer confidence and ease of use. Tested in multi-year, multi-site field trial experiments throughout the U.S. Corn Belt, fields grown with Kv137-1036 exhibited both higher yields (0.35 ± 0.092 t/ha ± SE or 5.2 ± 1.4 bushels/acre ± SE) and reduced within-field yield variance by 25% in 2018 and 8% in 2019 compared to fields fertilized with synthetic nitrogen fertilizers alone. These results demonstrate the capacity of a broad-acre BNF product to fix nitrogen for corn in field conditions with reliable agronomic benefits.

Details

Language :
English
ISSN :
2161-5063
Volume :
10
Issue :
12
Database :
MEDLINE
Journal :
ACS synthetic biology
Publication Type :
Academic Journal
Accession number :
34851109
Full Text :
https://doi.org/10.1021/acssynbio.1c00049