Effect of twenty four wheat genotypes on soil biochemical and microbial properties

BACKGROUND AND AIMS: Understanding the effect of wheat genotype on soil properties will be crucial in breeding towards more sustainable wheat production and increased yield. We examined the relationships between root traits, soil properties and grain yield for 24 wheat genotypes grown under field co...

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Bibliographic Details
Published in:Plant and soil 2016-07, Vol.404 (1-2), p.141-155
Main Authors: Corneo, Paola E, Haruna Suenaga, Michael A. Kertesz, Feike A. Dijkstra
Format: Article
Language:English
Subjects:
Agricultural soils
Agrology
Bacteria
Biochemistry
Biomass
Biomedical and Life Sciences
carbon
Community structure
Crop production
Crop yield
deoxynivalenol
developmental stages
Ecology
fine roots
Genetic aspects
genetic background
Genotype
Genotype & phenotype
Genotypes
grain yield
Life Sciences
microbial biomass
microbial growth
Nitrogen
Observations
Organic nitrogen
Organic soils
Plant breeding
Plant Physiology
Plant roots
Plant Sciences
Plant-soil relationships
planting
Regular Article
Roots
Soil bacteria
Soil plant interactions
Soil properties
Soil quality
Soil Science & Conservation
Soils
stem elongation
Sustainable production
synthetic populations
total dissolved nitrogen
Triticum
Triticum aestivum
Wheat
Wheat soils
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Summary:BACKGROUND AND AIMS: Understanding the effect of wheat genotype on soil properties will be crucial in breeding towards more sustainable wheat production and increased yield. We examined the relationships between root traits, soil properties and grain yield for 24 wheat genotypes grown under field conditions. METHODS: Wheat genotypes (Triticum spp.) with a range of different genetic backgrounds (varieties, breeding and synthetic lines) were planted in the field in northern NSW, Australia. Specific root length (SRL), root diameter (RD) and the proportion of root length in different diameter classes were characterized at the stem elongation growth stage. Soil microbial biomass carbon (MBC) and nitrogen (MBN), total dissolved nitrogen (TDN), organic nitrogen (DON), inorganic nitrogen (DIN), and soil bacterial community structure were measured. RESULTS: A significant wheat genotype effect was found for SRL, proportion of coarse roots (1-2 mm), MBN, MBC/MBN, TDN, and DIN. Genotypes with more fine roots generally had lower TDN, DIN and DON, higher MBN, and lower grain yield. We observed no wheat genotype effect on the structure and diversity of the soil bacterial community. CONCLUSIONS: Long, thin wheat roots may promote microbial growth and N immobilisation, negatively affecting grain yield. We suggest that SRL, MBN and inorganic N should be considered by plant breeding schemes.
ISSN:0032-079X
1573-5036
DOI:10.1007/s11104-016-2833-1