Managing dryland wheat to produce high-quality grain

Managing dryland wheat to produce high-quality grain

The properties of individual grain weight, protein concentration and protein composition contribute to grain quality of wheat. They are known to be affected by genetics, environment and crop management. This paper reports these properties in two dryland field experiments comparing cultivars with sim...

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Bibliographic Details
Published in:Field crops research Vol. 280; p. 108473
Main Authors: Larroque, O.R., Calderini, D.F., Angus, J.F.
Format: Journal Article
Language:English
Published: Elsevier B.V 01-05-2022
Subjects:
Glutenin
Grain protein
Grain weight
Screenings
Spikes
UPP
Spikes
HMW
UPP
GLMM
Grain protein
Grain weight
Screenings
A+G
Glutenin
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Summary:The properties of individual grain weight, protein concentration and protein composition contribute to grain quality of wheat. They are known to be affected by genetics, environment and crop management. This paper reports these properties in two dryland field experiments comparing cultivars with similar yield but with contrasting grain weight and number. A large-seeded cultivar, Baviacora, and a small-seeded cultivar, H45, were managed with different nitrogen (N) fertilizer applications and grown in seasons with different rainfall. The aim is to suggest strategies to produce wheat grain of consistently high quality for specified markets, with either pre-harvest or post-harvest management. Individual grain weight and protein concentration varied throughout the spikes of the cultivars and responded to crop management and environment. Protein concentration within a spike was closely correlated with individual grain weight, increasing by 0.05 ± 0.006% per mg of additional grain weight, independent of cultivar or position of grains on the spike. Grain protein composition was related to protein concentration of individual grains but was not as sensitive to individual grain weight. Larger grains were associated with less glutenin per unit of protein, partly offsetting the increase in protein concentration with grain weight. Unextracted polymeric protein (%UPP) was unrelated to grain weight but was negatively related to grain protein concentration in Baviacora. If found to be general, the within-spike relationships between individual grain weight, and the concentrations of grain protein, glutenin and %UPP offer promise for improving grain segregation and post-harvest processing to produce grain of closely defined quality from an unprocessed harvest sample. •Grain protein amount and composition varied with genotype, environment and management.•Within spikes, protein concentration was positively correlated with grain weight.•Glutenin concentration varied with protein concentration of individual grains.
ISSN:0378-4290
1872-6852
DOI:10.1016/j.fcr.2022.108473