Abstract
Wheat (Triticum aestivum L.) grain quality is determined by multiple physical and chemical attributes. However, previous studies mainly focused on protein quantity and composition, which may not be adequate for understanding grain quality, especially end-use quality. Field experiments were conducted at two locations for two years to better understand how and to what extent water and nitrogen (N) availability affect flour end-use quality. Four drought stress levels (i.e., mild, moderate, severe, and well-watered) and four N rates (i.e., zero, low, medium, and high) were applied to two spring wheat cultivars (i.e., Dayn and Egan). Evaluated end-use quality traits, including milling quality, mixograph parameters, flour protein and gluten contents, solvent retention capacity (SRC), and baking quality. Most end-use quality parameters were not significantly different between the well-watered treatment and mild drought stress in both cultivars. Nitrogen availability above the low rate (168 kg N ha−1) failed to further improve most end-use quality traits in either cultivar. Among all the end-use quality traits, lactic acid SRC may be a reliable indicator of flour end-use quality. These results indicate that mild drought stress (i.e., a 25% reduction in irrigation throughout the growing season) may not negatively affect end-use quality and excessive N fertilization offers minimal improvement in end-use quality. Such information could facilitate the development of irrigation and fertilization guidelines targeting at grain quality.
Highlights
Wheat (Triticum aestivum L.) is one of the most important food crops worldwide [1]
For better understanding of the effects of water and N availability on grain quality, we examined two spring wheat cultivars in response to different drought stress levels and N application rates and analyzed the relationships between grain quality parameters in two environments in the Northwestern U.S
The current study indicates that Egan carrying the Gpc-B1 gene, is able to produce high protein (15.5–15.7%) at various water regimes, which surpasses the premium market quality of grain protein content for hard red spring wheat (i.e., 14%) in the U.S
Summary
Due to the distinctive viscoelastic properties of the dough, wheat has been utilized for various food products such as bread, cookies, cakes, and noodles, consisting of approximately 20% of calories and proteins in the human diet [2,3]. Both optimum grain yield and consistent quality should be achieved to meet the food demand. Wheat grain quality is mainly determined by endosperm texture (i.e., grain hardness), protein content, and gluten strength [4], which are affected by genetics and environment, as well as their. It has been widely reported that grain protein content increases under drought stress [15,20,21,22]; responses of gluten-related parameters to reduced water availability are not consistent among previous studies
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