Variable water cycles have a greater impact on wheat growth and soil nitrogen response than constant watering

Variable water cycles have a greater impact on wheat growth and soil nitrogen response than constant watering

•Wheat variety Gladius was more responsive to nitrogen (N) than to the water treatments imposed.•Low N negatively affected plant growth.•The Reduced water treatment encouraged plant growth with medium and high N.•Plants were not well adapted to variable watering (Wet/Dry cycling).•Larger root growth...

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Bibliographic Details
Published in:Plant science (Limerick) Vol. 290; p. 110146
Main Authors: Cousins, Olivia H., Garnett, Trevor P., Rasmussen, Amanda, Mooney, Sacha J., Smernik, Ronald J., Brien, Chris J., Cavagnaro, Timothy R.
Format: Journal Article
Language:English
Published: Ireland Elsevier B.V 01-01-2020
Subjects:
Bacteria - metabolism
Biomass
Biomass allocation
Carbon - analysis
Nitrogen - analysis
Nitrogen stress
Roots
Soil - chemistry
Soil Microbiology
Triticum - growth & development
Triticum - metabolism
Triticum aestivum
variable water
Water Cycle
Water use efficiency
Nitrogen stress
variable water
Biomass allocation
Water use efficiency
Roots
Triticum aestivum
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Summary:•Wheat variety Gladius was more responsive to nitrogen (N) than to the water treatments imposed.•Low N negatively affected plant growth.•The Reduced water treatment encouraged plant growth with medium and high N.•Plants were not well adapted to variable watering (Wet/Dry cycling).•Larger root growth was found under Reduced water and medium or high N treatments. Current climate change models project that water availability will become more erratic in the future. With soil nitrogen (N) supply coupled to water availability, it is important to understand the combined effects of variable water and N supply on food crop plants (above- and below-ground). Here we present a study that precisely controls soil moisture and compares stable soil moisture contents with a controlled wetting-drying cycle. Our aim was to identify how changes in soil moisture and N concentration affect shoot-root biomass, N acquisition in wheat, and soil N cycling. Using a novel gravimetric platform allowing fine-scale control of soil moisture dynamics, a 3 × 3 factorial experiment was conducted on wheat plants subjected to three rates of N application (0, 25 and 75 mg N/kg soil) and three soil moisture regimes (two uniform treatments: 23.5 and 13% gravimetric moisture content (herein referred to as Well-watered and Reduced water, respectively), and a Variable treatment which cycled between the two). Plant biomass, soil N and microbial biomass carbon were measured at three developmental stages: tillering (Harvest 1), flowering (Harvest 2), and early grain milk development (Harvest 3). Reduced water supply encouraged root growth when combined with medium and high N. Plant growth was more responsive to N than the water treatments imposed, with a 15-fold increase in biomass between the high and no added N treatment plants. Both uniform soil water treatments resulted in similar plant biomass, while the Variable water treatment resulted in less biomass overall, suggesting wheat prefers consistency whether at a Well-watered or Reduced water level. Plants did not respond well to variable soil moisture, highlighting the need to understand plant adaptation and biomass allocation with resource limitation. This is particularly relevant to developing irrigation practices, but also in the design of water availability experiments.
ISSN:0168-9452
1873-2259
DOI:10.1016/j.plantsci.2019.05.009