Individual Versus Combined Effects of Warming, Elevated CO2 and Drought on Grassland Water Uptake and Fine Root Traits.

IF 6 1区 生物学 Q1 PLANT SCIENCES
Maud Tissink, Jesse Radolinski, David Reinthaler, Sarah Venier, Erich M Pötsch, Andreas Schaumberger, Michael Bahn
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Abstract

Increasing warming, atmospheric CO2 and drought are expected to change the water dynamics of terrestrial ecosystems. Yet, limited knowledge exists about how the interactive effects of these factors will affect grassland water uptake, and whether adaptations in fine root production and traits will alter water uptake capacity. In a managed C3 grassland, we tested the individual and combined effects of warming (+3°C), elevated CO2 (eCO2; +300 ppm) and drought on root water uptake (RWU) as well as on fine root production, trait adaptation, and fine root-to-shoot production ratios, and their relationships with RWU capacity. High temperatures, amplified by warming, exacerbated RWU reductions under drought, with negligible water-sparing effects from eCO2. Drought, both under current and future (warming, eCO2) climatic conditions, shifted RWU towards deeper soil layers. Overall, RWU capacity related positively to fine root production and specific root length (SRL), and negatively to mean root diameters. Warming effects on traits (reduced SRL, increased diameter) and the ratio of fine root-to-shoot production (increased) were offset by eCO2. We conclude that under warmer future conditions, irrespective of shifts in water sourcing, it is particularly hot droughts that will lead to increasingly severe restrictions of grassland water dynamics.

气候变暖、二氧化碳升高和干旱对草地吸水率和细根性状的单独影响与综合影响。
气候变暖、大气中二氧化碳含量增加和干旱预计将改变陆地生态系统的水分动态。然而,对于这些因素的相互作用将如何影响草地的吸水能力,以及细根生产和性状的适应是否会改变吸水能力,我们的了解还很有限。在一片管理良好的 C3 草地上,我们测试了升温(+3°C)、二氧化碳升高(eCO2;+300 ppm)和干旱对根系吸水能力(RWU)的单独和综合影响,以及对细根生产、性状适应和细根与根生产比率的影响及其与 RWU 能力的关系。由于气候变暖,高温加剧了干旱条件下根系吸水能力的降低,而二氧化碳对水分的节约作用可以忽略不计。在当前和未来(气候变暖、eCO2)的气候条件下,干旱都会使RWU向更深的土壤层移动。总体而言,RWU 能力与细根产量和特定根长(SRL)呈正相关,与平均根径呈负相关。升温对性状(SRL 减少、直径增加)和细根与根产量之比(增加)的影响被 eCO2 抵消。我们的结论是,在未来气候变暖的条件下,无论水源如何变化,尤其是高温干旱将导致草原水动态受到越来越严重的限制。
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来源期刊
Plant, Cell & Environment
Plant, Cell & Environment 生物-植物科学
CiteScore
13.30
自引率
4.10%
发文量
253
审稿时长
1.8 months
期刊介绍: Plant, Cell & Environment is a premier plant science journal, offering valuable insights into plant responses to their environment. Committed to publishing high-quality theoretical and experimental research, the journal covers a broad spectrum of factors, spanning from molecular to community levels. Researchers exploring various aspects of plant biology, physiology, and ecology contribute to the journal's comprehensive understanding of plant-environment interactions.
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