生根深度和比叶面积改变了实验干旱持续时间对温带草原物种的影响

IF 5.3 1区环境科学与生态学 Q1 ECOLOGY

Journal of Ecology Pub Date : 2025-01-11 DOI:10.1111/1365-2745.14468

Yvonne Künzi, Michaela Zeiter, Markus Fischer, Andreas Stampfli

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引用次数: 0

摘要

由于气候变化，温带草原正面临日益严重的干旱。与此同时，土地利用集约化通过促进生长迅速、资源获取性强、比叶面积（SLA）高的物种，正在改变草地的功能组成。SLA如何影响草地物种抵抗和从日益严重的干旱中恢复的能力，以及深根是否改善了它们的干旱性能尚不清楚。为了研究这一点，我们建立了一个普通花园的田间试验，包括温带草地物种，SLAs为17.9-39.3 mm2 g−1，最大生根深度为16-252 cm。1.5年后，我们分别模拟了0、79、134、177和220天的干旱。干旱对植物性能的影响随着干旱时间的延长而增加，在所考虑的32种植物中，绿色组织的存活率和年生物量降低了50%。由于植物有效水分在所有处理结束时仍保留在深层土壤中，深根减轻了干旱后期干旱时间增加对生产力的负面影响，并在较长干旱后有利于生产力。16种禾草类植物的低到高的SLA特征梯度似乎代表了从耐脱水到避免脱水的不同生存策略，而不是干旱敏感性。沿着植物的SLA梯度变化的干旱响应意味着多种其他性状与进化上遥远的物种的抗旱性有关。合成。我们的研究结果表明，当植物有效水分在浅层土壤中缺乏而在深层土壤中保留时，深根对温带草地物种长期无降雨是有益的。因此，面对日益严重的干旱，我们建议(1)在集约化草地上培育深根物种，并在肥沃的土壤上培育深根物种；(2)指导进一步的研究，以确定在半自然草地上支持深根的管理实践。

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Rooting depth and specific leaf area modify the impact of experimental drought duration on temperate grassland species

Due to climate change, temperate grasslands are being exposed to increasingly severe droughts. Concurrently, land‐use intensification is altering grasslands' functional composition by promoting fast‐growing, resource‐acquisitive species with high specific leaf area (SLA).

How SLA affects the ability of grassland species to resist and recover from increasingly severe droughts and if deep roots improve their drought performance remains unclear. To investigate this, we established a common‐garden field experiment including temperate grassland species with SLAs of 17.9–39.3 mm2 g−1 and maximal rooting depths of 16–252 cm. After 1.5 years, we simulated droughts for 0, 79, 134, 177 and 220 days.

Drought effects on plant performance increased with drought length, reducing the survival of green tissue and annual biomass by up to ~50% across all 32 species considered. As plant‐available water remained in deep soil layers by the end of all treatments, deep roots mitigated the negative effect of increasing drought length on productivity in the later stage of drought and favoured productivity after a longer drought. The low‐to‐high SLA trait gradient among the 16 graminoid species seemed to represent alternative survival strategies ranging from dehydration tolerance to dehydration avoidance, rather than drought sensitivity. Variable drought responses along the SLA gradient of forbs imply that multiple other traits are related to drought resistance across evolutionarily distant species.

Synthesis. Our results suggest that deep roots are beneficial for temperate grassland species subjected to longer periods without rainfall when plant‐available water is lacking in shallow soil layers but remaining in deep soil layers. In the face of increasing drought severity, we thus recommend (1) fostering deep‐rooted species in intensive grasslands on deep, productive soil and (2) directing further studies towards identifying management practices that support deep rooting in semi‐natural grasslands.

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来源期刊

Journal of Ecology 环境科学-生态学

CiteScore

10.90

自引率

5.50%

发文量

207

审稿时长

3.0 months

期刊介绍： Journal of Ecology publishes original research papers on all aspects of the ecology of plants (including algae), in both aquatic and terrestrial ecosystems. We do not publish papers concerned solely with cultivated plants and agricultural ecosystems. Studies of plant communities, populations or individual species are accepted, as well as studies of the interactions between plants and animals, fungi or bacteria, providing they focus on the ecology of the plants. We aim to bring important work using any ecological approach (including molecular techniques) to a wide international audience and therefore only publish papers with strong and ecological messages that advance our understanding of ecological principles.