Clea N. van de Ven, Tjisse van der Heide, Tjeerd J. Bouma, Lennart van Ijzerloo, Djeli D. Lindhout, Valérie C. Reijers
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引用次数: 0
Abstract
Coastal vegetated ecosystems including mangroves, seagrasses, and salt marshes are often shaped by positive plant–environment feedbacks. Plants improve their own living conditions with increasing patch size and density by attenuating hydrodynamics and stabilizing sediments. As these habitat modifications are critical for survival and growth, the positive density‐dependent nature of these feedbacks can lead to establishment thresholds for young plants in absence of mature conspecifics. Although feedback strength is known to depend on hydrodynamic exposure and plant traits (e.g. stiff versus flexible stems), it remains unclear how 1) opposing morphological plant traits affect establishment in contrasting environments, and 2) whether trait plasticity influences establishment success. Here, we investigate this by transplanting two tidal species with opposing growing strategies – Spartina anglica forms tussocks of stiff stems while Zostera noltii forms patches of stress‐avoiding flexible shoots – from two different donor sites in eight experimental locations. Results show that the survival and growth of both species was most successful at field locations with diverging environmental characteristics, while overall survival was highest for Z. noltii. Mainly, S. anglica survival was highest at locations with high organic matter and silt content and higher elevation relative to the tidal amplitude. In contrast, Z. noltii survival was highest at locations with larger grainsize and lower relative elevations. Furthermore, despite initial differences in plant traits between the two donor sites of Z. noltii, we found no effects of donor origin. Contrastingly, we found a significant effect of donor origin on S. anglica growth, even though transplants from the two donor sites showed no initial trait differences. Collectively, these results suggest that the stress‐tolerance strategy of S. anglica hampers establishment in exposed conditions, whereas the stress‐avoiding Z. noltii appears to be more susceptible to stress from desiccation and silty sediments.
包括红树林、海草和盐沼在内的沿海植被生态系统通常是由植物-环境正反馈形成的。随着斑块面积和密度的增加,植物通过减弱水动力和稳定沉积物来改善自身的生存条件。由于这些生境的改变对植物的生存和生长至关重要,因此这些正反馈的密度依赖性会导致幼苗在没有成熟同种植物的情况下达到建群阈值。尽管已知反馈强度取决于水动力暴露和植物性状(如硬茎与柔茎),但目前仍不清楚:1)植物的相反形态性状如何影响对比环境中的建群;2)性状可塑性是否影响建群成功率。在此,我们通过将两种生长策略截然相反的潮汐物种--Spartina anglica(形成硬茎草丛)和 Zostera noltii(形成可规避压力的柔性芽块)--从两个不同的供体地点移植到八个实验地点,对此进行了研究。结果表明,在环境特征不同的野外地点,这两个物种的存活和生长都最为成功,而 noltii 的总体存活率最高。主要是在有机物和淤泥含量高、海拔高度相对于潮汐涨落幅度较高的地点,S. anglica 的存活率最高。与此相反,在粒径较大、相对海拔较低的地点,糯稻的存活率最高。此外,尽管诺尔特藻类在两个供体地点的植物性状存在初步差异,但我们没有发现供体来源的影响。与此形成鲜明对比的是,我们发现供体来源对 S. anglica 的生长有显著影响,尽管来自两个供体地点的移栽植物没有表现出初始性状差异。总之,这些结果表明,S. anglica的耐压策略会阻碍其在暴露条件下的生长,而避免应激的Z. noltii似乎更容易受到干燥和淤泥的应激。
期刊介绍:
Oikos publishes original and innovative research on all aspects of ecology, defined as organism-environment interactions at various spatiotemporal scales, so including macroecology and evolutionary ecology. Emphasis is on theoretical and empirical work aimed at generalization and synthesis across taxa, systems and ecological disciplines. Papers can contribute to new developments in ecology by reporting novel theory or critical empirical results, and "synthesis" can include developing new theory, tests of general hypotheses, or bringing together established or emerging areas of ecology. Confirming or extending the established literature, by for example showing results that are novel for a new taxon, or purely applied research, is given low priority.