Univ Lyon, Université Claude Bernard Lyon 1, CNRS, ENTPE, UMR 5023 LEHNA, F-69622 Villeurbanne, France.
Univ Lyon, Université Claude Bernard Lyon 1, CNRS, ENTPE, UMR 5023 LEHNA, F-69622 Villeurbanne, France.
Sci Total Environ. 2021 Jun 15;773:145061. doi: 10.1016/j.scitotenv.2021.145061. Epub 2021 Feb 4.
Few studies have addressed how the diversity of basal resources change with stream regulation and the potential consequences on river biota. We sampled invertebrates above and below a series of dams, over two years, at both downwelling and upwelling zones. In each zone, we recorded the daily temperature and flow variations, estimated the algal development, measured the available resources, and analysed carbon and nitrogen stable isotope compositions of the invertebrate community. The number of hydrological pulses were typically higher below the dams than above the dams especially during high-flow periods whereas the groundwater outlets had minor effects on invertebrate assemblages. Invertebrate abundance, richness and diversity tended to decrease below the dams. Co-inertia analysis showed that flow and temperature variations, and eutrophication explained most of the variance in the invertebrate assemblages, which comprised a higher number of resilient taxa below than above the dams. The proportions of pesticide-sensitive invertebrates were lower below the dams and ovoviviparous and more generalist taxa were prominent. We did not observe the expected CPOM decrease and FPOM increase downstream. Accordingly, the proportions of each functional feeding group were remarkably similar above and below the dams despite the long distance between the sectors (>100 kms). The diversity of basal resources used within assemblages progressively increased downstream above dams. In contrast, the diversity of resources used by organisms below the dams decreased from upstream to downstream suggesting a significant influence of flow regulation on aquatic food webs. Finally, the shorter trophic chains for the invertebrate assemblages below the dams suggests that the effects of stream regulation and eutrophication induced a simplification of food webs. To our knowledge, this study is the first to connect taxonomic and functional trait changes in response to multiple stressors with the associated modifications in isotopic niches within aquatic invertebrate assemblages.
Understanding how stream regulation and associated anthropogenic pressures act on aquatic assemblages and trophic niches is necessary to guide management actions.
We aimed to investigate the functional responses (traits and trophic niches) of aquatic invertebrate assemblages to stream regulation and eutrophication.
We used univariate and multivariate analyses to compare the invertebrate assemblages above and below the dams and to assess the contributions of hydrology (including groundwater supplies to the river), temperature and eutrophication to the variability in the composition of invertebrate assemblages. We also considered the relative utilization of a selected set of traits describing invertebrate resilience, resistance and specialization to address the potential functional effects of stream regulation on invertebrate assemblages. Finally, carbon and nitrogen isotope analyses allowed us to characterize the length and width of invertebrate assemblage food webs as related to the availability and diversity of basal resources.
Invertebrate abundance and richness generally decreased below the dams, with the highest impacts on insect taxa. Co-inertia analysis showed that stream regulation and eutrophication were main drivers of the aquatic invertebrate assemblages. The analysis separated the sites above and below the dams according to flow and temperature variation, whereas eutrophication appeared as a secondary stressor that separated the sites within each sector. Furthermore, the series of dams resulted in (i) a higher proportion of resilient (e.g., multivoltine) and resistant (ovoviviparous) taxa and a majority of generalists in assemblages below dams, (ii) an impact on the classical dynamics of CPOM (decrease) and FPOM (increase) sources from upstream to downstream, and (iii) a reduction in the diversity of resource use and in the trophic chain length of invertebrate assemblages below dams. The cooler and less oxygenated upwelling zones had lower invertebrate abundance; however, contrary to our expectation, the variation in the groundwater supply did not affect the composition of epigean invertebrate assemblages.
This study provides insights about the impacts of flow regime alteration and eutrophication on food webs that may have been caused by regulation of permanent streams. To our knowledge, this is the first to connect taxonomic and functional trait changes in response to multiple stressors with the associated modifications in energy fluxes in aquatic invertebrate assemblages. This study suggests that bed stability, which is associated with a reduction in channel mobility below the dams and with moderate eutrophication, may provide the shelter and resources that can locally favour invertebrate assemblage dynamics and lessen the effects of flow regulation. In addition, the study suggests that the biological trait-based approach and isotope analysis are complementary approaches for addressing ecosystem functioning. The relative utilization of traits indicates the functional potential of aquatic invertebrate assemblages to face multiple stressors whereas isotope analysis is an expression of the actual effect of the stressors on the trophic structure of aquatic invertebrate assemblages.
很少有研究探讨基础资源多样性如何随河流调节而变化,以及这对河流生物群可能产生的潜在影响。我们在两个不同年份,在一系列大坝的上下游,以及上升流区和下降流区,采集了无脊椎动物样本。在每个区域,我们记录了每日温度和流量变化,估计了藻类的发育情况,测量了可用资源,并分析了无脊椎动物群落的碳和氮稳定同位素组成。下游的水文脉冲数量通常高于上游,尤其是在高流量期,而地下水出口对无脊椎动物群落的影响较小。无脊椎动物的丰度、丰富度和多样性往往在大坝下游减少。共协方差分析表明,流量和温度变化以及富营养化解释了无脊椎动物群落的大部分变化,这表明大坝下游的抗逆性更强。下游的杀虫剂敏感无脊椎动物比例较低,卵胎生和更普遍的类群更为突出。我们没有观察到预期的 CPOM 减少和 FPOM 增加。因此,尽管上下游之间的距离超过 100 公里,但各功能摄食群的比例在大坝上下游之间非常相似。无脊椎动物群落中使用的基础资源的多样性逐渐增加。相反,大坝下游的资源利用多样性从上游到下游减少,这表明流量调节对水生食物网有显著影响。最后,大坝下游无脊椎动物群落的营养链较短,表明河流调节和富营养化的影响导致食物网的简化。据我们所知,这项研究首次将对多种胁迫因素的分类和功能特征变化与水生无脊椎动物群落中同位素生态位的相关变化联系起来。
了解河流调节和相关人为压力如何作用于水生集合体和营养位对于指导管理行动是必要的。
我们旨在研究水生无脊椎动物集合体对河流调节和富营养化的功能反应(特征和营养位)。
我们使用单变量和多变量分析来比较大坝上下游的无脊椎动物集合体,并评估水文(包括地下水对河流的供应)、温度和富营养化对无脊椎动物集合体组成变化的贡献。我们还考虑了一系列描述无脊椎动物抗逆性、抵抗力和专业化的特征的相对利用,以解决河流调节对无脊椎动物集合体的潜在功能影响。最后,碳和氮同位素分析允许我们描述无脊椎动物集合体食物网的长度和宽度,这与基础资源的可利用性和多样性有关。
无脊椎动物的丰度和丰富度普遍在大坝下游减少,对昆虫类群的影响最大。共协方差分析表明,河流调节和富营养化是水生无脊椎动物集合体的主要驱动因素。分析根据流量和温度变化将站点分开,而富营养化似乎是第二个压力因素,将每个区域内的站点分开。此外,一系列大坝导致(i)更具弹性(例如,多化性)和抗性(卵胎生)的类群和大多数无脊椎动物的类群在大坝下游的集合体中更普遍,(ii)从上游到下游经典 CPOM(减少)和 FPOM(增加)源的变化,以及(iii)无脊椎动物集合体的资源利用多样性和营养链长度减少。上升流区较冷、含氧量较低,无脊椎动物的丰度较低;然而,与我们的预期相反,地下水供应的变化并没有影响到地上无脊椎动物集合体的组成。
本研究提供了关于流量变化和富营养化对食物网的影响的见解,这些影响可能是由于永久性河流的调节造成的。据我们所知,这是首次将对多种胁迫因素的分类和功能特征变化与水生无脊椎动物集合体中能量通量的相关变化联系起来。本研究表明,床的稳定性,与大坝下游的渠道移动性降低以及中度富营养化有关,可能为无脊椎动物集合体的动态提供庇护和资源,并减轻流量调节的影响。此外,该研究表明,生物特征为基础的方法和同位素分析是解决生态系统功能的互补方法。特征的相对利用表明了水生无脊椎动物集合体面对多种压力因素的功能潜力,而同位素分析则是压力因素对水生无脊椎动物集合体的营养结构的实际影响的表现。
