河岸带土地利用驱动下受生态补水河流鱼类多样性格局

刘晗; 李鲁丹; 郭伟杰; 乔强龙; 贡丹丹; 杜琦; 李航; 赵伟华

doi:10.11988/ckyyb.20240686

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长江科学院院报 ›› 2025, Vol. 42 ›› Issue (8) : 198-207. DOI: 10.11988/ckyyb.20240686

重大引调水工程基础理论与关键技术研究专栏

河岸带土地利用驱动下受生态补水河流鱼类多样性格局

刘晗 ¹^,² ,
李鲁丹 ¹^,² ,
郭伟杰 ¹^,² ,
乔强龙 ¹^,² ,
贡丹丹 ¹^,² ,
杜琦 ¹^,² ,
李航 ¹^,² ,
赵伟华 ¹^,²

作者信息 +

Fish Diversity Patterns in Rivers Receiving Ecological Water Supplement Driven by Riparian Land Use

LIU Han ¹^,² ,
LI Lu-dan ¹^,² ,
GUO Wei-jie ¹^,² ,
QIAO Qiang-long ¹^,² ,
GONG Dan-dan ¹^,² ,
DU Qi ¹^,² ,
LI Hang ¹^,² ,
ZHAO Wei-hua ¹^,²

Author information +

文章历史 +

摘要

为探究华北地区受生态补水河流鱼类群落多样性的环境驱动机制,于2020—2022年生态补水期间以2个受补水水系(子牙河水系、白洋淀水系)为研究区域,使用多元统计方法比较不同生态补水年度间鱼类群落及多样性的差异,并探讨了驱动鱼类多样性变异的关键河岸带土地利用因子。结果显示:华北地区受生态补水河流中鱼类物种数与多样性指数无显著变化,鱼类种类组成发生了显著的变化,喜流水型、清洁型的鱼类种群占比逐年上升;鱼类群落格局与3个维度的多样性指数年际变化均不显著;多元回归线性模型分析结果显示建筑用地的增加对鱼类多样性产生了显著的负面影响,而湿地、草地和水域面积占比则与鱼类多样性呈显著正相关;不同缓冲区大小内土地利用类型对鱼类多样性指数的解释率存在差异。研究成果有助于理解鱼类多样性对受生态补水河流沿岸带不同土地利用类型的响应特征,为受补水河流制定有效生态保护和管理提供科学依据。

Abstract

[Objectives] This study aims to: (1) elucidate the spatiotemporal dynamics of fish communities and multi-dimensional diversity (species, functional, taxonomic) in ecological water supplement rivers of North China; and (2) determine the mechanistic effects of riparian land use across varying buffer sizes (0.5 km, 1 km, 2 km, 5 km) on these diversity patterns. The research focused on two major water-supplemented systems—the Ziya River Basin and Baiyangdian Lake Basin—during the ecological water supplement period from 2020 to 2022. [Methods] Field surveys were conducted annually during the water supplement period. Fishes were collected using standardized multi-mesh gillnets and traps, identified to species level, and quantified for abundance and biomass. Species functional traits (feeding, locomotion, predator avoidance, trophic level, reproduction) were compiled following Villéger et al., primarily sourced from FishBase and literature. Taxonomic diversity metrics were calculated based on Linnaean hierarchies (species to class). Riparian land use types (built area, wetland, trees, crop, water, bare ground, and rangeland) within four buffer zones (0.5 km, 1 km, 2 km, 5 km) were extracted from ESRI’s global 10-m resolution land cover data. Statistical analyses included: Analysis of Variance (ANOVA) and Permutational Multivariate Analysis of Variance (PERMANOVA) to test interannual differences; Non-metric Multidimensional Scaling (NMDS) to visualize community structure; Pearson correlation analysis to examine relationships among diversity indices; and Multiple Linear Regression (MLR) models to quantify the driving effects of riparian land use on fish diversity. [Results] A total of 2,720 fish individuals, belonging to 40 species, 12 families across 6 orders, were recorded during the three-year field survey. Species richness (26 species in 2020, 27 in 2021, 26 in 2022; ANOVA, p>0.05) and diversity indices (Shannon, Margalef, Pielou) showed no significant interannual changes. However, significant shifts in species composition were observed: rheophilic, clean-water indicator species (e.g., Opsariichthys bidens, Zacco platypus) increased in relative abundance from 7.3% (2020) to 12.6% (2022), while pollution-tolerant generalists (e.g., Carassius auratus) remained dominant but declined from 22.38% to 17.14%. NMDS and PERMANOVA confirmed no significant interannual differences in overall community structure. Multi-dimensional diversity indices (functional:FRic,FDiv,FDis,FEve;taxonomic: Delta, Delta*, Delta+, Lambda+) also exhibited no significant temporal trends. Pearson correlations revealed strong positive relationships among species diversity indices (e.g., Richness vs. Shannon: r=0.91) and showed that functional dispersion (FDis) was significantly positively correlated with all diversity dimensions (r=0.32-0.64). Built area exerted significant negative effects on most diversity indices. Wetland, rangeland, and water positively correlated with diversity. Buffer size significantly influenced explanatory rate: Riparian land use explained 7.3% to 28.3% of the variation in diversity indices. Effects were strongest on functional and species diversity within smaller buffers (0.5-1 km; e.g., 28.3% explanation for Shannon within 0.5 km buffer), >2 km buffers, cropland and bare ground significantly reduced functional diversity (FRic and FDiv; p<0.05), while larger buffers (5 km) showed higher explanatory power for taxonomic diversity metrics (11.9% explanation for Delta). Functional dispersion (FDis) and taxonomic diversity (Delta) correlating significantly with all diversity dimensions (r=0.36-0.90; p<0.05) and outperforming species richness in detecting environmental responses. [Conclusions] Although overall diversity metrics showed no significant changes, the increase in sensitive rheophilic fish species indicates improved water quality following ecological water supplementation. Riparian land use, particularly built area expansion, significantly reduced multi-dimensional fish diversity, whereas wetlands, rangeland, and water enhanced it. Land use impacts exhibited scale dependence: near-shore buffers (0.5-1 km) dominated functional and species diversity changes, while larger-scale land use (5 km) primarily influenced taxonomic diversity. This underscores the need for scale-targeted management measures. Furthermore, functional dispersion (FDis) and taxonomic diversity (Delta) proved more sensitive indicators of community changes than species richness alone, recommending their integration into future monitoring frameworks. These findings provide a scientific basis for prioritizing conservation targets and formulating management strategies in water-supplemented river restoration.

导出引用

刘晗, 李鲁丹, 郭伟杰, 等. 河岸带土地利用驱动下受生态补水河流鱼类多样性格局[J]. 长江科学院院报. 2025, 42(8): 198-207 https://doi.org/10.11988/ckyyb.20240686

LIU Han, LI Lu-dan, GUO Wei-jie, et al. Fish Diversity Patterns in Rivers Receiving Ecological Water Supplement Driven by Riparian Land Use[J]. Journal of Changjiang River Scientific Research Institute. 2025, 42(8): 198-207 https://doi.org/10.11988/ckyyb.20240686

中图分类号： X826 (生物评价、生态评价)

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Functional diversity is increasingly identified as an important driver of ecosystem functioning. Various indices have been proposed to measure the functional diversity of a community, but there is still no consensus on which are most suitable. Indeed, none of the existing indices meets all the criteria required for general use. The main criteria are that they must be designed to deal with several traits, take into account abundances, and measure all the facets of functional diversity. Here we propose three indices to quantify each facet of functional diversity for a community with species distributed in a multidimensional functional space: functional richness (volume of the functional space occupied by the community), functional evenness (regularity of the distribution of abundance in this volume), and functional divergence (divergence in the distribution of abundance in this volume). Functional richness is estimated using the existing convex hull volume index. The new functional evenness index is based on the minimum spanning tree which links all the species in the multidimensional functional space. Then this new index quantifies the regularity with which species abundances are distributed along the spanning tree. Functional divergence is measured using a novel index which quantifies how species diverge in their distances (weighted by their abundance) from the center of gravity in the functional space. We show that none of the indices meets all the criteria required for a functional diversity index, but instead we show that the set of three complementary indices meets these criteria. Through simulations of artificial data sets, we demonstrate that functional divergence and functional evenness are independent of species richness and that the three functional diversity indices are independent of each other. Overall, our study suggests that decomposition of functional diversity into its three primary components provides a meaningful framework for its quantification and for the classification of existing functional diversity indices. This decomposition has the potential to shed light on the role of biodiversity on ecosystem functioning and on the influence of biotic and abiotic filters on the structure of species communities. Finally, we propose a general framework for applying these three functional diversity indices.

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The concept of functional redundancy is at the core of theory relating changes in ecosystem functioning to species loss. However, few empirical studies have investigated the strength and form of the relationship between species and functional diversity (i.e., the presence of functional redundancy in ecological communities) in this context. In particular, we know little about how local extinctions in real communities might impact functional diversity. Here, we examined the relationship between species and functional diversity in plant communities along a grazing gradient across Mongolian rangeland ecosystems. We applied a recently described measure of functional diversity that incorporates species' dissimilarities defined from plant functional traits and tested several hypothesized forms of the relationship between species and functional diversity using linear and nonlinear modeling techniques. We found a significant sigmoid logistic relationship between species richness and functional diversity in relatively benign environmental conditions. This indicates high functional redundancy at low levels of species richness followed by a rapid increase at intermediate levels, until functional diversity reaches an asymptote at high levels (i.e., two-phase functional redundancy). In contrast, we generally observed a positive linear relationship between these parameters in relatively harsh environmental conditions, indicating low functional redundancy. Observed functional redundancy probably resulted from two factors, intrinsic redundancy in species' functional traits and extrinsic redundancy caused by nonrandom compositional change that is nonrandom with respect to functional traits. Lack of either intrinsic or extrinsic redundancy may result in low functional redundancy. Two-phase functional redundancy suggests that functional traits are abruptly lost from a community below a certain level of species richness, and a community then shifts into a contrasting state that has a few limited functional groups characterized by disturbance-resistant traits, as a consequence of disturbances such as livestock grazing. This study represents a major step forward in predicting the consequences of livestock grazing on the functioning of Mongolian rangeland ecosystems.

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https://doi.org/10.11988/ckyyb.20240662

摘要

为强化华北地下水超采及地面沉降综合治理,水利部2018年以滹沱河、滏阳河、南拒马河的部分河段作为河湖地下水生态补水试点,启动生态补水工作。为评估生态补水对河流生态环境的改善效果,探索浮游植物群落结构对生态补水的响应机制,选取连续5 a(2018—2022年)进行生态补水的滹沱河和南拒马河开展连续监测(2019—2022年),对浮游植物的群落结构及水环境因子变化展开分析。研究结果表明,生态补水使得受水水体的水质由劣Ⅴ类逐渐向Ⅱ类转变,至补水第3 a基本达到最佳水质状态;受水环境因子的影响浮游植物群落结构发生较大变化,浮游植物密度、生物量、蓝藻门种类数、密度百分比及优势种优势度均总体呈现降低趋势;硅藻门种类数和密度百分比、Margalef 丰富度指数、Shannon-Wiener多样性指数和Pielou均匀度指数则总体呈升高趋势;浮游植物优势种逐渐由蓝藻门种类向硅藻门、绿藻门种类转变。冗余分析结果表明,总氮和pH值是影响补水河流浮游植物群落结构的主要环境因子。

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Zhi-wei

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