氮沉降对土壤线虫群落影响的研究进展

综述了主要陆地生态系统(草原、农田和森林)土壤线虫群落对氮沉降增加的响应格局和机制。总体上,氮沉降增加对线虫数量一般无显著影响,但增加了土壤中富集机会主义者(即低营养级的r-策略者)数量,降低了线虫群落成熟度指数(MI),表明氮沉降增加可能会使土壤食物网简化。氮沉降增加主要通过改变土壤微环境(如增加含氮离子浓度、降低土壤pH)直接影响土壤线虫群落,或者改变植物地上地下资源的输入和线虫与其他土壤动物的关系,间接影响线虫群落。最后,根据目前研究现状,指出了当前研究存在的局限性,包括研究时间和空间尺度上以及研究技术手段上的局限。建议综合多个全球环境变化因子,并结合室内试验及分子手段的方法对土壤线虫群落进行研究。     

土壤线虫作为生态指示生物的研究进展

土壤线虫广布于各种类型的土壤中, 在维持土壤生态系统的稳定性、促进物质循环和能量流动等方面发挥着重要的作用, 同时也是理想的环境指示生物。简述了土壤线虫的生活史策略和营养类群的多样性、土壤线虫多样性的生态指数、影响土壤线虫群落多样性的环境因素, 以及线虫作为指示生物在农业生态系统、草地生态系统、森林生态系统的功能作用。提出了全球气候变化背景下对青藏高原高寒草地土壤线虫分类、群落结构特征以及土壤线虫的生物指示作用研究的必要性, 并对土壤线虫未来的发展趋势做了展望。     

藏北高寒草甸植物群落对土壤线虫群落功能结构的影响

2011年5-11月,对西藏北部高寒草甸3种典型植物群落下0-30cm范围内不同深度土层的土壤线虫群落进行调查,采用浅盆法分离线虫,土壤性质指标,如pH、含水量、电导率分别采用电位法、烘干法、电导率仪法进行测定,应用营养类群组成、c-p类群结构及营养结构特征指数,以及营养类群、c-p类群与土壤性质之间的关系等特征值分析高寒环境下土壤线虫群落的功能结构特征,以了解高寒环境下植被对土壤线虫群落功能结构的影响.调查共分离得到33038条土壤线虫,隶属于2纲6目51科93属;线虫个体密度平均为847条/100g干土;表聚性明显.研究结果表明,高寒草甸不同植物群落的土壤线虫群落营养类群组成及分布特征均存在一定差异,植食性线虫和食细菌性线虫是调查区域的主要营养类群,不同植物群落间植食性线虫和杂食/捕食性线虫的相对多度差异明显.c-p类群组成结构特征结果表明:3种植物群落的土壤线虫cp2类群均为优势类群,生活策略以r-对策为主;高山嵩草植物群落土壤中的线虫食物资源在3种植物群落中最丰富;藏北嵩草群落土壤线虫数量低的可能原因是线虫食物资源的减少限制了cp1、cp2类群的增殖.PPI值表明:委陵菜群落受扰动的影响程度大于其余两种植被类型,而MI、PPI/MI值及cp5类群数量的结果则表明:委陵菜群落的稳定性较高,受到的干扰在3种植物群落中最少.F/B及NCR值均说明了3种植物群落的土壤有机质分解均主要依靠细菌分解途径.相关性分析结果表明:杂食/捕食性线虫在枯草期明显受到土壤含水量的影响;食真菌性线虫与土壤pH之间的关系密切,在盛长期则明显受到土壤电导率的影响;食细菌性线虫仅在返青期与pH有相关性.不同植物群落下土壤线虫群落功能结构特征的分异显示出线虫指示环境因子影响土壤生态系统的潜力.     

土壤线虫对气候变化的响应研究进展

全球变化对陆地生态系统功能具有重要而深远的影响。陆地生态系统地下部分具有重要的生态功能,其组成及结构对气候变化的响应将进一步减缓或加剧全球化进程。土壤线虫在各类生态系统中分布十分广泛,是地下食物网的重要组分,在维持土壤生物多样性及营养物质循环过程中发挥重要作用,其组成及结构对不同气候变化驱动因子的响应机制与模式不尽相同。增温及降水格局变化主要是通过改变线虫生境而直接影响其种群密度与结构,两者通常表现为正效应且作用效果随处理时间的延长而增强。CO2与大气氮沉降主要是通过影响地上植被,凋落物质量,土壤理化性质等间接过程影响土壤线虫。同时,不同的全球变化因子之间存在着复杂的交互作用,深入理解这些因子之间交互作用对线虫群落的影响模式与机制对于探讨未来气候变化情景下生态统生物多样性及养分循环过程具有重要的理论指导意义。     

江苏省不同农业区土壤线虫群落分布特征

调查了江苏省不同农业区农田土壤线虫群落多样性,分析了土壤线虫数量和群落结构与土壤环境因子的关系,并探讨了土壤线虫对土壤健康的生物指示作用.结果表明： 农田土壤线虫共鉴定出2纲7目19科41属.6个农业区的土壤线虫的密度、群落组成均具有一定的差异性.沿海农业区的线虫数量最多(每100 g干土400条),显著高于徐淮、宁镇扬和沿江农业区(P＜0.05),而沿江农业区的土壤线虫数量最少(每100 g干土232条),这可能是由于土壤质地、年均降雨量和年均气温等因素的差异造成的.地理位置相近的农业区线虫优势属相似.相关性分析结果显示,土壤线虫数量与土壤有机质、全氮、速效氮、速效钾和速效磷均呈显著正相关关系;RDA分析表明,土壤全氮含量、速效磷及pH对线虫群落种属组成影响较大.分析江苏省农田土壤线虫群落空间分布特征,可为农田土壤生态系统健康状况评价提供数据支撑.     

典型黑土区农田土壤线虫群落的纬度分布格局及其驱动机制

东北黑土区是保障我国粮食安全的重要土壤资源, 了解该区域内农田土壤线虫的群落组成及其对环境驱动因子的响应机制, 对于研究黑土区农田土壤生态系统的生物多样性分布格局具有重要意义。2018年9月, 我们在42°50°‒49°08° N的典型黑土区采集了93个农田土壤样品, 利用形态学鉴定技术分析了土壤线虫群落的组成与结构。共鉴定出47个线虫属(相对丰度 > 1%), 其中食细菌线虫中的拟丽突属(Acrobeloides)是典型黑土区农田土壤中的优势属(相对丰度 > 5%)。土壤线虫总丰富度和总多度均随纬度增加而显著增加, 然而类似的变化趋势只出现在食细菌和杂食/捕食线虫中。土壤有机碳是影响土壤线虫丰富度和多度最为重要的环境因子, 其次是月平均温度。典型黑土区农田土壤线虫群落结构以47° N为分界线分为南部和北部两类, 主要归因于线虫群落中植物寄生和杂食/捕食线虫的相对多度在南、北特征属中存在差异。土壤pH值和容重分别是影响南部与北部黑土区线虫群落最重要的环境因子。本研究明确了典型黑土区农田土壤线虫群落的纬度分布格局及其与环境因素的关系, 可为揭示农业活动干扰下土壤生物对环境因子的响应机制提供基础数据和理论参考。     

下辽河平原农田土壤线虫群落组成的季节变化

下辽河平原农田生态系统在管理过程中频繁的耕作、施肥以及农用化学品施用等引发了一系列问题, 如土壤退化、耕地数量减少以及生产力下降等, 不可避免地对土壤生物健康产生影响。为探究农田土壤人工管理对土壤生物群落动态的影响, 本研究在辽宁沈阳农田生态系统国家野外科学观测研究站开展了农田土壤线虫群落组成的季节变化研究, 对4个季节农田和废弃农田(对照)的土壤线虫群落组成、多度以及多样性等进行了比较分析。研究结果表明, 土壤线虫总多度在废弃农田中显著高于农田, 但季节间差异不显著。季节变化主要显著影响了自由生活线虫的多度, 其在9月达到最高; 季节变化也显著影响了属的数量, 其在非生长季的11月最低。与废弃农田相比, 农田管理显著降低了杂食捕食线虫和食真菌线虫的多度, 土壤食物网结构相对稳定; 而废弃的农田更易受到季节波动的影响, 土壤食物网也受到一定的干扰。     

降水格局对北方温带草原土壤微食物网结构的影响

全球气候变化背景下, 降水格局发生改变, 呈现降水总量不变, 但降水强度增加、降水频率降低的趋势, 影响了地下生态系统的结构和功能。土壤微食物网作为地下生态系统的重要组成部分, 在驱动生态系统多功能性方面起着重要作用。降水格局的变化能够通过土壤微食物网的改变对生态系统产生影响。然而, 以往研究多关注于降水量的变化对微食物网的影响, 降水格局变化对其影响的研究较少。因此, 本研究在内蒙古温带草原开展连续8年的降水添加控制试验(控制降水总量不变, 降水频率及强度改变), 包括5个降水强度处理(2 mm、5 mm、10 mm、20 mm和40 mm), 通过磷脂脂肪酸法(PLFA)确定微生物含量, 高通量测序法(16S和ITS)确定微生物多样性及群落结构, 线虫形态学鉴定确定线虫群落组成及结构。结果表明在降水总量不变降水强度改变的背景下, 高降水强度(20 mm)促进了北方温带草原真菌含量的增长, 适度降水强度(10 mm)促进了微生物的多样性。而线虫的多度随着降水强度的增加而增大, 中高降水强度下线虫多样性最高。土壤微食物网的变化进一步影响了生态系统多功能性, 主要通过提高真菌生物量、食真菌线虫多度和线虫多样性, 从而提高了生态系统多功能性。     

土壤细菌网络互作调控线虫肠道细菌群落

动物肠道细菌群落在联系宿主与生态系统功能中发挥着至关重要的作用。【目的】本研究旨在评估绿肥翻压和水稻生长不同时期对土壤细菌和线虫肠道细菌群落组成和结构的影响,并探究土壤细菌和线虫肠道细菌群落间的潜在关联关系。【方法】基于盆栽试验,结合16S rRNA基因高通量测序技术,分析黑麦草翻压和对照处理下水稻生长的前期(返青期)和后期(收获期)土壤细菌和线虫肠道细菌群落,结合网络分析研究土壤细菌网络互作对线虫肠道细菌群落的潜在影响。【结果】黑麦草翻压对土壤细菌和线虫肠道细菌群落组成和结构没有显著影响(P>0.05);水稻生长后期样品比前期样品具有更高的α多样性。基于随机森林机器学习法获得的土壤细菌和线虫肠道细菌生物标志物之间存在广泛的显著相关关系,为土壤细菌群落变化调控线虫肠道细菌群落组成提供了有力的证据。共现网络分析表明土壤细菌之间的正相互作用显著促进了土壤细菌和线虫肠道细菌之间的正相互作用(P<0.01),进而影响了线虫肠道细菌之间的网络互作。结构方程模型进一步表明土壤养分含量的降低主要通过降低土壤细菌之间正相互作用,从而间接影响线虫肠道细菌之间的互作。【结论】土壤细菌互作可能在...     

短期围封对西藏北部高寒草甸土壤线虫群落的影响

为了解放牧对高寒草甸的影响,以及围封对高寒草甸的恢复作用,2013年5月、8月、10月,分别对藏北短期围封高寒草甸和自由放牧高寒草甸不同深度土层的土壤线虫群落及土壤理化性质等进行了调查。调查结果表明,3a围封提高了土壤全氮、磷、钾及土壤有机质含量,土壤保水能力也明显提高;围封使土壤线虫个体密度下降,但物种多样性和丰富度却提高了;围封使土壤线虫群落中的植食性线虫所占比重呈下降趋势,食真菌线虫比重加大。短期围封有利于高寒草甸生态系统的正向演替,使之向更稳定的方向发展,同时,土壤线虫数量对土壤理化性质变化有明显的响应,通过土壤线虫群落的群落特征可以反映放牧干扰及围封对高寒草甸生态系统的影响。     

Antarctic nematode communities: observed and predicted responses to climate change

The rapidly changing climate in Antarctica is impacting the ecosystems. Since records began, climate changes have varied considerably throughout Antarctica with both positive and negative trends in temperatures and precipitation observed locally. However, over the course of this century a more directional increase in both temperature and precipitation is expected to occur throughout Antarctica. The soil communities of Antarctica are considered simple with most organisms existing at the edge of their physiological capabilities. Therefore, Antarctic soil communities are expected to be particularly sensitive to climate changes. However, a review of the current literature reveals that studies investigating the impact of climate change on soil communities, and in particular nematode communities, in Antarctica are very limited. Of the few studies focusing on Antarctic nematode communities, long-term monitoring has shown that nematode communities respond to changes in local climate trends as well as extreme (or pulse) events. These results are supported by in situ experiments, which show that nematode communities respond to both temperature and soil moisture manipulations. We conclude that the predicted climate changes are likely to exert a strong influence on nematode communities throughout Antarctica and will generally lead to increasing abundance, species richness, and food web complexity, although the opposite may occur locally. The degree to which local communities respond will depend on current conditions, i.e., average temperatures, soil moisture availability, vegetation or more importantly the lack thereof, and the local species pool in combination with the potential for new species to colonize.     

Soil Nematode Responses to Increases in Nitrogen Deposition and Precipitation in a Temperate Forest

The environmental changes arising from nitrogen (N) deposition and precipitation influence soil ecological processes in forest ecosystems. However, the corresponding effects of environmental changes on soil biota are poorly known. Soil nematodes are the important bioindicator of soil environmental change, and their responses play a key role in the feedbacks of terrestrial ecosystems to climate change. Therefore, to explore the responsive mechanisms of soil biota to N deposition and precipitation, soil nematode communities were studied after 3 years of environmental changes by water and/or N addition in a temperate forest of Changbai Mountain, Northeast China. The results showed that water combined with N addition treatment decreased the total nematode abundance in the organic horizon (O), while the opposite trend was found in the mineral horizon (A). Significant reductions in the abundances of fungivores, plant-parasites and omnivores-predators were also found in the water combined with N addition treatment. The significant effect of water interacted with N on the total nematode abundance and trophic groups indicated that the impacts of N on soil nematode communities were mediated by water availability. The synergistic effect of precipitation and N deposition on soil nematode communities was stronger than each effect alone. Structural equation modeling suggested water and N additions had direct effects on soil nematode communities. The feedback of soil nematodes to water and nitrogen addition was highly sensitive and our results indicate that minimal variations in soil properties such as those caused by climate changes can lead to severe changes in soil nematode communities.     

Local climate mediates spatial and temporal variation in carabid beetle communities in three forests in Mount Odaesan,Korea

1. Global environmental change can dramatically alter the composition of floral and faunal communities, and elucidating the mechanisms underlying this process is important for predicting its outcomes. Studies on global climate change have mostly focused on statistical summaries within wide spatial and temporal scales; less attention has been paid to variability in microclimates at narrower spatial and temporal scales. 2. The microclimate is the suite of climatic conditions measured in a local area. Environmental variables at the microclimatic scale can be critical for the ecology of organisms inhabiting each area. The effect of spatial and temporal changes in the microclimate on the ecology of carabid beetle communities in three sites on Mount Odaesan, Korea was examined. 3. Carabid beetle communities and quantified site‐specific environmental factors from measurements of air temperature, air humidity, light intensity and soil temperature over 5 years (2010–2015) were surveyed. 4. It was found that microclimatic variables and the patterns of temporal changes in carabid beetle communities differed between the three sites within the single mountain system. Microclimatic variables influencing temporal changes in beetle communities also differed between the sites. Therefore, it is suggested that variation in local microclimates affects spatial and temporal variation in carabid beetle communities at a local scale. 5. The present results demonstrate the importance of regular surveys of communities at local scales. Such surveys are expected to reveal an additional fraction of variation in communities and underlying processes that have been overlooked in studies of global community patterns and change.     

高通量测序技术在线虫多样性研究中的应用

土壤线虫多样性是土壤生态学研究的热点之一, 然而对土壤线虫群落组成及多样性的研究通常受到分类学和方法学的限制。当前, 分子生物学技术的快速发展丰富了我们对土壤线虫多样性的认识, 但也存在一定的局限性。本文综述了常用分子生物学技术如变性梯度凝胶电泳(denaturing gradient gel electrophoresis, DGGE)、末端限制性片段长度多态性分析(terminal restriction fragment length polymorphism, T-RFLP)、实时荧光定量PCR (quantitative real-time PCR, qPCR)和高通量测序(high-throughput sequencing, HTS)技术近年来在线虫多样性研究中的应用, 重点从土壤线虫DNA提取方法、引物和数据库的选择、高通量测序技术和形态学鉴定结果的比较等方面阐述了高通量测序技术在线虫多样性研究中的优势与不足, 并提出选择合适的线虫DNA提取方法结合特定引物和数据库进行注释分析, 仍是今后使用高通量测序技术开展线虫多样性研究的重点。当研究目标是土壤线虫多样性时, 优先推荐富集线虫悬液提取DNA的方法, 因此, 研究人员应根据具体目标选择最优组合开展实验研究。     

气候变化对鸟类影响：长期研究的意义

过去一个多世纪全球气候发生了明显变化,地球表面温度正在逐渐变暖。已有大量研究结果表明,鸟类已经在种群动态变化、生活史特性以及地理分布范围等方面对全球气候变化作出了相应的反应。根据全球范围内气候变化对鸟类影响的研究资料,尤其是北美和欧洲的一些长期研究项目的成果,综述了气候变化对鸟类分布范围、物候、繁殖和种群动态变化等方面的可能影响。这些长期研究项目为探讨气候变化在个体和种群的水平上如何长时间地影响鸟类提供了独特的机会,对未来中国鸟类学研究也会有所裨益。     

Reduced tillage,but not organic matter input,increased nematode diversity and food web stability in European long‐term field experiments

Soil nematode communities and food web indices can inform about the complexity, nutrient flows and decomposition pathways of soil food webs, reflecting soil quality. Relative abundance of nematode feeding and life‐history groups are used for calculating food web indices, i.e., maturity index (MI), enrichment index (EI), structure index (SI) and channel index (CI). Molecular methods to study nematode communities potentially offer advantages compared to traditional methods in terms of resolution, throughput, cost and time. In spite of such advantages, molecular data have not often been adopted so far to assess the effects of soil management on nematode communities and to calculate these food web indices. Here, we used high‐throughput amplicon sequencing to investigate the effects of tillage (conventional vs. reduced) and organic matter addition (low vs. high) on nematode communities and food web indices in 10 European long‐term field experiments and we assessed the relationship between nematode communities and soil parameters. We found that nematode communities were more strongly affected by tillage than by organic matter addition. Compared to conventional tillage, reduced tillage increased nematode diversity (23% higher Shannon diversity index), nematode community stability (12% higher MI), structure (24% higher SI), and the fungal decomposition channel (59% higher CI), and also the number of herbivorous nematodes (70% higher). Total and labile organic carbon, available K and microbial parameters explained nematode community structure. Our findings show that nematode communities are sensitive indicators of soil quality and that molecular profiling of nematode communities has the potential to reveal the effects of soil management on soil quality.     

A framework for representing microbial decomposition in coupled climate models

Accurate prediction of future atmospheric CO₂ concentrations is essential for evaluating climate change impacts on ecosystems and human societies. One major source of uncertainty in model predictions is the extent to which global warming will increase atmospheric CO₂ concentrations through enhanced microbial decomposition of soil organic carbon. Recent advances in microbial ecology could help reduce this uncertainty, but current global models do not represent direct microbial control over decomposition. Instead, all of the coupled climate models reviewed in the most recent Intergovernmental Panel on Climate Change (IPCC) report assume that decomposition is a first-order decay process, proportional to the size of the soil carbon pool. Here we argue for the development of a new generation of models that link decomposition directly to the size and activity of microbial communities in coupled global models. This process begins with the formulation and validation of fine-scale models that capture fundamental microbial mechanisms without excessive mathematical complexity. These mechanistic models must then be scaled up through an aggregation process and validated at ecosystem to global scales prior to incorporation into global climate models (GCMs). Parameterizing microbial models at the global scale is challenging because some microbial properties such as in situ extracellular enzyme activities are very difficult to measure directly. New parameter fitting procedures may therefore be needed to infer the values of important microbial variables. Validating decomposition models at the global scale is also a challenge, and has not yet been accomplished with the land carbon models embedded in current GCMs. Fortunately new global datasets on soil carbon stocks and fluxes offer promising opportunities to validate both existing land carbon models and new microbial models. If challenges in scaling, parameterization, and validation can be overcome, a new generation of microbially-based decomposition models could substantially improve predictions of carbon–climate feedbacks in the Earth system. Development of new models structures would also reduce any bias due to the assumption of first-order decomposition across all of the models currently referenced in reports of the IPCC.     

Regional‐scale patterns of soil microbes and nematodes across grasslands on the Mongolian plateau: relationships with climate,soil, and plants

Belowground communities exert major controls over the carbon and nitrogen balances of terrestrial ecosystems by regulating decomposition and nutrient availability for plants. Yet little is known about the patterns of belowground communities and their relationships with environmental factors, particularly at the regional scale where multiple environmental gradients co‐vary. Here, we describe the patterns of belowground communities (microbes and nematodes) and their relationships with environmental factors based on two parallel studies: a field survey with two regional‐scale transects across the Mongolia plateau and a water‐addition experiment in a typical steppe. In the field survey, soils and plants were collected across two large‐scale transects (a 2000‐km east–west transect and a 900‐km south–north transect). At the regional‐scale, the variations in soil microbes (e.g. bacterial PLFA, fungal PLFA, and F/B ratio) were mainly explained by precipitation and soil factors. In contrast, the variation in soil nematodes (e.g. density of trophic groups and the bacterial‐feeding/fungal‐feeding nematode ratio) were primarily explained by precipitation. These variations of microbe or nematode variables explained by environmental factors at regional scale were derived from different vegetation types. Along the gradient from nutrient‐poor to nutrient‐rich vegetation types, the total variation in soil microbes explained by precipitation increased and that explained by plant and soil decreased, while the opposite was true for soil nematodes. Experimental water addition, which increased rainfall by 30% during the growing season, increased biomass or density of belowground communities, with the nematodes being more responsive than the microbes. The different responses of soil microbial and nematode communities to environmental gradients at the regional scale likely reflect their different adaptations to climate, soil nutrients, and plants. Our findings suggest that the soil nematode and microbial communities are strongly controlled by bottom‐up effects of precipitation alone or in combination with soil conditions.     

Flying with diverse passengers: greater richness of parasitic nematodes in migratory birds

Environmental changes are simultaneously affecting parasitic diseases and animal migrations, making it important to understand the disease dynamics of migratory species, including their range of infections and investment into defences. There is an urgent need for such knowledge because migratory animals, especially birds, are important for pathogen transmission and also particularly sensitive to environmental changes. Here we compare the nematode species richness and relative immune investment (via relative spleen size) of almost 200 migratory and non‐migratory species within three diverse groups of birds (Anseriformes, Accipitriformes and Turdidae) with worldwide distributions and varied ecology. Our results provide the first large‐scale demonstration that migratory birds face greater challenge from macroparasites as they have significantly dissimilar nematode fauna and higher nematode species richness compared to non‐migratory species. Even though birds with relatively large spleens had more nematode species, there was no difference in relative spleen size between migratory and non‐migratory bird species. The physiological stress of migration can be exacerbated by the potential range of pathologies induced by their richer nematode communities, particularly in combination with environmental perturbations. Altered migration stemming from global changes can also have important consequences for nematode transmission. Synthesis Most studies on parasites of migratory birds versus non‐migratory birds focus upon blood parasites; here we compared the diversity of another important parasite group – nematodes (roundworms) in three orders of birds. We found for any given order, migratory species and species with proportionally larger spleens generally have a wider range of nematodes. It is unclear why migratory species harbour more nematode species. Global climate change is expected to influence both bird migration patterns and infectious diseases, which may increase host susceptibility to parasitism and also introduce diverse nematodes to new areas and potential hosts.