长期施用不同无机肥对旱地红壤线虫群落的影响

红壤生态系统中土壤生物群落对于维持土壤功能的正常发挥具有重要作用.本研究基于持续25年的红壤旱地化肥定位试验,研究不同无机肥组合,包括氮磷钾(NPK)、氮磷钾补充石膏(NPKCaS)、氮磷(NP)、氮钾(NK)和磷钾(PK)对花生生长季土壤线虫群落的影响.结果表明： 土壤线虫总数、营养类群以及各生态指数在处理间差异显著(P<0.01).线虫总数由高到低的顺序为PK>NPKCaS>NPK>NP>NK.除5月外,NPK、NP、NK处理的线虫总数均显著低于NPKCaS和PK处理.NPKCaS处理的优势类群为食细菌线虫,平均丰度为42.1%,其他处理均以植食性线虫为优势营养类群,其平均丰度为38%~65%.NPKCaS处理线虫群落较高的成熟度指数、瓦斯乐斯卡指数和结构指数说明土壤食物网结构较为成熟和稳定,同时表明氮磷钾补充石膏通过缓解土壤酸化创建了良好的土壤健康状况.仅施氮钾的处理则相反.本研究证实了施用石膏和磷肥是改善红壤质量的有效措施,土壤线虫群落分析能较好地反映不同无机肥对红壤旱地生态系统的影响.
     

西藏色季拉山急尖长苞冷杉林土壤线虫群落特征

为了解西藏东南部亚高山地带典型森林群落类型——急尖长苞冷杉林土壤生态系统线虫多样性现状,于2010年夏季至2011年春季,调查了0～30 cm范围内不同深度土层的土壤线虫群落,用线虫个体密度、多样性指数和营养类群指数等特征值分析了土壤线虫群落的组成与结构特点.调查采用浅盘法分离得到土壤线虫7915条,隶属于2纲6目38科67属;线虫个体密度平均为620条·100 g-1干土;表层(0～5 cm)土壤中线虫个体数量占总数的56.9％,表聚性明显.垫咽属、螺旋属及绕线属为优势属.植食性线虫是主要营养类群,非植食线虫中食真菌性线虫所占比例最大.土壤有机质以真菌分解途径为主.土壤线虫群落H'多样性指数、J'均匀度指数、λ优势度指数及SR丰富度指数季节间差异均不显著,不同土层间的.J'均匀度指数差异不显著,H'多样性指数、λ优势度指数及SR丰富度指数土层间的差异随土壤深度加深而增大.表明色季拉山急尖长苞冷杉林生态系统成熟度较高,抵抗外界干扰的能力较强.     

环渤海湾苹果产区老果园与连作果园土壤线虫群落特征

应用类群多样性、类群丰富度、个体密度和功能类群指数等群落参数,于2009年5-10月分3次对环渤海湾苹果栽植区老果园不同位置和连作果园取样研究了土壤线虫群落特征。结果表明:苹果连作对果园土壤生物环境具有明显的恶化作用,连作果园土壤环境条件恶劣;对功能类群指数的统计表明,苹果连作明显改变了果园土壤中植物寄生性线虫r-选择和k-选择的比例,与自由生活线虫比较,连作对植物寄生线虫影响更明显;连作提高了果园的土壤线虫PPI/MI,说明连作对果园土壤健康的扰动最大;土壤不同食性线虫数量统计结果显示,环渤海湾苹果栽植区植食性线虫数量未达线虫伤害阈值,线虫不是引起环渤海湾地区苹果连作障碍的主要原因。     

农田土壤线虫多样性研究现状及展望

目前土壤生物多样性已成为土壤生态学研究的热点问题之一。土壤生物以不同的方式改变着土壤的物理、化学和生物学特性。在农田生态系统中, 土壤动物是分解作用和养分矿化作用等生态过程的主要调节者。线虫作为土壤中数量最丰富的后生动物, 其生活史和取食类型多样, 在生态系统中发挥着重要作用。本文介绍了农田生态系统中影响线虫多样性的主要因素; 回顾了土壤线虫的物种多样性、营养类群多样性、生活史多样性和功能多样性的研究现状; 并提出了今后农田生态系统线虫多样性研究的重点。建议通过综合土壤线虫的生活史策略和营养类群等信息, 深入了解其生物多样性和土壤生态系统功能, 从而更好地发挥土壤线虫对农田生态系统变化的生物指示作用。     

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.     

藏东南急尖长苞冷杉林林隙土壤线虫群落特征

为了解西藏东南部急尖长苞冷杉林林隙土壤线虫群落特征,对林隙、非林隙土壤0~30 cm范围内不同深度土层的线虫群落进行调查,并用线虫个体密度、生物多样性指数和营养类群指数等特征值分析了土壤线虫群落的结构及多样性特点.结果表明： 采用浅盘法分离得到土壤线虫26801 条,隶属于2纲5目40科64属;线虫个体密度平均为3552 条·100 g-1干土,表聚性极强.垫咽属、丝垫刃属为林隙土壤线虫优势属;食细菌性线虫为主要营养类群.土壤有机质的分解兼有真菌分解和细菌分解两种途径.线虫的生物多样性及丰富度与林隙面积有关.土壤线虫群落特征表明,林隙具有异于郁闭林分和林间空地的特性,在环境指示方面具有应用潜力.     

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。     

不同果园土壤线虫的群落结构与多样性

2012 年 7 月, 对粤东地区柑橘园、番石榴园、荔枝园和芒果园 4 种不同果园土壤线虫群落进行调查, 应用土壤线虫群落生态学指数、土壤线虫各食性类群组成、 cp 类群结构及营养结构特征指数, 分析 4 种不同果园土壤线虫群落的功能结构特征, 探讨果树栽植年限、果园管理方式对土壤线虫群落功能结构的影响。共分离获得土壤线虫 53551 条, 隶属 2 纲 11 目 20 科 28 属。对不同果园土壤线虫的生态指数分析表明, 4 种果园的 Shannon 指数(H′)、Pielou 均匀性指数(J)、 Simpson 指数(D)、 Margalef 丰富度指数(SR)和密度类群指数(DG)均具有显著差异(P<0.05)。Gower 系数表明, 种植年限短的果园土壤线虫群落结构与种植年限长的果园之间具有显著相异性。食细菌线虫的H′、 J、 SR 指数排序为柑橘园>番石榴园>芒果园>荔枝园, 植食性线虫的 H′、 J、 SR 指数排序为荔枝园>芒果园>番石榴园>柑橘园。 cp 类群组成结构特征分析结果显示, 4 种果园的 cp1-cp2 类群的相对丰度均显著高于 cp3-cp5类群(P<0.05), 土壤线虫生活策略组成以 cp2 类群占优势。 PPI 指数表明: 荔枝园和芒果园受扰动程度大于柑橘园和番石榴园, MI、 PPI/MI 值则表明: 柑橘园和番石榴园土壤线虫群落的稳定性较高, 受到的干扰程度小。 NCR 值均说明了 4 种果园的土壤有机质分解主要依靠细菌分解途径。综合线虫功能类群的指数分析结果显示, 果树的栽植年限对果园土壤线虫的 PPI/MI 值有很大影响, 随着果树栽植年限的增加, PPI/MI 值呈上升趋势。土壤线虫各营养类群统计结果表明, 荔枝园和芒果园植食性线虫数量增加虽未达到对果树的伤害阈值, 但种植年限较长的果园土壤环境受到的扰动较大。     

我国土壤线虫生态学研究进展和展望

土壤线虫生态学主要探讨土壤线虫群落和其周围环境(包括生物和非生物)的相互关系, 包括不同生态系统中土壤线虫群落的分布和结构组成、线虫群落与土壤环境及其他土壤生物之间的相互作用等。本文回顾了我国研究者近年来在土壤线虫生态学研究领域的研究现状, 包括不同生态系统土壤线虫群落的分布、组成和多样性及其影响因素, 土壤线虫群落与全球气候环境变化的关系, 土壤线虫群落的生态功能以及土壤线虫群落生态学分析方法的发展及应用。重点评述近年来我国土壤线虫生态学的发展现状, 同时分析和比较了国内外土壤线虫生态学的发展态势, 提出建设全国范围的监测网络的重要性。未来我国土壤线虫生态学的发展方向应继续加强小尺度下土壤微食物网联通性和大尺度下全球气候变化对土壤线虫群落影响的研究以及加强相关新的研究技术方法的应用。     

不同植物群丛下铜尾矿复垦地土壤线虫的分布特征

对铜陵市凤凰山铜尾矿复垦地禾本科(矛叶荩草AL、白茅IC)和豆科(野豌豆GS)等3类典型植物群丛及外围对照禾本科(毛马唐)植物群丛下的土壤线虫群落进行调查.共分离得到1277 条土壤线虫,隶属于51属,平均密度590条·100 g^-1干土.采用多样性指数和土壤食物网结构指数等分析铜尾矿复垦地土壤线虫群落的分布特征.结果表明： 铜尾矿复垦地3类植物群丛下土壤线虫群落的类群总数和Shannon〖KG-*4〗多样性指数明显小于毛马唐对照组.对比铜尾矿复垦地和邻近自然栖息地不同植物群丛下的土壤线虫群落生态指数,发现野豌豆群丛下土壤食物网结构较成熟,土壤有机质分解以细菌分解通道为主;生态系统较不稳定,低度干扰;表明该豆科植物群丛下的土壤食物网具有较大的发展潜力,从而提高铜尾矿复垦地的生态稳定性.白茅与矛叶荩草群丛下土壤食物网处于结构化状态,土壤有机质分解以真菌分解通道为主;生态系统较稳定,无干扰;表明禾本科植物群丛下的土壤食物网处于较低层次的发展状态.     

Role of Nematodes in Soil Health and Their Use as Indicators

The composition of nematode communities (plant-parasitic and free-living) may be used as bioindicators of soil health or condition because composition correlates well with nitrogen cycling and decomposition, two critical ecological processes in soil. Maturity and trophic diversity indices withstand statistical rigor better than do abundances, proportions, or ratios of trophic groups. Maturity indices respond to a variety of land-management practices, based largely on inferred life history characteristics of families. Similarity indices may be more useful than diversity indices because they reflect taxon composition. Improving existing indices or developing alternative indices refined by a greater understanding of the biology of key taxa may enhance the utility of nematodes as bioindicators.     

Biodiversity of nematofauna of oilseed rape (Brassica napus L.)

Few data is available on the nematodes found in Brassicaceae, except for the most important plant parasite. However, studying the structure of nematofauna could be an important database for the soil quality and in order to assess the effects of future disturbance. This is particularly important considering that the diffusion of the canola crop in the world is increasing because of its use as a bio-diesel. Very diffused is also the Bt variety of oil seed rape, and, in this case, the study of the impact on the soil health and on bio-diversity is essential. In this research we have analyzed the nematode community, used as a bio-indicator of the soil condition. The nematofauna found in canola (Brassica napus var. oleifera) fields located in Southern Italy (Metaponto - MT) was investigated. The nematode community was studied considering its abundance, genus composition and trophic structure. Maturity and biodiversity indices were also calculated. A total of 5286 nematodes were extracted. They belong to 14 families and 24 genera. Bacterial and fungal feeders, 50.18% and 42.90% of the total respectively, dominated the trophic structure. Aphelencus is the most abundant genus (23.71%) followed by Acrobeloides (20.49%) and Aphelencoides (19.18%). Among plant feeders (6.59%), Pratylenchus is the dominant genus (2.20%) and Tylenchidae the main family (3.54%). No infestation of Meloidogyne, Heterodera or Naboccus, important plant-parasitic nematodes of canola crops, was recorded. Other important phytophagous were Helycotylenchus (0.5%), Trichotylenchus (0.5%) and Filenchus (0.9%). All of them had an abundance level below injury level. The indices of biodiversity are rather low (H'=0.93, J'=0.67), as is typical for agro ecosystems. However, the nematofauna community is quite well structured (N2=6.31, D=0.16) and the maturity index rather high (EMI=1.94). These values demonstrate that oilseed rape has a lower impact on the soil compared to other crop systems and that it could be taken into consideration for crop rotation programs. Canola could follow other more stressful crops, trying to maintain soil equilibrium.     

The influence of nematodes on below-ground processes in grassland ecosystems

This review summarises recent information on beneficial roles that soil nematodes play in the cycling of carbon and other plant nutrients in grassland ecosystems. In particular, we focus on the role of the two dominant functional groups of nematodes, namely the microbial- and root-feeders, and how their activities may enhance soil ecosystem-level processes of nutrient cycling and, ultimately, plant productivity in managed and unmanaged grassland ecosystems. We report recent experiments which show that low amounts of root herbivory by nematodes can increase the allocation of photoassimilate carbon to roots, leading to increased root exudation and microbial activity in the rhizosphere. The effects of these interactions on soil nutrient cycling and plant productivity are discussed. Evidence is presented to show that the feeding activities of microbial-feeding nematodes can enhance nutrient mineralization and plant nutrient uptake in grasslands, but that these responses are highly species-specific and appear to be strongly regulated by higher trophic groups of fauna (top-down regulation). We recommend that future studies of the roles of nematodes in grasslands ecosystems should consider these more complex trophic interactions and also the effects of species diversity of nematodes on soil ecosystem-level processes. This revised version was published online in June 2006 with corrections to the Cover Date.     

食微线虫对植物生长及土壤养分循环的影响

近二十多年来, 土壤动物的生态功能受到广泛重视。越来越多的证据表明, 土壤动物和微生物间的相互作用对土壤生态系统过程和植物生长起着重要的调节作用。本文综述了食细菌线虫和食真菌线虫对土壤微生物、土壤氮矿化和植物生长的影响。大量研究发现, 食细菌线虫和食真菌线虫都有助于土壤氮素等养分矿化, 从而促进植物生长。这种作用主要是线虫通过取食活动加速微生物周转, 并通过代谢分泌和释放微生物所固持的养分而实现的。但这种作用会因不同的线虫、微生物和植物的种类以及土壤基质的C/N营养状况而异, 此外还受线虫的营养类群及其与其他土壤动物之间复杂关系的影响。今后应该加强以下几方面的研究: (1)深入研究线虫、微生物和植物之间相互作用的机制; (2) 增加控制实验系统的复杂性, 研究线虫不同功能群之间及其与其他土壤动物之间的关系; (3)加强长期实验和观察, 在较长的时间尺度上了解线虫的生态功能; (4)加强对不同生态系统的研究, 在更大的空间尺度上综合了解土壤线虫的生态功能; (5)在全球气候变化的背景下了解土壤线虫的响应, 并预测土壤线虫对全球变化的反馈。     

Characteristics of soil nematode community along an age sequence of sandy desert soil cultivation in a marginal oasis of middle reaches of Heihe River

This paper studied the characteristics of soil nematode community following the conversion of native sandy desert soil to irrigated farmland in a marginal oasis of the middle reaches of Heihe River basin, aimed to approach the bioindicating function of soil nematodes in soil evolution process. A total of 27921 soil nematode individuals were captured, belonging to 25 families and 34 genera. The total number of nematodes increased gradually with increasing age of cultivation. At all sampling sites, bacterivores and plant parasites were the dominant trophic groups, and made up the main parts of nematode community in oasis farmland. Through the analysis of the evenness index (J) and dominance index (lambda) of nematode community, the ecosystems were found to be fragile for the farmlands having cultivated for 0, 10, and > 50 years. The maturity index MI2-5 and MMI decreased with increasing cultivation age, suggesting that the practice of agricultural use enhanced the disturbance on farmland. The soil properties changed significantly after 10 years of cultivation, which was at a significant change stage for the structure stability of soil ecosystems. The characteristics of soil nematode community could be used as the bioindicator of soil evolution following the conversion of native desert soil to irrigated farmland.     

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.     

Measures of nematode community structure and sources of variability among and within agricultural fields

Whole nematode communities, extracted from soil samples taken from agricultural fields, were enumerated by taxonomic family and trophic group (i.e., bacterivores, fungivores, omnivores, plant-parasites, and predators) to evaluate nematode community structure as an indicator for monitoring ecological condition of soil. No differences were found in mixing treatments or methods of packing or shipping samples. However, extraction using Cobb's sifting and gravity method, followed by sucrose centrifugation, gave greater recovery of free-living nematodes than elutriation followed by sucrose centrifugation. Population means and variance of the sampled area were similar when sampled using different strategies for collecting soil samples within fieds, including several patterns, directions and repetitions of transects. Components of variation associated with ratios among the five trophic groups of nematodes and selected indices of community structure were quantified as variation among regions, among counties, among agricultural fields (2-ha area), among transects within agricultural fields, and within composite soil samples. The variance component for'within composite soil samples' was relatively large compared to the other components of variance. Variation within composite soil samples was less for maturity indices (based on life-history strategy characteristics), ratio of bacterivores to plant-parasites, sum of bacterivores and fungivores, populations of plant-parasites, and populations of bacterivores than for trophic diversity indices, populations of fungivores, populations of omnivores, populations of predators, or the ratio of fungivores to bacterivores. With a single composite sample per field, the ability to differentiate ecological condition of soils among fields within a region improved if the variance among and within fields exceeded the variance within composite samples. Given the variance components, power curves indicated that detection of a 10% change (with 0.8 power) in the ecological condition of soils within a region between two time periods would require sampling a minimum of 25 and 50 fields with one composite soil sample analyzed per field for the maturity and trophic diversity index, respectively. More than 100 fieldsper region would be required to detect temporal change in populations of individual trophic groups. Biplots of maturity indices, but not of trophic diversity or populations of individual trophic groups, identified clear differences among fields. Thus, maturity indices, which differentiated among sampling sites better and more efficiently than trophic diversity indices or measures based on populations of individual trophic groups, may be appropriate for use in a regional and/or national monitoring program.     

Influence of ecological and edaphic factors on biodiversity of soil nematodes

Nematodes are the most diverse and highly significant group of soil-inhabiting microorganisms that play a vital role in organic material decomposition and nutrient recycling.Diverse geographical locations and environmental gradients show a significant impact on the diversity of nematodes. Present study aims to assess the effects of ecological (altitude, temperature, moisture) and edaphic (soil pH, nutrients, soil patches) factors on the soil nematode diversity and structure at five different landscape patches (forests, apple orchards, rice fields, pastures, and alpine zone) from ten different sites of Kashmir valley (India). Differences in the altitudinal gradients results in the shift of generic nematode population. Among the soil patches, highest nematode diversity was observed in forest soil and least in alpine soil; however, bacteriovorous nematodes dominated all the soil patches. The temperature and moisture have a significant effect on nematode diversity, the highest nematode trophic levels were observed above 21°C temperature, and 30% moisture. Nematode abundance decreased from alkaline to acidic pH of the soil. Soil nutrients such as, nitrogen (N) and phosphorus (P) have shown a detrimental effect in nematode richness at each site, where nematode diversity and richness of genera were higher at abundant soil N and P but decreased at low soil nutrients. Ecological indices like diversity index (DI), Shannon-Wiener Index (H'), enrichment index (EI), and maturity Index (MI) values demonstrated forest soil more favourable for nematodes and high soil health status than other soil patches. This study suggested that these indices may be helpful as soil monitoring tools and assessing ecosystem sustainability and biodiversity.     

Utility of nematode community analysis as an integrated measure of the functional state of soils: perspectives and challenges

Soil nematode communities have the potential to provide unique insights into many aspects of soil processes. Since most nematodes are active in soil throughout the year, they can potentially provide a holistic measure of the biotic and functional status of soils. In contrast to other soil microbial groups, representative samples of soil nematode communities are relatively easy to obtain. However, most current nematode ecological information has been survey-based or purely observational in nature, with a persistent focus on detailed taxonomic analysis of nematode communities. The development of a Maturity Index, MI, represents a significant advance in classifying communities and it continues to be refined and developed. But, to develop a wide capacity to use soil nematode information for diagnostic and predictive purposes, particularly for agricultural soils, we need a new, more robust approach, which does not require extensive taxonomic skill and includes more functional criteria. One of the key attributes of nematodes is the relationship between structural form (principally oesophagal feeding apparatus) and function (i.e. trophic group). Nematode form is readily determinable by direct observation of extracted nematodes and high-level taxonomic skills are not needed to assign the major community components to their different trophic and ecological groups. Consequently, the trophic structure of nematode communities is relatively easy to determine and can provide an integrated measure of the status of the other groups on which they feed. Similarly, population numbers and proportions of juveniles and adults can be readily determined, permitting calculation of relative biomass and dynamics of population growth. The size distribution of individuals within the community is likely also to be an indicator of the structural status of soils from a biotic standpoint. However, fundamental gaps remain in our understanding which limit our ability to relate differences in nematode communities to functional differences. There needs to be a greater emphasis on the development and experimental testing of hypotheses, a greater integration of nematology into soil-process related studies, and the development of a specific, soil-nematode related theoretical framework for understanding epidemiological and soil colonisation processes. This revised version was published online in June 2006 with corrections to the Cover Date.