根际效应对大豆田土壤线虫群落组成及多样性的影响

根际作为重要的环境界面是植物与环境之间物质能量交换的场所,关于根际效应的研究已成为土壤生态学的新兴热点领域,然而有关大豆根际效应对土壤动物多样性影响的研究报道并不多见。在三江平原选择连续耕作15a的大豆田,对大豆根际区与非根际区土壤线虫群落结构组成进行了对比分析。结果表明:大豆根际区土壤线虫总数、辛普森多样性指数(Dom)显著高于非根际区,根际区的物种数(S)、物种丰富度指数(SR)显著低于非根际区。说明大豆根际效应增加土壤线虫的丰度,但降低了线虫群落结构的复杂性。大豆根际区植物寄生线虫(PP)、食真菌线虫(FF)和食细菌线虫(BF)数量显著高于非根际区,而PP类群的比例在根际区却显著低于非根际区。这一研究结果表明食微线虫(FF和BF)类群在大豆根际区的比例增加更显著。食真菌与食细菌线虫数量比值(F/B)指示大豆根际区细菌生物量相对高于真菌生物量。研究结果丰富了农田土壤线虫多样性的研究内容,并为我国东北大豆田线虫病害的防治及定制相应的农业管理措施提供参考。     

Feeding of biofilm-dwelling nematodes examined using HPLC-analysis of gut pigment contents

The natural feeding behaviour of the nematodes Chromadorina bioculata (Schultze in Carus 1857) and Chromadorina viridis (Linstow 1876) was studied in situ, within epilithic biofilms of the Garonne River (France). Based on their feeding-type characteristics and population dynamics, it was hypothesised that these species feed selectively on microphytobenthos (MPB) within the biofilm, and that among MPB groups, diatoms are preferred. High-performance liquid chromatography (HPLC) was used for separation, identification and quantification of pigments both in nematode guts and in the biofilm. This is the first time that nematode gut pigment contents were examined under natural conditions. Diatoms dominated the MPB which also comprised cyanobacteria and green microalgae. The comparison between chlorophyll a content in nematode guts versus in the biofilm showed that C. bioculata and C. viridis fed opportunistically (non-selectively) on MPB within the biofilm. Only diatom biomarker pigments were found in nematode guts suggesting that they could preferentially fed on diatoms among MPB groups. However, the non-detection of biomarker pigments for other microphyte groups could be also linked to HPLC detection limits. It was estimated that Chromadorina nematodes daily ingested on average 0.03–0.67% of the MPB standing stock. This grazing covered only a small part of their energetic requirements, suggesting that besides MPB they probably also fed on other biofilm food sources. Some considerations on the applicability of the HPLC gut pigment analysis technique for the examination of nematode feeding are also presented.     

Trophic interactions in soils as they affect energy and nutrient dynamics. III. Biotic interactions of bacteria,amoebae, and nematodes

Bacteria (Pseudomonas), amoebae (Acanthamoeba), and nematodes (Mesodiplogaster) were raised in soil microcosms with and without glucose additions. Nematode and amoebal grazing on bacteria significantly reduced bacterial populations by the end of a 24-day incubation period. Amoebal numbers decreased in the presence of nematodes with a corresponding increase in nematode numbers which reached a maximum of 230 nematodes/g of soil in the treatment with amoebae and glucose additions. After 24 days the nematode populations in the treatments without carbon additions were dominated by resistant dauer larvae indicating the unavailability of food. Although larval numbers were high in the treatments with glucose additions, the adult component of the population was still increasing at the end of the 24-day experiment. The effect of the presence of amoebae on nematode abundance was of the same magnitude as addition of 600g glucose-C.     

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...     

Effect of slow-release urea on soil nematode community structure in a Chinese soybean field

The effect of slow-release urea on soil nematode community structure was investigated in a soybean field in northeast China. Three treatments, no urea (CK), conventional urea (U) and slow-release urea (SRU), were arranged in a completely random design. The results show that the abundance of total nematodes was significantly higher in SRU than in CK and U. Significant differences in the abundance of bacterivores with colonizer-persister (cp) values 2–3, fungivores with cp 2 and herbivores with cp 3 were found among different treatments. Forty-one genera were identified, of which Acrobeloides, Aphelenchus and Heterodera were dominant. Soil nematode guilds and genera exhibited different responses to slow-release urea. The most trophic groups and genera had greater abundances in SRU than in CK and U. Slow-release urea had a positive effect on soil nematode community structure.     

Impacts of ocean acidification and burrowing urchins on within-sediment pH profiles and subtidal nematode communities

Rising carbon dioxide levels in the atmosphere will affect the ocean carbonate system, resulting in a predicted future decrease in the pH of seawater by 0.3-0.5 units. To investigate whether the presence of a burrowing urchin, Echinocardium cordatum, might influence the impact of ocean acidification on subtidal sediment pH profiles and nematode community structure an experiment was conducted using subtidal sediment, with urchins present or absent and seawater at either pH 8.0 (ambient) or 7.5. The presence of urchins, and a reduction in pH, both had significant effects on within-sediment pH profiles. Where urchins were present sediment profiles were more consistent and sediment pH was lower than that of the overlying seawater. There were significant differences in nematode abundance between treatments. The primary effect was a higher abundance of nematodes in replicates with urchins in natural seawater. All treatments had similar nematode community structure and diversity. Ocean acidification could therefore lead to changes in nematode communities in subtidal sediments affected by burrowing urchins.     

Effects of defoliation intensity on soil food-web properties in an experimental grassland community

We established a greenhouse experiment based on replicated mini‐ecosystems to evaluate the effects of defoliation intensity on soil food‐web properties in grasslands. Plant communities, composed of white clover (Trifolium repens), perennial ryegrass (Lolium perenne) and plantain (Plantago lanceolata) with well‐established root and shoot systems, were subjected to five defoliation intensity treatments: no trimming (defoliation intensity 0, or DI 0), and trimming of all plant material to 35 cm (DI 1), 25 cm (DI 2), 15 cm (DI 3) and 10 cm (DI 4) above soil surface every second week for 14 weeks. Intensification of defoliation reduced shoot production and standing shoot and root mass of plant communities but increased their root to shoot ratio. Soil microbial activity and biomass decreased with intensification of defoliation. Concentrations of NO₃–N in soil steadily increased with intensifying defoliation, whereas NH₄–N concentrations did not vary between treatments. Numbers of microbi‐detritivorous enchytraeids, bacterial‐feeding rotifers and bacterial‐feeding nematodes steadily increased with intensifying defoliation, while the abundance of fungal‐feeding nematodes was significantly enhanced only in DI 3 and DI 4 relative to DI 0. The abundance of herbivorous nematodes per unit soil mass was lower in DI 3 and DI 4 than in DI 0, DI 1 and DI 2, but when calculated per unit root mass, their abundance tended to increase with defoliation intensity. The abundance of omnivorous and predatory nematodes appeared to be highest in the most intensely defoliated systems. The ratio of abundance of fungal‐feeding nematodes to that of bacterial‐feeding nematodes was not significantly affected by defoliation intensity. The results infer that defoliation intensity may significantly alter the structure of soil food webs in grasslands, and that defoliation per se is able to induce patterns observed in grazing studies in the field. The results did not support hypotheses that defoliation per se would cause a shift between the bacterial‐based and fungal‐based energy channels in the decomposer food web, or that herbivore and detritivore densities in soil would be highest under intermediate defoliation. Furthermore, our data for microbes and microbial feeders implies that the effects of defoliation intensity on soil food‐web structure may depend on the duration of defoliation and are therefore likely to be dynamic rather than constant in nature.     

Relation between nematode communities and trophic state in southern Swedish lakes

The aim of this study was to examine whether littoral nematode community patterns are shaped by lake trophic state. It was hypothesized that trophic level is associated negatively with the proportion of omnivores and positively with the percentages of bacterial feeders, but not at all with the diversity, abundance, and biomass of freshwater nematodes. Sediment samples were taken at littoral sites of eight southern Swedish lakes of different trophy in spring and autumn 2007. Trophic level was found to strongly influence species richness, as oligotrophic and mesotrophic lakes supported the greatest species numbers, whereas nematode abundance, biomass, and Shannon index were unaffected. Furthermore, our results indicated effects on the nematode community’s trophic structure, with a larger proportion of predatory nematodes in oligotrophic and mesotrophic lakes but no differences in the other feeding types (bacteria, algae and suction feeders, omnivorous species). Multivariate analysis indicated a shift in species compositions along the threshold from mesotrophic to eutrophic conditions, with the presence of Tobrilus gracilis, Monhystera paludicola, Brevitobrilus stefanskii, and Ethmolaimus pratensis related to the latter. Nematode communities in oligotrophic and mesotrophic lakes were characterized by a similar species composition, with pronounced occurrences of Eumonhystera longicaudatula, Semitobrilus cf. pellucidus, Prodesmodora circulata, and Rhabdolaimus terrestris. Overall, the results suggested that lake trophic state is a major factor structuring littoral nematode communities, although intra-lake variations might be of importance as well.     

Influence of bacterivorous nematodes on the decomposition of cordgrass

The influence of bacterivorous nematodes (Diplolaimelloides meyli, Diplolaimelloides oschei, Diplolaimella dievengatensis, Panagrolaimus paetzoldi) on the decomposition of a macrophyte (Spartina anglica) in an aquatic environment was investigated by using laboratory microcosm experiments. Several earlier studies have shown enhancement of the decomposition process in the presence of nematodes, but nematode species-specific effects were never tested. In this study four bacterivorous nematode species were applied separately to microcosms to investigate such species-specific influences.No stimulation of the decomposition process nor of the microbial community was observed in the presence of the nematodes, both were highest in the absence of nematodes. However, clear differences were found between nematode treatments. P. paetzoldi reached much higher numbers than the other species, causing a decrease in microbial activity, probably due to (over)grazing. Remarkably this low microbial activity did not result in a slow-down of the decomposition process compared to the other nematode treatments, raising the question whether P. paetzoldi might be able to directly assimilate detrital compounds. Other nematode species reached much lower densities, but nevertheless an influence on the decomposition process was observed. However, this experiment does not support the view that bacterivorous nematodes enhance decomposition rate.The experimental results show that in nematode communities the use of functional groups is inadequate for biodiversity studies. The four nematode species used in this study belong to the same functional group, but are clearly not functionally redundant since they all have a different influence on the cordgrass decomposition. This suggests that the relationship between nematode species diversity and ecosystem functioning may be idiosyncratic.     

Vertical distribution of soil nematodes in an age sequence of <Emphasis Type="Italic">Caragana microphylla</Emphasis> plantations in the Horqin Sandy Land,Northeast China

The vertical distribution of soil nematodes down to a depth of 50 cm was studied in an age sequence of 0-, 5-, 10-, and 22-year-old Caragana microphylla plantations (treatments) in the Horqin Sandy Land, Northeast China. The abundances and generic compositions of nematode fauna in five soil layers (0–10, 10–20, 20–30, 30–40, and 40–50 cm) were analyzed. 42 genera were observed in the nematode suspensions, and Acrobeles was the dominant genus in all treatments. The results showed that the total number of nematodes and the generic diversity in an age sequence of C. microphylla plantations decreased with increasing soil depth. Significant differences in the numbers of total nematodes, bacterivores (BF), plant parasites (PP), and omnivores–predators (OP) were observed between treatments and depths. BF was the most abundant trophic group in our study, followed by OP. The numbers of OP showed an obviously increasing trend with increasing age of C. microphylla plantation. The vertical distribution of the soil nematode communities was related to gradual changes in soil chemical properties, and it indicated that C. microphylla plantations have played positive roles in improving soil environmental conditions and restoring desertified ecosystems in the Horqin Sandy Land. The ecological indices selected were influenced by plantation chronosequence but not by soil depth.     

The bacterial community of entomophilic nematodes and host beetles

Insects form the most species‐rich lineage of Eukaryotes and each is a potential host for organisms from multiple phyla, including fungi, protozoa, mites, bacteria and nematodes. In particular, beetles are known to be associated with distinct bacterial communities and entomophilic nematodes. While entomopathogenic nematodes require symbiotic bacteria to kill and reproduce inside their insect hosts, the microbial ecology that facilitates other types of nematode–insect associations is largely unknown. To illuminate detailed patterns of the tritrophic beetle–nematode–bacteria relationship, we surveyed the nematode infestation profiles of scarab beetles in the greater Los Angeles area over a five‐year period and found distinct nematode infestation patterns for certain beetle hosts. Over a single season, we characterized the bacterial communities of beetles and their associated nematodes using high‐throughput sequencing of the 16S rRNA gene. We found significant differences in bacterial community composition among the five prevalent beetle host species, independent of geographical origin. Anaerobes Synergistaceae and sulphate‐reducing Desulfovibrionaceae were most abundant in Amblonoxia beetles, while Enterobacteriaceae and Lachnospiraceae were common in Cyclocephala beetles. Unlike entomopathogenic nematodes that carry bacterial symbionts, insect‐associated nematodes do not alter the beetles' native bacterial communities, nor do their microbiomes differ according to nematode or beetle host species. The conservation of Diplogastrid nematodes associations with Melolonthinae beetles and sulphate‐reducing bacteria suggests a possible link between beetle–bacterial communities and their associated nematodes. Our results establish a starting point towards understanding the dynamic interactions between soil macroinvertebrates and their microbiota in a highly accessible urban environment.     

Trampling and Spatial Heterogeneity Explain Decomposer Abundances in a Sub-Arctic Grassland Subjected to Simulated Reindeer Grazing

Mammal grazing is composed of three mechanisms—removal of foliar tissue (defoliation), return of nutrients via dung and urine (fertilization), and trampling. To evaluate the relative role of these mechanisms in the effect of reindeer grazing on soil biota in northern grasslands, we subjected experimental plots in a sub-arctic alpine meadow to defoliation, fertilization (using NPK-solution), simulated trampling, and their factorial combinations once a year from 2002 to 2004 and measured the response of plants and decomposers (including microbes, nematodes, collembolans, and enchytraeids) in 2004. Trampling affected both plant and decomposer communities: the coverage of the moss Pleurozium schreberi and the sedge Carex vaginata, as well as the abundance of collembolans and enchytraeids were reduced in trampled plots. Trampling and fertilization also interacted significantly, with fertilization increasing the abundance of bacteria and bacterial-feeding and omnivorous nematodes in trampled plots only, and trampling decreasing fungal biomass in non-fertilized plots only. Defoliation had no overall effects on plants or decomposers. Nematode genera were not affected by the experimental treatments, but nematode and plant communities were significantly associated, and all decomposer biota, except collembolans, were strongly affected by the spatial heterogeneity of the study site. Our results indicate that trampling may have larger and defoliation and fertilization smaller roles than anticipated in explaining reindeer grazing effects in sub-arctic grasslands. However, even the effects of trampling seem to be outweighed by the spatial heterogeneity of decomposer abundances. This suggests that in sub-arctic grasslands spatial variation in abiotic factors can be a more important factor than grazing in controlling soil biota abundances. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users. Author contributions  LIS was involved in planning of the study, fieldwork, lab work, analysis, and wrote the article with contributions from all other authors; JM and MMK conceived the study and contributed to the data analyses; MMK further contributed to the field work and JM refined the final appearance of the text; JO started and was responsible for managing the field experiment, collecting the plant data and gave advice on statistical analysis.     

青藏高原不同牧草人工草地对土壤线虫群落的影响

为缓解草蓄矛盾,青藏高原人工草地得到快速发展。土壤线虫对环境变化敏感,是草地生态系统的重要组成部分。然而,不同牧草人工草地对土壤线虫群落的影响尚不明确。2016年7月,对多年生禾本科(垂穗披碱草Elymus nutans Griseb.、老芒麦Elymus sibiricus L.、早熟禾Poa annua L.和羊茅Festuca ovina L.)、一年生禾本科燕麦Avena sativa L.和多年生豆科紫花苜蓿Medicago sativa L.等6种单播牧草人工草地(建植期4年)和天然草地(对照)的土壤线虫群落进行了调查。结果表明：(1)土壤线虫隶属于2纲8目32科58属,平均密度为1754个/100 g干土;紫花苜蓿样地的线虫密度最低,为949个/100 g干土;燕麦样地最高,为3267个/100 g干土;(2)与天然草地相比,燕麦样地的线虫群落总密度、多样性以及植食性和杂食-捕食性线虫密度显著增加,而其他人工草地的线虫群落密度、多样性以及植食性、食真菌和食细菌线虫密度均无显著变化;(3)土壤线虫总密度以及各营养类群密度在不同人工草地间差异显著,且均在燕麦样地最高;(4)建...     

Low-level herbivory by root-knot nematodes (Meloidogyne incognita) modifies root hair morphology and rhizodeposition in host plants (Hordeum vulgare)

Low amounts of root infestation by plant parasitic nematodes are suggested to increase nutrient supply and in turn enhance microbial activity and net mineralization rate in the rhizosphere. These effects are generally related to “leakage” of plant-derived metabolites from damaged roots. Besides leakage, the present study examines other nematode–host interactions such as alterations in root exudation and morphology, which were almost not considered yet. This includes undamaged root parts in order to assess systemic plant response. The root-knot nematode Meloidogyne incognita (Kofoid and White 1919; Chitwood 1949) and barley (Hordeum vulgare L. cv. Europa) was used as model system. Host plants were grown in mini-rhizotrons inoculated with 0, 2,000, 4,000 or 8,000 M. incognita for 4 weeks. Root morphology, rhizodeposition (sugars, carboxylates, amino acids), and rhizosphere microbial communities (PLFAs) were assessed. In treatments with 4,000 nematodes, shoot biomass, total N and P content increased by the end of the experiment. Generally, an enhanced release of plant metabolites (sugars, carboxylates, amino acids) from the apical root zone occurred 1 week after inoculation with 4,000 and 8,000 M. incognita, indicating root leakage. Low levels of root herbivory stimulated root hair elongation in both infected and uninfected roots. These systemic changes in root morphology likely contributed to the increased sugar exudation in uninfected roots in all nematode treatments at 3 weeks after inoculation. Root-knots formed a separate microhabitat within the root-system. They were characterised by decreased rhizodeposition and increased fungal to bacterial ratio in the adhering rhizosphere soil. The present study provides the first evidence that, apart from leakage, nematode root herbivory at background levels induces local and systemic effects on root morphology and exudation, which in turn may affect plant performance.     

氮磷添加对黄土旱塬农田土壤线虫群落及能量结构的影响

为探究氮磷添加对黄土旱塬农田土壤线虫群落结构和微食物网中能量流动的影响,以中国科学院长武农业生态实验站长期施用氮磷肥农田土壤作为研究对象,选取6个处理,分别为:不施肥(CK),氮添加(N₁₂、N₂₄),磷添加(P₁₂、P₂₄),氮磷添加(N₁₂P₁₂),测定土壤理化性质,采用浅盘法分离线虫,分析线虫营养类群结构和生活史征,并计算线虫生态学指数,代谢足迹和食物网内部能量流动数值。结果表明:不同处理土壤的植物寄生线虫(Pp)比例显著高于其他类群(50.7%-66.4%),生活史为低营养级r策略者(cp2)的线虫类群比例也显著高于其他类群(68.1%-84.0%)。P₁₂处理的线虫丰度最高,为1147条/100 g干土,其次是P₂₄处理,为1100条/100 g干土。与CK相比,两种磷添加处理显著增加了香农多样性指数(H),提升了食真菌和捕食杂食线虫的代谢足迹,微食物网中拥有更高的能量通量,其余处理对线虫丰度和代谢足迹没有产生影响。与N₂₄处理相比,N₁₂处理显著增加了线虫群落的H,均匀度指数(J)和丰富度指数(SR)。N₁₂P₁₂处理增加了高营养级k策略者(cp4-5)的线虫数量,显著提高了结构指数(SI)。冗余分析表明,土壤中全磷和速效磷含量是影响线虫丰度和代谢足迹的主要环境因子。综上所述,适量氮添加提升了土壤线虫群落多样性和结构稳定性,过量氮添加会抵消这种积极影响。磷添加对线虫群落和代谢足迹产生积极影响并提高了土壤微食物网的能量通量,氮磷添加则为土壤线虫创造了适宜的生存环境。这一结果为黄土区农田土壤的施肥措施提供了科学依据。     

Interactions between Zeldia Punctata (Cephalobidae) and bacteria in the presence or absence of maize plants

Bacterial-feeding nematodes constitute one of the primary grazers of soil bacteria. We investigated the effects of selective grazing of a representative nematode (Zeldia punctata, Cephalobidae) on nematode life history and population biology and on the soil microbial community. Firstly, we measured (i) the effect of five different bacterial strains on the nematode life cycle using petri dishes and (ii) the impact of bacterial inoculation on nematode population growth in a soil microcosm. Selection of the five bacterial strains was based on morphology, cell-wall characteristics and mucus production. Z. punctata development was strongly affected by the type of bacteria ingested, independent of experimental design. Bacterial cell-wall characteristics seemed to directly affect Z. punctata development since high nematode densities were only reached with gram-negative strains (Pseudomonas monteilii and Methylobacterium nodulans). In petri dishes, the filamentous organisms (Actinomyces sp.) and mucus-producing bacteria (Bradyrhizobium sp.) led to the least reproduction. Duration of the various nematode life phases (egg, juvenile, reproductive stage and non-reproductive stage) was significantly affected by the bacterial food source. Total life span varied from 12.5 days (Bradyrhizobium sp.) to 40 days (Pseudomonas monteilii). Secondly, we monitored the influence of Z. punctata on the indigenous soil microbial community in the presence or absence of a maize plantlet. Nematode inoculation led to an increase in bacterial activity (as measured by alkaline phosphatase activity) but did not significantly influence bacterial biomass. The genetic fingerprint (DGGE) of soil bacteria was more influenced by plant presence than by nematode inoculation. Nematode activity has important repercussions on N flux in the soil since inoculation of Z. punctata in the absence of plants resulted in a net increase of N mineralization (2 mg N per pot) while a decrease of mineral N (0.5 mg N per pot) was observed in the absence of the nematodes, due to bacterial immobilization. This study underscores the close relationship between selective bacterial grazing and nematode development. Nevertheless, the impact of nematode grazing on the overall soil microbial community seems to primarily affect microbial activity and relative dominance rather than microbial diversity.     

Soil microorganisms control plant ectoparasitic nematodes in natural coastal foredunes

Belowground herbivores can exert important controls on the composition of natural plant communities. Until now, relatively few studies have investigated which factors may control the abundance of belowground herbivores. In Dutch coastal foredunes, the root-feeding nematode Tylenchorhynchus ventralis is capable of reducing the performance of the dominant grass Ammophila arenaria (Marram grass). However, field surveys show that populations of this nematode usually are controlled to nondamaging densities, but the control mechanism is unknown. In the present study, we first established that T. ventralis populations are top-down controlled by soil biota. Then, selective removal of soil fauna suggested that soil microorganisms play an important role in controlling T. ventralis. This result was confirmed by an experiment where selective inoculation of microarthropods, nematodes and microbes together with T. ventralis into sterilized dune soil resulted in nematode control when microbes were present. Adding nematodes had some effect, whereas microarthropods did not have a significant effect on T. ventralis. Our results have important implications for the appreciation of herbivore controls in natural soils. Soil food web models assume that herbivorous nematodes are controlled by predaceous invertebrates, whereas many biological control studies focus on managing nematode abundance by soil microorganisms. We propose that soil microorganisms play a more important role than do carnivorous soil invertebrates in the top-down control of herbivorous ectoparasitic nematodes in natural ecosystems. This is opposite to many studies on factors controlling root-feeding insects, which are supposed to be controlled by carnivorous invertebrates, parasitoids, or entomopathogenic nematodes. Our conclusion is that the ectoparasitic nematode T. ventralis is potentially able to limit productivity of the dune grass A. arenaria but that soil organisms, mostly microorganisms, usually prevent the development of growth-reducing population densities.     

Grazing in a porous environment. 2. Nematode community structure

The influence of soil matric potential on nematode community composition and grazing associations were examined. Undisturbed cores (5 cm diameter, 10 cm depth) were collected in an old field dominated by perennial grasses on a Hinckley sandy loam at Peckham Farm near Kingston, Rhode Island. Ten pairs of cores were incubated at −3, −10, −20 and −50 kPa matric potential after saturation for 21–28 or 42–58 days. Nematodes were extracted using Cobb's decanting and sieving method followed by sucrose centrifugal-flotation and identified to family or genus. Collembola and enchytraeids present were also enumerated because they are grazers that reside in air-filled spaces. Direct counts of bacteria and fungi were made to estimate biovolume using fluorescein isothiocyanate and fluorescein diacetate stains, respectively. Trophic diversity and maturity indices were calculated for nematode communities. Three patterns of matric potential effect were observed for nematode taxa. One, there was a consistent effect of matric potential for all seasons for Alaimus, Monhysteridae, Prismatolaimus, Paraxonchium and Dorylaimoides. Two, some effects of matric potential were consistent among seasons and other effects were inconsistent for Aphelenchoides, Aphelenchus, Cephalobidae, Coomansus, Eudorylaimus, Huntaphelenchoides, Panagrolaimidae, Paraphelenchus, Sectonema, and Tripyla. Third, effects of matric potential were always inconsistent among seasons for Aphanolaimus, Aporcelaimellus, Bunonema, Rhabditidae, and Tylencholaimus. As predicted, fungal and bacterial biomass responded oppositely to matric potential. Total bacterial biomass was greater at −3 kPa than −10, −20 and −50 kPa (P=0.0095). Total fungal biomass was greater at −50, −20 and −10 kPa than −3 kPa (P=0.0095). Neither bacterial-feeding, fungal-feeding nor predacious nematodes correlated significantly with bacterial or fungal biomass. Omnivorous and predacious nematodes correlated positively with number of bacterial-feeding nematodes; predacious nematodes also correlated positively with fungal-feeding nematodes. Numbers of Collembola and enchytraeids were more often correlated positively with microbial-grazing nematode numbers in drier than moist soils. From this study, we propose two mechanisms that may explain nematode community structure changes with matric potential: differential anhydrobiosis and/or enclosure hypotheses. The later suggests that drying of soil generates pockets of moisture in aggregates that become isolated from one another enclosing nematodes and their food in relatively high concentrations creating patches of activity separated by larger areas of inactivity. This revised version was published online in June 2006 with corrections to the Cover Date.     

Interactions between bacteria-feeding nematodes and bacteria in the rape rhizosphere: effects on root exudation and distribution of bacteria

Abstract Effects of rhizosphere bacteria (RB), and rhizosphere bacteria with bacteria-feeding nematodes (RBN), on the composition of root exudate were examined after 2 weeks in gnotobiotic culture systems with rape seedlings ( Brassica napus (L.)). The amounts of low molecular weight carbohydrates and of some free amino acids, per unit root dry weight, in the exudates were lower in the RB and RBN treatments than in the axenic control (R treatment). The growth of nematodes implied a production of bacterial cells in the RBN treatment 2.6 times that in the RB treatment. The bacterial growth in the RB treatment and the bacterial growth in combination with grazing by nematodes in the RBN treatment implied 24 and 63 times as much exudation of organic carbon, respectively, as in the R treatment.
Most bacteria were attached to sand particles. The nematodes being suspension-feeders, decreased the proportion of free bacteria from 6% in the RB treatment to 2% in the RBN treatment. The numbers of attached bacteria in the RBN treratment were positively correlated with the numbers of nematodes, indicating stimulation of bacterial growth by the grazing.     

天然高寒草地转变为燕麦人工草地对土壤线虫群落的影响

为查明高寒草地上种植燕麦(Avena sativa)对土壤线虫群落的影响,于2014年7、9月用土钻法和湿漏斗法(Baermann法)对西南民族大学青藏高原畜牧业高科技研发示范基地内燕麦地(Oat grassland,OG)和天然草地(Natural grassland,NG)的土壤线虫群落进行调查。共分离土壤线虫10179条,隶属于2纲8目50科143属,平均密度477条/100g干土。燕麦地与天然草地土壤线虫群落结构具有明显差异,影响群落结构的主要类群为拟丽突属(Acrobeloides)、原杆属(Protorhabditis)、丝尾垫刃属(Filenchus)和盘旋属(Rotylenchus),但不同月份间存在差异。燕麦地的土壤线虫群落密度、食细菌线虫密度、食真菌线虫密度和自由生活线虫成熟度指数(MI)均显著高于天然草地(P0.01;P0.05;P0.001;P0.01),植物寄生线虫成熟度指数(PPI)则显著低于天然草地(P0.05)。两种草地7月份的土壤线虫群落类群数和香农多样性指数(H′)均显著低于9月(P0.05),仅燕麦地7月份的食细菌、食真菌线虫密度和Simpson优势度指数(C)显著高于9月(P0.05;P0.001;P0.01)。典范对应分析(Canonical correspondence analysis,CCA)及回归分析结果表明,土壤pH、有机质、全氮、速效磷和含水量是影响线虫群落的主要环境因子。研究结果表明,高寒草地种植燕麦后在短期内改变了线虫群落结构,增加了线虫群落密度以及食细菌和食真菌线虫在群落中的比例,以植物寄生线虫为主的群落营养结构转变为以食细菌线虫为主,同时也增加了线虫群落不同月份间的差异。