若尔盖高寒草甸退化对中小型土壤动物群落的影响

土壤动物是陆地生态系统物质循环和能量流动的中心环节,也是生态系统演化的重要驱动因子。为了查明青藏东缘若尔盖高寒草甸生态系统退化过程对中小型土壤动物群落的影响,2008年7、10两月分别对若尔盖高寒草甸沼泽草甸、草原草甸和沙化草甸三个不同退化阶段的中小型土壤动物群落进行了调查。共分离到中小型土壤动物9450个,隶属于4门5纲12目70科104类;优势类群为线虫（Nematode）,个体数占85.79%;蜱螨目（Arachnida）、弹尾目（Collembola）、寡毛纲（Oligochaeta）和昆虫纲（Insect）依次占8.73%、3.24%、1.32%和0.88%。群落密度、类群数、Margalef丰富度指数和密度-类群指数均在7、10两月份均随高寒草甸的退化而显著降低（p<0.01或p<0.05）,10月份的差异更明显。Shannon-wiener多样性指数、Pielou均匀性指数和Simpson优势度指数无显著变化（p>0.05）。各主要类群个体数在群落中所占的比例呈波动性变化,但沙化可使蜱螨目的数量相对提高,而弹尾目相对下降。随退化程度的加重,三个退化阶段的Sorenson群落相似性逐渐降低,而Morisita-Horn相似性的变化则不同,说明高寒草甸的退化对中小型土壤动物群落物种组成的影响较大,对群落优势类群数量的影响较小。10月份的群落密度、多样性和群落相似性均高于7月份,表明群落结构组成受季节的影响;但是各退化阶段的Sorenson和Morisita-Horn季节相似性比较说明,季节变化对沙化草甸种类组成的影响大于草原草甸,对草原草甸群落优势类群数量的影响大于沙化草甸。个体密度和类群数的表聚性程度也随退化加重而降低。以上研究结果表明,高寒草甸的退化能够降低土壤动物群落的组成种类和结构复杂性,将会影响其生态服务功能。     

海南尖峰岭热带林土壤动物群落——群落的组成及其特征

以海南尖峰岭自然保护区热带山地雨林为标准样地,研究热带土壤动物在原始生境中的群落结构。样地设５个固定取样点,每月固定时间用３种方法,对原生动物、线虫和其它大、中型土壤动物分别取样。调查结果显示：（１）以风干土培养法获得的原生动物共有１８目７２种,种类以纤毛虫类为主,数量则以肉足虫类为主。本调查点与以北各地带相比,其分布的种类较少,这与热带林枯枝落叶层薄有关。（２）以湿漏斗法获得的线虫有７目７６种,为国内各地带之首。其中矛线目种类及个体数量均占多数。（３）以手拣和大、小于漏斗法获得的土壤动物共有３２个类群（以目为主）,其多样性指数（Ｈ′）高于本区以北各地带调查点。类群的重要性,按平均数量及其稳定性来排序,排在最前的几个类群有蚂蚁、鞘翅目、蚯蚓、及等翅目等。比西双版纳热带沟谷雨林的土壤动物群落结构更具热带性。     

热带次生林刀耕火种过程中土壤节肢动物群落结构及多样性的变化

通过模拟刀耕火种过程,对热带次生林土壤节肢运动群薄结构及多样性在刀耕火种过程中变化进行了初步研究,结果表明,火烧1周后,土壤节肢运行类群数和个体数从次生林地的14类,564头降为7类,164头,并且在群落组成上发生了较大变化,膜翅目的烧后1天成为突出优势类群,蜱蟥目在烧后1周成为唯一的优势类群,而在多样性方面,土壤节肢运动群落类群数（丰度）,个体数（多度）和DG多样性指数在刀耕火种过程中均降低,土壤节肢运动的垂直分布因刀耕火种干扰发生了很大变化,尚存土壤节肢运动随干扰强度的加剧,出现逐步由土壤表层向深层迁移的现象,一些土壤节肢运动在土层间做垂直迁移活动,说明土壤层在一定程度上减轻了刀耕火种对它们的破坏作用,维持了某些类群数量及群落多样性。     

豚草发生地土壤动物的初步研究

土壤动物个体数量和类群数随着际的推进而增加,8月份达到最高值。8月份和9月份,豚草发生地土壤动物个体数量和类群数明显少于对照样地。豚草对于土壤动物的抑制作用具有类群上的选择性,对线虫类和线蚓类的抑制作用更强。豚草对土壤动物的影响,生殖生长期大于营养生长期,普通豚草大于三裂叶豚草,豚草纯群落大于豚草与其它植物混生群落。     

热带次生林、旱稻种植地和火烧迹地土壤节肢动物群落结构特征及季节变化

通过模拟刀耕火种过程 ,对刀耕火种前后的次生林、旱稻地 (第 2年 )和火烧迹地 (火烧后直接撂荒地第 2年 )土壤节肢动物群落结构特征及季节变化进行了调查研究。结果显示 :3块样地土壤节肢动物群落的优势类群组成相同 ,均为蜱螨目、膜翅目和弹尾目 ,但不同生境样地中各优势类群所占群落总数的比例不同 ,并且 3样地常见和稀有类群的组成差异较大 ;土壤节肢动物类群数、个体数和 DG多样性指数表现为次生林高于其它 2块样地 ,而旱稻地和火烧迹地则无较大差异 ,但一些类群在旱稻地、火烧迹地的数量分布与次生林具有差异 ,且在土壤层的表现较为突出 ;3块样地土壤节肢动物群落具有较好相似性 ,其中旱稻地与火烧迹地达到极相似水平 (D、DS>0 .9)。3种不同类型生境土壤节肢动物群落在类群数、个体数和多样性指数的季节变化总体呈现出雨量少的干季或雨季初末期高于雨量最大的雨季中期 ,与当地降雨量和气温变化有密切关系 ,同时各样地土壤节肢动物群落因生境条件不同及人为活动干扰强弱而形成各自的季节消长特点。研究表明刀耕火种后的旱稻种植对土壤节肢动物群落的恢复和发展在一定限制条件 (面积、周围次生林和坡度 )下无破坏性影响 ,但植被改变、农事活动等对直接撂荒地和旱稻地土壤节肢动物群落的季节消长产生     

季节变化对沙漠生态系统土壤中自由生活线虫和原生动物间营养关系的影响

选择沙漠常绿灌木丛枝霸王(Zygophyllum dumosum)群落及群落间的开阔地带采样,研究土壤线虫和原生动物的种群大小、物种组成及营养结构.本研究共获线虫29属,裸变形虫33属90种;在所获各类原生动物中,鞭毛虫和纤毛虫均为食细菌类群,而鞭毛虫个体数量最多;在沙漠生态系统中,土壤湿度被认为是影响生物活性的最重要因素之一.然而,本研究显示:土壤湿度对线虫和原生动物是否重要取决于这些动物对土壤湿度的生理生态适应能力;土壤线虫和原生动物的体型大小、生活史策略和活动能力与土壤湿度的有效性相关不显著,但它们对微生物和微小土壤动物区系间的相互作用有重要影响,在干旱生态系统中,这种影响能够显著改变土壤生态系统短期的养分循环.本研究还表明,土壤线虫和原生动物种群间的关系主要取决于两者营养类群组成的变化.     

城市化地区不同生境下中小型土壤动物群落结构特征

2007年5月（春季）、7月（夏季）、11月（秋季）和2008年1月（冬季）,对广州市天河区3种土地利用类型（林地、人工绿地、农田）下6个不同生境的中小型土壤动物群落的结构特征和季节变化进行了调查研究.结果表明：研究区不同生境下中小型土壤动物的水平分布有所不同.调查期间,华南农业大学树木园捕获的中小型土壤动物个体数最多,达1286个,农用地中捕获的个体数较少,以凤凰街农用地中小型土壤动物的个体数和类群数最低;研究区各样地中小型土壤动物的个体数总量有明显的季节消长,由高到低依次为：秋季（1815）>春季（1623）>冬季（1365）>夏季（1276）.聚类与排序结果也说明不同生境样地的中小型土壤动物的群落结构组成随季节不同而呈现出明显的变化规律,同一季节不同生境的中小型土壤动物群落的组成和结构差异与人为干扰程度、土壤环境因素等有关.     

刈割活动对松嫩草原碱化羊草草地土壤线虫群落的影响

应用类群数、个体密度、多样性指数和功能类群指数等多个群落参数, 研究刈割活动对松嫩草原碱化羊草草地土壤线虫群落特征的影响。本研究共捕获土壤线虫8,335条, 分别隶属于线虫动物门2纲7目23科40属。结果表明, 与围栏封育样地相比, 刈割活动样地中线虫个体密度和类群数显著减少, 群落多样性指数(H′)、均匀度指数(J)和丰富度指数(SR)虽低于围栏封育样地, 但两类处理间差异不显著, 表明刈割活动尽管明显降低土壤线虫群落个体密度和类群数, 但对土壤线虫群落多样性的影响有限; 样地间PPI／MI值差异明显, 表明刈割活动在一定程度上确实改变了土壤线虫功能类群组成, 其中受影响的主要是非植物寄生线虫。     

江苏常熟虞山土壤动物群落多样性研究

对江苏省常熟市虞山国家森林公园内的土壤动物进行了调查,共采得土壤动物样本 3916个,隶属于 5门 10纲,共26类群。蜱螨目、弹尾目和线虫纲是优势类群,占个体总数的88.22％,它们构成了该地区土壤动物的主体。对针阔混交林、竹林和茶园的土壤动物群落结构分析表明:土壤动物密度、类群数、多样性指数(H’)、密度-类群指数(DG)和多群落比较多样性指数(DIG)排序均为针阔混交林>茶园>竹林。茶园的均匀度指数最高。竹林的优势度指数最大。不同群落的相似性(q)分析表明,3种生境的土壤动物群落两两间的相似性指数q均大于0.5,都达到了中等相似水平。土壤动物的类群数垂直分布有明显差异,类群数向下逐渐减少。     

吉林省中西部平原区土壤线虫群落生态特征

于 2 0 0 3年 7月和 9月 ,在吉林省中西部平原区进行土壤线虫取样 ,10个采样区 2 8个调查样地 2次共捕获线虫 10 2 2 0只 ,个体密度平均 182 5 0只 /m2 ,分别隶属于线形动物门 2纲 7目 2 0科 32属。真滑刃属、短体属和垫刃属为优势类群 ,是吉林省中西部平原区土壤线虫群落最重要的类群 ,稀有类群个体数量尽管很少 ,但分布的范围并不狭小 ,线虫各类群空间分布的广狭与个体数量的多寡在吉林省中西部平原区并末呈现出明显的一致性。土壤线虫群落垂直分布 ,受人类活动扰动的生境土壤线虫类群数和个体密度表聚性较差 ,土壤线虫向土壤下层移动明显 ;水平分布 ,天然林和受人类活动扰动生境土壤线虫类群数和个体密度差异显著 ;农田土地利用方式对土壤线虫群落特征影响总体是负面的 ,而居民点园地可能增加土壤线虫的类群数和生物多样性。 PPI/MI值对于不同人类活动对土壤生态环境的变化反映更敏感     

Impact of protozoan grazing on bacterial community structure in soil microcosms

The influence of grazing by a mixed assemblage of soil protozoa (seven flagellates and one amoeba) on bacterial community structure was studied in soil microcosms amended with a particulate resource (sterile wheat roots) or a soluble resource (a solution of various organic compounds). Sterilized soil was reinoculated with mixed soil bacteria (obtained by filtering and dilution) or with bacteria and protozoa. Denaturing gradient gel electrophoresis (DGGE) of PCR amplifications of 16S rRNA gene fragments, as well as community level physiological profiling (Biolog plates), suggested that the mixed protozoan community had significant effects on the bacterial community structure. Excising and sequencing of bands from the DGGE gels indicated that high-G+C gram-positive bacteria closely related to Arthrobacter spp. were favored by grazing, whereas the excised bands that decreased in intensity were related to gram-negative bacteria. The percentages of intensity found in bands related to high G+C gram positives increased from 4.5 and 12.6% in the ungrazed microcosms amended with roots and nutrient solution, respectively, to 19.3 and 32.9% in the grazed microcosms. Protozoa reduced the average bacterial cell size in microcosms amended with nutrient solution but not in the treatment amended with roots. Hence, size-selective feeding may explain some but not all of the changes in bacterial community structure. Five different protozoan isolates (Acanthamoeba sp., two species of Cercomonas, Thaumatomonas sp., and Spumella sp.) had different effects on the bacterial communities. This suggests that the composition of protozoan communities is important for the effect of protozoan grazing on bacterial communities.     

Protozoan Response to the Addition of Bacterial Predators and Other Bacteria to Soil

Representatives of several categories of bacteria were added to soil to determine which of them might elicit responses from the soil protozoa. The various categories were nonobligate bacterial predators of bacteria, prey bacteria for these predators, indigenous bacteria that are normally present in high numbers in soil, and non-native bacteria that often find their way in large numbers into soil. The soil was incubated and the responses of the indigenous protozoa were determined by most-probable-number estimations of total numbers of protozoa. Although each soil was incubated with only one species of added bacteria, the protozoan response for the soil was evaluated by using most-probable-number estimations of several species of bacteria. The protozoa did not respond to incubation of the soil with either Cupriavidus necator, a potent bacterial predator, or one of its prey species, Micrococcus luteus. C. necator also had no effect on the protozoa. Therefore, in this case, bacterial and protozoan predators did not interact, except for possible competition for bacterial prey cells. The soil protozoa did not respond to the addition of Arthrobacter globiformis or Bacillus thuringiensis. Therefore, the autochthonous state of Arthrobacter species in soil and the survival of B. thuringiensis were possibly enhanced by the resistance of these species to protozoa. The addition of Bacillus mycoides and Escherichia coli cells caused specific responses by soil protozoa. The protozoa that responded to E. coli did not respond to B. mycoides or any other bacteria, and vice versa. Therefore, addition to soil of a nonsoil bacterium, such as E. coli, did not cause a general increase in numbers of protozoa or in protozoan control of the activities of other bacteria in the soil.     

贺兰山不同海拔植被下土壤微生物群落结构特征

为明确海拔变化对干旱区山地森林土壤微生物群落的影响,揭示环境因子改变后土壤微生物群落结构特征及影响因素。对贺兰山5个海拔梯度土壤理化性质进行测定,同时采用磷酸脂肪酸(PLFA)图谱法分析土壤微生物群落组成,通过主成分分析、冗余分析(RDA)探究土壤理化性质与土壤微生物群落相对丰度之间的相关关系。结果表明:土壤养分含量在不同海拔之间差异性显著(P<0.05),土壤有机碳和全氮含量随海拔的升高而升高,全磷含量随海拔升高先升高再降低再升高;土壤微生物量随海拔升高先升高后降低,土壤微生物的相对丰度在不同海拔之间存在差异(P<0.05);主成分分析表明,与第1主成分相关性较强的微生物类群为革兰氏阳性细菌(G~+)、革兰氏阴性细菌(G~-)和真菌;与第2主成分相关性较强的微生物类群为放线菌、原生动物和非特异性细菌。非特异性细菌和真菌与各土壤因子之间均有显著相关关系,而放线菌、G~+和G~-与各土壤因子相关性较弱,原生动物与土壤全磷含量的关系密切。海拔是影响特征微生物分布的重要因素,特征微生物的含量和相对丰度随海拔的升高先升高后降低,符合山地生态学中的"中部膨胀"理论。探明了贺兰山不同海...     

Protozoan community structure in a fractal soil environment.

Protozoan abundance was quantified, and 365 protozoan species were recorded, in 150 soil samples from an upland grassland in Scotland. Across the entire size range (2-200 pm) protozoan species richness varied by a factor of two, whereas abundance increased by a factor of 20 with decreasing body size. As the soil had fractal structure, the relatively flat species curve can be explained if spatial heterogeneity determines species number--for in a fractal environment, heterogeneity will be the same at all spatial scales. Community structure appeared to approach a temporary steady-state about six days after re-hydration of dried soil. A simple model based on combining the fractal character of increasing habitat area at smaller spatial scales, with the weight-specific energy requirements of protozoa, provided theoretical curves of abundance and biovolume on body size which provide a reasonable fit to real data. We suggest two possibilities--that the apparent competence of the theoretical model is fortuitous and the product of poorly understood dynamic elements of the trophic structure in the community; or that key elements of protozoan community structure in a fractal soil environment may be largely explained in terms of habitat space and energy requirements.     

土壤原生动物对环境污染的生物指示作用

土壤原生动物具有丰富的种类和巨大的生物量,在土壤生态系统中具有十分重要的地位．作为指示生物,土壤原生动物具有与其他土壤动物相比更独特的优势．研究它们的群落结构、数量及多样性动态变化,可以很好地评价和监测自然环境变化及人类活动带来的环境污染．本文根据国内外相关文献,简要概述了土壤原生动物在生态系统中的作用．对原生动物的生物指示物优势、土壤原生动物对环境因子响应和污染指示作用及对大气CO2浓度变化的响应等进行了论述,并对土壤原生动物在生态毒理诊断中的应用前景进行了展望．     

Plant metabolomics for plant chemical responses to belowground community change by climate change

General circulation models on global climate change predict increase in surface air temperature and changes in precipitation. Increases in air temperature (thus soil temperature) and altered precipitation are known to affect the species composition and function of soil microbial communities. Plant roots interact with diverse soil organisms such as bacteria, protozoa, fungi, nematodes, annelids and insects. Soil organisms show diverse interactions with plants (eg. competition, mutualism and parasitism) that may alter plant metabolism. Besides plant roots, various soil microbes such as bacteria and fungi can produce volatile organic compounds (VOCs), which can serve as infochemicals among soil organisms and plant roots. While the effects of climate change are likely to alter both soil communities and plant metabolism, it is equally probable that these changes will have cascading consequnces for grazers and subsequent food web components aboveground. Advances in plant metabolomics have made it possibile to track changes in plant metabolomes as they respond to biotic and abiotic environmental changes. Recent developments in analytical instrumentation and bioinformatics software have established metabolomics as an important research tool for studying ecological interactions between plants and other organisms. In this review, we will first summarize recent progress in plant metabolomics methodology and subsequently review recent studies of interactions between plants and soil organisms in relation to climate change issues.     

Estimating the growth potential of the soil protozoan community

We have developed a method for determining the potential abundance of free-living protozoa in soil. The method permits enumeration of four major functional groups (flagellates, naked amoebae, testate amoebae, and ciliates) and it overcomes some limitations and problems of the usual 'direct' and 'most probable number' methods. Potential abundance is determined using light microscopy, at specific time intervals, after quantitative re-wetting of air-dried soil with rain water. No exogenous carbon substrates or mineral nutrients are employed, so the protozoan community that develops is a function of the resources and inhibitors present in the original field sample. The method was applied to 100 soil samples (25 plots x 4 seasons) from an upland grassland (Sourhope, Southern Scotland) in the UK. Median abundances for all four functional groups lie close to those derived from the literature on protozoa living in diverse soil types. Flagellates are the most abundant group in soil, followed by the naked amoebae, then the testate amoebae and ciliates. This order is inversely related to typical organism size in each group. Moreover, preliminary evidence indicates that each functional group contains roughly the same number of species. All of these observations would be consistent with soil having fractal structure across the size-scale perceived by protozoa. The method described will be useful for comparing the effects on the soil protozoan community of different soil treatments (e.g. liming and biocides).     

Contrasting Soil Ciliate Species Richness and Abundance between Two Tropical Plant Species: A Test of the Plant Effect

We still have a rudimentary understanding about the mechanism by which plant roots may stimulate soil microbial interactions. A biochemical model involving plant-derived biochemical fractions, such as exudates, has been used to explain this “rhizosphere effect” on bacteria. However, the variable response of other soil microbial groups, such as protozoa, to the rhizosphere suggests that other factors could be involved in shaping their communities. Thus, two experiments were designed to: (1) determine whether stimulatory and/or inhibiting factors associated with particular plant species regulate ciliate diversity and abundance and (2) obtain a better understanding about the mechanism by which these plant factors operate in the rhizosphere. Bacterial and chemical slurries were reciprocally exchanged between two plant species known to differ in terms of ciliate species richness and abundance (i.e., Canella winterana and plantation Tectona grandis). Analysis of variance showed that the bacteria plus nutrients and the nutrients only treatment had no significant effect on overall ciliate species richness and abundance when compared to the control treatment. However, the use of only colpodean species increased the taxonomic resolution of treatment effects revealing that bacterial slurries had a significant effect on colpodean ciliate species richness. Thus, for particular rhizosphere ciliates, biological properties, such as bacterial diversity or abundance, may have a strong influence on their diversity and possibly abundance. These results are consistent with a model of soil bacteria-mediated mutualisms between plants and protozoa.     

Characteristics of soil fauna community in the Dongjiao coconut plantation ecosystem in Hainan, China

From July 2002 to July 2004, we investigated the soil fauna in the Dongjiao coconut plantation of Hainan Island. A total of 5,378 specimens were obtained. These species represented 4 phyla, 12 classes and 27 genera. The soil animal clusters are as follows: All major animal groups presented in a tropical rain forest are present in Dongjiao coconut plantation's soil community. The Dongjiao coconut plantation demonstrated the typical characteristics of a tropical soil animal community. The number of species and the diversity index (H) increase from the high latitude areas toward the equator; The dominance index (C) decreased from the high latitude areas toward the equator; the ratio of Acarina/Collembola and the percentage occurrence of increase along the declination of latitude; the occurrence of termites, a typical member of tropical community, varies from absent to present and a dramatic increase along the declination of latitude. Compared to primary tropical rainforests, the Dongjian coconut plantation community is relatively low in species diversity, and has a high dominance index and low diversity index. This may partially due to some characters of the plantation: singular tree species, monsoon climate, seashore location, high pH and salinity of the soil, soil moisture and other environmental factors. A seasonal change occurs in the community structure but is not obvious. Soil around human residences has a higher organic material content, and has higher counts of specimens and numbers of species, compared to other three sampling sites. Coconut production at locations around human residences is higher than at any other microhabitats. The high production is positively correlated with the richness of animal community in the soil.     

Characteristics of soil fauna community in the Dongjiao coconut plantation ecosystem in Hainan, China

From July 2002 to July 2004, we investigated the soil fauna in the Dongjiao coconut plantation of Hainan Island. A total of 5,378 specimens were obtained. These species represented 4 phyla, 12 classes and 27 genera. The soil animal clusters are as follows: All major animal groups presented in a tropical rain forest are present in Dongjiao coconut plantation's soil community. The Dongjiao coconut plantation demonstrated the typical characteristics of a tropical soil animal community. The number of species and the diversity index (H) increase from the high latitude areas toward the equator; The dominance index (C) decreased from the high latitude areas toward the equator; the ratio of Acarina/Collembola and the percentage occurrence of increase along the declination of latitude; the occurrence of termites, a typical member of tropical community, varies from absent to present and a dramatic increase along the declination of latitude. Compared to primary tropical rainforests, the Dongjian coconut plantation community is relatively low in species diversity, and has a high dominance index and low diversity index. This may partially due to some characters of the plantation: singular tree species, monsoon climate, seashore location, high pH and salinity of the soil, soil moisture and other environmental factors. A seasonal change occurs in the community structure but is not obvious. Soil around human residences has a higher organic material content, and has higher counts of specimens and numbers of species, compared to other three sampling sites. Coconut production at locations around human residences is higher than at any other microhabitats. The high production is positively correlated with the richness of animal community in the soil.