Biomass size spectra of net plankton in the adjacent area near the Yangtze River Estuary in spring

Based on data from survey carried out in spring 2005, the biomass size spectra of net plankton were explored in the adjacent sea of Yangtze River Estuary. Results revealed an approximately continuous size distribution of plankton individuals, from phytoplankton (5–250 μm cell^?1 in equivalent sphere diameter (ESD), 15 pg–146 ng C cell^?1) to zooplankton (120 μm–2 cm ESD, 115 ng–7.5 mg C ind^?1). The normalized spectra (carbon scale) were linear with slope ranged from –0.889 to –0.445, and intercept ranged from 12.866 to 16.863 (all stations together, slope = –0.606, intercept = 19.448), indicating strong deviations from the ideal value (slope = –1.22) of a steady pelagic ecosystem. Correlation analysis presented that intercept and regression coefficient of net plankton size spectra had significant relationship with plankton biomass size diversity.     

What determines the slope of a plankton biomass spectrum?

A number of studies have been performed to understand the characteristicsof biomass (size) spectra in aquatic plankton communities aroundthe world. Although the area below a biomass spectrum curverepresents the abundance or biomass of a plankton community,it has been hypothesized that the slope and shape of a biomassspectrum are determined by rates of growth, respiration, mortalityand trophic dynamics. Observations of biomass spectra indicatethat the slope of a biomass spectrum is around –1 on thelogarithmic coordinates. Empirical hypotheses of growth-survivaland the theoretical framework on biomass conservation basedon the rates of individual body growth and abundance changehave been developed for interpreting the slope and domes ofa biomass spectrum. Here, a mathematical method is developedfor estimating specific rates of body growth and abundance changefrom observations of biomass spectra, and a mathematical modelis constructed for the relationship between a biomass spectrumslope, community assimilation efficiency and trophic levels. This paper was presented in a session on "Size Structure ofPlankton Communities", at the ASLO Summer International Meeting,held in Santiago de Compostela, Spain, between 19 and 24 June,and coordinated by Xabier Irigoien, Roger Harris and Angel Lopez-Urrutia.     

春季长江口邻近外海网采浮游生物的生物量谱

对2005年春季黄海南部、东海北部近江口外海水域网采的浮游生物个体大小的粒径分布进行研究,确定各粒级大小的功能群组成,建立此季该调查水域网采浮游生物的生物量谱.样品是用小、中、大型浮游生物网(网孔径为77、160、 505μm)采集所得.三网具采集浮游生物个体大小粒径是连续的,其中浮游植物,其等效粒径(ESD)和含碳量范围分别为5～250μm、15pg～146ng;浮游动物,含碳量范围为115ng～7.5mg,ESD分别为120μm～5.8mm、200μm～2cm.所得网采浮游生物的标准生物量谱,总测区的斜率为-0.607±0.059、截距为19.45±0.46;各站位的生物量谱斜率为-0.889～-0.455、截距为12.866～16.863,两特征参数分布规律为南高北低,且具有显著的站位间差异.相关性分析表明截距和回归系数与粒级多样性有关.     

生态学研究中的分析与能值分析理论

与能值是研究生态系统自组织过程的两个重要的目标函数。分析与能值分析理论在 2 0世纪 70年代开始应用于生态学研究 ,它们有各自的理论起点 ,在应用上从不同的角度表现生态系统功能 ,两者的互补关系受到了生态学家的关注 ,并在实际应用中取得了有益的研究成果。从与能值各自的理论基础与研究成果出发 ,概述了两者在描述生态系统功能上的互补关系 ,并分析了其在生态学理论研究及实际应用上的重要意义     

Effects of water-column mixing on bacteria,phytoplankton, and rotifers under different levels of herbivory in a shallow eutrophic lake

Water-column mixing is known to have a decisive impact on plankton communities. The underlying mechanisms depend on the size and depth of the water body, nutrient status and the plankton community structure, and they are well understood for shallow polymictic and deep stratified lakes. Two consecutive mixing events of similar intensity under different levels of herbivory were performed in enclosures in a shallow, but periodically stratified, eutrophic lake, in order to investigate the effects of water-column mixing on bacteria abundance, phytoplankton abundance and diversity, and rotifer abundance and fecundity. When herbivory by filter-feeding zooplankton was low, water-column mixing that provoked a substantial nutrient input into the euphotic zone led to a strong net increase of bacteria and phytoplankton biomass. Phytoplankton diversity was lower in the mixed enclosures than in the undisturbed ones because of the greater contribution of a few fast-growing species. After the second mixing event, at a high biomass of filter-feeding crustaceans, the increase of phytoplankton biomass was lower than after the first mixing, and diversity remained unchanged because enhanced growth of small fast-growing phytoplankton was prevented by zooplankton grazing. Bacterial abundance did not increase after the second mixing, when cladoceran biomass was high. Changes in rotifer fecundity indicated a transmission of the phytoplankton response to the next trophic level. Our results suggest that water-column mixing in shallow eutrophic lakes with periodic stratification has a strong effect on the plankton community via enhanced nutrient availability rather than resuspension or reduced light availability. This fuels the basis of the classic and microbial food chain via enhanced phytoplankton and bacterial growth, but the effects on biomass may be damped by high levels of herbivory. Received: 3 May 1999 / Accepted: 13 April 2000     

The maximum empower principle: An invisible hand controlling the self-organizing development of forest plantations in south China

Derived from the maximum power principle (MPP), the maximum empower principle (MePP) is considered as the foundation of emergy theory and evaluation methods. However, it has often encountered some doubts since proposed, because of lacking sufficient empirical evidence. To test the validity of the MePP in the self-organization of forest ecosystems, this paper applied a process-based ecosystem model (Biome-BGC) to simulate the dynamics of biomass, litter and soil organic matter (SOM) of three forest plantations in south China during 1985–2007, and attempted to replicate their self-organizing processes. The simulated results and input flows were transformed to emergy as a common basis and, from the viewpoint of emergy synthesis, the dynamics of the production efficiency and empower of the three forest ecosystems were revealed along with their self-organizing developments over time. The results showed that three forest plantations had similar dynamic change patterns of emergy efficiency and empower, but the production efficiencies of them were not always consistent with their empower performances. The production efficiency firstly increased rapidly to maximums, and then decreased to optimal moderate values. However, the empower came to the maximums after the efficiency peaked and then fluctuated up and down, dependent on weather. These results implied that, a forest ecosystem in its self-organizing process tends toward maximum empower at optimal efficiency. Behind the maximum empower of the forest ecosystem is the desynchrony development of different components, e.g., biomass, litter and SOM; leaf, stem and root; biomass and biodiversity. As a whole, the MePP functions like an invisible hand controlling the general self-organizing development of forest ecosystems and pointing out the direction of their development.     

Nitrogen subsidies to pelagic food webs through profundal methane-oxidising bacteria in oligotrophic fresh water

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栽植生姜对不同种植模式下紫色土微生物生物量及水解酶活性的影响

研究了岷江下游紫色丘陵区玉米+红薯间作、大豆单作、生姜连作、水稻-紫云英轮作等4个典型种植模式下栽植生姜后土壤微生物生物量碳、氮、磷含量和水解酶活性的变化特征.结果表明： 栽植生姜显著降低了4个种植模式下土壤微生物生物量碳、氮和磷含量,但各种植模式之间存在较大差异.其中,玉米+红薯间作和水稻-紫云英轮作模式下土壤微生物生物量碳、氮的下降幅度明显低于大豆单作与生姜连作模式,但土壤微生物生物量磷下降幅度明显较高.栽植生姜显著降低了土壤酸性磷酸酶活性,其下降幅度以玉米+红薯间作模式最大,水稻-紫云英轮作模式最小;土壤转化酶活性在生姜连作模式下显著降低;土壤脲酶活性在大豆单作、生姜连作和水稻-紫云英轮作模式下均显著降低.相对于其他模式,栽植生姜使玉米+红薯间作模式下的土壤维持了较高的转化酶和脲酶活性.     

Effect of Thermal Effluents and Retention Time on Lake Functioning and Ecological Efficiencies in Plankton Communities

The following changes were observed in three lakes as a result of their heating and decrease of retention time (data for summer periods): increase of mixing rate, active bottom area, and nutrients (P_inorg., N_inorg.) concentrations; significant changes in gross primary production, phytoplankton biomass and production of filtering cladocerans. These changes seem to indicate the higher efficiency of utilization of autochthonous trophic resources and energy transfer in plankton.     

Effects of sea surface warming on marine plankton

Ocean warming has been implicated in the observed decline of oceanic phytoplankton biomass. Some studies suggest a physical pathway of warming via stratification and nutrient flux, and others a biological effect on plankton metabolic rates; yet the relative strength and possible interaction of these mechanisms remains unknown. Here, we implement projections from a global circulation model in a mesocosm experiment to examine both mechanisms in a multi‐trophic plankton community. Warming treatments had positive direct effects on phytoplankton biomass, but these were overcompensated by the negative effects of decreased nutrient flux. Zooplankton switched from phytoplankton to grazing on ciliates. These results contrast with previous experiments under nutrient‐replete conditions, where warming indirectly reduced phytoplankton biomass via increased zooplankton grazing. We conclude that the effect of ocean warming on marine plankton depends on the nutrient regime, and provide a mechanistic basis for understanding global change in marine ecosystems.     

顺德产业生态系统能值动态分析

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Consumer-dependent responses of lake ecosystems to nutrient loading

The nutrient loading concept proposes that algal biomass, waterclarity and the processes of lake eutrophication are a functionof nutrient loading. We hypothesized that grazers play an importantrole in determining the impacts of nutrient loading on algalbiomass and water clarity, and the overall eutrophication process.To test how the contrasting grazer communities modify the fateof nutrients, we added nutrients (nitrate and phosphate) ata known loading rate to four large enclosures, but in two ofthe four enclosures large cladoceran grazers (Daphnia >1mm mean length) were allowed to develop by removing the planktivorousfish. In the remaining two enclosures, the development of largeDaphnia was prevented by adding planktivorous fish. The concentrationsof epilimnetic total phosphorus (TP) increased at a similarrate in all four enclosures. However, the daily accumulationof added phosphate into the participate or planktonic forms,especially into plankton <20 µm, was three times fasterwhen large Daphnia were absent than when large Daphnia wereabundant. In the enclosures with large Daphnia, added phosphatewas accumulated in the dissolved pool instead. At a constantnutrient loading, algal biomass (chlorophyll a) increased fourtimes faster in the enclosures without large Daphnia than inthose with large Daphnia. Similarly, Secchi depth declined from3.5 to <1 m when Daphnia were absent, but did not declinewhen Daphnia were common. Our results demonstrate that the samenutrient loading and the resultant increase in epilimnetic TPdo not produce the same trophic conditions, as indicated byalgal biomass and water clarity, if the grazers of the majorassimilators of nutrients (the fraction of plankton edible toDaphnia) are different. We suggest that stratified lake ecosystemshaving functionally dominant large grazer communities may beless prone to eutrophication than those lacking large grazers.Consistent with the nutrient loading concept, epilimnetic concentrationsof phosphorus increase proportionately with increased loadingof phosphorus, but the trophic conditions of ecosystems indicatedby algal biomass and water clarity do not follow the same patternsunder contrasting conditions of grazer communities. We suggestthat models predicting algal biomass from loading rates shouldaccount for the role of grazers.     

Complexity of multitrophic interactions in a grassland ecosystem depends on plant species diversity

1.?We studied the theoretical prediction that a loss of plant species richness has a strong impact on community interactions among all trophic levels and tested whether decreased plant species diversity results in a less complex structure and reduced interactions in ecological networks. 2.?Using plant species-specific biomass and arthropod abundance data from experimental grassland plots (Jena Experiment), we constructed multitrophic functional group interaction webs to compare communities based on 4 and 16 plant species. 427 insect and spider species were classified into 13 functional groups. These functional groups represent the nodes of ecological networks. Direct and indirect interactions among them were assessed using partial Mantel tests. Interaction web complexity was quantified using three measures of network structure: connectance, interaction diversity and interaction strength. 3.?Compared with high plant diversity plots, interaction webs based on low plant diversity plots showed reduced complexity in terms of total connectance, interaction diversity and mean interaction strength. Plant diversity effects obviously cascade up the food web and modify interactions across all trophic levels. The strongest effects occurred in interactions between adjacent trophic levels (i.e. predominantly trophic interactions), while significant interactions among plant and carnivore functional groups, as well as horizontal interactions (i.e. interactions between functional groups of the same trophic level), showed rather inconsistent responses and were generally rarer. 4.?Reduced interaction diversity has the potential to decrease and destabilize ecosystem processes. Therefore, we conclude that the loss of basal producer species leads to more simple structured, less and more loosely connected species assemblages, which in turn are very likely to decrease ecosystem functioning, community robustness and tolerance to disturbance. Our results suggest that the functioning of the entire ecological community is critically linked to the diversity of its component plants species.     

Land-use intensification systematically alters the size structure of aquatic communities in the Neotropics

Land-use and land-cover transitions can affect biodiversity and ecosystem functioning in a myriad of ways, including how energy is transferred within food-webs. Size spectra (i.e. relationships between body size and biomass or abundance) provide a means to assess how food-webs respond to environmental stressors by depicting how energy is transferred from small to larger organisms. Here, we investigated changes in the size spectrum of aquatic macroinvertebrates along a broad land-use intensification gradient (from Atlantic Forest to mechanized agriculture) in 30 Brazilian streams. We expected to find a steeper size spectrum slope and lower total biomass in more disturbed streams due to higher energetic expenditure in physiologically stressful conditions, which has a disproportionate impact on large individuals. As expected, we found that more disturbed streams had fewer small organisms than pristine forest streams, but, surprisingly, they had shallower size spectrum slopes, which indicates that energy might be transferred more efficiently in disturbed streams. Disturbed streams were also less taxonomically diverse, suggesting that the potentially higher energy transfer in these webs might be channelled via a few efficient trophic links. However, because total biomass was higher in pristine streams, these sites still supported a greater number of larger organisms and longer food chains (i.e. larger size range). Our results indicate that land-use intensification decreases ecosystem stability and enhances vulnerability to population extinctions by reducing the possible energetic pathways while enhancing efficiency between the remaining food-web linkages. Our study represents a step forward in understanding how land-use intensification affects trophic interactions and ecosystem functioning in aquatic systems.     

Nontrophic interactions, biodiversity, and ecosystem functioning: an interaction web model

Research into the relationship between biodiversity and ecosystem functioning has mainly focused on the effects of species diversity on ecosystem properties in plant communities and, more recently, in food webs. Although there is growing recognition of the significance of nontrophic interactions in ecology, these interactions are still poorly studied theoretically, and their impact on biodiversity and ecosystem functioning is largely unknown. Existing models of mutualism usually consider only one type of species interaction and do not satisfy mass balance constraints. Here, we present a model of an interaction web that includes both trophic and nontrophic interactions and that respects the principle of mass conservation. Nontrophic interactions are represented in the form of interaction modifications. We use this model to study the relationship between biodiversity and ecosystem properties that emerges from the assembly of entire interaction webs. We show that ecosystem properties such as biomass and production depend not only on species diversity but also on species interactions, in particular on the connectance and magnitude of nontrophic interactions, and that the nature, prevalence, and strength of species interactions in turn depend on species diversity. Nontrophic interactions alter the shape of the relationship between biodiversity and biomass and can profoundly influence ecosystem processes.     

Efficiency of biomass transfer and the stability of model food-webs

Low efficiency of biomass transfer between trophic levels was found to enhance the stability of a model ecosystem in Lotka-Volterra form, consisting of six basal species, three primary consumers and an omnivore (De Angelis, 1975). The present paper extends De Angelis's result to a more general class of models, varying in species number, connectance and precise features of web design. Whilst the efficiency of biomass transfer does influence stability, it does not do so in the relatively simple way proposed by De Angelis. Three ranges of maximum efficiency of biomass transfer, γ_max, were employed, biologically probable (1 > γ_max > 0· 1), possible to very unlikely (0 · 1 > γ_max>0 · 01) and highly improbable (0.01> γ_max> 0· 001). Over most web configurations, in biologically probable regions of ymax, increasing connectance decreased the probability of webstability—the opposite of De Angelis's prediction. Increasing connectance only enhanced stability in biologically unrealistic regions of γ_max. Stability was also markedly influenced in these models by the number of component species and trophic levels in the web, features not evaluated by De Angelis. Low efficiency of biomass transfer enhanced stability in some types of web, but not in others.     

Copepod grazing impact on the trophic structure of the microbial assemblage of the San Pedro Channel, California

In August 2002 and March 2003 the trophic structure of the microbialassemblage from the San Pedro Channel, California was studiedfollowing the experimental alteration of the number of copepods.Changes in the abundance/biomass of microorganisms <80 µmduring 3-day incubations were monitored in (i) the absence ofmetazoa >80 µm, (ii) the presence of natural abundancesof metazoa and (iii) the presence of an elevated number of copepods.Prokaryotes and small-sized eukaryotes (<4 µm) dominatedplankton biomass during both experimental months. Diatoms numericallydominated the 10–80 µm plankton in August 2002,but ciliate and heterotrophic dinoflagellate biomass generallyexceeded diatom biomass on both dates. Ingestion of protozooplankton(predominantly ciliates) contributed substantially to copepoddaily carbon rations. The adult copepod assemblage removed 4.6and 36% per day of the microzooplankton standing stocks (10–80µm size fraction) in August and March, respectively. Elevatedcopepod grazing pressure on protozooplankton resulted in increasedbiomass of nanoplankton (<5 µm) presumably via a trophiccascade. Accordingly, the copepod–protozoan trophic linkappears to be a key factor structuring the planktonic microbialassemblage in the San Pedro Channel. This paper is one of six on the subject of the role of zooplanktonpredator–prey interactions in structuring plankton communities.     

Structure and functioning of two pelagic communities in the North Chilean Patagonian coastal system

The size composition of primary producers is important for how energy is channeled through a food web and on to the higher trophic levels and eventually to fisheries. To evaluate this, we studied the productive patterns for large (micro) versus small (nano) phytoplankton in two south marine Patagonian ecosystems: The Inner Sea of Chiloe—ISCh and, Moraleda Channel—MCh. We built Ecopath models (EwE), and evaluated the hypothesis that the overall primary productivity—rather than the ratio of large to small primary producers—constitutes an adequate proxy for predicting the amount of secondary and tertiary production and biomass (up to the fisheries). The EwE model included four small-scale fisheries and 36 functional groups. The functioning of both ecosystems was similar but the ecosystem parameters (biomass, energy transfer efficiencies from primary producers, secondary, and tertiary production) were twice as much in the basin with more microphytoplankton biomass. Overall, the hypothesis was rejected, albeit it was possible to highlight the importance of the quality and size spectrum of plankton on the structure of marine ecosystem, and to demonstrate the key role of the microbial loop over traditional food web in the functioning of the carbon biological pump in Patagonia ecosystems.     

Spatial insurance against a heatwave differs between trophic levels in experimental aquatic communities

Climate change-related heatwaves are major threats to biodiversity and ecosystem functioning. However, our current understanding of the mechanisms governing community resistance to and recovery from extreme temperature events is still rudimentary. The spatial insurance hypothesis postulates that diverse regional species pools can buffer ecosystem functioning against local disturbances through the immigration of better-adapted taxa. Yet, experimental evidence for such predictions from multi-trophic communities and pulse-type disturbances, like heatwaves, is largely missing. We performed an experimental mesocosm study to test whether species dispersal from natural lakes prior to a simulated heatwave could increase the resistance and recovery of plankton communities. As the buffering effect of dispersal may differ among trophic groups, we independently manipulated the dispersal of organisms from lower (phytoplankton) and higher (zooplankton) trophic levels. The experimental heatwave suppressed total community biomass by having a strong negative effect on zooplankton biomass, probably due to a heat-induced increase in metabolic costs, resulting in weaker top-down control on phytoplankton. While zooplankton dispersal did not alleviate the negative heatwave effects on zooplankton biomass, phytoplankton dispersal enhanced biomass recovery at the level of primary producers, providing partial evidence for spatial insurance. The differential responses to dispersal may be linked to the much larger regional species pool of phytoplankton than of zooplankton. Our results suggest high recovery capacity of community biomass independent of dispersal. However, community composition and trophic structure remained altered due to the heatwave, implying longer-lasting changes in ecosystem functioning.     

Density-dependent Mortality Induced by Low Nutrient Status of the Substrate

The hypothesis that changing the fertility level of the substratewould change the self-thinning line (different slope or intercept)followed by high-density populations was tested by sowing populationsof Ocimum basilicum L. at two densities on a soil-based pottingmix adjusted to three fertility levels (F0, F1 and F2). Fertilitylevel significantly affected the slope of the thinning linesfor both shoot and root biomass. For shoot biomass, more mortalityoccurred per unit increase in biomass as fertility level declined(the slope of the thinning line became flatter). The slope ofthe log shoot biomassvs. log density relationship was -0.5 atthe F2-, zero at the F1-, and 0.94 at the F0-fertility. Forthe log root biomassvs. log density lines, slopes were zeroat the F2- and F0-fertility levels, and -0.32 at F1. Packingof shoot biomass into canopies of individual plants correlatedwell with observed exponents of self-thinning lines at the F2-and F1-fertility level. Plants at the F2-fertility level requiredmore canopy space to support a given shoot biomass than plantsat F1, indicating that shoot competition was more intense atthe F2-fertility level for a given biomass. Leaf area indexand size inequality also increased with fertility level fora given shoot biomass. Density-dependent mortality in populationsgrown at the F0-fertility level was highly unusual in havinga positive slope for the shoot biomass vs. density relationship.Shoot growth per plant was static as density declined in theF0-populations; however, root growth per plant increased. Allmeasurements of shoot growth (mass, height, canopy extension,leaf area) remained static in the F0-populations: root massand length increased in comparison. It is argued that root competitionbecame sufficiently intense to cause the density-dependent mortalityseen at the F0-fertility level, with little contribution ofshoot competition to mortality. Copyright 1999 Annals of BotanyCompany Ocimum basilicum, self-thinning, root competition, shoot competition, fertility level and competition, density-dependent mortality, allometric self-thinning.