Limiting similarity and niche theory for structured populations

We develop the theory of limiting similarity and niche for structured populations with finite number of individual states (i-state). In line with a previously published theory for unstructured populations, the niche of a species is specified by the impact and sensitivity niche vectors. They describe the population's impact on and sensitivity towards the variables involved in the population regulation. Robust coexistence requires sufficient segregation of the impact, as well as of the sensitivity niche vectors. Connection between the population-level impact and sensitivity and the impact/sensitivity of the specific i-states is developed. Each i-state contributes to the impact of the population proportional to its frequency in the population. Sensitivity of the population is composed of the sensitivity of the rates of demographic transitions, weighted by the frequency and by the reproductive value of the initial and final i-states of the transition, respectively. Coexistence in a multi-patch environment is studied. This analysis is interpreted as spatial niche segregation.     

Coexistence in a fluctuating environment by the effect of relative nonlinearity: A minimal model

The minimal model of the “relative nonlinearity” type fluctuation-maintained coexistence is investigated. The competing populations are affected by an environmental white noise. With quadratic density dependence, the long-term growth rates of the populations are determined by the average and the variance of the (fluctuating) total density. At most two species can coexist on these two “regulating” variables; competitive exclusion would ensue in a constant environment. A numerical study of the expected time until extinction of any of the two species reveals that the criterion of mutual invasibility predicts the parameter range of long-term coexistence correctly in the limit of zero extinction threshold. However, any extinction threshold consistent with a realistic population size will allow only short-term coexistence. Therefore, our simulations question the biological relevance of mutual invasibility, as a sufficient condition of coexistence, for large density fluctuations. We calculate the average and the variance of the fluctuating density of the coexisting populations analytically via the moment-closure approximation; the results are reasonably close to the simulated behavior. Based on this treatment, robustness of coexistence is studied in the limit of infinite population size. We interpret the results of this analysis in the context of necessity of niche segregation with respect to the regulating variables using a framework theory published earlier.     

A model of niche overlap and interaction in ecological systems

Ecological niches are the result of ecosystem element (compartment) interaction under the influence of environmental factors. The competence model is devised to map this interaction. It includes the assumption of an overall physiological state of a compartment depending only on intensive environmental factors, expressions for the adaptedness and competence of the compartment in interaction. Consequently, niches are environmental factor domains of superior competence. The situation of niches (niche structure) and competence maxima are extensively studied in the fundamental case of two interacting compartments and in the special case of n concentric compartments. The impact of one immigrating compartment is discussed. All detailed investigations made involve only one intensive environmental factor and the special assumption of similar physiological state functions of all compartments.     

Concurrent niche and neutral processes in the competition-colonization model of species coexistence

The importance of neutral dynamics is contentiously debated in the ecological literature. This debate focuses on neutral theory's assumption of fitness equivalency among individuals, which conflicts with stabilizing fitness that promotes coexistence through niche differentiation. I take advantage of competition-colonization trade-offs between species of aquatic micro-organisms (protozoans and rotifers) to show that equalizing and stabilizing mechanisms can operate simultaneously. Competition trials between species with similar colonization abilities were less likely to result in competitive exclusion than for species further apart. While the stabilizing mechanism (colonization differences) facilitates coexistence at large spatial scales, species with similar colonization abilities also exhibited local coexistence probably due to fitness similarities allowing weak stabilizing mechanisms to operate. These results suggest that neutral- and niche-based mechanisms of coexistence can simultaneously operate at differing temporal and spatial scales, and such a spatially explicit view of coexistence may be one way to reconcile niche and neutral dynamics.     

Multispecies coexistence of trees in tropical forests: spatial signals of topographic niche differentiation increase with environmental heterogeneity

Neutral and niche theories give contrasting explanations for the maintenance of tropical tree species diversity. Both have some empirical support, but methods to disentangle their effects have not yet been developed. We applied a statistical measure of spatial structure to data from 14 large tropical forest plots to test a prediction of niche theory that is incompatible with neutral theory: that species in heterogeneous environments should separate out in space according to their niche preferences. We chose plots across a range of topographic heterogeneity, and tested whether pairwise spatial associations among species were more variable in more heterogeneous sites. We found strong support for this prediction, based on a strong positive relationship between variance in the spatial structure of species pairs and topographic heterogeneity across sites. We interpret this pattern as evidence of pervasive niche differentiation, which increases in importance with increasing environmental heterogeneity.     

美国杏李园瓢虫群落组成及生态位

对美国杏李园中瓢虫的种群动态和生态位进行研究,结果表明,异色瓢虫、龟纹瓢虫、多异瓢虫为优势种群,黑缘红瓢虫、红点唇瓢虫、七星瓢虫、马铃薯瓢虫、深点食螨瓢虫、二星瓢虫种群密度长时间处于稳定状态。马铃薯瓢虫占据生态位最宽,对美国杏李树危害时间较长。红点唇瓢虫和七星瓢虫的生态位重叠较高,出现频率高。在瓢虫类天敌中,生态位宽度越宽的种类往往数量较低,且持续时间较长,对害虫种群的控制程度较低,生态位宽度较低的种类出现时间较短,短时间内种群数量较高,可以控制害虫种群数量。     

转Bt基因棉田蜘蛛的时空动态及控害作用

1998-1999年在河北棉区系统调查转Bt基因棉棉田中的蜘蛛发生时空的研究结果表明,在转Bt基因棉田中,全年百株累计数量为3984头,占棉田总捕食性天敌数量的49.7%。其中优势蜘蛛温室希蛛,狼蛛和草间小黑蛛分别占53.6%,16.7%和18.6%。季节动态表现为棉田前期少,中,后期多,最高可达百株454头;棉株下部和地面的蜘蛛增加快,而上,中部蜘蛛增加慢,空间分布表现为下部和地面占优势,丰富度分别为0.464和0.303,而上部蜘蛛的丰富度仅为0.067。地面蜘蛛中以狼蛛和草间小黑蛛占优势,分别占52.6%和40.6%。基于蜘蛛的数量,时空动态及与棉铃虫的配合程度认为,对棉铃虫起主要控制作用的为草间小黑蛛,温室希蛛和卷叶蛛,分别占蜘蛛总控制指数的41.3%,25.2%和10.9%。其中2代棉铃虫发生期,草间小黑蛛贡献最大。占67.7%。3代棉铃虫发生期,温室希蛛和草间小黑蛛分别占29.0%和25.4%的贡献率,4代棉铃虫发生期温室希蛛起主要作用。占45.3%的贡献率。     

Network properties, species abundance and evolution in a model of evolutionary ecology

We study the evolution of the network properties of a populated network embedded in a genotype space characterized by either a low or a high number of potential links, with particular emphasis on the connectivity and clustering. Evolution produces two distinct types of network. When a specific genotype is only able to influence a few other genotypes, the ecosystem consists of separate non-interacting clusters (i.e. isolated compartments) in genotype space. When different types may influence a large number of other sites, the network becomes one large interconnected cluster. The distribution of interaction strengths--but not the number of connections--changes significantly with time. We find that the species abundance is only realistic for a high level of species connectivity. This suggests that real ecosystems form one interconnected whole in which selection leads to stronger interactions between the different types. Analogies with niche and neutral theory and assembly models are also considered.     

Fractal analysis of the root architecture of Gliricidia sepium for the spatial prediction of root branching,size and mass: model development and evaluation in agroforestry

Based on fractal and pipe model assumptions, a static three-dimensional model of the Gliricidia sepium root system was developed, in order to provide a basis for the prediction of root branching, size and mass in an alley cropping system. The model was built from observations about the topology, branching rules, link length and diameter, and root orientation, provided by in situ and extracted root systems. Evaluation tests were carried out at the plant level and at the field level. These tests principally concerned coefficients α and q –- the proportionality factor α between total cross-sectional area of a root before and after branching, and allocation parameter q that defines the partitioning of biomass between the new links after a branching event –- that could be considered as key variables of this fractal approach. Although independent of root diameter, these coefficients showed a certain variability that may affect the precision of the predictions. When calibrated, however, the model provided suitable predictions of root dry matter, total root length and root diameter at the plant level. At the field level, the simulation of 2D root maps was accurate for root distribution patterns, but the number of simulated root dots was underestimated in the surface layers. Hence recommendations were made to improve the model with regard to α and q. This static approach appeared to be well suited to study the root system of adult trees. Compared with explicit models, the main advantage of the fractal approach is its plasticity and ease of use. This revised version was published online in June 2006 with corrections to the Cover Date.