Dynamics of threatened goldenseal populations and implications for recovery

Goldenseal (Hydrastis canadensis) is a North American perennial clonal herb highly prized for its medicinal value. It is threatened at the northern range limit with only 20 populations known in Canada. To assist recovery planning, 13 populations were sampled to model dynamics. The fate of all ramets in one square-meter was monitored from 1998 to 2001. Transition matrices were built for 2000-2001, using three stage classes based on size and reproductive status. A six-stage pooled matrix, separating established ramets from newly produced ramets, was also constructed. Recruitment by seed was not observed and therefore excluded. The average population growth rate (λ) was 1.062 ± 0.053, which did not significantly differ from the equilibrium value (1.0) suggesting that the northern population is stationary. However, growth rates among population samples varied largely and had wide confidence intervals. Populations with λ-values less than or close to 1.0 require environmental change to increase. Recovery of goldenseal, and possibly other woodland perennials at risk, requires intervention aimed at population size augmentation, habitat optimization, and targeted dispersal.     

Interpreting the Possible Ecological Role(s) of Cyanotoxins: Compounds for Competitive Advantage and/or Physiological Aide?

To date, most research on freshwater cyanotoxin(s) has focused on understanding the dynamics of toxin production and decomposition, as well as evaluating the environmental conditions that trigger toxin production, all with the objective of informing management strategies and options for risk reduction. Comparatively few research studies have considered how this information can be used to understand the broader ecological role of cyanotoxin(s), and the possible applications of this knowledge to the management of toxic blooms. This paper explores the ecological, toxicological, and genetic evidence for cyanotoxin production in natural environments. The possible evolutionary advantages of toxin production are grouped into two main themes: That of “competitive advantage” or “physiological aide”. The first grouping illustrates how compounds produced by cyanobacteria may have originated from the need for a cellular defence mechanism, in response to grazing pressure and/or resource competition. The second grouping considers the contribution that secondary metabolites make to improved cellular physiology, through benefits to homeostasis, photosynthetic efficiencies, and accelerated growth rates. The discussion also includes other factors in the debate about possible evolutionary roles for toxins, such as different modes of exposures and effects on non-target (i.e., non-competitive) species. The paper demonstrates that complex and multiple factors are at play in driving evolutionary processes in aquatic environments. This information may provide a fresh perspective on managing toxic blooms, including the need to use a “systems approach” to understand how physico-chemical conditions, as well biological stressors, interact to trigger toxin production.     

Naturally acidic waterways: conceptual food webs for better management and understanding of ecological functioning

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The red fox in Australia—an exotic predator turned biocontrol agent

The most important problem regarding mammal conservation in mainland Australia is the low abundance and limited distributions of many species, a legacy of an unprecedented collapse of the mammal fauna on a continental scale that unfolded following European colonisation. Two major hypotheses (not necessarily always mutually exclusive) have been proposed to account for the collapse (1) niche loss-damage due to a variety of causes and (2) predation by exotics, in particular by the red fox. This paper provides evidence the supporting the latter cause as a major factor.Five case studies in Western Australia demonstrate that the fox is an efficient predator that restricts medium-sized marsupials to refugia at low densities. Removal of the fox by baiting typically produces two prey responses (1) significant population recoveries and (2) the colonisation and exploitation of habitats outside of refugia. To date, 11 medium-sized marsupial species, representing seven families, have responded in a like manner. The impact of the fox on its known marsupial prey mimics a biocontrol agent as it severely limits prey distribution and abundance. Niche denial and population suppression characterise it's actions on a suite of vulnerable species not yet fully documented.     

Acari (mite) assemblages under plantations of bluegum, Eucalyptus globulus, in southwestern Australia

Farm forestry, in particular the planting of exotic bluegums Eucalyptus globulus, is a strategy increasingly used in southwestern Australia to mitigate the damaging effects of land clearing and to improve agricultural productivity. At the same time, such agroforestry systems have the potential to at least partially impede the biodiversity decline associated with habitat destruction and agriculture. The soil/litter habitat, an important repository of biodiversity in terrestrial systems, is one of the habitats most affected by clearing and conventional agricultural practices. Within this habitat, free-living mites are one of the most diverse and abundant animal groups contributing significantly to key ecosystem functions. This study compares the soil and litter mite assemblages of 7-year-old E. globulus plantations with those of adjacent native forest and pasture sites. The assemblages associated with E. globulus were substantially more diverse than those of the pasture soils but well below that of the native forest. Particularly low densities of oribatid mites were observed in the plantation sites. We suggest that the young plantation age, the exotic nature of the plantation species, and the homogeneous, mono-specific litter all contributed to limit the potential for these plantations to enhance mite biodiversity.     

Boron fertilization enhances photosynthesis and water use efficiency in soybean at vegetative growth stage

Abstract

Influence of boron (B) on photosynthesis and water use has not sufficiently been evaluated in soybean despite its worldwide importance as a crop. The objective of this work was to evaluate the effects of B application on photosynthesis and water use in soybean at vegetative growth stage. A pot experiment was carried out in a greenhouse. Soybean [Glycine max (L.) Merrill cv. M8644 IPRO] was grown in a clayey Oxisol previously fertilized with 4 B rates (0, 1.5, 3.0, and 6.0?mg dm^?3). Net photosynthesis rate (P_n), intercellular CO₂ concentration (C_i), transpiration rate (E), stomatal conductance (g_s) were measured in the second trifoliate leaf of plants at the V4 growth stage. Instantaneous water use efficiency (WUEis = P_n/E) and intrinsic water use efficiency (WUEic = P_n/g_s) were calculated. B application to soil increased all these variables. The most consistent increases were in P_n, WUEis, and WUEic. The critical level of hot water extractable B in soil that maximized photosynthesis and optimized water use by soybean at vegetative growth stage was calculated to be 0.38?mg dm^?3.