The chemical composition of Astragalus: a comparison of seleniferous and non-seleniferous plants growing side by side

COWGILL, U. M. & LANDENBERGER, B.D., 1992. The chemical composition of Astragalus: a comparison of seleniferous and non-seleniferous plants growing side by side. This paper describes how non-seleniferous plant species coexist with seleniferous ones and what chemical changes occur in non-seleniferous species that allow the toleration of large quantities of volatilized Se-bearing compounds. These compounds are known for their phytotoxicity as well as for their toxicity to mammals and insects. Twenty-three sites (Colorado, Utah, New Mexico, U.S.A.) were examined over a 6-year period. Plants collected from these sites were divided into four groups: seleniferous astragali, seleniferous Brassicaceae, non-seleniferous astragali and non-seleniferous associated genera. Furthermore, it was possible to categorize these sites: Type 1 sites supported all four groups of plants, Type 2 sites contained only seleniferous astragali, whereas Type 3 sites sustained only non-seleniferous astragali. When concentrations of Cu, Zn (P <0.0001), Si (P<0.02), As, Pb (P<0.03) and Cs (P<0.05) were measured, the values for those seleniferous astragali that coexisted with other species were significantly different from the values found for those seleniferous astragali that grew alone. There were four areas that in some years supported all four groups of plants (Type 1 site) and in other years contained only seleniferous astragali. In this way, the latter may be used as a chemical control for the former. The seleniferous astragali collected at Type 1 sites always contained more Cu, As, Si and Pb than the solitary astragali of Type 2 sites. When seleniferous astragali of Type 1 sites that support all four groups of plants develop in a year where the usually associated species of past years are absent, they contain in their tissues concentrations of Cu, As, Si, Pb, Zn and Cs typical of Type 2 sites where the seleniferous astragali grew alone. Non-seleniferous astragali of Type 1 sites that support all four groups of plants have a chemical composition that differs significantly in the quantity of 15 elements from non-seleniferous astragali of Type 3 sites where the latter grew alone. Since allelochemicals such as phenolic acids and flavonoids are well known to be able to alter mineral absorption by plants and since the astragali are known to produce such substances, it is suggested that the possible production of phenolic acids and flavonoids may permit coexistence of seleniferous plants with non-seleniferous ones and thus explain the chemical differences among the plants of the four types of sites.     

The relationship between sea surface temperature and population change of Great Cormorants Phalacrocorax carbo breeding near Disko Bay,Greenland

Arctic seas have warmed and sea ice has retreated. This has resulted in range contraction and population declines in some species, but it could potentially be a boon for others. Great Cormorants Phalacrocorax carbo have a partially wettable plumage and seem poorly suited to foraging in Arctic waters. We show that rates of population change of Cormorant colonies around Disko Bay, Greenland, are positively correlated with sea surface temperature, suggesting that they may benefit from a warming Arctic. However, although Cormorant populations may increase in response to Arctic warming, the extent of expansion of their winter range may ultimately be limited by other factors, such as sensory constraints on foraging behaviour during long Arctic nights.     

Future climate‐driven shifts in distribution of Calanus finmarchicus

Calanus finmarchicus is a key‐structural species of the North Atlantic polar biome. The species plays an important trophic role in subpolar and polar ecosystems as a grazer of phytoplankton and as a prey for higher trophic levels such as the larval stages of many fish species. Here, we used a recently developed ecological niche model to assess the ecological niche (sensu Hutchinson) of C. finmarchicus and characterize its spatial distribution. This model explained about 65% of the total variance of the observed spatial distribution inferred from an independent dataset (data of the continuous plankton recorder survey). Comparisons with other types of models (structured population and ecophysiological models) revealed a clear similarity between modeled spatial distributions at the scale of the North Atlantic. Contemporary models coupled with future projections indicated a progressive reduction of the spatial habitat of the species at the southern edge and a more pronounced one in the Georges Bank, the Scotian Shelf and the North Sea and a potential increase in abundance at the northern edge of its spatial distribution, especially in the Barents Sea. These major changes will probably lead to a major alteration of the trophodynamics of North Atlantic ecosystems affecting the trophodynamics and the biological carbon pump.     

Compositions of fungal secretomes indicate a greater impact of phylogenetic history than lifestyle adaptation

Background

Since the first fungal genome sequences became available, investigators have been employing comparative genomics to understand how fungi have evolved to occupy diverse ecological niches. The secretome, i.e. the entirety of all proteins secreted by an organism, is of particular importance, as by these proteins fungi acquire nutrients and communicate with their surroundings.

Results

It is generally assumed that fungi with similar nutritional lifestyles have similar secretome compositions. In this study, we test this hypothesis by annotating and comparing the soluble secretomes, defined as the sets of proteins containing classical signal peptides but lacking transmembrane domains of fungi representing a broad diversity of nutritional lifestyles. Secretome size correlates with phylogeny and to a lesser extent with lifestyle. Plant pathogens and saprophytes have larger secretomes than animal pathogens. Small secreted cysteine-rich proteins (SSCPs), which may comprise many effectors important for the interaction of plant pathogens with their hosts, are defined here to have a mature length of ≤ 300 aa residues, at least four cysteines, and a total cysteine content of ≥5%. SSCPs are found enriched in the secretomes of the Pezizomycotina and Basidiomycota in comparison to Saccharomycotina. Relative SSCP content is noticeably higher in plant pathogens than in animal pathogens, while saprophytes were in between and closer to plant pathogens. Expansions and contractions of gene families and in the number of occurrences of functional domains are largely lineage specific, e.g. contraction of glycoside hydrolases in Saccharomycotina, and are only weakly correlated with lifestyle. However, within a given lifestyle a few general trends exist, such as the expansion of secreted family M14 metallopeptidases and chitin-binding proteins in plant pathogenic Pezizomycotina.

Conclusions

While the secretomes of fungi with similar lifestyles share certain characteristics, the expansion and contraction of gene families is largely lineage specific, and not shared among all fungi of a given lifestyle.

Electronic supplementary material

The online version of this article (doi:10.1186/1471-2164-15-722) contains supplementary material, which is available to authorized users.     

A Comparison of the Chemical Composition of Injured Leaves in Contrast to Uninjured Leaves of Victoria amazonica (Nymphaeaceae)

The object of this paper is to describe chemical and mineralogicalchanges in Victoria leaves that have sustained insect damage. Of 44 elements detected in various plant parts of Victoria amazonica(Poeppig) J. de C. Sowerby (V. regia auctt) Nymphaeaceae, only15 elements showed statistically significant differences inconcentration between insect-damaged leaves and whole (undamaged)leaves of the same plants. Two different types of insect damagewere noted: one was clearly recent, while the other was clearlyolder, probably not differing in time more than three weeks.Mg, Ca, Al, Si, S, Fe, Mn, Li and Ce were significantly moreconcentrated in the damaged leaf sections than in undamagedleaves of the mature plants with unopened buds. In the caseof preflowering plants, Na, Mg, Ca, Al, Si, S, Cl, Fe and Mnwere more prevalent in the damaged tissue than in the unattackedleaves of the same plants. In the former case, Na, K, Cl andP are rapidly lost when damage occurs, while plants that havehad a chance to recover from the damage, as in the case of thepreflowering plant leaves, begin to make up the difference inelemental concentration between the damaged and undamaged leaves. Mineralogical investigation showed that the amount of calcite(CaCO₃), the calcium oxalates weddellite and whewellite, andthe siliceous minerals - low-form cristobalite opal, low-formtridymite opal and quartz-was higher in the recently injuredleaves than in those that had been injured some time previouslyor than in the uninjured leaves. It is hypothesized that theincreased precipitation of minerals resulting from injury ispart of the plants' defence mechanism against further attackby insects or animals. Insect injury, Victoria, leaves, inorganic composition, mineralogy     

Simulated brain tumor growth dynamics using a three-dimensional cellular automaton

We have developed a novel and versatile three-dimensional cellular automaton model of brain tumor growth. We show that macroscopic tumor behavior can be realistically modeled using microscopic parameters. Using only four parameters, this model simulates Gompertzian growth for a tumor growing over nearly three orders of magnitude in radius. It also predicts the composition and dynamics of the tumor at selected time points in agreement with medical literature. We also demonstrate the flexibility of the model by showing the emergence, and eventual dominance, of a second tumor clone with a different genotype. The model incorporates several important and novel features, both in the rules governing the model and in the underlying structure of the model. Among these are a new definition of how to model proliferative and non-proliferative cells, an isotropic lattice, and an adaptive grid lattice.