The nutrient-load hypothesis: patterns of resource limitation and community structure driven by competition for nutrients and light

Resource competition theory predicts that the outcome of competition for two nutrients depends on the ratio at which these nutrients are supplied. Yet there is considerable debate whether nutrient ratios or absolute nutrient loads determine the species composition of phytoplankton and plant communities. Here we extend the classical resource competition model for two nutrients by including light as additional resource. Our results suggest the nutrient-load hypothesis, which predicts that nutrient ratios determine the species composition in oligotrophic environments, whereas nutrient loads are decisive in eutrophic environments. The underlying mechanism is that nutrient enrichment shifts the species interactions from competition for nutrients to competition for light, which favors the dominance of superior light competitors overshadowing all other species. Intermediate nutrient loads can generate high biodiversity through a fine-grained patchwork of two-species and three-species coexistence equilibria. Depending on the species traits, however, competition for nutrients and light may also produce multiple alternative stable states, suppressing the predictability of the species composition. The nutrient-load hypothesis offers a solution for several discrepancies between classical resource competition theory and field observations, explains why eutrophication often leads to diversity loss, and provides a simple conceptual framework for patterns of biodiversity and community structure observed in nature.     

Genetic transformation of duckweed Lemna gibba and Lemna minor

Summary We developed efficient genetic transformation protocols for two species of duckweed, Lemna gibba (G3) and Lemna minor (8627 and 8744), using Agrobacterium-mediated gene transfer. Partially differentiated nodules were co-cultivated with Agrobacterium tumefaciens harboring a binary vector containing β-glucuronidase and nptII expression cassettes. Transformed cells were selected and allowed to grow into nodules in the presence of kanamycin. Transgenic duckweed fronds were regenerated from selected nodules. We demonstrated that transgenic duckweed could be regenerated within 3 mo. after Agrobacterium-mediated transformation of nodules. Furthermore, we developed a method for transforming L. minor 8627 in 6 wk. These transformation protocols will facilitate genetic engineering of duckweed, ideal plants for bioremediation and large-scale industrial production of biomass and recombinant proteins.     

Colourful coexistence of red and green picocyanobacteria in lakes and seas

Hutchinson's paradox of the plankton inspired many studies on the mechanisms of species coexistence. Recent laboratory experiments showed that partitioning of white light allows stable coexistence of red and green picocyanobacteria. Here, we investigate to what extent these laboratory findings can be extrapolated to natural waters. We predict from a parameterized competition model that the underwater light colour of lakes and seas provides ample opportunities for coexistence of red and green phytoplankton species. To test this prediction, we sampled picocyanobacteria of 70 aquatic ecosystems, ranging from clear blue oceans to turbid brown peat lakes. As predicted, red picocyanobacteria dominated in clear waters, whereas green picocyanobacteria dominated in turbid waters. We found widespread coexistence of red and green picocyanobacteria in waters of intermediate turbidity. These field data support the hypothesis that niche differentiation along the light spectrum promotes phytoplankton biodiversity, thus providing a colourful solution to the paradox of the plankton.     

Evolution of nutrient uptake reveals a trade-off in the ecological stoichiometry of plant-herbivore interactions

Nutrient limitation determines the primary production and species composition of many ecosystems. Here we apply an adaptive dynamics approach to investigate evolution of the ecological stoichiometry of primary producers and its implications for plant-herbivore interactions. The model predicts a trade-off between the competitive ability and grazing susceptibility of primary producers, driven by changes in their nutrient uptake rates. High nutrient uptake rates enhance the competitiveness of primary producers but also increase their nutritional quality for herbivores. This trade-off enables coexistence of nutrient exploiters and grazing avoiders. If herbivores are not selective, evolution favors runaway selection toward high nutrient uptake rates of the primary producers. However, if herbivores select nutritious food, the model predicts an evolutionarily stable strategy with lower nutrient uptake rates. When the model is parameterized for phytoplankton and zooplankton, the evolutionary dynamics result in plant-herbivore oscillations at ecological timescales, especially in environments with high nutrient availability and low selectivity of the herbivores. High herbivore selectivity stabilizes the community dynamics. These model predictions show that evolution permits nonequilibrium dynamics in plant-herbivore communities and shed new light on the evolutionary forces that shape the ecological stoichiometry of primary producers.     

Effect of genotype on rooting of hypocotyls and in vitro-produced shoots of Pinus radiata

Significant genotypic variation at both the family and clone-within-family levels was seen for hypocotyl rooting and the rooting of adventitious shoots produced in vitro for Pinus radiata D. Don. High rooting frequencies for hypocotyls were obtained in the absence of exogenous auxin; auxin greatly stimulated the rooting of adventitious shoots. No correlation was seen between the rooting of hypocotyls and shoots; families whose hypocotyls rooted at high frequencies did not necessarily produce shoots that rooted at high frequency. No correlation was seen between adventitious shoot production and subsequent rooting at either the family or clone level. The lack of a negative correlation indicated that selecting families or clones for high levels of shoot production will not automatically select for low rooting ability, obviating a possible bottleneck for commercial propagation of Pinus radiata. Significant family by replication interaction suggests that rooting protocols could be optimized through manipulations of the rooting environment for each family.     

Agrobacterium-mediated transformation of apple (Malus x domestica Borkh.): an assessment of factors affecting gene transfer efficiency during early transformation steps

The factors influencing transfer of an intron — containing -glucuronidase gene to apple leaf explants were studied during early steps of an Agrobacterium tumefaciens-mediated transformation procedure. The gene transfer process was evaluated by counting the number of -glucuronidase expressing leaf zones immediately after cocultivation, as well as by counting the number of -glucuronidase expressing calli developing on the explants after 6 weeks of postcultivation in the presence of 50 mg/l kanamycin. Of three different tested disarmed A. tumefaciens strains, EHA101(pEHA101) was the most effective for apple transformation. Cocultivation of leaf explants with A. tumefaciens on a medium with a high cytokinin level was more conducive to gene transfer than cocultivation on media with high auxin concentrations. Precultivation of leaf explants, prior to cocultivation, slightly increased the number of -glucuronidase expressing zones measured immediately after cocultivation, but it drastically decreased the number of transformed calli appearing on the explants 6 weeks after infection. Other factors examined were: Agrobacterium cell density during infection, bacterial growth phase, nature of the carbon source, explant age, and explant genotype.Abbreviations 2,4-D 2,4-dichlorophenoxyacetic acid - CaMV35S 35S RNA of cauliflower mosaic virus - EDTA ethylenediaminetetraacetate - FeNaEDTA ethylenediaminetetraacetate ferric-sodium salt - GusA -glucuronidase - gusA ß-glucuronidase gene of Escherichia coli - gusA-intron ß-glucuronidase gene containing an intron in the coding region - IBA indole butyric acid - 2iP N6-2-isopentenyl adenine - NAA naphthaleneacetic acid - nptII neomycinphosphotransferase II gene - X-Gluc 5-bromo-4-chloro-3-indolyl ß-D-glucuronide     

Selenium status indices,laboratory data,and selected biochemical parameters in end-stage renal disease patients

We investigated the relations between selenium status (SeS) parameters, indexes of nutrition, erythropoiesis, and uremic toxemia, serum electrolytes, and other biochemical markers in end-stage renal disease (ESRD) patients, as no multivariate statistical analysis concerning all of these parameters was performed so far. SeS was evaluated by plasma Se concentration (plSe) and glutathione peroxidase (plGSHPx) activity in 69 uremic patients treated with hemodialysis (HD) and 40 healthy controls. The hierarchical multivariate partial least squares model (PLS2) was employed to establish data structure and correlations between parameters investigated. plSe and plGSHPx activity were significantly lower in patients when compared with controls (p=0.000). plSe was positively associated with indexes of erythropoiesis and nutritional status, as well as serum electrolytes and parameters of uremic toxemia. plGSHPx was inversely dependent on the pair of parameters: intact parathyroid hormone (iPTH) and aluminum plasma concentration (Al). We conclude that (1) ESRD strongly decreases selenium status and (2) the PLS2 approach revealed the existence of significant interactions among plSe, plGSHPx, and selected biochemical parameters or groups of such parameters; some of these associations need further studies to be clarified.     

Nutrient recovery from swine lagoon water by Spirodela punctata.

Spirodela punctata 7776, the best duckweed strain in total protein production selected from in vitro screening experiments with synthetic swine lagoon water medium was examined for N and P recovery. It has shown a capability to grow in and to remove N and P from synthetic swine lagoon water with high N (240 mg NH4 N/l) and P (31.0 mg PO4 P/l) levels. A lag period of approximately 96 h was observed before the duckweed started to grow. During the lag period, utilization of N and P by the duckweed was very slow. The rates of N and P uptake, and duckweed growth increased with the increase of the initial N and P concentrations in the medium. The highest rates of N and P uptakes, and duckweed growth observed in this study were 0.955. 0.129 mg/l-h, and 1.33 g/m2-h (or 31.92 g/m2-day), respectively. The N:P ratio in swine lagoon water is adequate for growing the duckweed.     

Early-flowering Scots pines through tissue culture for accelerating tree breeding

Scots pine plantlets were produced via tissue culture using cotyledons excised from germinated embryos as explants. The optimum tissue culture conditions were: 1/2GDbasal medium gelled with agar-Gelrite during shoot formation and with agar during rooting, inclusion of 5.0M benzylaminopurine (BAP) and 0.05 M naphthaleneacetic acid (NAA) for 2 weeks for shoot induction, and repeated 2.7 M NAA pulses of 1 week for rooting. Micropropagation success was genotype-dependent. Average multiplication rates varied among experiments from 3 to 15 shoots per embryo. The maximum shoot production from a single embryo was 35. Rooting was the most difficult phase in the propagation process. Most of the plantlets had a plagiotrophic and highly branched growth habit when growing in the greenhouse. Some individuals produced megasporangiate strobili at the age of 3 years and microsporangiate strobili with viable pollen at the age of 4 years. Early-flowering clones and the ability to conserve seedlings from which cotyledons have been cultured give new possibilities for accelerated tree breeding.