Temperature- and density-dependence of diapause induction and its life history correlates in the geometrid moth Chiasmia clathrata (Lepidoptera: Geometridae)

The relative roles of genetics and developmental plasticity in creating phenotypes adapted to prevailing conditions are insufficiently understood. In potentially multivoltine temperate insects, individuals that do not enter diapause but develop directly into reproductive adults within the same season are severely time-constrained. Direct development is, however, under selection only if expressed in the wild. Thus, adaptive correlates of the direct development are expected to evolve and persist only in multivoltine populations. We studied the genetic and phenotypic components of variation in juvenile development in the geometrid moth Chiasmia clathrata from univoltine and bivoltine regions. Larvae were reared at two temperatures (14/20 °C) and densities (low/high) in a factorial split-brood experiment. High temperature and low density promoted direct development, the former condition being associated with a short development time, high growth rate and large body size. Genotypes of bivoltine origin had a higher propensity for direct development and seemingly expressed an exaggerated plastic response to increasing temperature compared to the ones from univoltine populations. Alternative life history phenotypes associated with the induced developmental pathway emerged only in the bivoltine region, direct development resulting in a short larval period, high growth rate and small size at 20 °C there. The degree of differentiation between the developmental pathways was insensitive to larval density; high density only decreased both development time and body size to a certain degree. We conclude that the differences between the pathways are not due to the induction of a particular pathway itself, but geographically varying selection pressures shape the correlation structure among life history traits and their pathway-specific expression.     

Short-term LDL cholesterol-lowering efficacy of plant stanol esters

Background  

The short-term cholesterol-lowering efficacy of plant stanol esters has been open to debate, and the data from different clinical studies with hypercholesterolemic subjects are variable, partly due to lack of systematic studies. Therefore, we investigated the time in days needed to obtain the full cholesterol-lowering effect of stanol esters in hypercholesterolemic subjects.     

Cost efficiency of nutrient acquisition and the advantage of mycorrhizal symbiosis for the host plant

Mycorrhizal symbiosis involves reciprocal transfer of carbon and nutrients between shoots on the one hand and roots colonized by symbiotic fungi on the other. Mycorrhizas may improve the mineral nutrient acquisition rates, but simultaneously increase the belowground demand for carbon. Mycorrhizal plants will have a selective advantage over non-mycorrhizal ones if they are more cost-efficient in terms of carbon cost per unit of acquired mineral nutrient. However, we demonstrate here in a simple model system that this is not a necessary condition. Mycorrhizas may evolve even when they are less cost-efficient, provided that photosynthesis and/or growth are strongly nutrient-limited. This result implies a unique hypothesis for the evolution of mycorrhizal associations which may be inherently cost-inefficient as compared to plant roots. Such symbioses may have evolved when the superior nutrient acquisition rate of fungi combines with the relatively high photosynthetic nutrient use efficiency of the host plant. Consequently, provided that mycorrhizas are really cost-inefficient, the selective advantage of mycorrhizal plants will disappear when an increase in the nutrient acquisition rate is not associated with a sufficiently high nutrient use efficiency of photosynthesis, as at high soil nutrient levels or due to a loss of leaf area, shading or low temperatures.     

Expression of photosynthesis- and senescence-related genes during leaf development and senescence in silver birch (Betula pendula) seedlings

Leaf development and senescence were studied in greenhouse-grown silver birch ( Betula pendula Roth) seedlings over a period of 7 weeks. Prior to the experiment, leaves from 100 seedlings were marked for five sampling dates. Timing of the developmental phases was studied with biochemical analyses of total soluble protein, Rubisco protein, chlorophyll concentration and at the level of gene expression related to photosynthesis, energy metabolism, ethylene synthesis and protein degradation. During the sampling period, an initial increase in photosynthetic capacity could be seen, when expression of the Rubisco small subunit gene ( RbcS ) and Rubisco protein (EC 4.1.1.39) were examined. Down-regulation of photosynthesis, visible as a decrease in Rubisco protein and RbcS mRNA, started soon after full expansion of the leaves and processes related to senescence followed. mRNA accumulation for the ethylene-forming enzyme 1-aminocyclopropane-1-carboxylic acid oxidase increased first during the onset of senescence. Protein degradation was observed as a loss of soluble proteins, with a simultaneous increase in the leucine aminopeptidase (EC 3.4.11.1) mRNA levels. The mRNA levels of ribonuclease-like pathogenesis-related protein 10 also increased clearly during senescence, but the mitochondrial phosphate translocator mRNA showed only a slight increase. Chlorophyll concentration of the leaves decreased after the mRNA levels of these senescence-related genes had become more abundant.