2,4-D-Induced Changes in the K+ Uptake of Wheat Roots at Different pH Values

The effects of an auxin herbicide, 2,4-D, at a concentration of 0.01 mM, on the K⁺ uptake and efflux of excised roots of wheat (Triticum aestivum L. cv. Rannaya) were investigated at different pH values. The K⁺ movement was monitored with a K⁺ (⁸⁶Rb) tracer. In parallel experiments the ATPase activities of microsomal fractions were determined by the inorganic phosphate liberation method. 2,4-D inhibited the K⁺ uptake especially at low pH, irrespective of whether Ca²⁺ was present or not. No marked changes were observed in the K⁺ efflux properties at pH values above 4. The inhibitory effect on K⁺ uptake exhibited a correlation with the hydrocarbon solubility of the herbicide, but not with the 2,4-D-induced decrease of the ATPase activity. It is suggested that 2,4-D exerts a non-specific effect on the lipid-protein interactions, giving rise to a generalized alteration of the transport barrier properties of the plasma membrane even at as low a concentration as 0.01 mM.     

Evolution of body condition‐dependent dispersal in metapopulations

Body condition‐dependent dispersal strategies are common in nature. Although it is obvious that environmental constraints may induce a positive relationship between body condition and dispersal, it is not clear whether positive body conditional dispersal strategies may evolve as a strategy in metapopulations. We have developed an individual‐based simulation model to investigate how body condition–dispersal reaction norms evolve in metapopulations that are characterized by different levels of environmental stochasticity and dispersal mortality. In the model, body condition is related to fecundity and determined either by environmental conditions during juvenile development (adult dispersal) or by those experienced by the mother (natal dispersal). Evolutionarily stable reaction norms strongly depend on metapopulation conditions: positive body condition dependency of dispersal evolved in metapopulation conditions with low levels of dispersal mortality and high levels of environmental stochasticity. Negative body condition‐dependent dispersal evolved in metapopulations with high dispersal mortality and low environmental stochasticity. The latter strategy is responsible for higher dispersal rates under kin competition when dispersal decisions are based on body condition reached at the adult life stage. The evolution of both positive and negative body condition‐dependent dispersal strategies is consequently likely in metapopulations and depends on the prevalent environmental conditions.     

Endodermis-like Sheaths in the Submerged Freshwater MacrophyteRanunculus trichophyllusChaix

Light, fluorescence and electron microscopical analysis of therooted freshwater plantRanunculus trichophyllusrevealed a peculiaranatomical feature. In addition to the true endodermis encirclingthe root stele, endodermis-like sheaths occurred around eachvascular bundle of the leaf segments and of the eustelic stemwith its large central cavity, which assumed an anatomical featureresembling that of some pteridophyte stems. These impermeablesheaths, whose cells differentiate suberized walls, can playa major role in hampering the apoplastic leakage of the pressurizedwater solution which flows throughout the plant in xylem vesselsand contains the mineral nutrients taken up by the roots fromthe sediment. Moreover, these sheaths can function in preventingflooding of the aerenchymatic cavities of the submerged organs.In this way the endodermis-like sheaths preserve the correctcirculation of gas and nutrient solution through the entireorganism and assume great significance as a structural mechanismevolved by this species to survive and grow underwater.Copyright1999 Annals of Botany Company. Ranunculus trichophyllus,freshwater macrophyte, submerged angiosperm, anatomy, endodermis, endodermis-like sheaths, light microscopy, fluorescence microscopy.