A model for water uptake by plant roots

We present a model for water uptake by plant roots from unsaturated soil. The model includes the simultaneous flow of water inside the root network and in the soil. It is constructed by considering first the water uptake by a single root, and then using the parameterized results thereby obtained to build a model for water uptake by the developing root network. We focus our model on annual plants, in particular the model will be applicable to commercial monocultures like maize, wheat, etc. The model is solved numerically, and the results are compared with approximate analytic solutions. The model predicts that as a result of water uptake by plant roots, dry and wet zones will develop in the soil. The wet zone is located near the surface of the soil and the depth of it is determined by a balance between rainfall and the rate of water uptake. The dry zone develops directly beneath the wet zone because the influence of the rainfall at the soil surface does not reach this region, due to the nonlinear nature of the water flow in the partially saturated soil. We develop approximate analytic expressions for the depth of the wet zone and discuss briefly its ecological significance for the plant. Using this model we also address the question of where water uptake sites are concentrated in the root system. The model indicates that the regions near the base of the root system (i.e. close to the ground surface) and near the root tips will take up more water than the middle region of the root system, again due to the highly nonlinear nature of water flow in the soil.     

Disturbance by the mound-building termite,shape Trinervitermes trinervoides,and vegetation patch dynamics in a semi-arid,southern African grassland

Changes in the composition and abundance of grasses and shrubs, soil fertility, and the productivity and nutrition of the grass, Themeda triandra, were examined along an age gradient of Trinervitermes trinervoides mounds occurring in a semi-arid grassland of the Free State, South Africa. The composition and abundance of grasses and shrubs change alongside mounds as they become inactive and then erode away. The pioneer grass, Tragus koelerioides, and the climax grass, Themeda triandra, dominate around active mounds. As the mounds become inactive and erode away, these two grass species are replaced by the subclimax grass, Eragrostis lehmanniana, along with an increase in the cover of the unpalatable shrub, Walafrida saxatilis. Mound soils, in contrast, are sparsely vegetated and only change in composition, and the population abundance of T. triandra, on old active mounds compared to earlier or older mound age states. Soils on eroded mounds are more acidic, and contain higher concentrations of Mg, Ca, N, P, and total exchangeable cations (T.E.C.) than soils occurring 0.5 m from the margins of eroded, inactive and active mounds. A plant bioassay, using Lolium perenne, confirms the higher soil fertility on eroded mounds but also shows significant increases in soil fertility alongside inactive and eroded mounds. Pot experiments show an increase in the production of T. triandra plants grown on soils from eroded mounds, and those occurring alongside inactive and eroded mounds. Foliar protein and nitrogen increase when these plants are grown on soils from eroded mounds. Mounds of T. trinervoides are foci of biotic disturbance because they alter soil resources, and the population abundance and composition of grasses and shrubs in the first metre around their margins. Increases in soil fertility alongside inactive and eroded mounds, and the accompanying increase in the productivity of T. triandra, along with signs of its foliar nutrient enrichment, suggest the removal of this species through preferential grazing by animals as the mounds become inactive and erode away.Plant nomenclature: follows Gibbs Russell, G. E., Reid, C., Van Rooyen, J. & Smook, L. 1985. List of species of southern African plants. Mem. Bot. Surv. S. Afr. 51: 1-152, and Gibbs Russell, G. E., Welman, W. G., Retief, E., Immelman, K. L., Germishuizen, G., Pienaar, B. J., Van Wyk, M. & Nicholas, A. 1987. List of species of southern African plants. Mem. Bot. Surv. S. Afr. 56: 1–270.     

Space exploration by dendritic cells requires maintenance of myosin II activity by IP3 receptor 1

Dendritic cells (DCs) patrol the interstitial space of peripheral tissues. The mechanisms that regulate their migration in such constrained environment remain unknown. We here investigated the role of calcium in immature DCs migrating in confinement. We found that they displayed calcium oscillations that were independent of extracellular calcium and more frequently observed in DCs undergoing strong speed fluctuations. In these cells, calcium spikes were associated with fast motility phases. IP₃ receptors (IP₃Rs) channels, which allow calcium release from the endoplasmic reticulum, were identified as required for immature DCs to migrate at fast speed. The IP₃R1 isoform was further shown to specifically regulate the locomotion persistence of immature DCs, that is, their capacity to maintain directional migration. This function of IP₃R1 results from its ability to control the phosphorylation levels of myosin II regulatory light chain (MLC) and the back/front polarization of the motor protein. We propose that by upholding myosin II activity, constitutive calcium release from the ER through IP₃R1 maintains DC polarity during migration in confinement, facilitating the exploration of their environment.     

Ecological and evolutionary consequences of spatial and temporal variation in pre-dispersal seed predation

Pre-dispersal seed predation may have important effects on population dynamics and trait evolution in plants. In this review, we first present a conceptual framework of the strength of pre-dispersal seed predation and its variation in space and time. We consider the interaction between plants and their seed predators to be “strong” when it affects plant population dynamics or causes changes in plant trait–fitness relationships, and “weak” when it has no such effects, and propose ways of how to adequately assess these effects. Second, we review the ecological literature between 1991 and 2005 to evaluate documented effects of pre-dispersal seed predation on plants and draw five major conclusions. (1) Pre-dispersal seed predation rates are usually low but sometimes high, and show a considerable variation in space and time. (2) Direct evidence suggests that pre-dispersal seed predation can have a significant effect on recruitment and plant population growth rate. Accumulating evidence of seed-limited recruitment suggests that such effects are common. (3) Pre-dispersal seed predation affects selection on several plant traits, such as flowering phenology and flower number, which are usually interpreted mainly in the context of plant–pollinator interactions. (4) The patterns of variation in the interactions between plants and pre-dispersal seed predators suggest that geographic selection mosaics may be common. (5) Although there are numerous studies estimating seed predation, there are still rather few studies that have aimed at examining the interaction explicitly in terms of effects on plant population dynamics and trait selection. From these we know that seed predators can have important, and often variable, effects on plant population dynamics and trait evolution. However, it still remains to assess how important they are across study systems and relative to other aspects of the plant's biotic and abiotic environment.     

BIOLOG系统鉴定黄瓜根围促生菌的初步研究

对筛选出的８株具有明显促生防病作用的黄瓜根围促生菌ＣＮ１１,ＣＮ３１,ＣＮ４５,ＣＮ１ １６,ＣＮ１２９,ＸＢ１２０,ＸＢ５,ＸＢ４１通过ＢＩＯＬＯＧ法进行了分类鉴定,分别为：铜绿假单胞菌（Ｐｓｅｎｄｏｍｏｎａｓ ａｅｒｕｇｉｎｏｓａ）,波纹假单胞菌（Ｐ． Ｃｏｒｒｕｇａｔａ）,短芽孢杆菌（Ｂａｃｉｌｌｕｓ ｂｒｅｖｉｓ）,荧光假单胞菌Ｂ型（Ｐ． Ｆｌｕｏｒｅｓｃｅｎｓ ｔｙｐｅ Ｂ）,铜绿假单胞菌（Ｐ． Ａｅｒｕｇｉｎｏｓａ）,荧光假     

Gaps in the canopy: the missing dimension in vegetation dynamics

Canopy gaps are important as entry points for new genotypes and new species into many types of vegetation, yet little is known about them in any type of vegetation but forests. Forest gaps are too large for manipulative experiments to be readily undertaken, and hitherto grassland gaps have been too small to be easily mapped. Preliminary results from mapping small (>1 cm) grassland gaps with a new fibre-optic device suggest that experiments need to be performed at a smaller physical scale than has hitherto been achieved.     

Modification of plant hormone levels and signaling as a tool in plant biotechnology

Plant hormones are signal molecules, present in trace quantities, that act as major regulators of plant growth and development. They are involved in a wide range of processes such as elongation, flowering, root formation and vascular differentiation. For many years, agriculturists have applied hormones to their crops to either increase the yield, or improve the quality of the commercial product. Nowadays, the knowledge of hormone biosynthesis, degradation and signaling pathways has allowed the utilization of biotechnological tools to further improve the main agricultural crops. Natural or artificial mutants, with impaired functioning of the corresponding genes, have been adopted because of their superior phenotype in specific agricultural traits. In addition, transgenic plants have been generated to regulate internal hormone levels, or their signaling pathways, resulting in some crops that have revolutionized agriculture.     

Modeling of Branching Patterns in Plants

A major determinant of plant architecture is the arrangement of branches around the stem, known as phyllotaxis. However, the specific form of branching conditions is not known. Here we discuss this question and suggest a branching model which seems to be in agreement with biological observations. Recently, a number of models connected with the genetic network or molecular biology regulation of the processes of pattern formation appeared. Most of these models consider the plant hormone, auxin, transport and distribution in the apical meristem as the main factors for pattern formation and phyllotaxis. However, all these models do not take into consideration the whole plant morphogenesis, concentrating on the events in the shoot or root apex. On the other hand, other approaches for modeling phyllotaxis, where the whole plant is considered, usually are mostly phenomenological, and due to it, do not describe the details of plant growth and branching mechanism. In this work, we develop a mathematical model and study pattern formation of the whole, though simplified, plant organism where the main physiological factors of plant growth and development are taken into consideration. We model a growing plant as a system of intervals, which we will consider as branches. We assume that the number and location of the branches are not given a priori, but appear and grow according to certain rules, elucidated by the application of mathematical modeling. Four variables are included in our model: concentrations of the plant hormones auxin and cytokinin, proliferation and growth factor, and nutrients—we observe a wide variety of plant forms and study more specifically the involvement of each variable in the branching process. Analysis of the numerical simulations shows that the process of pattern formation in plants depends on the interaction of all these variables. While concentrations of auxin and cytokinin determine the appearance of a new bud, its growth is determined by the concentrations of nutrients and proliferation factors. Possible mechanisms of apical domination in the frame of our model are discussed.