Optimization of Dynamic Plant Nitrogen Uptake,Using Apriori Information of Plant Nitrogen Content

Emphasizing that model development should be in accordance with the context under consideration, a model for plant nitrogen uptake is developed for use in connection with soil nitrogen models. The aim of the modeling is to improve the accuracy in model simulations of plant nitrogen uptake by application of optimization theory and apriori information of plant nitrogen content. A simple soil nitrogen model is coupled to the plant nitrogen uptake model, and solutions, obtained by two different methods, are presented. Suggestion for how to use the modeling principles in connection with a more complex plant nitrogen uptake model, and apriori information of plant dry weight, is given. It is believed that the modeling principles can also be used on other types of dynamic models with given apriori information.     

An inexpensive and rapid method of plant water determination

Summary A wide-mouthed pycnometer was employed for rapid determination of plant water content. The principle involved is to weigh the pycnometer when filled with the homogenate of plant sample and water. The density of homogenate of dry plant needs to be known. Density of dry plant homogenate of a species is constant in time and with cultural treatment. For the five different plant species studied, water content values obtained by the proposed method were similar to those by oven-drying.     

Plant species richness,identity and productivity differentially influence key groups of microbes in grassland soils of contrasting fertility

The abundance of microbes in soil is thought to be strongly influenced by plant productivity rather than by plant species richness per se. However, whether this holds true for different microbial groups and under different soil conditions is unresolved. We tested how plant species richness, identity and biomass influence the abundances of arbuscular mycorrhizal fungi (AMF), saprophytic bacteria and fungi, and actinomycetes, in model plant communities in soil of low and high fertility using phospholipid fatty acid analysis. Abundances of saprophytic fungi and bacteria were driven by larger plant biomass in high diversity treatments. In contrast, increased AMF abundance with larger plant species richness was not explained by plant biomass, but responded to plant species identity and was stimulated by Anthoxantum odoratum. Our results indicate that the abundance of saprophytic soil microbes is influenced more by resource quantity, as driven by plant production, while AMF respond more strongly to resource composition, driven by variation in plant species richness and identity. This suggests that AMF abundance in soil is more sensitive to changes in plant species diversity per se and plant species composition than are abundances of saprophytic microbes.     

植物叶片厚度日变化规律数学模型的研究

为了实现对植物生长状态的精确控制,本文对植物的可观测性进行了研究．首先, 运用工业计量的先进方法研制了适合植物叶片精密测量的仪器,用该仪器对二种花卉植物进行了 6个月以上的监测,获得了所监测植物的短周期变化规律,从而证实了植物叶片厚度的“可测量性”．该变化规律的峰值发生在中午,成为研究的重点．对峰值期建立了具有微分形式的数学模型,该模型可为后续的控制研究提供重要的理论依据．     

Role of Arbuscular Mycorrhizal Fungi in Uptake of Phosphorus and Nitrogen From Soil

Abstract

Colonization of plant roots by arbuscular mycorrhizal fungi can greatly increase the plant uptake of phosphorus and nitrogen. The most prominent contribution of arbuscular mycorrhizal fungi to plant growth is due to uptake of nutrients by extraradical mycorrhizal hyphae. Quantification of hyphal nutrient uptake has become possible by the use of soil boxes with separated growing zones for roots and hyphae. Many (but not all) tested fungal isolates increased phosphorus and nitrogen uptake of the plant by absorbing phosphate, ammonium, and nitrate from soil. However, compared with the nutrient demand of the plant for growth, the contribution of arbuscular mycorrhizal fungi to plant phosphorus uptake is usually much larger than the contribution to plant nitrogen uptake. The utilization of soil nutrients may depend more on efficient uptake of phosphate, nitrate, and ammonium from the soil solution even at low supply concentrations than on mobilization processes in the hyphosphere. In contrast to ectomycorrhizal fungi, nonsoluble nutrient sources in soil are used only to a limited extent by hyphae of arbuscular mycorrhizal fungi. Side effects of mycorrhizal colonization on, for example, plant health or root activity may also influence plant nutrient uptake.     

Preparation of megabase-size DNA from plant nuclei

A novel technique has been developed for the preparation of high molecular weight (HMW) DNA from plant nuclei. This technique involves physical homogenization of plant tissues, nuclei isolation, embedding of the nuclei in low-melting-point agarose microbeads or plugs, and DNA purification in situ . This technique is simple, rapid, and economical, and the majority of the DNA prepared is over 5.7 Mb in size. The genomic DNA content of the HMW DNA prepared by this technique is enriched by at least threefold and the chloroplast DNA content is reduced by over twofold relative to that prepared from plant protoplasts by existing methods. The DNA is readily digestible with different restriction enzymes and partial digestions of the DNA could be reproducibly performed. This method has been successfully used for the preparation of HMW DNA from a wide range of plant taxa, including grasses, legumes, vegetables, and trees. These results demonstrate that the DNA prepared by this technique is suitable for plant genome analysis by pulsed-field gel electrophoresis and for the construction of yeast and bacterial artificial chromosomes.     

Conservation of plant diversity in Korea

Korea is a land of contrasts. The mountainous Korean peninsula arches north and northwest towards the Russian and Chinese borders, where the last areas of old growth coniferous forest and the land formed five forest types. Plant and habitat diversity in Korea has been largely damaged by various kinds of human activities. The plant diversity of Korea is severely threatened due to the high population density and rapid industrialization since the 1960s, as well as the illegal collection of wild plants for ornamental, medicinal, and food purposes. Natural areas have been greatly fragmented and survive only as ecological islands surrounded by modified cultivated and industrial lands. For instance, more than 60 industrial parks are located along the coast, and these have contributed to the rapid destruction of plant diversity in the coastal areas of the peninsula. The modern concept of plant conservation in Korea is still in an infant stage. The cooperation of plant conservation bodies with disciplinary approaches based on conservation biology are essential strategies to pursue plant conservation. The capacity building for plant conservation in Korea has different management regimes by the relevant ministries. Since the late 1990s, the plant conservation body Korean Plant Specialist Group of the International Union for the Conservation of Nature and Natural Resources Species Survival Commission (IUCN SSC) has been closely linked with international conservation bodies for in situ and ex situ conservation management. Under the umbrella of the national plant conservation strategies, the different strategies and working agencies can be fully integrated. Furthermore, the systematic approaches for the recovery of threatened species, as well as habitat monitoring over the long-term basis, will need to be supported by a stable budget policy. Also, protocol for the conservation of rare and endangered plant species, including recovery works in Korea, is strongly needed.     

The presence of generalist plant pathogens might not explain the long-term coexistence of plant species

Pathogens have been shown to contribute to the possibility of coexistence of competing plant species by creating ecological distinction between the coexisting species. This coexistence promoting mechanism resembles intra-specific density dependence as found in Lotka-Volterra models. However, plant species adapt in their level of resistance against pathogen infection and this adaptation has been shown to be traded-off by a reduction in growth rate. A model is developed to show that taking into account the possible adaptation of plant species to increase their resistance against pathogen infection by generalist pathogens has consequences for the coexistence of the plant species. The results show that in systems where plants adapt to the pathogen infection, coexistence becomes impossible. The implication of this finding is that plant pathogens might contribute less to the coexistence of plant species than is commonly thought.     

高通量植物生物反应器及其在遗传资源挖掘中的应用

生物反应器(bioreactor)是一种以表达目标产物或获得繁殖体为目的的设备系统,包括微生物、动物、植物生物反应器以及相关设备。植物生物反应器(phytobioreactor)是借鉴植物组织培养和微生物发酵原理制作的设备系统。其中,应用较广泛的是间歇浸没式植物生物反应器。与传统植物组织培养相比,该方法具备可换气、无需转接和大容量培养等特点。国内制作的BIOF系列新型植物生物反应器还可以利用串/并联方法,实现更高通量培养能力,其应用于植物种苗繁育、代谢产物的表达、耐盐等变异的定向筛选、植物生长发育的动态分析等方面均具备显著优势。现代植物生物技术在基础研究和产业方面的应用对植物生物反应器提出了新要求,新型生物反应器应用方法的持续改进和设备系统的不断完善,使其成为植物学领域的高效研究平台,并将促进植物育种和植物源化合物的发掘等方面研究效率的提高。     

Emerging role of roots in plant responses to aboveground insect herbivory

Plants have evolved complex biochemical mechanisms to counter threats from insect herbivory. Recent research has revealed an important role of roots in plant responses to above ground herbivory (AGH). The involvement of roots is integral to plant resistance and tolerance mechanisms. Roots not only play an active role in plant defenses by acting as sites for biosynthesis of various toxins and but also contribute to tolerance by storing photoassimilates to enable future regrowth. The interaction of roots with beneficial soil‐borne microorganisms also influences the outcome of the interaction between plant and insect herbivores. Shoot‐to‐root communication signals are critical for plant response to AGH. A better understanding of the role of roots in plant response to AGH is essential in order to develop a comprehensive picture of plant‐insect interactions. Here, we summarize the current status of research on the role of roots in plant response to AGH and also discuss possible signals involved in shoot‐to‐root communication.     

Development of a novel and efficient strategy for practical identification of Pyrus spp (Rosaceae) cultivars using RAPD fingerprints

Accurate and reliable cultivar identification of crop species is essential to guarantee plant material identity for purposes of registration, cultivar protection and production. To facilitate identification of plant cultivars, we developed a novel strategy for efficient recording of DNA molecular fingerprints in genotyped plant individuals. These fingerprints can be used as efficient referential information for quick plant identification. We made a random amplified polymorphic DNA (RAPD) marker analysis of 68 pear cultivars. All pear genotypes could be distinguished by a combination of eight 11-mer primers. The efficiency of the method was further verified by correct identification of four cultivars randomly chosen from the initial 68. The advantages of this identification include use of fewer primers and ease of cultivar separation by the corresponding primers marked on the cultivar identification diagram. The cultivar identification diagram can efficiently serve for pear cultivar identification by readily providing the information needed to separate cultivars. To the best of our knowledge, this is the most efficient strategy for identification of plant varieties using DNA markers; it could be employed for the development of the pear industry and for the utilization of DNA markers to identify other plant species.     

Molecular characterization of Haloxylon salicornicum Moq. in Saudi Arabia

The purpose of write this paper is to study the genetic variability between and within different Halosylon salicornicum populations in different regions of Saudi arabia Kingdom, using the determination of genetic fingerprint method by Inter Simple Sequence Repeat (ISSR). Because this plant highly vulnerable to depletion by humans in all places of existence, it is an economically valuable plant where raft is an important pastoral resource in central and northern Arabia. It also has multiple medical uses. It is a plant that can withstand abiotic stresses such as drought and high temperature, making it suitable for cultivation in marginal lands in arid areas. All of the above was a catalyst for plant characterization using a number of Haloxylon salicornicum samples, collected from different regions of Saudi Arabia to find out the genetic variation of species, genetic diversity in knowing the plant community is an essential step towards the design of programs for plant breeding as well as preserved from extinction. This was done using the Inter Simple Sequence Repeat (ISSR). The results showed there were significant differences and molecular differences between plant samples. The average polymorphism between the genetic inputs of the studied Haloxylon salicornicum samples was 53.7%, and this percentage of genetic variability is significant for progress in growth and plant regeneration in the face of unfair practices against it, in addition to adverse environmental conditions in most years. As evidenced by the percentage of matrix similarity. The ISSR results indicate that the genotype between five different regions genotypes ranged from 0.365 to 0.527, indicating that Haloxylon salicornicum is a local plant capable of surviving and adapting to the environmental conditions in Saudi Arabia through the positive change in the genetic makeup of this species.     

The steps of vascular plant and land ecosystem evolution

Basal steps of higher plant evolution are reconstructed by the structure of their conducting tissues. Historically, transport networks are derivatives of buffer zones for symbiotic exchange between prokaryotic pro-cursers. Two symbiogenetic acts (prochlorophytes + protists → higher algae; marine algae + fungi → higher land plants) are fixed in plant body by two networks for water transport. Descending phloem arises in phylogenesis from the membrane capsule of cyanobacteria. Fungi mycelium is a source of rising xylem exudates. The diversity of plant life forms is considered as a sequence of adaptive evolution of algo-myco-bacterial complex. Relationship to global chronical of climate events is shown by the specificities of Paleogene thermal floras and Neogene cold floras. The trends of plant genome size evolution are discussed.     

Long-term ant-species-dependent dynamics of a myrmecochorous plant community

Myrmecochory or seed dispersal by ants is a widely spread phenomenon, and myrmecochorous plants constitute a large portion of species in many ecosystems. Since the ant species complex in the ecosystem is continuously changing in time and space, the long-term effects of such ant–plant interactions on the plant community remained unclear. The manifold information obtained in numerous previous studies from one ecosystem in the deciduous forests of Central Ukraine allowed us to simulate the possible scenarios for plant survival and distribution in the ecosystem after a reduction in the number or local extinction of one of the ant species. The results of the virtual long-term experiment show that the abundance and spatial distribution of myrmecochorous plants strongly depends on both the abundance of ants and their species composition in the ecosystem. The positive role of ant species diversity for maintaining myrmecochorous plant species diversity is shown. Competition between plant species for seed dispersers is influenced by the ant community in such a way that the disappearance of one ant species may lead to the reduction or even local extinction of a particular plant population.     

高原鼠兔干扰对高寒草甸植物物种和功能性状beta多样性的影响

采用野外空间多点同步取样,分析了高原鼠兔干扰对高寒草甸植物物种beta多样性和植物功能性状beta多样性的影响,确定了高原鼠兔干扰下高寒草甸植物物种和功能性状beta多样性的变化途径,分别提出了高原鼠兔干扰区域内,基于植物物种多样性和功能性状多样性的高寒草甸植物多样性维持策略。结果表明,高原鼠兔干扰使高寒草甸植物物种相似性显著降低了28.1%,植物功能相似性降低了28.7%。尽管高原鼠兔干扰没有改变高寒草甸植物物种和功能性状beta多样性的变化途径,且对植物物种和功能性状的嵌套组分不存在显著影响,但高原鼠兔干扰显著降低了植物物种和功能性状周转组分所占的比例,降幅分别为36.6%和34.3%。高原鼠兔干扰区域内,高寒草甸植物物种beta多样性的变化以周转为主导(周转占比81.4%;嵌套占比:18.6%),植物功能性状beta多样性的变化以嵌套为主导(嵌套占比64.9%;周转占比35.1%)。因此,针对划定的高原鼠兔干扰区,需要同时保护区域内所有高原鼠兔栖息地(多位点保护),以达到维持植物物种多样性的目的,而可以仅通过保护该区域内植物功能性状丰富的位点,即可维持较高的植物功能多样性。     

A rule-based model for the functional analysis of vegetation change in Australasian grasslands

Abstract. Grasslands encompass a broad array of vegetation and climatic zones. We describe the first developments towards a rule-based functional model for predicting vegetation structure in Australian and New Zealand pastures and rangelands. The approach aims to predict the combined effects of climate and disturbance by humans and grazing livestock, and to provide a level of resolution needed for predicting changes in pastures and rangelands. We enlisted expert knowledge to develop: (1) a minimum set of critical traits; (2) rules relating site variables to favoured plant attributes; (3) rules relating attributes to plant functional traits, and (4) rules relating plant functional types to likely plant communities. We tested the resulting model by deriving some simple predictions of plant communities of some existing pasture and rangeland sites in Australia and New Zealand, with differing climatic and human disturbance inputs. The results indicate that this first model is able to predict plant communities with varying success rates, and with the best results in cases where there are extreme climates or high management inputs. Key sensitivities in the model where further research is required include: (1) the urgent need for more explicit understanding of the key plant functional attributes favoured by differing climates and disturbance regimes, (2) the functional relationships between these plant functional attributes and recognisable plant functional types in vegetation, and (3) the assembly rules for the coexistence of these different plant functional types in major plant communities. The same understanding is required for subsequent process-based modelling development.     

Simulating the effects of localized red:far-red ratio on tillering in spring wheat (Triticum aestivum) using a three-dimensional virtual plant model

The outgrowth of tiller buds in Poaceae is influenced by the ratio of red to far-red light irradiance (R:FR). At each point in the plant canopy, R:FR is affected by light scattered by surrounding plant tissues. This paper presents a three-dimensional virtual plant modelling approach to simulate local effects of R:FR on tillering in spring wheat (Triticum aestivum). R:FR dependence of bud outgrowth was implemented in a wheat model, using three hypothetical responses of bud extension to R:FR (unit step, curvilinear and linear response). Bud break occurred when a threshold bud length was reached. Simulations were performed for three plant population densities. In accordance with experimental observations, fewer tillers per plant were simulated for higher plant population densities. The linear and curvilinear responses caused a delay in the increase in tiller number compared with experimental data. The unit step response approached experimental results best. It is suggested that a model based on relatively simple relations can be used to simulate degree of tillering. This study has shown that the virtual plant approach is a promising tool with which to address crop morphological and ecological research questions where the determining factors act at the level of the individual plant organ.     

Exogenous application of plant defense hormones alters the effects of live soils on plant performance

The overall effect of a live soil inoculum collected from nature on plant biomass is often negative. One hypothesis to explain this phenomenon is that the overall net pathogenic effect of soil microbial communities reduces plant performance. Induced plant defenses triggered by the application of the plant hormones jasmonic acid (JA) and salicylic acid (SA) may help to mitigate this pathogenic effect of live soil. However, little is known about how such hormonal application to the plant affects the soil and how this, in turn, impacts plant growth. We grew four plant species in sterilized and inoculated live soil and exposed their leaves to two hormonal treatments (JA and SA). Two species (Jacobaea vulgaris and Cirsium vulgare) were negatively affected by soil inoculation. In these two species foliar application of SA increased biomass in live soil but not in sterilized soil. Two other species (Trifolium repens and Daucus carota) were not affected by soil inoculum and for these two species foliar application of SA reduced plant biomass in both the sterilized and live soil. Application of JA reduced plant biomass in both soils for all species. We subsequently carried out a multiple generation experiment for one of the plant species, J. vulgaris. In each generation, the live soil was a mixture of 10% soil from the previous generation and 90% sterilized soil and the same hormonal treatments were applied. The negative effects of live soil on plant biomass were similar in all four generations, and this negative effect was mitigated by the application of SA. Our research suggests that the application of SA can mitigate the negative effects of live soil on plant growth. Although the inoculum of soil containing a natural live soil microbial community had a strong negative effect on the growth of J. vulgaris, we found no evidence for an increase or decrease in negative plant-soil feedback in either the control or the SA treated plants. Also plant performance did not decrease consistently with succeeding generations.