Mathematical Modeling of the Dynamics of Plant Mineral Nutrition in the Fertilizer–Soil–Plant System

A numerical simulation of the spatial–temporal dynamics of a multi-parameter system has been developed. The components of this system are plant biomass, the mobile and stationary forms of mineral nutrition elements, rhizosphere microorganisms, and environmental parameters (temperature, humidity, and acidity). Parametric identification and verification of the adequacy of the model were carried out based on the experimental data on the growth of Krasnoufimskaya-100 spring wheat on peat lowland soil. The results are represented by temporal distributions of biomass from agricultural crops and the findings on the contents of the main nutrition elements within the plant (nitrogen, phosphorus, and potassium). An agronomic assessment and interpretation of the results are given.

     

Common Physical Errors in the Description of Water Fluxes in the Soil–Plant–Atmosphere System

Widely accepted concepts and definitions concerning the driving forces of upward water fluxes, such as osmotic pressure (OP) and water potential (WP), were analyzed in the soil–plant–atmosphere system. It is emphasized that, at present, there are no physically correct definitions of the mentioned parameters, because such a concept as the heat pressure of molecules in a liquid has not been introduced. Physical definitions of OP and WP are presented. It is demonstrated that WP is not a driving force for water fluxes at the water–vapor interface. The fundamental difference in mechanisms of diffusion fluxes and active transport across the biological membranes is analyzed. The biological specificity of driving forces at the soil–root and leaf–air interfaces is described.     

Soil Type and Maize Cultivar Affect the Genetic Diversity of Maize Root–Associated Burkholderia cepacia Populations

Abstract Burkholderia cepacia populations associated with the Zea mays root system were investigated to assess the influence of soil type, maize cultivar, and root localization on the degree of their genetic diversity. A total of 180 B. cepacia isolates were identified by restriction analysis of the amplified 16S rDNA (ARDRA technique). The genetic diversity among B. cepacia isolates was analyzed by the random amplified polymorphic DNA (RAPD) technique, using the 10-mer primer AP5. The analysis of molecular variance (AMOVA) method was applied to estimate the variance components for the RAPD patterns. The results indicated that, among the factors studied, the soil was clearly the dominant one in affecting the genetic diversity of maize root–associated B. cepacia populations. In fact, the percentage of variation among populations was significantly higher between B. cepacia populations recovered from maize planted in different soils than between B. cepacia populations isolated from different maize cultivars and from distinct root compartments such as rhizoplane and rhizosphere. The analysis of the genetic relationships among B. cepacia isolates resulted in dendrograms showing bacterial populations with frequent recombinations and a nonclonal genetic structure. The dendrograms were also in agreement with the AMOVA results. We were able to group strains obtained from distinct soils on the basis of their origin, confirming that soil type had the major effect on the degree of genetic diversity of the maize root–associated B. cepacia populations analyzed. On the other hand, strains isolated from distinct root compartments exhibited a random distribution which confirmed that the rhizosphere and rhizoplane populations analyzed did not significantly differ in their genetic structure. Received: 22 January 1999; Accepted: 7 April 1999     

Microevolution of Nodule Bacteria upon Generation of Mutants with Altered Survival in the Plant–Soil System

Simulation of cyclic processes in the plant–soil system was used to analyze the effects of factors responsible for the population dynamics of rhizobia on generation of mutants with changedex planta viability. Rhizobial evolution in a system of ecological niches (soil, rhizosphere, nodules) was described with recurrent equations. Computer experiments were carried out with parameters determining the mutation pressure, selection, and amplitude of the population wave arising in soil on the release of bacteria from nodules and the rhizosphere. Analysis of the model showed that (1) mutants with enhanced ex planta viability do not completely replace the parental strain and (2) mutants with impaired ex planta viability may be fixed in the population. The maintenance of genotypes subject to elimination from the soil and rhizosphere by Darwinian selection was associated with frequency-dependent selection (FDS), which is effective in competition for nodulation. The FDS index was proposed to characterize FDS pressure and was shown to determine the population polymorphism for adaptive traits. An increase in population wave amplitude proved to increase the fixation level (the proportion in the limiting state of the system) of mutants with enhanced viability and to decrease it in mutants with low viability. The results obtained with the model agreed with the data that, in edaphic stress, rhizobial populations remain highly polymorphic, which is associated with the maintenance of sensitive strains. The simulation procedure may be employed in estimating the genetic consequences of introduction of modified rhizobial strains in the environment.     

The Calculative Nature of Microbe–Mineral Interactions

Microorganisms continually redefine themselves at many levels, including the molecule, cell, and community. Although it was initially assumed that this resulted from the genesis of information within DNA alone, it has since been shown that innovation originates at multiple levels. This occurs through calculative units, each unit consisting of two proliferating structures, one nested within the other and each undergoing changes in structural geometry that affect the proliferation rate of the other. For example, the recombination of genetic structures affects the proliferation of community structures, and the recombination of community structures affects the proliferation of genetic structures. The proliferation of a nested series of structures (e.g., genes proliferating within cells, cells proliferating within communities, communities proliferating within ecosystems) results in a logic circuit that calculates the form and function of each structural element in the series. In this situation each element functions as both a habitat and an inhabitant (environment and organism), and it is this dichotomy that determines the balance of nature. Nested geological structures, such as minerals and continents, also proliferate and redefine themselves in much the same way. Microbe–mineral interactions thus link nested biological calculations to an analogous set of nested geological calculations. Examples include the microorganisms involved in the nucleation (proliferation) of ferric hydroxides, carbonates, silicates, and ice crystals.     

A Model of the Hippocampal–cortical Memory System

Based on physiological evidence, we propose a theoretical model of the hippocampal–cortical memory system. The model consists of the following components: the sensory system, the hippocampus (short-term memory), and the association cortex (long-term memory). A series of key codes (local information) is supplied from the sensory system, while context (global information) is inputted from the hippocampus. The two inputs interact dynamically in the association cortex. The interactive neurons work as a detector of coincidence. The cortical network learns the memory information through the coincidence window and, finally, stores it in the form of attractors. This local–global information works as an addressor to designate the stored location of the memory in the association cortex and accelerates the process of storing and retrieving memory information.     

Gas Transport through the Root–shoot Transition Zone of Rice Tillers

Rice plants (Oryza sativa L.) are mainly cultivated in flooded paddy fields and are thus dependent on oxygen transport through the plant to maintain aerobic root metabolism. This gas transport is effectuated through the aerenchyma of roots and shoots. However, the efficiency of gas transport through the root–shoot transition zone is disputed and there are indications that the root–shoot transition zone may represent one of the largest resistances for gas transport. Therefore, we present gas conductance measurements of the root–shoot transition of individual rice tillers measured using SF₆. SF₆ was detected with a highly advanced laser based photoacoustic detection scheme allowing sensitive, high resolution measurements. In conjunction with these measurements, various plant morphological parameters were quantified. These measurements indeed indicate that the conductance at the root–shoot transition may be much smaller than the conductance of root and shoot aerenchyma within the rice plant. Conductance was strongly correlated to tiller transverse area. After elimination of tiller area from the conductance equation, the resulting permeance coefficient was still correlated to tiller area, but negatively and related to the process of radial tiller expansion. In addition, a decrease in the permeance coefficient was also observed for increasing distance from the plant centre. No correlation was found with tiller type or age of the mother tiller. Incorporation of estimates of the conductance of the root–shoot transition zone coupled to plant morphological parameters will allow considerable improvement of understanding and models on gas transport through plants.     

Manifestations of Dissolution of the Central Nervous System in the Wakefulness–Sleep Cycle of Mammals

The data are presented on three stages of formation of the wakefulness–sleep cycle (WSC) in representatives of poikilothermal animals (fish, amphibians, and reptiles), which are formed in accordance with morphofunctional stages of CNS integration. Comparison of morphofunctional development of brain structures in ontogenesis of mammals with dynamics of formation of the WSC neurophysiological parameters allows revealing similarity and parallelism in phylo- and ontogenetic stages of development of this cycle. All these results confirm the statement that in the process of transition from wakefulness to sleep there occurs a gradual rearrangement of activity of the evolutionary formed levels of CNS integration from the cortico-striatal to the bulbar integration. It is emphasized that unlike the known classical concept of CNS dissolution in pathological catastrophes in its activity, processes of periodical functional dissolution of CNS perform an important protective-restorative function and are vitally important to an organism.     

Isolation of β-Tocopherol from the Root Bark of the Mulberry Tree

Kluyvera citrophila KY7844 enzymatically catalyzed N-acylation of 7-amino-desacetoxycephalosporanic acid with 1-(1H)-tetrazolylacetate methylester to produce 7-[1-(1H)-tetrazolylacetamido]-desacetoxycephalosporanic acid. The product was purified and characterized.     

Co-Composting of Soil Heavily Contaminated with Creosote with Cattle Manure and Vegetable Waste for the Bioremediation of Creosote–Contaminated Soil

Mispah form (FAO: Lithosol) soil contaminated with >380 000 mg kg^?1 creosote was co-composted with cattle manure and mixed vegetable waste for 19 months. The soil was mixed with wood chips to improve aeration and then mixed with cattle manure or mixed vegetable waste in a ratio of 4:1. Moisture, temperature, pH, ash content, C:N ratios, and the concentrations of creosote in the compost systems were monitored monthly. The concentrations of selected hydrocarbons in the compost systems were determined at the end of composting. Temperature rose to about 45°C in the cattle manure compost within two months of incubation while temperature in the control and vegetable waste remained below 30°C until the fourth month. Creosote concentration was reduced by 17% in the control and by more than 99% in the cattle manure and vegetable waste compost after composting. The rate of reduction in concentration in the mixed vegetable waste compost was initially lower than in the cattle manure compost. The reduction rate became similar in later months with only small differences towards the end of the composting. The concentrations of selected creosote components were reduced by between 96% and 100% after composting. There was no significant difference in reduction in concentration in both compost systems at p 0.05. Microbial activity correlated with reduction in creosote concentration.     

The Role of the Transport System in the Control of the Source–Sink Relations in Pinus sylvestris

Morphophysiological correlations were studied in medium-aged (20- to 60-year-old) Scots pine trees under the northern taiga conditions. Under various ecological conditions, pine trees developed a well-balanced structure, with close linear relationships between needle and root weight and their cross-section areas in all components of the continuous transport network (the coefficient of determination was between 0.88 and 0.999). When the annual cycle of soluble and insoluble carbohydrate contents was followed in various pine tissues, the total concentrations of soluble and insoluble carbohydrates were maintained at constant and tissue-specific levels, except in the growth period. The maximum level of carbohydrates was observed in all tissues at the beginning of rapid growth, and the minimum, at growth cessation. The qualitative composition and amount of carbohydrates matched the phenological phases of development and were not affected by the ecological growth conditions pertinent to the particular environment. The authors conclude that assimilate synthesis and partitioning are related to structural development, and the state of sink centers determines the attracting capacity, whereas the transport network, from roots to needles, and its conducting capacity are essential for the realization of systemic relationships and the control over growth and development in Pinus sylvestris L.     

Changes in Root Exudates and Root Proteins in Groundnut–Pseudomonas sp. Interaction Contribute to Root Colonization by Bacteria and Defense Response of the Host

Journal of Plant Growth Regulation - Selection and application of rhizobacteria, for improved plant health will benefit from a complete understanding of the plant–bacteria interaction. Root...     

System identification of muscle–joint interactions of the cat hind limb during locomotion

Neurophysiological experiments in walking cats have shown that a number of neural control mechanisms are involved in regulating the movements of the hind legs during locomotion. It is experimentally hard to isolate individual mechanisms without disrupting the natural walking pattern and we therefore introduce a different approach where we use a model to identify what control is necessary to maintain stability in the musculo-skeletal system. We developed a computer simulation model of the cat hind legs in which the movements of each leg are produced by eight limb muscles whose activations follow a centrally generated pattern with no proprioceptive feedback. All linear transfer functions, from each muscle activation to each joint angle, were identified using the response of the joint angle to an impulse in the muscle activation at 65 postures of the leg covering the entire step cycle. We analyzed the sensitivity and stability of each muscle action on the joint angles by studying the gain and pole plots of these transfer functions. We found that the actions of most of the hindlimb muscles display inherent stability during stepping, even without the involvement of any proprioceptive feedback mechanisms, and that those musculo-skeletal systems are acting in a critically damped manner, enabling them to react quickly without unnecessary oscillations. We also found that during the late swing, the activity of the posterior biceps/semitendinosus (PB/ST) muscles causes the joints to be unstable. In addition, vastus lateralis (VL), tibialis anterior (TA) and sartorius (SAT) muscle-joint systems were found to be unstable during the late stance phase, and we conclude that those muscles require neuronal feedback to maintain stable stepping, especially during late swing and late stance phases. Moreover, we could see a clear distinction in the pole distribution (along the step cycle) for the systems related to the ankle joint from that of the other two joints, hip or knee. A similar pattern, i.e., a pattern in which the poles were scattered over the s-plane with no clear clustering according to the phase of the leg position, could be seen in the systems related to soleus (SOL) and TA muscles which would indicate that these muscles depend on neural control mechanisms, which may involve supraspinal structures, over the whole step cycle.     

Predicting Soil Salinity with Vis–NIR Spectra after Removing the Effects of Soil Moisture Using External Parameter Orthogonalization

Robust models for predicting soil salinity that use visible and near-infrared (vis–NIR) reflectance spectroscopy are needed to better quantify soil salinity in agricultural fields. Currently available models are not sufficiently robust for variable soil moisture contents. Thus, we used external parameter orthogonalization (EPO), which effectively projects spectra onto the subspace orthogonal to unwanted variation, to remove the variations caused by an external factor, e.g., the influences of soil moisture on spectral reflectance. In this study, 570 spectra between 380 and 2400 nm were obtained from soils with various soil moisture contents and salt concentrations in the laboratory; 3 soil types × 10 salt concentrations × 19 soil moisture levels were used. To examine the effectiveness of EPO, we compared the partial least squares regression (PLSR) results established from spectra with and without EPO correction. The EPO method effectively removed the effects of moisture, and the accuracy and robustness of the soil salt contents (SSCs) prediction model, which was built using the EPO-corrected spectra under various soil moisture conditions, were significantly improved relative to the spectra without EPO correction. This study contributes to the removal of soil moisture effects from soil salinity estimations when using vis–NIR reflectance spectroscopy and can assist others in quantifying soil salinity in the future.     

The Nature of the Inhibitory Action of Anionic Polyamidoamine Dendrimers of Generation 1.5–3.5 on the Activity of the Fibrinolytic System

Russian Journal of Bioorganic Chemistry - Polyamidoamine (PAMAM) dendrimers are used in medicine for systemic drug delivery. The safety assessment of biomaterials, which come into contact with...     

Sex Differences in Hypertension: Contribution of the Renin–Angiotensin System

Numerous studies have shown that female human beings exhibit lower blood pressure levels over much of their life span compared with their age-matched counterparts. This sexual dimorphism is apparent in human beings as well as most, if not all, mammals. However, after the onset of menopause blood pressure levels in women increase and become similar to those in men, suggesting an important role of sex hormones in the regulation of blood pressure. The lower blood pressure levels in premenopausal women are associated with a lower risk of development and progression of cardiovascular disease and hypertension compared with age-matched men. This clear female advantage with respect to lower incidence of cardiovascular disease no longer exists after menopause, again highlighting the importance of sex hormones in the pathophysiology of cardiovascular disease in both men and women. In fact, both estrogens and androgens have been implicated in the development of cardiovascular disease and hypertension, with estrogens, in general, being protective and androgens being detrimental. Although the exact mechanisms by which sex hormones contribute to the regulation of cardiovascular function and blood pressure are still being investigated, there is increasing evidence that modulating the activity of locally active hormonal systems is one of the major mechanisms of sex hormone actions in target organs, including the vasculature and kidneys. Indeed, several studies have demonstrated the importance of the interaction between sex hormones and the renin–angiotensin system in regulating cardiovascular function and blood pressure. Furthermore, the differential effects of estrogens and androgens on the expression and activity of the components of the renin–angiotensin system could possibly explain the sex differences in blood pressure levels and the development and progression of cardiovascular disease and hypertension.