Root CEC determinations to establish root biomasses of two plant species grown in mixtures

Summary The use of measurements on the cation exchange capacity (CEC) of roots in competition experiments with two plant species is suggested. If the root-CEC differences between the two species are not too small, measurement of this parameter offers a very simple way to determine the separate contributions of the two plant species in the total root biomass of the mixture. This root-CEC method can be applied to total root yields as well as to detailed root-zone studies.Grassland Species Research Group, Publication no. 48     

Enantioseparation of glycyl-dipeptides by CEC using particle-loaded monoliths prepared by ring-opening metathesis polymerization (ROMP)

Novel particle-loaded monolithic capillary electrochromatography (CEC) phases for chiral separations were prepared via ring-opening metathesis polymerization (ROMP) within the confines of fused silica columns with 200 microm i.d. using norborn-2-ene (NBE), 1,4,4a,5,8,8a-hexahydro-1,4,5,8,exo,endo-dimethanonaphthalene (DMN-H6) as monomers, 2-propanol and toluene as porogens, RuCl2(PCy3)2(CHPh) as initiator and silica-based particles containing the chiral selector. By suspending silica particles bearing the chiral selector in the polymerization mixture, particle-based monoliths are easily prepared. This approach has several advantages compared to particle-based separation media: (i) the concept of particle-based monoliths is broadly applicable, as any silica-based chiral phase can be used; (ii) they are inexpensive to prepare; and (iii) the manufacturing process is very simple, no sophisticated packing procedures or the preparation of end frits are required. To show the usefulness of this concept for chiral CEC, the chiral separation performance of particle-loaded CEC monoliths bearing teicoplanin aglycone, chemically bonded to 3 microm silica gel, was investigated for a set of glycyl-dipeptides. Particle-loaded ROMP CEC monoliths showed good separation performance for glycyl-dipeptides.     

Root navigation by self inhibition

Circumventing physical obstacles is critical for a plant's survival and performance. Although the ability of roots to circumvent obstacles has been known for over 100 years, the phenomena and its mechanisms have received relatively little attention. In this study it is demonstrated that roots of Pisum sativum are able to detect and avoid growth towards inanimate obstacles and the hypothesis that this behaviour is based on the sensitivity of roots to their own allelopathic exudates that accumulate in the vicinity of physical obstacles is tested. The development of lateral roots of Pisum sativum towards an obstacle (a piece of nylon string, similar in dimensions to a plant root) was followed. Lateral roots were similar in number, but significantly shorter in the direction of the nylon string. In addition, up to half of the lateral roots that developed towards the nylon string withered, whereas no withering was observed in the absence of the nylon string. These avoidance growth patterns were suppressed in the presence of potassium permanganate or activated carbon, indicating a role of allelopathic exudates in promoting obstacle avoidance. The demonstrated obstacle avoidance by self inhibition could increase plant performance by limiting resource allocation to less promising parts of the root system.     

Physicochemical selectivity for cations and CEC of grass roots

Summary A study of root selective adsorption of Ca, Mg, K and Na was made with rootlets of 20 species of Gramineae (from natural vegetation) exhibiting low cation exchange capacities (CEC) scattered over a narrow range 7.6–16.7 meq 100 g^-1 dry matter). For each sample of rootlets successive measurements were made of its CEC (amount of Ca adsorbed from 0.05 N calcium nitrate solution) and the amounts of Ca, Mg, K and Na adsorbed from a tetracationic nitrate solution having equal concentrations (0.05 N) of each cation. Rootlet selectivity for bivalent cations increased with CEC and was greater for Ca than for Mg. In contrast, the selectivity for monovalent cations increased with decreasing CEC and was greater for K than for Na. A root's selective adsorption may therefore be governed by its CEC, in conformation with the exchange laws, as is the case with clays and resins. Paper read at the XII International Botanical Congress (mineral nutrition session) held in Leningrad, July, 1975.     

Root colonization by endophytic insect-pathogenic fungi

Several ascomycetous insect-pathogenic fungi, including species in the genera Beauveria and Metarhizium, are plant root symbionts/endophytes and are termed as endophytic insect-pathogenic fungi (EIPF). The endophytic capability and insect pathogenicity of Metarhizium are coupled to provide an active method of insect-derived nitrogen transfer to plant hosts via fungal mycelia. In exchange for the insect-derived nitrogen, the plant provides photosynthate to the fungus. This symbiotic interaction offers other benefits to the plant—EIPF can improve plant growth, they are antagonistic to plant pathogens and herbivores and can enhance the plant tolerance to abiotic stresses. The mechanisms and underlying biochemical and genetic features of insect pathogenesis are generally well-established. However, there is a paucity of information regarding the underlying mechanisms in this plant-symbiotic association. Here we review five aspects of EIPF interactions with host plant roots: (i) rhizosphere colonization, (ii) signalling factors from the plant and EIPF, (iii) modulation of plant defence responses, (iv) nutrient exchange and (v) tripartite interactions with insects and other micro-organisms. The elucidation of these interactions is fundamental to understanding this symbiotic association for effective application of EIPF in an agricultural setting.     

Root colonization by symplasmata-forming Enterobacter agglomerans

Abstract Enterobacter agglomerans strains are able to form cell aggregates called symplasmata when grown in a liquid medium. The nitrogen-fixing E. agglomerans strain NO30, isolated from the rhizosphere soil of rice, was inoculated onto roots of axenically grown wheat and rice seedlings and could colonize the roots of both plants. The ability of NO30 cells to colonize the plant roots seemed comparable in the host and non-host plants, as far as colony forming units (cfu) measurements were concerned. Nevertheless, electron microscopy (SEM, TEM) revealed that, in the case of rice, the normal host plant for NO30, the colonization was characterized by the formation of symplasmata, whereas only individual cells were found on wheat roots. Symplasmata formation seems to be specific for colonization of the host plant, rice. This finding also means that colonization of the host plant may be largely underestimated when measured by conventional techniques. Symplasmata formed in liquid medium or on the roots of rice were stained using Thiery's and Swift's technique, and the presence of polysaccharides and proteins was revealed in the extracellular matrix as well as in fibrils anchoring symplasmata to other symplasmata or to plant cells.     

Root growth as influenced by aggregate size

Summary This study examined the effects of aggregate size on root impedance and developed an equation to describe the root pressure necessary to avoid deflection around an aggregate. This critical root pressure was predicted to increase with increasing aggregate size, decreasing root diameter, and decreasing deflection angle. In growth chamber experiments, maize (Zea mays L.) seedlings were grown in A horizon material of Groseclose silt loam (Clayey, mixed, mesic, Typic Hapludult). The soil had been moist sieved into different aggregate sizes (0–1, 1–2, 2–3, and 3–6 mm diameter). The larger aggregates did constitute a slight root impedance as roots were deflected around them. Diameters of roots grown in 3–6 mm aggregates increased significantly, whereas root lengths were not always signficantly decreased. The smaller aggregates did not impede root growth and were readily displaced by roots. Large aggregates were more of an impedance to lateral roots than to main axes.     

Root architecture remodeling induced by phosphate starvation

Plants have evolved efficient strategies for utilizing nutrients in the soil in order to survive, grow and reproduce. Inorganic phosphate (Pi) is a major macroelement source for plant growth; however, the availability and distribution of Pi are varying widely across locations. Thus, plants in many areas experience Pi deficiency. To maintain cellular Pi homeostasis, plants have developed a series of adaptive responses to facilitate external Pi acquisition, limit Pi consumption and adjust Pi recycling internally under Pi starvation conditions. This review focuses on the molecular regulators that modulate Pi starvation-induced root architectural changes.Key words: auxin, phosphate deficiency, root system architecture modulation     

Nonhost Root Penetration by Soybean Cyst Nematode

A total of 66 plants in 50 species were inoculated with eggs and juveniles of soybean cyst nematode, Heterodera glycines. Roots were stained and observed for penetration and development of the nematode. Twenty-six plants were not penetrated; twenty-three were penetrated, but there was no development of the nematode; eight were penetrated with some nematode development; two were penetrated and had considerable nematode development, but few nematodes, if any, matured; and seven were penetrated with many nematodes maturing. The penetration of nonhosts may imply some susceptibility and that populations eventually would build up on the penetrated plants. Plants not penetrated may be useful as rotation plants because no reproduction would occur.     

Root Colonization by Inoculated Plant Growth-Promoting Rhizobacteria

Certain rhizobacteria referred to as 'plant growth-promoting rhizobacteria' (PGPR) can contribute to the biological control of plant pathogens and improve plant growth. They enhance root development either directly by producing phytohormones, or indirectly by inhibiting pathogens through the synthesis of different compounds. PGPR are likely to be of great interest in sustainable crop protection and have drawn much attention in recent years. However, the use of these bacteria to protect crops sometimes fails because rhizobacteria are unable to recolonize the rhizosphere of inoculated plants. The colonization of roots by inoculated bacteria is an important step in the interaction between beneficial bacteria and the host plant. However, it is a complex phenomenon influenced by many biotic and abiotic parameters, some of which are now apparent. This paper summarises knowledge on rhizosphere colonization by PGPR.     

Cytokinin Production by Tomato Root: Occurrence of Cytokinins in Staled Medium of Root Culture

Cytokinins were released into the medium by cultures of excised tomato (Lycopersicon esculentum Mill.) root tips. A large portion was directly released from the proximal cut-end of the roots. The most active substance was found to co-chromatograph with zeatin riboside in both paper and Sephadex column chromatographies. The cytokinin activity after 7 days of growth was found about eight times higher in the medium as compared with that in the root tissues. When freshly excised root tips were subcultured throughout eight passages, the accumulation of cytokinin in the medium of each passage was approximately the same. These results show that the root tip is a main site of cytokinin synthesis.     

Root Growth Inhibition by Siduron and Its Relief by Kinetin

The growth of crabgrass (Digitaria ssp.) and barley (Hordeum vulgare) seedlings was susceptible to injury by siduron (1-2(methylcyclohexyl)-3-phenylurea). In both species, root growth was inhibited more than shoot growth and if a functional root system was developed before coming into contact with siduron the plant survived. Kinetin partially overcame the effect of siduron on root growth and increased root length and the number of cells undergoing mitosis per root tip. The effect of siduron seems specific to cell division.     

Stimulation of Root Elongation and Curvature by Calcium

Ca²⁺ has been proposed to mediate inhibition of root elongation. However, exogenous Ca²⁺ at 10 or 20 millimolar, applied directly to the root cap, significantly stimulated root elongation in pea (Pisum sativum L.) and corn (Zea mays L.) seedlings. Furthermore, Ca²⁺ at 1 to 20 millimolar, applied unilaterally to the caps of Alaska pea roots, caused root curvature away from the Ca²⁺ source, which was caused by an acceleration of elongation growth on the convex side (Ca²⁺ side) of the roots. Roots of an agravitropic pea mutant, ageotropum, responded to a greater extent. Roots of Merit and Silver Queen corn also responded to Ca²⁺ in similar ways but required a higher Ca²⁺ concentration than that of pea roots. Roots of all other cultivars tested (additional four cultivars of pea and one of corn) curved away from the unilateral Ca²⁺ source as well. The Ca²⁺-stimulated curvature was substantially enhanced by light. A Ca²⁺ ionophore, A23187, at 20 micromolar or abscisic acid at 0.1 to 100 micromolar partially substituted for the light effect and enhanced the Ca²⁺-stimulated curvature in the dark. Unilateral application of Ca²⁺ to the elongation zone of intact roots or to the cut end of detipped roots caused either no curvature or very slight curvature toward the Ca²⁺. Thus, Ca²⁺ action on root elongation differs depending on its site of application. The stimulatory action of Ca²⁺ may involve an elevation of cytoplasmic Ca²⁺ in root cap cells and may participate in root tropisms.     

Hydrogen Uptake and Exchange by Pea Root Nodules

Hydrogenase activity in pea root nodules was studied by followinggas exchanges of hydrogen and deuterium. It was found that thenodules did not evolve hydrogen but that hydrogen was takenup when it was provided in the gas mixture. When increasingpartial pressures of deuterium were supplied, hydrogen was evolvedat a rate which increased as the pressure of deuterium increased.Deuterium was taken up at the same time as this hydrogen wasevolved. Hydrogen evolution in the presence of deuterium wasinhibited by nitrogen, while the uptake of deuterium remainedunaffected. It was concluded that pea root nodules have at leasttwo separate hydrogenase system that are working in oppositedirections and must thus be situated in sites of different oxidation-reductionpotentials within the nodule.     

侧根的发生及其激素调控

本文概述了侧根发生及其植物激素调控的研究进展。侧根的发生起源于特定的中柱鞘细胞,其发生过程可简单地分为侧根发生的起始、侧根原基的形成、侧根分生组织的形成和活化等几个关键时期。参与侧根发生调控的植物激素主要是生长素,它影响到侧根发生过程的各个时期。茉莉酸对侧根的发生也有一定的调控作用。     

Suppression of Pythium Root Rot of Cucumber by a Fluorescent Pseudomonad s Related to Reduced Root Colonization by Pythium Apbanidermatum

Root colonization of cucumber with P aphanidermatum OP4 was examined in the absence and in the presence of either fluorescent pseudomonad strain CH31 or strain CHI. Quantification was performed by antigen-coated plate enzyme-linked immunosorbent assay (ACP-ELISA) using an antiserum obtained from a rabbit immunized with zoospore cysts: this antiserum did not cross-react with non-infested roots of cucumber, or with the fluorescent pseudomonads CH31 and CHI. Application of the previously developed biotest enabled us to assess the ability of the two strains of fluorescent pseudomonad to suppress root rot caused by P. aphanidermaium OP4.
At all bacterial densities tested, the fluorescent pseudomonad CH31 led to a significant reduction of both the root colonization of cucumber with P aphanidermatum OP4 and the severity of Pythium root rot. In contrast, the fluorescent pseudomonad CHI had no effect on either root colonization oe disease sevenity.     

Characterization of Orthophosphate Absorption by Pea Root Protoplasts

Root protoplasts were isolated from 4 d old seedlings of Pisumsativum. Viability was verified by fluorescin diacetate, directblue and neutral red vital staining techniques. Phosphate influx of the protoplasts was similar to that of rootswith respect to phase 1 affinity for orthophosphate /{K_m = 99mmol m^–3) and sensitivity to pH and metabolic inhibitors.Carbonyl cyanide p-trifluoromethoxyphenyl-hydrazone decreaseduptake to 4% of the control and diethyl-stilboestrol inducedleakiness in the protoplasts. Influx was only slightly lessthan that in plasmolysed roots which in turn was 3.6 times lowerthan that of normal roots. Efflux from the protoplasts was highwith a value of approximately 2% of the cellular phosphate contentper hour. The elevated leakage indicated an essential differencebetween the effects of protoplast isolation on influx and effluxof phosphate. Key words: Root protoplasts, Phosphate absorption, Influx, Efflux, Metabolic inhibitors, Diethyl-stilboestrol, Subprotoplasts