Site of Oxygen Absorption for Downward Transport in Seedlings of Rice and Other Plants

Our earlier reports have shown that appreciable portions (ranging from 20% to 70%) of the total amount of oxygen absorbed by the aerial part can be transported downwards to roots in water cultured intact seedlings of rice, barnyard grass, wheat, pea, etc. By interrupting the alternative paths of transport, it has been demonstrated that oxygen moves downwards mainly through gaseous diffusion along the intercellularspaces in the cortex. The aim of the present investigation is to ascertain the site of oxygen absorption for downward transport in the aerial part and to show that such a transport does not necessarily involve active participation of the absorbing organ. The results are summarized below: 1. Provided that a small upper portion of the leaf is left exposed in air, flooding of the aerial part of the rice seedling does not reduce the amount of total oxygen absorption to any appreciable extent (Fig. 1). In agreement with field observation, the unflooded tip is capable of furnishing the submerged part with enough oxygen to keep it alive. 2. Nor does the complete or partial removal of leaves by cutting in seedlings of rice and pea affect downward oxygen transport appreciably, provided that the stem segment or a leaf sheath is left exposed in air. 3. The following common notion has been confirmed by actual measurement: The abnormal excessive elongation of the coleoptile in rice seedling germinated under water, which may easily extend itself above the water surface, is an adaptive device to furnish the seedling with the oxygen required for root development. 4. The "floating" roots developed at the later stage in rice culture have been demonstrated to be a possible site of oxygen absorption for downward transport. 5. When a rice seedling is held up side down, with its roots exposed in air and the shoot submerged, downward oxygen transport still takes place, although to a lesser extent than in its normal position.     

Manganese Active Transport in Escherichia coli

Manganese was accumulated by cells of Escherichia coli by means of an active transport system quite independent of the magnesium transport system. When the radioisotope (54)Mn was used, manganese transport showed saturation kinetics with a K(m) of 2 x 10(-7)m and a V(max) of 1 to 4 nmoles/min per 10(12) cells at 25 C. The manganese transport system is highly specific; magnesium and calcium did not stimulate, inhibit, or compete with manganese for cellular uptake. Cobalt and iron specifically interfered with (54)Mn uptake, but only when added at concentrations 100 times higher than the K(m) for manganese. Active transport of manganese is temperature- and energy-dependent: uptake of (54)Mn was inhibited by cyanide, dinitrophenol, and m-chlorophenyl carbonylcyanide hydrazone (CCCP). Furthermore, the turnover or exit of manganese from intact cells was inhibited by energy poisons such as dinitrophenol and CCCP.     

Influence of Calcium and Magnesium on Manganese Absorption

Mutual effects between Mn, Ca, and Mg were studied during steady-state absorption experiments with excised barley roots. Calcium appeared to enhance the rate of Mn absorption; whereas, Mg had a highly depressive effect. The combination of both Ca and Mg was even more inhibitory to Mn absorption than Mg alone. Manganese had no effect on the usual negligible Ca absorption by this tissue, but effectively inhibited the absorption of Mg. Although divalent cation absorption from the Ca-Mg-Mn system was essentially nil, K absorption was greatly stimulated in the presence of these cations.These mutual effects and others reported in the literature are explained by the hypothesis that selectivity in ion absorption results from cation-induced conformational changes in the structure of the carrier molecule.     

植物对Si的吸收、运输和沉积

本文综述了植物中的S i及其吸收、运输和沉积的研究进展:(1)植物含S i量因植物种、品种甚至无性系与器官的不同而有较大差异,S i在细胞中呈现区隔化分配;(2)植物中沉积的S i主要是非晶态的S iO2.nH2O(又称硅胶、植物蛋白石、植硅石等),是有机物质矿质化的产物,不同植物所形成的S i化结构及其形态不同,可用于植物分类、鉴定及古气候与环境变化的研究;(3)硅藻和高等植物主要吸收S i(OH)4,高等植物中存在S i主动吸收机制;(4)有机大分子物质(包括多胺、碳水化合物、纤维素)作为有机衬质参与了植物的S i沉积过程;(5)突变体的鉴定和应用,对S i营养研究具有重要作用.     

Manganese Transport in Bacillus subtilis W23 During Growth and Sporulation

Manganese is accumulated in Bacillus subtilis by a highly specific active transport system. This trace element "pump" is insensitive to added magnesium or calcium and preferentially accumulates manganese in the presence of cobalt, iron, and copper. Manganese uptake in B. subtilis is inhibited by cyanide, azide, pentachlorophenol, and m-chlorophenyl carbonylcyanide hydrazone. The uptake of manganese follows Michaelis-Menten kinetics, and the net accumulation of manganese is regulated by increasing the V(max) after exposure to manganese-starvation conditions and by decreasing the V(max) for manganese uptake during growth in excess manganese. The K(m) remains constant during these regulatory changes in V(max). Manganese accumulated during growth is exchangeable for exogenous manganese and can be released from the cells by toluene (which causes leakage but not lysis) or by lysis with lysozyme. Two stages can be distinguished with regard to intracellular manganese during the process of growth and sporulation. During logarithmic growth, B. subtilis maintains a relatively constant internal manganese content, which is a function of the external manganese concentration following approximately a Langmuir adsorption isotherm. At the end of log phase, net accumulation of manganese slows. A second phase of net manganese accumulation begins at about the same time during sporulation as the accumulation of calcium begins. The manganese accumulated during growth and early sporulation is exchangeable and therefore relatively "free"; intracellular manganese is converted later during sporulation into a bound form that cannot be released by toluene or lysozyme.     

Active Transport of Manganese in Isolated Membranes of Escherichia coli

Accumulation of manganese was measured in subcellular membrane vesicles isolated from Escherichia coli. Accumulation of (54)Mn by vesicles in 0.5 m sucrose is stimulated by glucose and d-lactate and is inhibited by metabolic poisons such as dinitrophenol, m-chlorophenyl carbonylcyanide hydrazone, valinomycin, and nigericin. Manganese uptake by vesicles requires 10 mm calcium, which is not required for uptake of manganese by intact cells. The calcium requirement is specific and cannot be replaced by magnesium, sodium, or potassium. Strontium can replace calcium but is somewhat less effective than calcium. The uptake of manganese is via a manganese-specific system which shows saturation kinetics with manganese with a K(m) of 8 x 10(-6)m and a V(max) of 4 nmoles per min per g (wet weight) at 25 C. Magnesium and calcium do not compete for uptake. The accumulated manganese can be released from the vesicles by lipid active agents such as toluene, and can be exchanged for external manganese.     

Absorption and Transport of Fluorescent Brighteners by Microorganisms

The absorption of brighteners by living cells and their transport to subsequent growth is described. Brighteners are highly fluorescent, ultraviolet-absorbing compounds which appear to be essentially nontoxic, stable biological markers. They have been effectively absorbed by growing cultures of bacteria, yeasts, actinomycetes, and higher fungi, with active growth centers evidencing the greatest flourescence.     

Absorption,Transport and Metabolism of Vitamin E

Vitamin E includes eight naturally occurring fat-soluble nutrients called tocopherols and dietary intake of vitamin E activity is essential in many species. α-Tocopherol has the highest biological activity and the highest molar concentration of lipid soluble antioxidant in man. Deficiency of vitamin E may cause neurological dysfunction, myopathies and diminished erythrocyte life span. α-Tocopherol is absorbed via the lymphatic pathway and transported in association with chylomicrons. In plasma α-tocopherol is found in all lipoprotein fractions, but mostly associated with apo B-containing lipoproteins in man. In rats approximately 50% of α-tocopherol is bound to high density lipoproteins (HDL). After intestinal absorption and transport with chylomicrons α-tocopherol is mostly transferred to parenchymal cells of the liver were most of the fat-soluble vitamin is stored. Little vitamin E is stored in the non-parenchymal cells (endothelial, stellate and Kupffer cells). α-Tocopherol is secreted in association with very low density lipoprotein (VLDL) from the liver. In the rat about 90% of total body mass of α-tocopherol is recovered in the liver, skeletal muscle and adipose tissue. Most α-tocopherol is located in the mitochondrial fractions and in the endoplasmic reticulum, whereas little is found in cytosol and peroxisomes. Clinical evidence from heavy drinkers and from experimental work in rats suggests that alcohol may increase oxidation of α-tocopherol, causing reduced tissue concentrations of α-tocopherol. Increased demand for vitamin E has also been observed in premature babies and patients with malabsorption, but there is little evidence that the well balanced diet of the healthy population would be improved by supplementation with vitamin E.     

Effects of Exogenous Gibberellic Acid3 on Iron and Manganese Plaque Amounts and Iron and Manganese Uptake in Rice

Gibberellins (GA) regulate various components of plant development. Iron and Mn plaque result from oxiding and hydroxiding Fe and Mn, respectively, on the roots of aquatic plant species such as rice (Oryza sativa L.). In this study, we found that exogenous gibberellic acid₃ (GA₃) spray decreased Fe plaque, but increased Mn plaque, with applications of Kimura B nutrient solution. Similar effects from GA₃, leading to reduced Fe plaque and increased Mn plaque, were also found by scanning electron microscopy and energy dispersive X-ray spectrometric microanalysis. Reduced Fe plaque was observed after applying GA₃ to the groups containing added Fe²⁺ (17 and 42 mg•L^-1) and an increasing trend was detected in Mn plaques of the Mn²⁺ (34 and 84 mg•L^-1) added treatments. In contrast, an inhibitor of GA₃, uniconazole, reversed the effects of GA₃. The uptake of Fe or Mn in rice plants was enhanced after GA₃ application and Fe or Mn plaque production. Strong synergetic effects of GA₃ application on Fe plaque production were detected. However, no synergetic effects on Mn plaque production were detected.     

OsNRAMP3 Is a Vascular Bundles-Specific Manganese Transporter That Is Responsible for Manganese Distribution in Rice

Manganese (Mn) is an essential trace element for plants. Recently, the genes responsible for uptake of Mn in plants were identified in Arabidopsis and rice. However, the mechanism of Mn distribution in plants has not been clarified. In the present study we identified a natural resistance-associated macrophage protein (NRAMP) family gene in rice, OsNRAMP3, involved in Mn distribution. OsNRAMP3 encodes a plasma membrane-localized protein and was specifically expressed in vascular bundles, especially in phloem cells. Yeast complementation assay showed that OsNRAMP3 is a functional Mn-influx transporter. When OsNRAMP3 was absent, rice plants showed high sensitivity to Mn deficiency. Serious necrosis appeared on young leaves and root tips of the OsNRAMP3 knockout line cultivated under low Mn conditions, and high Mn supplies could rescue this phenotype. However, the necrotic young leaves of the knockout line possessed similar levels of Mn to the wild type, suggesting that the necrotic appearance was caused by disturbed distribution of Mn but not a general Mn shortage. Additionally, compared with wild type, leaf Mn content in osnramp3 plants was mostly in older leaves. We conclude that OsNRAMP3 is a vascular bundle-localized Mn-influx transporter involved in Mn distribution and contributes to remobilization of Mn from old to young leaves.     

Cytoskeletal Drugs and Gravity-Induced Lateral Auxin Transport in Rice Coleoptiles

Abstract: Gravity-induced events such as amyloplast sedimentation and lateral auxin transport were probed with cytoskeletal drugs in coleoptiles of rice ( Oryza sativa L.). Amyloplast sedimentation was retarded by taxol. Lateral transport of auxin (³H-indoleacetic acid) was strongly inhibited by EPC (ethyl N-phenylcarbamate), but only partially inhibited by taxol. 1 mM EPC reduced gravitropism while phototropism was not affected. The findings suggest that microtubules may transduce pressure or proximity of amyloplasts to the auxin exporter in the plasmalemma.     

Foliar Manganese Supply Enhances Crop Productivity,Net Benefits,and Grain Manganese Accumulation in Direct-Seeded and Puddled Transplanted Rice

Journal of Plant Growth Regulation - Manganese (Mn) deficiency in human nutrition is widespread in the rice–wheat cropping system where cereal grains are the staple food. Agronomic...     

Imaging Carrier Dynamics and Transport in Hybrid Perovskites with Transient Absorption Microscopy

In this review, the recent progress in using transient absorption microscopy to image charge transport and dynamics in semiconducting hybrid organic–inorganic perovskites is discussed. The basic principles, instrumentation, and resolution of transient absorption microscopy are outlined. With temporal resolution as high as 10 fs, sub‐diffraction‐limit spatial resolution, and excited‐state structural resolution, these experiments have provided crucial details on charge transport mechanisms that have been previously obscured in conventional ultrafast spectroscopy measurements. Morphology‐dependent mapping unveils spatial heterogeneity in carrier recombination and cooling dynamics. By spatially separating the pump and probe beams, carrier transport across grain boundaries has been directly visualized. Further, femtosecond temporal resolution allows for the examination of nonequilibrium transport directly, revealing extraordinarily long‐range hot carrier migration. The application of transient absorption microscopy is not limited to hybrid perovskites but can also be useful for other polycrystalline materials in which morphology plays an important role in carrier transport.     

Selective Inhibition of Absorption and Long Distance Transport in Relation to the Dual Mechanisms of Ion Absorption in Maize Seedlings

The influence of several uncouplers of oxidative phosphorylation and inhibitors of terminal electron transport was studied on absorption and long distance transport of both K and C1 at concentrations within each range of the dual isotherm typical of ion uptake by maize roots. At low concentrations in the range of system 1, the system considered to implement ion movement through the plasma membrane, root absorption and long distance transport are equally inhibited by a given inhibitor. In the high range of system 2, the system considered to mediate ion passage through the tonoplast, long distance transport is markedly less sensitive to inhibitors than is absorption. The observations are in accord with the hypothesis that only system 1 is involved in the uptake of ions from the external solution into the symplast, and hence into the xylem. At high concentrations, entrance into the symplasm is deemed to be largely by diffusion and therefore less inhibitor sensitive.With respect to absorption by the roots, the plasma membrane system is more inhibitor sensitive than is the tonoplast system. It is suggested that the difference in sensitivity is real, and not the consequence of an inequality of inhibitor concentration in the vicinity of the plasma membrane and tonoplast respectively.     

Tracing Cadmium from Culture to Spikelet: Noninvasive Imaging and Quantitative Characterization of Absorption,Transport, and Accumulation of Cadmium in an Intact Rice Plant

We characterized the absorption and short-term translocation of cadmium (Cd) in rice (Oryza sativa ‘Nipponbare’) quantitatively using serial images observed with a positron-emitting tracer imaging system. We fed a positron-emitting ¹⁰⁷Cd (half-life of 6.5 h) tracer to the hydroponic culture solution and noninvasively obtained serial images of Cd distribution in intact rice plants at the vegetative stage and at the grain-filling stage every 4 min for 36 h. The rates of absorption of Cd by the root were proportional to Cd concentrations in the culture solution within the tested range of 0.05 to 100 nm. It was estimated that the radial transport from the culture to the xylem in the root tissue was completed in less than 10 min. Cd moved up through the shoot organs with velocities of a few centimeters per hour at both stages, which was obviously slower than the bulk flow in the xylem. Finally, Cd arrived at the panicles 7 h after feeding and accumulated there constantly, although no Cd was observed in the leaf blades within the initial 36 h. The nodes exhibited the most intensive Cd accumulation in the shoot at both stages, and Cd transport from the basal nodes to crown root tips was observed at the vegetative stage. We conclude that the nodes are the central organ where xylem-to-phloem transfer takes place and play a pivotal role in the half-day travel of Cd from the soil to the grains at the grain-filling stage.Contamination of arable soil with cadmium (Cd) is one of the most serious agricultural problems in the world. Crops, particularly irrigated rice (Oryza sativa), are generally suggested as the main source of Cd intake by humans (United Nations Environment Programme, 2008). From the viewpoint of plant nutrition, the dynamics and mechanisms of Cd transition from the soil to the edible parts in the plants should be elucidated.Generally, the process of metal accumulation in plants mainly consists of uptake from the soil by the roots, xylem loading and transport, and distribution between metal sinks in the aerial parts (Clemens et al., 2002). It has been demonstrated that xylem loading and transport but not absorption by the roots is one of the rate-controlling steps for Cd accumulation in the grain of graminaceous plants. Hart et al. (1998) reported that greater Cd accumulation in durum wheat grain than in bread wheat grain was not correlated with the root influx rates of these cultivars. Harris and Taylor (2004) employed two near-isogenic lines of durum wheat that differ in grain Cd accumulation and showed that elevated activity of root-to-shoot transport of Cd was responsible for the higher accumulation of Cd in grain, but Cd uptake by roots was not. Uraguchi et al. (2009) analyzed two rice cultivars that show different levels of Cd accumulation in the grain and concluded that root-to-shoot Cd translocation via xylem is the major process determining the Cd accumulation level in rice grain. Phloem transport has also been considered a key step of Cd translocation to the grain, because xylem transport is directed mainly to the organs of highest transpiration, such as leaves, but not to the sites of highest demand for mineral, such as grains (Marschner, 1995). Cd was detected in the phloem sap of rice collected from leaf sheaths (Tanaka et al., 2003) and from the uppermost internode at the grain-filling stage (Tanaka et al., 2007). Tanaka et al. (2007) also estimated that 91% to 100% of Cd in rice grains is deposited from the phloem. In wheat, it has been observed in a split-root system that Cd fed to one bundle of the roots moved into the other bundle, probably via the phloem (Welch et al., 1999; Page and Feller, 2005), and steam girdling, which stops only phloem transport but not xylem flow, to the peduncle below the ear reduced Cd translocation to the grain (Riesen and Feller, 2005). These results suggest that the xylem loading and transport is the first rate-controlling step of Cd transition from the soil to the grain in graminaceous plants and the phloem transport and unloading into the grain is the last. However, the intermediate steps between the xylem and phloem transport of Cd have not been clarified. In general, it is known that mineral micronutrients are remobilized from senescent leaves to the phloem at the reproductive stage or transferred from the xylem to the phloem directly via transfer cells (Marschner, 1995; Clemens et al., 2002). Therefore, where and how the xylem-to-phloem transfer of Cd occurs is of considerable interest. The main objective of this study was to quantitatively describe the whole route and the time scale of Cd transition from the soil to the grain in rice at the vegetative and reproductive stages.In this study, we also raised a methodological challenge. We employed a positron-emitting tracer imaging system (PETIS), one of the most advanced radiotracer-based imaging methods available today. PETIS provides serial time-course images (i.e. animation) of the two-dimensional distribution of a radiotracer within a living organism without contact. Its principle is the same as that of positron emission tomography, which has been widely used for medical diagnosis, but PETIS was specially designed for studying plants and has been applied to many studies on plant nutrition over the last decade (Uchida et al., 2003; Fujimaki, 2007; Fujimaki et al., 2010). Recently, the transport of metals, including iron (Ishimaru et al., 2006, 2007; Tsukamoto et al., 2009), zinc (Suzuki et al., 2006), and manganese (Tsukamoto et al., 2006), in intact graminaceous plants has been visualized using PETIS. Furthermore, the time course of tracer amounts within any selected region of interest (ROI) on the obtained image can be easily generated and applied for mathematical analyses because PETIS provides highly quantitative images. The rates of photoassimilation and the velocities of phloem transport in intact plants under various environmental conditions have been estimated quantitatively using PETIS (Matsuhashi et al., 2005; Kawachi et al., 2006). However, to our knowledge, no study has been carried out to describe the whole dynamics and kinetics of a substance in an intact plant body by taking full advantage of PETIS, namely noninvasive visualization and quantitative time-course analysis. The second objective of this study was to demonstrate the potential of the latest radiotracer imaging technology for plant physiology.     

Phosphate Absorption, Fluxes, and Symplasmic Transport in Osmotically-Shocked Zea mays Roots

Osmotic shock with sequential 30 min treatments in ice-coldsaline solutions and distilled water inhibited both the subsequentuptake of orthophosphate (Pi) and its transport into the xylemof excised corn (Zea mays L.) roots. Measurements of Pi fluxeswith ³²P indicated that the decrease in net Pi uptake over a24 h period caused by osmotic shock was due primarily to delayedrecovery of Pi influx rather than to increasing efflux. Despitecomplete recovery of Pi absorption within 2–6 h aftershocking with 150–200 mM NaCl, transport to the xylemduring the subsequent 24 h only partially recovered. Leucineuptake and incorporation into protein was also markedly inhibitedby osmotic shock but both almost completely resumed controlrates within 24 h after shocking with up to 150 mM NaCl. Tetracyclineinhibited recovery of Pi uptake after NaCl treatment whereaspuromycin did not. These results with corn roots are consistentwith the hypothesis that recovery of Pi uptake activity aftermoderate osmotic shock requires de novo synthesis of membraneproteins. Incomplete recovery of Pi transport to the xylem suggeststhat osmotic shock may damage plasmodesmata. Key words: Corn, Ion uptake, Leucine uptake, NaCl, Puromycin, Tetracycline     

丛枝菌根养分吸收和转运机制的研究历史与进展

丛枝菌根真菌(AMF)在土壤生态系统中分布最广且在农业生态系统中作用最大,是颇受研究人员关注的一类菌根真菌。多年来,人们尝试着用各种技术和方法从不同角度、不同层次对AMF与植物的互惠机制进行研究并取得了较大进展。近年来分子技术在该领域得以广泛应用,使得人们对这一共生体的互惠机制有了更为详尽的了解。从营养学角度入手,综述了国内外关于丛枝菌根(AM)真菌对土壤中养分吸收和转运机制的研究进展,并在概括当前AMF促生机制研究热点的基础上对其发展前景作了展望。