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1.
To deteimine if direct Ca sprays could affect the distribution and binding of Ca in the leaves and the severity of leaf/bract distortion in two varieties of poinsettia (Euphorbia pulcherimma Willd.), we applied either 100 mg.l‐1 or 400 mg.l‐1 of Ca either one time or weekly to leaves of distortion‐ susceptible ('V‐14 Glory') and nonsusceptible ('Annette Hegg Dark Red,’ AHDR) cultivars. Only weekly spraying with 400 mg.l‐1 Ca reduced distortion in V‐14 plants, compared to controls or AHDR plants. Both bound and unbound Ca concentrations were higher in AHDR leaves than in V‐14 leaves, but these differences were not correlated with distortion severity. EDX analysis demonstrated that distorted regions of V‐14 leaves and bracts had lower Ca concentrations than did undistorted regions or AHDR leaves; weekly spraying with 400 mg.r1 Ca produced relatively uniform leaf Ca distribution in V‐14 leaves. Localized Ca deficiencies appear to produce the bract/leaf distortion in ‘V‐14 Glory plants, and these deficiencies can be partially overcome by weekly Ca spray applications. 相似文献
2.
Single‐pinched poinsettia (Euphorbia pulcherrima ’V‐14 Glory') in 15‐cm pots received constant fertigation with 50, 100, 200, and 300 mg.L‐1 nitrogen (N) from a 20N‐4.4 phosphorus (P)‐16.6 potassium (K) fertilizer with a leaching fraction (LF) of 0, 0.2, or 0.4. Plants received 25 irrigations during the 13‐week study. The shoot fresh and dry masses with 50, 100, and 300 mg.L‐1 N at the 0.4 LF were 30% larger than at the 0 LF. The 300 mg.L‐1 N fertigated plants had approximately 15% more leaf area and almost 122% more bract area than the 50 mg.L‐1 N fertigated plants. The leaf N concentration of plants fertigated with 100, 200, and 300 mg.L‐1 N was near or in the normal range of 4 to 6%, but was below the critical level of 3.5% with 50 mg.L‐1 N fertigation. In contrast, the leaf P concentration approached or exceeded the toxic level of 0.9% with 100 to 300 mg.L‐1 N. The N fertigation of 100 to 200 mg.L‐1 is adequate for producing a quality poinsettia crop. Quality poinsettias can be grown at a 0 LF if quality irrigation water is available. With 11 mg.L‐1 P via fertigation, the leaf P concentration was in the acceptable range. The P concentration in the 20N‐4.4P‐16.6K complete fertilizer was excessive for poinsettia and would contribute to unnecessary P leaching. 相似文献
3.
《Communications in Soil Science and Plant Analysis》2012,43(11):1253-1267
Abstract Macadamia (Macadamia integrifolia) is increasingly becoming an important tree crop in many parts of the world. However, knowledge about the plant's nutritional behavior, especially under adverse soil conditions, has been deficient. To address this deficiency, a pot experiment was conducted to study the effects of Al, Mn and Ca (soil acidity and liming) on macadamia seedlings. Three soils having different mineralogy and fertility were used; soil pH was adjusted based on lime requirement curves so that several pH levels ranging from 4.5 to 7.5 were obtained for each soil. Chemical composition of the soil solution and of recently fully mature leaves was monitored periodically to assess the growth response. Results suggested that Al was detrimental to physiological processes of macadamia seedlings when leaf Al was greater than 275 mg kg and soil‐solution Al exceeded 1.2 mg L‐1. Furthermore, Al seemed to have reduced Mn uptake by the plant, although macadamia could accumulate as much as 1200 mg Mn kg‐1 in leaves without apparent toxic symptoms. The internal Ca requirement of the plant was not clearly defined; however, maximum growth could be expected when soil solutions contained 160 mg Ca L‐1 , which corresponded to 0.9 cmol(+)kg‐1 of exchangeable Ca (or 10% of CEC) in a highly weathered Oxisol. 相似文献
4.
The quality of irrigation water used for greenhouse crop production can strongly influence plant growth. However, the effect on plant growth is probably a combination of water quality and the type of growing media used. To determine the effect of saline and alkaline irrigation water on plant growth and nutrition, pansy and impatiens were grown in peat, peat:pine bark, and pine bark media under standard greenhouse conditions. Salinity treatments of 0, 100 and OmgL‐1 NaCl: CaCl2 and alkalinity treatments of 0, 100, 200, 300, and 400 mg L‐1 NaHCO3 were applied at every irrigation. Salinity levels at 100 mg L‐1 and greater caused necrosis of leaf edges, upward curling of leaves, and reduced flower number for pansy. Treatment symptoms for impatiens were reduced growth, general chlorosis, and reduced flower number. These treatment symptoms increased in severity for plants grown in pine bark. Alkalinity levels at 200 mg L‐1 and greater caused decreased flower number, necrosis of leaf edges, and downward cupping of leaves of pansy. Treatments symptoms of impatiens were general chlorosis, water‐soaked appearance of leaves and leaf abscission. Elemental concentrations of sodium (Na+), chloride (Cl), calcium (Ca++), magnesium (Mg++), and potassium (K+) varied in media solution and tissue with symptom and treatment. 相似文献
5.
This study was conducted to evaluate the responses of potatoes to six K solution concentrations maintained with a flow‐through nutrient film system. Potato plants were grown for 42 days in sloping shallow trays containing a 1 cm layer of quartz gravel with a continuous flow of 4 ml min‐1 of nutrient solutions having K concentrations of 0.10, 0.55, 1.59, 3.16, 6.44, 9.77 meq L‐1. Plant leaf area, total and tuber dry weights were reduced over 25% at 0.10 meq L‐1 of K and over 17% at 9.77 meq L‐l of K compared to concentrations of 0.55, 1.59, 3.16 and 6.44 meq L‐1 of K. Gas exchange measurements on leaflets in situ after 39 days of growth demonstrated no significant differences among different K treatments in CO2 assimilation rate, stomatal conductance, intercellular CO2 concentration, and transpiration. Further measurements made only on plants grown at 0.10, 1.59, 6.44 meq L‐1 of K showed similar responses of CO2 assimilation rate to different intercellular CO2 concentrations. This suggested that the photosynthetic systems were not affected by different K nutrition. The leaves of plants accumulated about 60% less K at 0.10 meq L‐1 of K than at higher K concentrations. However, Ca and Mg levels in the leaves were higher at 0.10 meq L‐1 of K than at higher K concentrations. This indicates that low K nutrition not only reduced plant growth, but also affected nutrient balance between major cations. 相似文献
6.
Mineral element deficiencies and toxicities are common problems associated with sorghum [Sorghum bicolor (L.) Moench] production on acid soils. To better understand some of the mineral element problems and the analysis of plant tissue of sorghum plants grown on acid soils, four sorghum genotypes were grown on an acid Oxisol at Carimagua, Colombia limed with dolomite at 2 and 6 Mg ha‐1. Samples for mineral element analyses were obtained from leaves at different positions on the four genotypes. Concentrations of P and Mg were highest in the flag leaf (Leaf No. 1) and decreased as the position on the plant declined from the top of the plant for plants grown at 2 Mg lime ha‐1. Similar decreases in P, Mg, K, and Zn concentrations occurred in plants grown with 6 Mg lime ha‐1. Concentrations of Ca, S, Si, Mn, Fe, Cu, and Al increased as leaf position declined from the flag leaf for plants grown at 2 and 6 Mg lime ha‐1. The higher lime supply enhanced Ca and reduced Mn and Fe concentrations in leaves. Differences in mineral element concentrations for the four genotypes used were fairly extensive. The elements to show the greatest range among genotypes were Al and Si and the elements to show the least range among genotypes were P, K, and S. Care should be used in collecting leaf samples for plant analysis and genotypic differences for accumulation of mineral elements should be considered in interpretation of results. 相似文献
7.
Antonio L. Alarcón Ramón Madrid Félix Romojaro Eulogio Molina 《Journal of plant nutrition》2013,36(9):1897-1912
The time course trend of the various calcium (Ca) forms (soluble, bound, inorganic insoluble, and organic insoluble) was studied throughout the growing period in mature and young leaves of Cucumis melo L. cv. Revigal plants cultivated on rockwool under unfavorable conditions for Ca uptake. The following anions accompanying Ca were tested: NO3 ‐ as control, as well as EDTA2‐, Cl‐ and SO4 2‐ with two concentration levels equivalent to half and a quarter part of the Ca level of the control. The differences between mature and young leaves were very marked for all the forms. Generally, the inorganic insoluble Ca form was predominant in mature leaves, while the bound form showed the lowest levels. In young leaves, on the other hand, soluble Ca was usually the major form, whereas organic insoluble Ca was the least plentiful. The treatments with Ca‐EDTA (Ch‐#fr1/2> and Ch‐#fr1/4>) resulted in lower leaf Ca concentration than the other treatments. The ratios referring to the Ca contents of mature leaves/young leaves for the six Ca‐deficiency treatments varied from 5.0 to 18.5 (soluble Ca), 3.8 to 11.0 (bound Ca), 9.0 to 41.7 (inorganic insoluble Ca), and 9.0 to 47.7 (organic insoluble Ca). For the control, these ratios were 2.3 (soluble Ca), 1.6 (bound Ca), 22.3 (inorganic insoluble Ca), and 61.5 (organic insoluble Ca). The insoluble forms always showed higher ratios. For all treatments and sampling dates the total Ca level was approximately ten times higher in mature leaves than in young leaves and always in the following order: NO‐>Cl‐‐#fr1/2> ~ SO42‐#fr1/2>> Cl‐‐#fr1/4> ~ SO4 2‐‐#fr1/4>> Ch‐#fr1/2>>Ch‐#fr1/4>, which was the same order observed in the response as reflected by fruit and vegetative biomass production. 相似文献
8.
Y. Kohno 《Journal of plant nutrition》2013,36(10):1261-1272
Seedlings of two bush bean cultivars (Phaseolus vulqaris L. cvs. Mn‐sensitive ‘Wonder Crop 2’ and Mn‐tolerant ‘Green Lord') were grown for 14 days in full strength Hoagland No. 2 nutrient solution containing 0.05 ‐ 2 mg L‐1 of vanadium (V) as ammonium vanadate.
Increasing V concentration in the solution decreased total dry weight of both cultivars. Plant tops were stunted and leaf color became dark green at 1 ‐ 2 mg L‐1 V, especially in ‘Green Lord’. Veinal necrosis similar to that of Mn toxicity was observed in the primary leaves of ‘Wonder Crop 2’ at 0.2 mg L‐1 V or above, but not in those of ‘Green Lord’.
The V concentrations in the roots increased exponentially with increasing V concentration in the solution; however, V concentrations in the leaves and stems were not affected. The Mn concentrations in the primary leaves increased under the higher V treatment in ‘Wonder Crop 2'; but not in ‘Green Lord’. In contrast, Fe concentration in the leaves of ‘Wonder Crop 2’ decreased markedly with increasing V concentration in the solution. Enhanced Mn uptake and greater reduction of Fe uptake by ‘Wonder Crop 2’ may explain the incidence of V‐induced Mn toxicity. 相似文献
9.
Sulfur (S)‐diagnostic tools are essential for rational use of S fertilizers. There is little information about the suitability of leaf greenness intensity to detect S deficiency in corn (Zea mays L.). This work evaluates, under controlled S‐stressed conditions, (1) the performance of leaf greenness intensity as an indicator of the degree of S deficiency in corn, and (2) the advantage of the upper leaves in relation to the middle leaves for S‐deficiency determination. A pot experiment using sand as growth medium was conducted in greenhouse with corn at S rates of 0, 5, 10, 20, and 40 mg kg–1 and sufficiency of other nutrients. Measurements of aboveground biomass (AB), total nitrogen (N), and S concentrations, and chlorophyll‐meter readings (CMR) in upper and middle leaves, were performed at the growth stages of 6–7, 11–12, and 14–15 fully expanded leaves (V6‐V7, V11‐V12, and V14‐V15, respectively). Sulfur application significantly increased AB, leaf S concentration, and CMR. Significantly positive relationships were obtained between leaf S concentration and CMR. A sulfur‐sufficiency index (SSI) based on CMR measured in upper and middle leaves was significantly associated with AB (R2 = 0.58 and 0.62 for the middle and upper leaves, respectively). It is concluded that under sufficiency of other nutrients and high‐S‐stressed conditions, leaf greenness intensity could be a good indicator of corn S status, although little or no advantage was found for taking CMR from the upper leaves. 相似文献
10.
《Communications in Soil Science and Plant Analysis》2012,43(6):681-693
Abstract Strawberry plants cv. Cambridge Favourite were grown in pots of soil in a glasshouse. A relationship was found between the function aCa: SaCations(soil solution) x guttation score, the severity of leaf tipburn and the calcium concentration in the emerging leaf. Slightly less well related but of more practical use was the function cCa: ScCations/electrical conductivity of the soil solution; values below 0.15 mS‐1 resulted in increased tipburn and reduced calcium concentrations in emerging leaves and in the fruit. 相似文献
11.
In 2006–2007 small radish was cultivated in a pot experiment. Foliar applications were applied twice with solutions of the following compounds: 1) control (water); 2) urea; 3) urea+molybdenum (Mo), 4) urea+Mo+benzyladenine (BA); 5) urea+Mo+BA+sucrose; 6) urea+Mo+BA+sucrose+salicylic acid (SA), 7) BA; 8) SA; and 9) sucrose. The above solutions contained following concentrations of compounds: urea 20 g dm?3, sucrose 10 g dm?3, Mo 1 mg dm?3, BA 5 mg dm?3 and SA 10 mg dm?3. In comparison with the control, spraying plants with the solution of urea+Mo+BA+sucrose and SA only caused an increase in leaf mass of one plant. Foliar applications did not have any effect on the yield of edible roots. When compared with the control, the use of sucrose resulted in a decreased content of nitrate (V) in leaves, while the application of urea+Mo+BA+sucrose led to elevated content of nitrate (V) in roots. In case of spraying plants with solutions containing urea (combinations no. 2–6) there was a tendency to increase ammonium (NH4 +) and nitrogen (N)-total content in leaves and roots, and increase in N uptake by leaves and by the whole plant but not by the radish roots. In combinations 7–9 we noted a decline in the level of ascorbic acid, and in combinations 2–6 there was a decrease in the content of soluble sugars in roots. In comparison with the control, an increase was observed in combinations 2 and 3, while in combinations 7–9 a decrease in the content of free amino acids in roots was observed. None of the combinations with foliar application caused any significant changes in the content of assimilative pigments in radish leaves and concentration of nitrate (III), dry matter in leaves and roots, the content of phenolic compounds, content of potassium (K), magnesium (Mg), calcium (Ca) extracted with 2% acetic acid in roots as well as free radical activity of radish roots. 相似文献
12.
Toshihiro Watanabe Mitsuru Osaki Toshiaki Tadano 《Soil Science and Plant Nutrition》2013,59(4):827-837
Effects of Al, Ca, Mg, and Si on the growth and mineral accumulation of M. malabathricum (Melastoma malabathricum L.), which is an Al accumulator plant, were investigated using the water culture method. Rice (Oryza sativa L.) and barley (Hordeum vulgare L.) were used as control plants. After Al application, growth was inhibited in barley, but stimulated in M. malabathricum and rice. The growth of M. malabathricum was not reduced by very low Ca and Mg concentrations (0.1 mm Ca and 0.05 mm Mg). However, it was depressed in the absence of Ca. Ca and Mg contents somewhat decreased by Al application, which was most evident in young leaves and roots. M. malabathricum accumulated more than 10,000 mg kg-1 Al in mature leaves, and more than 7,000 mg kg-1 even in the youngest leaf. Al content in leaves of M. malabathricum did not decrease by the Ca or Mg application, but slightly decreased by in the absence of Ca. Although Si is a strong ligand of Al in solution, in M. malabathricum, Si application hardly affected the growth, Al accumulation and nutrient uptake. 相似文献
13.
《Communications in Soil Science and Plant Analysis》2012,43(13-14):2309-2318
Abstract Calcium (Ca) uptake was studied by immersing the central tip of a trifoliate leaf in various concentrations of 45CaCl2 solutions and under moisture stress conditions during the seed‐filling period of soybean. Beta‐ray gauging and the diurnal leaf temperature variation showed similar characteristics for leaf water status. The activities of 45Ca were significantly higher (p < 0.0001) at 5, 10, 20, and 30 mM concentrations for water stressed and non‐stressed leaves compared with the control. Calcium (45Ca) activities at 5, 10, and 20 mM Ca concentrations between stressed and non‐stressed leaves were not significant, but the difference in their mean values at 30 mM Ca concentration was significant (p = 0.0159). The relationship between 45Ca uptake and Ca concentration was parabolic for both stressed (R2 = 0.77) and non‐stressed (R2 = 0.81) leaves. Autoradiographs indicated Ca movement through the mid‐rib and veins of the tip‐immersed trifoliate leaf but showed no activity in other plant parts. An activity gradient developed between seeds when a pod‐tip was immersed in the radioactive solution. 相似文献
14.
Calcium (Ca2+) amelioration of the plant's growth response to salinity depends on genetic factors. In this work, supplemental Ca2+ did not improve growth in Phaseolus vulgaris L. cv. Contender under high‐saline conditions and negatively affected several physiological parameters in nonsalinized plants. The response to supplemental Ca2+ was examined using plants grown in 25% modified Hoagland solution at different Na+ : Ca2+ ratios. In control plants (1 mM Ca2+; 1 mM Na+) surplus Ca2+ (4 or 10 mM) was associated with stomatal closure, decrease of hydraulic conductivity, sap flow, leaf specific dry weight, leaf K+ and leaf Mg2+ concentrations, and inhibition of CO2 assimilation. Leaf water content was enhanced, while water‐use efficiency and dry matter were unaffected during the 15 d experimental period. The Ca2+ effect was not cation‐specific since similar results were found in plants supplied with high external Mg2+ or with a combination of Ca2+ and Mg2+. Relative to control plants, salinization (50 and 100 mM NaCl) caused a decrease in dry matter, hydraulic conductivity, sap flow, leaf Mg2+ activity, and inhibition of stomatal opening and CO2 assimilation. However, NaCl (50 and 100 mM NaCl) enhanced leaf K+ concentration and water‐use efficiency. At 100 mM NaCl, leaf water content also significantly increased. Supplemental Ca2+ had no amelioration effect on the salt‐stress response of this bean cultivar. In contrast, the 50 mM–NaCl treatment improved stomatal conductance and CO2‐assimilation rate in plants exposed to the highest Ca2+ concentration (10 mM). Phaseolus vulgaris is classified as a very NaCl‐sensitive species. The similarities in the effects caused by supplemental Ca2+, supplemental Mg2+, and NaCl salinity suggest that P. vulgaris cv. Contender has a high non‐ion‐specific salt sensitivity. On the other hand, the improvement in gas‐exchange parameters in Ca2+‐supplemented plants by high NaCl could be the result of specific Na+‐triggered responses, such as an increase in the concentration of K+ in the leaves. 相似文献
15.
Some poinsettia (Euphorbia pulcherrima Willd. ex Klotzsch) cultivars are susceptible to bract calcium (Ca) deficiency in developing bracts. In this study, we evaluated the efficacy of foliar uptake of Ca from milk-based products plus calcium chloride (CaCl2) as a potential Ca source. Weekly foliar applications of 237 mL L?1 whole milk, 80 mL L?1 powdered milk, 30 mL L?1 condensed milk, 0.94 g L?1 CaCl2, or distilled water (used as a control) were applied to runoff of ‘Prestige Red’ for four weeks. The four largest bracts with petioles on three different inflorescences and three leaves with petioles below the transitional leaf per inflorescence were collected per pot. None of the treatments affected bract or leaf Ca concentration. Powdered milk treatments resulted in a higher concentration of zinc (Zn) in bracts and aluminum (Al) in bracts and leaves. White residue remained on the bracts and leaves after treatment with powdered milk, which would reduce marketability. 相似文献
16.
Experiments were conducted with sunflower (Helianthus annuus, L.) of two inbred lines and eight cultivars grown in the field, in pots in the greenhouse or growth chamber and in nutrient solution. Water solutions of 2,3,5‐triiodobenzoic (TIBA) were sprayed over the top of the plants or added to the nutrient solution TIBA treatment resulted in induction of bract necrosis in some plants, increasing the bract necrosis index with higher TIBA concentration. TIBA had little effect on element concentration in leaves but it decreased the levels of Ca, Mg and B in bracts of plants. At a low TIBA concentration (25 μM) in the nutrient solution, young plants growing in hydroponic solution at a low Ca level, the levels of Ca and Mg of young leaves were decreased but TIBA treatment did not affect significantly the levels of these elements in roots. Since TIBA produces both bract necrosis and lower Ca content in bracts, it is suggested that bract necrosis is a physiological disorder related with lower Ca levels existing in the bracts when plants are grown under stress conditions. 相似文献
17.
Juliane Lilienfein Wolfgang Wilcke Lourival Vilela Samuel do Carmo Lima Richard Thomas Wolfgang Zech 《植物养料与土壤学杂志》2000,163(4):411-419
No‐tillage (NT) cropping systems are becoming increasingly important in the Brazilian savanna. To evaluate their sustainability we compared soil chemical properties in 1‐ to 3‐year‐old NT systems following 9 to 11 years of conventional tillage (CT) with systems where CT was continuously in place for 12 years. In the rainy season 1997/98, NT was cropped with soybean and CT with corn while in the rainy season 1998/99 both systems were cropped with soybean. Soil solid phase samples were taken from the 0—0.15, 0.15—0.3, 0.3—0.8, 0.8—1.2, and 1.2—2 m layers on three spatially separated plots under each of NT and CT. Soil solution samples were collected weekly at 0.15, 0.3, 0.8, 1.2, and 2 m soil depth during two rainy seasons (14 October to 28 April 1997/98 and 1998/99). We determined soil moisture contents, pH, the concentrations of exchangeable cations, the electrical conductivity (EC) of the soil solution, and the concentrations of Al, C, Ca, Cl—, K, Mg, Mn, Na, NH4+, NO3—, P, S, and Zn in solid soil and soil solution samples. Differences in soil solid phase properties and moisture content between NT and CT were small, few were significant. Under NT, the average solution pH was significantly lower (5.5), Al (26 μg l—1), Mn (17 μg l—1) and total organic C concentrations (TOC, 6.5 mg l—1) were higher than under CT (pH: 6.0, Al: 14μg l −1, Mn: 14μg l −1, TOC: 5.5 mg l −1). Irrespective of the different crops in the first rainy season, under NT, the EC (205 μS cm—1), Ca (17 mg l—1), and Mg (2.9 mg l—1) concentrations at 0—0.3 m depth were lower than under CT (EC: 224 μS cm—1, Ca: 25 mg l—1, Mg: 5.6 mg l—1). At 1.2—2 m depth, the reverse order was observed (EC: 124 μS cm—1 under NT and 84 μS cm—1 under CT, Ca: 11 mg l—1 under NT and 7.5 mg l—1 under CT, Mg: 3.1 mg l—1 under NT and 1.8 mg l—1 under CT). Our results indicate that enhanced soil acidification because of higher rates of organic matter mineralization and a more pronounced nutrient leaching because of increased pore continuity may limit the sustainability of NT. 相似文献
18.
Charles D. Foy Julio C. de Paula Jose A. Centeno Emilia Ivanova Jücker 《Journal of plant nutrition》2013,36(4-5):769-782
Plant genotypes within species differ widely in tolerance to excess manganese (Mn) that may occur in acid soils, or in neutral or alkaline soils having poor aeration caused by imperfect drainage or compaction. However, Mn tolerance mechanisms in plants are largely unknown. Silicon (Si) is reported to detoxify Mn within plants, presumably by preventing localized accumulations of Mn associated with lesions on leaves. Because Mn is paramagnetic, electron paramagnetic resonance (EPR) spectroscopy, shows promise as a tool for characterizing toxic and non‐toxic forms of Mn in tolerant and sensitive plants. The objective of our study was to use EPR to: i) determine the chemical/ physical state of Mn in Mn‐tolerant and ‐sensitive snapbean cultivars; and ii) characterize the protective effects of Si against Mn toxicity. Manganese‐sensitive Wonder Crop 2 (WC) and Mn‐tolerant Green Lord (GL) cultivars of snapbean were grown at pH 5.0, in a greenhouse, in a modified Steinberg solution containing: Mn=0.05mg.L‐1 (optimal); Mn=1.0mgL‐1 (toxic); Mn=1.0 mg L‐1 plus Si=4 mg L‐1; and Mn=0.05 mg L‐1 plus 4 mg Si L‐1. All trifoliate leaf samples exhibited a 6‐line EPR signal that is characteristic of hexaaquo Mn2+. In both cultivars, a higher EPR Mn2+ signal‐intensity generally correlated with lower total leaf mass, higher total Mn concentrations and more pronounced symptoms of toxicity. Tolerance to excess Mn coincided with lower Mn2+ signal intensity. Silicon treatments ameliorated Mn toxicity symptoms in both genotypes, decreased total leaf Mn concentrations, and decreased EPR Mn2+ signal intensity. Results suggest that Mn toxicity is associated with reduced electron transport and accumulation of oxidation products in leaves. Amelioration of Mn toxicity by Si is regarded as connected with a reduction in this Mn‐induced process. Results indicated that EPR spectroscopy can be useful in investigating the biochemical basis for differential Mn tolerance in plants. The EPR observations might also help plant breeders in developing Mn‐tolerant cultivars. 相似文献
19.
Marta Simone Mendonça Freitas Pedro Henrique Monnerat Ivo José Curcino Vieira 《Journal of plant nutrition》2013,36(10):1844-1854
ABSTRACT A greenhouse experiment was performed to evaluate macronutrients and boron deficiencies on vitexin bioproduction by sweet passion fruit leaves. Sand irrigated with nutrient solution was used as substrate in a complete randomized design, with eight treatments: 1) complete, 2) nitrogen-deficient(-N), 3) phosphorus-deficient(-P), 4) potassium-deficient(-K), 5) calcium-deficient(-Ca), 6) magnesium-deficient(-Mg), 7) sulfur-deficient(-S), and 8) boron-deficient(-B). After thirty days, the fourth fully expanded leaves were harvested. Under deficiency treatments, leaf dry matter concentrations of N, P, K, Ca, Mg, S, and B were 52, 53, 62, 76, 69, 31, and 80% lower than in complete treatment, respectively. Nitrogen, P, and K deficiency increased vitexin leaf concentration by 46, 16, and 18%, although Ca and B deficiencies decreased vitexin concentration by 22 and 33%, respectively, when compared to complete treatment. Magnesium and S deficiencies had no significant effect on vitexin concentration. In complete treatment, the concentration of nutrients and vitexin, in leaf dry matter were: 43.4 g kg? 1 of N, 2.47 g kg? 1 of P, 27.4 g kg? 1 of K, 15.6 g kg? 1 of Ca, 3.8 g kg? 1 of Mg, 5.28 g kg? 1 of S, 64 mg kg? 1 of B, and 5.57 mg kg? 1 of vitexin. 相似文献
20.
P. H. C. Luz M. A. Marin F. F. S. Devechio A. M. G. Zuñiga M. W. S. Oliveira 《Communications in Soil Science and Plant Analysis》2018,49(2):159-169
The aim of this study was to evaluate the diagnostic imaging approach to identify the deficiency of boron in leaves of maize. The experiment was conducted in a greenhouse under a hydroponic system. The treatments were four levels of boron (B) in solution nutrition (zero, 0.12, 0.24 and 0.60 mg L?1), combined at V4, V7, and R1 growing stages. Plant parts sampled included index leaf and new leaf to chemical analysis and texture image analysis. Our proposal was to apply these texture analysis and pattern classification schemes to identify the levels of B. Texture methods achieved 98% of accuracy in differentiating between leaves properly fertilized with B, from leaves with deficiency, in V4. In all tests, with index leaf success rate was higher than 80%, and around 90% for the new leaf. The image analysis by texture techniques applied on maize leaves are able to identify boron deficiencies in younger plants. 相似文献