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1.
Chicory (Cichorium intybus L.) and dandelion (Taraxacum officinale Web.) were demonstrated to be potential indicator plants for heavy metal contaminated sites. Chicory, grown with 0.5–50 μM cadmium (Cd) in nutrient solution, accumulated 10–300 μM Cd g?1 in shoots and 10–890 μg Cd μg?1 in roots and rhizomes. With dandelion, 20–410 μg Cd μg?1 was found in shoots and 20–1360 μg Cd μg?1 in roots and rhizomes. An inverse correlation existed between chlorophyll and Cd concentrations in shoots of both species. Accumulation of Cd from nutrient solution was similar with the counter-anions SO4 2?, Cl1? and NO3 ? in chicory. In chicory grown in Cd-amended (11.2 kg Cd ha?1 applied five years previously) soils, Cd concentrations were substantially higher than in controls in all plant parts following the order: leaf > caudex > stem > root and rhizome. The above trend was the opposite of that observed in solution culture, where Cd accumulation was higher in roots and rhizomes than in shoots. Higher cadmium accumulation was found from a Cd-treated sand (Grossarenic Paleudult) than from a loamy sand (Typic Kandiudult) soil type. Chicory and dandelion are proposed indicator plants of cadmium contamination, and both have the potential to be an international standard heavy phytomonitor species of heavy metal contaminantion. 相似文献
2.
《Communications in Soil Science and Plant Analysis》2012,43(9-10):1517-1531
Abstract A pot experiment was conducted to investigate the effects of different cadmium (Cd) concentrations of phaeozem on growth and uptake of Cd and mineral nutrient copper (Cu) and zinc (Zn) by three maize genotypes in the mature stage. The results showed that the dry‐matter accumulation of shoots was inhibited by added Cd for Jidan209 and Jitian6, but this did not influence Chunyou30. The root biomasses decreased significantly for Jitian6 and stimulated Jidan209 and Chunyou30. Yields of three genotypes of maize were decreased by increasing soil Cd concentrations. Among them, Chunyou30 had a high tolerance and Jitian6 was most sensitive to Cd. The accumulation order of Cd in different parts of plants was root > leaf > stem > grain. The percentage of absorbed Cd by roots was 70–85% of total absorbed amount. Cadmium uptake by maize in the mature stage had a significant genetic variation: Jitian6 > Jidan209 > Chunyou30 for root, stem and leaf, and Jidan209 > Jitian6 > Chunyou30 for grain, respectively. Increase of soil Cd had no significant effect on Zn concentration of leaves, but there was a significant genetic variation: Chunyou30 > Jidan209 > Jitian6 (P=0.023). Cu concentration of leaves was increased significantly with increase of soil Cd (P<0.01), but no genetic variation was observed. 相似文献
3.
For better understanding of mechanisms responsible for differences in uptake and distribution of cadmium (Cd) and nickel (Ni) in different plant species, nutrient solution experiments were conducted with four plant species [bean (Phaseolus vulgaris L.), rice (Oryza saliva L.), curly kale (Brassica oleracea L.) and maize (Zea mays L.)]. The plants were grown in a complete nutrient solution with additional 0.125 and 0.50 μM Cd or 0.50 and 1.00 μM Ni. Large differences in Cd and Ni concentrations in shoot dry matter were found between plant species. Maize had the highest Cd concentration in the shoots, and bean the lowest. Contrary to Cd, the Ni concentrations were highest in the shoots of bean and the lowest in maize. A gradient of Cd concentrations occurred in bean and rice plants with the order roots > > stalk base >> shoots (stems/sheaths > leaves). A similar gradient of Ni concentrations was also found in maize and rice plants. In the xylem sap, the Cd and Ni concentrations were positively correlated with Cd and Ni concentrations in the shoot dry matter. In the roots of maize, about 60% of Cd could be extracted with Tris‐HCl buffer (pH 8.0), while in roots of other plant species this proportion was much lower. This higher extractability of Cd in the roots of maize is in accordance with the higher mobility as indicated by the higher translocation of Cd from roots to shoots and also the higher Cd concentrations in the xylem sap in maize than in the other plant species. Similarly, a higher proportion of Ni in the soluble fraction was found in the roots of bean compared with maize which is in agreement with the higher Ni accumulation in the shoots of bean. The results of gel‐filtration of the soluble extracts of the roots indicated that phytochelatins (PCs) were induced in the roots upon Cd but not Ni exposure. The higher Cd concentrations and proportions of Cd bound to PC complexes in the roots of maize compared with the other plant species suggest that PCs may be involved in the Cd trans‐location from roots to shoots. 相似文献
4.
Potassium (K) fertility recommendations based on cotton petiole diagnostic analysis results have been inconsistent in the past, partly because the lowest acceptable petiole K concentration is unknown. Therefore, cotton was grown in sand filled 8‐L pots under two K treatments in a growth chamber at the Altheimer Laboratory in Fayetteville, AR to determine the petiole K concentration that will impact leaf physiology. Chamber‐grown plants were watered every second day with nutrient solution and with deionized water on alternate days. At 14 days after planting two treatments were established consisting of (1) continued complete nutrient solution, and (2) nutrient solution containing no K. Measurements were taken 13, 19, and 26 days after treatment establishment (DATE). Organ K concentrations, leaf chlorophyll, photosynthesis, adenosine triphosphate (ATP), and nonstructural carbohydrate concentrations were monitored as plant K deficiencies developed. All organ K concentrations were much lower in the no‐K treatment on each analysis date. Visual K deficiencies were first observed at 19 DATE along with reductions reductions in leaf chlorophyll concentration. Leaf photosynthesis was greatly reduced in the no‐K treatment beginning at 19 DATE. However, leaf ATP and nonstructural carbohydrate concentrations were higher at 19 and 26 DATE in the no‐K treatment, which may have been the result of reduced utilization and translocation of these metabolites. Our studies show that reductions in leaf physiological processes and plant growth did not occur until the petiole K concentration fell below 0.88% on a dry weight basis. Therefore, reductions in lint yield and quality should not develop until this critical petiole level is attained. 相似文献
5.
The effect of varying solution calcium (Ca) and magnesium (Mg) concentrations in the absence or presence of 10 μM aluminum (Al) was investigated in several experiments using a low ionic strength (2.7 × 10‐3 M) solution culture technique. Aluminium‐tolerant and Al‐sensitive lines of wheat (Triticum aestivum L.) were grown. In the absence of Al, top yields decreased when solution Ca concentrations were <50 μM or plant Ca concentrations were <2.0 mg/g. Top and root yields decreased when solution Mg concentrations were <50 μM or plant Mg concentrations were <1.5 mg/g. There were no differences between the lines in solution or plant concentrations at which yield declined. Increasing solution Ca concentrations decreased plant Mg concentrations in the tops (competitive ion effect) but increased plant Mg concentrations in the roots of wheat. This suggests that Ca is competing with Mg when Mg is transported from the roots. Increasing solution Mg concentrations decreased plant Ca concentrations in the tops and the roots (competitive ion effect). In the roots, increasing solution Mg concentrations decreased plant Ca concentrations at a lower solution Ca concentration in the Al‐sensitive line than the Al‐tolerant line. In the presence of Al, increasing solution Ca and Mg concentrations increased yield (Ca and Mg ameliorating Al toxicity). Yield increased until the sum of the solution concentrations of the divalent cations (Ca+Mg) was 2,000 μM for the Al‐tolerant line or 4,000 μM for the Al‐sensitive line. The exception was that yield decreased when solution Mg concentrations were > 1,500 μM and the solution Ca concentration was 100 μM (Mg exacerbating Al toxicity). The ameliorative effects of solution Ca or Mg on Al tolerance were not related to plant Ca or Mg concentrations per se. 相似文献
6.
土壤增施蛋氨酸硒对厚皮甜瓜生理特性和品质的影响 总被引:3,自引:0,他引:3
【目的】本研究探究了蛋氨酸硒对厚皮甜瓜生长与生理特性的调控作用,硒在厚皮甜瓜中的富集效益,以及硒在土壤中的变化趋势。【方法】以‘M135’厚皮甜瓜为试材,蛋氨酸硒为硒源,采用盆栽试验,以土壤本底硒为对照,通过向土壤中增施蛋氨酸硒使土壤中的总硒含量分别增加4、 10和16 mg/kg,研究了蛋氨酸硒对厚皮甜瓜生长、 产量、 光合特性、 产品品质及果肉硒含量的影响,对厚皮甜瓜不同组织器官中总硒含量的影响,以及对土壤中不同形态硒含量变化的影响。【结果】施硒4、 10和16 mg/kg均可显著提高甜瓜叶片光合色素含量、 叶片光合速率、 植株生长量以及甜瓜产量; 另外,不同浓度施硒处理还显著提高了果肉中有机硒、 无机硒、 可溶性糖、 可溶性蛋白、 游离氨基酸和维生素C的含量,并以10 mg/kg施硒处理的效果最佳。10 mg/kg施硒处理的单株产量比对照提高了19.53%,果肉中的可溶性糖、 可溶性蛋白、 游离氨基酸和维生素C的含量比对照分别提高了14.82%、 49.88%、 23.42%和25.03%,果肉中硒的总含量为44.74 μg/kg,其中有机硒含量36.87 μg/kg,占到总硒含量的82.91%,达到富硒标准。进一步的研究发现,虽然果肉中硝酸还原酶活力、 硝酸盐和亚硝酸盐含量均随施硒浓度的增加而增加,但4、 10和16 mg/kg施硒处理后的亚硝酸盐含量分别为1.499、 1.907和2.131 mg/kg,均远低于国家标准的上限(20 mg/kg)。对施硒后厚皮甜瓜不同组织器官中硒含量的研究发现,厚皮甜瓜各组织器官(根、 茎、 叶柄、 叶、 果皮、 果肉和种子)的总硒含量也随施硒浓度的增加而增加。对根、 茎、 叶柄和叶的比较发现,在未增施蛋氨酸硒时叶中的硒含量最高,其次为根、 茎和叶柄; 而增施蛋氨酸硒后则表现为根中最多,其次为茎、 叶和叶柄。对果皮、 果肉和种子的比较发现,各处理果实内各组织的总硒含量均表现为种子中最多,其次为果肉和果皮。对施硒后土壤中不同形态硒含量的研究发现,定植后未施蛋氨酸硒的上层土壤中总硒、 无机态Se6+的含量均呈下降趋势,土壤中有机硒和无机态Se4+的含量变化不大; 4、 10和16 mg/kg施硒处理的土壤中有机硒、 总硒以及无机态Se4+含量都呈先下降后趋于平缓的趋势,而无机态Se6+的含量则呈先上升后下降的趋势。【结论】土壤增施蛋氨酸硒后提高了厚皮甜瓜果肉的硒含量,增强了光合能力,促进了厚皮甜瓜植株的生长,从而提高了产量和综合品质,其适宜的土壤施硒浓度为10 mg/kg。 相似文献
7.
《Communications in Soil Science and Plant Analysis》2012,43(15-16):2597-2611
Abstract A solution culture study was conducted to determine the effects of cadmium (Cd) application on Cd accumulation and growth of two durum wheat (Triticum turgidum L. var durum) cultivars. Arcola and DT618 were grown in nutrient solution for 13 days. Cadmium application to nutrient solution significantly (P ≤ 0.05) decreased root and shoot biomass, leaf area, leaf mass, total root length, and chlorophyll a and b concentration of the first leaf. The deleterious effects of Cd on plant growth were explained by a modified version of Weibull distribution function of the form, y = a.exp(b.√Cd), where ‘y’ is the growth parameter, ‘a’ is plant growth in the absence of Cd, and ‘b’ is reduction in growth with per unit increase in solution Cd. Total root length was decreased the most (80%) and chlorophyll b concentration of the first leaf decreased the least (9%) with per unit increase in solution Cd. Although the two cultivars were significantly different in some growth characteristics, both responded similarly to increase of Cd concentration in solution. Cadmium concentration in roots and shoots increased significantly (P ≤ 0.05) with Cd application, but due to concomitant decrease in growth the Cd content of plants remained constant at solution Cd concentrations of 5 μm or above. We concluded that seedlings of durum cultivars with different growth potential responded similarly to Cd application in nutrient solution. 相似文献
8.
Abstract A solution culture study was conducted to determine the genotypic difference in the effects of cadmium (Cd) addition on growth and on the uptake and distribution of Cd and other 11 nutrients in wheat plants. Cadmium addition at a rate of 1 mg L?1 significantly reduced root and shoot dry matter production, shoot height, root length, chlorophyll content, and tillers per plant. On the average of 16 wheat genotypes used in study, Cd concentrations of Cd‐treated plants were 48.1 and 459 μg g?1 dry weight (DW) in shoots and roots, respectively, and retained 77.91% of total Cd taken up in the roots. On the whole, Cd addition reduced the concentration of sulfur (S), phosphorus (P), magnesium (Mg), molybdenum (Mo), manganese (Mn), and boron (B), and increased iron (Fe), irrespective of the plant parts. The effect of Cd on the concentration of potassium (K), calcium (Ca), and copper (Cu) differed in shoots and roots. The significant difference existed among 16 wheat genotypes in their response to Cd in terms of growth and nutrient concentrations. Genotype E81513, which showed relatively less inhibition in growth, had the lowest shoot Cd concentration and more Cd accumulation in roots, while Ailuyuang had the highest Cd concentration and accumulation in shoot with lower Cd concentration in root. The significant interaction was found between Cd treatment and genotype for all nutrient concentrations in both shoot and root, except S and Zn in root. 相似文献
9.
An Indiana silt loam soil was equilibrated with various amounts of Ca(H2PO4)2 H2O and a 0.01 M CaCl2 solution to construct its phosphorus sorption isotherms. Using the isotherms, the P buffering capacity of the soil was calculated and amounts of fertilizer P necessary to give several levels of P in the soil solution, for experiments conducted over a 2 year period, were determined. Twenty‐four day old tomato seedlings were grown and measured for leaf area, root length, dry weights and P concentrations in leaf, petiole, stem and root.
Phosphorus concentration in soil solution increased slowly with the first increment of P added to the soil. Subsequent P additions increased the P concentrations in solution exponentially. The maximum P absorption by the soil was 324 μg P/g soil and the constant related to P binding energy was 1.37. In addition, the soil buffering capacity decreased with an increase in the amount of P in the soil solution.
Plant shoot dry weight increased linearly with P increase in the concentration range 0.65 to 6.5 μM P in soil solution. However, beyond this level the response was low. The leaf area rate of increase in the 0.65 to 6.5 μM P solution concentration range was 75 times that in the 6.5 to 84 μM P. The root length: shoot dry weight ratio decreased with increasing P supply in the soil solution. P uptake by the plants increased with increased P concentration in soil solution. At soil solution concentrations above 6.5 μMP the rate of P uptake in the shoot was 20 times less than the rate for concentrations below 6.5 μM P. Of the P taken up by tomato seedlings about 65% was in the leaf, 13% in the stem, 13% in the petiole and 9% in the root. 相似文献
10.
《Communications in Soil Science and Plant Analysis》2012,43(11):1067-1075
Abstract Plant species, as well as cultivars within species, have been shown to vary in response to soil nutrient levels due to variation in tissue requirements and variation in ability to absorb nutrients from the soil. In order to study this latter aspect in sunflowers (Helianthus annuus L.), two field trials were conducted in which nutrient concentrations in the topmost nature leaf were determined. At two growth stages, 16 cultivars differed significantly in leaf nutrient levels of N, K, Ca, Mg, Mn, Cu, Zn, and B. Seed yields were highly significantly correlated with leaf nutrient levels, variation in nutrient concentrations accounting for 43% of the observed variation in seed yield. On this soil which was low in B, variation in B concentration alone accounted for 28% of the variation in seed yield in spite of 2 kg B/ha having been applied. Marked differences were observed in the leaf nutrient concentrations of 40 inbred lines tested. 相似文献
11.
Tapan Adhikari Elisha Tel-Or Yael Libal Moshe Shenker 《Journal of plant nutrition》2013,36(11):1919-1940
ABSTRACT To better understand the mechanisms responsible for differences in uptake and distribution of cadmium (Cd), nutrient-solution experiments were conducted with different varieties of rice (Oryza sativa), ‘Khitish’ and ‘CNRH3’. The plants were grown in a complete nutrient solution with different levels of pCd (-log free Cd+2 activity) and pFe [-log free iron (Fe+2) activity]. The required concentrations of chelating agent and metals were determined using a computerized chemical equilibrium model such as Geochem-PC. Experimental treatments included a combination of four pCd activity levels (0, 7.9, 8.2, and 8.5) applied as Cd (NO3)2 4H2O, and two pFe activity levels (17.0 and 17.8) applied as FeCl3. The application of both Cd and Fe in solution culture significantly affected plant growth, yield, and Cd accumulation in plant tissue. In general, yield of rice was decreased by an increase in amount of solution Cd; however, yield response varied among the cultivars. At the 7.9 pCd level, yields of rice cultivars ‘Khitish’ and ‘CNRH3’ were reduced to 69% and 65%, respectively, compared with control plants. Root Cd concentrations ranged from 2.6 mg kg?1 (control plants) to 505.7 mg kg?1 and were directly related to solution Cd concentrations. In rice plants, Cd toxicity symptoms resembled Fe chlorosis. Differential tolerance of varieties to phytotoxicity was not readily visible, but a significant interaction of substrate Cd and variety was obtained from dry-matter yields. Significant interactions indicated that response of tissue Cd concentration, plant Cd uptake, and translocation of Cd to the aerial parts were dependent on variety as well as substrate Cd. Uptake of Cd by roots was significantly higher than by shoots. Higher Cd uptake by rice plants decreased the uptake of other beneficial metals. The effect of Cd and Fe on the rate of phytometallophore release was also studied in the nutrient solution. Among the rice genotypes, ‘Khitish’ was the most sensitive to Cd toxicity. In both genotypes, with the onset of visual Cd-toxicity symptoms, the release of phytometallophore (PM) was enhanced. Among the rice varieties, ‘Khitish’ had the highest rate of PM release. Treatments with the metal ions studied produced a decrease in chlorophyll and enzyme activity. A decrease in concentrations of chlorophyll pigments in the third leaf was observed due to the highest activity level of Cd (pCd 7.9). Activities of enzymes such as peroxidase (POD) and superoxide dismutase (SOD) are altered by toxic amounts of Cd. Changes in enzyme activities occurred at the lowest activity of Cd (pCd 8.5) in solution. Peroxidase activity increased in the third leaf. Results showed that in contrast with growth parameters, the measurements of enzyme activities may be included as early biomarkers in a plant bioassay to assess the phytotoxicity of Cd-contaminated solution on rice plants. Evidence that Cd uptake and translocation are genetically controlled warrants the selection of varieties that assimilate the least Cd and that translocate the least metal to the plant part to be used for human and animal consumption. 相似文献
12.
The effect of NH4NO3 (control) and increasing NO3- levels in nutrient solutions containing no and 100 μM Fe respectively on iron chlorosis of Glycine max was investigated. After two weeks of growth apoplastic pH in excised leaves was measured by means of fluorescence. In plants growing without Fe supply increasing concentrations of NO3- in the nutrient solution which also was applied to the cut end of the petiole, resulted in a pH increase in the leaf apoplast from 5.34 (NH4NO3) to 5.50 (NO3-) associated with chlorosis observed with intact plants. A close negative correlation was found between chlorophyll concentration and pH in the apoplast (r = ?0.97). While leaves in the treatment exclusively fed with NO3- were strongly chlorotic, those in the NH4NO3 treatment were green. With exception of the plants only fed with NO3- the Fe concentration in the leaves was not affected by the type of N nutrition. It is therefore assumed that some Fe is immobilized in the leaf tissue by high apoplast pH induced by an increase in the proportion of nitrate in the nutrient solution. Plants fed with Fe (100 μM) showed no chlorosis, regardless of the form of N nutrition and hence regardless of apoplast pH. The Fe concentration in leaves of Fe fed plants was approximately twice those in the leaves not supplied with Fe. 相似文献
13.
Cadmium (Cd) is toxic to plants, animals, and humans. However, different plant species growing on the same soil may have very different shoot Cd concentrations depending on properties such as size of the root system, Cd net influx, shoot‐growth rate, Cd translocation from root to shoot, and the ability to affect Cd availability in the soil. To investigate possible reasons for different shoot Cd concentrations maize, sunflower, flax, and spinach were grown on an acid sandy soil (pH<$>_{{\rm{(CaCl}}_{\rm{2}} {\rm)}<$> 4.5, and Corg 2.8%) in a growth chamber with Cd additions as Cd(NO3)2 of none, 14, and 40 μmol (kg soil)–1 resulting in Cd soil‐solution concentrations of 0.04, 0.68, and 2.5 μM. Only the high Cd addition caused a significant growth reduction of flax and spinach. The shoot Cd concentration was up to 30 times higher in spinach than in maize; the other species were intermediate. Of the plant properties studied only the variation of the Cd net influx explained the differences in shoot Cd concentrations. This was due to a decreased (maize, sunflower) or increased (flax) Cd concentration in soil solution or more effective uptake kinetics (spinach). 相似文献
14.
There is little agreement on the leaf and shoot boron (B) requirement of rice (Oryza saliva L.) and the optimum hydroponic solution B concentration for rice. Questions on the mechanism of B uptake active or passive are also unresolved. We grew rice in hydroponic solutions in a growth chamber for six weeks with B at 0, 0.05, 0.2, 1, 5, 10, 25, and 50 μM. Transpirational flow, dry matter yields and tissue B were determined. Results indicated that B deficiency occurred when there was <7.3 mg kg‐1 B in the flag leaves, <3.6 mg kg‐1 B in shoots, and <0.2 μM B in the nutrient solutions. Boron additions increased dry matter and plant height. Typical B‐deficiency symptoms were a light color or chlorosis on almost all of the youngest leaves and stems, an unthriftiness, leaf tip burn, and pale bands 2–3 mm wide on leaves, particularly on the moderately B‐deficient plants. Whitish and twisted new leaf tips occurred at >0.05 μM B. A mass balance analysis that compared the total mass of B in the plant versus B provided via transpirational flow showed that at high hydroponic B supply, passive uptake and active excretion of B, or, active blockage of B may have occurred, for > 10‐fold differences existed between the B mass in plant and B mass that could be provided via transpirational flow. Thus, B uptake was against a concentration gradient and high B supply, and as other evidence indicated, at low B supply. 相似文献
15.
D. M. Wheeler 《Journal of plant nutrition》2013,36(5):949-954
The effect of aluminium (Al) on the relative yield of plants grown from seeds of ryegrass (Lolium perenne L.) or white clover (Trifolium repens L.) and either tillers (ryegrass) or stolon tip cuttings (white clover) were investigated using a low ionic strength (2.7 x 10‐3 M) solution culture technique. In ryegrass, plants grown from tillers had higher relative yields than plants grown from seedlings in the tops when solution Al concentrations were greater than 16 μM and in the roots when solution Al concentrations were greater than 7 μM. In white clover, relative yields in the tops and roots plants were higher in plants grown from stolon tip cuttings than from seedlings when solution Al concentrations were greater than 10 μM. There were no significant cultivar effects. The results indicate that plants used in Al‐tolerance experiments can be grown from seed or vegetatively propagated, provided solution Al rates are adjusted to reflect differences in Al tolerance. 相似文献
16.
Two hydroponic experiments were conducted to investigate the antioxidant response of winter wheat (Triticum aestivum L.) to cadmium (Cd)-zinc (Zn) interactions, Seedlings of winter wheat (cv. Yuandong 977), were grown in modified Hoagland nutrient solution with the addition of increasing concentrations of Cd (0, 10, 25, 50 μM). In experiment 2, the seedlings of the same cultivar were treated with constant concentration of Cd (25 μM) and varying levels of Zn (0, 1, 10, 50 μM). Hydrogen peroxide (H2O2) and malondialdehyde (MDA) as well as the activities of three antioxidant enzymes, catalase (CAT), guaiacol peroxidase (GPX), ascorbate peroxidase (APX) were monitored to estimate the amount of oxidative stress and the antioxidant ability of seedlings treated with Cd and Zn for 10 days. The results showed that levels of H2O2 and MDA in experiment 1 were significantly increased with increasing Cd concentrations. The data indicated that Cd could induce oxidative stress and lipid peroxidation in the plants. While H2O2 and MDA levels were significantly reduced by addition of Zn in experiment 2, the activities antioxidant enzymes were enhanced. A concentration of 10 μM Zn appeared to be the optimal level in this experiment for seedlings' growth, chlorophyll synthesis and antioxidant status, indicating that Zn alleviated the oxidative stress induced by Cd. 相似文献
17.
《Communications in Soil Science and Plant Analysis》2012,43(21):3076-3091
Aluminum (Al) and cadmium (Cd) are two elements that contaminate soil in different ways as waste products of some industrial processes and that can be tolerated by some plant species in different concentrations. In this study, growth parameters of leaves and stems (fresh and dry weights, stem lengths, leaf surface area, and lamina thickness), anatomical changes in leaves (lower and upper epidermis, stomata and mesophyll tissue), and photosynthetic pigment contents (chlorophyll a and b, total chlorophyll, and carotenoids) were investigated in cotton (Gossypium hirsutum L. cv. Nazilli 84S), which was treated with Al and Cd for 3 months. Cotton seedlings were grown in greenhouse conditions and watered with Hoagland nutrient solutions, which contained 0, 100, and 200 μM aluminum chloride (AlCl3) and cadmium chloride (CdCl2). It was observed that reduced soil pH positively affected many parameters in cotton plants. Aluminum accumulation was greater in leaves than stems while the opposite was true for Cd accumulation. Leaves and stems of cotton plants treated with 100 and 200 μM Al and Cd showed slight growth changes; however, high concentrations of Al (200 μM) caused significant reductions in leaf area and leaf fresh weight, whereas stem fresh weight decreased with 200 μM Cd treatment. Anatomical parameters were mostly affected significantly under both concentrations of Al and Cd solutions (100 and 200 μM). The results revealed that the anatomical changes in the leaves varied in both treatments, and the long-term effect of the tested metals did not include harmful effects on anatomical structures. Moreover, the variations could be signals of tolerance or adaptive mechanisms of the leaves under the determined concentrations. 相似文献
18.
Cadmium (Cd) uptake by lettuce (Lactuca sativa L.) was studied in a hydroponic solution study at concentrations approaching the total concentration in contaminated soil solutions. Four cultivars of lettuce were tested (Divina, Reine de Mai, Melina, and J.44). Ten 12‐day old seedlings, pretreated in 0.5 μM CdCl2 solution, were labelled with carrier free 109CdCl2 (from 0.05 μM to 5 μM Cd in nutrient solution) in the presence and absence of metabolic inhibitors, DNP and DCCD. Cadmium taken up by the roots was determined after a 30 min desorption in unlabelled CdCl2 solution. In the absence of metabolic inhibitors and at 5 μM Cd, root absorbed from 2.5 to 8 mg Cd/g root dry weight. Exchangeable Cd measured after desorption represented less than 1% of the total Cd absorbed by the root. Cadmium absorption in presence of DNP showed that approximately 80% of the Cd enters the cell through an active process. This mechanism seems to be directly associated with H+‐ATPase as observed with DCCD inhibition. Varietal differences in shoot Cd uptake were only demonstrated at concentrations below 0.1 μM. Screening lettuce cultivars only by the Cd level in the tissue seems not to be possible for these cultivars except at concentrations close to that in the soil solution. But differences in relative contribution of uptake mechanisms in total Cd absorption were observed. High levels of Cd in roots were correlated with high contri‐ butions from H+‐ATPase in the active process of Cd uptake. 相似文献
19.
20.
Virginia peanut types need more calcium (Ca) in the soil than Spanish types for high pod yield, but their actual soil solution and fruit tissue Ca requirements have not been well defined. A split root and pod solution culture technique was used to examine the effects of Ca concentration on fruiting of one Virginia cv. ‘Virginia Bunch 1’ and one Spanish peanut cv. ‘TMV-2’. Plants were grown in complete nutrient solution (root zone) containing 100 μM Ca, and six treatments imposed in which the pod zone solution Ca was controlled at 0 to 2500 μM. ‘TMV-2’ produced some mature seeds with no Ca added to the pod zone solution and 81% of maximum seed dry matter at 5 μM Ca, a concentration at which its pod dry matter production was close to maximum. In contrast, ‘Virginia Bunch 1’ produced no pods with no Ca added to the pod zone and only 28% of maximum pod dry matter at 5 μM Ca. ‘TMV-2’ required 6 and 21 μM Ca in the pod zone solution for 95% of maximum pod and seed production, respectively. The corresponding solution concentrations for ‘Virginia Bunch 1’ were 35 and 50 μM Ca. The seed dry matter production of ‘Virginia Bunch 1’ decreased with ≥112 μM Ca in the pod zone solution due to a decrease in individual seed mass, but there was no depression in the case of ‘TMV-2’ up to the highest pod zone solution concentration of 2500 μM Ca studied. The Ca concentration in pod walls and seeds of both cultivars increased with increase in Ca up to 500 μM in the pod zone, the effect being greater in ‘TMV-2’. However, the seed production of both cultivars was maximized at approximately the same seed Ca concentration of 0.04%. The results of this study have shown that the Spanish peanut cv. ‘TMV-2’ and the Virginia peanut cv. ‘Virginia Bunch 1’ have a similar tissue Ca requirement for seed growth despite the higher pod zone Ca requirement of ‘Virginia Bunch 1’. 相似文献