The effect of different iron concentrations on lead accumulation in hydroponically grown <Emphasis Type="Italic">Matthiola flavida</Emphasis> Boiss

The general relationship between heavy metals and mineral nutrition of plants grown in polluted environments is one of the most important factors for modifying the toxic properties of these metals. To study the effect of iron and lead pollution on the growth of Matthiola flavida a factorial research was undertaken in the form of a completely randomized design with four replications in hydroponic culture. After germination, seedlings were transferred to a hydroponic culture. During the pre-treatment step, a series of plants contained enough iron (+Fe), whereas the second series was without iron (?Fe). After the pre-treatment step, both series of plants were treated with three levels of iron as FeEDDHA and two levels of lead as Pb(NO₃)₂. The results showed that in both series of plants, lead reduced the root growth, shoot height, shoot and root dry weight. For 5 µM lead concentration, with increasing concentration of iron in the nutrient solution, concentration of lead in the roots and shoots decreased. For 1 µM concentration of lead, increasing the iron concentration in the nutrient solution reduced the concentration of lead in the roots, but had no significant effect on the amount of lead in shoots. Lead accumulation in shoots and roots of plants with Fe was more than plants without Fe. Also, in low concentrations of iron, the amount of iron in shoot increased with the increase of lead concentration in the nutrient solution. The results showed that in lead pollution, iron has a positive effect on investigated traits.     

Comparative accumulation of manganese and boron in barley tissues

Summary The uptake of Mn and B by barley plants was studied in a 5-week period in growth chambers. Fluorescent light was provided with an intensity of 3200 foot-candles in a 12-hour day length and the entire plants were grown at temperatures of 10°, 15°, or 20°C. The root medium consisted of a base nutrient solution in which Mn or B was added in the following concentrations: 0, 0.1, 0.5, 2.0, and 5.0 ppm. Five plants were grown in volumes of 20 liters of solution. At the end of the growth period the shoots and roots were analyzed for Mn and B. The Mn content of the roots increased with temperature and with the Mn concentration of the external solution while the B content remained virtually static regardless of temperature or solution concentration. The shoots were divided into young, mature, and old leaves. The Mn and B content of the old leaves showed increases which varied both with temperature and concentration. Similar results were obtained with young and mature leaves. The failure of B to accumulate in the roots was discussed. It was suggested that boric acid, with a very low degree of dissociation, is present largely in a molecular form and does not participate in the customary metabolic activity connected with ion uptake and accumulation in roots.     

Lead uptake from solution by perennial ryegrass and its transport from roots to shoots

Summary The uptake of lead by roots and its transport to the shoots was examined with perennial ryegrass in solution cultures. Root uptake as measured by the decrease in concentration of lead in an aqueous solution containing 1 mg Pb/l as Pb (NO₃)₂ was rapid, almost complete, and unaffected by removing the shoots or killing the roots. Lead bound in the roots was not released by exchange with Ca or Ba ions. The distribution of lead within the plant was examined at intervals after a single, 3-day exposure to various levels of lead added to a nutrient solution. The total uptake, or lead burden, increased with increasing rates of addition and ranged from 281 to 9969 g/Pb per 3 plants. The proportion of the lead reaching the shoots at the first harvest (7 days after adding lead) was 3.5 to 22.7 per cent of total uptake, the lower value being for plants with the greatest burden. Transport to the shoots continued throughout the experimental periods of 21 and 28 days but did not exceed 28.9 per cent of total uptake. The concentration of lead in shoots at the first harvest ranged from 0.2 to 58.4 ppm and that in the corresponding roots from 5.5 to 5310 ppm. At later harvests, and after cutting, the concentration in the shoots decreased; an exception was in plants with the greatest lead burden. It is concluded that roots of actively growing ryegrass provide a barrier which restricts the movement of lead to the above-ground parts of plants, and so to animals or man.     

Leaf endophyte Neotyphodium coenophialum modifies mineral uptake in tall fescue

Neotyphodium coenophialum (Morgan-Jones and Gams) Glenn, Bacon and Hanlin, a fungal endophyte found primarily in shoots of tall fescue (Festuca arundinacea Shreb.), can modify rhizosphere activity in response to phosphorus (P) deficiency. In a controlled environment experiment, two cloned tall fescue genotypes (DN2 and DN4) free (E-) and infected (E+) with their naturally occurring endophyte strains were grown in nutrient solutions at low P (3.1 ppm) or high P (31 ppm) concentrations for 21 d. Endophyte infection increased root dry matter (DM) of DN4 by 21% but did not affect root DM of DN2. Under P deficiency, shoot and total DM were not affected by endophyte but relative growth rate was greater in E+ than E- plants. In high P nutrient solution, E+ plants produced 13% less (DN2) or 29% more (DN4) shoot DM than E- plants. Endophyte affected mineral concentrations in roots more than in shoots. Regardless of P concentration in nutrient solution, E+ DN2 accumulated more P, Ca, Zn and Cu but less K in roots than E- plants. When grown in high P nutrient solution, concentrations of Fe and B in roots of E+ DN2 plants were reduced compared with those of E- plants. Concentrations of P, Ca and Cu in roots of DN4 were less, but K was greater in E+ than E- plants. In shoots, E+ DN2 had greater concentrations of Fe and Cu than E- DN2, regardless of P concentration in nutrient solution. Genotype DN4 responded to endophyte infection by reducing B concentration in shoots. Nutrient uptake rates were affected by endophyte infection in plants grown in low P nutrient solution. A greater uptake rate of most nutrients and their transport to shoots was observed in DN2, but responses of DN4 were not consistent. Results suggest that endophyte may elicit different modes of tall fescue adaptation to P deficiency. This revised version was published online in June 2006 with corrections to the Cover Date.     

Potassium and phosphate uptake of cucumber plants at different ammonia supply

Summary Experiments on cucumber plants grown in nutrient solution were conducted in order to study long and short time effects of ammonia on growth, nutrient element uptake and respiration of roots.Shoot yield and potassium concentration in tissue of plants treated 18 days with varied ammonia concentration were decreased. However, it was not assumed that K deficiency caused the yield reduction. The ammonia effect on K content was more pronounced in roots than in shoots.The decreased K concentration of plant tissue was linked to a diminished ability of plant roots to absorb potassium. The maximum rate of potassium uptake was lowered by ammonia during both, long- and short-time treatment. The results indicated that the NH₃ influence on potassium uptake was due to effects on metabolism and permeability of roots because changes of K uptake rate occurred immediately after starting the NH₃ treatment. Furthermore, it is shown that ammonia inhibited respiration of roots.During the short-time treatment net potassium efflux of roots was observed at higher NH₃ concentrations. The extent of K efflux depended on K concentration of both, root tissue and nutrient solution.Pretreating the plants for 12 hours with ammonia also resulted a decline in K uptake rate. However, plant roots subjected to ammonia concentrations up to 0.09 mM completely recovered during 24 hours after removing the NH₃ treatment whereas at higher NH₃ concentrations only a partial recovery occurred.Furthermore, it was shown that ammonia also influenced P uptake by plant roots.     

Interaction between a copper-tolerant and a copper-sensitive population of Silene cucubalus

Interactions between copper-tolerant and copper-sensitive plants of Silene cucubalus (L.) Wib. were absent when grown in mixed culture in a nutrient solution with a normal Cu²⁺ concentration (0.5 μ M ). When grown in mixed culture in a nutrient solution with 40.5 μ M CuSO₄, however, the biomass production of the sensitive plants was less affected than when grown in monoculture. At 40.5 μ M Cu²⁺, in the presence of tolerant plants, the concentration of copper in both roots and shoots of sensitive plants was significantly diminished in comparison to a monoculture without tolerant plants. At the same time the copper concentration in the roots of the tolerant plants was higher in the presence of sensitive plants. The possibility of external detoxification of the copper by tolerant plants as a mechanism of heavy metal resistance is discussed.     

Nitrate-uptake capacity of different root zones of Zea mays (L.) in vitro and in situ

The close relationship between nitrate depletion of the subsoil and root-length densities found in field experiments could not be explained by mathematical models simulating nitrate uptake (Wiesler and Horst, 1994). The objective of the present study was the validation of some of the assumptions made in these models namely uniform nitrate-uptake rates (NURs) independent on root age and daytime.Different techniques were developed and compared for the measurement of NUR of different root zones: (i) isolated root segments, (ii) compartmented uptake cuvettes, (iii) depletion of nitrate (water) from agarose blocks placed on specific zones of roots growing in nutrient solution and (iv) in rhizotrones filled with soil over the whole growing cycle of maize plants. All methods yielded a similar magnitude of NUR (10 - 30 pmol cm-2 s-1). However, only intact plants growing in nutrient solution as well as in soil, but not isolated root segments, showed higher NUR at apical root zones compared to more mature branching root zones by a factor of 2 - 8. The NUR of the root apex was particularly sensitive to the nitrogen demand of the plant and the assimilate supply from the shoots as affected by light intensity. At suboptimal, but not at optimal light conditions during preculture, NUR was lower in the dark than in the light. As plants matured, NUR of soil grown plants became increasingly dependent on water uptake. But even if nitrate uptake by mass flow was subtracted from total nitrate uptake, mature roots showed a surprisingly high nitrate-uptake capacity.The results indicate that the formation of root-age classes with different NUR and the assumption of lower NUR at night could improve the modelling of nitrate uptake.     

Effects of NaCl on the nitrogen metabolism of the halophyteArthrocnemum fruticosum (L.) Moq., grown in a greenhouse

Summary Arthrocnemum fruticosum (L.)Moq., a halophyte from the shore of the Dead Sea in Jordan was grown in a greenhouse with nutrient solution supplemented with various concentrations of NaCl. It was shown that with increasing salinity the plants became more succulent, mainly due to an accumulation of sodium and water. Sodium was taken up into the roots in equal amounts to chloride, but in the shoots far more sodium than chloride was found, suggesting a control of these ions either in the excretion into the xylem, or in the uptake by the shoot out of the xylem. Ammonium and nitrate in the plants decreased with time on nutrient solution more or less independently of the salt concentration. However, more nitrate appeared again in the plants when they started flowering. After an initial period of adaptation the nitrate reductase activityin vivo was not inhibited by a salinity of up to 2%, but at higher NaCl concentrations a shift of nitrate reductase activity occurred from the roots to the shoots. This was consistent with earlier observations in the field. In the vegetative phase of the plants the nitrate reductase in the roots was influenced by the soil water potential, but in the shoot it was mainly dependent on the supply of nitrate from the roots. High NaCl concentrations delayed flower initiation. During flowering the nitrate reductase was involved in the re-allocation of nitrogenous compounds from the roots to the developing flowers, and it became effectively independent from salinity.     

Uptake and transport of cadmium by perennial ryegrass from flowing solution culture with a constant concentration of cadmium

Summary Perennial ryegrass was sown in flowing solution culture at 7, 6, 5 and 4 weeks before the addition of cadmium to the nutrient solution. The concentration of cadmium in solution was held constant at 0.01 ppm for the following 15 days during which period uptake by the 4 sets of plants of different ages was followed by plant analysis at 3-day intervals. During the 15-day period the total uptake per g (dry weight) root remained nearly constant. The cadmium content of the roots was much greater than that of the corresponding shoots and, although older plants contained more cadmium than younger plants, the proportion of the total content retained by roots was much the same in the 4 sets of plants,i.e. >90 per cent. It is concluded that the roots of ryegrass restrict the transport of cadmium to the shoots. The concentration in the shoots increased only slightly during the 15-day period but to a different extent amongst the 4 sets of plants. These differences reflect differences in growth rate; thus the shoots of the younger sets of plants had lower growth rates and contained correspondingly higher concentrations of cadmium.     

Cadmium uptake from solution by plants and its transport from roots to shoots

Summary The uptake of cadmium by the roots of plants, and its transport to shoots was examined using solution culture. Uptake by the roots of perennial ryegrass over a period of 4 hours from an aqueous solution containing 0.25 ppm cadmium as CdCl₂ was (i) enhanced by killing the roots and (ii) depressed when Ca²⁺, Mn²⁺ or Zn²⁺ were added to the solution. The distribution of cadmium between the roots and shoots of 23 species was examined at 4 days after a single, 3-day exposure to a nutrient solution containing 0.01 ppm added Cd. In all except 3 species, i.e. kale, lettuce and watercress, more than 50 per cent of that taken up was retained in the roots. The concentration in the roots was always greater than in the shoots, and in fibrous roots of fodder beet, parsnip, carrot and radish it was greater than in the swollen storage roots. When perennial ryegrass was similarly exposed to solutions containing 0.01, 0.05, and 0.25 ppm added cadmium, uptake, as measured at 3 days after adding cadmium, increased with increasing rates of addition, but the proportion retained in the roots was constant (approximately 88 per cent). There was no further transport from roots to shoots during the next 21 days, with the result that the concentration in the shoots decreased progressively with increasing growth. It is concluded that although the roots of several species can take up large quantities of cadmium from solution there are mechanisms which may restrict the movement of cadmium through plants, and thus to animals.     

Arsenic uptake, translocation and speciation in pho1 and pho2 mutants of Arabidopsis thaliana

Arsenate [As (V)] is taken up by phosphate [P (V)] transporters in the plasma membrane of roots cells, but the translocation of As from roots to shoots is not well understood. Two mutants of Arabidopsis thaliana (L.) [( pho1 , P deficient) and ( pho2 , P accumulator)], with defects in the regulation and translocation of P (V) from roots to shoots, were therefore used in this study to investigate uptake, translocation and speciation of As in roots and shoots of plants grown in soil or nutrient solution. The shoots of the pho2 mutant contained higher P concentrations, but similar or slightly higher As concentrations, in comparison with the wild type. In the pho1 mutant, the P concentration in the shoots was lower, and the As concentration was higher, in comparison with the wild type. Both pho2 and the wild type contained mainly As (III) in roots and shoot (67–90% of total As). Arsenic was likely to be translocated by a different pathway to P (V) in the pho2 and pho1 mutants . Therefore, it is suggested that As (III) is the main As species translocated from roots to shoots in Arabidopsis thaliana.     

The effect of calcium bicarbonate on iron absorption and distribution byChrysanthemum morifolium, (Ram.)

Summary Plants grown for two weeks in high-bicarbonate nutrient solution with iron became chlorotic, absorbed less iron, and translocated a lower percentage of absorbed iron than did green plants grown under low bicarbonate with iron. Chlorotic plants, pretreated in low-bicarbonate solutions lacking iron, absorbed more iron and translocated a higher percentage to leaves than the green plants. Plants induced to chlorosis by high bicarbonate absorbed less iron after transfer to low-bicarbonate solution containing iron than did chlorotic plants pretreated with low-carbonate solution lacking iron. Initial localization of iron occurred in the roots. A considerable amount of the iron initially found on the roots was translocated to developing shoots over a nine-week period unless the plants were grown in high bicarbonate solutions. More iron was translocated from roots of plants in minus-iron solutions following initial absorption than when iron was supplied in the nutrient solutions. Journal Series Paper736. University of Georgia, College of Agriculture Experiment Stations, College Station, Athens, Ga. 30601.     

Effects of Nitrogen Nutrition on Leaf Expansion and Photosynthesis of Trifolium subterraneum L. II. Comparison between Nodulated Plants and Plants Supplied with Combined Nitrogen

Subterranean clover plants depending on symbiotic nitrogen fixationhad smaller leaf areas than control plants supplied with combinednitrogen in the nutrient solutions. There were no differencesin chlorophyll content per unit fresh weight of leaves or petioles,nor in net rates of carbon dioxide uptake per unit leaf areaat light intensities above 2000 fc and at carbon dioxide concentrationsabove 300 ppm. Dark respiration by the shoots of the nodulatedplants was considerably higher than for the controls. This couldhave been a direct result of nodule activity and is suggestedas a possible factor contributing to the slower growth of theseplants compared with the controls. A comparison of the nitrogen contents of shoots and roots showeda sub-optimal nitrogen status, particularly in the roots, ofthe nodulated plants. This is suggested as another factor contributingto the slower growth of the nodulated plants compared with thecontrols. The response patterns before and after the addition of combinednitrogen differed in a number of important respects from thosefound previously under conditions of a sub-optimal nitrogensupply in the nutrient solution outside the roots. These arebriefly discussed.     

Uptake and translocation of griseofulvin by wheat seedlings

Summary 1. A roughly quantitative technique for studying uptake and translocation of the antibiotic griseofulvin by wheat plants has been devised. Wheat plants were grown in nutrient solutions containing griseofulvin and translocation measured by bioassay of the griseofulvin appearing in the guttation drops induced by transfer to a humid atmosphere.2. Griseofulvin was phytotoxic at concentrations of 5 µg/ml and above, the first symptoms observed being stunting and swelling of the roots.3. The concentration of griseofulvin in the guttation drops was directly related to the concentration in the nutrient solution; there was evidence of griseofulvin accumulation in the leaves, the concentration in the guttation drops being frequently higher than that in the nutrient solution.4. Atmospheric conditions favouring transpiration increased uptake and translocation of griseofulvin.5. Uptake and translocation of griseofulvin was inhibited by inclusion of respiratory enzyme inhibitors in the nutrient solution.     

Uptake and Distribution of Mercury within Higher Plants

The uptake and distribution of inorganic mercury (HgCl₂) within higher plants (Pisum sativum and Mentha spicata) was examined using solution culture and radiotracer techniques. Plants were found to tolerate an external level of 1 mgHg/kg of solution but both physiological and biochemical processes were affected at 5 mgHg/kg and 10 mgHg/kg. The uptake of Hg into plants grown in hydroponic solution was a function of external concentration. Over the concentration range considered the accumulation of Hg in the roots was linear on a log-log basis although the uptake of the element into the shoots appeared to be two-phased. The distribution of Hg in plants was asymmetrical with much greater amounts of the element in the roots than the shoots. Although the level of Hg increased generally in plant tissues with increasing external levels, the proportion retained in the roots, relative to the shoots, was constant (approximately 95%). Two binding characteristics of the Hg within plant tissue were detected. A major proportion of Hg was tightly bound, being unaffected by treatment with ethanol and hydrochloric acid. The remaining Hg in the tissue was removed by either water or hydrochloric acid treatment. Cell fractionation indicated that the major binding component of Hg in plant tissues was the cell wall.     

Effects of Cd2+ and EDTA on young sugar beets (Beta vulgaris). I. Cd2+ uptake and sugar accumulation

Sugar beets ( Beta vulgaris L. cv. Monohill) grown in a complete nutrient solution, were treated with Cd²⁺ (5 or 50 μ M ) and/or EDTA (10 or 100 μ M ) in different combinations. The Cd contents of five-week-old roots and shoots were determined by atomic absorption spectrophotometry, and the sucrose, glucose and fructose contents were measured enzymatically. The Cd²⁺ uptake in both roots and shoots shows a linear relationship to the concentration of free Cd²⁺ in the nutrient solution. This uptake is diminished in the presence of EDTA, suggesting that the Cd-EDTA complex is unable to penetrate the membranes. The contents of glucose, fructose and sucrose in both roots and shoots decrease with increasing uptake of free Cd²⁺. This may be a secondary effect caused by the inhibition of photosynthesis in the presence of Cd²⁺. EDTA reduces the inhibition of Cd²⁺ on sugar formation and accumulation. In the presence of EDTA alone the sugar content increases somewhat. EDTA slightly influences the dry weights of whole plants. The ratio roots:whole plants increases. Cd²⁺ (≤ 50 μ M ) increases the dry matter portion of roots by ca 30%, but not that of shoots.     

The effect of mineral nutrition on the growth and maintenance components of respiration during heterotrophic growth of barley seedlings

Spring barley seedling were grown in the dark for 21 d and respiration rates of the whole plant (including the seed), of the shoots, and of the roots were determined. A function describing the growth and maintenance components of respiration was interpolated through the experimental points and its parameters in plants under different mineral nutrition were compared. The plants grown in a complete nutrient solution showed the highest growth rate in the initial phase of development and thus reached the maximum respiration rate earlier than plants in the other variants. The highest proportion of substrate was respired in the shoot. Plants grown under deficiency of phosphorus and magnesium had a slower respiration rate than plants grown in the complete nutrient solution (NP), whereas the amount of respired substrate in plant parts was similar to that recorded in the NP plants. Plants grown in distilled water showed the lowest growth efficiency and respirated the highest proportion of substrate in the root.     

Cadmium and nickel accumulation in rice plants. Effects on mineral nutrition and possible interactions of abscisic and gibberellic acids

Rice plants accumulate high quantities of Cd and Ni when grown for 10 days in a medium containing these heavy metals. Accompanying Cd and Ni uptake, a decrease in shoot and root length was observed, though dry matter accumulation was not affected accordingly. Metal treatments also induced a decrease in K, Ca and Mg contents in the plants, particularly in the shoots, indicating that Cd and Ni interfered not only with nutrient uptake but also with nutrient distribution into the different plant parts. Addition of abscisic acid (ABA) or gibberellic acid (GA₃) to the external solution could not overcome the depressing effects of the metals on nutrient acquisition, and even induced a further decrease of Ca content in Ni-treated plants. Both hormones also reduced, significantly, heavy metal incorporation into the plants. Additionally, hormonal applications affected the transport of Cd and Ni to the shoots, resulting in a higher percentage of the metals taken up remaining in the roots.     

Effect of two nutrient solution temperatures on nitrate uptake,nitrate reductase activity,NH4+ concentration and chlorophyll a fluorescence in rose plants

The effect of two nutrient solution temperatures (cold (10 °C) and warm (22 °C)) during two flowering events of rose plants (Rosa × hybrida cv. Grand Gala) were examined by measuring chlorophyll (Chl) a fluorescence, ammonium (NH₄⁺) content and nitrate reductase (NR) activity in four different leaf types, that is, external and internal leaves of bent shoots and lower and upper leaves of flowering stems. Besides, nitrate (NO₃^?) uptake and water absorption, total nitrogen (N) concentration in the plant, dry biomass, and the ratios of shoot/root and thin-white roots/suberized-brown roots were determined. Generally, cold solution increased NO₃^? uptake and thin-white roots production but decreased water uptake, so plants grown at cold solution had to improve their NO₃^? uptake mechanisms to obtain a higher amount of nutrient with less water absorption than plants grown at warm solution. The higher NO₃^? uptake can be related to an increase in NR activity, NH₄⁺ content and total N concentration at cold solution. Nutrient solution temperature also had an effect on the photosynthetic apparatus. In general terms, the effective quantum yield (?_PSII) and the fraction of open PSII reaction centres (q_L) were higher in rose plants grown at cold solution. These effects can be associated to a higher NO₃^? uptake and total N concentration in the plants and were modulated by irradiance throughout all the experiment. Plants could adapt to cold solution by enhancing their metabolism without a decrease in total dry biomass. Nevertheless, the effect of nutrient solution temperature is not simple and also affected by climatic factors.     

Occurrence of Inverted Water Potential Gradients between Soil and Bean Roots

Measurements with a pressure chamber were made of the xylem water potential of leaves, shoots and roots from bean plants (Pkaseolus vulgaris L. cv. Processor) grown with a 12 hour dark period and natural or artificial light conditions during the day. The water potentials were measured at the end of a dark period and during the light period. Measurements taken at the end of the dark period indicated normal potential gradients within the soil/plant system (leaf < shoot < root < soil), when the matric potential of soil water was relatively high (above ?0.02 bar), and the gradients then also remained normal during the day (natural light). When the soil water potential was ?1 bar or lower in the morning, however, the root xylem water potential was higher than the soil water potential; at very low soil water potentials (< ?4 bar) it remained higher during most of the day. In this case also leaf and shoot xylem water potentials were higher than the soil water potential in the early morning, although decreasing rapidly in daylight. Under artificial light, both leaf and root water potentials were higher than the soil water potential throughout the whole diurnal cycle when the latter potential was below ?4 bar. From measurements of stomatal diffusion resistance, transpiration, relative water content of leaves and of changes in the matric potential of soil water, it was concluded that when the matric potential of soil water was low, water could be taken up by the plant against a water potential gradient. Because leaf xylem water potential was always lower than root xylem water potential, the mechanism involved in the inversion of water potential gradient must be localized in the roots, and probably related to ion uptake. Symbols and abbreviations used in the text: Ψ: Plant water potential (thermocouple psychrometer); Ψx: Xylem water potential (pressure chamber); Ψs: Osmotic potential of xylem sap; Ψm: Matric potential of soil water; RWC: Relative water content.