The Translocation of Sulphonamides in Higher Plants: I. UPTAKE AND TRANSLOCATION IN BROAD BEANS

The uptake and translocation of sulphanilamide, sulphacetamide,sulphaguani-dine, sulphapyridine, sulphadiazine, sulphathiazole,and 4:4-diaminodiphenyl-sulphone by broad bean plants growingin water culture has been studied. After varying times of exposureto the compounds at 100/µg./ml., total sulphonamide presentin the roots, stems, and leaves was determined in acid-hydrolysedmacerates by diazotization and coupling of the primary aminogroup. These compounds were identified in the leaves of treatedplants by paper chromatography. Accumulation of sulphonamide in the roots appears to be relatedsimply to time, and the concentration of sulphonamide may, eventually,be far higher than that in the treating solution. Movement fromthe roots to the stems and leaves depends on transpiration.Sulphanilamide and the sulphone passed rapidly into the leaves;sulphacetamide, sulphapyridine, sulphadiazine, and sulphathiazolemoved less rapidly. There was, however, a marked accumulationof sulphacetamide, sulphapyridine, sulphadiazine, sulphathiazole,and the sulphone in the roots. Sulphaguanidine was poorly absorbedfrom the treating solution.     

Adventitious Shoot Regeneration in Carnation (Dianthus caryophyllus) from Axillary Bud Explants

Adventitious shoots were regenerated from axillary bud explantsof 15 carnation cultivars. The use of leaf and stem explantswas not successful, largely due to explant senescence in thepresence of benzyladenine, kinetin and, to a lesser extent,zeatin. For axillary bud explants, a suitable optimum adventitiousregeneration medium contained Murashige and Skoog basal mediumsolidified with Gelrite and supplemented with 15 µm benzyladenineand 0.5 µM a-napthaleneacetic acid. Adventitious primordiaarose from the cut basal end of bud explants erupting as individualshoots after 2–3 weeks incubation. The axillary bud sizeand the time between subcultures of source material influencedthe production of adventitious shoots. Transfer of regeneratedshoots onto a medium solidified with agar minimized visiblesigns of vitrification. Regenerated shoots could be easily rooted,transferred to glasshouse conditions and grown to flowering. Vitrification, tissue culture, cut flowers, Dianthus caryophyllus L., carnation, cytokinins, explant     

Node-derived cultures with high-morphogenic competence in barley and wheat

A successful regeneration system is presented for elite cultivars in barley and wheat based on nodes. Nodal explants were excised from in vitro and ex vitro grown plants. A combination of 8.28 μM 4-amino-3,5,6-trichloropicolinic acid and 4.54 μM to 22.71 μm thidiazuron (TDZ) used in MS-based medium containing 60 g l⁻¹ maltose favoured induction of clumps of multiple shoots/buds with or without callus formation in the primary cultures. Within 8–10 weeks upon further subcultures, the proliferation into callus with rapid and continuously forming adventitious buds containing clusters of meristemoids, termed meristematic bulk tissue (MBT) was obtained. Lowering the levels of growth regulators resulted in redifferentiation of shoots, which elongated, rooted, developed into morphologically normal plants and set seeds normally. With a frequency ranging between 37 and 82% the nodes raised from in vitro grown plants were proliferated into MBT independent of TDZ concentration, cultivar and species. The average number of shoots per responding node in different cultivars was 7–15 in barley and 1–6 in wheat after 12–14 weeks. Nodes from greenhouse grown plants mainly responded for callus formation with poor development of MBT.     

Absorption and Distribution of Copper in Plants with Sufficient or Deficient Supplies

Wheat, red clover and ryegrass were grown in flowing solutionculture with sufficient (+ Cu) and deficient (–Cu) suppliesof copper. The rates of Cu absorption (µg g^–1 dryroot day^–1) did not differ greatly between species ineither treatment. Wheat plants, when transferred from the –Cu to the +Cu treatment, absorbed Cu at a much slower rate thanthose which had remained throughout in the + Cu treatment. Inall plants considerable proportions of the absorbed Cu wereretained in the roots, even when the plants were Cu-deficient,and the concentration in roots usually exceeded that in anypart of the shoots in both treatments. Transferring wheat plantsfrom the +Cu to the –Cu treatment decreased the concentrationin all plant parts except old leaves; similarly, transferringfrom the –Cu to +Cu treatment increased the concentrationin all parts of the shoots, execept old leaves, and in the roots. Lolium perenne, Trifolium pratense, Triticum aestivum, ryegrass, red clover, wheat, absorption, copper, flowing solution culture     

Effect of growth regulators on rapid micropropagation and psoralen production in <Emphasis Type="Italic">Psoralea corylifolia</Emphasis> L.

A rapid and efficient micropropagation system was developed for Psoralea corylifolia, an endangered, valuable medicinal plant. Multiple shoot buds were obtained in half-strength liquid Phillips–Collins (L2) medium supplemented with 5 μM benzylaminopurine (BA) and 5 μM thidiazuron (TDZ) from apical bud explants of 1-week-old cultures. The shoot buds were subcultured on enriched solid L2 medium supplemented with different concentrations and combinations of BA, kinetin (KIN), 2-isopentenyladenine (2iP), TDZ, bavistin (BVN) and trimethoprim (TMP). Enriched solid L2 medium supplemented with 2 μM BA, 1 μM TDZ and 100 mg l⁻¹ BVN were more effective in producing greater number of shoots per explant (85.2 ± 0.9 shoots/explant) after 4 weeks of culture. The regenerated shoots (40–50 mm in length) rooted and accompanied by hardening upon transfer to 50 μM indole-3-butyric acid (IBA) for 15 min and followed by planting in sterile soil mixture and vermiculate (3:1 v/v), with 50 ml of one-eight strength L2 basal salt solution devoid of sucrose and inositol, supplemented with 5 μM IBA and 100 mg l⁻¹ BVN. The plants achieved 100% rooting with hardening. Subsequently the rooted plants were successfully established in the field. The survival percentage differed with seasonal variations. The concentration of psoralen was evaluated in different tissues of ex vitro and in vivo grown plants by high-performance liquid chromatography (HPLC). Psoralen content was increased in leaves (2.97%), roots (2.38%), stems (5.40%) and seeds (1.63%) of ex vitro plants than the in vivo plants. This system facilitates for commercial and rapid propagation of P. corylifolia for conservation strategies and phytomedicine production.     

Quantitative Aspects of Leaf Acid Phosphatase Activity and the Phosphorus Status of Tomato Plants

The relation between tomato leaf acid phosphatase activity andleaf tissue P content has been examined, and a study made ofthe effects of leaf development, variation in nitrogen supply,and variation in the growing medium on this relationship. Tomatoplants were grown in sand and given various concentrations ofphosphate. Plants were also grown for an initial period in peatcontaining an adequate level of phosphate, then transferredto peat to which was added 0 or 2.3 kg superphosphate m^–3and supplied with either 50 of 300 µg N ml^–1. Expressed on a unit tissue f. wt basis, acid phosphatase activityin the control plants in sand (given 41 µg P ml^minus;1)was highest in extracts from the expanding leaves and decreasedwith leaf maturity. However, when given a reduced supply ofphosphate, the enzyme activity in the more mature leaves wasequal to, or greater than, that in the expanding leaves. Thephosphatase activity increased first in the young, fully-expandedleaves and in the mature leaves (with 4.1 µg P ml^–1),but did not increase in the expanding leaves until the supplywas restricted to 2.1 µg P ml^–1. On closer examination,the increase in enzyme activity appeared to be associated withthe P level in the leaf tissues, the activity increasing whenthe level fell below about 0.25 per cent (g P per 100 g drywt tissue). The same relation was found with the plants grownin peat, and was independent of the concentration of nitrogensupplied to the plants. The fully expanded leaves showed the best enzyme response whenthe phosphate supply was restricted and the activity reflectedclosely the local levels of tissue P. The assay of the enzymein unpurified leaf extracts is simple and rapid, and could beused in a test to detect P-deficiency in tomato plants. Lycopersicon esculentum L, tomato, acid phosphatase activity, phosphorus status     

Morphological and physiological responses of proliferating shoots of teak to temporary immersion and BA treatments

Shoot-tips, collected from greenhouse-grown plants of Tectona grandis L. (teak), were incubated on a semi-solid Murashige and Skoog (MS) medium with 2% (w/v) sucrose, and supplemented with 4.44 μM 6-benzyladenine (BA). These were then transferred to a temporary immersion system (TIS) using liquid MS medium supplemented with 0 (CK-free medium), 2.22, 4.44, 6.66 μM BA. High mean numbers of shoots per explant were obtained when explants were grown on medium containing either 4.44 or 6.66 μM BA and yielding 7.7 and 10.3 normal shoots (NS)/explant, respectively. Moreover, these high BA levels contributed to lower accumulation of phenolic compounds and deposition of lignin in vascular cells of the teak shoots following histochemical analysis. Morphological analysis of proliferating shoots by scanning microscopy revealed that leaves of shoots incubated on either CK-free medium, 2.22, or 4.44 μM BA had elliptical stomata; whereas, stomata of leaves of shoots grown on medium containing 6.66 μM BA were primarily ring-shaped, raised, and open. Moreover, misshapen stomata with broken epidermal layers of guard cells, typical of hyperhydric leaves, were also observed. When shoots were rooted ex vitro by dipping in 492.1 μM indole-3-butyric acid (IBA) for 2 min, the frequency of rooting of shoots previously grown on either CK-free medium or 2.22 μM BA (96.7 and 91.7%, respectively) was higher than that of shoots grown on semi-solid medium (73%). Shoots from both TIS treatments developed good root systems, and all plantlets (100%) survived transfer to soil mix and acclimatization in the greenhouse. Plantlets established from shoots grown on 6.66 μM BA showed the lowest frequency of survival (60%). After 3 months, plants were transferred to field conditions.     

Some effects of benomyl and carbendazim on Aphis fabae and Acyrthosiphon pisum on field bean (Vicia faba)

Field bean plants were treated with benomyl in a glasshouse, then nymphs of Aphis fabae and Acyrthosiphon pisum were caged on the second pinnate leaf. Soil drenches at concentrations of 150 and 75 μg benomyl/ml or above increased mortality of A. fabae and A. pisum respectively; 250 μg a.i./ml increased mortality and decreased progeny production of alate A. fabae. The effect on mortality persisted for at least 16 days after treatment. Foliar sprays increased mortality at concentrations of 75 μg a.i./ml and above (A. fabae). Field populations of A. pisum were reduced when bean plants were drenched or sprayed at a concentration of 250 μg a.i./ml and A. fabae populations were reduced by drenches but not by foliar sprays. A commercial formulation of carbendazim (Bavistin) increased aphid mortality whereas the formulation medium did not. Under the experimental conditions, benomyl affected the distribution of both species on young bean plants but did not induce a repellent effect; aphids preferred untreated leaves. Mortality and preference tests, and a field experiment, indicated that A. pisum was affected more than A. fabae.     

Nitrosomethylurea induced streptomycin resistance in Lycopersicon esculentum Mill

High frequency of streptomycin resistant variants of Lycopersicon esculentum were isolated on selective shoot regeneration medium supplemented with IAA (0.5 mg/L), zeatin (1.5 mg/L) and streptomycin sulphate (500 mg/L). Nonmutagenized (controls) and NMU treated cotyledons were placed on shoot regeneration medium supplemented with antibiotic streptomycin. Resistant shoots appeared at a high frequency in mutagenized cotyledons, whereas in controls morphogenesis was suppressed, accompanied by bleaching. Shoot regeneration occurred from the nodular tissues developed at the cut ends of cotyledons. Resistant shoots developed into complete plantlets on rooting medium containing selective concentration of antibiotic. Stability of streptomycin resistance was confirmed by leaf assay and reciprocal crosses between streptomycin-resistant and sensitive plants.     

The Effects of Nitrogen Supply on the Absorption and Distribution of Copper in Red Clover (Trifolium pratense L.) Grown in Flowing Solution Culture with a Low, Maintained Concentration of Copper

The absorption and distribution of Cu in red clover (Trifoliumpratense L.) were measured in plants grown in flowing solutionculture with Cu maintained throughout at 0.5 µg 1^–1and N supplied either as nitrate or through symbiotic fixation.Although there was a decrease in Cu absorption, both with time,and with a depleted nitrate supply, it increased to its formerrate when nitrate was adjusted to 10 mg N 1^–1 after aperiod of depletion. Differences in absorption between plantsdependent upon fixation and those supplied with nitrate wererelated to the slower initial growth of the plants fixing N.Considerable proportions (> 30 per cent) of the absorbedCu were retained by the roots. At the final harvest, and withthe exception of plants grown with nitrate adjusted to 0.1 mgN 1^–1 after a period of depletion, the proportion of theCu retained was related to the concentration of N in the roots.The different N treatments produced differences in Cu concentrationin the shoots, and the effects were greater in the youngestfully expanded leaves than in older leaves. Trifolium pratense L., red clover, absorption, copper, flowing solution culture, nitrogen     

Thidiazuron-induced shoot organogenesis and production of hepatoprotective lignan phyllanthin and hypophyllanthin in <Emphasis Type="Italic">Phyllanthus amarus</Emphasis>

Callus cultures from nodal and leaf explants of Phyllanthus amarus were established on Murashige and Skoog (MS) medium with various combinations of auxins and cytokinins. The leaf-derived callus induced on 2.26 μM 2,4-dichlorophenoxyacetic acid (2, 4-D) + 2.32 μM Kinetin (Kin) upon transfer to medium containing thidiazuron (TDZ) exhibited higher shoot regeneration (32.4 ± 1.3 shoots per culture). Four-week-old shoots rooted readily on 1.5 μM Indol acetic acid (IAA)-containing medium and were successfully acclimatized with 98% survival. The lignans, Phyllanthin (PH) and Hypohyllanthin (HPH), of leaf extracts from naturally grown plants were identified by using TLC, HPLC and H1-NMR. The PH and HPH production in the regenerated shoots was compared to their production in callus cultures, plants under field conditions and in naturally grown plants. The regenerated shoots on MS + 2.27 μM TDZ produced about two times higher PH and HPH than the leaves of naturally grown plant. The present study provides a useful system for further studies on in vitro morphogenesis, elicitor-assisted production of PH and HPH and A. rhizogenes-mediated genetic transformation in Phyllanthus amarus.     

The Distribution of P32 in the Plum and its Mutagenic Possibilities

The occurrence and utility of bud sports in fruit-trees arediscussed and the merits of various mutagenic agents compared.P³² is suggested as a suitable mutagen in fruit-tree mutationstudies and experiments are described on the uptake and distributionof P³² in plums. The uptake in ten 3-year-old trees culturedin sand appeared to be of the order of 10 to 30 per cent. increasingwith the vigour of the tree. The P³² was distributed mainlyin the shoots, the average initial concentration being 1·5µc./g., and in their buds, average initial concentration3µc./g. The latter figure corresponds to a dose to thebuds of the order of 2,000 r., and although this is a dosagelevel at which mutagenic effects are likely to occur, therewas little sign of macroscopic damage. The method thereforeappears to be a suitable one for fruit-trees.     

Micropropagation of Hemidesmus indicus for cultivation and production of 2-hydroxy 4-methoxy benzaldehyde

Caulogenic responses of various explant types from 12-month-old plants of Hemidesmus indicus were tested. Second and third visible nodes (0.5 cm) from the apex and root segments (0.5 cm) were the most and least regenerative respectively, with the formation of 9.37 and 2.6 shoots in 4 weeks on half strength MS medium supplemented with 2.22 μM BA and 1.07 μM NAA and 4.44 μM BA and 2.69 μM NAA respectively. Caulogenic ability of the nodes decreased with increasing maturity. Shoot buds initiated upon the young nodes on day 10 developed into 7.2 cm long shoots within 4 weeks thereby making a shoot elongation phase unnecessary. Nodal explants of the in vitro raised shoots subcultured in the same medium produced 9.32 shoots of 7.1 cm length in 3–4 weeks, similar to those of the mature plant-derived nodes. Multiplication through subculture of the nodes up to 25 passages of 4 weeks each was achieved without decline. Shoot cultures were rooted in quarter salt strength MS medium containing 9.8 μM IBA and the rooted plants were hardened for establishment in pots at 96% rate. Four months after establishment, the micropropagated plants were stable and showed uniform morphological and growth characteristic. After 12 months of cultivation in the field, on an average micropropagated plant consisted of 4–5 shoots, 5–8 branches per shoot and increased root biomass (13.5 g) compared to the poor growth (single shoot and 2–3 branches) and root production (4.6 g) values obtained with plants raised from conventional rooted stem cuttings. The concentration of the root specific compound, 2-hydroxy 4-methoxy benzaldehyde per plant was 2–3 fold higher in micropropagated plants though on unit dry root biomass (0.12% per g dry wt) basis it remained the same between two sources of plants. This revised version was published online in June 2006 with corrections to the Cover Date.     

Effect of NaCl salinity on growth,pigment and mineral element contents,and gas exchange of broad bean and pea plants

Increasing salinity of growth medium induced a reduction in growth and transpiration rate. The concentrations of chlorophylls and carotenoids were increased in most cases in broad bean leaves while in pea plants they remained more or less unchanged with the rise of salinization up to 80mM NaCl. Thereabove a significant decrease in these contents was observed. A stimulation of the net photosynthetic rate of pea was observed at the lowest levels of NaCl but at the highest levels inhibitory effect was recorded. In broad bean all salinization levels inhibited photosynthetic activity, but dark respiration of both plant species was stimulated. The content of Na⁺ in the roots and shoots of both species increased at increasing salinity. In broad bean, Ca²⁺ concentration in shoots and K⁺ and Ca²⁺ contents of roots increased at increasing salinization, while in pea plants, the content of K⁺ and Ca²⁺ was almost unaffected by salinity. Salinity induced an increase in the content of these ions in pea roots. Mg²⁺ content in shoots and roots of both broad bean and pea decreased at increasing salinity except in roots of pea, where it was generally increased.     

Effects of Concentration and Time of Exposure on the Phytotoxicity of Linuron

When seedlings of lettuce and turnip were grown in nutrientsolutions containing different concentrations of linuron, theconcentration in the shoot at the time when toxicity symptomsappeared was related to the solution concentration. With lettuce,for example, symptoms were recorded after 7 d at 0.15 µg/mland the shoot concentration was 2.7 µg/g fresh wt. At0.06 µg/ml, symptoms appeared after 10 d and the shootconcentration was then 1.1 µg/g fresh wt. If grown fordifferent periods in solutions containing linuron and then transferredto fresh nutrient solutions containing no herbicide, turnipor lettuce seedlings which had accumulated 0.7–0.8 µglinuron/g fresh wt developed toxicity symptoms 4 to 6 d later.Seedlings were also treated with linuron after they had grownfor different periods in control nutrient solutions. The shootconcentrations attained before toxicity symptoms appeared werehigher in those seedlings which were larger when herbicide treatmentbegan. These results show that the herbicide concentration insolution, time of exposure, and age of seedling are interrelatedin determining linuron phytotoxicity.     

The Occurrence of Translocated Antibiotics in Expressed, Plant Sap

The details of a convenient laboratory press are presented anda procedure by which plant sap is readily obtained is described.The pressing procedure has been shown to release 53–74per cent. of the total plant water as expressed sap. Preliminary observations on the uptake and translocation ofantibiotics by higher plants obtained by examining expressedsap are described. It is shown that the assay of expressed sapprovides a measure of the griseofulvin and chloramphenicol concentrationin leaves of plants grown in solutions of these antibioticsthat does not differ significantly from the value obtained bythe assay of water extracts. Extraction of leaves from plants grown in griseofulvin solutionswith organic solvents demonstrates a much greater antibioticcontent than is indicated by the assay of expressed sap. Toexplain this difference a ‘free’ antibiotic fraction,obtainable in expressed sap or water extracts, and a ‘bound’fraction recovered from the leaf only by organic solvent extractionare postulated.     

Copper Nutrition of Sugarbeet

Sugarbeet (Beta vulgaris L.) plants were grown in refined sandat graded levels of copper ranging from acute deficiency (0.000325µg Cu cm^–3) to excess (65 µg Cu cm^–3).Visible effects of copper deficiency appeared up to 0-00065µg Cu cm^–3and depression in growth up to 00065µCucm^–3. Copper deficiency decreased the concentrations ofDNA and RNA and the activities of polyphenol oxidase, cytochrome-coxidase, catalase and aldolase; and it increased the activitiesof peroxidase, ribonuclease and acid phosphatase in leaves.The maximum sucrose concentration in roots was obtained at 0-65µCucm^–3 Twenty four h after infiltration of a solution of 65µCucm^–3into copper deficient leaves, the activities of cytochrome-coxidase and peroxidase had increased even in the presence ofcycloheximide but that of polyphenol oxidase increased onlyin the absence of this inhibitor. Key words: Beta vulgaris, Cu deficiency: Enzymes     

Root Nodules of Phaseolus: Efficient Scavengers of Molybdenum for N2-fixation

Molybdenum is thought to be of intermediate mobility in thephloem and this may limit N₂-fixation by restricting the supplyof molybdenum to the nodules of legumes. When no molybdenumwas supplied to Phaseolus vulgaris nodule Mo content increasedat the expense of shoots and roots even when seed molybdenumcontent was large. Nodules sampled from plants receiving molybdenumin the feeding solution had a concentration of 21–78 µgMo g^-1. In the absence of molybdenum and with deficient seedcontent (<0.5 µg Mo seed^-1) nodule concentrations rangedfrom 1.9 to 3.5 fig Mo g^-1 in a small seeded genotype and 8.7±0.48µg Mo g^-1 in a large seeded genotype. N₂-fixation in theseplants was not impaired except in one instance where noduleconcentration was 1.9 µg Mo g^-1. Evidence that molybdenumis effectively translocated from leaves to roots and noduleswas obtained using foliar treatments. All of the 3.3 µgMo applied to a leaf was recovered in the plant after 10 d.Mo content of the nodules increased by 81%, whilst Mo contentof shoots increased by 56%. Root Mo content was eight timesgreater than that in plants not receiving a foliar treatmentof molybdenum. We conclude that when molybdenum was scarce inthe plant it was mobile and was translocated from roots andshoots to the nodules. As a result, nodule concentrations andcontents of molybdenum were frequently maintained at amountssufficient for N₂-fixation even when the plant was entirelydependent on a small seed reserve of molybdenum.     

Essential oils enhanced by ultra-high carbon dioxide levels from Lamiaceae species grown in vitro and in vivo

The growth (fresh weight), morphogenesis (leaves, roots and shoots) and essential oil composition of mint (Mentha sp. L.) and thyme (Thymus vulgaris L.) plants were determined after 8 weeks under 350, 1,500, 3,000, 10,000 and 30,000 µmol mol^-1 CO₂. Plants were grown in vitro on basal medium (BM) consisting of Murashige and Skoog salts and 0.8% agar that contained either 0 or 3% sucrose under a 16-h (day)/8-h (night) photoperiod at a light intensity of 180 µmol s^-1 m^-2 or in soil in a greenhouse under conditions of natural sunlight. Ultra-high CO₂ levels (i.e. ́,000 µmol mol^-1 CO₂) substantially increased fresh weights, leaves, shoots and roots for all plants compared to plants grown under ambient air (350 µmol mol^-1 CO₂) both in vivo and in vitro. For both species, 10,000 µmol mol^-1 CO₂ was the optimum concentration to obtain the largest growth and morphogenesis responses under in vitro conditions, while the 3,000- to 10,000-µmol mol^-1 CO₂ range provided the largest yields for soil-grown plants. Essential oil composition (i.e. monoterpenes, piperitonone oxide and limonene from mint and aromatic phenol and thymol from thyme) from the shoot portion of plants grown at all CO₂ levels was analyzed in CH₂Cl₂ extracts via gas chromatography. Higher levels of secondary compounds occurred in vitro when cultures were grown under ultra-high CO₂ levels than in ambient air. The concentration of thymol, a major secondary compound in thyme plants grown on BM containing sucrose, was 317-fold higher at 10,000 µmol mol^-1 CO₂ than in plants grown under ambient air conditions with the same BM. The levels of secondary compound in in-vitro-grown plantlets exposed to ultra-high CO₂ concentrations exceeded those occurring in plants grown in the greenhouse under the same CO₂ levels. Substantially higher levels of secondary compound occurred in plants under ultra-high CO₂ levels on BM containing sucrose than on BM lacking sucrose or in soil. Thymol levels in thyme plants grown on BM containing sucrose were 3.9-fold higher at 10,000 µmol mol^-1 CO₂ than in shoots grown on BM without sucrose under the same CO₂ levels. High positive correlations occurred between thymol concentrations and CO₂ levels, fresh weights, shoots, roots and leaves when thyme shoots were grown on BM with sucrose. High positive correlations for thyme shoots grown on BM without sucrose only occurred between thymol concentrations and CO₂ levels, fresh weights, shoots and leaves. No positive correlations between thymol concentrations and CO₂ levels or any growth or morphogenesis responses occurred for thyme shoots when grown in soil.     

The Uptake and Distribution of Copper in Some Forage Grasses as Affected by Nitrate-nitrogen Supply in Flowing Solution Culture

The effect of changes in nitrate-nitrogen supply on the absorptionand distribution of copper was examined in grasses grown inflowing solution culture with a maintained concentration ofcopper. Absorption by roots (µg Cu g^–1 dry root)decreased markedly when nitrogen had been depleted or was maintainedat 0.1 mg l^–1 N, but there was an immediate increase whennitrogen was maintained at 1.0 or 10.0 mg l^–1. There werealso large increases in the concentration of copper in the shootsof plants grown with 1.0 and 10.0 mg 1^–1 N. The rootsof plants grown with 0.1 or 1.0 mg 1^–1 N retained similarproportions of uptake, but a lower proportion was retained whenthe plants were grown with 10.0 mg 1^–1. Although a lowerproportion of the copper was associated with cell walls in theplants grown at 10.0 mg 1^–1 N this was the result of alower content of cell walls rather than an effect on copperitself. In a longer-term experiment in conventional solutionculture with a range of nitrogen concentration, the concentrationof copper in shoots was largely determined by shoot growth. Dactylis glomerata, Festuca arundinacea, Lolium perenne, cell walls, copper absorption, copper distribution, flowing solution culture, nitrate-nitrogen