钙离子对盐胁迫小麦幼苗氮代谢的影响

为探讨增强小麦抗盐能力的调控途径,以普通小麦豫麦34为材料,研究了Ca2+对盐胁迫下小麦幼苗氮代谢及生长的影响.采用全营养液培养小麦幼苗至第一片叶完全展开,更换无钙营养液,并开始不同处理.处理分别为低盐胁迫(150 mmol · L-1 NaCl)、低盐胁迫+4 mmol · L-1 Ca2+、高盐胁迫(300 mmol · L-1 NaCl)、高盐胁迫+4mmol · L-1 Ca2+,以无NaCl胁迫的小麦为对照.5 d后取样,测定了氮同化酶活性、代谢物含量、积累量及幼苗生长状况.结果表明,Ca2+明显缓解了低盐胁迫对小麦幼苗的生长抑制,表现在鲜重、叶绿素及可溶性蛋白含量的增加,而对高盐胁迫下小麦幼苗的生长无明显改善效果;Ca2+改善了低盐胁迫下小麦幼苗的氮营养状况,表现在氮积累量的增加,这一效应主要是通过硝酸还原酶(NR)、谷氨酰胺合成酶(GS)以及异柠檬酸脱氢酶(NADP-ICDH)活性的增强而实现的.Ca2+未能改善高盐胁迫下小麦幼苗氮营养状况的主要限制因子在于NADP-ICDH活性未明显增加.     

Ribulose bisphosphate carboxylase, protein and nitrogen in Scots pine seedlings cultivated at different nutrient levels

Seedlings of Scots pine (Pinus sylvestris L.) of a northern provenance were cultivated in nutrient solution for 10 weeks in a climate chamber. The nutrient solution (renewed by solution exchange) contained 2.5, 10 or 50 mg N I^?1. All other essential elements were added in optimal proportion to the nitrogen. Seedlings cultivated at 10 and 50 mg N I^?1 were similar with respect to all characteristics studied. Seedlings cultivated at 2.5 mg N I^?1 showed a lower growth rate, especially for the shoot, and an altered morphology, with high root:shoot ratios and long, slender roots. The nitrogen concentrations in shoot and needles as well as in whole seedlings were not significantly affected by the nitrogen supply, while the nitrogen concentrations in the roots were somewhat lower at 2.5 mg N I^?1. Ribulose bisphosphate carboxylase (EC 4.1.1.39) activity and the concentrations of carboxylase, total and soluble protein and of chlorophyll in the needles were consistently much lower for seedlings cultivated at 2.5 mg N I^?1, than for seedlings grown at higher nutrient levels. A close correlation was observed between activity and concentration of the carboxylase (r=0.95). Carboxylase activity and protein were more sensitive to a low nutrient supply than was chlorophyll. The data show how activity and concentration of ribulose bisphosphate carboxylase and the concentrations of soluble and total protein and of chlorophyll in needles of pine seedlings can be negatively affected by the nutrient supply, also when the nitrogen concentrations in the needles are close to those observed at optimal nutrient supply. It is suggested that pine seedlings store assimilated non-protein nitrogen in the needles when protein synthesis is under restraint. The nitrogen concentration in needles and seedlings could not be used as a measure of the physiological state of the seedlings.     

Relationships between shoot to root ratio, growth and leaf soluble protein concentration of Pisum sativum, Phaseolus vulgaris and Triticum aestivum under different nutrient deficiencies

Relations between shoot to root dry weight ratio (S : R), total plant dry weight (DW), shoot and plant N concentration and leaf soluble protein concentration were examined for pea ( Pisum sativum L.), common bean ( Phaseolus vulgaris L.) and wheat ( Triticum aestivum L.) under different nutrient deficiencies. A regression model incorporating leaf soluble protein concentration and plant DW could explain greater than 80% of the variation in S : R within and between treatments for pea supplied different concentrations of NO₃^– or NH₄⁺ in solid substrate; pea and bean supplied different concentrations of N, P, K and Mg in liquid culture; and wheat supplied different concentrations of N, P, K, Mg, Ca and S in liquid culture. Addition of shoot or plant N concentration to the model explained little more of the variation in S : R. It is concluded that results are consistent with the proposal that macronutrient effects on S : R are primarily mediated through their effects on protein synthesis and growth.     

Sulphate uptake and xylem loading of young pea (Pisum sativum L.) seedlings

Sulphate uptake and xylem loading was analysed in young pea (Pisum sativum) seedlings. The rate of sulphate uptake into intact 8-days-old pea seedlings (determined by a 1 h exposure to radiolabelled sulphate in the nutrient solution) was 585 nmol sulphate g^–1 root fresh weight h^–1. When the cotyledons were removed on day 6 the 8-days-old seedlings took up only 7% of the controls. Interruption of the phloem transport by steam girdling of the stem or the root (1 h before incubation with radiolabelled sulphate) diminished sulphate uptake by approximately 50%. The addition of sucrose to the nutrient solution during incubation did not restore sulphate uptake rates indicating that the decrease was not due to a lack of energy. Apparently, a signal from the shoot and/or the cotyledons is necessary to stimulate sulphate uptake into the roots of pea seedlings. Glutathione fed to the roots for 3 h prior to incubation with radiolabelled sulphate diminished sulphate uptake by approximately 50%. The relative proportion of the sulphate taken up that was loaded into the xylem remained unchanged (between 7 and 9% of total uptake), even when the stem was girdled above the cotyledons or when the seedlings were pre-exposed to glutathione. Only removal of the cotyledons or girdling of the root below the cotyledons increased the proportion of sulphate loaded into the xylem to 13–15% of total uptake upon exposure to glutathione. Apparently, a signal from the cotyledons represses xylem loading to some extent.     

Effects of humic acid-herbicide interactions on the growth of Pisum sativum in nutrient solution

Slight increases in root length and dry matter production were measured in roots and shoots of Pisum sativum seedlings, when germinated seeds were grown for eight days in a controlled environment chamber, on Nitch nutrient solution to which 10 mg L^-1 soil humic acid (HA) had been added. A concentration of 100 mg L^-1 of HA produced a small reduction in dry matter production of shoots. In the presence of herbicides, 10 mg L^-1 cycluron or 100 mg L^-1 prometone, root elongation and shoot growth was reduced by varying degrees with respect to the control. Nutrient solutions containing 100 mg L^-1 cycluron, 10 or 100 mg L^-1 alachlor, or as little as 0.1 mg L^-1 of 2,4-D resulted in an almost complete suppression of the growth of pea seedlings. The addition of 10 or 100 mg L^-1 of HA to nutrient solution containing the herbicide was found to be either ineffective in enhancing growth, or even further reduced growth, compared to samples grown in the presence of the herbicide alone. The results of this preliminary study suggest that the generally accepted view that humic substances exert a positive effect on plant growth may not occur when humic substances interact with herbicides.     

Nitrogen Assimilation and Protein Synthesis in Wheat Seedlings as Affected by Mineral Nutrition. II. Micronutrients

Activity of nitrate reductase from Triticum aestivum L. seedlings was decreased by deficiencies of molybdenum, zinc, and chlorine. Nitrate accumulated in molybdenum-deficient seedlings, declined in zinc-deficient seedlings, and was unaffected by the other micronutrient treatments. Glutamic acid dehydrogenase activity was decreased by deficiency of molybdenum, the only nutrient that affected the enzyme. Glutamine synthetase activity was decreased only by copper deficiency, and glutamic-oxaloacetic transaminase was not affected by any micronutrient deficiencies. Incorporation of ¹⁴C-leucine into protein by wheat seedlings was increased by molybdenum deficiency, apparently because of decreased inhibition from endogenous amino acids, and was decreased by copper deficiency. Protein content was not affected significantly by the micronutrient treatments.     

Physiological Investigations on the Banana Plant: Factors which Affect the Nitrogen Compounds of the Leaves

Banana plants (Musa acuminate cv. Gros Michel) have been grownin sand culture, irrigated with a full nutrient solution andwith solutions deficient in each of several nutrient elements.The growth was continued long enough to establish the conditionscharacteristic of these nutrient treatments. Extracts of leaves,sampled according to their position on the axis, have been madefrom plants grown in full nutrient solution; these extractshave been examined by chromatographic methods to detect anddetermine the various nitrogen compounds they contain (A) Therelative proportions of the soluble nitrogen compounds of thebanana leaf are quite different from those of the fruit and,in response to the deficiency of specified mineral nutrients,both the total amount and the relative composition of the solublenitrogen fraction are greatly affected. The results are interpretedin terms of the more active accumulation of soluble compoundsin young leaves and the maintenance of a low amide (glutamine)level in leaves engaged in protein synthesis. The accumulationof soluble nitrogen compounds when growth and synthesis arearrested, and the relative accumulation of a specified numberof nitrogenous substances, due to the lack of a nutrient element,indicates that metabolic blocks in reaction pathways occur.Examples of these effects are given and are related to nutritionaldeficiency (B).     

Cycling of amino-nitrogen between shoots and roots in wheat seedlings

Summary One part of a split root system of wheat seedlings received full nutrient solution with¹⁵N-nitrate, the other received an identical solution with unlabelled nitrate. Appearance of labelled amino compounds was measured in the xylem sap exuding from roots not supplied directly with¹⁵N-nitrate after removal of the¹⁵N-nitrate-fed roots. This material indicates cycling of nitrogen from the shoots and through the roots. About 60 per cent of the nitrogen in the xylem appears to be cycling in this way.     

Differential reactions of wheat and pea genotypes to root inoculation with growth-affecting rhizosphere bacteria

Spring wheat (Triticum aestivum L.) and pea (Pisum spp.) genotypes were tested for reaction to root inoculation with rhizosphere bacteria affecting plant growth. Plant response was studied in greenhouse experiments after treatment of seedlings with bacteria suspended in nutrient broth. Significant genotype variation was found in both wheat and pea in terms of shoot dry weight and severity of bacteria-induced leaf symptoms. For most bacterial isolates tested, there was good correlation between ratings of leaf symptoms 7 to 14 days after inoculation and growth inhibition measured after four weeks. Interactions between isolates and plant genotypes were significant in both wheat and pea (P=0.0024 and 0.0001, respectively), but genotypes with sensitivity or tolerance to most isolates could be distinguished. In an outdoor pot experiment, two of the bacterial isolates caused delayed plant development and differential decreases in grain yield of wheat genotypes. The hypothesis that the reaction of wheat genotypes to the tested becteria was related to their influence on bacterial establishment in the rhizosphere could not be substantiated.     

Action of volatile substances liberated from couch grass

A study was made of the action of volatile substances liberated from the rhizome of couch grass on wheat seedlings. The experiments were made in a closed atmosphere in glass vessels with continual removal of expired CO₂ and the addition of O₂. Volatile substances liberated from couch grass produced numerous morphological and physiological changes in wheat seedlings. They caused retarding of the growth of overground parts and roots, the excessive formation of root hairs, curling of the roots and bending of the coleoptiles. The respiratory rate was higher in the leaves and roots of the experimental wheat seedlings than in the controls. The changes observed were similar to those produced by hydrocarbons of the ethylene series, which are well documented in the literature.     

Dependence of radiostrontium uptake by pea and lupin on the content of calcium in the nutrient solution

In lupin (Lupinus albus L.) and pea (Pisum sativum L., cv. Raman) it was shown that the uptake of⁸⁹Sr from Knop's nutrient solution is significantly increased from a solution with decreased calcium content (one tenth of the normal content) and is slightly decreased from a solution with higher calcium content (150% of the normal content). The calciphile pea absorbs approximately 50% more calcium than the calciphobe lupin, and accordingly 50% radiostrontium less. The pea plant more strongly blocks the translocation of radiostrontium from roots to overground parts, as is proved by the higher discrimination factor of pea (i.e. by the ratio of specific activities of mCi⁸⁹ Sr/g Ca of roots to overground parts). The presence of chlorine in the nutrient solution decreases the content of radiostrontium per gram of dry matter, both in pea and lupin. Radiostrontium is absorbed quickly by both species of plants and is autoradiographically detectable as early as 2 hours after the introduction of radiostrontium to the nutrient solution. *** DIRECT SUPPORT *** A01GP049 00004     

Induction of the Root Cell Plasma Membrane Ferric Reductase (An Exclusive Role for Fe and Cu)

Induction of ferric reductase activity in dicots and nongrass monocots is a well-recognized response to Fe deficiency. Recent evidence has shown that Cu deficiency also induces plasma membrane Fe reduction. In this study we investigated whether other nutrient deficiencies could also induce ferric reductase activity in roots of pea (Pisum sativum L. cv Sparkle) seedlings. Of the nutrient deficiencies tested (K, Mg, Ca, Mn, Zn, Fe, and Cu), only Cu and Fe deficiencies elicited a response. Cu deficiency induced an activity intermediate between Fe-deficient and control plant activities. To ascertain whether the same reductase is induced by Fe and Cu deficiency, concentration- and pH-dependent kinetics of root ferric reduction were compared in plants grown under control, -Fe, and -Cu conditions. Additionally, rhizosphere acidification, another process induced by Fe deficiency, was quantified in pea seedlings grown under the three regimes. Control, Fe-deficient, and Cu-deficient plants exhibited no major differences in pH optima or Km for the kinetics of ferric reduction. However, the Vmax for ferric reduction was dramatically influenced by plant nutrient status, increasing 16- to 38-fold under Fe deficiency and 1.5- to 4-fold under Cu deficiency, compared with that of control plants. These results are consistent with a model in which varying amounts of the same enzyme are deployed on the plasma membrane in response to plant Fe or Cu status. Rhizosphere acidification rates in the Cu-deficient plants were similarly intermediate between those of the control and Fe-deficient plants. These results suggest that Cu deficiency induces the same responses induced by Fe deficiency in peas.     

Comparison of homoserine dehydrogenase from different plant sources

Homoserine dehydrogenase (HSD) was partially purified from castor bean, pea and wheat seedlings. The enzyme from pea had a MW of 75 000 and no sensitivity to threonine when measured in the direction of homoserine formation (forward reaction). The enzyme purified from castor bean had a MW of 290 000–350 000 and exhibited an almost complete inhibition by 1 mM threonine. Furthermore, this enzyme exhibited a polymeric nature as shown by polyacrylamide electrophoresis of the desensitized preparation and by SDS electrophoresis of the native enzyme. In wheat two isoenzymes were separated by gel filtration on Sephadex G 200. The fast-moving fraction (HSD I) was completely inhibited by threonine and exhibited a MW of 280 000, while the slow-moving fraction (HSD II) was insensitive to threonine and had a MW of 75 000. The sensitive enzyme from wheat and castor bean showed an almost absolute requirement for K⁺. The enzyme from pea and the insensitive form from wheat did not show a requirement for K⁺. For the wheat enzyme the effect of several amino acids and the main kinetic constants were studied.     

Plant Growth Substances Produced by Micro-organisms of Soil and Rhizosphere

S ummary : Micro-organisms isolated from rhizospheres and rhizoplanes of wheat plants, and from root-free soil, produced growth regulating substances with the properties of gibberellins and indolyl-3-acetic acid (IAA). Substances inhibiting extensions of pea plant internodes and lettuce hypocotyls were also produced, especially by bacteria from the root region of seedlings 6 days old. Bacteria producing growth promoting substances were most abundant on roots of older plants. Seedlings grown aseptically with added gibberellic acid (GA₃) and IAA, or grown with a soil inoculum, developed similarly and differed in their morphology from those grown aseptically without additives.     

A physiological study on the toxicity of culture filtrate of helminthosporium sativum P.K. & P.

Summary When symptoms of the leaf-spot disease of barley caused byHelminthosporium sativum could be reproduced by dipping host plants in fungal filtrate, it was thought to trace any correlation that may exist between nitrogenous constituents of the filtrate and its wilt-inducing capacity to test plants (lupin seedlings). The fungus was grown on a modified Fries' No 3 medium with sodium nitrate or ammonium chloride or an equivalent mixture of both as nitrogen source. The nitrogen content of the culture medium and its wilt-inducing capacity were traced over 34 days. The nitrogen content, after reaching a minimum, was found to rise again; the rise being more rapid and bigger in nitrate and ammonium-nitrate media than in ammonium media. Only a partial apparent correlation could be noted between the trend in the wilt-inducing capacity of filtrates obtained at different periods of incubation, and the trend in the change in their nitrogen content. It is suggested that the toxicity of the culture filtrate may be attributed to more than one substance, one of them being a nitrogenous product (possibly of peptide nature). The observed degree of toxicity would therefore depend on the relative amounts of the nitrogenous product and other substances.     

Effects of phosphorus supply on growth and nitrogen fractions in xylem sap and foliage of Eucalyptus regnans (F.Muell.), E. nitens (Maiden) and E. globulus (Labill.) seedlings: implications for herbivory

Rates of growth of seedlings of E. globulus, E. regnans and E. nitens were related to phosphorus supply in two soils but concentrations of total nitrogen and total phosphorus in most plant tissues did not vary significantly among soil or phosphorus treatments. Differences in concentrations of nitrogen and phosphorus and in the composition of the pool of free amino-acids among leaves at different stages of development were far greater than differences between treatments. The most significant of these differences were several-fold greater concentrations of arginine in the oldest leaves and these are most likely due to protein degradation and/or in situ synthesis since arginine is not generally phloem mobile. The concentration of reduced nitrogen in xylem sap was inversely related to growth and glutamine was by far the dominant nitrogenous solute. We suggest that specific nitrogenous solutes may be useful indices of the nitrogen status of eucalypt tissues for insect herbivores.     

Characterization of cadmium uptake, translocation and storage in near-isogenic lines of durum wheat that differ in grain cadmium concentration

Here we examined several physiological properties of two near-isogenic lines of durum wheat (Triticum turgidum var. durum) that differ in grain cadmium accumulation, to identify the function of a gene locus that confers differential grain Cd concentrations. Time- and concentration-dependent uptake and translocation studies using 109Cd were conducted on nutrient solution-grown seedlings. Root extracts were analysed by inductively coupled plasma emission spectrometry, gel filtration and capillary electrophoresis to determine the interaction between Cd and phytochelatins (PCs) in storage of Cd in roots. The two isolines did not differ in time- or concentration-dependent root Cd uptake, but the low grain-Cd-accumulating isoline showed decreased movement of Cd from roots to shoots. All buffer-soluble Cd extracted from roots of both isolines was in the form of a low-molecular-weight PC-containing complex. The data suggest that PC synthesis is not a limiting factor in the differential storage of Cd in roots, and that movement of Cd through the root and into the transpiration stream may be the cause of differential Cd partitioning in the two isolines.     

Preferential Assimilation of Ammonium Ions from Ammonium Nitrate Solutions by Apple Seedlings

Apple seedlings, Pyrus malus L., were grown in complete nutrient solutions containing nitrate, ammonium, or ammonium plus nitrate as the nitrogen source. Uptake of nitrogen was calculated from depletion measurements of the nutrient solutions and by using ¹⁵N labelled nitrate and ammonium salts. If the plants received nitrogen as ammonium only or as nitrate only, the amounts of nitrogen taken up were similar. However, if the seedlings were supplied with ammonium nitrate, the amount of nitrate-nitrogen assimilated was only half that of ammonium. Nevertheless, if ammonium and nitrate were supplied to a plant with a split-root system, with each root half receiving a different ion, the uptakes were similar. The possibility of independent inhibition by ammonium of both nitrate uptake and reduction in the roots is discussed.     

Physiological Characteristics of Fe Accumulation in the ;Bronze' Mutant of Pisum sativum L., cv ;Sparkle' E107 (brz brz)

The pea (Pisum sativum L.) mutant, E107 (brz, brz) accumulated extremely high concentrations of Fe in its older leaves when grown in light rooms in either defined nutrient media or potting mix, or outdoors in soil. Leaf symptoms (bronze color and necrosis) were correlated with very high Fe concentrations. When E107 plants were grown in nutrient solutions supplied 10 μm Fe, as the Fe(III)-N,N′-ethylenebis[2-(2-hydroxyphenyl)glycine] chelate, their roots released higher concentrations of Fe(III) reducing substances to the nutrient media than did roots of the normal parent cv, `Sparkle.' Reciprocal grafting experiments demonstrated that the high concentrations of Fe in the shoot was controlled by the genotype of the root. In short-term <sup>59</sup>Fe uptake studies, 15-day-old E107 seedlings exhibited higher rates of Fe absorption than did `Sparkle' seedlings under Fe-adequate growth conditions. Iron deficiency induced accelerated short-term Fe absorption rates in both mutant and normal genotypes. Iron-treated E107 roots also released larger amounts of both protons and Fe(III) reductants into their nutrient media than did iron-treated `Sparkle' roots. Furthermore, the mutant translocated proportionately more Fe to its shoot than did the parent regardless of Fe status.     

Effects of the auxin-inhibiting substances raphanusanin and benzoxazolinone on apical dominance of pea seedlings

The effects of the auxin-inhibiting substances raphanusanin ((3R*,6S*)-3-[methoxy (methylthio) methyl]-2-pyrrolidinethione, raphanusanin B)and benzoxazolinone (6-methoxy-2-bezoxazolinone, MBOA) on apical dominance of pea(Pisum sativum L. cv. Alaska) seedlings were studied.Application of raphanusanin B or MBOA to the apical bud, internode, or lateralbud of pea seedlings released apical dominance in either intact orindole-3-acetic acid (IAA )-treated, decapitated plants. These results suggestthat the auxin-inhibiting substances raphanusanin B and MBOA have activity inreleasing apical dominance. Conversely, the auxin transport inhibitors2,3,4-triiodobenzoic acid (TIBA) and 1-naphthylphthalamic acid (NPA) did notstimulate lateral bud growth when they were applied directly to the lateralbud,although application to the apical bud or internode released apical dominance.Therefore, the mode of action of raphanusanin B and MBOA in apical dominance isclearly different from that of auxin transport inhibitors. Raphanusanin B andMBOA may suppress the synthesis of growth-inhibiting factor(s) of the lateralbud induced by endogenous auxin transported from the apical bud or exogenouslyapplied auxin, and/or the action of the factor(s).