Kinetic Studies of (Mg2+)ATPase in Oat Roots

Kinetic studies on a microsomal fraction from oat roots (Arena sativa) indicate that the MgATP complex is the primary substrate for the ATPase. Free ATP was a weak competitive inhibitor. Free Mg²⁺ appeared to be either a competitive or noncompetitive inhibitor.     

Triton X—100加KI对燕麦根细胞质膜ATP酶的溶解

在酸性条件下,1％ Triton X—100加 0.25mol/L KI能有效地溶解燕麦根细胞质膜ATP酶。溶解的ATP酶水解ATP的最适pH在6.5左右,酶活性受到Na_3VO_4和DES的强烈抑制,而不受Na_2MoO_4和NaN_3的抑制。溶解的酶液经透析后,K~ —ATP酶活性占Mg~(2 ),KCl—ATP酶活性的85％。     

Characterization of a NO(3)-Sensitive H-ATPase from Corn Roots

When assayed in the presence of azide, NO₃⁻ was shown to be a specific inhibitor of a proton-translocating ATPase present in corn (Zea mays L. cv WF9 × M017) root microsomal membranes. The distribution of the NO₃⁻-sensitive ATPase on sucrose gradients and its general characteristics are similar to those previously reported for the anion-stimulated H⁺-ATPase of corn roots believed to be of tonoplast origin. An ATPase inhibited by 20 μm vanadate and insensitive to molybdate was also identified in corn root microsomal membranes which could be largely separated from the NO₃⁻-sensitive ATPase on sucrose gradients and is believed to be of plasma membrane origin. Inasmuch as both ATPase most likely catalyze the efflux of H⁺ from the cytoplasm, our objective was to characterize and compare the properties of both ATPases under identical experimental conditions. The vanadate-sensitive ATPase was stimulated by cations (K⁺ > NH₄⁺ > Rb⁺ > Cs⁺ > Li⁺ > Na⁺ > choline⁺) whereas the NO₃⁻-sensitive ATPase was stimulated by anions (Cl⁻ > Br⁻ > C₂H₃O₂⁻ > SO₄²⁻ > I⁻ > HCO₃⁻ > SCN⁻). Both ATPases required divalent cations. However, the order of preference for the NO₃⁻-sensitive ATPase (Mn²⁺ > Mg²⁺ > Co²⁺ > Ca²⁺ > Zn²⁺) differed from that of the vanadate-sensitive ATPase (Co²⁺ > Mg²⁺ > Mn²⁺ > Zn²⁺ > Ca²⁺). The vanadate-sensitive ATPase required higher concentrations of Mg:ATP for full activity than did the NO₃⁻-sensitive ATPase. The kinetics for Mg:ATP were complex for the vanadate-sensitive ATPase, indicating positive cooperativity, but were simple for the NO₃⁻-sensitive ATPase. Both ATPases exhibited similar temperature and pH optima (pH 6.5). The NO₃⁻-sensitive ATPase was stimulated by gramicidin and was associated with NO₃⁻-inhibitable H⁺ transport measured as quenching of quinacrine fluorescence. It was insensitive to molybdate, azide, and vanadate, but exhibited slight sensitivity to ethyl-3-(3-dimethylaminopropyl carbodiimide) and mersalyl. Overall, these results indicate several properties which distinguish these two ATPases and suggest that under defined conditions NO₃⁻-sensitive ATPase activity may be used as a quantitative marker for those membranes identified tentatively as tonoplast in mixed or nonpurified membrane fractions. We feel that NO₃⁻ sensitivity is a better criterion by which to identify this ATPase than either Cl⁻ stimulation or H⁺ transport because it is less ambiguous. It is also useful in identifying the enzyme following solubilization.     

Potassium Stimulation of Corn Root Plasmalemma ATPase : II. H-Pumping in Native and Reconstituted Vesicles with Purified ATPase

The stimulation by K⁺ of the initial rate of H⁺-pumping by ATPase was studied in native plasmalemma (Zea mays L. var Mona) vesicles and in reconstituted vesicles with enzyme purified on a glycerol gradient. In reconstituted vesicles, a very high H⁺-pumping rate (200,000% quenching per minute per milligram protein) was obtained with 9-amino-6-chloro-2-methoxyacridine provided that the pump was short-circuited by K⁺-valinomycin. A constant ionic strength was used to prevent indirect stimulation by the electrostatic effects of K⁺ salts. Indirect stimulation of H⁺-pumping by the short-circuiting effect of internal K⁺, could be abolished by using the permeant anions NO₃⁻ and Br⁻ in native, but not in reconstituted vesicles. In both materials, half-stimulation of the H⁺-pumping by K⁺ was observed at about 5 millimolar. The same stimulation was obtained when K⁺ was present only in the external solution or when it was present both outside and inside the vesicles. It was concluded that the stimulating effect of K⁺ on the H⁺-pumping evidenced in these experiments on both native and reconstituted vesicles was due to a direct effect of the cation on the cytoplasmic face of the ATPase. These results are discussed within the context of the hypothesis of an active K⁺ transport driven by the ATPase through a direct H⁺/K⁺ exchange mechanism.     

Growth-Promoting Effects of Fatty Acids on Excised Wheat Roots and Oat Coleoptiles

The growth action of some fatty acids and alcohols with carbon number from 1 to 4 was tested on excised wheat roots in aseptic cultures. Growth, cell length, and dry weight were measured after seven days. The tested substances were: Formic acid, acetic acid, propionic acid, n-Butyric acid, isobutyric acid, acelaldehyde, propionaldohyde, ethanol, n-propanol, isopropanol, n-butanoL and isobutanol. The primary alcohols and all of the acids, except formic acid, promoted the cell elongation and the total growth, but the meristematic activity was inhibited in the higher concentrations. The concentrations with maximal growth-promoting activity were 10^?2M to 10^?3M for the alcohols and 10^?4M for the acids. Propionic acid was applied in darkness, red light, and white light and proved to increase the cell length from 215 μ, 180 μ, and 120 μ up to 240 μ in all three treatments. The growth rate was not affected, but the duration of the cell elongation was extended. The presence of iron proved to be necessary for the stimulation. The chlorophyll content in the light grown roots was relatively unaffected when the cell length was increased and the dry weight was not increased as long the cell number was normal. The growth of Avena coleoptile segments was slightly promoted by propionic acid in the presence of IAA.     

Modeling the C Economy of Anabaena flos-aquae: Estimates of Establishment, Maintenance, and Active Costs Associated with Growth on NH(3), NO(3), and N(2)

Steady state cultures of Anabaena flos-aquae were established over a wide range of phosphate-limited growth rates while N was supplied as either NH₃, NO₃⁻, or N₂ gas. At growth rates greater than 0.03 per hour, rates of gross and net carbon fixation were similar on all N sources. However, at lower growth rates (<0.03 per hour) in the NO₃⁻ and N₂ cultures, gross photosynthesis greatly exceeded net photosynthesis. The increase in photosynthetic O₂ evolution with growth rate was greatest when N requirements were met by NO₃⁻ and least when met by NH₃. These results were combined with previously reported measurements of cellular chemical composition, N assimilation, and acetylene reduction (Layzell, Turpin, Elrifi 1985 Plant Physiol 78: 739-745) to construct empirical models of carbon and energy flow for cultures grown at 30, 60, and 100% of their maximal growth rate on all N sources. The models suggested that over this growth range, 89 to 100% of photodriven electrons were allocated to biomass production in the NH₃ cells, whereas only 49 to 74% and 54 to 90% were partitioned to biomass in the NO₃⁻-and N₂-grown cells, respectively. The models were used to estimate the relative contribution of active, maintenance, and establishment costs associated with NO₃⁻ and N₂ assimilation over the entire range of growth rates. The models showed that the relative contribution of the component costs of N assimilation were growth rate dependent. At higher growth rates, the major costs for NO₃⁻ assimilation were the active costs, while in N₂-fixing cultures the major energetic requirements were those associated with heterocyst establishment and maintenance. It was concluded that compared with NO₃⁻ assimilation, N₂ fixation was energetically unfavorable due to the costs of heterocyst establishment and maintenance, rather than the active costs of N₂ assimilation.     

Some Effects of Root Anatomy on K, Na and Cl Loading of Citrus Roots and Leaves

Loading of K, Na and Cl into fibrous roots of salt-treated citrusgenotypes, Rangpur lime (Citrus reticulata var. austera hybrid?)and Etrog citron (C. medica L.) was investigated in relationto root anatomy, in particular, the differentiation of the epidermal-hypodermallayers with distance from the root tip. The influence of durationof salinity treatment on the characteristics of K, Na and Claccumulation in leaves of the two genotypes was explored intwo experiments respectively, covering the short term (14 d)and long term (12 weeks). This study focused on two regions of the fibrous root, a segment2–12 mm from the root tip, immediately basipetal to thezone of elongation and a differentiated region of the maturesuberized, fibrous root, 40–50 mm from the root tip. Inthe distal root segment (2–12 mm) the epidermis and hypodermisof both genotypes was observed as two closely packed, uniseriatelayers of living cells. In the proximal root segment (40–50mm) the differentiated hypodermis was evident as a uniseriatelayer of thick-walled lumina interspersed with ‘passagecells’ which were frequently associated with clustersof viable epidermal cells. The characteristics of Na and Cl loading in the two root zonesdiffered profoundly during the short term loading (acclimation)phase. Attainment of quasi-steady-states for Na and Cl in thedistal region (with the exception of Na in Etrog citron) wasrapid as was Na equilibration of the proximal root segmentsin both genotypes. In contrast, Cl loading in the proximal regiontook c. 14 d to reach a quasi-steady-state by which time Cllevels were 2 to 3 times higher in the proximal than in thedistal root segments. The superior tolerance of Rangpur lime to long term salinitywas highly correlated to Cl exclusion from the leaves. However,during the first 14 d of acclimation to 50 mol m^–3 NaClthere was no segregation of the two genotypes based upon leafCl levels. Expression of differential accumulation of Cl inleaves appeared to be a time dependent process and was manifestonly after Cl saturation of the proximal root which representsthe bulk of the fibrous root system. The salt tolerance of Rangpurwas also associated with high selectivity of fibrous roots forK. over Na. A pronounced loss of K from cortical cells in theproximal root segment of salt-stressed Etrog citron was alsoevident by X-ray microanalysis. Key words: Citrus, anatomy, salinity, roots, X-ray microanalysis     

Different Effects of Tris and Histidine on a Membrane Bound NaK ATPase from Sugar Beet Roots

A membrane fraction of sugar beet roots prepared in the presence of dithiothreitol contains (Na⁺+ K⁺+ Mg²⁺) ATPase activity. This activity was studied in the presence of different concentrations of Tris and histidine. Tris was found to interact with the ATPase in the following way: (1) Tris at 50 mM increases, in the absence of Na and/or K, the activity in an uncompetitive way with respect to MgATP. (2) Concentrations of Tris > 50 mM cause inhibition in the absence of Na and K when the ratio between MgATP and Tris is relatively low. (3) Though Tris at 50 mM stimulates similarly to Na, it can not substitute for Na in the Na + K activation. (4) In the presence of Na and K, Tris acts as a competitive inhibitor. Histidine has little influence on the rate both in the presence and absence of Na and/or K.     

Extra- and Intracellular pH and Membrane Potential Changes Induced by K, Cl, H(2)PO(4), and NO(3) Uptake and Fusicoccin in Root Hairs of Limnobium stoloniferum

Short-term ion uptake into roots of Limnobium stoloniferum was followed extracellularly with ion selective macroelectrodes. Cytosolic or vacuolar pH, together with the electrical membrane potential, was recorded with microelectrodes both located in the same young root hair. At the onset of chloride, phosphate, and nitrate uptake the membrane potential transiently decreased by 50 to 100 millivolts. During Cl⁻ and H₂PO₄⁻ uptake cytosolic pH decreased by 0.2 to 0.3 pH units. Nitrate induced cytosolic alkalinization by 0.19 pH units, indicating rapid reduction. The extracellular medium alkalinized when anion uptake exceeded K⁺ uptake. During fusicoccin-dependent plasmalemma hyperpolarization, extracellular and cytosolic pH remained rather constant. Upon K⁺ absorption, FC intensified extracellular acidification and intracellular alkalinization (from 0.31 to 0.4 pH units). In the presence of Cl⁻ FC induced intracellular acidification. Since H⁺ fluxes per se do not change the pH, recorded pH changes only result from fluxes of the stronger ions. The extra- and intracellular pH changes, together with membrane depolarization, exclude mechanisms as K⁺/A⁻ symport or HCO₃⁻/A⁻ antiport for anion uptake. Though not suitable to reveal the actual H⁺/A⁻ stoichiometry, the results are consistent with an H⁺/A⁻ cotransport mechanism.     

Intracellular pH Regulation during NO(3) Assimilation in Shoot and Roots of Ricinus communis

Ricinus communis L. was used to test the Dijkshoorn-Ben Zioni hypothesis that NO₃⁻ uptake by roots is regulated by NO₃⁻ assimilation in the shoot. The fate of the electronegative charge arising from total assimilated NO₃⁻ (and SO₄²⁻) was followed in its distribution between organic anion accumulation and HCO₃⁻ excretion into the nutrient solution. In plants adequately supplied with NO₃⁻, HCO₃⁻ excretion accounted for about 47% of the anion charge, reflecting an excess nutrient anion over cation uptake. In vivo nitrate reductase assays revealed that the roots represented the site of about 44% of the total NO₃⁻ reduction in the plants. To trace vascular transport of ionic and nitrogenous constituents within the plant, the composition of both xylem and phloem saps was thoroughly investigated. Detailed dry tissue and sap analyses revealed that only between 19 and 24% of the HCO₃⁻ excretion could be accounted for from oxidative decarboxylation of shoot-borne organic anions produced in the NO₃⁻ reduction process. The results obtained in this investigation may be interpreted as providing direct evidence for a minor importance of phloem transport of cation-organate for the regulation of intracellular pH and electroneutrality, thus practically eliminating the necessity for the Dijkshoorn-Ben Zioni recycling process.     

Branchial Cl transport, anion-stimulated ATPase and acid-base balance inAnguilla anguilla adapted to freshwater: Effects of hyperoxia

Summary Freshwater eel gills are notorious for their limited ability to pump chloride. As a result there is a considerable discrepancy between the Na⁺ and Cl^– plasma levels, and plasma HCO₃ ^– and blood pH are relatively high in this species.When eels are kept in tanks aerated with pure oxygen, significant alterations in blood acid-base balance, an increase in plasma pCO₂ and a decrease in blood pH, are observed. In fish studied after 3 weeks hyperoxia, the decrease in blood pH is compensated by an increase in plasma HCO₃ ^–. Such fish exhibit a Cl^– influx 5 times higher than that observed in normoxic fish. This Cl^– influx is readily inhibited by addition of SCN^– to the external medium.An anion-stimulated ATPase activated by HCO₃ ^– and by Cl^– and inhibited by SCN^– was recently described in membrane fractions of the gills ofCarassius auratus, a fish noted for its high Cl^– pumping rate. This enzyme is also found in the gills of the eel. While the maximal rates of enzyme activation by HCO₃ ^– and by Cl^– are similar inCarassius andAnguilla, the affinity of the enzyme for Cl^– is 25 times higher inCarassius. In the microsomal fraction of the hyperoxic eel gills, the maximal anionstimulated ATPase activity remains unchanged but HCO₃ ^– affinity decreases by 50%, while Cl^– affinity increases 5 times. Thus some characteristics of this ATPase seem to be closely related to the Cl^– pump activity exhibited by the gill in fresh water.     

Decrease of pH Gradients in Tonoplast Vesicles by NO(3) and Cl: Evidence for H-Coupled Anion Transport

Chloride or nitrate decreased a pH gradient (measured as [¹⁴C]methylamine accumulation) in tonoplast-enriched vesicles. The ΔpH decrease was dependent on the anion concentration. These effects are independent of the anion-sensitive H⁺-ATPase of the tonoplast, since the pH gradient (acid inside) was imposed artificially using a pH jump or a K⁺ gradient and nigericin. 4,4′-Diisothiocyano-2,2′-stilbene disulfonic acid partially prevented the decrease in pH gradient induced by Cl⁻. Two possible models to account for this anion-dependent decrease of ΔpH are: (a) H⁺ loss is accompanied by Cl⁻ or NO₃⁻ efflux from the vesicles via H⁺/anion symport systems on the tonoplast and (b) H⁺ loss is accompanied by Cl⁻ or NO₃⁻ uptake into the vesicles via H⁺/anion antiport systems. Depending on the requirements and conditions of the cell, these two systems would serve to either mobilize Cl⁻ and NO₃⁻ stored in the vacuole for use in the cytoplasm or to drive anions into the vacuole. Chloride or nitrate also decreased a pH gradient in fractions containing plasma membrane and Golgi, implying that these membranes may have similar H⁺-coupled anion transport systems.     

Effect of Phloem-Translocated Malate on NO(3) Uptake by Roots of Intact Soybean Plants

In soybean (Glycine max L. Merr. cv Kingsoy), NO₃⁻ assimilation in leaves resulted in production and transport of malate to roots (B Touraine, N Grignon, C Grignon [1988] Plant Physiol 88: 605-612). This paper examines the significance of this phenomenon for the control of NO₃⁻ uptake by roots. The net NO₃⁻ uptake rate by roots of soybean plants was stimulated by the addition of K-malate to the external solution. It was decreased when phloem translocation was interrupted by hypocotyl girdling, and partially restored by malate addition to the medium, whereas glucose was ineffective. Introduction of K-malate into the transpiration stream using a split root system resulted in an enrichment of the phloem sap translocated back to the roots. This treatment resulted in an increase in both NO₃⁻ uptake and C excretion rates by roots. These results suggest that NO₃⁻ uptake by roots is dependent on the availability of shoot-borne, phloem-translocated malate. Shoot-to-root transport of malate stimulated NO₃⁻ uptake, and excretion of HCO₃⁻ ions was probably released by malate decarboxylation. NO₃⁻ uptake rate increased when the supply of NO₃⁻ to the shoot was increased, and decreased when the activity of nitrate reductase in the shoot was inhibited by WO₄²⁻. We conclude that in situ, NO₃⁻ reduction rate in the shoot may control NO₃⁻ uptake rate in the roots via the translocation rate of malate in the phloem.     

Regulation of NO(3) Influx in Barley : Studies Using NO(3)

Short-term (10 minutes) measurements of plasmalemma NO₃⁻ influx (_oc) into roots of intact barley plants were obtained using ¹³NO₃⁻. In plants grown for 4 days at various NO₃⁻ levels (0.1, 0.2, 0.5 millimolar), _oc was found to be independent of the level of NO₃⁻ pretreatment. Similarly, pretreatment with Cl⁻ had no effect upon plasmalemma ¹³NO₃⁻ influx. Plants grown in the complete absence of ¹³NO₃⁻ (in CaSO₄ solutions) subsequently revealed influx values which were more than 50% lower than for plants grown in NO₃⁻. Based upon the documented effects of NO₃⁻ or Cl⁻ pretreatments on net uptake of NO₃⁻, these observations suggest that negative feedback from vacuolar NO₃⁻ and/or Cl⁻ acts at the tonoplast but not at the plasmalemma. When included in the influx medium, 0.5 millimolar Cl⁻ was without effect upon ¹³NO₃⁻ influx, but NH₄⁺ caused approximately 50% reduction of influx at this concentration.     

Aluminium Effects on ATPase Activity and Lipid Composition of Plasma Membranes in Sugar Beet Roots

The effect of aluminium (Al) in vivo and in vitro on root plasmamembranes has been studied in two sugar beet (Beta vulgarisL.) cultivars, Monohill (Al-sensitive) and Regina (relativelyAl-tolerant). Although Al in vitro inhibited the MgATPase inan uncompetitive way for both cultivars raised in the absenceof Al, the specific K⁺-activation of the MgATPase was only inhibitedby Al in cv. Monohill. Arrhenius analysis of the MgATPase activity showed that theeffect of Al in vitro depended on whether or not the plantswere exposed to Al in vivo. Al treatment in vitro of the MgATPasefrom control plants cultivated at a low pH (5·4) causedan increase in the phase transition temperature from 17 to 22°C. Only at a higher pH range (pH 6·1) could a secondtransition temperature be induced (at 9 °C). By additionof Al in vitro to plants cultivated with Al at pH 5·4,the slopes of the activity plots did not change. Aluminium changedthe K_m of the ATPase for MgATP in an opposite way by treatmentin vivo and in vitro. Lipid analyses of the plasma membranes showed that the acylcomposition differed little following Al treatment in vivo,but that the ratio of phosphatidylcholine: phosphatidylethanolamineincreased. The changes correlated with the observed change inthe K_m for the MgATPase. We conclude that the main effect ofAl on the MgATPase is not due to the formation of an Al-ATPcomplex. Instead, Al may bind to the membrane-bound enzyme(s)and/or modify the lipid environment. Key words: Aluminium, ATPase, Beta vulgaris, lipids     

NaCl胁迫对高粱根、叶鞘和叶片液泡膜ATP酶和焦磷酸酶活性的影响

NaCl胁迫初期 ,Na 主要在根和叶鞘中积累。相应地 ,根和叶鞘液泡膜ATP酶和焦磷酸酶水解活性、依赖ATP和PPi的质子泵活性及Na /H 逆向转运活性均明显增加 ,根和叶鞘的生长没有受到抑制。NaCl胁迫后期 ,Na 开始向地上部分运输并在叶片中积累。此时 ,叶片液泡膜质子泵和Na /H 逆向转运活性开始增加 ,根和叶鞘的Na/K比增加 ,其液泡膜ATP酶和焦磷酸酶水解活性、质子泵活性和Na /H 逆向转运活性下降。相应地 ,根和叶鞘的生长也下降。当保温介质中Na/K比超过 1时 ,液泡膜微囊ATP酶和焦磷酸酶活性均随Na/K比的增加而下降。表明非盐生植物液泡膜质子泵在盐胁迫的初期对Na 在液泡内的积累及其耐盐性起重要作用     

Proteome Analysis of Roots in Cucumber Seedlings Under Iso-Osmotic NaCl and Ca(NO3)2 Stresses

The growth and productivity of cucumber are severely affected by salinity. To understand the complex salt response mechanism, the physiological and biochemical responses of cucumber seedlings to iso-osmotic NaCl and Ca(NO₃)₂ stresses were investigated. In this study, the biomass was significantly decreased under iso-osmotic NaCl and Ca(NO₃)₂ stresses, and the inhibitory effect of Ca(NO₃)₂ stress was less than that of NaCl stress. The soluble protein contents were increased under Ca(NO₃)₂ stress, whereas they were decreased after 6 days of NaCl stress. A sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis revealed that there were 14 differentially expressed protein bands in roots under iso-osmotic NaCl and Ca(NO₃)₂ stresses at 0, 3, 6, and 9 days, and seven protein bands were little expressed under NaCl stress at 6 and 9 days. Based on these results, 2-D gel electrophoresis was used to separate cucumber root proteins in response to iso-osmotic NaCl and Ca(NO₃)₂ stresses at 3 days. A total of 43 protein spots changed under salt stress. Of these proteins, 33 were successfully identified by matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOF-MS) and liquid chromatography electro-spray ionization tandem mass spectrometry (LC-ESI-MS/MS) and categorized into classes, including those corresponding to antioxidants and defense-related proteins and energy and metabolism. The functions of the significantly differentially expressed root proteins were analyzed, which may facilitate a better understanding of different salt response mechanisms, and we suggest that cucumber seedlings showed a more powerful ability to resist Ca(NO₃)₂ stress.