Anion uptake in maize roots: Interactions between chlorate and nitrate

Effects of nitrate, chloride and chlorate ions upon nitrate and chlorate uptake by roots of maize ( Zea mays L., cv. B73) seedlings were examined. Net nitrate uptake, ³⁶ClO₃⁻ influx and ³⁶Cl⁻ influx (the latter two in a background of 0.5 m M KNO₃) displayed similar pH profiles with optima at pH 5.5 and below. External, non-labeled chloride had little effect on the accumulation of ³⁶ClO₃⁻ (both in 5 h and 20 min uptake assays), while nitrate and chlorate had almost identical, marked inhibitory effects. Nitrate pretreatment caused an apparent induction of both ³⁶ClO₃⁻ and ¹⁵NO₃⁻ uptake activities. After 5 h of treatment in nitrate, the uptake activities of chloride- and chlorate-pretreated plants increased to that of nitrate-pretreated plants. During 6 h exposure to chlorate, ³⁶ClO₃⁻ uptake activity of nitrate-pretreated plants decreased to that of chlorate- and chloride-pretreated plants. The results support the existence of a shared nitrate/chlorate transport system in maize roots which is not inhibited by external chloride, and which is induced by nitrate, but not by chlorate or chloride. The suggestion is made that selection of chlorate-resistant mutants of maize can identify nitrate uptake as well as nitrate reductase mutants.     

Isolation and characterization of nitrate reductase deficient mutants of the ectomycorrhizal fungus Hebeloma cylindrosporum

To clarify the role of the fungal nitrate assimilation pathway in nitrate reduction by mycorrhizal plants, nitrate reductase (NR)-deficient (NR⁻) mutants of the ectomycorrhizal basidiomycete Hebeloma cylindrosporum Romagnesi have been selected. These mutants were produced by u.v. mutagenesis on protoplasts originating from homokaryotic mycelia belonging to complementary mating types of this heterothallic tetrapolar species. Chlorate-resistant mutants were first selected in the presence of different nitrogen (N) sources in the culture medium. Among 1495 chlorate resistant mycelia, 30 failed to grow on nitrate and lacked a detectable NR activity. Growth tests on different N sources suggested that the NR activity of all the different mutants is specifically impaired as a result of mutations in either the gene coding for NR apoprotein or genes controlling the synthesis of the molybdenum cofactor. Furthermore, restoration of NR activity in some of the dikaryons obtained after crosses between the different mutant mycelia suggested that not all the selected mutations mapped in the same gene. Utilization of N on a NH₄¹⁵NO₃ medium was studied for two mutant strains and their corresponding wild-type homokaryons. None of the mutants could use nitrate whereas ¹⁵N enrichment values indicated that 13–27% of N present in 13-d-old wild-type mycelia originated from nitrate. Apparently, the mutant mycelia do not compensate their inability to use nitrate by a more efficient use of ammonium. These different NR mutants still form mycorrhizas with the habitual host plant, Pinus pinaster (Ait.), making them suitable for study of the contribution of the fungal nitrate assimilation pathway to nitrate assimilation by mycorrhizal plants.     

Nitrate-induced de novo synthesis and regulation of NAD(P)H nitrate reductase from Sphagnum

The NO⁻₃-triggered induction of nitrate reductase (NR; EC 1.6.6.2) in the bryophyte Sphagnum magellanicum Brid. has been studied, using in vivo and in vitro assays as well as immunological methods. The time-course of induction was triphasic with maximal NR activity after 6–8 h. Results obtained from Western blots show that NR is synthesized de novo after NO⁻₃ application. The inhibitory effect of cycloheximide on NR induction corroborated this conclusion. Light enhanced the NO⁻₃-triggered NR induction. The enzyme activity, measured in vivo, increased more than the in vitro activity. No evidence for phytochrome control of NR was found. Nitrate uptake, in contrast to NR activity, showed no lag period after NO⁻₃ application and, under the experimental conditions used, was not rate limiting for NR induction. Neither light nor a NO⁻₃ pretreatment significantly affected NO⁻₃ uptake.     

Effect of nitrate on nitrogen fixation and nodule carbohydrate and organic acid concentrations in pea mutants deficient in nitrate reductase

Nitrate inhibits symbiotic N₂ fixation and a number of hypotheses concerned with NO₃⁻ assimilation have been suggested to explain this inhibition. These hypotheses were tested using a pea ( Pisum sativum L. cv. Juneau) with normal nitrate reductase NR; (EC 1,6,6,4) activity and two mutants of cv. Juneau, A317 and A334, with impaired NR activity. The plants were inoculated with three strains of Rhizobium leguminosarum and grown for 3 weeks in N-free medium, followed by 1 week in medium supplemented with 0, 5 or 10 m M KNO₃ before harvesting. NO₃ was taken up at comparable rates by the parent and the mutants and accumulated in leaf and stem tissue of the latter. Acetylene reduction rates were inhibited similarly in both the parent and mutants in the presence of KNO₃ but there were differences among rhizobial strains. Starch concentration of the nodules decreased by 46% in the presence of KNO₃ and there were differences among rhizobial strains but not among pea genotypes. Malate and succinate accumulated in nodules in the presence of KNO₃. These data are not consistent with the photosynthate deprivation hypothesis as a primary mechanism for NO₃ inhibition of N₂ fixation since NO₃ affected the nodule carbohydrate composition of all three pea genotypes in a similar manner. The lack of correlation between NR activity and NO₃ inhibition of N₂ fixation suggests that NO₃ assimilation may be only indirectly involved in the inhibition phenomenon.     

Nitrate reductase activity in nodules of pea inoculated with hydrogenase positive and hydrogenase negative strains of Rhizobium leguminosarum

The nitrate reductase (NR, EC 1.6.6.1) activity in root nodules formed by hydrogenase positive (Hup⁺) and hydrogenase negative (Hup⁻) Rhizobium leguminosarum strains was examined in symbioses with the pea cultivar Alaska ( Pisum sativum L.), Rates of activity were determined by the in vivo assay in nodules from plants that were only N₂-dependent or grown in the presence of 2 m M KNO₃. The rates varied widely among strains, regardless of the Hup phenotype of the R. leguminosarum strain used for inoculation, but the overall results indicated that nodules formed by Hup⁻ strains accumulated more nitrite in the incubation medium than did those with Hup⁻ phenotypes. Total plant dry weight and reduced nitrogen content of pea plants grown in the presence of 2 m M KNO₃ and inoculated with single Hup⁺ and Hup⁻ R. leguminosarum strains were statistically different among some strains. These observations suggest that the possible advantages derived from the presence of the Hup system on whole plant growth may be counteracted by the higher rates of NR activity in the Hup⁻ strains in the R. leguminosarum -pea symbiosis.     

Uptake of chlorate and other ions in seedlings of the nitrate-uptake mutant B1 of Arabidopsis thaliana

The accumulation of labelled ions was measured in seedlings of Arabidopsis thaliana (L.) Heynh. grown in submerged cultures. Genotypes used were wild type and the nitrate-uptake mutant B1, which is altered in the uptake of nitrate and chlorate from concentrations above 1 m M when grown under normal conditions. At low and high concentrations of chlorate, chloride, and K⁺, significantly less radioactivity was accumulated in seedlings of B1 than in seedlings of wild type. The influx of sulphate did not decrease in B1. The results indicate that the effect of the mutation in B1 is restricted to the uptake of monovalent ions.     

Hydrogen uptake in Anabaena sp. strain CA does not protect nitrogenase from inactivation by hyperbaric oxygen

Abstract Two mutants of Anabaena sp. strain CA were used to demonstrate that oxygen-dependent hydrogen uptake was not the primary means to protect the nitrogenase enzyme complex from the deleterious effects of hyperbaric oxygen in vivo. Exposure to air caused the immediate and irreversible inactivation of nitrogenase activity in an oxygen-sensitive mutant, designated strain 22Y. Inactivation was concomitant with the destruction of the molybdo-iron (MoFe) protein of the nitrogenase complex. The mutant 22Y expressed an O₂-stable, Ni²⁺-stimulated hydrogen uptake of up to 2.7 μM H₂ per mg dry wt per h. Conversely, after exposure to 1% CO₂-99% O₂ for 3 h, both wild-type strain CA and a hydrogen uptake deficient (Hup⁻) mutant, strain N9AR, recovered 70–80% of their original acetylene reduction capacity with no apparent perturbations in the MoFe protein.     

Induction of nitrate reductase in needles of Scots pine seedlings by NOX and NO3−

The possibility to induce nitrate reductase (NR; EC 1.6.6.2) in needles of Scots pine ( Pinus sylvestris L.) seedlings was studied. The NR activity was measured by an in vivo assay. Although increased NR activities were found in the roots after application of NO₃⁻, no such increase could be detected in the needles. Detached seedlings placed in NO₃⁻ solution showed increasing NR activities with increasing NO₃⁻ concentrations. Exposure of seedlings to NO_x (70–80 ppb NO₂ and 8–12ppb NO) resulted in an increase of the NR activity from 10–20 nmol NO₂⁻ (g fresh weight)⁻¹ h⁻¹ to about 400 nmol NO₂⁻ (g fresh weight)⁻¹ h⁻¹. This level was reached after 2–4 days of exposure, thereafter the NR activity decreased to about 200 nmol NO₂⁻ (g fresh weight)⁻¹ h⁻¹. Analyses of free amino acids showed low concentrations of arginine and glutamine in NO_x-fumigated seedlings compared to corresponding controls.     

Uptake kinetics of iron-phytosiderophores in two maize genotypes differing in iron efficiency

Iron inefficiency in the maize ( Zea mays L.) mutant ysl is caused by a defect in the uptake system for Fe-phytosiderophores. To characterize this defect further, the uptake kinetics of Fe-phytosiderophores in ysl was compared to the Fe-efficient maize cultivar Alice. Short-term uptake of ⁵⁹Fe-labeled Fe-deoxymugineic acid (Fe-DMA) was measured over a concentration range of 0.03 to 300 μM. Iron uptake in Fe-deficient plants followed Michaelis-Menten kinetics up to about 30 μM and was linear at higher concentrations, indicating two kinetically distinct components in the uptake of Fe-phytosiderophores. The saturable component had similar K_m (∼ 10 μM) in both genotypes. In contrast. V_max was 5.5 μmol Fe-DMA g⁻¹ dry weight [30 min]⁻¹ in Alice, but only 0.6 μmol Fe-DMA g⁻¹ dry weight [30 min]⁻¹ in _ysl. Uptake experiments with double-labeled ⁵⁹Fe-[¹⁴C]DMA suggest that in both cultivars Fe-DMA was taken up by the roots as the intact chelate. The results indicate the existence of a high-affinity and a low-affinity uptake system mediating Fe-phytosiderophore transport across the root plasma membrane in maize. Apparently, the mutation responsible for Fe inefficiency in ysl affected high-affected uptake and led to a decrease in activity and/or number of Fe-phytosiderophore transporters.     

Assimilation of nitrate and ammonium by the Scots pine (Pinus sylvestris) seedling under conditions of high nitrogen supply

Seedlings of Scots pine ( Pinus sylvestris L.) were grown on perlite for 21 days under controlled conditions. Apart from the water control, KNO₃ (15 m M ), (NH₄)₂SO₄ (7.5 m M ), and NH₄NO₃ (15 m M ) were offered to study the effects of a high nitrogen supply on nitrogen assimilation. In some experiments 1.3 m M potassium was added to the basic ammonium solutions. In labelling studies nitrate and ammonium were 2.3 atom%¹⁵N-enriched. It was found that over the 21-day period approximately three times more ammonium-N was taken up than nitrate-N. However, nitrate and ammonium, applied simultaneously, were taken up to the same extent as if they were applied separately (additivity). The presence of K⁺ in the medium did not affect N-uptake. Among the soluble N-containing compounds nitrate, ammonium and 8 amino acids were quantified. It was found that assimilation of nitrate can cope with the uptake of NO⁻₃ under all circumstances. Neither free nitrate nor ammonium or amino acids accumulated to an extent exceeding the values of water-grown seedlings. On the other hand, in case of high ammonium supply considerably more nitrogen was taken up than could be incorporated into nonsoluble N-containing substance ('protein'). The remaining nitrogen was found to accumulate in intermediary storage pools (free NH₄⁺, glutamine, asparagine, arginine). Part of this accumulated N could be incorporated into protein when potassium was offered in the nutrient solution. It is concluded that potassium is a requirement for a high rate of protein synthesis not only in crop plants but also in conifers.     

供钾水平对苹果砧木M9T337幼苗生长、光合特性与15N、13C吸收利用的影响

以苹果M9T337幼苗为试材进行水培试验,采用¹⁵N和¹³C同位素示踪技术,研究不同供钾水平(0、3、6、9、12 mmol·L^-1,分别以K₀、K₁、K₂、K₃、K₄表示)对M9T337幼苗生长、光合特性与¹⁵N、¹³C吸收利用的影响.结果表明: K₂处理M9T337幼苗各器官干质量、根系长度、根系表面积、根尖数和根系活力均显著高于其他处理.叶片净光合速率(P_n)随着供钾水平的升高先上升后下降,在K₂处理时达到最高值,为15.5 μmol CO₂·m^-2·s^-1.处理30 d后,硝酸还原酶(NR)和碳代谢酶活性均以K₂处理最高,K₀处理最低.随着供钾水平的提高,各处理幼苗的¹³C积累量呈先升高后降低的趋势,且在K₂处理时各器官¹³C分配率最均衡.各处理间¹⁵N吸收量和利用率差异显著,K₂处理下幼苗的¹⁵N吸收量和利用率最高,分别为16.11 mg和17.9％,是K₀处理的3.0倍.因此,钾素供应过低或过高均抑制幼苗根系生长和叶片光合作用,不利于植株碳氮吸收,而适宜的钾素供应水平可以提高根系活力和净光合速率,增强硝酸还原酶(NR)和碳代谢酶活性,从而促进碳氮代谢.     

Nitrite in the root zone and its effects on ion uptake and growth of wheat seedlings

The immediate and posteffects of various concentrations of NaNO₂ on ion uptake of wheat ( Triticum aestivum L. cv. GK Öthalom) seedlings were studied at different pH values. Without pretreatment, the higher the concentration of NaNO₂ the greater was the decrease in uptake of K⁺ into the roots, both at pH 4 and pH 6. At pH 6 but not at pH 4 the reverse was true when the seedlings were pretreated with NaNO₂. Due to the high Na⁺ content of the roots, an effect of Na⁺ in this process cannot be excluded. Nitrite was taken up by the roots more rapidly than nitrate. Nitrite at 0.1 m M in the medium induced the development of an uptake system for both NO⁻₂ and NO⁻₃ in wheat roots. At higher concentrations pretreatment with NO⁻₂ decreased NO⁻₃ uptake by the roots, but NO₃ did not inhibit the uptake of NO₂. The toxic effect of NO⁻₂ was strongly pH dependent. Lower pH of the external solution led to an increased inhibition by NO⁻₂ of both ion uptake and growth of seedlings. The inhibitory effect of NO⁻₂ differed considerably for roots and shoots. The roots and especially the root hairs were particularly sensitive to NO⁻₂ treatment.     

Soybean root and nodule nitrate reductase

Nitrate reductase (NR) activity was followed in root and nodule from Glycine max (L.) Merr. (Cv. Tracy) inoculated with Rhizobium japonicum . Initially, a plus NO^3- in vivo assay was used. When chlorate-resistant mutants were used as inoculum, nodule NR activity was reduced by about 90%. indicating that the bacteroid accounts for much of the normal nodule's NR. With plants 3 to 15 weeks of age nodule NR activity (g fresh weight)^-1 was highest in young plants and root activity highest in old plants. Root and nodule total NR activity increased with plant age and were often not greatly different. Root NR activity correlated with plant NO^3- supply and increased from 0.8 to 11.4 μmol plant^-1 h^-1 as NO^3- was increased from 0 to 3 m M . In contrast, nodule NR activity was high in plants grown without NO^3- and did not appear to increase as nitrate supply to the plant was increased. Nodule activity was 6 to 14 μmol NO^2- plant^-1 h^-1. Use of a minus NO^3- in vivo assay had little affect on root NR activity, but greatly reduced nodule activity. Root tissue was found to have 5 to 38 times more NO^3- than nodule tissue. It is concluded that low nitrate levels within the nodule limit NR activity and that it is improbable that the nodule is a major site of plant nitrate reduction.     

Occurrence and activity of hydrogenase in symbiotic Frankia from field-collected Alnus incana

Occurrence and activity of the hydrogen uptake enzyme were studied in root nodule homogenates made from plants of Alnus incana (L.) Moench collected from field sites in the northern part of Sweden. Nitrogenase (EC 1.7.99.2) activity (estimated by acetylene reduction) and hydrogen evolution were studied in excised nodules. All Frankia sources showed acetylene reduction activity, and possessed a hydrogen uptake system. Hydrogen uptake in nodule homogenates from the Frankia sources measured at 23.8 μM H₂ ranged from 0.04 to 5.0 μmol H₂ (g fresh weight nodule)⁻¹ h⁻¹. The H₂ uptake capacity of nodule homogenates from one of the Frankia sources was almost 8 times higher than the hydrogen evolution from nitrogenase, both expressed on a nodule fresh weight basis. Frankia sources from field sites 6 and 11 showed K_m for H₂ of 13.0 and 23.6 μM H₂, respectively. This indicates similarities in the hydrogen uptake enzymes in the two Frankia sources. It is concluded that hydrogen uptake is a common characteristic in Frankia.     

Nitrate reductase activity, nitrogenase activity and photosynthesis of black alder exposed to chilling temperatures

Actinorhizal ( Frankia -nodulated) black alder [ Alnus glutinosa (L.) Gaertn.] seedlings fertilized with 0.36 m M nitrate (low nitrate fertilizer treatment) or 7.14 m M nitrate (high nitrate fertilizer treatment) and acclimated in a growth chamber for 2 weeks were exposed to 2.5 h of night-time chilling temperatures of −1 to 4°C. Cold treatment decreased nitrogenase activity (acetylene reduction activity) 33% for low nitrate fertilized plants and 41% for high nitrate fertilized plants. Recovery of nitrogenase activity occurred within 7 days after chilling treatment. In contrast, in vivo nitrate reductase (NR) activities of leaves and fine roots increased immediately after chilling then decreased as nitrogenase activities recovered. Fine roots of alder seedlings exhibited NR activities proportional to the amounts of nitrate in the rooting medium. In contrast, the NR activities of leaves were independent of substrate and tissue nitrate levels and corresponded to nitrogenase activity in the root nodules. In a separate experiment, net photosynthesis (PS) of similarly treated black alder seedlings was measured before and after chilling treatments. Net PS declined in response to chilling by 17% for plants receiving low nitrate fertilizer and 19% for plants receiving high nitrate fertilizer. After chilling, stomatal conductance (g_s) decreased by 39% and internal CO₂ concentration (c_i) decreased by 5% in plants receiving the high nitrate fertilizer, whereas plants receiving the low nitrate fertilizer showed no change in g_s and a 13% increase in c_i. Results indicate that chilling stimulates stomatal closure only at the high nitrate level and that interference with biochemical functions is probably the major impact of chilling on PS.     

Cesium-insensitive mutants of Arabidopsis thaliana

The molecular analysis of solute transport across the plasma membrane in animals and microorganisms has been aided by the analysis of well-defined transport mutants. To obtain mutant plants with genetic defects in cation transport, the inhibitory effect of monovalent cations (Li⁺, Na⁺, Rb⁺, and Cs⁺) on Arabidopsis thaliana seed germination was tested. Cesium was unique in that at low concentration it strongly inhibited seedling development. In this report it is demonstrated that cesium is a competitive inhibitor for potassium transport in A. thaliana and its toxicity is closely tied to the level of potassium supplied. Conditions were obtained to maximize the cesium-sensitivity for seed germination in a large population, and selection for resistance using M₂ seeds derived from ethyl methane sulfonate (EMS)-treated plants yielded several dozen resistant plants. Seeds derived from these plants yielded cesium-insensitive mutant lines with heritable changes in energy-dependent potassium uptake. In progeny from a backcross to wild-type plants, at least one of the lines showed the segregation ratio expected for a single-gene recessive mutation and an RFLP analysis mapped the mutant locus to the top of chromosome 4.     

Effects of saponin extracts from Solanum elaeagnifotium fruits on ion uptake by clover seedlings

Solanum elaeagnifolium Cav. fruits contain high concentrations of steroidal saponins. Treatment of 3-day-old clover seedlings with aqueous fruit extracts modified Ca²⁺ uptake without significantly altering K⁺ and H₂PO₄⁻ uptake. The extracts increased Ca²⁺ uptake in the concentration range of 0.2 to 20 m M Ca²⁺. Uptake curves could be represented by two phases. In the lower phase (0.2-1.0 m M Ca²⁺), this change could be related to an increase in V_max. Pretreatment of seedlings with saponin extracts significantly reduced ATP-dependent Ca²⁺ uptake and Ca²⁺-dependent ATPase activity in a fraction isolated from root homogenates by centrifugation at 1500 g for 15 min. Saponins purified from S. eleagnifolium extracts by thin-layer chromatography modified in vitro the Ca²⁺-ATPase activity of this fraction, indicating that the steroid may act directly on Ca²⁺ transport across membranes.     

Nitrate and nitrite reduction by alfalfa root nodules: Accumulation of nitrite in Rhizobium melioti bacteroids and senescence of nodules

Addition of NO⁻₃ rapidly induced senescence of root nodules in alfalfa ( Medicago sativa L. cv. Aragon). Loss of nodule dry matter began at the lowest NO⁻₃ concentration (10 m M ) but degradation of bacteroid proteins was only detected when nodules were supplied with NO⁻₃ concentrations above 20 m M .
Bacteroids from Rhizobium meliloti contained high specific activities of nitrate reductase (NR) and nitrite reductase (NiR). Both enzymes were presumably substrate-induced although substantial enzyme activities were present in the absence of NO⁻₃ Typical specific activities for soluble NR and NiR of bacteroids under NO⁻₃ free conditions were 1.2 and 1.4 μmol (mg protein)⁻¹h⁻¹, respectively. In the presence of NO⁻₃, the specific activity of NR was considerably greater than that of NiR, thus causing NO⁻₂ accumulation in bacteroids. Nitrite levels in the bacteroids were linearly correlated with specific activities of NR and NiR, indicating that NO⁻₂ is formed by bacteroid NR and that this NO⁻₂ in turn, induces bacteroid NiR. Accumulation of NO⁻₂ within bacteroids also indicates that NO⁻₂ inhibits nodule activity after feeding plants with NO⁻₃     

Control of Nitrate Uptake by Phloem-Translocated Glutamine in Zea mays L. Seedlings

Abstract: The putative role of glutamine, exported from leaves to roots, as a negative feedback signal for nitrate uptake was investigated in Zea mays L. seedlings. Glutamine (Gln) was supplied by immersion of the tip-cut leaves in a concentrated solution. Nitrate (NO₃⁻) uptake was measured by its depletion in amino acid-free medium. The treatment with Gln resulted in a strong inhibition of nitrate uptake rate, accompanied by a significant enrichment of amino compounds in root tissue. The effect of N-availability on NO₃⁻ uptake was determined in split-root cultures. The plants were subjected to complete or localized N supply. Inducible NO₃⁻ uptake systems were also induced in N-deprived roots when the opposite side of the root system was supplied with KNO₃. The inhibitory effect of Gln was unaffected by localized N supply on one side of the split-root. The potential role of Gln in the shoot-to-root control of NO₃⁻ uptake is discussed.     

Nitrate reductase is inhibited in leaves of Triticum aestivum treated with high levels of copper

Copper is a potent sulfhydryl reagent which can also catalyse the generation of active oxygen. Since nitrate reductase (EC 1.6.6.1) is an SH-enzyme sensitive to oxidative environments, the relations among copper, active oxygen species and nitrate reductase (NR) activity are of interest. Foliar segments of wheat ( Triticum aestivum cv. Oasis) were floated on CuSO₄ solutions (up to 250 μ M ) for 24 h under continuous light. Copper decreased NR activity before affecting active oxygen generation as estimated by changes in oxidative parameters, including malondialdehyde, K⁺ leakage and chlorophyll degradation. Cysteine and Na-benzoate counteracted this decrease, suggesting an oxidative damage of the enzyme in leaves exposed to high copper levels. Copper-induced NR inactivation was further studied in the partially purified enzyme. Preincubation with CuSO₄ inhibited NR. Copper inhibition was reversed by subsequent incubation with EDTA, indicating that the metal bonded to key -SH groups of the enzyme. In addition, an ^˙OH-generating system (composed of CuSO₄, ascorbate and H₂O₂) irreversibly decreased the activity of purified NR to a greater extent than copper alone. Our results show that copper affects nitrogen metabolism by diminishing NR activity, involving a direct effect on key SH-groups and an indirect effect via attack by active oxygen species induced by the metal.