Regulation of Sulfate Assimilation by Nitrogen Nutrition in the Duckweed Lemna minor L

The effect of nitrate and ammonium on the extractable activity of two enzymes of assimilatory sulfate reduction, ATP sulfurylase (EC 2.7.7.4) and adenosine 5′-phosphosulfate sulfotransferase (APSSTase), was examined in Lemna minor L. cultivated under steady state conditions. Nitrate reductase (EC 1.6.6.1) was measured for comparison. Low nitrate concentrations (0.2 and 0.04 millimolar) caused a decrease in the specific activity of all three enzymes measured. Twenty-four hours after transfer to medium without a nitrogen source, the specific activity of APSSTase and nitrate reductase was at less than 30% of the original level, whereas ATP sulfurylase was still at about 80%. NH₄⁺ added to the nutrient solution caused a 50 to 100% increase in the specific activity of APSSTase within 24 hours, followed by a slow decrease. After 72 hours with NH₄⁺, the specific activity was still 25% higher than originally. During the same period, the extractable protein increased by 30% on a fresh weight basis, and total protein by 55 to 60%. Nitrate reductase activity decreased to less than 5%. After omission of NH₄⁺ from the nutrient solution extractable APSSTase activity rapidly decreased to the level of cultures with NO₃⁻ as a nitrogen source. Using [³⁵S]SO₄²⁻ as a sulfur source, an increased incorporation of label into the protein fraction could be detected when NH₄⁺ was added to the nutrient solution. This indicated that more sulfate was assimilated and used for protein synthesis. The higher extractable activity of APSSTase with NH₄⁺ may be a regulatory mechanism involved in the formation of sufficient sulfur amino acids during a period of increased protein synthesis.     

Metabolism of Glycollate by Lemna minor L. Grown on Nitrate or Ammonium as Nitrogen Source

Marques, I. A., Oberholzer, M. J. and Erismann, K. H. 1985.Metabolism of glycollate by Lemna minor L. grown on nitrateor ammonium as nitrogen source.—J. exp. Bot. 36: 1685–1697. Duckweed, Lemna minor L., grown on inorganic nutrient solutionscontaining either NH₄⁺ or NO₃^– as nitrogen source wasallowed to assimilate [1-¹⁴C]- or [2-¹⁴C]glycollate during a20 min period in darkness or in light. The incorporation ofradioactivity into water-soluble metabolites, the insolublefraction, and into the CO₂ released was measured. In additionthe extractable activity of phosphoenolpyruvate carboxylasewas determined. During the metabolism of [2-¹⁴C]glycollate in darkness, as wellas in the light, NH₄⁺ grown plants evolved more ¹⁴CO₂ than NO₃^–grown plants. Formate was labelled only from [2-¹⁴C]glycollateand in NH₄⁺ grown plants it was significantly less labelledin light than in darkness. In NO₃^– grown plants formateshowed similar radioactivity after dark and light labelling.The radioactivity in glycine was little influenced by the nitrogensource. Amounts of radioactivity in serine implied that thefurther metabolism of serine was reduced in darkness comparedwith its metabolism in the light under both nitrogen regimes.In illuminated NH₄⁺ plants, serine was labelled through a pathwaystarting from phosphoglycerate. After [1-¹⁴C]glycollate feedingNH₄⁺ grown plants contained markedly more radioactive aspartateand malate than NO₃^– plants indicating a stimulated phosphoenolpyruvatecarboxylation in plants grown on NH₄⁺. Key words: Photorespiration, glycollate, nitrogen, Lemna     

Regulation of Sulfate Assimilation by Light and O-Acetyl-l-Serine in Lemna minor L

The effect of 0.5 millimolar O-acetyl-l-serine added to the nutrient solution on sulfate assimilation of Lemna minor L., cultivated in the light or in the dark, or transferred from light to the dark, was examined. During 24 hours after transfer from light to the dark the extractable activity of adenosine 5′-phosphosulfate sulfotransferase, a key enzyme of sulfate assimilation, decreased to 10% of the light control. Nitrate reductase (EC 1.7.7.1.) activity, measured for comparison, decreased to 40%. Adenosine 5′-triphosphate (ATP) sulfurylase (EC 2.7.7.4.) and O-acetyl-l-serine sulfhydrylase (EC 4.2.99.8.) activities were not affected by the transfer. When O-acetyl-l-serine was added to the nutrient solution at the time of transfer to the dark, adenosine 5′-phosphosulfate sulfotransferase activity was still at 50% of the light control after 24 hours, ATP sulfurylase and O-acetyl-l-serine sulfhydrylase activity were again not affected, and nitrate reductase activity decreased as before. Addition of O-acetyl-l-serine at the time of the transfer caused a 100% increase in acid-soluble SH compounds after 24 hours in the dark. In continuous light the corresponding increase was 200%. During 24 hours after transfer to the dark the assimilation of ³⁵SO₄²⁻ into organic compounds decreased by 80% without O-acetyl-l-serine but was comparable to light controls in its presence. The addition of O-acetyl-l-serine to Lemna minor precultivated in the dark for 24 hours induced an increase in adenosine 5′-phosphosulfate sulfotransferase activity so that a constant level of 50% of the light control was reached after an additional 9 hours. Cycloheximide as well as 6-methyl-purine inhibited this effect. In the same type of experiment O-acetyl-l-serine induced a 100-fold increase in the incorporation of label from ³⁵SO₄²⁻ into cysteine after additional 24 hours in the dark. Taken together, these results show that exogenous O-acetyl-l-serine has a regulatory effect on assimilatory sulfate reduction of L. minor in light and darkness. They are in agreement with the idea that this compound is a limiting factor for sulfate assimilation and seem to be in contrast to the proposed strict light control of sulfate assimilation.     

Nitrogen Metabolism of Lemna minor. I. Growth, Nitrogen Sources and Amino Acid Inhibition

Lemna minor grown in sterile culture on a minerals-sucrose medium can utilize as nitrogen source, in order of increasing growth rate: ammonia, nitrate, a mixture of glutamic and aspartic acids plus arginine, or a balanced mixture of amino acids (hydrolyzed casein). Maximum growth is found with nitrate plus hydrolyzed casein.Many synthetic mixtures of amino acids are unable to support growth. Many single amino acids are inhibitory, and when added (at 2 mm or less) to cultures, growing in the presence of nitrate, cause a decrease in growth rate or even death of the plants (e.g. with alanine, valine, methionine or leucine). Some of these inhibitory effects are also found when the amino acid is added to cultures growing on ammonia or hydrolyzed casein. Arginine was the only amino acid of those tested which gave a marked stimulation of growth when added to cultures growing with inorganic nitrogen.The rapid rate of growth, sterile nature of tissue, decreased biological variation of samples containing many plants and ability to utilize different culture media make this an attractive organism for studies on higher plant metabolism.     

Amino Acid Metabolism of Lemna minor L. : II. Responses to Chlorsulfuron

Chlorsulfuron, an inhibitor of acetolactate synthase (EC 4.1.3.18) (TB Ray 1984 Plant Physiol 75: 827-831), markedly inhibited the growth of Lemna minor at concentrations of 10⁻⁸ molar and above, but had no inhibitory effects on growth at 10⁻⁹ molar. At growth inhibitory concentrations, chlorsulfuron caused a pronounced increase in total free amino acid levels within 24 hours. Valine, leucine, and isoleucine, however, became smaller percentages of the total free amino acid pool as the concentration of chlorsulfuron was increased. At concentrations of chlorsulfuron of 10⁻⁸ molar and above, a new amino acid was accumulated in the free pool. This amino acid was identified as α-amino-n-butyrate by chemical ionization and electron impact gas chromatography-mass spectrometry. The amount of α-amino-n-butyrate increased from undetectable levels in untreated plants, to as high as 840 nanomoles per gram fresh weight (2.44% of the total free pool) in plants treated with 10⁻⁴ molar chlorsulfuron for 24 hours. The accumulation of this amino acid was completely inhibited by methionine sulfoximine. Chlorsulfuron did not inhibit the methionine sulfoximine induced accumulations of valine, leucine, and isoleucine, supporting the idea that the accumulation of the branched-chain amino acids in methionine sulfoximine treated plants is the result of protein turnover rather than enhanced synthesis. Protein turnover may be primarily responsible for the failure to achieve complete depletion of valine, leucine, and isoleucine even at concentrations of chlorsulfuron some 10⁴ times greater than that required to inhibit growth. Tracer studies with ¹⁵N demonstrate that chlorsulfuron inhibits the incorporation of ¹⁵N into valine, leucine, and isoleucine. The α-amino-n-butyrate accumulated in the presence of chlorsulfuron and [¹⁵N]H₄⁺ was heavily labeled with ¹⁵N at early time points and appeared to be derived by transamination from a rapidly labeled amino acid such as glutamate or alanine. We propose that chlorsulfuron inhibition of acetolactate synthase may lead to accumulation of 2-oxobutyrate in the isoleucine branch of the pathway, and transamination of 2-oxobutyrate to α-amino-n-butyrate by a constitutive transaminase utilizing either glutamate or alanine as α-amino-N donors.     

Regulation of Nitrate Assimilation and Nitrate Respiration in Aerobacter aerogenes

The influence of growth conditions on assimilatory and respiratory nitrate reduction in Aerobacter aerogenes was studied. The level of nitrate reductase activity in cells, growing in minimal medium with nitrate as the sole nitrogen source, was much lower under aerobic than anaerobic conditions. Further, the enzyme of the aerobic cultures was very sensitive to sonic disintegration, as distinct from the enzyme of anaerobic cultures. When a culture of A. aerogenes was shifted from anaerobic growth in minimal medium with nitrate and NH(4) (+) to aerobiosis in the same medium, but without NH(4) (+), the production of nitrite stopped instantaneously and the total activity of nitrate reductase decreased sharply. Moreover, there was a lag in growth of about 3 hr after such a shift. After resumption of growth, the total enzymatic activity increased again slowly and simultaneously became gradually sensitive to sonic disintegration. These findings show that oxygen inactivates the anaerobic nitrate reductase and represses its further formation; only after a de novo synthesis of nitrate reductase with an assimilatory function will growth be resumed. The enzyme in aerobic cultures was not significantly inactivated by air, only by pure oxygen. The formation of the assimilatory enzyme complex was repressed, however, by NH(4) (+), under both aerobic and anaerobic conditions. The results indicate that the formation of the assimilatory enzyme complex and that of the respiratory enzyme complex are regulated differently. We suggest that both complexes have a different composition, but that the nitrate reductase in both cases is the same protein.     

Nitrogen Utilization in Lemna: II. Studies of Nitrate Uptake Using NO(3)

¹³N-labeled nitrate was used to trace short-term nitrate influx into Lemna gibba L. G3 in experiments where disappearance of both radioactivity and total nitrate from the incubation medium was measured continuously and simultaneously. In plants performing net nitrate uptake from an initial nitrate concentration of 40 to 60 micromolar, there was no discrepancy between net uptake and influx, irrespective of the N status of the plants, indicating that concomitant nitrate efflux was low or nil. Plants treated with tungstate to inactivate nitrate reductase were able to take up nitrate following induction of the uptake system by exposure to a low amount of nitrate. Also, in this case, net uptake was equivalent to influx. In tungstate-treated plants preloaded with nitrate, both net uptake and influx were nil. In contrast to these observations, a clear discrepancy between net uptake and influx was observed when the plants were incubated at an initial nitrate concentration of approximately 5 micromolar, where net uptake is low and eventually ceases. It is concluded that plasmalemma nitrate transport is essentially unidirectional in plants performing net uptake at a concentration of 40 to 60 micromolar, and that transport is nil when internal nitrate sinks (vacuole, metabolism) are eliminated. The efflux component becomes increasingly important when the external concentration approaches the threshold value for net nitrate uptake (the nitrate compensation point) where considerable exchange between internal and external nitrate occurs.     

Regulation of Sulfate Assimilation in Plants: 7. Cysteine Inactivation of Adenosine 5'-Phosphosulfate Sulfotransferase in Lemna minor L

When 0.5 mm cysteine is added to cultures of Lemna minor L. growing with sulfate as the sole sulfur source, there is a rapid 80% loss of extractable adenosine 5′-phosphosulfate sulfotransferase. This loss is accompanied by an inhibition of sulfate uptake; however, lack of sulfate is not responsible for the decreasing adenosine 5′-phosphosulfate sulfotransferase activity.     

Flower Induction by Suppression of Nitrate Assimilation in Lemna paucicostata 6746

In vitro activity of nitrate reductase was studied in Lemnapaucicostata 6746 grown on modified Hoagland medium supplementedwith 1% sucrose, containing various inhibitors. Copper, silver,tungstate or cyanide which induces daylength-independent flowering,inhibited the nitrate reductase activity, but azide which doesnot induce daylength-independent flowering did not. Molybdate-deficientmedium induced flowering, and inhibited nitrate reductase activity.Lowering of nitrate level of the medium also induced daylength-independentflowering. These results suggest that the suppression of nitrate assimilationcauses daylength independent flowering in Lemna paucicostata6746, and that one of the flower-inducing actions of the copper,silver, tungstate, cyanide or the deletion of molybdate is tosuppress the nitrate assimilation. (Received June 26, 1985; Accepted October 30, 1985)     

Influence of Nitrogen Availability on Aminotransferases in Lemna minor L.

Protein contents and glutamate: glyoxylate, serine: glyoxylate,alanine: glyoxylate and glutamate: pyruvate aminotransferaseactivities per gram fresh weight declined sharply when Lemnaminor L., previously grown on nitrate medium, was starved ofnitrogen. Nitrogen replenishment after 5 d caused complete recoveryof these parameters with higher values in ammonium-fed thannitrate-fed plants 7 d after transfer of plants from nitrogen-freemedium. Glutamate: glyoxylate and alanine: glyoxylate aminotransferasespecific activities (based on total extracted protein) showedlittle change with nitrogen availability. Serine: glyoxylateaminotransferase increased slowly during nitrogen starvationand decreased following nitrogen replenishment whether withammonium or nitrate. After 1 d of nitrogen starvation the specificactivity of glutamate: pyruvate aminotransferase declined; itincreased following nitrogen replenishment and ammonium gaverise to agreater activity than nitrate. The results are discussed in relation to the differences instability of the various enzymes relative to the overall proteinturnover rate. Key words: Aminotransferases, Nitrogen source, Photorespiration     

Phosphate Regulation of Nitrate Assimilation in Soybean

It is known that phosphorus deficiency results in alterationsin the assimilation of nitrogen. An experiment was conductedto investigate mechanisms involved in altered ¹⁵NO^–₃ uptake,endogenous ¹⁵N translocation, and amino acid accumulation insoybean (Glycine max L. Merrill, cv. Ransom) plants deprivedof an external phosphorus supply for 20 d in solution culture.Phosphorus deprivation led to decreased rates of ¹⁵NO^–₃uptake and increased accumulation of absorbed ¹⁵N in the root.Both effects became more pronounced with time. Asparagine, theprimary transport amino acid in soybean, accumulated in largeexcess in roots and stems. In roots of phosphorus-deprived plants,concentrations of ATP and inorganic phosphate declined rapidly,but dry weight accumulation was similar to or above that ofthe control even after 20 d of treatment. Arginine accumulationin leaves was greatly enhanced, even though ¹⁵N partitioninginto the insoluble reduced-N fraction of leaves was unaffected.The results suggest that decreases in NO^–₃ uptake in lowphosphorus plants could be caused by feedback control factorsand by limited ATP availability. The decline in endogenous Ntransport from the root to the shoot may be associated withchanges in membrane properties, which also result in paralleleffects on hydraulic conductance and the upward flow of waterthrough the plant. Key words: Phosphorus stress, nitrate uptake, nitrate translocation, arginine     

The Regulation of Nitrite Reductase Level in Lemna minor L.

The regulation of nitrite reductase in Lemna minor has beenstudied. The evidence indicates that in nitrate-fed plants nitrateitself is the inducer of nitrite reductase. The enzyme is subjectto end-product repression by ammonia and various amino acids.Nitrate reductase is also repressed by a similar range of compounds.Most of the repressors tested are more effective when nitraterather than nitrite is supplied as the inducer. The effectsof cyclo-heximide, D-threo-chloramphenicol and lincomycin onthe induction by nitrate and nitrite suggest that both enzymesare synthesized on cytoplasmic ribosomes. The mechanism of repressionby ammonia and amino acids is discussed.     

Some Aspects of Nitrate Assimilation in the Seedlings of Normal and Opaque-2 Mutant of Maize

The effects of 10 mM nitrate on the growth and nitrogenous componentsof Zea mays L. var. W64A wild type (normal) were compared tothose on its opaque-2 (high lysine) mutant during the first10 d of seedling growth at a constant temperature of 26 °Cand with a 16 h photoperiod. Nitrate supply had no effect onthe growth of embryonic axes in both lines till day 6. Growthof both lines was enhanced slightly after that time, however.Increases in 80% (v/v) ethanolsoluble and protein nitrogen werealso observed only after day 4 when the supply of nitrogen fromthe storage proteins in the endosperm was limiting. Nitratehad no effect on the synthesis of chlorophyll during leaf developmentbut it did increase the total chlorophyll in mature and senescingprimary leaves. The increase in nitrogenous components or chlorophyllin opaque-2 was more pronounced than in the normal type. Itmight be related to the lower proline or higher lysine in themutant.     

Ferricyanide Induces Flowering by Suppression of Nitrate Assimilation in Lemna paucicostata 6746

Lemna paucicostata 6746, a short-day plant, produced flowerbuds even under continuous light when cultured for 3 days inferricyanide containing ammonium-free medium followed by cultureon nitrogen-rich medium (either nitrate or ammonium). Dailytreatment with ferricyanide in the absence of ammonium for morethan 8 hours, which completely inhibited nitrate reductase activitywithin 6 hours after the addition to the medium, induced daylength-independentflowering even when the ammonium-rich medium was given duringthe remaining hours. The presence of ammonium for 1 hour atthe middle of the 14-h ferricyanide treatment almost completelysuppressed floral induction. (Received March 6, 1986; Accepted June 3, 1986)     

Effect of Nitrogen Supply on the Kinetics and Regulation of Nitrate Assimilation in Chlamydomonas reinhardtii Dangeard

Concentration-dependent NO     

Some characteristics of nitrate reductase induction in Lemna minor L.

Summary Low levels of nitrate reductase can be detected in plants of Lemna minor grown on some organic nitrogen sources. Nitrogen-starvation does not lead to a derepression of nitrate reductase activity. Nitrate ions are necessary for the development of maximum enzyme activity and the maintenance of high enzyme levels. Nitrogen-starvation of ammonia-grown plants increases the subsequent rate of nitrate-mediated induction. It is suggested that ammonium ions, either directly or indirectly modulate the rate of nitrate reductase induction. The pattern of control regulating nitrate reductase levels in Lemna is contrasted with that in some species of algae.     

Methanol Assimilation in Methylobacterium extorquens AM1: Demonstration of All Enzymes and Their Regulation

Background

Methylobacterium extorquens AM1 is an aerobic facultative methylotrophic α-proteobacterium that can use reduced one-carbon compounds such as methanol, but also multi-carbon substrates like acetate (C₂) or succinate (C₄) as sole carbon and energy source. The organism has gained interest as future biotechnological production platform based on methanol as feedstock.

Methodology/Principal Findings

We present a comprehensive study of all postulated enzymes for the assimilation of methanol and their regulation in response to the carbon source. Formaldehyde, which is derived from methanol oxidation, is assimilated via the serine cycle, which starts with glyoxylate and forms acetyl-CoA. Acetyl-CoA is assimilated via the proposed ethylmalonyl-CoA pathway, which thereby regenerates glyoxylate. To further the understanding of the central carbon metabolism we identified and quantified all enzymes of the pathways involved in methanol assimilation. We observed a strict differential regulation of their activity level depending on whether C₁, C₂ or C₄ compounds are used. The enzymes, which are specifically required for the utilization of the individual substrates, were several-fold up-regulated and those not required were down-regulated. The enzymes of the ethylmalonyl-CoA pathway showed specific activities, which were higher than the calculated minimal values that can account for the observed growth rate. Yet, some enzymes of the serine cycle, notably its first and last enzymes serine hydroxymethyl transferase and malate thiokinase, exhibit much lower values and probably are rate limiting during methylotrophic growth. We identified the natural C₁ carrying coenzyme as tetrahydropteroyl-tetraglutamate rather than tetrahydrofolate.

Conclusion/Significance

This study provides the first complete picture of the enzymes required for methanol assimilation, the regulation of their activity levels in response to the growth substrate, and the identification of potential growth limiting steps.     

Regulation of root growth by gibberellin in Lemna minor

Hormonal control of root growth was studied in Lemna minor. Although addition of gibberellic acid (GA3) to the culture medium did not promote the root growth, a gibberellin biosynthesis inhibitor, uniconazole P (Un-P), significantly inhibited root growth. Both length and diameter of roots in Un-P-treated plants were significantly smaller than those in control plants, mainly caused by inhibition of cell division. In epidermal cells, the length was slightly decreased and the width increased by Un-P treatment, indicating inhibition of elongation growth. GA3 completely nullified the inhibition caused by Un-P. Transverse cortical microtubules (CMTs) of epidermal cells in the elongation zone were significantly fragmented by treatment with Un-P, but not by that in the presence of GA3. The cellulose microfibril array in the Un-P-treated cells was more random and more oblique than that in the control cells. These results suggested that root growth in L. minor is regulated by endogenous gibberellin.     

Investigations on Cytokinins. IV. The Metabolism of 6-Benzylaminopurine in Lemna minor

The metabolism of ¹⁴C-labeled 6-benzylaminopurine in aseptic cultures of Lemna minor was investigated. This cytokinin is slowly taken up by the plants; part of it can be released and part of it is rapidly metabolized to several compounds, among which the corresponding nucleotides can be identified. In this connection the feasibility of locating the site of hormone receptors (sites of primary action) in plants is discussed. Incorporation of the labeled cytokinin into Lemna tRNA was not observed, although tRNA hydrolysates, isolated from plants grown on a cytokinin-free medium, contain a fair amount of cytokinin activity and therefore presumably cy okinin molecules.