Regulation of nitrate uptake by amino acids in maize cell suspension culture and intact roots

The effect of amino acids on nitrate transport was studied in Zea mays cell suspension cultures and in Zea mays excised roots. The inclusion of aspartic acid, arginine, glutamine and glycine (15mM total amino acids) in a complete cell-culture media containing 1.0 mM NO₃ ^- strongly inhibited nitrate uptake and the induction of accelerated uptake rates. The nitrate uptake rate increased sharply once solution amino acid levels fell below detection limits. Glutamine alone inhibited induction in the cell suspension culture. Maize seedlings germinated and grown for 7 days in a 15 mM mixture of amino acids also had lower nitrate uptake rates than seedlings grown in 0.5 mM Ca(NO₃)₂ or 1 mM CaCl₂. As amino acids are the end product of nitrate assimilation, the results suggest an end-product feed-back mechanism for the regulation of nitrate uptake.     

Substitution of glutamine by pyruvate to reduce ammonia formation and growth inhibition of mammalian cells

In mammalian cell culture technology glutamine is required for biomass synthesis and as a major energy source together with glucose. Different pathways for glutamine metabolism are possible, resulting in different energy output and ammonia release. The accumulation of ammonia in the medium can limit cell growth and product formation. Therefore, numerous ideas to reduce ammonia concentration in cultivation broths have been developed. Here we present new aspects on the energy metabolism of mammalian cells. The replacement of glutamine (2 mM) by pyruvate (10 mM) supported cell growth without adaptation for at least 19 passages without reduction in growth rate of different adherent commercial cell lines (MDCK, BHK21, CHO-K1) in serum-containing and serum-free media. The changes in metabolism of MDCK cells due to pyruvate uptake instead of glutamine were investigated in detail (on the amino acid level) for an influenza vaccine production process in large-scale microcarrier culture. In addition, metabolite profiles from variations of this new medium formulation (1-10 mM pyruvate) were compared for MDCK cell growth in roller bottles. Even at very low levels of pyruvate (1 mM) MDCK cells grew to confluency without glutamine and accumulation of ammonia. Also glucose uptake was reduced, which resulted in lower lactate production. However, pyruvate and glutamine were both metabolized when present together. Amino acid profiles from the cell growth phase for pyruvate medium showed a reduced uptake of serine, cysteine, and methionine, an increased uptake of leucine and isoleucine and a higher release of glycine compared to glutamine medium. After virus infection completely different profiles were found for essential and nonessential amino acids.     

Nitrate transport in Zea mays cell suspension cultures: the effect of solution composition and cell age

Nitrate transport characteristics of an amino acid-grown Zeamays P3377 cell culture line were studied. Age (days after subculturing)of the cells was shown to have a significant effect on transport; older stationary phasecultures did not absorb nitrate from the medium as rapidly asyounger growing cultures. Solution composition had a pronouncedimpact on induction of accelerated nitrate transport and transportrates. Maximum uptake rates required fresh culture media ratherthan simple solutions. Differences in ionic strength among uptakesolutions of equal concentration were shown to affect the apparent uptake rates by changing theactivity coefficient of . The uptake kinetics were established by following uptake for 24h in a wide range of nitrate concentrations. Uptake patternsof cells in solutions ranging from 0.02 to 2 mM were as typicallyreported for plants. The kinetic constants for the Zea mayscell suspension cultures concurred with reports of other solution-culturedcells. When cells were placed in solutions containing greater than 2 mM, uptake patternssuggested a significant passive uptake component. Passive diffusionof was estimated by Nernst analysis and indicated to be an important component of nitrateuptake in maize cell suspension cultures grown in the absenceof nitrate then transferred into nitrate-containing media. Key words: Cell suspension culture, nitrate, passive uptake, Zea mays     

The effects of amino acids and ammonium on the growth of plant cells in suspension culture

A suspension culture of soybean (Glycine max L.) was grown on a defined medium in which the nitrogen sources were nitrate (25 mM) and ammonium (2 mM). The cells did not grow on nitrate unless the medium was supplemented with ammonium or glutamine. The l- and d-isomers of 12 amino acids tested singly could not replace ammonium. Most amino acids (4 mM) inhibited growth when the cells were cultured on nitrate and ammonium. Cells from five other plants (Reseda luteoli L.; Triticum monococcum L.; flax, Linum usitatissimum L.; horseradish, Amoracia lapathifolia Gilib; Haplopappus gracilis L.) grew on the defined medium with nitrate (25 mM) as the sole nitrogen source. Higher cell yields were obtained when ammonium (2 mM) or glutamine also was present. Supplementing the defined medium with high concentrations of ammonium (20 mM) inhibited growth of soybean, Haplopappus, and wheat cells. Addition of citrate (5 mM) relieved the inhibitory effects of ammonium in soybean and wheat cells but not in the Haplopappus cells.     

An amino-acid-grown maize cell line for use in investigating nitrate assimilation

Summary Studies on uptake and assimilation of nitrate in plants are confounded by differences in cell function associated with anatomical features of roots as well as by problems inherent with growing plants without nitrate. To circumvent these problems, a Zea mays L. embryo cell line was grown in suspension culture using an amino-acid-based medium consisting of a Murashige and Skoog medium in which ammonium and nitrate were replaced by aspartic acid (100 mg/l), glycine (100 mg/l), arginine (150 mg/l), and glutamine (1 g/l). The growth, cellular characteristics, and physical appearance of the amino-acid-grown cells were similar to cells grown in the presence of nitrate. The amino-acid-grown cells exhibited the expected induction pattern and inhibitor sensitivity of nitrate uptake. This cell line should facilitate research on the induction of nitrate uptake and the regulation of nitrate assimilation into proteins.     

Ammonium and amino acids as regulators of nitrate reductase in corn roots

When amino acids or ammonia are added to plant systems, the effects on the development of nitrate-dependent nitrate reductase activity are variable. In addition, amino acids added singly or as casein hydrolysate may not support a normal growth. A physiologically correct mixture of amino acids, one similar in composition to amino acids released by the endosperm, has been shown to support normal growth and protein synthesis in corn (Zea mays) embryos. In this investigation, we have used the mixture of corn amino acids to determine whether amino acids have an effect on the appearance or disappearance of nitrate reductase activity. The results show that these amino acids partially inhibit the induction of nitrate reductase in corn roots. The effect is more pronounced in mature root than in root tip sections. When glutamine and asparagine are included along with the "corn amino acid mixture," the inhibition is more severe. Amino acids or amino acid analogues added singly to the induction medium have a similar effect: i.e. when the induction of nitrate reductase is inhibited in the root tips (lysine, canavanine, azaserine, azetidine-2-carboxylic acid, dl-4-azaleucine, asparagine, and glutamine), that inhibition is more severe in mature root sections. Arginine enhanced the recovery of nitrate reductase in root tips but inhibited it in mature root sections. The effect of the amino acids is apparently on some phase of the induction processes (i.e. the uptake or distribution of nitrate or a direct effect on the synthesis of the enzyme) and not on the turnover of the enzyme.     

Nutrient modifications for improved growth of Brassica nigra cell suspension cultures

Cell pellet yield of two Brassica nigra suspension cultures was stimulated by amino acid supplements in the growth medium. This could confound the interpretation of amino acid feeding studies involved in characterizing amino acid metabolism mutants. The nutritional requirements of one of the Brassica nigra suspension cultures growing in modified Murashige & Skoog medium were therefore reviewed. Sucrose at 2% w/v was growth limiting and amino or organic acid supplements stimulated growth rate and yield. Increasing sucrose to 6% and supplementing with 15 mM sodium succinate increased maximum cell pellet volume by 2.7 times and maximum dry weight by 2.8 times, stimulated cell enlargement and produced similar maximum numbers of cells per culture. The further addition of an amino acid supplement of 4 mM alanine, 4 mM glutamine and 1 mM glutamate produced no further improvement. The revised medium was more strongly buffered, supported cell growth for a longer period and permitted a 30-fold reduction in the minimum cell inoculum. Cells grown in the revised medium are 10-fold more resistant to growth inhibition by the tryptophan analogue 5MT. These advantages recommend the revised medium for amino acid feeding, mutant isolation and similar studies.     

Glutamine transport and feedback regulation of nitrate reductase activity in barley roots leads to changes in cytosolic nitrate pools

The size of tissue amino acid pools in plants may indicate nitrogen status and provide a signal that can regulate nitrate uptake and assimilation. The effects of treating barley roots with glutamine have been examined, first to identify the transport system for the uptake of the amino acid and then to measure root NR activity and cellular pools of nitrate. Treating N replete roots with glutamine elicited a change in the cell membrane potential and the size of this response was concentration dependent. In addition, the size of the electrical change depended on the previous exposures of the root to glutamine and was lost after a few cycles of treatment. Whole root tissue pools of glutamine and phenylalanine increased when roots were incubated in a nutrient solution containing 10 mM nitrate and 1 mM glutamine. Treating roots with 1 mM glutamine increased cytosolic nitrate activity from 3 mM to 7 mM and this change peaked after 2 h of treatment. Parallel measurements of root nitrate reductase activity during treatment with 1 mM glutamine showed a decrease. These measurements provide evidence for feedback regulation on NR activity that result in changes in cytosolic nitrate activity. After 6 h in glutamine both root NR activity and cytosolic nitrate activity returned to pretreatment values, while tissue concentrations of glutamine and phenylalanine remained elevated. The data are discussed in terms of the mechanisms that are most likely to be responsible for the changes in cytosolic nitrate.     

Accumulation of Glutamine by Suspension Cultures of Symphytum officinale

A callus was induced from the veins of a leaf of Symphytum officinale, comfrey, on a medium containing the inorganic elements reported by Murashige and Skoog with addition of 3% sucrose, 0.5 mg/liter 2,4-D and 0.3~3.0 mg/liter kinetin.

Suspension cultures of this cell line obtained from the callus were shown to accumulate a large amount of L-glutamine intracellularly, The effect of growth hormones and nutrients on accumulation of the amino acid has been examined in suspension cultures. The most suitable concentrations of 2,4-D and kinetin for glutamine accumulation were 0.3 mg/liter each. The presence of potassium nitrate as a nitrogen source was beneficial for growth and ammonium nitrate stimulated the accumulation of glutamine. High levels of these nitrogen sources in the medium were required for obtaining a high level of glutamine. The concentration of glutamine accumulated reached to approximately 20% of dry cell weight when S. officinale was incubated in the medium containing 0.495 % of ammonium nitrate and 0.570% of potassium nitrate which corresponded to three times higher levels than those in a Murashige and Skoog’s medium.

Most of the amino acid was found intracellularly but a small amount was excreted into the medium in the later stages of the incubation. Addition of a cationic surfactant, cetyltrimethylammonium bromide, to the cultures caused to increase the amount of the amino acid in the culture filtrate.

The contents of free amino acids in leaves of S. officinale were compared with those in the callus. The level of glutamine in the callus was 260 times higher than that in the intact plant.     

Differential regulation of nitrate reductase induction in roots and shoots of cotton plants

The induction of nitrate reductase activity in root tips of cotton (Gossypium hirsutum L.) was regulated by several amino acids and by ammonium. Glycine, glutamine, and asparagine strongly inhibited induction of activity by nitrate and also decreased growth of sterile-cultured roots on a nitrate medium. Methionine, serine, and alanine weakly inhibited induction, and 11 other amino acids had little or no effect. Ammonium also decreased induction in root tips, but was most effective only at pH 7 or higher. The optimum conditions for ammonium regulation of induction were identical to those for growth of sterile-cultured roots on ammonium as the sole nitrogen source. Aspartate and glutamate strongly stimulated induction, but several lines of evidence indicated that the mechanism of this response was different from that elicited by the other amino acids. The effects of amino acids on induction appeared to be independent of nitrate uptake.     

Human 293 cell metabolism in low glutamine-supplied culture: interpretation of metabolic changes through metabolic flux analysis

Metabolic flux analysis is a useful tool to analyze cell metabolism. In this study, we report the use of a metabolic model with 34 fluxes to study the 293 cell, in order to improve its growth capacity in a DMEM/F12 medium. A batch, fed-batch with glutamine feeding, fed-batch with essential amino acids, and finally a fed-batch experiment with both essential and nonessential amino acids were compared. The fed-batch with glutamine led to a maximum cell density of 2.4x10(6) cells/ml compared to 1.8x10(6) cells/ml achieved in a batch mode. In this fed-batch with glutamine, it was also found that 2.5 mM ammonia was produced compared to the batch which had a final ammonia concentration of 1 mM. Ammonia was found to be growth inhibiting for this cell line at a concentration starting at 1 mM. During the fed-batch with glutamine, the flux analysis shows that a majority of amino acid fluxes and Kreb's cycle fluxes, except for glutamine flux, are decreased. This observation led to the conclusion that the main nutrient used is glutamine and that during the batch there is an overflow in the Kreb's cycle. Thus, a fed-batch with glutamine permits a better utilization of this nutrient. A fed-batch with essential amino acid without glutamine was also assayed in order to reduce ammonia production. The maximum cell density was increased further to 3x10(6) cells/ml and ammonia production was reduced below 1 mM. Flux analysis shows that the cells could adapt to a medium with low glutamine by increasing the amino acid fluxes toward the Kreb's cycle. Adding nonessential amino acids during this feeding strategy did not improve growth further and the nonessential amino acids accumulated in the medium.     

The differential transport of amino acids into the phloem of Ricinus communis L. seedlings as shown by the analysis of sieve-tube sap

The cotyledons of castor bean (Ricinus communis L.) act as absorption organs for amino acids, which are supplied to the medium. The analysis of the sieve-tube sap, which exudes from the cut hypocotyl, demonstrated the ability of the cotyledons to load particular amino acids into the phloem and to reject the loading of others. The sieve-tube sap of cotyledons, which were embedded in the endosperm, contained 150 mM amino acids, with 50 mM glutamine as the major amino acid, and 10–15 mM each of valine, isoleucine, lysine and arginine. Removal of the endosperm led to a drastic decline in the amino-acid content of sieve-tube sap down to 16 mM. Addition of single amino acid species to the medium increased the amino acid concentration in the sieve-tube sap in specific manner: glutamine caused the largest increase (up to 140 mM in exudate), glutamate and alanine smaller increases (up to 60 mM), and arginine the smallest. In addition, the amino acid composition of the sieve-tube sap changed, for instance, glutamine or alanine readily appeared in the sieve-tube sap upon incubation in glutamine or alanine, respectively, whereas glutamate was hardly discernible even in the case of incubation with glutamate; arginine was loaded into the sieve tubes only reluctantly. In general, glutamine and alanine accumulated four- to tenfold in the sieve tubes. The uptake of amino acids and of sucrose into the sieve tubes was interdependent: the loading of sucrose strongly reduced the amino acid concentration in the sieve-tube exudate and loading of amino acids decreased the sucrose concentration. Comparison of the concentrations of various amino acids on their way from the endosperm via the cotyledon-endosperm interface, through the cotyledons and into the sieve tubes showed that glutamine, valine, isoleucine and lysine are accumulated on this pathway, whereas glutamate and arginine are more concentrated in the cotyledons than in the sieve tubes. Obviously the phloem-loading system has a transport specificity different from that of the amino acid uptake system of the cotyledon in general and it strongly discriminates between amino acids within the cotyledons.     

Nitrogen nutrition in the cyanobacterium Nostoc ANTH, a symbiotic isolate from Anthoceros: uptake and assimilation of inorganic-n and amino acids

Amino acid uptake and utilization of various nitrogen sources (amino acids, nitrite, nitrate and ammonia) were studied in Nostoc ANTH and i ts mu tant (Het(-)Nif(-)) isolate defective in heterocyst formation and N2-fixation. Both parent and its mutant grew at the expense of glutamine, asparagine and arginine as a source of fixed-nitrogen. Growth was better in glutamine-and asparagine-media as compared to that in arginine media. Glutamine and asparagine repressed heterocyst formation, N2-fixation and nitrate reduction in Nostoc ANTH, but arginine did so only partially. The poor growth in arginine-medium was not due to poor uptake rates, since the uptake rates were not significantly different from those for glutamine or asparagine. The glutamine synthetase activity remained unaffected during cultivation in media containing any one of the three amino acids tested. The uptake of amino acids was substrate-inducible, energy-dependent and required de novo protein synthesis. Nitrate and ammonium repressed ammonium uptake, but did not repress uptake of amino acids. In N2-medium (BG-11(0)), the uptake of ammonium and amino acids in the mutant was significantly higher than its parent strain. This was apparently due to nitrogen limitation since the mutant was unable to fix N2 and the growth medium lacked combined-N.     

Effects of Nutrient Supply on Seed Growth of Field Bean (Vicia faba L.). 1. Effects of Different Sulphur and Methionine Regimes on Cotyledon Growth, Protein and Uncombined Amino Acids In vitro

The effects of differemt S and methionine regimes on growthof developing Vicia faba cotyledons in vitro were studied. Basalmedium (containing adequate S) supplemented with 05 mM methioninemarginally increased d. wt and uncombined amino acid accumulationbut adding 1–5 mM methionine inhibited both growth andprotein accumulation. Sulphur deficiency reduced both d. wtand protein accumulation but incresed accumulation of uncombinedamino acids. Adding 1 mM methionine to the S-deficient mediumrestored growth, normal protein and uncombined amino acid acnunulation.High sulphate medium (7.5 mM ) decreased d. wt, protein anduncombined amino acid accumulation. High sulphate medium or basal medium+methionine (05 mM) changedthe proportions of the seed proteins; legumin increased butvicilin decreased. Sulphur deficiency caused a relative increasein vicilin but a decrease in legumin. The different S and methionineregimes markedly changed the composition of the uncombined aminoacids, especially those derived from aspartic acid but not thecomposition of the protein fraction, except during S deficiency. The data presented indicates a flexibility in the storage proteincomposition of developing cotyledons grown in vitro, with theS and methionine status having a regulatory effect. Vicia faba L., field bean, cotyledon, growth, in vitro culture, uncombined amino acids, protein composition, legumin, vicilin, methionine, sulphur     

Amino Acid interactions in the regulation of nitrate reductase induction in cotton root tips

Glycine, asparagine, and glutamine inhibited the induction by nitrate of nitrate reductase activity in root tips of cotton (Gossypium hirsutum L.). This inhibition was partially or entirely prevented when the inhibitor was applied in combination with any of several other amino acids. Studies of ¹⁴C-labeled amino acid uptake showed that, in most cases, the apparent antagonism resulted simply from competition for uptake. However, certain antagonists did not curtail uptake. The most effective of these were leucine (against all three inhibitors), and isoleucine and valine (against asparagine or glutamine, but not glycine). These results show that interactions among amino acids in the regulation of nitrate reductase induction result from at least two mechanisms, one acting on uptake of inhibitory amino acids, and the other involving true antagonism.     

Effects of atrazine on the assimilation of inorganic nitrogen in cereals

The inclusion of sub-lethal amounts ofthe herbicide atrazine [2-chloro-4-(ethylamino)-6-(isopropylamino)-s-triazine] in the nutrient solution supplied to maize and barley increased the growth of the root and shoot and the uptake of nitrate. The activities of nitrate and nitrite reductases, glutamine synthetase and glutamate synthase were enhanced and the amino acid and nitrate contents of the xylem sap increased. All these effects of atrazine were found only in plants grown with nitrate as the nitrogen source. The uptake of ¹⁵NO₃^? and its incorporation into protein in the root and shoot of maize and barley seedlings was significantly greater in the atrazine treated plants. However, a stimulation in the incorporation of leucine-[¹⁴C] into TCA-precipitable protein of detached leaves from 7-day-old barley seedlings was obtained only in the absence of a supply of combined nitrogen either in the culture medium or in the in vitro incubation mixture containing the labelled amino acid.     

The Influence of Nitrogen Nutrition on the Accumulation of Free Amino Acids in Root Tissue of Urtica dioica and their Apical Transport in Xylem Sap

Urtica dioica plants were grown on a nitrogen supply of 3, 15and 22 mM with nitrate and ammonium as nitrogen source. In contrastto nitrate reductions amino acid synthesis occurred in roottissue. At 3 mM ammonium obviously the amino acids were rathertransported via xylem upwards to the shoots than stored in theroots. Particularly increased ammonium supply led to stimulatedstorage of free amino acids in the roots, mainly as asparagineand arginine. In xylem asparagine was the dominant nitrogentransporting compound, while arginine was hardly translocated.With the enhancement of nitrogen supply, the second amide, glutamine,became more and more important with respect to the transportof nitrogen. (Received September 3, 1984; Accepted November 2, 1984)     

Cancer cell metabolism: the essential role of the nonessential amino acid,glutamine

Biochemistry textbooks and cell culture experiments seem to be telling us two different things about the significance of external glutamine supply for mammalian cell growth and proliferation. Despite the fact that glutamine is a nonessential amino acid that can be synthesized by cells from glucose‐derived carbons and amino acid‐derived ammonia, most mammalian cells in tissue culture cannot proliferate or even survive in an environment that does not contain millimolar levels of glutamine. Not only are the levels of glutamine in standard tissue culture media at least ten‐fold higher than other amino acids, but glutamine is also the most abundant amino acid in the human bloodstream, where it is assiduously maintained at approximately 0.5 mM through a combination of dietary uptake, de novo synthesis, and muscle protein catabolism. The complex metabolic logic of the proliferating cancer cells' appetite for glutamine—which goes far beyond satisfying their protein synthesis requirements—has only recently come into focus. In this review, we examine the diversity of biosynthetic and regulatory uses of glutamine and their role in proliferation, stress resistance, and cellular identity, as well as discuss the mechanisms that cells utilize in order to adapt to glutamine limitation.     

Metabolism of Arginine and Ornithine in Suspension-Cultured Cells and Aseptic Roots of Intact Plants of Atropa belladonna

Suspension-cultured cells and aseptically cultured roots ofintact plants of Atropa belladonna L. removed tropane alkaloidprecursors arginine (Arg) and ornithine (Orn) at nearly an equalrate from the feeding medium. A great part of Arg- and Orn-derived¹⁴C-label was found in ethanol-insoluble compounds, mostly inproteins already after 2 h feeding. Ethanol-soluble label inthe roots was found mainly in amino acids (e.g. glutamine, Gln)after 2 h feeding, and after 20 h also in some intermediatesof the urea cycle (e.g. argininosuccinate). In suspension cultures, subculturing of the initiation callusdecreased both the uptake of the basic amino acids tested andtheir binding on to the apoplastic space. After 20 h feedingwith Arg more label was found in organic acids in stationaryphase suspension cultures with repressed alkaloid synthesisthan in roots producing alkaloids. The growth phase and passagenumber also affected into which amino acids the label was incorporated.When the initiation callus was young (the 3rd passage), theintermediates of the urea cycle were actively labelled, butwhen the initiation callus was older (the 8th passage) and thesuspension formed roots, especially Gln was labelled. Only tracesof -N-methylornithine were detected in feeding experiments withOrn and Arg. Considerable arginase activity with a high pH optimumwas observed in cell suspensions and roots of A. belladonna. Key words: Atropa, arginine, ornithine, roots, suspension culture