Ammonium regulation in Aspergillus nidulans

l-Glutamate uptake, thiourea uptake, and methylammonium uptake and the intracellular ammonium concentration were measured in wild-type and mutant cells of Aspergillus nidulans held in various concentrations of ammonium and urea. The levels of l-glutamate uptake, thiourea uptake, nitrate reductase, and hypoxanthine dehydrogenase activity are determined by the extracellular ammonium concentration. The level of methylammonium uptake is determined by the intracellular ammonium concentration. The uptake and enzyme characteristics of the ammonium-derepressed mutants, meaA8, meaB6, DER3, amrA1, xprD1, and gdhA1, are described. The gdhA mutants lack normal nicotinamide adenine dinucleotide phosphate-glutamate dehydrogenase (NADP-GDH) activity and are derepressed with respect to both external and internal ammonium. The other mutant classes are derepressed only with respect to external ammonium. The mutants meaA8, DER3, amrA1, and xprD1 have low levels of one or more of the l-glutamate, thiourea, and methylammonium uptake systems. A model for ammonium regulation in A. nidulans is put forward which suggests: (i) NADP-GDH located in the cell membrane complexes with extracellular ammonium. This first regulatory complex determines the level of l-glutamate uptake, thiourea uptake, nitrate reductase, and xanthine dehydrogenase by repression or inhibition, or both. (ii) NADP-GDH also complexes with intracellular ammonium. This second and different form of regulatory complex determines the level of methylammonium uptake by repression or inhibition, or both.     

Urea and thiourea transport in Aspergillus nidulans

Wild-type Aspergillus nidulans has an active transport system specific for urea which concentrates urea at least 50-fold relative to the extracellular concentration. It is substrate concentration dependent, with an apparent K _m of 3×10^–5 m for urea. Competition studies and the properties of mutants indicate that thiourea is taken up by the same system as urea. Thiourea is toxic at 5mm to wild-type cells of Aspergillus nidulans. Mutants, designated ureA1 to ureA16, resistant to thiourea have been isolated, and transport assays and growth tests show that they are specifically impaired in urea transport. The mutant ureA1 has a higher K _m value than the wild type for thiourea uptake. The ureA locus has been assigned to linkage group VIII. ureA1 is recessive for thiourea resistance while semidominant for the low uptake characteristic. The urea uptake system is under nitrogen regulation, with l-glutamine as the probable effector. The mutants, meaA8 and gdhA1, which are insensitive to ammonium control of many nitrogen-regulated metabolic systems, are also insensitive to ammonium control of urea uptake, but both are sensitive to l-glutamine regulation.Formerly at the Department of Genetics, University of Glasgow, Glasgow, Scotland.     

Studies of partially repressed mutants at the tamA and areA loci in Aspergillus nidulans

Summary Mutants, designated tamA ^r, have been isolated on the basis of simultaneous resistance to toxic analogues thiourea, aspartate hydroxamate and chlorate with L-alanine as the sole nitrogen source. tamA ^r mutants are also resistant to methylammonium. This resistance of tamA ^r mutants is correlated with partially repressed activity of a number of enzyme and transport systems regulated by ammonium. Furthermore, tamA ^r mutants have low NADP-glutamate dehydrogenase (NADP-GDH) activity and also efflux ammonium under certain growth conditions.Mutants at the areA locus (areA ^r) have also been isolated on the basis of resistance to these analogues, with nitrate or L-aspartate as the nitrogen source. These, similar to tamA ^r lesions, result in resistance to methylammonium and are partially repressed for ammonium repressible systems, but in contrast to tamA ^r, areA ^r alleles have wild-type NADP-GDH activity and normal ammonium efflux. tamA ^r and areA ^r mutants grow as wild type on all nitrogen or carbon sources tested, are recessive, and appear to be epistatic to all other mutations (gdhA1, meaA8 and meaB6) which result in derepressed levels of ammonium regulated system. Whereas tamA ^r and areA ^r phenotypes are additive, tamA ^r is epistatic to areA ^d phenotype.     

Ammonium and methylammonium uptake in a fertilizer-degrading strain of Ochrobactrum anthropi

The transport of ammonium and methylammonium was studied in a strain of Ochrobactrum anthropi, a microorganism isolated from garden soil and able to degrade methyleneureas which are used as slow-release nitrogen fertilizer. The activity of both transport systems was determined using [¹⁴C]methylammonium. Differences between the two transport systems were observed with regard to their pH- and temperature dependence as well as their kinetic parameters and regulation during growth with various nitrogen sources. Ammonium transport was subject to repression by ammonium and to derepression in its absence, while the methylammonium carrier was induced in the presence of methylamine. The ammonium but not the methylammonium transport system was severely inhibited by ammonium, and metabolic poisons inhibited both uptake systems. The analysis of intracellular metabolites using thin-layer chromatography and matrix-assisted laser desorption/ionisation time-of-flight mass spectrometry indicated that methylammonium was rapidly metabolized to N-methylglutamate via -N-methylglutamine.     

A mutant of Chlamydomonas reinhardtii altered in the transport of ammonium and methylammonium

Summary A methylammonium-resistant mutant, named hereafter strain 2170 (ma-1), was isolated for the first time from a eukaryotic phototrophic organism. Mutant 2170 from Chlamydomonas reinhardtii carries a single mendelian mutation which results in a decreased rate of uptake of both ammonium and methylammonium without being affected either in uptake of nitrate or nitrite or any of the tested enzyme activities related to ammonium assimilation. Mutant cells could not use methylammonium as nitrogen source nor excrete ammonium into the medium but they had derepressed nitrate and nitrite reductases when growing in the presence of ammonium. Mutant 2170 also exhibited a diminished methylammonium transport rate in comparison with the wild-type cells. We conclude that mutant 2170 is affected in a transport system responsible for the entrance of both ammonium and methylammonium into the cells.Abbreviations CHES 2-(N-Cyclohexylamino)ethanesulphonic acid - MOPS 3(N-morpholine)propanesulphonic acid     

Metabolism of methylammonium by Azotobacter vinelandii

Azotobacter vinelandii takes up the ammonium analog methylammonium from the external medium and metabolizes it to a less polar compound which has been identified as N-methylglutamine. The enzyme glutamine synthetase appears responsible for methylammonium metabolism in this organism and full activity of the enzyme is required for maximal rates of methylammonium uptake. L-methionine-DL-sulfoximine or L-methionine sulfone, inhibitors of glutamine synthetase activity, were shown to reduce the rate of methylammonium uptake by wild type cultures. A mutant strain with low glutamine synthetase activity was shown to be unable to carry out in vitro N-methylglutamine synthesis or in vivo uptake of methylammonium. Thus, methylammonium uptake assays may prove useful as a method of identifying mutants with altered glutamine synthetase activity.Abbreviations MSX L-methionine-DL-sulfoximine - MSF L-methionine sulfone     

Methylammonium uptake by Rhodobacter capsulatus

The ammonium uptake system of Rhodobacter capsulatus B100 was examined using the ammonium analog methylammonium. This analog was not transported when cells were grown aerobically on ammonium. When cultured on glutamate as a nitrogen source, or when nitrogen-starved, cells would take up methylammonium. Therefore, in cells grown under nitrogen-limiting conditions, a second system of ammonium uptake (or a modified form of the first) is present which is distinguished by its capacity for transporting the analog in addition to ammonium. The methylammonium uptake system exhibited saturation kinetics with a K _m of 22 M and a V _max of about 3 nmol per min · mg protein. Ammonium completely inhibited analog transport with a K _i in the range of 1 M. Once inside the cell methylammonium was rapidly converted to -N-methylglutamine; however, a small concentration gradient of methylammonium could still be observed. Kinetic parameters reflect the effects of assimilation.The methylammonium uptake system was temperature and pH dependent, and inhibition studies indicated that energy was required for the system to be operative. A glutamine auxotroph (G29) lacking the structural gene for glutanime synthetase did not accumulate the analog, even when nitrogen starved. The Nif^- mutant J61, which is unable to express nitrogenase structural genes, also did not transport methylammonium, regardless of the nitrogen source for growth. However, the mutant exhibited wild-type ammonium uptake and glutamine synthetase activity. These data suggest that transport of ammonium is required for growth on limited nitrogen and is under the control of the Ntr system in R. capsulatus.Abbreviations CCCP carbonyl cyanide-m-chlorophenyl hydrazone - CHES cyclohexylaminoethanesulfonic acid - DMSO dimethyl sulfoxide - GMAD -N-methylglutamine - GS glutamine synthetase - MES 2-(N-morpholino) ethanesulfonic acid - MSX methionine-Dl-sulfoximine - pCMB p-chloromercuribenzoate - Tricine N-tris(hydroxymethyl)methylglycine     

The regulation of hexokinase and phosphoglucomutase activity in Aspergillus nidulans.

Summary The levels of glucose-6-phosphate and 6-phosphogluconate dehydrogenase in wildtype cells of Aspergillus nidulans varied with the carbon and nitrogen source. In general, hexokinase activity did not vary with carbon or nitrogen source. The ammonium derepressed mutant amrA1 had only 50% of the wildtype level of hexokinase. Phosphoglucomutase activity was low in wildtype cells grown with nitrate, but high in cells grown with ammonium when glucose was the carbon source. A non-inducible mutant, nirA ^-1, in the regulatory gene for nitrate reductase, had high phosphoglucomutase activity when grown with nitrate or ammonium. A constitutive mutant nirA ^c1, in the regulatory gene for nitrate reductase had low phosphoglucomutase activity when grown with nitrate or ammonium. The mutants nir ^-1 and nirA ^c1 are recessive and semi-dominant respectively for abnormal phosphoglucomutase activity.     

Mutants of Aspergillus nidulans altered in the transport of methylammonium and ammonium

Summary Mutations to methylammonium resistance occur in at least two loci in Aspergillus nidulans, meaA in linkage group IV and meaB in linkage group III. Transport studies using methylammonium-¹⁴C, at a concentration which inhibits protein synthesis in the wild type but not in resistant mutants, show that meaA mutants are defective in methylammonium (and hence ammonium) transport. The ability of meaA mutations to be expressed in the absence of a substrate of the ammonium-methylammonium transport system suggests that ammonium efflux may be involved, although it has not been established whether ammonium influx is also affected.     

Regulation of urea uptake inPseudomonas aeruginosa

The energy-dependent urea permease was studied in two strains ofPseudomonas aeruginosa, measuring the uptake (transport and metabolism) of¹⁴C-urea. In both strains urea uptakein vivo and urease activityin vitro differed significantly with respect to kinetic parameters, temperature and pH dependence and response to metabolic inhibitors. Ammonium strongly interfered both with the expression of the urea uptake system and its activity. The inhibition of the uptake activity by ammonium was partially relieved by hydraziniumsulfate, which prevented the translocation of ammonium into the cell, and in a methylammonium/ammonium transport-defective mutant of strain DSM 50071. Furthermore, methionine-sulfoximine, which prevented the intracellular glutamine formation from ammoniumvia inhibition of glutamine synthetase, relieved the inhibition of urea uptake by ammonium. These findings suggested that urea uptake activity inP. aeruginosa is regulated by intracellular glutamine.Abbreviations CCCP carbonylcyanide-m-chlorphenylhydrazone - DCCD dicyclohexylcarbodiimide - GS glutamine synthetase - MSX methionine-sulfoximine     

Effect of benzoic acid on the ammonium transport system of Zygosaccharomyces bailii

Summary A study of the ammonium transport system of Zygosaccharomyces bailii was carried out using methylammonium as a non-metabolizable analogue. Benzoic acid in the growth medium decreased the capacity of the transport system from 1.46 ± 0.11 mmol.g^–1.h^–1 to 0.41±0.04 mmol.g^–1.h^–1, while the affinity for ammonium was not significatively affected. Although ammonium uptake was inhibited by benzoic acid, the ammonium transport system was still active at preservative concentrations which fully inhibited growth suggesting that inhibition of growth was not governed by the uptake of this nutrient.     

Mutants of Azospirillum brasilense resistant to methylammonium

One hundred and twenty-nine mutants of Azospirillum brasilense strain Sp6, resistant to methylammonium, were isolated. Three of the mutants were found to be able to reduce acetylene in the presence of 4 mM ammonium or 120mM methylammonium, concentrations which strongly reduced the nitrogenase activity of the parental strain. Under N₂-fixing conditions, two mutants failed to switch off nitrogenase when NH₄Cl was added. Moreover, the three mutants showed a reduced capacity to incorporate [¹⁴C]methylammonium. The level of glutamine synthetase activity found in the mutants was not reduced as compared to that of the parental strain. All of the data indicate an impairement in the mechanism of ammonium uptake by the bacterial cell.Abbreviations MEA Methylammonium - MSP minimal medium (ammonium free) - PY complete medium - GS glutamine synthetase     

Molybdenum cofactor amounts in Chlamydomonas reinhardtii depend on the Nit5 gene function related to molybdate transport

Strain 21gr from Chlamydomonas reinhardtii is a cryptic mutant defective in the Nit5 gene related to the biosynthesis of molybdenum cofactor (MoCo). In spite of this mutation, this strain has active MoCo and can grow on nitrate media. In genetic crosses, the Nit5 mutation cosegregated with a phenotype of resistance to high concentrations of molybdate and tungstate. Molybdate/tungstate toxicity was much higher in nitrate than in ammonium media. Strain 21gr showed lower amounts of MoCo activity than the wild type both when grown in nitrate and after growth in ammonium and nitrate induction. However, nitrate reductase (NR) specific activity was similar in wild type and 21gr cells. Tungstate, either at nanomolar concentrations in nitrate media or at micromolar concentrations during growth in ammonium and nitrate induction, strongly decreased MoCo and NR amounts in wild‐type cells but had a slight effect in 21gr cells. Molybdate uptake activity of ammonium‐grown cells from both the wild‐type and 21gr strains was small and blocked by sulphate 0·3 mM . However, cells from nitrate medium showed a molybdate uptake activity insensitive to sulphate. This uptake activity was much higher and more sensitive to inhibition by tungstate in the wild type than in strain 21gr. These results suggest that strain 21gr has a high affinity and low capacity molybdate transport system able to discriminate efficiently tungstate, and lacks a high capacity molybdate/tungstate transport system, which operates in wild‐type cells upon nitrate induction. This high capacity molybdate transport system would account for both the stimulating effect of molybdate on MoCo amounts and the toxic effects of tungstate and molybdate when present at high concentrations.     

Methylammonium uptake by Rhizobium sp. strain 32H1

We present evidence that methylammonium is transported into cowpea Rhizobium sp. strain 32H1 cells by a membrane carrier whose natural substrate is ammonium. After growth in low (0.2%) oxygen, which is necessary for nitrogen fixation by these cells, respiring rhizobial cells took up [14C]methylammonium to high intracellular levels. Cells grown in atmospheric (21%) oxygen did not take up methylammonium. Uptake (transport plus metabolism) was maximal in cells harvested in the early stationary phase of batch culture and had a distinct pH optimum of 6.5 to 7.0. Uptake was inhibited by metabolic poisons that dissipate the proton motive force or inhibit ATP synthesis. Inhibition of uptake by ammonium and the counterflow phenomenon indicated that ammonium and methylammonium share a transport carrier. Of the methylammonium taken up, about 15% was accumulated to intracellular levels 20 times higher than those in the medium; most of the methylammonium was metabolized to gamma-N-methylglutamine.     

Regulation by light of ammonium transport systems in Chlamydomonas reinhardtii

The unicellular green alga Chlamydomonas reinhardtii is able to take up methylammonium/ammonium from the medium at different stages of its sexual life cycle. Vegetative cells and pre‐gametes mostly used a low‐affinity system (LATS) component, but gametes obtained after light treatment of N‐deprived pre‐gametes expressed both LATS and high‐affinity system (HATS) components for the uptake of methylammonium/ammonium. The activity of the LATS component was stimulated by light in only 5 min in a process independent of protein synthesis. By using the lrg6 mutant that produces sexually competent gametes in the dark, light effects on ammonium transport and gamete differentiation have been separately analysed. We have found light regulation of four Amt1 genes: Amt1; 1, Amt1; 2, Amt1; 4 and Amt1; 5. Whereas light‐dependent expression of Amt1; 1, Amt1; 2 and Amt1; 4 was independent of gametogenesis, and that of Amt1; 5 was activated in the lrg6 mutant, suggesting a connection between this transporter and the subsequent events taking place during gametogenesis.     

The role of glutamine in regulation of ammonium transport in Azotobacter vinelandii

Under N₂-fixing conditions, Azotobacter vinelandii expresses a specific transport system for methylammonium (ammonium) [E. M. Barnes, Jr. and P. Zimniak (1981) J. Bacteriol. 146, 512–516]. This activity is decreased markedly by culture of cells in the presence of 10 mm ammonium or 2 mm methylammonium; in both cases, the V_max values for methylammonium uptake were 25% of those of N₂-fixing cells. Mixing experiments with assay medium indicate that transport activity is controlled by intracellular rather than extracellular metabolites. Glutamine synthetase activity of cells cultured with ammonium was 33% that of N₂-fixing cultures, but activity was unaffected by incubation with methylammonium. Thus ammonium transport and ammonium fixation are regulated independently. When ammonium was removed from the medium, cells recovered over 90% of the initial transport activity after 1 h; this recovery was not affected by addition of chloramphenicol. The loss of uptake activity in cells incubated with ammonium or methylammonium correlated with over sixfold increases in intracellular levels of glutamine and γ-glutamylmethylamide, respectively. Recovery of transport was accompanied by similar reductions in pools of these compounds. Over one-half of methylammonium transport activity could be blocked by direct addition of 10 mm glutamine or γ-glutamylmethylamide to transport assays; these concentrations were similar to those observed in vivo. The glutamine analog, 6-diazo-5-oxo-l-norleucine, was the most potent inhibitor found (68% inhibition at 10 μm). These results indicate that the regulation of ammonium transport by ammonium and methylammonium is due to inhibition of the transporter by intracellular γ-glutamyl amides rather than by repression of transporter synthesis.     

Physiological and biochemical analysis of the glutamine synthetase-impaired mutants of the nitrogen-fixing cyanobacteriumNostoc muscorum

Three types of glutamine synthetase (GS)-impaired mutants (gln) ofNostoc muscorum were isolated as ethylenediamine (EDA)-resistant phenotypes and characterized with respect to heterocyst development, nitrogen fixation, ammonium metabolism, photosynthetic characteristics, and glutamine synthetase activity. The criterion for categorizing the mutants was the extent of loss of GS activity (both in transferase and biosynthetic assays) compared with wild type; it was 70% in EDA-1, 30% in EDA-2, and more than 90% in EDA-3 strains. The level of nitrogenase activity in mutant strains was proportionate to heterocyst frequency and was found refractory to ammonium and EDA repression. In EDA-resistant strains, development of heterocysts and their spacing pattern remained unaffected and did not respond to treatment of amino acid analogues, drugs, and ammoniacal compounds which otherwise either stimulated or suppressed the number and altered the spacing pattern in wild type. A biphasic pattern of ammonium uptake indicating two transport systems was observed in all the strains except that the Km values for both high- and low-affinity systems were altered in mutant strains. In vivo treatment with MSX or EDA significantly inhibited the GS activity in wild type, whereas mutant strains did not respond to these treatments and were able to liberate NH ₄ ⁺ continuously into the medium without MSX treatment. During NH ₄ ⁺ uptake, percentage inhibition of O₂ evolution and changes in increase of fluorescence intensity were low in EDA strains compared with wild type. Assessment of GS protein with antibodies against GS and quantitative polyacrylamide gel electrophoresis (PAGE) suggested that loss in specific activity of GS per milligram of extractable protein in EDA mutants was owing to low production of GS-specific protein. SDS-PAGE of purified GS enzyme from all the strains revealed only one polypeptide band of molecular weight of about 51.28 kDa.     

Methylammonium-resistant mutants ofNicotiana plumbaginifolia are affected in nitrate transport

This work reports the isolation and preliminary characterization ofNicotiana plumbaginifolia mutants resistant to methylammonium.Nicotiana plumbaginifolia plants cannot grow on low levels of nitrate in the presence of methylammonium. Methylammonium is not used as a nitrogen source, although it can be efficiently taken up byNicotiana plumbaginifolia cells and converted into methylglutamine, an analog of glutamine. Glutamine is known to repress the expression of the enzymes that mediate the first two steps in the nitrate assimilatory pathway, nitrate reductase (NR) and nitrite reductase (NiR). Methylammonium has therefore been used, in combination with low concentrations of nitrate, as a selective agent in order to screen for mutants in which the nitrate pathway is de-repressed. Eleven semi-dominant mutants, all belonging to the same complementation group, were identified. The mutant showing the highest resistance to methylammonium was not affected either in the utilization of ammonium, accumulation of methylammonium or in glutamine synthase activity. A series of experiments showed that utilization of nitrite by the wild-type and the mutant was comparable, in the presence or the absence of methylammonium, thus suggesting that the mutation specifically affected nitrate transport or reduction. Although NR mRNA levels were less repressed by methylammonium treatment of the wild-type than the mutant, NR activities of the mutant remained comparable with or without methylammonium, leading to the hypothesis that modified expression of NR is probably not responsible for resistance to methylammonium. Methylammonium inhibited nitrate uptake in the wild-type but had only a limited effect in the mutant. The implications of these results are discussed.