Prevention of phosphate inhibition of cephalosporin synthetases by ferrous ion

Abstract Phosphate interference in the production of cephalosporins by Streptomyces clavuligerus had been associated with repression of expandase (desacetoxycephalosporin C synthetase) and inhibition of both expandase and cyclase (isopenicillin N synthetase). The present work shows that inhibition of enzyme action could be prevented by increasing the Fe²⁺ added to the cell-free reactions or to resting cells incubated with chloramphenicol. Since excess Fe²⁺ could not reverse phosphate interference of antibiotic synthesis in complete fermentations, it is clear that the major cause of the phosphate effect in fermentations is phosphate repression, rather than phosphate inhibition caused by Fe²⁺ deprivation.     

Properties and localization of the homoglutathione synthetase from Phaseolus coccineus leaves

The synthesis of homoglutathione (hGSH) by several plants of the tribe Phaseoleae is shown to be catalysed by a β-alanine-specific hGSH synthetase, Properties of the enzyme from Phaseolus coccineus L. cv. Preisgewinner were studied, using ammonium sulfate precipitates of primary leaf extracts. The hGSH synthetase showed a broad pH optimum at pH 8–9, an absolute requirement for Mg²⁺, a stimulation by K⁺, and a high affinity for γ-glutamylcysteine [K_m(app.) 73 μ M ]. The enzyme exhibited a high specificity for β-alanine [K_m(app.) 1.34 m M ] compared to glycine [K_m(app.) 98 m M ]. Chloroplasts, isolated from the leaves of Phaseolus coccineus , contained about 17% of the hGSH synthetase activity in the leaf cells.     

l-Methionine-dl-sulfoximine resistant Het+ Nif+ and Het− Nif− strains of Nostoc muscorum assimilating methylamine as ammonium nitrogen source

Abstract The Het⁺ Nif⁺ and Het⁻ Nif⁻ strains of Nostoc muscorum sensitive to growth inhibition by methylamine (MA), overcame the MA inhibition as a result of their mutation to l -methionine- dl -sulfoximide (MSX)-resistant phenotype, which enabled them to assimilate MA like an ammonium nitrogen source. The MSX-resistant Het⁺ Nif⁺ strain synthesized the inhibitor-resistant transferase-defective glutamine synthetase (GS), which unlike parental GS underwent MA-dependent in vivo activation. These results suggest the involvement of GS enzyme in control of MA assimilation in cyanobacteria.     

Enzymes involved in ammonia assimilation in the fungus Acremonium persicinum

Abstract Acremonium persicinum grown in batch culture with ammonium tartrate as the nitrogen source possessed an NADP⁺-dependent glutamate dehydrogenase and a glutamine synthetase. Glutamate synthase was not detected under the culture conditions used. Kinetic studies of the NADP⁺-dependent glutamate dehydrogenase at 25°C and pH 7.6 revealed an apparent K _m of 3.2 × 10⁻⁴ M for 2-oxoglutarate and an apparent K _m of 1.0 × 10⁻⁵ M for ammonium ions, with corresponding apparent V _max values of 0.089 and 0.13 μmol substrate converted/min/mg of protein, respectively. Glutamine synthetase was measured by the γ-glutamyl transferase reaction at 30°C and pH 7.55. This transferase reaction of glutamine synthetase had a higher rate at 30°C than at 25°C or 37°C.     

Regulation of cytosol acidity in plants under conditions of drought

In plants under water stress, the activity of photosynthesis declines most. Stimulation of the oxidative respiration and fermentation results in an increase in the amount of related organic acids: citrate, malate and lactate. In spite of some decline in photo-respiratory activity, dehydration may enhance the concentration of related organic acids, glycerate and glycolate. The resulting amount of H⁺ should stimulate NAD(P)H reduction of organic acids by dehydrogenases. Accumulation of proline could be the consequence of such reactions. In the oxidation of glycine, regeneration of NAD(P)H does not liberate H⁺ but NH₄⁺.
Assimilation of NH₄⁺ by cytosolic glutamine synthetase (EC 6.3.1.2) results in positively charged glutamine. It is also conceivable that the charge is essential in the final asparagine synthesis by cytosolic asparagine synthetase (EC 6.3.1.1).
At low pH the activity of the oxidative respiration declines. In water-stressed plants, maintenance of oxidative respiration will depend on the availability of sufficient amounts of carbohydrates and on adequate removal of excess H⁺ by accumulation of proline and asparagine.     

Symbiotic effectiveness, rate of respiration and glutamine synthetase activity of sodium azide-resistant strains of Rhizobium leguminosarum biovar trifolii

Nitrogen fixing efficiency of sodium azide-resistant strains of Rhizobium leguminosarum bv. trifolii was studied in symbiosis with berseem clover plants in chillum jars. Rate of respiration and glutamine synthetase activity were tested in cultured cells and nodules, respectively. It was observed that shoot dry weight and percentage shoot nitrogen were maximum in plants inoculated with strains resistant to 15 μg ml⁻¹ sodium azide. Rate of respiration in cultured cells was lowest in strains resistant to 15 μg ml⁻¹ sodium azide and highest in strains resistant to 5 μg ml⁻¹ sodium azide. A negative correlation was observed between rate of respiration (in cultured cells) and shoot dry weight of host plants. Glutamine synthetase activity was maximum in nodule extracts of host plants inoculated with strains resistant to 5 and 10 μg ml⁻¹ sodium azide, whereas it was minimum for strains resistant to 15 μg ml⁻¹ sodium azide. Hence, resistance to low doses (15 μg ml⁻¹) of sodium azide, together with lower respiratory and glutamine synthetase activities, could be used as a potential method for isolating the symbiotically effective strains of Rh. leguminosarum bv. trifolii.     

The use of colloid gold labelling in the detection of plasma membrane from symbiotic and non-symbiotic Glycine max root cells

Glycine max L. Merr. cv. Maple Arrow protoplasts were prepared from both tissue-cultured root cells and symbiotically-infected (fix⁺) nodule cells. Whilst both cell types showed glucan synthetase II (GS II; EC 2.4.1.29) activity, neither cell type, whole or gently disrupted, showed glucan synthetase I activity. After sucrose density gradient centrifugation one of the several GS II activity peaks co-sedimented with the single radioactive particulate peak from [¹²⁵I]-labelled protoplasts at 1.14 g ml⁻¹. This peak is presumed to be the plasma membrane peak because labelling of protoplasts with colloidal gold prior to disruption moved the ¹²⁵I peak and the corresponding glucan synthetase II activity into denser regions of the gradient, leaving endoplasmic reticulum-contaminating IDPase (EC 3.1.3.31) and other glucan synthetase II peaks unmoved. Results are discussed in relation to various strategies of plasma membrane isolation.     

An alternative PII protein in the regulation of glutamine synthetase in Escherichia coli

The P_II protein has been considered pivotal to the dual cascade regulating ammonia assimilation through glutamine synthetase activity. Here we show that P_II, encoded by the glnB gene, is not always essential; for instance upon ammonia deprivation of a glnB deletion strain, glutamine synthetase can be deadenylylated as effectively as in the wild-type strain. We describe a new operon, glnK amtB , which encodes a homologue of P_II and a putative ammonia transporter. We cloned and overexpressed glnK and found that the expressed protein had almost the same molecular weight as P_II, reacted with polyclonal P_II antibody, and was 67% identical in terms of amino acid sequence with Escherichia coli P_II. Like P_II, purified GlnK can activate the adenylylation of glutamine synthetase in vitro , and, in vivo , the GlnK protein is uridylylated in a glnD -dependent fashion. Unlike P_II, however, the expression of glnK depends on the presence of UTase, nitrogen regulator I (NRI), and absence of ammonia. Because of a NRI and a σ^N (σ⁵⁴) RNA polymerase-binding consensus sequence upstream from the glnK gene, this suggests that glnK is regulated through the NRI/NRII two-component regulatory system. Indeed, in cells grown in the presence of ammonia, glutamine synthetase deadenylylation upon ammonia depletion depended on P_II. Possible regulatory implications of this conditional redundancy of P_II are discussed.     

The activation of glutamine synthetase from the cyanobacterium Anabaena cylindrica by thioredoxin

Abstract The present communication defines the conditions under which thioredoxin activates glutamine synthetase from Anabaena cylindrica . Effects are obtained at pH values around neutrality, and the activation is affected by Mg²⁺ in the assays. The thioredoxin systems from A. cylindrica and spinach are functionally interchangeable in the activation of glutamine synthetase. The enzyme is efficiently activated by thioredoxin_m and also by thioredoxin_f, but at much higher concentrations. Thioredoxin_m has previously been shown to activate NADPH-dependent malate dehydrogenase and isocitrate dehydrogenase from cyanobacteria. It is speculated that thioredoxin_m plays a role in the differentiation of vegetative cells to heterocysts.     

Different effects of supplied ammonium on glutamine synthetase activity in mustard (Sinapis alba) and pine (Pinus sylvestris) seedlings

The activity of glutamine synthetase (GS) in mustard ( Sinapis alba L.) and Scots pine ( Pinus sylvestris L.) seedlings was used as an index to evaluate the capacity to cope with excessive ammonium supply. In these 2 species GS activity was differently affected by the application of nitrogen compounds (NH₄⁺ or NO₃⁻). Mustard seedlings older than 5 days showed a considerable increase in GS activity after NH₄⁺ or NO₃⁻ application. This response was independent of the energy flux, but GS activity in general was positively affected by light. Endogenous NH₄⁺ did not accumulate greatly after nitrogen supply. In contrast, seedlings of Scots pine accumulated NH₄⁺ in cotyledons and roots and showed no stimulation of GS activity after the application of ammonium. In addition, root growth was drastically reduced. Thus, the pine seedlings seem to have insufficient capacity to assimilate exogenously supplied ammonium. NO₃⁻, however, did not lead to any harmful effects.     

Impact of gaseous nitrogen deposition on plant functioning

Dry deposition of NH₃ and NO_x (NO and NO₂) can affect plant metabolism at the cellular and whole-plant level. Gaseous pollutants enter the plant mainly through the stomata, and once in the apoplast NH₃ dissolves to form NH₄⁺, whereas NO₂ dissolves to form NO₃⁻ and NO₂⁻. The latter compound can also be formed after exposure to NO. There is evidence that NH₃-N and NO_x-N can be reversibly stored in the apoplast. Temporary storage might affect processes such as absorption rate, assimilation and re-emission. Once formed, NO₃⁻ and NO₂⁻ can be reduced, and NH₄⁺ can be assimilated via the normal enzymatic pathways, nitrate reductase (NR), nitrite reductase and the glutamine synthetase/glutamate synthase (GS/GOGAT) cycle. Fumigation with low concentrations of atmospheric NH₃ increases in vitro glutamine synthetase activity, but whether this involves both or only one of the GS isoforms is still an open question. There seems to be no correlation between fumigation with low concentrations of NH₃ and in vitro GDH activity. The contribution of atmospheric NH₃ and NO₂ deposition to the N budget of the whole plant has been calculated for various atmospheric pollutant concentrations and relative growth rates ( RGRs ). It is concluded that at current ambient atmospheric N concentrations the direct impact of gaseous N uptake by foliage on plant growth is generally small.     

Accumulation and conversion of sugars by developing wheat grains. 4. Effects of phosphate and potassium ions in endosperm slices

Abstract. Transverse slices through developing grains of Triticum aestivum cv. SUN 9E 16 d after anthesis were incubated in simple defined media with various radioactive labels. In some enzymic assays slices were pretreated with 2.5% Triton X-100 or with 5% butanol to remove cellular membranes and endogenous substrates.
Endogenous potassium leaked from endosperm slices into 30mol m⁻³ sucrose while sucrose was converted partly into starch. Exogenous alkali-ions, except Li⁺, stimulated conversion of sucrose to insoluble matter, specifically to starch with K⁺. Starch synthetase activity of Triton-pretreated slices was stimulated by K⁺ at both high and low substrate ADPG concentration, but was not affected by phosphate (25 mol m⁻³).
Phosphate in the medium had no effect on incorporation of sucrose or glucose into alcohol-insoluble material or starch in fresh slices (internal inorganic phosphate (P,) concentration was about 11 mol m⁻³). Three- to four-fold contrasts in internal P_i level, achieved by prolonged preincubations in different media, did not show an inhibition of starch synthesis by P_i. However, phosphate (25mol m⁻³) inhibited starch synthesis, that was mediated by ADPG pyrophosphorylase in butanol-pretreated endosperm slices by 15–18%.
It is concluded that starch synthesis in wheat endosperm is not regulated directly by apoplastic P_i; level.     

Mycobiont-cyanobiont interactions during dark nitrogen fixation by the lichen Peltigera aphthosa

Acetylene reduction (nitrogenase activity) by excised cephalodia of Peltigera aphthosa Willd. slowly declined on transfer of the cephalodia from light to darkness. The decline was more rapid in the absence of CO₂ or when phosphoenolpyruvate carboxylase activity was inhibited by adding maleic acid or malonic acid. When glutamine synthetase (GS) activity was totally inhibited by adding l -methionine- dl -sulphoximine (MSX) the decline in nitrogenase activity in the absence of CO₂ still occurred. However, this loss of activity did not occur when the mycobiont was disrupted using digitonin (0.01 % w/v) and the fixed NH₄⁺ was released into the medium. The data suggest that dark CO₂ fixation by the fungus supplies carbon skeletons which remove newly fixed NH₄⁺ produced by the cyanobacterium. When such carbon skeletons are not available MH₄⁺ accumulates and inhibits nitrogenase activity even in the absence of GS activity. It is probable that NH₄⁺ and a product of GS exert independent inhibitory effects on nitrogenase activity.     

A single base change prevents import of cytosolic tRNAAla into mitochondria in transgenic plants

Plant mitochondria do not contain a full set of tRNA genes, and the additional tRNAs needed for protein synthesis (including tRNA^Ala) are imported from the cytosol. The import process appears to be highly specific for certain tRNAs, and it has been suggested that the cognate aminoacyl-tRNA synthetases may be responsible for this specificity. In order to test this, we have grown transgenic tobacco plants expressing Arabidopsis thaliana tRNA^Ala carrying a U₇₀ to C₇₀ mutation, which we have previously shown blocks aminoacylation by the plant alanyl-tRNA synthetase. Unlike the wild-type tRNA^Ala, the mutant tRNA is not present in the mitochondrial tRNA fraction. This is the first report of a tRNA mutation which prevents mitochondrial import and strongly supports the hypothesis that aminoacyl-tRNA synthetases are involved in this process in plants. Insertion of four bases into the anticodon loop of tRNA^Ala does not prevent mitochondrial import, implying that the tRNA might not need to participate in translation to be imported.     

Nitrate metabolism in the cyanobacterium Anabaena cycadeae: Regulation of nitrate uptake and reductase by ammonia

Nitrogen regulation of nitrate uptake and nitrate reductase (EC 1.7.99.4) was studied in the cyanobacterium Anabaena cycadeae Reinke and its glutamine auxotroph. Development of the nitrate uptake system preceded, and was independent of, the development of the nitrate reductase system. The levels of both systems were several-fold higher in the glutamine auxotroph lacking glutamine synthetase (EC 6.3.1.2) than in the wild type strain having normal glutamine synthetase activity. The nitrate uptake system was found to be NH4-repressible and the nitrate reductase system NO₃⁻-inducible. NH₄⁺ was the initial repressor signal for the uptake process which was involved in the control of the NO₃⁻inducible reductase system.     

Expression of a bacterial asparagine synthetase gene in oilseed rape (Brassica napus) and its effect on traits related to nitrogen efficiency

The investigation and improvement of nitrogen efficiency in oilseed rape ( Brassica napus L.) are important issues in rapeseed breeding. The objective of this study was to modify ammonium assimilation in transgenic rapeseed plants through the expression of the Escherichia coli asparagine synthetase (AsnA, E.C. 6.3.1.1) gene under the control of the cauliflower mosaic virus (CaMV) 35S promoter, and to study its influence on amino acid composition in leaves and on seed traits related to nitrogen efficiency. In regenerated transgenic plants, the 37 kDa AsnA protein was detected by Western blot analysis, but was lacking in untransformed control plants of cv. Drakkar. In the transformants, in vitro asparagine synthetase activities ranged from 105 to 185 nmol asparagine mg⁻¹ protein h⁻¹, whereas, in untransformed control plants, only negligible asparagine synthetase activities of up to 5 nmol asparagine mg⁻¹ protein h⁻¹ were found. Despite these significant activities, no changes in the amino acid composition in the leaves or in the phloem of transgenic plants were detectable. In a pot experiment, two transgenic lines expressing the prokaryotic asparagine synthetase clearly performed inferiorly to control plants at limiting nitrogen (N) fertilizer supply. Although the seed N content was increased, the seed yield and the seed N yield were reduced, which was interpreted as an increased nitrate assimilation leading, at limiting N supply, to a reduced seed yield and seed N yield. At high N fertilizer supply, the differences were less pronounced for one transgenic line, whereas the other showed a higher seed N yield and an improved nitrogen harvest index. The results show that the expression of the E. coli asnA gene in oilseed rape could be of advantage at high N supply, but not at limiting N fertilizer supply.     

Cloning and functional characterization of a homoglutathione synthetase from pea nodules

The thiol tripeptide glutathione (GSH; γ Glu-Cys-Gly) is very abundant in legume nodules where it performs multiple functions that are critical for optimal nitrogen fixation. Some legume nodules contain another tripeptide, homoglutathione (hGSH; γ Glu-Cys- β Ala), in addition to or instead of GSH. We have isolated from a pea ( Pisum sativum L.) nodule library a cDNA, GSHS2 , that is expressed in nodules but not in leaves. This cDNA was overexpressed in insect cells and its protein product was identified as a highly active and specific hGSH synthetase. The enzyme, the first of this type to be completely purified, is predicted to be a homodimeric cytosolic protein. It shows a specific activity of 3400 nmol hGSH min⁻¹ mg⁻¹ protein with a standard substrate concentration (5 m M β -alanine) and K_m values of 1.9 m M for β -alanine and 104 m M for glycine. The specificity constant (V_max/K_m) shows that the pure enzyme is 57.3-fold more specific for β -alanine than for glycine. Southern blot analysis revealed that the gene is present as a single copy in the pea genome and that there are homologous genes in other legumes. We conclude that the synthesis of hGSH in pea nodules is catalysed by a specific hGSH synthetase and not by a GSH synthetase with broad substrate specificity.     

Response of nitrogen metabolism to boron toxicity in tomato plants

Boron (B) toxicity has become important in areas close to the Mediterranean Sea where intensive agriculture has been developed. The objective of this research was to study the effects of B toxicity (0.5 m m and 2.0 m m B) on nitrogen (N) assimilation of two tomato cultivars that are often used in these areas. Leaf biomass, relative leaf growth rate (RGR_L), concentration of B, nitrate (NO₃⁻), ammonium (NH₄⁺), organic N, amino acids and soluble proteins, as well as nitrate reductase (NR), nitrite reductase (NiR), glutamine synthase (GS), glutamate synthetase (GOGAT) and glutamate dehydrogenase (GDH) activities were analysed in leaves. Boron toxicity significantly decreased leaf biomass, RGR_L, organic N, soluble proteins, and NR and NiR activities. The lowest NO₃⁻ and NH₄⁺ concentration in leaves was recorded when plants were supplied with 2.0 m m B in the root medium. Total B, amino acids, activities of GS, GOGAT and GDH increased under B toxicity. Data from the present study prove that B toxicity causes inhibition of NO₃⁻ reduction and increases NH₄⁺ assimilation in tomato plants.     

Nitric Oxide-Mediated Mitochondrial Damage in the Brain: Mechanisms and Implications for Neurodegenerative Diseases

Abstract: Within the CNS and under normal conditions, nitric oxide (^•NO) appears to be an important physiological signalling molecule. Its ability to increase cyclic GMP concentration suggests that ^•NO is implicated in the regulation of important metabolic pathways in the brain. Under certain circumstances ^•NO synthesis may be excessive and ^•NO may become neurotoxic. Excessive glutamate-receptor stimulation may lead to neuronal death through a mechanism implicating synthesis of both ^•NO and superoxide (O₂^•−) and hence peroxynitrite (ONOO⁻) formation. In response to lipopolysaccharide and cytokines, glial cells may also be induced to synthesize large amounts of ^•NO, which may be deleterious to the neighbouring neurones and oligodendrocytes. The precise mechanism of ^•NO neurotoxicity is not fully understood. One possibility is that it may involve neuronal energy deficiency. This may occur by ONOO⁻ interfering with key enzymes of the tricarboxylic acid cycle, the mitochondrial respiratory chain, mitochondrial calcium metabolism, or DNA damage with subsequent activation of the energy-consuming pathway involving poly(ADP-ribose) synthetase. Possible mechanisms whereby ONOO⁻ impairs the mitochondrial respiratory chain and the relevance for neurotoxicity are discussed. The intracellular content of reduced glutathione also appears important in determining the sensitivity of cells to ONOO⁻ production. It is concluded that neurotoxicity elicited by excessive ^•NO production may be mediated by mitochondrial dysfunction leading to an energy deficiency state.     

Translocation of NH4+ in oilseed rape plants in relation to glutamine synthetase isogene expression and activity

Translocation of NH₄⁺ was studied in relation to the expression of three glutamine synthetase (GS, EC 6.3.1.2) isogenes and total GS activity in roots and leaves of hydroponically grown oilseed rape ( Brassica napus ). The concentration of NH₄⁺ in the stem xylem sap of NO₃⁻-fed plants was 0.55–0.70 m M , which was ≈60% higher than that in plants deprived of external nitrogen for 2 days. In NH₄⁺-fed plants, xylem NH₄⁺ concentrations increased linearly both with time of exposure to NH₄⁺ and with increasing external NH₄⁺ concentration. The maximum xylem NH₄⁺ concentration was 8 m M , corresponding to 11% of the nitrogen translocated in the xylem. In the leaf apoplastic solution, the NH₄⁺ concentration increased from 0.03 m M in N-deprived plants to 0.20 m M in N-replete plants. The corresponding values for leaf tissue water were 0.33 and 1.24 m M , respectively. The addition of either NO₃⁻ or NH₄⁺ to N-starved plants induced both cytosolic gs isogene expression and GS activity in the roots. In N-replete plants, gs isogene expression and GS activity were repressed, probably due to carbon limitations, thereby protecting the roots against the excessive drainage of photosynthates. Repressed gs isogene expression and GS activity under N-replete conditions caused enhanced NH₄⁺ translocation to the shoots.