Immunochemical characterization of glutamine synthetase from Neurospora crassa glutamine auxotrophs.

Glutamine synthetase derived from two Neurospora crassa glutamine auxotrophs was characterized. Previous genetic studies indicated that the mutations responsible for the glutamine auxotrophy are allelic and map in chromosome V. When measured in crude extracts, both mutant strains had lower glutamine synthetase specific activity than that found in the wild-type strain. The enzyme from both auxotrophs and the wild-type strain was partially purified from cultures grown on glutamine as the sole nitrogen source, and immunochemical studies were performed in crude extracts and purified fractions. Quantitative rocket immunoelectrophoresis indicated that the activity per enzyme molecule is lower in the mutants than in the wild-type strain; immunoelectrophoresis and immunochemical titration of enzyme activity demonstrated structural differences between the enzymes from both auxotrophs. On the other hand, the monomer of glutamine synthetase of both mutants was found to be of a molecular weight similar to that of the wild-type strain. These data indicate that the mutations are located in the structural gene of N. crassa glutamine synthetase.     

Regulation of glutamine synthetase in fed-batch cultures of Neurospora crassa.

The effect of the nitrogen and carbon sources in the regulation of g$\text{l}$u tamine synthetase has been studied in fed-batch cultures of $\text{Neurospora crassa}$. The limitation of ammonium in an excess of the carbon source, leads to an accumulation of α-ketoglutarate and elevation of glutamine sy$\text{n}$ thetase. The limitation of sucrose in an excess of ammonium results in a decrease in glutamine synthetase activity. These results indicate that the carbon source exerts a positive control in the regulation of glutamine synthetase.     

Nitrogen metabolite repression of nitrate reductase in Neurospora crassa: effect of the gln-1a locus.

Nicotinamide adenine dinucleotide phosphate (reduced form)-nitrate reductase was freed from ammonium repression in a Neurospora crassa mutant having drastically lowered glutamine synthetase activity, gln-1a. The general phenomenon of nitrogen metabolite repression required glutamine or some aspect of glutamine metabolism.     

Nitrogen source regulates glutamine synthetase mRNA levels in Neurospora crassa.

Neurospora crassa glutamine synthetase mRNA was measured by its capacity to direct the synthesis of the specific protein in a cell-free system derived from rabbit reticulocytes. N. crassa cultures grown on glutamate as the sole nitrogen source had higher mRNA activities than did those grown on glutamine. The differences were about 10-fold when polysomal RNA was used for translation and about 5-fold when either total cellular RNA or polyadenylic acid-enriched cellular RNA was used. These data indicate that in exponentially growing N. crassa, the nitrogen source regulates glutamine synthetase by adjusting specific mRNA levels.     

Glutamine Synthetase Isoenzymes of Striga hermonthica and other Angiosperm Root Parasites

The occurrence of multiple forms of glutamine synthetase inStriga hermonthica and other angiosperm root parasites was investigated.The facultative chlorophyllous parasite Melampyrum arvense exhibitedtwo isoenzymes in leaf tissue, the cytosolic component (GS₁)comprised less than 30% of total glutamine synthetase. In contrastGS₁ was the major component (<70%) in photosynthetic tissueof Striga hermonthica and S. gesnerioides. Only a single isoenzyme(GS₁) was detectable in the achlorophyllous root parasites Orobancheand Lathraea and in non-photosynthetic tissue of S. gesnerioides.The kinetic and physical properties of GS₁ and GS₂ of theseangiosperm parasites were similar to those of the isoenzymesin other non-parasitic angiosperms. Key words: Glutamine synthetase, Angiosperms, Root parasites     

Resveratrol Increases Glutamate Uptake, Glutathione Content, and S100B Secretion in Cortical Astrocyte Cultures

Resveratrol (3,5,4′-trihydroxy-trans-stilbene) is a polyphenol present in grapes and red wine, which has antioxidant properties and a wide range of other biological effects. In this study, we investigated the effect of resveratrol, in a concentration range of 10–250 μM, on primary cortical astrocytes; evaluating cell morphology, parameters of glutamate metabolism such as glutamate uptake, glutamine synthetase activity and glutathione total content, and S100B secretion. Astrocyte cultures were prepared of cerebral cortex from neonate Wistar rats. Morphology was evaluated by phase-contrast microscopy and immunocytochemistry for glial fibrillary acidic protein (GFAP). Glutamate uptake was measured using l-[2,3-³H]glutamate. Glutamine synthetase and content of glutathione were measured by enzymatic colorimetric assays. S100B content was determined by ELISA. Typical polygonal morphology becomes stellated when astrocyte cultures were exposed to 250 μM resveratrol for 24 h. At concentration of 25 μM, resveratrol was able to increase glutamate uptake and glutathione content. Conversely, at 250 μM, resveratrol decreased glutamate uptake. Unexpectedly, resveratrol at this high concentration increased glutamine synthetase activity. Extracellular S100B increased from 50 μM upwards. Our findings reinforce the protective role of this compound in some brain disorders, particularly those involving glutamate toxicity. However, the underlying mechanisms of these changes are not clear at the moment and it is necessary caution with its administration because elevated levels of this compound could contribute to aggravate these conditions.     

The use of affinity elution from Blue Dextran Sepharose by yeast tRNA2Val in the complete purification of the cytoplasmic valyl-tRNA synthetase from Euglena gracilis

Two distinct monomers, α and β participate in the structures of diffe$\text{r}$ ent oligomers of $\text{Neurospora crassa}$ glutamine synthetase (EC 6. 3. 1. 2). In ammonium-limited cultures a tetrameric form composed mainly of α monomers was found. In excess of nitrogen an octameric form composed mainly from β monomers is the predominant oligomeric state. The presence of both monomers was observed in intermediate oligomeric forms.     

Regulation of ammonium ion assimilation enzymes inNeurospora crassa nit-2 andms-5 mutant strains

InNeurospora crassa thenit-2 andnmr-1 (ms-5) loci represent the major control genes encoding regulatory proteins that allow the coordinated expression of various systems involved with the utilization of a secondary nitrogen source. In this paper we examine the effect of thenit-2 andms-5 (nmr-1 locus) mutations on the regulation of the ammonium assimilation enzymes, glutamine synthetase and glutamate dehydrogenase, which are regulated by the products of these genes; however, glutamate synthase is not so regulated. Glutamine synthetase and glutamate dehydrogenase levels are also regulated by the amino nitrogen content. We present evidence that thems-5 andgln ^r strains, which behave very similarly in their resistance to glutamine repression, are different and map in different loci.     

Neurospora crassa glutamine synthetase. Translation of specific messenger ribonucleic acid in a cell-free system derived from rabbit reticulocytes.

The total reticulocyte lysate cell-free protein-synthesizing system was incubated in the presence of Neurospora crassa RNA. With the aid of an antibody directed against purified N. crassa glutamine synthetase, the synthesis of a specific protein was detected. This protein precipitates with antiglutamine synthetase using both direct and indirect procedures, migrates with the same molecular weight as the monomer of N. crassa glutamine synthetase when subjected to acrylamide gel electrophoresis in the presence of sodium dodecyl sulfate, and chromatographs as N. crassa glutamine synthetase on anthranilate-bound Sepharose. These data indicate the translation of the mRNA that codes for N. crassa glutamine synthetase. This RNA behaves as poly(A)-containing material when fractionated on oly(U)-Sepha-rose.     

Vertical distribution, life cycle and production of the chaetognath Sagitta crassa in Tokyo Bay, Japan

The daytime vertical distribution of Sagiita crassa in TokyoBay was examined from February 13, 1988 to February 20, 1989.High densities of larger-size chaetognaths were found near thesea bottom, whereas the smaller animals tended to inhabit theupper layers. This feature of distribution is discussed in relationto the distribution of their main food organisms, e g. Pseudodiaptomusmarinus, Acartia omoru, Centropages abdomialis and Oithona davisae.The two periods of replacement of two morphs were confirmedby the variation only in mean body length of this chaetognath,unlike the previous authors who made additional morphologicalobservations. It was hypothesized that S.crassa has at leastfive generations Two generations, including mostly the largerforms, had higher growth rates than the generation consistingmainly of the small form. Yearly respiration of S.crassa was8.2 g C m^–Abstract. Yearly production of this animal wasestimated to be 3.8 g C m^–. A feeding estimate revealedthat chaetognaths require a prey production of 13.1 g C m^–year^–1. The impact of this chaetognath on the prey populationin Tokyo Bay and the propriety of an estimated value of annualproduction of S crassa is discussed.     

Neurospora crassa glutamine synthetase. Role of enzyme synthesis and degradation on the regulation of enzyme concentration during exponential growth.

The specific activity of Neurospora crassa glutamine synthetase varies according to the nitrogen source in which the organism is grown. In a poor nitrogen source such as glutamate, the specific activity of the enzyme is higher than that found in good nitrogen sources such as ammonium or glutamine. These differences in specific enzyme activity correspond to differences in enzyme concentration. The relative rates of glutamine synthetase synthesis and degradation were measured in exponential cultures grown in different nitrogen sources. The differences in enzyme concentration are explained by differences in the relative rate of enzyme synthesis.     

Nitrogen metabolism in the blue mycelia ofNeurospora crassa isolated from copper toxic cultures

The toxicity of copper on a sole nitrate medium containing KH₂PO₄ as the phosphate source has been studied inNeurospora crassa. Iron counteracted the copper toxicity by suppressing the copper uptake and restored complete growth at a lower iron-copper molar ratio. Nitrite reductase activity was inhibited (75%) in copper toxic cultures, while the nitrate reductase activity was unaltered. Nitrite accumulated in the medium; this indicated decreased conversion of nitrate to ammonia. Alanine transaminase was also inhibited in copper toxicity, resulting in an accumulation of keto acids. Iron could restore the nitrite reductase and the transaminase activities to about 70% of the control value. The accumulation of both nitrite and keto acids disappeared under conditions of reversal of copper toxicity by iron.     

NADH-dependent glutamate synthase and nitrogen metabolism in Neurospora crassa

The GDH (NADPH) mutant strain $\text{am-1}$ of $\text{N. crassa}$ has sizable pools of glutamine and glutamate under ammonium-limited conditions for which requires an elevated glutamine synthetase activity. Glutamine in the pre$\text{s}$ ence of 2-oxoglutarate, stimulated nicotinamide nucleotide oxidation by crude and purified extracts of the $\text{am-1}$ strain and led to a reductant dependent formation of two molecules of glutamate. Aminooxyacetate did not have any effect on the reaction, whereas azaserine inhibited it completely. It is concluded that in $\text{N. crassa}$ glutamine synthetase and glutamate synthase are responsible for the assimilation of low ammonium concentrations.     

Glutamine Synthetase Sensitivity to Oxidative Modification during Nutrient Starvation in Prochlorococcus marinus PCC 9511

Glutamine synthetase plays a key role in nitrogen metabolism, thus the fine regulation of this enzyme in Prochlorococcus, which is especially important in the oligotrophic oceans where this marine cyanobacterium thrives. In this work, we studied the metal-catalyzed oxidation of glutamine synthetase in cultures of Prochlorococcus marinus strain PCC 9511 subjected to nutrient limitation. Nitrogen deprivation caused glutamine synthetase to be more sensitive to metal-catalyzed oxidation (a 36% increase compared to control, non starved samples). Nutrient starvation induced also a clear increase (three-fold in the case of nitrogen) in the concentration of carbonyl derivatives in cell extracts, which was also higher (22%) upon addition of the inhibitor of electron transport, DCMU, to cultures. Our results indicate that nutrient limitations, representative of the natural conditions in the Prochlorococcus habitat, affect the response of glutamine synthetase to oxidative inactivating systems. Implications of these results on the regulation of glutamine synthetase by oxidative alteration prior to degradation of the enzyme in Prochlorococcus are discussed.     

Glutamine transport by the blood-brain barrier: a possible mechanism for nitrogen removal

Glutamine and glutamate transport activities were measuredin isolated luminal and abluminal plasma membrane vesiclesderived from bovine brain endothelial cells. Facilitativesystems for glutamine and glutamate were almost exclusivelylocated in luminal-enriched membranes. The facilitativeglutamine carrier was neither sensitive to2-aminobicyclo(2,2,1)heptane-2-carboxylic acid inhibition nor did itparticipate in accelerated amino acid exchange; it therefore appearedto be distinct from the neutral amino acid transport system L1. TwoNa-dependent glutamine transporters were found in abluminal-enrichedmembranes: systems A and N. System N accounted for ~80% ofNa-dependent glutamine transport at 100 µM. Abluminal-enriched membranes showed Na-dependent glutamate transport activity. The presence of 1) Na-dependent carrierscapable of pumping glutamine and glutamate from brain into endothelialcells, 2) glutaminase withinendothelial cells to hydrolyze glutamine to glutamate and ammonia, and3) facilitative carriers forglutamine and glutamate at the luminal membrane may provide a mechanismfor removing nitrogen and nitrogen-rich amino acids from brain.

     

Effects of Auxin and Gibberellin on Elongation of Young Hyphae in Neurospora crassa

IAA, 2,4-D and GA₃ promoted the elongation of young hyphae inNeurospora crassa at the optimum concentrations of 10^–6,10^–6 and 10^–4 M, respectively. The effects of IAAand GA₃ were additive. (Received June 17, 1983; Accepted December 22, 1983)     

Enzymology of Glutamine Metabolism Related to Senescence and Seed Development in the Pea (Pisum sativum L.)

The metabolism of glutamine in the leaf and subtended fruit of the aging pea (Pisum sativum L. cv. Burpeeana) has been studied in relation to changes in the protein, chlorophyll, and free amino acid content of each organ during ontogenesis. Glutamine synthetase [EC 6.3.1.2] activity was measured during development and senescence in each organ. Glutamate synthetase [EC 2.6.1.53] activity was followed in the pod and cotyledon during development and maturation. Maximal glutamine synthetase activity and free amino acid accumulation occurred together in the young leaf. Glutamine synthetase (in vitro) in leaf extracts greatly exceeded the requirement (in vivo) for reduced N in the organ. Glutamine synthetase activity, although declining in the senescing leaf, was sufficient (in vitro) to produce glutamine from all of the N released during protein hydrolysis (in vivo). Maximal glutamine synthetase activity in the pod was recorded 6 days after the peak accumulation of the free amino acids in this organ.

In the young pod, free amino acids accumulated as glutamate synthetase activity increased. Maximal pod glutamate synthetase activity occurred simultaneously with maximal leaf glutamine synthetase activity, but 6 days prior to the corresponding maximum of glutamine synthetase in the pod. Cotyledonary glutamate synthetase activity increased during the assimilatory phase of embryo growth which coincided with the loss of protein and free amino acids from the leaf and pod; maximal activity was recorded simultaneously with maximal pod glutamine synthetase.

We suggest that the activity of glutamine synthetase in the supply organs (leaf, pod) furnishes the translocated amide necessary for the N nutrition of the cotyledon. The subsequent activity of glutamate synthetase could provide a mechanism for the transfer of imported amide N to alpha amino N subsequently used in protein synthesis. In vitro measurements of enzyme activity indicate there was sufficient catalytic potential in vivo to accomplish these proposed roles.

     

Nitrogenous nutrition of the potentially toxic diatom Pseudonitzschia pungens f. multiseries Hasle

The potentially toxic diatom Pseudonitzschia pungens f. multiserieswas grown on different sources of nitrogen in batch cultures.Ammonium did not support growth at concentrations >200 µM,and even lowered the growth rate, when it was supplied in additionto growth-saturating nitrate concentrations. This seemed tobe a combined effect of inhibition of nitrate uptake and directammonia toxicity. Urea, glutamine and nitrite were used readilyby P.pungens.     

Immunological Studies on Glutamine Synthetase using Antisera Raised to the Two Plant Forms of the Enzyme from PhaseolusRoot Nodules

Antisera specific for glutamine synthetase (GS) have been raisedto the two forms of the enzyme from the plant fraction of rootnodules of Phaseolus vulgaris. The two antisera recognized bothforms of plant nodule GS and also the enzyme from some otherhigher plant tissues. However, the antiserum did not cross-reactwith GS from free-living or bacteroid Rhizobium Phaseolinorwith the enzyme from representatives of green algae, fungi,mammals and bacteria. Results are presented which suggest thatone of the forms of nodule GS is closely related to the rootenzyme whereas the other, the 'nodule specific' form, has someantigenic differences Key words: Phaseolus Vulgaris, Legume/Rhizobium symbosis, Glutamine synthetase, Immunology