Studies on in vivo inactivation of gramicidin S synthetase and its retardation

The oxygen-dependent in vivo inactivation of gramicidin S synthetase was investigated in Bacillus brevis ATCC 9999. Inhibitors of energy metabolism and of protein synthesis added to aerated cell suspensions did not provide any protection against inactivation, thus indicating that the process does not depend on energy-yielding metabolism nor on de novo protein synthesis. Organic thiols added to anaerobic long-term incubations retarded synthetase inactivation for several hours, whereas in short-term incubations of previously air-exposed cells they resulted in partial restoration of activity. The in vivo inactivation of the enzyme was found to be accompanied by a parallel drop in intracellular thiols. These results implicate enzyme SH oxidation as a mechanism of in vivo inactivation. Retardation of inactivation was achieved upon addition of utilizable carbon sources (glycerol, fructose, inositol) to aerated cell suspensions in buffer, the degree of stabilization being proportional to the ease of uptake and to the concentration of C source. This effect involves actual consumption of the exogenous C source and is accompanied by lower dissolved oxygen levels in the cell suspension. Pulsed additions of C source could retard inactivation but could not restore partly or fully lost activity. The C-source effect was blocked by the uncoupler dinitrophenol, while dissolved oxygen levels in the suspension remained low. C-source-supplemented cell suspensions incubated under air had a decreased intracellular redox state, as revealed by intracellular SH concentration.     

Glutamine synthetase is a molecular target of nitric oxide in root nodules of Medicago truncatula and is regulated by tyrosine nitration

Nitric oxide (NO) is emerging as an important regulatory player in the Rhizobium-legume symbiosis, but its biological role in nodule functioning is still far from being understood. To unravel the signal transduction cascade and ultimately NO function, it is necessary to identify its molecular targets. This study provides evidence that glutamine synthetase (GS), a key enzyme for root nodule metabolism, is a molecular target of NO in root nodules of Medicago truncatula, being regulated by tyrosine (Tyr) nitration in relation to active nitrogen fixation. In vitro studies, using purified recombinant enzymes produced in Escherichia coli, demonstrated that the M. truncatula nodule GS isoenzyme (MtGS1a) is subjected to NO-mediated inactivation through Tyr nitration and identified Tyr-167 as the regulatory nitration site crucial for enzyme inactivation. Using a sandwich enzyme-linked immunosorbent assay, it is shown that GS is nitrated in planta and that its nitration status changes in relation to active nitrogen fixation. In ineffective nodules and in nodules fed with nitrate, two conditions in which nitrogen fixation is impaired and GS activity is reduced, a significant increase in nodule GS nitration levels was observed. Furthermore, treatment of root nodules with the NO donor sodium nitroprusside resulted in increased in vivo GS nitration accompanied by a reduction in GS activity. Our results support a role of NO in the regulation of nitrogen metabolism in root nodules and places GS as an important player in the process. We propose that the NO-mediated GS posttranslational inactivation is related to metabolite channeling to boost the nodule antioxidant defenses in response to NO.     

Relationship of adhesiveness of cells in culture with specific enzyme activity.

l-Glutamine is required by mouse teratoma cells and other mouse ascites tumor cells in the synthesis of complex carbohydrates involved in intercellular adhesion. Since l-glutamine is synthesized by the enzyme glutamine synthetase (GS) (EC 6.3.1.2), these studies were undertaken to determine if a relationship exists between cellular adhesiveness and GS specific activity. Two types of experiment were performed to examine this relationship. Actinomycin D enhanced both teratoma cell GS specific activity and cellular adhesiveness over controls in batch cultures at confluency. Also, the relationship between cell adhesiveness and GS specific activity during the cell cycle was studied using cell populations synchronized with thymidine plus Colcemid. In these synchronized cultures, cellular adhesiveness displayed an oscillatory pattern with peaks of GS specific activity occurring just prior to peaks of adhesiveness. The levels of GS specific activity and intercellular adhesiveness were enhanced by the addition of hydrocortisone, a steroid known to induce GS specific activity in mouse teratoma cells. These results demonstrate a correlation between GS specific activity and cellular adhesiveness. Based upon previous work which implicates l-glutamine in intercellular adhesion, it is not unreasonable to speculate that GS specific activity and cellular adhesiveness may be causally related.     

Role of glutamine synthetase adenylylation in the self-protection of Pseudomonas syringae subsp. "tabaci" from its toxin, tabtoxinine-beta-lactam

Selected pathovars of Pseudomonas syringae produce an extracellular phytotoxin, tabtoxinine-beta-lactam, that irreversibly inhibits its known physiological target, glutamine synthetase (GS). Pseudomonas syringae subsp. "tabaci" retains significant amounts of glutamine synthetase activity during toxin production in culture. As part of our investigation of the self-protection mechanism(s) used by these pathovars, we have determined that GS becomes adenylylated after toxin production is initiated and that the serine released from the zinc-activated hydrolysis of tabtoxin is a factor in the initiation of this adenylylation. The adenylylation state of this GS was estimated to range from E5.0-7.5. The irreversible inactivation by tabtoxinine-beta-lactam of unadenylylated and adenylylated glutamine synthetase purified from P. syringae subsp. "tabaci" was investigated. Adenylylated GS was inactivated by tabtoxinine-beta-lactam at a slower rate than was unadenylylated enzyme. Adenylylated GS (E7.5-10.5) was significantly protected from this inactivation in the presence of the enzyme effectors, AMP, Ala, Gly, His, and Ser. Thus, the combination of the adenylylation of GS after toxin production is initiated and the presence of the enzyme effectors in vivo could provide part of the self-protection mechanism used by subsp. "tabaci".     

Oxidative inactivation of glutamine synthetase from the cyanobacterium Anabaena variabilis.

In crude extracts of the cyanobacterium Anabaena variabilis, glutamine synthetase (GS) could be effectively inactivated by the addition of NADH. GS inactivation was completed within 30 min. Both the inactivated GS and the active enzyme were isolated. No difference between the two enzyme forms was seen in sodium dodecyl sulfate-gels, and only minor differences were detectable by UV spectra, which excludes modification by a nucleotide. Mass spectrometry revealed that the molecular masses of active and inactive GS are equal. While the Km values of the substrates were unchanged, the Vmax values of the inactive GS were lower, reflecting the inactivation factor in the crude extract. This result indicates that the active site was affected. From the crude extract, a fraction mediating GS inactivation could be enriched by ammonium sulfate precipitation and gel filtration. GS inactivation by this fraction required the presence of NAD(P)H, Fe3+, and oxygen. In the absence of the GS-inactivating fraction, GS could be inactivated by Fe2+ and H2O2. The GS-inactivating fraction produced Fe2+ and H2O2, using NADPH, Fe3+, and oxygen. Accordingly, the inactivating fraction was inhibited by catalase and EDTA. This GS-inactivating system of Anabaena is similar to that described for oxidative GS inactivation in Escherichia coli. We conclude that GS inactivation by NAD(P)H is caused by irreversible oxidative damage and is not due to a regulatory mechanism of nitrogen assimilation.     

Glutathione peroxidase 3 of Saccharomyces cerevisiae suppresses non-enzymatic proteolysis of glutamine synthetase in an activity-independent manner

Glutathione peroxidase 3 (Gpx3) is ubiquitously expressed and is important antioxidant enzyme in yeast. It modulates the activities of redox-sensitive thiol proteins, particularly those involved in signal transduction pathway and protein translocation. Through immunoprecipitation/two-dimensional gel electrophoresis (IP-2DE), MALDI-TOF mass spectrometry, and a pull down assay, we found glutamine synthetase (GS; EC 6.3.1.2) as a candidate interacting protein with Gpx3. GS is a key enzyme in nitrogen metabolism and ammonium assimilation. It has been known that GS is non-enzymatically cleaved by ROS generated by MFO (thiol/ Fe(3+)/O(2) mixed-function oxidase) system. In this study, it is demonstrated that GS interacts with Gpx3 through its catalytic domain both in vivo and in vitro regardless of redox state. In addition, Gpx3 helps to protect GS from inactivation and degradation via oxidative stress in an activity-independent manner. Based on the results, it is suggested that Gpx3 protects GS from non-enzymatic proteolysis, thereby contributing to cell homeostasis when cell is exposed to oxidative stress.     

Glutamine Synthetase-Induced Enhancement of β-Amyloid Peptide Aβ(1–40) Neurotoxicity Accompanied by Abrogation of Fibril Formation and Aβ Fragmentation

Abstract: β-Amyloid peptide (Aβ) is the main constituent in both senile plaques and diffuse deposits in Alzheimer's diseased brains. It was previously shown that synthetic Aβs were able to form free radical species in aqueous solution and cause both oxidative damage to cell proteins and inactivation of key metabolic enzymes. We also previously demonstrated that an interaction of Aβ(1–40) with the oxidatively sensitive enzyme glutamine synthetase (GS) resulted in both inactivation of GS and an increase of Aβ toxicity to hippocampal cell cultures. In the present study the enhancement of Aβ toxicity during interaction with GS was found to be accompanied by abrogation of fibril formation and partial fragmentation of Aβ(1–40). HPLC elution profiles demonstrated the production of several peptide fragments. Analysis of the amino acid sequence of the major fragments identified them as the first 15 and the last six amino acids of Aβ(1–40). The fragmentation of Aβ was inhibited by immunoprecipitation of GS.     

Oxidative Modification of Glutamine Synthetase by Amyloid Beta Peptide

β-Amyloid peptide (Aβ), the main constituent of senile plaques and diffuse amyloid deposits in Alzheimer's diseased brain, was shown to initiate the development of oxidative stress in neuronal cell cultures. Toxic lots of Aβ form free radical species in aqueous solution. It was proposed that Aβ-derived free radicals can directly damage cell proteins via oxidative modification. Recently we reported that synthetic Aβ can interact with glutamine synthetase (GS) and induce inactivation of this enzyme. In the present study we present the evidence that toxic Aβ(25-35) induces the oxidation of pure GS in vitro. It was found that inactivation of GS by Aβ, as well as the oxidation of GS by metal-catalyzed oxidation system, is accompanied by an increase of protein carbonyl content. As it was reported previously by our laboratory, radicalization of Aβ is not iron or peroxide-dependent. Our present observations consistently show that toxic Aβ does not need iron or peroxide to oxidize GS. However, treatment of GS with the peptide, iron and peroxide together significantly stimulates the protein carbonyl formation. Here we report also that Aβ(25-35) induces carbonyl formation in BSA. Our results demonstrate that P-peptide, as well as other free radical generators, induces carbonyl formation when brought into contact with different proteins.     

Regulation of glutamine synthetase by metal-catalyzed oxidative modification in the marine oxyphotobacterium Prochlorococcus.

The inactivation of glutamine synthetase (GS; EC 6.3.1.2) by metal-catalyzed oxidation (MCO) systems was studied in several Prochlorococcus strains, including the axenic PCC 9511. GS was inactivated in the presence of various oxidative systems, either enzymatic (as NAD(P)H+NAD(P)H-oxidase+Fe(3+)+O(2)) or non-enzymatic (as ascorbate+Fe(3+)+O(2)). This process required the presence of oxygen and a metal cation, and is prevented under anaerobic conditions. Catalase and peroxidase, but not superoxide dismutase, effectively protected the enzyme against inactivation, suggesting that hydrogen peroxide mediates this mechanism, although it is not directly responsible for the reaction. Addition of azide (an inhibitor of both catalase and peroxidase) to the MCO systems enhanced the inactivation. Different thiols induced the inactivation of the enzyme, even in the absence of added metals. However, this inactivation could not be reverted by addition of strong oxidants, as hydrogen peroxide or oxidized glutathione. After studying the effect of addition of the physiological substrates and products of GS on the inactivation mechanism, we could detect a protective effect in the case of inorganic phosphate and glutamine. Immunochemical determinations showed that the concentration of GS protein significantly decreased by effect of the MCO systems, indicating that inactivation precedes the degradation of the enzyme.     

Regulation of glutamine metabolism in Chlorella pyrenoidosa. Mechanisms of regulating the activity of glutamine synthetase during ammonia assimilation]

Glutamine synthetase (GS) (E.C.6.3.1.2) activity in Chlorella cells decreased when NH4+ was added to nitrogen-free growth medium. This GS inactivation had such a rate, that it could not be due to the repression of enzyme synthesis: the GS activity decreased by 20% within 5 minutes of NH4+ assimilation. Glutamine content in cell increased in 2.5 times for this period. In vitro experiments have shown that glutamine is a strong inhibitor of GS from Chlorella grown in the presence of NO3-, and in a less degree--an inhibitor of GS from cells grown in ammonium-containing medium. The data obtained are negative with respect to possible mechanisms of GS activity regulation via adenylation and ATP-dependent destruction of glutamine synthetase.     

Enhancement of β-Amyloid Peptide Aβ(1–40)-Mediated Neurotoxicity by Glutamine Synthetase

Abstract: The β-amyloid peptide (Aβ), a main constituent in both senile and diffuse plaques in Alzheimer's disease brains, was previously shown to be neurotoxic and to be able to interact with several macromolecular components of brain tissue. Previous investigations carried out in our laboratory demonstrated free radical species formation in aqueous solutions of Aβ(1–40) and its C-end fragment, Aβ(25–35). Toxic forms of Aβ rapidly inactivate the oxidation-sensitive cytosolic enzyme glutamine synthetase (GS). In this regard, we suggested and subsequently demonstrated that Aβ radicals can cause an oxidative damage of cell proteins and lipids resulting in disruption of membrane functions, enzyme inactivation, and cell death. Because GS can be a substrate for Aβ-derived oxidizing species, the present study was conducted to determine if GS could protect against Aβ neurotoxicity. In contrast to this initial hypothesis, we here report that GS significantly enhances the neurotoxic effects of Aβ(1–40). The Aβ-mediated inactivation of GS was found to be accompanied by the loss of immunoreactive GS and the significant increase of Aβ(1–40) neurotoxicity.     

Effect of glutamine on glutamine-synthetase regulation in the green alga Monoraphidium braunii

Glutamine-synthetase (GS; EC 6.3.1.2) activity and protein levels were measured in crude extracts from Monoraphidium braunii Näegeli, strain 202-7d, cultures grown under different nitrogen sources. Only ammonium and l-glutamine promoted a partial enzyme inactivation, which, in the case of l-glutamine, was accompanied by a significant repression of GS. Methionine sulfoximine (MSX), a strong inhibitor of GS, produced a drastic inactivation of GS which was concomitant with a marked increase in GS protein as measured by rocket immunoelectrophoresis. Such an increase was prevented in the presence of cycloheximide. The effect of the l-glutamine analog on GS activity and protein was partially inhibited if l-glutamine was also added to cell cultures, possibly indicating competition in the transport of these two substances. In addition, the effects of MSX were reversed after longer times when cultures were treated with smaller concentrations of inhibitor. Treatment of cell cultures with azaserine, a specific inhibitor of glutamate synthase, the second enzyme acting in the ammonium assimilation pathway, promoted a strong GS inactivation and a partial repression of this enzyme, which paralleled a specific increase in the intracellular pools of glutamine High-performance liquid chromatography measurements of intracellular amino-acid concentrations showed that glutamine levels correlated negatively with GS concentration. A role for glutamine as a negative effector of GS synthesis is proposed.Abbreviations GS l-glutamine synthetase - GOGAT l-glu-tamine:2-oxoglutarate amidotransferase - MSX methionine sulfoximine During the course of this work, J.A. was supported by a fellowship from Junta de Andalucía, and J.M. G-F. by a fellowship from the Spanish Ministerio de Educatión y Ciencia. This work was supported by the Junta de Andalucía.     

Ammonium assimilation in Rhizobium phaseoli by the glutamine synthetase-glutamate synthase pathway.

Evidence from in vitro and in vivo studies showed that in Rhizobium phaseoli ammonium is assimilated by the glutamine synthetase (GS)-glutamate synthase NADPH pathway. No glutamate dehydrogenase activity was detected. R. phaseoli has two GS enzymes, as do other rhizobia. The two GS activities are regulated on the basis of the requirement for low (GSI) or high (GSII) ammonium assimilation. When the 2-oxoglutarate/glutamine ratio decreases, GSI is adenylylated. When GSI is inactivated, GSII is induced. However, induction of GSII activity varied depending on the rate of change of this ratio. GSII was inactivated after the addition of high ammonium concentrations, when the 2-oxoglutarate/glutamine ratio decreased rapidly. Ammonium inactivation resulted in alteration of the catalytic and physical properties of GSII. GSII inactivation was not relieved by shifting of the cultures to glutamate. After GSII inactivation, ammonium was excreted into the medium. Glutamate synthase activity was inhibited by some organic acids and repressed when cells were grown with glutamate as the nitrogen source.     

Electron Transport Controls Glutamine Synthetase Activity in the Facultative Heterotrophic Cyanobacterium Synechocystis sp. PCC 6803

Glutamine synthetase (GS) from Synechocystis sp. PCC 6803 was inactivated in vivo by transferring cells from light to darkness or by incubation with the photosynthetic inhibitor 3-(3,4-dichlorophenyl)-1,1-dimethylurea but not with 2,5-dibromo-3-methyl-6-isopropyl-p-benzoquinone. Addition of glucose prevented both dark and 3-(3,4-dichlorophenyl)-1,1-dimethylurea GS inactivation. In a Synechocystis psbE-psbF mutant (T1297) lacking photosystem II, glucose was required to maintain active GS, even in the light. However, in nitrogen-starved T1297 cells the removal of glucose did not affect GS activity. The fact that dark-inactivated GS was reactivated in vitro by the same treatments that reactivate the ammonium-inactivated GS points out that both nitrogen metabolism and redox state of the cells lead to the same molecular regulatory mechanism in the control of GS activity. Using GS antibodies we detected that dark-inactivated GS displayed a different electrophoretic migration with respect to the active form in nondenaturing polyacrylamide gel electrophoresis but not in sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The possible pathway to modulate GS activity by the electron transport flow in Synechocystis cells is discussed.     

Glutamine synthetase in cultured whole retinas from the embryonic chick: Enhancement of basal and induced activity by 4 °C storage

Storage of whole retinas from the embryonic chick for 24 h at 4 °C resulted in increased basal levels of glutamine synthetase (GS) during subsequent incubation at 37 °C in the absence of cortisol. GS levels in these retinas maintained initially at 4 °C (CS), in many cases, exceeded GS levels in cortisol-induced whole retinas incubated solely at 37 °C. The increase in basal GS activity is seen within 48 h of the transfer of the retinas from 4 to 37 °C. If cortisol (0.001 μg/ml = 2.8 nm or 0.01 μg/ml = 28 nm) is added during the last 24 h of culture to CS retinas subsequently transferred to 37 °C, levels of GS are attained that are higher than those in the corresponding retinas cultured continually at 37 °C. However, the activity ratios (GS specific activity in cortisol-treated retinas/GS specific activity in retinas not exposed to cortisol) are similar for CS retinas and those maintained at 37 °C throughout. Monolayers of retinal cells display similar basal and cortisol-induced levels of GS independent of treatment. Retinal monolayers maintained at 4 °C for 24 h and subsequently incubated at 37 °C do not exhibit increases in either basal or cortisol-induced levels of GS over those in monolayers maintained at 37 °C throughout. The CS-promoted increase in the basal and cortisol-induced GS activity of whole retinas is eliminated by enzymatic dispersion of the retina just prior to 37 °C culture of the cells as monolayers. Both basal and cortisol-induced GS levels in the latter monolayers resemble those in retinal cells kept as monolayers throughout.     

Regulation of glutamine synthetase, aspartokinase, and total protein turnover in Klebsiella aerogenes

When suspensions of Klebsiella aerogenes are incubated in a nitrogen-free medium there is a gradual decrease in the levels of acid-precipitable protein and of aspartokinase III (lysine-sensitive) and aspartokinase I (threonine-sensitive) activities. In contrast, the level of glutamine synthetase increases slightly and then remains constant. Under these conditions, the glutamine synthetase and other proteins continue to be synthesized as judged by the incorporation of [14C]leucine into the acid-precipitable protein fraction and into protein precipitated by anti-glutamine synthetase antibodies, by the fact that growth-inhibiting concentrations of chloramphenicol also inhibit the incorporation of [14C]leucine into protein and into protein precipitated by anti-glutamine synthetase antibody, and by the fact that chloramphenicol leads to acceleration in the loss of aspartokinases I and III and promotes a net decrease in the level of glutamine synthetase and its cross-reactive protein. The loss of aspartokinases I and III in cell suspensions is stimulated by glucose and is inhibited by 2,4-dinitrophenol. Glucose also stimulates the loss of aspartokinases and glutamine synthetase in the presence of chloramphenicol. Cell-free extracts of K. aerogenes catalyze rapid inactivation of endogenous glutamine synthetase as well as exogenously added pure glutamine synthetase. This loss of glutamine synthetase is not associated with a loss of protein that cross-reacts with anti-glutamine synthetase antibodies. The inactivation of glutamine synthetase in extracts is not due to adenylylation. It is partially prevented by sulfhydryl reagents, Mn2+, antimycin A, 2,4-dinitrophenol, EDTA, anaerobiosis and by dialysis. Following 18 h dialysis, the capacity of extracts to catalyze inactivation of glutamine synthetase is lost but can be restored by the addition of Fe2+ (or Ni2+) together with ATP (or other nucleoside di- and triphosphates. After 40-60 h dialysis Fe3+ together with NADH (but not ATP) are required for glutamine synthetase inactivation. The results suggest that accelerated protein degradation in cells exposed to nitrogen-limited conditions reflects the differential destruction of some proteins, including aspartokinases I and III, in order to sustain the biosynthesis of others such as glutamine synthetase. The loss of glutamine synthetase activity in cell-free extracts is likely mediated in part by mixed-function oxidation systems and could represent a 'marking' step in protein turnover.     

Modulation of cortisol receptors in embryonic retina cells by changes in cell-cell contacts: Correlations with induction of glutamine synthetase

Cortisol induces glutamine synthetase (GS) in neural retina tissue of chick embryos. GS induction represents a characteristic feature of embryonic retina differentiation. However, if the tissue is dissociated into single cells, the dispersed cells are not inducible for GS. We report that cell dispersion results in a rapid and marked reduction in the level of cortisol-binding cytoplasmic receptors. This reduction persists if the cells are maintained in a dispersed state. However, if the cells are reaggregated and they reconstruct tissue-like contacts and architecture, the level of cortisol receptors increases, and so does inducibility for GS. The results indicate that, in the embryonic neural retina histotypic cell contacts and interactions are involved in regulating the level of cortisol receptors. We propose that cell contact-dependent signals from the cell surface may modulate levels of cytoplasmic cortisol receptors necessary for GS induction.     

Interaction of substrates with glutamine synthetase after limited proteolysis

Previous studies [Dautry-Varsat, A., Cohen, G. N., & Stadtman, E.R. (1979) J. Biol. Chem. 254, 3124-3128; Lei, M., Aebi, U., Heidner, E. G., & Eisenberg, D. (1979) J. Biol. Chem. 254, 3129-3134] have shown that Escherichia coli glutamine synthetase (GS) can be cleaved by proteases to form a limited digestion species called nicked glutamine synthetase (GS). The present study gives the amino acid sequence of the protease-sensitive region of glutamine synthetase. The present study also shows that GS is enzymatically active, but this activity is low compared to the activity of GS. The apparent Michaelis constant value for glutamate was 90 mM for GS as compared to 3 mM for GS, while the Michaelis constant values for ATP were similar for GS and GS*. The dissociation constant values for ATP, as determined by intrinsic fluorescence measurements, were similar for GS and GS*. Glutamate decreased the dissociation constant value of ATP for GS because of synergism between the two binding sites; glutamate did not decrease the dissociation constant value of ATP for GS*. The glutamate analogue methionine sulfoximine bound very tightly to GS and inactivated the enzyme in the presence of ATP. Methionine sulfoximine did not appear to bind to GS* and did not inactivate GS* in the presence of ATP. The ATP analogue 5'-[p-(fluorosulfonyl)benzoyl]adenosine bound to GS and inactivated the enzyme by forming a covalent bond with it. Glutamate accelerated this inactivation because of the synergism between the ATP and glutamate binding sites of GS.(ABSTRACT TRUNCATED AT 250 WORDS)     

Oxidation of Neurospora crassa glutamine synthetase.

The glutamine synthetase of Neurospora crassa, either purified or in cell extracts, was inactivated by ascorbate plus FeCl3 and by H2O2 plus FeSO4. The inactivation reaction was oxygen dependent, inhibited by MnCl2 and EDTA, and stimulated in cell extracts by sodium azide. This inactivation could also be brought about by adding NADPH to the cell extract. The alpha and beta polypeptides of the active glutamine synthetase were modified by these inactivating reactions, giving rise to two novel acidic polypeptides. These modifications were observed with the purified enzyme, with cell extracts, and under in vivo conditions in which glutamine synthetase is degraded. The modified glutamine synthetase was more susceptible to endogenous phenylmethylsulfonyl fluoride-insensitive proteolytic activity, which was inhibited by MnCl2 and stimulated by EDTA. The possible physiological relevance of enzyme oxidation is discussed.     

Effect of nitrous oxide-induced inactivation of vitamin B12 on glycinamide ribonucleotide transformylase and 5-amino-4-imidazole carboxamide transformylase

Exposure to nitrous oxide (N2O) in vivo is accompanied by oxidation of cob[I]-alamin to the inactive cob[III]alamin [1]. There is loss of methionine synthetase activity [2] and evidence of depressed supply of single carbon units at the formate level of oxidation [3,4,5]. We measured the effect of inactivation of B12 on the folate-dependent transformylases concerned in purine synthesis. After 24 h exposure to N2O there was a significant fall in glycinamide ribonucleotide transformylase (EC 2.1.2.2) and a significant increase in 5-amino-4-imidazole carboxamide transformylase (EC 2.1.2.3).