Purification of a protease from Escherichia coli with specificity for oxidized glutamine synthetase

Regulation of Glutamine Synthetase Activity

Detailed studies of the glutamine synthetase (GS) in Escherichia coli and other bacteria have shown that the activity of this enzyme is regulated by at least five different mechanisms: (i) cumulative feedback inhibition by multiple end products of glutamine metabolism, (ii) interconversion between taut and relaxed protein configurations in response to binding and dissociation of divalent cations at one of its two metal binding sites, (iii) dynamic interconversion of the enzyme between covalently modified (adenylylated) and unmodified forms by a novel bicyclic cascade system, (iv) repression and derepression of glutamine synthetase formation by cyclic phosphorylation and dephosphorylation of an RNA factor that governs transcription activities, and (v) regulation of glutamine synthetase turnover by the coupling of site specific metal ion-catalyzed oxidation with proteolytic degradation of the enzyme. Glutamine synthetase activity in E. coli is subject to inhibition by seven different end products of glutamine metabolism, namely, by tryptophan, histidine, carbamyl-phosphate, CTP, AMP, glucose-6-phosphate, and NAD+, and also by serine, alanine, and glycine. The cascade theory predicts that the steady-state level of glutamine synthetase adenylylation and therefore its catalytic activity is determined by the combined effects of all metabolites that affect the kinetic parameters of one or more of the enzymes in the cascade. Furthermore, under conditions where the supplies of ATP and glutamate are not limiting and the production of glutamine exceeds the demand, GS is no longer needed, then it will be converted to the catalytically inactive adenylylated form that is not under protection of ATP and glutamate.

Protein oxidation and aging

Organisms are constantly exposed to various forms of reactive oxygen species (ROS) that lead to oxidation of proteins, nucleic acids, and lipids. Protein oxidation can involve cleavage of the polypeptide chain, modification of amino acid side chains, and conversion of the protein to derivatives that are highly sensitive to proteolytic degradation. Unlike other types of modification (except cysteine oxidation), oxidation of methionine residues to methionine sulfoxide is reversible; thus, cyclic oxidation and reduction of methionine residues leads to consumption of ROS and thereby increases the resistance of proteins to oxidation. The importance of protein oxidation in aging is supported by the observation that levels of oxidized proteins increase with animal age. The age-related accumulation of oxidized proteins may reflect age-related increases in rates of ROS generation, decreases in antioxidant activities, or losses in the capacity to degrade oxidized proteins.

Elevated Ras/protein kinase A activity in Saccharomyces cerevisiae reduces proliferation rate and lifespan by two different reactive oxygen species-dependent routes

Cells with overactive RAS/protein kinase A (PKA) signaling, such as RAS2(Val19) cells, exhibit reduced proliferation rates and accelerated replicative senescence. We show here that the extended generation time of RAS2(Val19)cells is the result of abrogated ATP/ADP carrier activity of the mitochondria. Both PKA-dependent and independent routes are responsible for inhibiting ATP/ADP exchange in the RAS-overactive cells. The reduced carrier activity is due, at least in part, to elevated levels of reactive oxygen species (ROS), which also cause a proteolysis-dependent fragmentation of the Aac2p carrier both in vivo and on isolated mitochondria. Attenuated carrier activity is suppressed by overproducing the superoxide dismutase, Sod1p, and this enhances both the proliferation rate and the replicative longevity of RAS2(Val19) cells. In contrast, overproducing functional Aac2p restored proliferation but not longevity of RAS2(Val19) cells. Thus, Ras signaling affects proliferation rate and replicative lifespan by two different, ROS-dependent, routes. While the reduction in generation time is linked to the inactivation, specifically, of the mitochondrial nucleotide carrier, longevity is affected by other, and hitherto unknown, target(s) of ROS attack.

N-acetylcysteine prevents HIV gp 120-related damage of human cultured astrocytes: correlation with glutamine synthase dysfunction

Background

HIV envelope gp 120 glycoprotein is released during active HIV infection of brain macrophages thereby generating inflammation and oxidative stress which contribute to the development of the AIDS-Dementia Complex (ADC). Gp120 has also been found capable to generate excitotoxic effect on brain tissue via enhancement of glutamatergic neurotransmission, leading to neuronal and astroglial damage, though the mechanism is still to be better understood.

Here we investigated on the effect of N-acetylcysteine (NAC), on gp120-induced damage in human cultured astroglial cells and the possible contribution of gp120-related reacting oxygen species (ROS) in the imbalanced activity of glutamine synthase (GS), the enzyme that metabolizes glutamate into glutamine within astroglial cells playing a neuroprotective role in brain disorders.

Results

Incubation of Lipari human cultured astroglial cells with gp 120 (0.1–10 nM) produced a significant reduction of astroglial cell viability and apoptosis as evaluated by TUNEL reaction and flow cytometric analysis (FACS). This effect was accompanied by lipid peroxidation as detected by means of malondialdehyde assay (MDA). In addition, gp 120 reduced both glutamine concentration in astroglial cell supernatants and GS expression as detected by immunocytochemistry and western blotting analysis. Pre-treatment of cells with NAC (0.5–5 mM), dose-dependently antagonised astroglial apoptotic cell death induced by gp 120, an effect accompanied by significant attenuation of MDA accumulation. Furthermore, both effects were closely associated with a significant recovery of glutamine levels in cell supernatants and by GS expression, thus suggesting that overproduction of free radicals might contribute in gp 120-related dysfunction of GS in astroglial cells.

Conclusion

In conclusion, the present experiments demonstrate that gp 120 is toxic to astroglial cells, an effect accompanied by lipid peroxidation and by altered glutamine release. All the effects of gp120 on astroglial cells were counteracted by NAC thus suggesting a novel and potentially useful approach in the treatment of glutammatergic disorders found in HAD patients.

Identification of enzymes and regulatory proteins in Escherichia coli that are oxidized under nitrogen, carbon, or phosphate starvation

Using proteomic technologies, we identified 62 proteins that are oxidized to carbonyl derivatives during growth of Escherichia coli under nitrogen starvation (NS), carbon starvation (CS), and phosphate starvation (PS) conditions. The carbonylated proteins were converted to 2,4-dinitrophenylhydrazone derivatives and these were identified using Western blotting and mass spectrometry by searching E. coli proteins in the Swiss-Prot and/or NCBI databases. Fourteen of the oxidized proteins were formed under both NS and CS conditions, and only three proteins were specifically oxidized under PS conditions. Interestingly, the carbonyl content of proteins in crude extracts of cells harvested after 48 h of stationary growth under NS and CS was significantly lower than that observed at mid-log and end-log phases of growth. In contrast, the carbonyl content of proteins in extracts of cells grown under PS conditions was fairly constant during comparable periods of growth.

Protein oxidation by the cytochrome P450 mixed-function oxidation system

This mini-review summarizes results of studies on the oxidation of proteins and low-density lipoprotein (LDL) by various mixed-function oxidation (MFO) systems. Oxidation of LDL by the O2/FeCl3/H2O2/ascorbate MFO system is dependent on all four components and is much greater when reactions are carried out in the presence of a physiological bicarbonate/CO2 buffer system as compared to phosphate buffer. However, FeCl3 in this system could be replaced by hemin or the heme-containing protein, hemoglobin, or cytochrome c. Oxidation of LDL by the O2/cytochrome P450 cytochrome c reductase/NADPH/FeCl3 MFO system is only slightly higher (25%) in the bicarbonate/CO2 buffer as compared to phosphate buffer, but is dependent on all components except FeCl3. Omission of FeCl3 led to a 60% loss of activity. These results suggest that peroxymonobicarbonate and/or free radical derivatives of bicarbonate ion and/or CO2 might contribute to LDL oxidation by these MFO systems.

Role of oxidative carbonylation in protein quality control and senescence

Proteins can become modified by a large number of reactions involving reactive oxygen species. Among these reactions, carbonylation has attracted a great deal of attention due to its irreversible and unrepairable nature. Carbonylated proteins are marked for proteolysis by the proteasome and the Lon protease but can escape degradation and form high-molecular-weight aggregates that accumulate with age. Such carbonylated aggregates can become cytotoxic and have been associated with a large number of age-related disorders, including Parkinson's disease, Alzheimer's disease, and cancer. This review focuses on the generation of and defence against protein carbonyls and speculates on the potential role of carbonylation in protein quality control, cellular deterioration, and senescence.

The effect of inflammatory stimuli on NMDA-related activation of glutamine synthase in human cultured astroglial cells

Removal of glutamate from the synaptic cleft by astroglial glutamine synthase (GS) is a crucial step in the regulation of glutamate turnover and metabolism, thus participating in endogenous neuroprotective processes occurring within brain tissues. Here we investigated on the effect of inflammatory cytokines on GS activity in astroglial cells undergoing NMDA receptors stimulation. Incubation of human cultured astroglial cells with NMDA (100 microM) enhanced GS expression, an effect driven by the generation of nitric oxide (NO) since l-NAME (500 microM), an inhibitor of NO synthase, reversed this effect. NMDA-related increase of GS activity and glutamine concentration was antagonised by previous incubation of astroglial cells with a mixture of LPS plus gammaIFN, an effect counteracted by dexamethasone, the latter effect being accompanied by inhibition of inducible NO synthase. These results show that LPS plus gammaIFN inhibit elevation of GS activity subsequent to NMDA receptor stimulation in astroglial cells via enhancement of inducible NO synthase, and this may represent the site of interaction between pro-inflammatory and excitotoxic stimuli in the brain.

Potential roles of protein oxidation and the immunoproteasome in MHC class I antigen presentation: the 'PrOxI' hypothesis

The major histocompatibility complex (MHC) class I (MHC-I) antigen presentation system is responsible for the cell-surface presentation of self-proteins and intracellular viral proteins. This pathway is important in screening between self, and non-self or infected cells. In this pathway, proteins are partially degraded to peptides in the cytosol and targeted to the cell surface bound to an MHC-I receptor protein. At the cell surface, T cells bypass cells displaying self-peptides but destroy others displaying foreign antigens. Cells contain several isoforms of the proteasome, but it is thought that the immunoproteasome is the major form involved in generating peptides for the MHC-I pathway. How all intracellular proteins are targeted for MHC-I processing is unclear. Oxidative stress is experienced by all cells, and all proteins are exposed to oxidation. We propose that oxidative modification makes proteins susceptible to degradation by the immunoproteasome. This could be called the protein oxidation and immunoproteasome or 'PrOxI' hypothesis of MHC-I antigen processing. Protein oxidation may, thus, be a universal mechanism for peptide generation and presentation in the MHC-I pathway.

Recent developments in the intracellular degradation of oxidized proteins

The accumulation of oxidized proteins in cells and tissues is a feature of a number of age-related diseases and may also occur as a result of the aging process itself. In this article we review recent advances in our understanding of the cellular degradation of oxidized proteins directing our attention primarily to information which directly bears on the behavior of intact eukaryotic cells. We summarize new work on the key intracellular degradative machineries, proteasomes and lysosomes and examine evidence implicating an increase in protein hydrophobicity as the primary signal to the proteasome to initiate degradation. The data identifying the proteasome as the main route of degradation of oxidized proteins is examined, as well as recent data investigating changes in proteasome function after exposure of cells to oxidants and the altered catabolism of oxidized proteins in aging cells. Evidence for the cooperation between the lysosomal and proteasomal systems in the degradation of oxidized proteins is discussed. We conclude that the cellular catabolism of oxidized proteins may be a more complex process than it first appeared and suggest key issues that need to be resolved to improve our understanding of this important process.

Importance of individuality in oxidative stress and aging

Tight linkage between aging and oxidative stress is indicated by the observations that reactive oxygen species generated under various conditions of oxidative stress are able to oxidize nucleic acids, proteins, and lipids and that aging is associated with the accumulation of oxidized forms of cellular constituents, and also by the fact that there is an inverse relationship between the maximum life span of organisms and the age-related accumulation of oxidative damage. Nevertheless, validity of the oxidative stress hypothesis of aging is questioned by (i) the failure to establish a causal relationship between aging and oxidative damage and (ii) lack of a consistent correlation between the accumulation of oxidative damage and aging. The present discussion is focused on the complexity of the aging process and suggests that discrepancies between various studies in this area are likely due to the fact that aging is not a single process and that the lack of consistent experimental results is partly explained by individual variations. Even so, there is overwhelming support for a dominant role of oxidative stress in the aging of some individuals.

Protein turnover by the proteasome in aging and disease

A significant body of evidence supports a key role for free radicals in causing cumulative damage to cellular macromolecules, thereby contributing to senescence/aging, and a number of age-related disorders. Proteins are recognized as major targets for oxidative damage (in addition to DNA and lipids) and the accumulation of oxidized proteins has been reported for many experimental aging models, as measured by several markers for protein oxidation. In young and healthy individuals, moderately oxidized soluble cell proteins are selectively and rapidly degraded by the proteasome. However, severely oxidized, cross-linked proteins are poor substrates for degradation and actually inhibit the proteasome. Considerable evidence now indicates that proteasome activity declines during aging, as the protease is progressively inhibited by binding to ever increasing levels of oxidized and cross-linked protein aggregates. Cellular aging probably involves both an increase in the generation of reactive oxygen species and a progressive decline in proteasome activity, resulting in the progressive accumulation of oxidatively damaged protein aggregates that eventually contribute to cellular dysfunction and senescence.

Carbonyl modified proteins in cellular regulation, aging, and disease

The oxidative modification of proteins by reactive species is implicated in the etiology or progression of a panoply of disorders and diseases. The level of these modified molecules can be quantitated by measurement of the protein carbonyl content, which has been shown to increase in a variety of diseases and processes, notably during aging. For the most part, oxidatively modified proteins are not repaired and must be removed by proteolytic degradation, a process which normally proceeds very efficiently, from microorganisms to mammals. In eukaryotes, removal is usually carried out by the proteosome, which selectively degrades oxidatively modified proteins, whether they be damaged by reactive oxygen species or specifically oxidized by cellular regulatory processes. The molecular deficiencies that cause accumulation of oxidatively modified proteins are not identified, but regardless of cause, the accumulation is likely to disrupt normal cellular function.

Vitamin C prevents cigarette smoke induced oxidative damage of proteins and increased proteolysis

Aqueous extract of cigarette smoke (CS) contains some stable oxidants, which oxidize human plasma proteins, bovine serum albumin, amino acid homopolymers, and also cause extensive oxidative degradation of microsomal proteins. Similar observations are made when the aqueous extract of cigarette smoke is replaced by whole phase CS solution or whole phase cigarette smoke. CS-induced microsomal protein degradation is a two step process: (i) oxidation of proteins by the oxidants present in the CS and (ii) rapid proteolytic degradation of the oxidized proteins by proteases present in the microsomes. Using aqueous extract of CS equivalent to that produced from one-twentieth of a cigarette, the observed initial and postcigarette smoke treated values of different parameters of oxidative damage per milligram of microsomal proteins are respectively: 0.24 and 1.74 nmoles for carbonyl formation, 125.4 and 62.8 fluorescence units for tryptophan loss, 10.2 and 33.4 fluorescence units for bityrosine formation, and 58.3 and 12.2 nmoles for loss of protein thiols. When compared with sodium dodecyl sulphate polyacrylamide gel electrophoresis profiles of untreated microsomal proteins, the extent of microsomal protein degradation after treatment with whole phase CS solution or aqueous extract of CS is above 90%. Ascorbate (100 microM) almost completely prevents cigarette smoke-induced protein oxidation and thereby protects the microsomes from subsequent proteolytic degradation. Glutathione is partially effective, but other antioxidants including superoxide dismutase, catalase, vitamin E, probucol, beta-carotene, mannitol, thiourea, and histidine are ineffective. The gas phase cigarette smoke contains unstable reactive oxygen species such as superoxide (O2*-) and hydrogen peroxide (H2O2) that can cause substantial oxidation of pure protein like albumin but is unable to produce significant oxidative damage of microsomal proteins. Gas phase cigarette smoke-induced albumin oxidation is not only inhibited by ascorbate and glutathione but also by superoxide dismutase, catalase and mannitol. The stable oxidants in the cigarette smoke are not present in the tobacco and are apparently produced by the interaction of O2*-/H2O2/OH* of the gas phase with some components of the tar phase during/following the burning of tobacco.

Singlet oxygen is part of a hyperoxidant state generated during spore germination

We show that singlet oxygen is generated in asexual spores (conidia) from Neurospora crassa at the onset of germination. Oxidation of N. crassa catalase-1 (Cat-1) was previously shown to be caused by singlet oxygen (Lledías et al. J. Biol. Chem. 273, 1998). In germinating conidia, increased protein oxidation, decrease of total protein, Cat-1 oxidation and accumulation of cat-1 mRNA was detected. These changes were modulated in vivo by light intensity, an external clean source of singlet oxygen, and by carotene amount and content of coordinated double bonds. Conditions that stimulated singlet oxygen formation increased Cat-1 oxidation and accumulation of cat-1 mRNA. Germinating conidia from mutant strains altered in carotene synthesis showed increased levels of protein degradation, Cat-1 oxidation and accumulation of cat-1 mRNA. During germination Cat-1a was oxidized, oxidized Cat-1c-Cat-1e conformers disappeared and Cat-1a was synthesized de novo. Furthermore, spontaneous oxygen-dependent chemiluminescence increased as soon as conidia absorbed dissolved oxygen. Low-level chemiluminescence is due to photon emission from excited electrons in carbonyls and singlet oxygen as they return to their ground state. H2O2 added to conidia under Ar caused a peak of chemiluminescence and germination of 20% of conidia, suggesting that a hyperoxidant state suffices to start germination under anaerobic conditions. Taken together, these results show that singlet oxygen is part of a hyperoxidant state that develops at the start of germination of conidia, in consonance with our proposal that morphogenetic transitions occur as a response to a hyperoxidant state.

Oxidative turnover of soybean root glutamine synthetase. In vitro and in vivo studies

Glutamine synthetase (GS) is the key enzyme in ammonia assimilation and catalyzes the ATP-dependent condensation of NH3 with glutamate to produce glutamine. GS in plants is an octameric enzyme. Recent work from our laboratory suggests that GS activity in plants may be regulated at the level of protein turnover (S.J. Temple, T.J. Knight, P.J. Unkefer, C. Sengupta-Gopalan [1993] Mol Gen Genet 236: 315-325; S.J. Temple, S. Kunjibettu, D. Roche, C. Sengupta-Gopalan [1996] Plant Physiol 112: 1723-1733; S.J. Temple, C. Sengupta-Gopalan [1997] In C.H. Foyer, W.P. Quick, eds, A Molecular Approach to Primary Metabolism in Higher Plants. Taylor & Francis, London, pp 155-177). Oxidative modification of GS has been implicated as the first step in the turnover of GS in bacteria. By incubating soybean (Glycine max) root extract enriched in GS in a metal-catalyzed oxidation system to produce the.OH radical, we have shown that GS is oxidized and that oxidized GS is inactive and more susceptible to degradation than nonoxidized GS. Histidine and cysteine protect GS from metal-catalyzed inactivation, indicating that oxidation modifies the GS active site and that cysteine and histidine residues are the site of modification. Similarly, ATP and particularly ATP/glutamate give the enzyme the greatest protection against oxidative inactivation. The roots of plants fed ammonium nitrate showed a 3-fold increase in the level of GS polypeptides and activity compared with plants not fed ammonium nitrate but without a corresponding increase in the GS transcript level. This would suggest either translational or posttranslational control of GS levels.

Methionine residues may protect proteins from critical oxidative damage

Cysteine and methionine are the two sulfur-containing residues normally found in proteins. Cysteine residues function in the catalytic cycle of many enzymes, and they form disulfide bonds which contribute to protein structure. In contrast, the key functions of methionine residues are not known. We propose that methionine residues constitute an important antioxidant defense mechanism. A variety of oxidants react readily with methionine to form methionine sulfoxide, and surface exposed methionine residues create an extremely high concentration of reactant, providing for efficient scavenging of oxidants. The effect of hydrogen peroxide exposure upon glutamine synthetase from Escherichia coli was studied as an in vitro model system. Eight of the sixteen methionine residues could be oxidized with little effect on activity. The oxidizable methionine residues were found to be relatively surface exposed while the intact residues were generally buried within the core of the protein. Further, the susceptible residues were physically arranged in an array which guarded the entrance to the active site. Methionine sulfoxide can be reduced back to methionine by the enzyme methionine sulfoxide reductase, providing a catalytic amplification of the antioxidant potential of each methionine residue. Given the importance of oxidative stress during aging, the potential function of methionine residues as antioxidants during aging should be investigated experimentally.

Metal-catalyzed oxidation of phenylalanine-sensitive 3-deoxy-D-arabino-heptulosonate-7-phosphate synthase from Escherichia coli: inactivation and destabilization by oxidation of active-site cysteines

The in vitro instability of the phenylalanine-sensitive 3-deoxy-D-arabino-heptulosonate-7-phosphate synthase [DAHPS(Phe)] from Escherichia coli has been found to be due to a metal-catalyzed oxidation mechanism. DAHPS(Phe) is one of three differentially feedback-regulated isoforms of the enzyme which catalyzes the first step of aromatic biosynthesis, the formation of DAHP from phosphoenolpyruvate and D-erythrose-4-phosphate. The activity of the apoenzyme decayed exponentially, with a half-life of about 1 day at room temperature, and the heterotetramer slowly dissociated to the monomeric state. The enzyme was stabilized by the presence of phosphoenolpyruvate or EDTA, indicating that in the absence of substrate, a trace metal(s) was the inactivating agent. Cu2+ and Fe2+, but none of the other divalent metals that activate the enzyme, greatly accelerated the rate of inactivation and subunit dissociation. Both anaerobiosis and the addition of catalase significantly reduced Cu2+-catalyzed inactivation. In the spontaneously inactivated enzyme, there was a net loss of two of the seven thiols per subunit; this value increased with increasing concentrations of added Cu2+. Dithiothreitol completely restored the enzymatic activity and the two lost thiols in the spontaneously inactivated enzyme but was only partially effective in reactivation of the Cu2+-inactivated enzyme. Mutant enzymes with conservative replacements at either of the two active-site cysteines, Cys61 or Cys328, were insensitive to the metal attack. Peptide mapping of the Cu2+-inactivated enzyme revealed a disulfide linkage between these two cysteine residues. All results indicate that DAHPS(Phe) is a metal-catalyzed oxidation system wherein bound substrate protects active-site residues from oxidative attack catalyzed by bound redox metal cofactor. A mechanism of inactivation of DAHPS is proposed that features a metal redox cycle that requires the sequential oxidation of its two active-site cysteines.

Plant responses to metal toxicity

Metal toxicity for living organisms involves oxidative and/or genotoxic mechanisms. Plant protection against metal toxicity occurs, at least in part, through control of root metal uptake and of long distance metal transport. Inside cells, proteins such as ferritins and metallothioneins, and glutathion-derived peptides named phytochelatins, participate in excess metal storage and detoxification. Low molecular weight organic molecules, mainly organic acids and amino acids and their derivatives, also play an important role in plant metal homeostasis. When these systems are overloaded, oxidative stress defense mechanisms are activated. Molecular and cellular knowledge of these processes will be necessary to improve plant metal resistance. Occurrence of naturally tolerant plants which hyperaccumulate metals provides helpful tools for this research.

Oxidation of catalase by singlet oxygen

Different bands of catalase activity in zymograms (Cat-1a-Cat-1e) appear during Neurospora crassa development and under stress conditions. Here we demonstrate that singlet oxygen modifies Cat-1a, giving rise to a sequential shift in electrophoretic mobility, similar to the one observed in vivo. Purified Cat-1a was modified with singlet oxygen generated from a photosensitization reaction; even when the reaction was separated from the enzyme by an air barrier, a condition in which only singlet oxygen can reach the enzyme by diffusion. Modification of Cat-1a was hindered when reducing agents or singlet oxygen scavengers were present in the photosensitization reaction. The sequential modification of the four monomers gave rise to five active catalase conformers with more acidic isoelectric points. The pI of purified Cat-1a-Cat-1e decreased progressively, and a similar shift in pI was observed as Cat-1a was modified by singlet oxygen. No further change was detected once Cat-1e was reached. Catalase modification was traced to a three-step reaction of the heme. The heme of Cat-1a gave rise to three additional heme peaks in a high performance liquid chromatography when modified to Cat-1c. Full oxidation to Cat-1e shifted all peaks into a single one. Absorbance spectra were consistent with an increase in asymmetry as heme was modified. Bacterial, fungal, plant, and animal catalases were all susceptible to modification by singlet oxygen, indicating that this is a general feature of the enzyme that could explain in part the variety of catalases seen in several organisms and the modifications observed in some catalases. Modification of catalases during development and under stress could indicate in vivo generation of singlet oxygen.

Evolution of an Escherichia coli protein with increased resistance to oxidative stress

L-1,2-Propanediol:NAD+ 1-oxidoreductase of Escherichia coli is encoded by the fucO gene, a member of the regulon specifying dissimilation of L-fucose. The enzyme normally functions during fermentative growth to regenerate NAD from NADH by reducing the metabolic intermediate L-lactaldehyde to propanediol which is excreted. During aerobic growth L-lactaldehyde is converted to L-lactate and thence to the central metabolite pyruvate. The wasteful excretion of propanediol is minimized by oxidative inactivation of the oxidoreductase, an Fe2+-dependent enzyme which is subject to metal-catalyzed oxidation (MCO). Mutants acquiring the ability to grow aerobically on propanediol as sole carbon and energy source can be readily selected. These mutants express the fucO gene constitutively, as a result of an IS5 insertion in the promoter region. In this study we show that continued selection for aerobic growth on propanediol resulted in mutations in the oxidoreductase conferring increased resistance to MCO. In two independent mutants, the resistance of the protein was respectively conferred by an Ile7 --> Leu and a Leu8 --> Val substitution near the NAD-binding consensus amino acid sequence. A site-directed mutant protein with both substitutions showed an MCO resistance greater than either mutant protein with a single amino acid change.

Age- and radiation-dependent changes in carbonyl content, susceptibility to proteolysis, and antigenicity of soluble rat liver proteins

Soluble liver proteins (SLP) from old and gamma-irradiated young rats were studied with respect to their carbonyl content, the rates of autolysis and degradation by proteinase K, and their antigenicity for mice and compared with SLP from non-irradiated young animals. A significant increase in the carbonyl level was found in SLP from old and gamma-irradiated young rats as compared to SLP from intact young rats. The rates of SLP autolysis and proteolysis by proteinase K were increased in the same animal groups but did not correlate the carbonyl level. At the same time, whereas the antigenicity for mice of SLP from old rats was significantly higher than that of SLP from young rats, the antigenicity of SLP from gamma-irradiated rats did not differ from non-irradiated animals. Enrichment of the diet with antioxidant and vitamin supplements (AVS) during one month before the irradiation caused a decrease in the radiation-induced carbonyl level in rat SLP. However, this raised antioxidant level in animal diet did not influence the rates of SLP autolysis and degradation by proteinase K and also did not alter the antigenicity of these proteins. The data allow us to suggest that the increase in autolysis, degradation by the exogenous proteinase, and antigenicity of SLP from old rats are determined not only by carbonyl formation in these proteins due to action of oxygen radicals but also by other age-specific protein modifications.

Methionine residues as endogenous antioxidants in proteins

Cysteine and methionine are the two sulfur-containing residues normally found in proteins. Cysteine residues function in the catalytic cycle of many enzymes, and they can form disulfide bonds that contribute to protein structure. In contrast, the specific functions of methionine residues are not known. We propose that methionine residues constitute an important antioxidant defense mechanism. A variety of oxidants react readily with methionine to form methionine sulfoxide, and surface exposed methionine residues create an extremely high concentration of reactant, available as an efficient oxidant scavenger. Reduction back to methionine by methionine sulfoxide reductases would allow the antioxidant system to function catalytically. The effect of hydrogen peroxide exposure upon glutamine synthetase from Escherichia coli was studied as an in vitro model system. Eight of the 16 methionine residues could be oxidized with little effect on catalytic activity of the enzyme. The oxidizable methionine residues were found to be relatively surface exposed, whereas the intact residues were generally buried within the core of the protein. Furthermore, the susceptible residues were physically arranged in an array that guarded the entrance to the active site.

Investigating the effects of posttranslational adenylylation on the metal binding sites of Escherichia coli glutamine synthetase using lanthanide luminescence spectroscopy

Lanthanide luminescence was used to examine the effects of posttranslational adenylylation on the metal binding sites of Escherichia coli glutamine synthetase (GS). These studies revealed the presence of two lanthanide ion binding sites of GS of either adenylylation extrema. Individual emission decay lifetimes were obtained in both H2O and D2O solvent systems, allowing for the determination of the number of water molecules coordinated to each bound Eu3+. The results indicate that there are 4.3 +/- 0.5 and 4.6 +/- 0.5 water molecules coordinated to Eu3+ bound to the n1 site of unadenylylated enzyme, GS0, and fully adenylylated enzyme, GS12, respectively, and that there are 2.6 +/- 0.5 water molecules coordinated to Eu3+ at site n2 for both GS0 and GS12. Energy transfer measurements between the lanthanide donor-acceptor pair Eu3+ and Nd3+, obtained an intermetal distance measurement of 12.1 +/- 1.5 A. Distances between a Tb3+ ion at site n2 and tryptophan residues were also performed with the use of single-tryptophan mutant forms of E. coli GS. The dissociation constant for lanthanide ion binding to site n1 was observed to decrease from Kd = 0.35 +/- 0.09 microM for GS0 to Kd = 0.06 +/- 0.02 microM for GS12. The dissociation constant for lanthanide ion binding to site n2 remained unchanged as a function of adenylylation state; Kd = 3.8 +/- 0.9 microM and Kd = 2.6 +/- 0.7 microM for GS0 and GS12, respectively. Competition experiments indicate that Mn2+ affinity at site n1 decreases as a function of increasing adenylylation state, from Kd = 0.05 +/- 0.02 microM for GS0 to Kd = 0.35 +/- 0.09 microM for GS12. Mn2+ affinity at site n2 remains unchanged (Kd = 5.3 +/- 1.3 microM for GS0 and Kd = 4.0 +/- 1.0 microM for GS12). The observed divalent metal ion affinities, which are affected by the adenylylation state, agrees with other steady-state substrate experiments (Abell LM, Villafranca JJ, 1991, Biochemistry 30:1413-1418), supporting the hypothesis that adenylylation regulates GS by altering substrate and metal ion affinities.

Proteases and their targets in Escherichia coli

Proteolysis in Escherichia coli serves to rid the cell of abnormal and misfolded proteins and to limit the time and amounts of availability of critical regulatory proteins. Most intracellular proteolysis is initiated by energy-dependent proteases, including Lon, ClpXP, and HflB; HflB is the only essential E. coli protease. The ATPase domains of these proteases mediate substrate recognition. Recognition elements in target are not well defined, but are probably not specific amino acid sequences. Naturally unstable protein substrates include the regulatory sigma factors for heat shock and stationary phase gene expression, sigma 32 and RpoS. Other cellular proteins serve as environmental sensors that modulate the availability of the unstable proteins to the proteases, resulting in rapid changes in sigma factor levels and therefore in gene transcription. Many of the specific proteases found in E. coli are well-conserved in both prokaryotes and eukaryotes, and serve critical functions in developmental systems.

High-level expression of Pinus sylvestris glutamine synthetase in Escherichia coli. Production of polyclonal antibodies against the recombinant protein and expression studies in pine seedlings

In a previous work we reported the molecular characterization of a glutamine synthetase (GS; EC 6.3.1.2.) complementary DNA from a woody plant (Cantón et al. (1993) Plant Mol. Biol. 22, 819-828). The isolated cDNA (pGSP114) encoding a Scots pine (Pinus sylvestris) cytosolic subunit, has been subcloned into the expression vector pET3c to overproduce the GS polypeptide in Escherichia coli cells. The recombinant GS protein showed the same molecular size as a native Scots pine GS subunit. Antibodies against the pET3c-GSP114 encoded protein were raised in rabbits by injecting purified preparations and specificity was determined by immunoprecipitation of GS activity present in pine crude extracts. In spite of the antibodies were able to recognize both cytosolic and chloroplastic GS in tomato plants, they were unable to immunodetect chloroplastic GS in green cotyledons of pine seedlings and cytosolic GS was the unique recognized polypeptide. Unlike to that found in other plant species, cytosolic GS was strongly expressed in green tissues as determined by protein and Northern analysis. Our results suggest a key role for cytosolic GS in photosynthetic tissues of conifers.

The fates of proteins in cells

Nascent polypeptide chains are in a dangerous situation as soon as they leave their place of birth, the channel of the large ribosomal subunit: more than 20 different pathways for the degradation of proteins exist in cells. Chaperones protect and guide the young protein molecules and support their correct foldings. Targeting signals direct the proteins to the organelles of their destination. The lysosome is the site of random degradation, while the proteasome is highly selective. Although these two organelles provide the most important pathways for the degradation of long- and short-lived proteins, other pathways with roles in deciding the fate of cellular proteins must also be considered.

C-terminal specific protein degradation: activity and substrate specificity of the Tsp protease

The activity of Tsp, a periplasmic endoprotease of Escherichia coli, has been characterized by assaying the cleavage of protein and peptide substrates, determining the cleavage sites in several substrates, and investigating the kinetics of the cleavage reaction. Tsp efficiently cleaves substrates that have apolar residues and a free alpha-carboxylate at the C-terminus. Tsp cleaves its substrates at a discrete number of sites but with rather broad primary sequence specificity. In addition to preferences for residues at the C-terminus and cleavage sites, Tsp displays a preference for substrates that are not stably folded: unstable variants of Arc repressor are better substrates than a hyperstable mutant, and a peptide with little stable structure is cleaved more efficiently than a protein substrate. These data are consistent with a model in which Tsp cleavage of a protein substrate involves binding to the C-terminal tail of the substrate, transient denaturation of the substrate, and then recognition and hydrolysis of specific peptide bonds.

Repair, refold, recycle: how bacteria can deal with spontaneous and environmental damage to proteins

Proteins, like DNA, are subject to various forms of damage that can render them non-functional. Conformational changes and covalent chemical alterations occur spontaneously, and the rates of these reactions can be increased by environmental stresses such as heat, oxidative agents, or changes in pH or osmotic conditions. Although affected proteins can be replaced by de novo biosynthesis, cells--especially those subjected to stress or nutrient limitation--have developed mechanisms which can either restore damaged polypeptides to an active state or remove them. Such mechanisms can spare the biosynthetic capacity of the cell and ensure that the presence of non-functional molecules does not disrupt cell physiology. Three major mechanisms, which operate in bacteria as well as eukaryotic organisms, have been described. First, chaperones not only assist in proper de novo folding of proteins but also provide an important means of restoring activity to conformationally damaged proteins. Second, enzymatic 'repair' systems exist to directly reverse certain forms of protein damage, including proline isomerization, methionine oxidation and the formation of isoaspartyl residues. Finally, proteolysis provides a 'last-resort' means of dealing with abnormal proteins which cannot be repaired. Protein maintenance and repair may be of special importance for bacteria preparing to survive extended periods in stationary phase: both constitutive and induced mechanisms are utilized to permit survival despite greatly reduced protein synthesis.

Ascorbic acid prevents lipid peroxidation and oxidative damage of proteins in guinea pig extrahepatic tissue microsomes

It has recently been indicated that in the absence of free iron, NADPH initiates oxidative damage of proteins in guinea pig liver microsomes and also lipid peroxidation and protein damage in cardiac microsomes and that ascorbic acid specifically inhibits both the lipid peroxidation and protein damage [Mukhopadhyay CK, Chatterjee IB: J Biol Chem 269: 13390-13397, 1994; Mukhopadhyay M et al.: Mol Cell Biochem 126: 69-75, 1993]. In this paper we demonstrate that Fe(III)-independent NADPH-initiated lipid peroxidation and oxidative damage of proteins occur in the microsomes of all the extrahepatic tissues including lung, kidney, adrenal gland and brain and that both the lipid peroxidation and protein damage are specifically prevented by ascorbic acid. We further demonstrate that when NADPH is replaced by O2 as the electron donor, the O2-initiated lipid peroxidation and protein damage are also inhibited by ascorbic acid.

Regeneration of catalytic activity of glutamine synthetase mutants by chemical activation: exploration of the role of arginines 339 and 359 in activity

In order to understand the nature of ATP and L-glutamate binding to glutamine synthetase, and the involvement of Arg 339 and Arg 359 in catalysis, these amino acids were changed to cysteine via site-directed mutagenesis. Individual mutations (Arg-->Cys) at positions 339 and 359 led to a sharp drop in catalytic activity. Additionally, the Km values for the substrates ATP and glutamate were elevated substantially above the values for wild-type (WT) enzyme. Each cysteine was in turn chemically modified to an arginine "analog" to attempt to "rescue" catalytic activity by covalent modification; 2-chloroacetamidine (CA) (producing a thioether) and 2,2'-dithiobis (acetamidine)(DTBA) (producing a disulfide) were the reagents used to effect these chemical transformations. Upon reaction with CA, both R339C and R359C mutants showed a significant regain of catalytic activity (50% and 70% of WT, respectively) and a drop in Km value for ATP close to that for WT enzyme. With DTBA, chemically modified R339C had a greater kcat than WT glutamine synthetase, but chemically modified R359C only regained a small amount of activity. Modification with DTBA was quantitative for each mutant and each modified enzyme had similar Km values for both ATP and glutamate. The high catalytic activity of DTBA-modified R339C could be reversed to that of unmodified R339C by treatment with dithiothreitol, as expected for a modified enzyme containing a disulfide bond. Modification of each cysteine-containing mutant to a lysine "analog" was accomplished using 3-bromopropylamine (BPA).(ABSTRACT TRUNCATED AT 250 WORDS)

Kinetic and mutagenic studies of the role of the active site residues Asp-50 and Glu-327 of Escherichia coli glutamine synthetase

The role of Asp-50 and Glu-327 of Escherichia coli glutamine synthetase in catalysis and substrate binding has been interrogated by construction of site-directed mutants at these positions. Steady-state and rapid-quench kinetic methods were used to elucidate contributions of Asp-50 and Glu-327 to the Km values of all three substrates, ATP, glutamate, and NH4+, as well as to the enzymatic kcat value. Kinetic constants were obtained for the D50A enzyme using both Mg2+ and Mn2+ as activating metal ions; the data reveal that Asp-50 has a significant role in both substrate binding and catalysis as reflected by the increases in the Km values for NH4+ and the destabilization of both the ground state and the transition state for phosphoryl transfer. The D50E mutant was found to have activity with Mn2+ but very low activity with Mg2+, the physiologically important metal ion. The kcat/Km values for all three substrates were substantially altered by changing Asp to Glu. The steady-state results for the E327A mutant indicate a decreased kcat/Km value for NH4+ compared to that of the wild-type enzyme. The E327A-Mg2+ enzyme destabilizes the ground state of the ternary complex (E-ATP-Glu-NH4+) and the transition state for phosphoryl transfer while the E327A-Mn2(+)-enzyme provides greater stabilization for the ATP and glutamate complexes but destabilizes phosphoryl transfer steps in the ternary complex. Overall, these results suggest that Asp-50 is likely involved in binding NH4+ and may also play a role in catalyzing deprotonation of NH4+ to form NH3.(ABSTRACT TRUNCATED AT 250 WORDS)

The oxidative inactivation of cytochrome P450 in monooxygenase reactions

Possible mechanisms of cytochrome P450 self-inactivation during catalytic turnover have been considered. Two ways of hemoprotein inactivation are so far known. The first, studied extensively by many authors, is the formation of active substrate intermediates, capable of modifying heme and apoenzyme. The second way, revealed quite recently and resulting from uncoupled cytochrome P450-catalyzed monooxygenase reactions, is yet to be clarified. Briefly, it involves formation of hydrogen peroxide in the hemoprotein active center, which interacts with the enzyme associated Fe2+, thereby generating hydroxyl radicals that bleach the heme and modify the apoenzyme. This mechanism operates with substrates and cytochrome P450 forms with partially coupled monooxygenase reactions, thus causing the formation of hydrogen peroxide as a byproduct.

Protein modification in aging

During aging a number of enzymes accumulate as catalytically inactive or less active forms. The age-related changes in catalytic activity are due in part to reactions of the protein with "active" oxygen species such as ozone, singlet oxygen, or with oxygen free radicals as are produced during exposure to ionizing radiation or to metal ion catalyzed oxidation (MCO) systems. The levels of oxidized proteins in cultured human fibroblasts from individuals of various ages and in liver and brain extracts of rats of different ages increase progressively with age, and in old rats can represent 30-50% of the total cellular protein. The age-related increase in oxidized protein in rat liver and brain tissue is accompanied by a loss of glutamine synthetase (GS) and glucose-6-P dehydrogenase (G-6-PDH) activities, and to a decrease in the level of cytosolic neutral protease activity which is responsible for the degradation of oxidized (denatured) protein. Of particular significance are the results of experiments showing that similar age-related changes occur in the gerbil brain and that these changes are accompanied by a loss of short-term memory as measured by the radial arm maze technique. Chronic treatment (intraperitoneal injections) of old animals with the free radical spin-trap reagent, N-tert-butyl-alpha-phenylnitrone (PBN) resulted in normalization of the several biochemical parameters to those characteristic of the young animals; coincidentally, the short-term memory index was restored to the young animal values. These results provide the first evidence that there is likely a linkage between the age-dependent accumulation of oxidized enzymes and the loss of physiological function.

Role of Clp protease subunits in degradation of carbon starvation proteins in Escherichia coli

When deprived of a carbon source, Escherichia coli induces the synthesis of a group of carbon starvation proteins. The degradation of proteins labeled during starvation was found to be an energy-dependent process which was inhibited by the addition of KCN and accelerated when cells were resupplied with a carbon source. The degradation of the starvation proteins did not require the ATP-dependent Lon protease or the energy-independent proteases protease I, protease IV, OmpT, and DegP. During starvation, mutants lacking either the ClpA or ClpP subunit of the ATP-dependent Clp protease showed a partial reduction in the degradation of starvation proteins. Strains lacking ClpP failed to increase degradation of starvation proteins when glucose was added to starving cells. The clpP mutants showed a competitive disadvantage compared with wild-type cells when exposed to repeated cycles of carbon starvation and growth. Surprisingly, the glucose-stimulated, ClpP-dependent degradation of starvation proteins did not require either the ClpA or ClpB protein. The patterns of synthesis of starvation proteins were similar in clpP+ and clpP cells. The clpP mutants had reduced rates of degradation of certain starvation proteins in the membrane fraction when a carbon source was resupplied to the starved cells.

Role of calcium in inactivation of calcium/calmodulin dependent protein kinase II after cerebral ischemia

Transient cerebral ischemia demonstrates an increase in activated oxygen species in the brain that could lead to eventual neuronal cell death. Neuronal cells respond to oxygen free radicals through the restructuring of the cytoskeleton and membranes, mobilization of calcium and gene expression which play a role in cell injury. Ten min of bilateral carotid artery occlusion resulted in a decrease in calcium/calmodulin dependent protein kinase II (CaM kinase II) phosphorylation and activity detected in the brain immediately following ischemia and was partially restored within 24 h of reperfusion. Pretreatment of animals with an anesthetic dose of pentobarbital (40 mg/kg) resulted in partial protection of inactivation of CaM kinase II following ischemia. CaM kinase II activity was maintained following pretreatment of animals with alpha-phenyl N-tert-butyl nitrone (PBN), which traps oxygen free radicals. Infusion of superoxide dismutase or catalase prior to ischemia, blocked CaM kinase II inactivation. Blockage of calcium uptake with bepridil resulted in a marked protection of CaM kinase II inactivation. In addition, trifluoperazine, a calmodulin antagonist also diminished the inhibition of CaM kinase II phosphorylation in our model. These results suggest that ischemia and reperfusion injury results in the generation of activated oxygen and the mobilization of calcium which inactivate CaM kinase II. These results indicate that changes associated with protein kinase activity in the brain following an ischemic insult may have profound effects upon neurodegeneration and neuronal survival.

Biochemical effects of ischemia on isolated, perfused rat heart tissues

Isolated working rat hearts perfused with Krebs-Hensleit buffer were arrested and made ischemic. After 22 min, the hearts were reperfused with buffer, yielding restoration of function. Nucleotide levels rose and fell in the cardiac tissue as ischemia was imposed; the changes were consistent with the energy needs of the tissue. ATP concentrations in the tissues fell by 75% during ischemia, AMP levels were low initially and subsequently rose 5-fold, and ADP levels were essentially unchanged. Upon reperfusion ATP levels rebounded, although not to initial values, and AMP returned to initial values. During ischemia, there was a 10-fold or greater rise in inosine, hypoxanthine, and xanthine levels which fell to normally low levels upon reperfusion. Lactate dehydrogenase (LDH) activity rose during ischemia and returned to baseline upon reperfusion. Changes in LDH isozyme distribution suggest that, during ischemia, there is an increased proportion of liver-associated forms which returns to normally low levels upon reperfusion. Glutamate oxalacetate transaminase activity rose slightly at 5 min of ischemia, but, by 22 min of ischemia, it had fallen to 60% of initial values. Upon reperfusion, activity rose and, by 15 min, had reached 127% of initial values. On the other hand, there is no significant change in levels of extractable creatine kinase or isocitrate dehydrogenase activities as a result of the various conditions imposed on the hearts. As an index of protein oxidation, carbonyl levels in extractable protein rose during ischemia and were over four times the initial values at 5 min of reperfusion but, with continued reperfusion, declined to approximately 150% of initial values at 15 min.

Proteases and protein degradation in Escherichia coli

In E. coli, protein degradation plays important roles in regulating the levels of specific proteins and in eliminating damaged or abnormal proteins. E. coli possess a very large number of proteolytic enzymes distributed in the cytoplasm, the inner membrane, and the periplasm, but, with few exceptions, the physiological functions of these proteases are not known. More than 90% of the protein degradation occurring in the cytoplasm is energy-dependent, but the activities of most E. coli proteases in vitro are not energy-dependent. Two ATP-dependent proteases, Lon and Clp, are responsible for 70-80% of the energy-dependent degradation of proteins in vivo. In vitro studies with Lon and Clp indicate that both proteases directly interact with substrates for degradation. ATP functions as an allosteric effector promoting an active conformation of the proteases, and ATP hydrolysis is required for rapid catalytic turnover of peptide bond cleavage in proteins. Lon and Clp show virtually no homology at the amino acid level, and thus it appears that at least two families of ATP-dependent proteases have evolved independently.

Investigation of the mechanism of phosphinothricin inactivation of Escherichia coli glutamine synthetase using rapid quench kinetic technique

A number of slow tight-binding inhibitors are known for glutamine synthetase that resemble the geometry of the tetrahedral intermediate formed during the enzyme-catalyzed condensation of gamma-glutamyl phosphate and ammonia. One of these inhibitors, phosphinothricin [L-2-amino-4-(hydroxymethyl-phosphinyl)butanoic acid], has been investigated by rapid kinetic methods. Phosphinothricin not only exhibits the kinetic properties of a slow tight-binding inhibitor but also undergoes phosphorylation during the course of the ATP-dependent inactivation. The acid lability of phosphinothricin phosphate enabled investigation of the kinetics of glutamine synthetase inactivation using rapid quench kinetic techniques. The rate-limiting step in the inhibition reaction is the binding of inhibitor (0.004-0.014 microM-1 s-1) and/or a conformational change associated with binding, which is several orders of magnitude slower than the binding of ATP. The association rate of phosphinothricin depends on which metal ion is bound to the enzyme (Mn2+ or Mg2+). With Mn2+ bound to glutamine synthetase the rate of association and the phosphorylation rate are faster than when Mg2+ is bound. The data are interpreted with use of a model in which the binding of a substrate analogue with a tetrahedral moiety enhances the phosphorylation rate of the reaction intermediate; however, the initial binding interaction is retarded because the enzyme has to bind a molecule that has a "transition-state" geometry rather than a ground-state substrate structure. During the course of the inactivation, progressively slower rates for binding and phosphoryl transfer were observed, indicating communication between active sites.

Construction and characterization of Escherichia coli strains deficient in multiple secreted proteases: protease III degrades high-molecular-weight substrates in vivo

Protease III, the product of the ptr gene, is a 110-kDa periplasmic protease with specificity towards insulin and other low-molecular-weight substrates (less than 7,000 molecular weight) in vitro (Y.-S.E. Cheng and D. Zipser, J. Biol. Chem. 254:4698-4706, 1979). Escherichia coli strains deficient in protease III were constructed by insertional inactivation of the ptr gene. This mutation did not appear to affect the function of the adjoining recB and recC genes. Expression of protein A-beta-lactamase, a protease-sensitive secreted polypeptide, was increased approximately twofold in ptr cells. A comparable increase in the half-life of protein A-beta-lactamase was observed by pulse-chase experiments, suggesting that protease III is involved in the catabolism of high-molecular-weight substrates in vivo, ptr mutants exhibited no detectable phenotypic alterations except for a slight reduction in growth rate. When the ptr mutation was transferred to a strain deficient in the secreted protease DegP, a further decrease in growth rate, as well as an additive increase in the expression of the fusion protein, was observed. A ptr degP ompT mutant strain resulted in a further increase in expression in minimal medium but not in rich medium.