Crystallization and preliminary crystallographic analysis of bifunctional gamma-glutamylcysteine synthetase-glutatione synthetase from Streptococcus agalactiae.

gamma-Glutamylcysteine synthetase-glutathione synthetase (gammaGCS-GS) is a bifunctional enzyme that catalyzes two consecutive steps of ATP-dependent peptide formation in glutathione biosynthesis. Streptococcus agalactiae gammaGCS-GS is a target for the development of potential therapeutic agents. gammaGCS-GS was crystallized using the sitting-drop vapour-diffusion method. The crystals grew to dimensions of 0.3 x 0.2 x 0.2 mm under reducing conditions with 5 mM TCEP. X-ray data were collected to 2.8 A resolution from a tetragonal crystal that belonged to space group I4(1).

Metabolic profiling of arginine and nitric oxide pathways predicts hemodynamic abnormalities and mortality in patients with cardiogenic shock after acute myocardial infarction.

BACKGROUND: It is unclear whether abnormalities of arginine and nitric oxide metabolism are related to hemodynamic dysfunction and mortality in patients with cardiogenic shock (CS) after acute myocardial infarction. METHODS AND RESULTS: Plasma metabolites reflecting arginine bioavailability, nitric oxide metabolism, and protein oxidation were analyzed by mass spectrometry in patients with CS (n=79) and age- and gender-matched patients with coronary artery disease and normal left ventricular function (n=79). CS patients had higher levels of asymmetric dimethylarginine (ADMA; P<0.0001), symmetric dimethylarginine (P<0.0001), monomethylarginine (P=0.0003), nitrotyrosine (P<0.0001), and bromotyrosine (P<0.0001) and lower levels of arginine (P<0.0001), ratio of arginine to ornithine (P=0.03), and ratio of arginine to ornithine plus citrulline) (P=0.0003). CS patients with elevated ADMA levels were 3.5-fold (95% confidence interval, 1.4 to 11.3; P=0.02) more likely to die in 30 days than patients with low ADMA levels. ADMA remained the only independent predictor of mortality on multiple logistic regression analysis. In patients with normal renal function, symmetric dimethylarginine levels inversely correlated with mean arterial pressure and systemic vascular resistance, whereas levels of ADMA correlated with pulmonary capillary wedge pressure and both systolic and diastolic pulmonary artery pressures. Despite dramatic elevations, levels of protein oxidation products did not predict hemodynamic dysfunction or mortality in CS patients. CONCLUSIONS: CS is characterized by an arginine-deficient and highly specific pro-oxidant state, with elevated levels of methylated arginine derivatives, including endogenous nitric oxide synthase inhibitors. Levels of methylated arginine derivatives strongly correlate with hemodynamic dysfunction. Among all clinical and laboratory parameters monitored, ADMA levels were the strongest independent predictor of 30-day mortality.

Gamma-glutamylcysteine synthetase-glutathione synthetase: domain structure and identification of residues important in substrate and glutathione binding.

In most organisms, glutathione (GSH) is synthesized by the sequential action of distinct enzymes, gamma-glutamylcysteine synthetase (gamma-GCS) and GSH synthetase (GS). In Streptococcus agalactiae, GSH synthesis is catalyzed by a single enzyme, gamma-glutamylcysteine synthetase-glutathione synthetase (gamma-GCS-GS). The N-terminal sequence of gamma-GCS-GS is similar to Escherichia coli gamma-GCS, but the C-terminal sequence is an ATP-grasp domain more similar to d-Ala, d-Ala ligase than to any known GS. In the present studies, C-terminally and N-terminally truncated constructs were characterized in order to define the limits of the gamma-GCS and GS domains, respectively. Although WT gamma-GCS-GS is nearly uninhibited by GSH (K(i) approximately 140 mM), shorter gamma-GCS domain constructs were unexpectedly found to be strongly inhibited (K(i) approximately 15 mM), reproducing a physiologically important regulation seen in monofunctional gamma-GCS enzymes. Because studies with E. coli gamma-GCS implicate a flexible loop region in GSH binding, chimeras of S. agalactiae gamma-GCS-GS were made containing gamma-GCS domain flexible loop sequences from Enterococcus faecalis and Pasteurella multocida gamma-GCS-GS, isoforms that are inhibited by GSH. Inhibition remained S. agalactiae-like (i.e., very weak). C-Terminal constructs of gamma-GCS-GS have GS activity (0.01-0.04% of WT), but proper folding and significant GS activity required a covalently linked gamma-GCS domain. In addition, site-directed mutants in the middle region of the gamma-GCS-GS sequence established that GS activity depends on residues in a region that is also part of the gamma-GCS domain. Our results provide new insights into the structure of gamma-GCS-GS and suggest gamma-GCS-GS evolved from a monomeric gamma-GCS that became C-terminally fused to a multimeric ATP-grasp protein.

Post-translational modification of manganese superoxide dismutase in acutely rejecting cardiac transplants: role of inducible nitric oxide synthase.

BACKGROUND: Nitration of a critical tyrosine residue in the active site of manganese superoxide dismutase (MnSOD) can lead to enzyme inactivation. In this study, we examined the effect of inducible nitric oxide synthase (iNOS) on MnSOD expression, activity and nitration in acutely rejecting cardiac transplants. METHODS: Lewis (isograft) or Wistar-Furth (allograft) donor hearts were transplanted into Lewis recipient rats. Some rats received L-N6-(1-iminoethyl) lysine (l-NIL), a specific iNOS inhibitor. Protein nitration was determined by immunohistochemical, Western blot and slot-blot analyses. MnSOD enzyme activity and gene expression were determined using Western, reverse transcriptase-polymerase chain reaction (RT-PCR) and immunoprecipitation techniques. RESULTS: MnSOD protein levels were decreased 50% by post-operative day 6 (POD 6), which was prevented by L-NIL. RT-PCR analysis indicated that this decrease could not be explained by any changes in MnSOD mRNA. MnSOD enzyme activity but not protein was decreased at POD 5 in untreated allografts. The loss of MnSOD activity at POD 5 was also prevented by L-NIL. Immunoreactive nitrotyrosine was apparent in untreated allografts at POD 6. Slot-blot analysis indicated that nitrotyrosine formation in allografts could be blocked by L-NIL. Nitration of MnSOD was evident upon immunoprecipitation of MnSOD followed by Western blotting for nitrotyrosine. CONCLUSIONS: These results suggest that the decreased MnSOD enzyme activity in acutely rejecting cardiac allografts can be attributed to a post-translational modification related to nitration arising via an iNOS-dependent pathway. This could be a potential major source of amplified oxidative stress in acute graft rejection.

Glutathione synthesis in Streptococcus agalactiae. One protein accounts for gamma-glutamylcysteine synthetase and glutathione synthetase activities.

Gamma-glutamylcysteine synthetase (gamma-GCS) and glutathione synthetase (GS), distinct enzymes that together account for glutathione (GSH) synthesis, have been isolated and characterized from several Gram-negative prokaryotes and from numerous eukaryotes including mammals, amphibians, plants, yeast, and protozoa. Glutathione synthesis is relatively uncommon among the Gram-positive bacteria, and, to date, neither the genes nor the proteins involved have been identified. In the present report, we show that crude extracts of Streptococcus agalactiae catalyze the gamma-GCS and GS reactions and can synthesize GSH from its constituent amino acids. The putative gene for S. agalactiae gamma-GCS was identified and cloned, and the corresponding protein was expressed and purified. Surprisingly, it was found that the isolated enzyme catalyzes both the ATP-dependent synthesis of L-gamma-glutamyl-L-cysteine from L-glutamate and L-cysteine and the ATP-dependent synthesis of GSH from L-gamma-glutamyl-L-cysteine and glycine. This novel bifunctional enzyme, referred to as gamma-GCS-GS, has been characterized in terms of catalytic activity, substrate specificity, and inhibition by GSH, cystamine, and transition state analog sulfoximines. The N-terminal 518 amino acids of gamma-GCS-GS (total M(r) 85,000) show 32% identity and 43% similarity with E. coli gamma-GCS (M(r) 58,000), but the C-terminal putative GS domain (remaining 202 amino acids) of gamma-GCS-GS shows no significant homology with known GS sequences. The C terminus (360 amino acids) is, however, homologous to D-Ala, D-Ala ligase (24% identity; 38% similarity), an enzyme having the same protein fold as known GS proteins. These results are discussed in terms of the evolution of GSH synthesis and the possible occurrence of a similar bifunctional GSH synthesis enzyme in other bacterial species.

Variable efficacy of N6-(1-iminoethyl)-L-lysine in acute cardiac transplant rejection.

We examined the efficacy and mechanism of action of N(6)-(1-iminoethyl)-L-lysine (L-NIL), a highly selective inhibitor of inducible nitric oxide (NO) synthase (iNOS), on acute cardiac transplant rejection. L-NIL produced a concentration-dependent attenuation of plasma NO by-products and a decrease in nitrosylation of heme protein without altering protein levels of iNOS. At postoperative day 4, L-NIL did not alter the increased binding activities for transcription factors nuclear factor-kappaB and activator protein-1. Whereas L-NIL decreased inflammatory cell infiltration, graft survival was only prolonged at the dose of 1.0 microg/ml that incompletely blocked NO production. Higher L-NIL concentrations (30 and 60 microg/ml) ablated the increased NO production but failed to improve graft survival and even potentiated NF-kappaB binding activity examined at day 6. Alloimmune activation indicated by increased cytokine gene expression for interferon-gamma, interleukin-6, and interleukin-10 was inhibited in grafts only by treatment with 1.0 microg/ml L-NIL. These findings suggest a complex role of NO in acute cardiac allograft rejection. Partial inhibition of iNOS is beneficial to graft survival, whereas total ablation may oppose any benefits to graft survival. These studies have important implications in understanding the dual role of NO in acute rejection and help to reconcile discrepancies in the literature.

Structural characterization and kinetics of nitric-oxide synthase inhibition by novel N5-(iminoalkyl)- and N5-(iminoalkenyl)-ornithines.

Isoform-specific nitric-oxide synthase (NOS) inhibitors may prove clinically useful in reducing the pathophysiological effects associated with increased neuronal NOS (nNOS) or inducible NOS (iNOS) activity in a variety of neurological and inflammatory disorders. Analogs of the NOS substrate L-arginine are pharmacologically attractive inhibitors because of their stability, reliable cell uptake, and good selectivity for NOS over other heme proteins. Some inhibitory arginine analogs show significant isoform selectivity although the structural or mechanistic basis of such selectivity is generally poorly understood. In the present studies, we determined by x-ray crystallography the binding interactions between rat nNOS and N5-(1-imino-3-butenyl)-L-ornithine (L-VNIO), a previously identified mechanism-based, irreversible inactivator with moderate nNOS selectivity. We have also synthesized and mechanistically characterized several L-VNIO analogs and find, surprisingly, that even relatively minor structural changes produce inhibitors that are either iNOS-selective or non-selective. Furthermore, derivatives having a methyl group added to the butenyl moiety of L-VNIO and L-VNIO derivatives that are analogs of homoarginine rather than arginine display slow-on, slow-off kinetics rather than irreversible inactivation. These results elucidate some of the structural requirements for isoform-selective inhibition by L-VNIO and its related alkyl- and alkenyl-imino ornithine and lysine derivatives and may provide information useful in the ongoing rational design of isoform-selective inhibitors.

Non-heme iron protein: a potential target of nitric oxide in acute cardiac allograft rejection.

We examined iron nitrosylation of non-heme protein and enzymatic activity of the Fe-S cluster protein, aconitase, in acute cardiac allograft rejection. Heterotopic transplantation of donor hearts was performed in histocompatibility matched (isografts: Lewis --> Lewis) and mismatched (allografts: Wistar-Furth --> Lewis) rats. On postoperative days (POD) 4-6, Western blot analysis and immunohistochemistry revealed inducible nitric-oxide synthase (iNOS) protein in allografts but not isografts. EPR spectroscopy revealed background signals at g = 2.003 (for semiquinone) and g = 2.02 and g = 1.94 (for Fe-S cluster protein) in isografts and normal hearts. In contrast, in allografts on POD4, a new axial signal at g = 2.04 and g = 2.02 appeared that was attributed to the dinitrosyl-iron complex formed by nitrosylation of non-heme protein. Appearance of this signal occurred at or before significant nitrosylation of heme protein. Iron nitrosylation of non-heme protein was coincidental with decreases in the nonnitrosylated Fe-S cluster signal at g = 1.94. Aconitase enzyme activity was decreased to approximately 50% of that observed in isograft controls by POD4. Treatment with cyclosporine blocked the (i) elevation of plasma nitrate + nitrite, (ii) up-regulation of iNOS protein, (iii) decrease in Fe-S cluster EPR signal, (iv) formation of dinitrosyl-iron complexes, and (v) loss of aconitase enzyme activity. Formation of dinitrosyl-iron complexes and loss of aconitase activity within allografts also was inhibited by treatment of recipients with a selective iNOS inhibitor, l-N(6)-(1-iminoethyl)lysine. This report shows targeting of an important non-heme Fe-S cluster protein in acute solid organ transplant rejection.

Escherichia coli gamma-glutamylcysteine synthetase. Two active site metal ions affect substrate and inhibitor binding.

Gamma-glutamylcysteine synthetase (gamma-GCS, glutamate-cysteine ligase), which catalyzes the first and rate-limiting step in glutathione biosynthesis, is present in many prokaryotes and in virtually all eukaryotes. Although all eukaryotic gamma-GCS isoforms examined to date are rapidly inhibited by buthionine sulfoximine (BSO), most reports indicate that bacterial gamma-GCS is resistant to BSO. We have confirmed the latter finding with Escherichia coli gamma-GCS under standard assay conditions, showing both decreased initial binding affinity for BSO and a reduced rate of BSO-mediated inactivation compared with mammalian isoforms. We also find that substitution of Mn2+ for Mg2+ in assay mixtures increases both the initial binding affinity of BSO and the rate at which BSO causes mechanism-based inactivation. Similarly, the specificity of E. coli gamma-GCS for its amino acid substrates is broadened in the presence of Mn2+, and the rate of reaction for some very poor substrates is improved. These results suggest that divalent metal ions have a role in amino acid binding to E. coli gamma-GCS. Electron paramagnetic resonance (EPR) studies carried out with Mn2+ show that E. coli gamma-GCS binds two divalent metal ions; Kd values for Mn2+ are 1.1 microm and 82 microm, respectively. Binding of l-glutamate or l-BSO to the two Mn2+/gamma-GCS species produces additional upfield and downfield X-band EPR hyperfine lines at 45 G intervals, a result indicating that the two Mn2+ are spin-coupled and thus apparently separated by 5 A or less in the active site. Additional EPR studies in which Cu2+ replaced Mg2+ or Mn2+ suggest that Cu2+ is bound by one N and three O ligands in the gamma-GCS active site. The results are discussed in the context of the catalytic mechanism of gamma-GCS and its relationship to the more fully characterized glutamine synthetase reaction.