Flavohemoglobin denitrosylase catalyzes the reaction of a nitroxyl equivalent with molecular oxygen.

We have previously reported that bacterial flavohemoglobin (HMP) catalyzes both a rapid reaction of heme-bound O(2) with nitric oxide (NO) to form nitrate [HMP-Fe(II)O(2) + NO --> HMP-Fe(III) + NO(3)(-)] and, under anaerobic conditions, a slower reduction of heme-bound NO to an NO(-) equivalent (followed by the formation of N(2)O), thereby protecting against nitrosative stress under both aerobic and anaerobic conditions, and rationalizing our finding that NO is rapidly consumed across a wide range of O(2) concentrations. It has been alternatively suggested that HMP activity is inhibited at low pO(2) because the enzyme is then in the relatively inactive nitrosyl form [k(off)/k(on) for NO (0.000008 microM) k(off)/k(on) for O(2) (0.012 microM) and K(M) for O(2) = 30-100 microM]. To resolve this discrepancy, we have directly measured heme-ligand turnover and NADH consumption under various O(2)/NO concentrations. We find that, at biologically relevant O(2) concentrations, HMP preferentially binds NO (not O(2)), which it then reacts with oxygen to form nitrate (in essence NO(-) + O(2) --> NO(3)(-)). During steady-state turnover, the enzyme can be found in the ferric (FeIII) state. The formation of a heme-bound nitroxyl equivalent and its subsequent oxidation is a novel enzymatic function, and one that dominates the oxygenase activity under biologically relevant conditions. These data unify the mechanism of HMP/NO interaction with those recently described for the nematode Ascaris and mammalian hemoglobins, and more generally suggest that the peroxidase (FeIII)-like properties of globins have evolved for handling of NO.

Calcium regulates S-nitrosylation, denitrosylation, and activity of tissue transglutaminase.

Nitric oxide (NO) and related molecules play important roles in vascular biology. NO modifies proteins through nitrosylation of free cysteine residues, and such modifications are important in mediating NO's biologic activity. Tissue transglutaminase (tTG) is a sulfhydryl rich protein that is expressed by endothelial cells and secreted into the extracellular matrix (ECM) where it is bound to fibronectin. Tissue TG exhibits a Ca(2+)-dependent transglutaminase activity (TGase) that cross-links proteins involved in wound healing, tissue remodeling, and ECM stabilization. Since tTG is in proximity to sites of NO production, has 18 free cysteine residues, and utilizes a cysteine for catalysis, we investigated the factors that regulated NO binding and tTG activity. We report that TGase activity is regulated by NO through a unique Ca(2+)-dependent mechanism. Tissue TG can be poly-S-nitrosylated by the NO carrier, S-nitrosocysteine (CysNO). In the absence of Ca(2+), up to eight cysteines were nitrosylated without modifying TGase activity. In the presence of Ca(2+), up to 15 cysteines were found to be nitrosylated and this modification resulted in an inhibition of TGase activity. The addition of Ca(2+) to nitrosylated tTG was able to trigger the release of NO groups (i.e. denitrosylation). tTG nitrosylated in the absence of Ca(2+) was 6-fold more susceptible to inhibition by Mg-GTP. When endothelial cells in culture were incubated with tTG and stimulated to produce NO, the exogenous tTG was S-nitrosylated. Furthermore, S-nitrosylated tTG inhibited platelet aggregation induced by ADP. In conclusion, we provide evidence that Ca(2+) regulates the S-nitrosylation and denitrosylation of tTG and thereby TGase activity. These data suggest a novel allosteric role for Ca(2+) in regulating the inhibition of tTG by NO and a novel function for tTG in dispensing NO bioactivity.

A metabolic enzyme for S-nitrosothiol conserved from bacteria to humans.

Considerable evidence indicates that NO biology involves a family of NO-related molecules and that S-nitrosothiols (SNOs) are central to signal transduction and host defence. It is unknown, however, how cells switch off the signals or protect themselves from the SNOs produced for defence purposes. Here we have purified a single activity from Escherichia coli, Saccharomyces cerevisiae and mouse macrophages that metabolizes S-nitrosoglutathione (GSNO), and show that it is the glutathione-dependent formaldehyde dehydrogenase. Although the enzyme is highly specific for GSNO, it controls intracellular levels of both GSNO and S-nitrosylated proteins. Such 'GSNO reductase' activity is widely distributed in mammals. Deleting the reductase gene in yeast and mice abolishes the GSNO-consuming activity, and increases the cellular quantity of both GSNO and protein SNO. Furthermore, mutant yeast cells show increased susceptibility to a nitrosative challenge, whereas their resistance to oxidative stress is unimpaired. We conclude that GSNO reductase is evolutionarily conserved from bacteria to humans, is critical for SNO homeostasis, and protects against nitrosative stress.

Protection from nitrosative stress by yeast flavohemoglobin.

Yeast hemoglobin was discovered close to half a century ago, but its function has remained unknown. Herein, we report that this flavohemoglobin protects Saccharomyces cerevisiae from nitrosative stress. Deletion of the flavohemoglobin gene (YHB1) abolished the nitric oxide (NO)-consuming activity of yeast cells. Levels of protein nitrosylation were more than 10-fold higher in yhb1 mutant yeast than in isogenic wild-type cells after incubation with NO donors. Growth of mutant cells was inhibited by a nitrosative challenge that had little effect on wild-type cells, whereas the resistance of mutant cells to oxidative stress was unimpaired. Protection conferred by yeast flavohemoglobin against NO and S-nitrosothiols was seen under both anaerobic and aerobic conditions, consistent with a primary function in NO detoxification. A phylogenetic analysis indicated that protection from nitrosative stress is likely to be a conserved function among microorganismal flavohemoglobins. Flavohemoglobin is therefore a potential target for antimicrobial therapy.

Fas-induced caspase denitrosylation.

Only a few intracellular S-nitrosylated proteins have been identified, and it is unknown if protein S-nitrosylation/denitrosylation is a component of signal transduction cascades. Caspase-3 zymogens were found to be S-nitrosylated on their catalytic-site cysteine in unstimulated human cell lines and denitrosylated upon activation of the Fas apoptotic pathway. Decreased caspase-3 S-nitrosylation was associated with an increase in intracellular caspase activity. Fas therefore activates caspase-3 not only by inducing the cleavage of the caspase zymogen to its active subunits, but also by stimulating the denitrosylation of its active-site thiol. Protein S-nitrosylation/denitrosylation can thus serve as a regulatory process in signal transduction pathways.

Nitroreductase A is regulated as a member of the soxRS regulon of Escherichia coli.

Nitroreductase A catalyzes the divalent reduction of nitro compounds, quinones, and dyes by NADPH. In this paper, nitroreductase A is induced in Escherichia coli by exposure to paraquat in a manner that depends on the expression of soxR. Nitroreductase activity was only slightly induced by paraquat in a strain bearing a mutational defect in the gene encoding nitroreductase A, but it was approximately 3-fold induced in the parental strain. Nitroreductase A thus appears to be a member of the soxRS regulon and probably contributes to the defenses against oxidative stress by minimizing the redox cycling attendant upon the univalent reduction of nitro compounds, quinones, and dyes.

Nitrosative stress: metabolic pathway involving the flavohemoglobin.

Nitric oxide (NO) biology has focused on the tightly regulated enzymatic mechanism that transforms L-arginine into a family of molecules, which serve both signaling and defense functions. However, very little is known of the pathways that metabolize these molecules or turn off the signals. The paradigm is well exemplified in bacteria where S-nitrosothiols (SNO)-compounds identified with antimicrobial activities of NO synthase-elicit responses that mediate bacterial resistance by unknown mechanisms. Here we show that Escherichia coli possess both constitutive and inducible elements for SNO metabolism. Constitutive enzyme(s) cleave SNO to NO whereas bacterial hemoglobin, a widely distributed flavohemoglobin of poorly understood function, is central to the inducible response. Remarkably, the protein has evolved a novel heme-detoxification mechanism for NO. Specifically, the heme serves a dioxygenase function that produces mainly nitrate. These studies thus provide new insights into SNO and NO metabolism and identify enzymes with reactions that were thought to occur only by chemical means. Our results also emphasize that the reactions of SNO and NO with hemoglobins are evolutionary conserved, but have been adapted for cell-specific function.

Oxidative modifications in nitrosative stress.

The molecular basis of redox sensitivity in proteins is not well understood. Here we consider a continuum of NO- and O2-related modifications of cysteine residues that constitute biological signaling events on the one hand and hallmarks of nitrosative and oxidative stresses on the other.

Nitrosative stress: activation of the transcription factor OxyR.

Hydrogen peroxide (H2O2) imposes an oxidative stress to Escherichia coli that is manifested by oxidation of glutathione and related redox-sensitive targets. OxyR is a thiol-containing transcriptional activator whose oxidation controls the expression of genes involved in H2O2 detoxification. Here we report that certain S-nitrosothiols (RSNOs) impose what we term a "nitrosative stress" to E. coli, evidenced by lowering of intracellular thiol and the transcriptional activation of OxyR by S-nitrosylation. This cellular and genetic response determines the metabolic fate of RSNOs and thereby contributes to bacterial rescue from stasis. Our studies reveal that signaling by S-nitrosylation can extend to the level of transcription and describe a metabolic pathway that constitutes an adaptation to nitrosative stress.

Superoxide and peroxynitrite inactivate aconitases, but nitric oxide does not.

The Escherichia coli and recombinant human cytosolic aconitases are inactivated by O2-., with a rate constant of approximately 3 x 10(7) M-1 s-1; the corresponding value for the porcine mitochondrial aconitase is approximately 0.8 x 10(7) M-1 s-1. Nitric oxide, which is reported to inactivate aconitase, did not do so at a perceptible rate, while incubation with peroxynitrite led to a rapid loss of aconitase activity. We propose that the reported inactivation of aconitase by nitric oxide in vivo is actually mediated through peroxynitrite, the product of the reaction between O2-. and NO..

Purification and characterization of glutathione reductase isozymes specific for the state of cold hardiness of red spruce.

Isozymes of glutathione reductase (GR) have been purified from red spruce (Picea rubens Sarg.) needles. Two isozymes could be separated by anion-exchange chromatography from both nonhardened or cold-hardened tissue. Based on chromatographic elution profiles, the isozymes were designated GR-1NH and GR-2NH in preparations from nonhardened needles, and GR-1H and GR-2H in preparations from hardened needles. N-terminal sequencing and immunological data with antisera obtained against GR-1H and GR-2H established that the isozymes from hardened needles are different gene products and show significant structural differences from each other. Chromatographic, electrophoretic, and immunological data revealed only minor differences between GR-2NH and GR-2H, and it is concluded that these isozymes are very similar or identical. Anion-exchange chromatography and native polyacrylamide gel electrophoresis also established that GR-1NH and GR-1H are different proteins. From these data we conclude that GR-1H is a distinct gene product, present only in hardened needles. Therefore, GR-1H can be considered to be a cold-hardiness-specific GR isozyme, and GR-1NH can be considered to be specific for nonhardened needles. It is proposed that GR-1H is a cold-acclimation protein.

Cold-hardiness-specific glutathione reductase isozymes in red spruce. Thermal dependence of kinetic parameters and possible regulatory mechanisms.

The thermal dependence of kinetic parameters has been determined in purified or partially purified preparations of cold-hardiness-specific glutathione reductase isozymes from red spruce (Picea rubens Sarg.) needles to investigate a possible functional adaptation of these isozymes to environmental temperature. We have previously purified glutathione reductase isozymes specific for nonhardened (GR-1NH) or hardened (GR-1H) needles. Isozymes that were distinct from GR-1NH and GR-1H, but appeared to be very similar to each other, were also purified from nonhardened (GR-2NH) or hardened (GR-2H) needles (A. Hausladen, R.G. Alscher [1994] Plant Physiol 105: 205-213). GR-1NH had 2-fold higher Km values for NADPH and 2- to 4-fold lower Km values for oxidized glutathione (GSSG) than GR-2NH, and a similar difference was found between GR-1H and GR-2H. However, no differences in Km values were found between the hardiness-specific isozymes GR-1NH and GR-1H. There was only a small effect of temperature on the Km(GSSG) of GR-1H and GR-2H, and no significant temperature effect on Km(NADPH) or Km(GSSG) could be found for the other isozymes. These results are discussed with respect to "thermal kinetic windows," and it is proposed that the relative independence of Km values to temperature ensures adequate enzyme function in a species that is exposed to extreme temperature differences in its natural habitat. A variety of substrates has been tested to characterize any further differences among the isozymes, but all isozymes are highly specific for their substrates, NADPH and GSSG. The reversible reductive inactivation by NADPH (redox interconversion) is more pronounced in GR-1H than in GR-2H. Reduced, partially inactive GR-1H is further deactivated by H2O2, whereas GR-2H is fully reactivated by the same treatment. Both isozymes are reactivated by GSSG or reduced glutathione. It is proposed that this property of GR-2H ensures enzyme function under oxidative conditions, and that in vivo the enzyme may exist in its partially inactive form and be activated in the presence of increased levels of GSSG or oxidants.

NADPH: ferredoxin oxidoreductase acts as a paraquat diaphorase and is a member of the soxRS regulon.

Soluble extracts of Escherichia coli contain four NADPH:paraquat diaphorases that were separable by anion-exchange HPLC over Mono Q. One of these was induced when the cells were exposed to paraquat. This was the case in a soxRS-competent strain but not in a soxRS-null strain, while a soxRS-constitutive strain overexpressed this diaphorase without the stimulus of exposure to paraquat. This NADPH:paraquat diaphorase could use cytochrome c or nitroblue tetrazolium as an electron acceptor, whereas O2 was a relatively poor acceptor. This diaphorase was identified as the NADPH:ferredoxin reductase. A role for reduced ferredoxin and flavodoxin in the adaptive soxRS response to oxidative stress and in the regulation of the redox status of soxR is discussed.

Excess substrate inhibition of xanthine oxidase: a reexamination.

Xanthine oxidase has long been considered to be subject to inhibition by excess substrate. It is now shown that, although such inhibition can be seen in Tris or N,N-bis(2-hydroxyethyl)glycine buffers, earlier reports in which phosphate, pyrophosphate, or Veronal buffers were used were probably the result of a spectrophotometric artifact imposed by stray light in the incident beam.

Competitive inhibition of xanthine oxidase by guanidinium: dependence upon monovalent anions and effects on production of superoxide.

Guanidinium chloride inhibits xanthine oxidase competitively with respect to xanthine. Although previously attributed solely to the guanidinium cation, it is now apparent that this inhibition owes much to the counter anion. Thus KCl or KBr, which were not themselves inhibitory, markedly increased the inhibitory potency of guanidinium sulfate. Weak binding of the guanidinium cation evidently creates a binding site for a monovalent anion, whose subsequent binding then stabilizes the binding of the guanidinium. In effect the ion pair is bound to the catalytic center. The proportion of univalent reduction of dioxygen by xanthine oxidase, at fixed concentrations of xanthine and dioxygen and at fixed pH, can be markedly increased by addition of a competitive inhibitor such as guanidinium bromide.

Seasonal changes in antioxidants in red spruce (Picea rubens Sarg.) from three field sites in the northeastern United States.

Changes in antioxidant levels were investigated in red spruce (Picea rubens Sarg.) from three field sites in the northeastern United States. Whiteface Mountain, NY at an elevation of 1090 m, represents a red spruce population in decline, while Millinocket and Howland, Maine are at 518 and 105 m above sea level, respectively, and have red spruce stands that show no symptoms of decline. The Millinocket site with saplings that are 15-20 yr old was compared with the Howland site with 60-yr-old trees to test the effect of age on antioxidant levels. The Howland site was compared with the Whiteface Mountain site, which has trees more than 100 yr old, to test the effects of air quality and elevation. Foliage developed in 1987 (87 needles) and in 1988 (88 needles) was sampled from May to November and from July to November, 1988, respectively. Quadratic polynomial and linear regressions were used to model the relationships through time of each variable measured. Regression coefficients were obtained by one-way analysis of variance. The means for total glutathione and oxidized glutathione were higher at Whiteface Mountain in 87 needles, and needles of both age classes sampled in November had significantly higher oxidized glutathione at Whiteface Mountain compared to those at Howland. No significant difference was observed in the mean ascorbate content of either needle class at all the three sites. The activity of superoxide dismutase declined with time in 87 needles at Whiteface Mountain and the mean activity was lower at Whiteface Mountain than at Howland. The effects of ozone concentration, site elevation and other environmental factors on seasonal changes in antioxidant levels and superoxide dismutase activity are discussed.