Biochemical Characterization of Human S-Nitrosohemoglobin
EFFECTS ON OXYGEN BINDING AND TRANSNITROSATION*

Rakesh P. PatelDagger §, Neil Hogg, Netanya Y. Spencer, B. Kalyanaraman, Sadis Matalon§parallel , and Victor M. Darley-UsmarDagger §**

From the Dagger  Department of Pathology, Molecular and Cellular Division, the § Center for Free Radical Biology, and the parallel  Department of Anesthesiology, Physiology, and Biophysics, University of Alabama at Birmingham, Birmingham, Alabama 35294-0019 and the  Biophysics Research Institute, Medical College of Wisconsin, Milwaukee, Wisconsin 53226

    ABSTRACT
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

S-Nitrosation of cysteine beta 93 in hemoglobin (S-nitrosohemoglobin (SNO-Hb)) occurs in vivo, and transnitrosation reactions of deoxygenated SNO-Hb are proposed as a mechanism leading to release of NO and control of blood flow. However, little is known of the oxygen binding properties of SNO-Hb or the effects of oxygen on transnitrosation between SNO-Hb and the dominant low molecular weight thiol in the red blood cell, GSH. These data are important as they would provide a biochemical framework to assess the physiological function of SNO-Hb. Our results demonstrate that SNO-Hb has a higher affinity for oxygen than native Hb. This implies that NO transfer from SNO-Hb in vivo would be limited to regions of extremely low oxygen tension if this were to occur from deoxygenated SNO-Hb. Furthermore, the kinetics of the transnitrosation reactions between GSH and SNO-Hb are relatively slow, making transfer of NO+ from SNO-Hb to GSH less likely as a mechanism to elicit vessel relaxation under conditions of low oxygen tension and over the circulatory lifetime of a given red blood cell. These data suggest that the reported oxygen-dependent promotion of S-nitrosation from SNO-Hb involves biochemical mechanisms that are not intrinsic to the Hb molecule.

    INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

The main function of Hb is transporting oxygen from the lungs to respiring tissues. Oxygen is released when Hb undergoes a conformational change from the "R" state (i.e. "relaxed" or high oxygen affinity form) to the "T" state (i.e. "tense" or low oxygen affinity form). Numerous allosteric mechanisms are present that regulate oxygen delivery by either increasing or decreasing the oxygen affinity of Hb. These include regulation by pH, carbon dioxide, and inorganic phosphates (1, 2). For example, by binding to the T state, which results in stabilization of this conformer, phosphates such as adenosine triphosphate or 2,3-bisphosphoglycerate decrease the oxygen affinity of whole blood relative to purified Hb. These physiological regulatory mechanisms work in concert to ensure that oxygen delivery satisfies metabolic demand.

Efficient oxygen delivery is also a function of the amount of blood flowing through the arteries and arterioles, which, in turn, is regulated by the action of agents that cause either vasorelaxation or vasoconstriction. Nitric oxide is critical in vascular homeostasis and an important physiological modulator of blood flow due to its ability to cause vessel relaxation (3). Nitric oxide is synthesized in endothelial cells via the oxidation of L-arginine, a reaction catalyzed by the type III nitric-oxide synthase and stimulated by physiological processes such as blood flow over the endothelium (4). Once formed, NO diffuses to the underlying smooth muscle cells, where it binds rapidly to the heme group of the enzyme soluble guanylate cyclase. This activates the enzyme and sets up a sequence of events eventually resulting in relaxation of the vessel (5-9). A controversial aspect of this hypothesis is that NO rapidly reacts with oxy-Hb1 (k approx  107-108 M-1 s-1) (10), and given the high intra-erythrocytic Hb concentration (5-10 mM heme), it is difficult to understand how any NO would be available to initiate the signaling pathway that results in relaxation of vascular smooth muscle (11).

Recent investigations suggest that, in part, the reaction of NO with the heme group of Hb is restricted by partitioning into the hydrophobic compartments of cell membranes, thus making diffusion of the free radical into the red blood cell the limiting process (12). In addition, several investigators have suggested that, in vivo, NO is transported in the thiol-bound, oxidized, and more stable form of an S-nitrosothiol. These compounds are insensitive to a direct reaction with heme groups and have been detected in vivo as both proteins (e.g. S-nitrosoalbumin) and small thiol-containing amino acids or peptides (e.g. S-nitrosoglutathione) (13-20).

Through the formation of S-nitrosothiols, Stamler and co-workers (13, 14) have recently proposed an intriguing hypothesis by which Hb can regulate blood flow and overcome problems associated with scavenging of NO by heme. A novel derivative of the heme protein, S-nitrosohemoglobin (SNO-Hb), was identified as a potential modulator of blood flow in vivo (13), and further investigations have suggested a role for this protein in regulating fetal blood pressure as well (21). S-Nitrosohemoglobin is a derivative in which NO is covalently bonded to the cysteine residue at position 93 on the beta -chain (Cys-beta 93) (22). The nitrosyl group bonded to this thiol may be reduced to NO, under certain conditions, to induce relaxation of pre-capillary vessels and to inhibit platelet aggregation (13, 14, 23). It was suggested that when Hb is in the R conformational state, the S-nitroso (SNO) group is oriented toward the interior of the protein and stabilized by shielding from the aqueous phase. However, when Hb undergoes transition to the T conformational state, as has been shown to occur in pre-capillary networks, it was proposed that the SNO moiety becomes exposed to the solvent, thereby allowing transnitrosation to glutathione or other thiols present in the red blood cell. The subsequent formation of S-nitrosoglutathione (GSNO) may then promote vessel relaxation (13, 14). In this way, SNO-Hb can increase blood flow and hence oxygen delivery at sites where it becomes deoxygenated. S-Nitrosohemoglobin offers a novel solution by which NO can modulate blood flow without the problems associated with Hb-dependent scavenging of NO.

This hypothesis requires that NO be released following a decrease in the oxygen concentration and thus in the degree of Hb oxygenation in the pre-arterioles. Although it was demonstrated that ligand-induced allosteric changes in Hb affect S-nitrosation of Cys-beta 93, the published studies have not addressed the effect on the oxygen affinity of Hb. The level of S-nitrosation in vivo (<0.1% of oxy-Hb being S-nitrosated) is insignificant compared with the total oxy-Hb present in the erythrocyte (13). Therefore, the effects of S-nitrosation on oxygen delivery to tissues are negligible. However, since the hypothesis requires that only the deoxygenated conformer of Hb release NO (13, 14), then the oxygen affinity of SNO-Hb (despite its low concentration) is critical to the role of Hb as an NO carrier. This is an important issue because previous studies on the role of Cys-beta 93 have shown that blockage of the thiol via alkylation or the formation of mixed disulfides increases the oxygen affinity of Hb (24, 25). Furthermore, the naturally occurring Hb variant Hb Okazaki, where Cys-beta 93 is substituted with an arginine residue, also has an increased oxygen affinity (26). Since the formation of SNO-Hb represents a physiologically relevant Hb derivative in which Cys-beta 93 is modified, we have examined the effect of S-nitrosation of Hb on its oxygen binding properties.

In addition, it is not clear how the oxygen-sensitive mechanisms underlying conformation-dependent NO release function. It has been proposed that transnitrosation reactions between deoxy-SNO-Hb and GSH to form GSNO, the mediator necessary to elicit the vasorelaxant signal, occur. However, transnitrosation reactions are, in general, relatively slow, with the exact kinetics depending on the physiochemical properties of the specific thiols involved. We have therefore also examined the kinetics and equilibria of transnitrosation reactions between Hb and GSNO and fitted the results to a bimolecular reversible reaction.

These data show that S-nitrosation increases the oxygen affinity of Hb, ensuring that if a Hb deoxygenation-sensitive mechanism of NO release exists, then SNO-Hb would only promote vasorelaxation at sites of very low oxygen concentrations, i.e. at sites where the Hb existed primarily in the deoxygenated state. Furthermore, the kinetics of the transnitrosation reaction between SNO-Hb and GSNO are too slow to explain the vasodilatatory effects of SNO-Hb. These data are discussed in the context of SNO-Hb as a potential modulator of blood flow.

    EXPERIMENTAL PROCEDURES
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
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Reagents-- All reagents were purchased from Sigma. SNOC and SNAP were synthesized as previously reported (27). Human HbA was purified as described below.

Preparation of Hemoglobin and S-Nitrosohemoglobin-- Human hemoglobin was prepared as described previously (10). S-Nitrosohemoglobin was synthesized by incubating oxy-Hb (200 µM; all stated Hb concentrations are in terms of heme) with SNOC (2 mM) at 20 °C for 20-40 min in 2% borate and 1 mM DTPA. In some experiments, SNAP was used instead of SNOC, in which case the incubation time was 1-2 h. All solutions were protected from light. Hb was separated from SNOC or SNAP by gel filtration using Sephadex G-25 (10 × 1 ml; pre-equilibrated with phosphate-buffered saline containing 1 mM DTPA, pH 7.4). When SNOC was used, ~10-20% of the Hb was oxidized to methemoglobin (metHb). This was attributed to the small, but unavoidable concentration of nitrite remaining in our SNOC preparations. No significant metHb (measured by visible spectroscopy) was formed when SNAP was used. Oxy-Hb concentrations were determined by UV-visible spectroscopy using the extinction coefficient per heme group epsilon 577 nm = 14.6 mM-1 cm-1 (10). S-Nitrosation of Hb was quantified by the Saville reaction, with all mercury-dependent nitrite formation being protein-precipitable (13, 27). Differing levels of S-nitrosation were obtained by altering the incubation times between oxy-Hb and either SNOC or SNAP. Cys-beta 93 thiols on Hb were measured using either dithionitrobenzoic acid or 2,2'-dithionitropyridine (28). Hb samples (5 µM heme) were incubated with dithionitrobenzoic acid or 2,2'-dithionitropyridine for 20 min at 20 °C, and absorbance at 412 or 386 nm, respectively, was measured. Reduced thiol concentrations were calculated using epsilon 412 nm = 12 mM-1 cm-1 or epsilon 386 nm = 14 mM-1 cm-1.

Oxygen Affinities of Hemoglobin and S-Nitrosohemoglobin-- Oxygen binding curves of Hb and SNO-Hb were determined using a tonometer. Hemoglobin samples (30-50 µM heme, 3 ml) were incubated initially with a metHb reductase system (29) at 20 °C to remove metHb formed during synthesis of SNO-Hb. The metHb reductase system was found to have no effect on the oxygen affinities of Hb or on the stability of the SNO group (data not shown). Furthermore, similar results were obtained in instances when the metHb reductase system was not required, i.e. when SNAP was used to synthesize SNO-Hb. Complete reduction to oxy-Hb occurred within 20 min as determined spectrophotometrically. Hb samples were then deoxygenated until deoxy-Hb was formed (determined spectrophotometrically). Samples were deoxygenated until A560 nm/A577 nm = 0.73-0.74. This value was determined from a spectrum of pure deoxy-Hb synthesized by addition of sodium dithionite to a solution of oxy-Hb. Deoxygenation was accompanied by a decrease in sample volume to between 1.5 and 2 ml. Aliquots of air (0.5-1 ml) were then injected into the tonometer, and the absorbance spectrum (500-700 nm) was recorded after each addition. Oxygen partial pressures were determined by measuring the atmospheric pressure at the time of the experiment using a digital barometer (Fisher). All oxygen binding curves were measured under identical conditions in 50 mM sodium phosphate buffer, pH 7.4, containing 250 µM DTPA at 20 °C and at a constant partial pressure of carbon dioxide.

Effect of Allosteric Mediators on the Oxygen Affinities of Hb and SNO-Hb-- The effect of temperature was assessed by measuring the oxygen binding curve at either 20 or 37 °C. Once deoxygenated, Hb solutions were incubated at the required temperature in a spectrophotometer for 15 min before addition of air. The modulation of oxygen binding by inorganic phosphates was ascertained by adding inositol hexaphosphate at a 100-fold excess concentration relative to tetrameric Hb, prior to measurement of oxygen affinity. The effect of pH was assessed by conducting the experiments in 50 mM sodium phosphate buffer containing 250 µM DTPA at either pH 6.5 or 7.4.

Transnitrosation Reactions between SNO-Hb and GSH-- To monitor transnitrosation reactions between GSH and deoxy-SNO-Hb, Hb was first deoxygenated in a tonometer, and then GSH (at a concentration 25 times that of heme) was added anaerobically using a gas-tight syringe. Interactions with a mixture of oxygenated and deoxygenated forms were also evaluated by partially oxygenated SNO-Hb before addition of GSH. In either case, the effect of GSH on the oxygenation state of Hb was monitored continuously over 5 min by measuring the absorbance spectrum. In parallel experiments, GSNO formation was determined either immediately or 5 min after GSH addition by adding trichloroacetic acid (20% v/v) to Hb in the tonometer. The solution was then centrifuged to remove precipitated protein, and GSNO was measured in the supernatant by the Saville assay.

The reaction between GSNO and either oxy-Hb or deoxy-Hb was also monitored by measuring the rate of loss of GSNO by HPLC. All experiments were performed in 50 mM phosphate buffer, pH 7.4, containing 100 µM DTPA. GSNO concentrations were determined by HPLC using a reverse-phase Kromasil C18 column (Alltech Associates, Inc.) and a mobile phase of 0.05% trifluoroacetic acid/methanol (94:6). GSNO was detected spectrophotometrically at 210 nm using a diode array detector and quantified using authentic GSNO. The identity of GSNO was confirmed by analyzing the full UV-visible spectrum of the putative GSNO peak using the diode array detector.

Kinetic Analysis of Second-order Reversible Reactions-- Transnitrosation reactions are second-order reversible reactions (Equation 1).
A+B ⇌ C+D (Eq. 1)
The kinetics of such processes can be described by two second-order rate constants: kf for the forward reaction and kr for the reverse reaction. The dependence of [A] on time (t) is given by Equation 2,
[A]=<FR><NU>P[A]<SUB>∞</SUB>([A]<SUB>0</SUB>+[A]<SUB>∞</SUB>+Q)+([A]<SUB>0</SUB>−[A]<SUB>∞</SUB>)([A]<SUB>∞</SUB>+Q)</NU><DE>P([A]<SUB>0</SUB>+[A]<SUB>∞</SUB>+Q)−([A]<SUB>0</SUB>−[A]<SUB>∞</SUB>)</DE></FR> (Eq. 2)
with terms defined in Equations 3-6.
P=<UP>exp</UP><FENCE><FR><NU>k<SUB>f</SUB>(2t[A]<SUB>∞</SUB>(K−1)+Q(K−1))</NU><DE>K</DE></FR></FENCE> (Eq. 3)
Q−<FR><NU>K([B]<SUB>0</SUB>−[A]<SUB>0</SUB>)+2[A]<SUB>0</SUB></NU><DE>K−1</DE></FR> (Eq. 4)
[A]<SUB>∞</SUB>=<FENCE><FR><NU>1</NU><DE>2(K−1)</DE></FR></FENCE><FENCE><RAD><RCD>(K([B]<SUB>0</SUB>−[A]<SUB>0</SUB>)+2[A]<SUB>0</SUB>)<SUP>2</SUP>+4[A]<SUP>2</SUP><SUB>0</SUB></RCD></RAD>(K−1)</FENCE> (Eq. 5)
<FENCE>−(K([B]<SUB>0</SUB>−[A]<SUB>0</SUB>)+2[A]<SUB>0</SUB>)</FENCE>
K=<FR><NU>k<SUB>f</SUB></NU><DE>k<SUB>r</SUB></DE></FR> (Eq. 6)
The subscripts 0 and infinity  indicate the concentrations of reactants at zero time and infinite time, respectively. The data obtained were fitted to the above equations and rate constants for the forward and reverse reactions, i.e. kf and kr calculated.

    RESULTS
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
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Oxygen Affinity of SNO-Hb-- The oxygen affinities of Hb and SNO-Hb were determined using a tonometer. Fig. 1 shows the absorbance spectra of Hb (panel A) and SNO-Hb (panel B) obtained when the corresponding deoxygenated derivatives were titrated with oxygen. In both cases, after removal of oxygen, a typical absorbance spectrum of deoxy-Hb was observed (lambda max = 555 nm), which, upon addition of oxygen, gradually changed to give the spectrum of oxy-Hb (lambda max = 544 and 577 nm). Isosbestic points at 524, 548, 569, and 585 nm were observed for both native Hb and SNO-Hb, indicating that nitrosation of Cys-beta 93 does not affect the spectral changes that occur upon oxygen binding to the heme. In addition, no spectral evidence of formation of nitrosylhemoglobin (i.e. NO bound to ferrous heme groups) was observed (with the methodology used, nitrosylation of ~5% of the total heme would have been detectable). The total concentration of solvent-exposed thiols (i.e. NO-bound thiol + free thiol) was the anticipated 2 thiols/tetramer (Table I).


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Fig. 1.   Changes in absorbance spectra on addition of oxygen to deoxy-Hb (A) or deoxy-SNO-Hb (B). Hemoglobin samples were deoxygenated by evacuation and reoxygenated by addition of oxygen. The arrows show the direction of absorbance changes on addition of increasing amounts of air, indicating the transition from deoxy-Hb to oxy-Hb. Reactions were carried out in 50 mM sodium phosphate buffer, pH 7.4, containing 250 µM DTPA at 20 °C and at a constant partial pressure of carbon dioxide.

                              
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Table I
Concentration of the S-nitroso group and free thiols after reaction of Hb with SNAP or N-ethylmaleimide
The free or S-nitrosated thiols in native oxy-Hb, oxy-SNO-Hb, or oxy-N-ethylmaleimide-Hb were determined as described under "Experimental Procedures." The data shown are representative of SNO-Hb synthesized with varying degrees of S-nitrosation. In this case, SNO-Hb was synthesized by incubation of oxy-Hb (200 µM) with SNAP (2 mM) in 2% borate buffer and 1 mM DTPA at 20 °C for 30 min. In all cases, the total thiol content was 2/tetramer. The S-nitroso group was measured by the Saville reaction, and reduced thiols using dithionitrobenzoic acid. Reactions were carried out in phosphate-buffered saline with 1 mM DTPA at 20 °C. Values represent means ± S.E. (n = 3).

The concentration of oxy-Hb for a given pO2 was calculated from the spectra shown in Fig. 1, and the oxygen binding curves for Hb and SNO-Hb were thus calculated and are shown in Fig. 2A. Native Hb displayed a characteristic sigmoidal oxygen binding curve. S-Nitrosohemoglobin (0.98 SNO groups/tetramer) also had a sigmoidal oxygen binding curve, which was, however, left shifted compared with native Hb (Fig. 2A). These data show that, relative to native Hb, SNO-Hb has a higher oxygen affinity and therefore, under physiological conditions, requires an environment of substantially lower oxygen concentration before releasing oxygen via a deoxygenation-sensitive mechanism as described previously (13, 14). Fig. 2B summarizes a series of experiments in which the oxygen affinities of Hb and SNO-Hb, with differing levels of S-nitrosation, were determined. Oxygen affinities were assessed by comparing the p50 values, i.e. the oxygen tensions at which 50% of the Hb was bound with oxygen. Unmodified Hb had a p50 of 7 ± 0.12 mm Hg (mean ± S.E., n = 12). In each case, S-nitrosation of Hb significantly increased the oxygen affinity (indicated by a decrease in the p50), with the p50 of SNO-Hb (0.6 SNO group/tetramer, i.e. 30% of beta 93 thiols being S-nitrosated (this number refers to a distribution of SNO groups, as it is not possible to distinguish between specific populations of Hb containing 1 or 2 SNO groups/tetramer)) being 4.3 ± 0.27 mm Hg (mean ± S.E., n = 5). Interestingly, S-nitrosation of up to one of the Cys-beta 93 residues proportionately increased the oxygen affinity; however, further modification did not affect the oxygen affinity (Fig. 2B).


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Fig. 2.   S-Nitrosation of Hb increases the oxygen affinity. Oxygen binding curves of Hb (black-square) and SNO-Hb (0.98 SNO group/tetramer; ) are shown in A and were obtained from the data shown in Fig. 1. Fractional saturation (Y) represents [oxy-Hb]/[total Hb]. B shows the effect of S-nitrosation of Hb on the p50 value for oxygen binding. p50 values were determined from the respective oxygen binding curves and plotted against the degree of S-nitrosation of Hb. The data shown were obtained from up to 20 separate experiments and with human Hb obtained from three different donors. *, p < 0.001 by analysis of variance. The line shown between 0 and 1 SNO group/tetramer was fitted using linear regression analysis (y = 7.01-4.09x, r2 = 0.99).

Previous studies found that the SNO group of SNO-Hb was less stable when Hb was in the deoxygenated state, resulting in nitrosyl-Hb formation, and that this was related to the ability of deoxy-SNO-Hb to promote vasorelaxation (13). Since the method used to determine the oxygen affinity involved initially deoxygenation followed by oxygenation, formation of nitrosyl-Hb would affect the results obtained. However, no spectral evidence of nitrosyl-Hb or metHb was seen during the deoxygenation-reoxygenation cycle. Furthermore, the concentration of S-nitrosation was measured before and after completion of the oxygen saturation curve. Over the time taken to deoxygenate and then to reoxygenate the Hb (~20-30 min), no significant change in the concentration of the Cys-beta 93-NO adduct could be detected. Further analysis over longer time periods indicated that the rate of spontaneous decomposition of deoxy-SNO-Hb was ~8 nM/min, representing 0.03% of the total bound NO/min in this preparation of SNO-Hb. From these results, we conclude that spontaneous release of NO from SNO-Hb is unlikely to be a physiologically relevant mechanism, where a given Hb molecule will be cycling between the oxygenated and deoxygenated forms on a time scale in the order of seconds.

Effect of Allosteric Mediators on the Oxygen Affinity of SNO-Hb-- The increased oxygen affinity of SNO-Hb suggests that it is less likely than native Hb to become deoxygenated and hence release NO under physiological conditions. However, in vivo, numerous regulatory mechanisms modulate the oxygen binding affinity of Hb in the red blood cell. It is possible that S-nitrosation of Hb alters the sensitivity to the various allosteric regulatory mechanisms present such that SNO-Hb may be able to deliver oxygen under physiological conditions. We therefore tested the effects of pH, temperature, and inorganic phosphates on the oxygen affinity of SNO-Hb and compared it with that of native Hb.

The effects on oxygen affinity of each of the allosteric modulators are shown in Table II and were determined by measuring the difference in log p50 of SNO-Hb and Hb elicited by the different allosteric mediators. An increase in temperature is known to decrease the oxygen affinity and thus facilitate oxygen delivery. Table II shows that the change in log p50 of Hb and SNO-Hb on increasing the temperature from 20 to 37 °C was the same. Inorganic phosphates decrease the oxygen affinity of Hb (1, 2). Inositol hexaphosphate induced similar increases in the p50 of Hb and SNO-Hb, indicating that S-nitrosation of Cys-beta 93 does not affect binding of inorganic phosphates to Hb. Finally, we assessed the effect of pH (also called the Bohr effect). The relatively acidic conditions in respiring tissues lower the p50 of oxygen binding by Hb, with the net result being oxygen delivery. This occurs in part through binding of protons to histidine residues present in both the alpha - and beta -chains, a property that also serves to buffer plasma. Decreasing the pH from 7.4 to 6.5 decreased the oxygen affinities of both Hb and SNO-Hb to similar extents, with the effect being approximately equal for both forms of Hb (Table II). This shows that S-nitrosation does not significantly affect the binding and release of protons by Hb. It has been calculated that binding of protons by His-beta 146 accounts for ~40% of the alkaline Bohr effect (30). The fact that a change in pH exerts similar effects on the oxygen affinities of SNO-Hb and Hb indicates that S-nitrosation of Hb does not significantly alter the biological properties of this histidine residue, which is closely situated to Cys-beta 93 (14). Thus, SNO-Hb and Hb are modulated to similar extents by allosteric effector mechanisms.

                              
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Table II
Allosteric modulators have similar effects on the oxygen affinities of Hb and SNO-Hb
The oxygen affinities of Hb and SNO-Hb (0.6-2 SNO groups/tetramer) were measured in the presence and absence of allosteric mediators. The change in oxygen affinity induced by the different allosteric regulators was calculated by measuring the difference in log p50. These were then compared to assess the regulatory effects on SNO-Hb relative to Hb. Values represent means (n = 2) ± S.E. (n = 3, as indicated).

Cooperative Nature of Oxygen Binding to SNO-Hb-- A feature of oxygen binding by Hb is that it is cooperative in nature. The effect of S-nitrosation on this property was calculated by Hill plot analysis of the oxygen binding data. Fig. 3 compares the Hill plots for Hb and SNO-Hb. The Hill coefficient at the 50% oxygen saturation level for each Hb was calculated. S-Nitrosation (0.6 SNO group/tetramer) did not significantly decrease the Hill coefficient (2.83 ± 0.11 compared with 3.17 ± 0.11 for unmodified Hb).


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Fig. 3.   Hill plots of oxygen binding curves of Hb and SNO-Hb. The cooperative nature of oxygen binding to Hb (black-square) and SNO-Hb () was examined by Hill plot analysis. Hill plots were constructed by plotting the logarithm of Y/1 - Y versus the logarithm of oxygen tension (mm Hg). In the example shown, SNO-Hb in which 30% of the Cys-beta 93 residues are nitrosated is represented. Hill coefficients were calculated by measuring the gradient at the p50, i.e. at log(Y/1- Y) = 0. Oxygen binding curves were determined as described in the legends to Figs. 1 and 2.

We can conclude from the minimal effects of S-nitrosation on the Hill coefficient that the observed changes in oxygen affinity do not involve altered heme interactions. Previous studies have shown that Cys-beta 93 is located close to the alpha 1beta 2-interface and that its covalent modification inhibits the formation of essential salt links between His-beta 146 and Asp-beta 94 and of various hydrogen bonds (14). The net effect is a destabilization of the T state and hence an increase in oxygen affinity as well as a decrease in the Hill coefficient. Since S-nitrosation of Hb does not alter the Hill coefficient, the increase in oxygen affinity does not appear to be modulated by affecting the stability of salt links.

Effect of Glutathione on Release of NO from SNO-Hb-- It has been suggested that transnitrosation reactions between SNO-Hb and low molecular weight thiols, such as GSH, mediate the transfer of the vasorelaxant signal from Hb to the vasculature (13, 14). The mechanism proposed involves transnitrosation from deoxy-SNO-Hb to GSH, with reaction with the oxy derivative being too slow and thus negligible (13). To examine this point further, GSH was added to a solution of SNO-Hb (2 SNO groups/tetramer) that was partially oxygenated (~60%, i.e. Y = 0.6), and the value of Y was measured over 5 min of incubation. Since unmodified Hb has a lower oxygen affinity compared with SNO-Hb (Fig. 2), it is predicted that transnitrosation from SNO-Hb to GSH, forming Hb and GSNO, will decrease the value of Y. Addition of GSH (heme/GSH molar ratio approx  1:25) to SNO-Hb did not significantly change the value of Y (Y = 0.59 ± 0.1 before addition of GSH and 0.61 ± 0.1 after 5 min of incubation; mean ± S.E., n = 5). These data indicate that extensive transnitrosation reactions are not occurring over the time scale, but this approach would not be able to detect the release of 50-100 nM NO needed to elicit vasorelaxation.

To gain insight into the kinetics of this process, transnitrosation between GSNO and oxy-Hb or deoxy-Hb was monitored by more sensitive HPLC techniques (Fig. 4). Incubation of GSNO with oxy-Hb caused a time-dependent reduction in GSNO concentration (Fig. 4A). The kinetics of GSNO decay fit well to a second-order reversible reaction (Equation 1 under "Experimental Procedures" and Fig. 4A). Fig. 4A shows the experimentally derived points (represented by symbols) together with fits of these data to a second-order reversible process (represented by lines). The values of both the forward (kf) and reverse (kr) rate constants for oxy-Hb were reasonably constant (0.08-0.2 M-1 s-1 for kf and 0.06-0.13 M-1 s-1 for kr) over a large range of initial GSNO concentrations (0-0.7 mM). This reaction conforms well to the model and precludes a simple first-order process. The average rate constants for this reaction were 0.13 ± 0.02 M-1 s-1 (kf) and 0.1 ± 0.01 M-1 s-1 (kr). This analysis gives an equilibrium constant for the reaction of 1.3, close to unity. This means that under equilibrium conditions and at the approximately equal concentrations of GSH and Hb that occur in the red blood cell, the nitroso functional group will be evenly distributed between Hb and GSH.


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Fig. 4.   Transnitrosation between GSNO and Hb under oxygenated and deoxygenated conditions. A, GSNO (700 (), 450 (black-square), 300 (black-triangle), 150 (black-down-triangle ), and 50 (black-diamond ) µM) was incubated with oxy-Hb (1 mM total heme) at 37 °C in 50 mM phosphate buffer, pH 7.4, containing 100 µM DTPA. GSNO concentration was monitored by HPLC. The data were fitted (solid lines) to a second-order reversible model (see "Experimental Procedures"), assuming 0.5 hemoglobin thiols/heme, to give both forward (kf) and reverse (kr) rate constants. For the above data, the values were 0.13, 0.08, 0.13, 0.14, and 0.20 M-1 s-1 (for kf), respectively, and 0.10, 0.06, 0.10, 0.13, and 0.10 M-1 s-1 (for kr), respectively. B, GSNO (1220 (), 620 (black-square), 450 (black-triangle), and 250 (black-down-triangle ) µM) was incubated with deoxy-Hb (, 2 mM; all others, 1 mM) at 37 °C in 50 mM phosphate buffer, pH 7.4, containing 100 µM DTPA under strict anaerobic conditions. GSNO concentration was monitored by HPLC. The data were fitted (solid lines) to a second-order reversible model, assuming 0.5 hemoglobin thiols/heme, to give both forward (kf) and reverse (kr) rate constants. For the above data, the values were 0.05, 0.01, 0.02, and 0.11 M-1 s-1 (for kf), respectively, and 0.01, <0.001, <0.001, and 0.05 M-1 s-1 (for kr), respectively. It should be noted that the concentrations given above for GSNO under anaerobic conditions are the recovered initial concentrations that were used for the fitting procedure. The amount added was significantly greater.

The kinetics of transnitrosation under anaerobic conditions (i.e. between deoxy-Hb and GSNO) were also determined as shown in Fig. 4B. The decay of GSNO conformed well to second-order kinetics at high concentrations of GSNO and hemoglobin, but less well at low concentrations. In addition, the rate constants derived from the fits varied dramatically as a function of GSNO concentration (between ~0.01 and 0.1 M-1 s-1 for kf). This suggests that a simple second-order reversible process cannot explain the reaction between GSNO and deoxy-Hb. One mitigating factor precluding accurate kinetic analysis of transnitrosation between GSNO and deoxy-Hb is the observation that GSNO binds to the heme group of deoxy-Hb. Consequently, the amount of GSNO available for transnitrosation will be modulated by the equilibrium of binding to the heme. Accurate kinetic analysis can only be performed if all reactions are taken into account, and we are currently pursuing this objective. The rate constants for the forward reactions (kf) for both oxy-Hb and deoxy-Hb are slower, but of a similar magnitude to those previously reported (35).

To determine the rate of GSNO formation from SNO-Hb under physiological conditions, simulation of this process were undertaken. Using the rate constants detailed above, the formation of GSNO, under aerobic conditions, from the reaction between 5 µM SNO-Hb and 5 mM GSH was calculated to be ~3 nM s-1. These concentrations were chosen to approximate the conditions within an erythrocyte. These data indicate that GSNO formation from SNO-Hb is a process capable of slowly generating physiologically relevant concentrations of GSNO (20-100 nM). Although the reactions of deoxy-Hb are kinetically more complex, our data indicate that under anaerobic conditions, the formation of GSNO will be slower than under aerobic conditions.

    DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

The diffusability of NO and the high concentrations of Hb in the circulation indicate that reaction between these two species will occur in vivo. In support of this, nitrosyl-Hb, a direct product of the reaction between deoxy-Hb and NO, has been detected in the venous circulation (31). The corresponding reaction with oxy-Hb results in formation of metHb and nitrate (32). Since metHb is reduced back to ferrous Hb by the metHb reductase system in erythrocytes and nitrate is an inert end product of NO metabolism, this reaction has been suggested to play a role in the safe removal of NO. However, this reaction also poses a problem regarding how NO, in the presence of Hb, can elicit vasorelaxation and other effects synonymous with this free radical.

The detection of the novel Hb derivative SNO-Hb in vivo and the subsequent description of mechanisms by which this protein can mediate blood flow via NO release have brought new insights into this paradox. This impacts upon the emerging area of NO biology addressing the role of S-nitrosation reactions (i.e. addition of NO+) as opposed to nitrosylation (i.e. addition of NO). It was suggested that, in the presence of GSH, the stability of the SNO group of SNO-Hb was dictated by the oxygenation state of this heme protein (13). A mechanism was formulated in which deoxy-SNO-Hb rapidly underwent transnitrosation reactions with GSH to form GSNO (14).

In this study, we have further evaluated these mechanisms by examining the biochemical properties of SNO-Hb, focusing on the effect of S-nitrosation of Cys-beta 93 on the oxygen binding characteristics of Hb and on transnitrosation reactions with GSH. This is important since both the oxygen affinity of Hb and the characteristics of transnitrosation reactions involving this protein are intrinsically linked to the deoxygenation-sensitive mechanism of NO release. Our results show that S-nitrosation of Hb increases its oxygen affinity (Fig. 2). As mentioned earlier, the relatively low concentrations of SNO-Hb in vivo suggest that although SNO-Hb has a higher oxygen affinity, this will not affect the efficiency of oxygen uptake and delivery by a given erythrocyte, and thus, S-nitrosation cannot be considered another allosteric modulator of oxygen uptake and delivery. In marked contrast, the effects on the ability of the small population of SNO-Hb molecules to deliver NO to tissues is highly significant and must be taken into account since the oxygen dissociation curve of SNO-Hb is left-shifted. Thus, in vivo, a deoxygenation-sensitive mechanism for NO release from SNO-Hb would only be effective at sites where the oxygen tension would drop significantly to allow SNO-Hb to release its oxygen. This would most likely occur in regions of hypoxia, and recent studies indicate that in the rat mesenteric vasculature, the pO2 can drop significantly (~50%) across the endothelium, suggesting that SNO-Hb may become deoxygenated in this tissue (33).

Since native Hb is symmetrical, both Cys-beta 93 residues are presumably equivalent in terms of their chemical reactivity. S-Nitrosation did not mediate oxidation of the thiol over the time course of these experiments. Interestingly, however, the effects on the oxygen affinity were mediated wholly by modification of only one of the two available Cys-beta 93 residues (Fig. 2). It is not clear how S-nitrosation of Cys-beta 93 increases the oxygen affinity on a molecular level. Although blocking this residue by alkylation has similar effects on the oxygen affinity, these data also show that unlike S-nitrosation, maximal increases in the oxygen affinity are only attained after both Cys-beta 93 residues are blocked by N-ethylmaleimide (24).

We also evaluated transnitrosation reactions between the oxygenated and deoxygenated forms of SNO-Hb and GSH, which have been proposed to play an important role in Hb-dependent regulation of blood flow (13, 14). Consistent with reported data on the kinetics of transnitrosation reactions in general and more specifically between GSNO and Hb (34), we found that the rate of this reaction is relatively slow, but can yield biologically relevant concentrations of GSNO. However, this is too slow to account for the vasodilatatory properties of SNO-Hb over the time taken for a given red blood cell to pass through the pre-capillary vasculature. Accurate estimation of the transnitrosation of GSH by deoxy-SNO-Hb was difficult to achieve because of the slow rates involved and the additional binding of the S-nitrosothiol to another site on the deoxy-Hb molecule (data not shown).

The concentration of SNO-Hb has been shown to be higher in arterial as opposed to venous blood, implying release of NO in the pre-capillary beds (13). Our data suggest that a deoxygenation-dependent mechanism is unlikely and that the biochemical mechanism that accounts for this observation does not reside within the Hb molecule. An alternative explanation is that the rates of SNO-Hb formation are oxygen-dependent and therefore change throughout the circulation. Indeed, SNO-Hb synthesis has been reported to be an oxygen-dependent process (35), and this and our findings that SNO-Hb will be constantly destroyed by GSH indicate that concentrations of this Hb derivative will be higher in the arterial circulation.

    ACKNOWLEDGEMENTS

We thank J. S. Beckman, B. A. Freeman, and M. T. Wilson for helpful discussions.

    FOOTNOTES

* This work was supported by the American Heart Association and the American Diabetes Association (to V. M. D.-U.), National Institutes of Health Grants GM55792 (to N. H.) and HL31197 and HL51173 (to S. M.), and Office of Naval Research Grant N00014-97-1-0309 (to S. M.).The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

** To whom correspondence should be addressed: Dept. of Pathology, University of Alabama at Birmingham, Volker Hall, Rm. GO19, 1670 University Blvd., Birmingham, AL 35294-0019. Tel.: 205-975-9686; Fax: 205-934-1775; E-mail: darley{at}path.uab.edu.

    ABBREVIATIONS

The abbreviations used are: oxy-Hb, oxygenated hemoglobin; deoxy-Hb, deoxygenated hemoglobin; SNO-Hb, S-nitrosohemoglobin; deoxy-SNO-Hb, deoxygenated S-nitrosohemoglobin; metHb, methemoglobin or ferric hemoglobin; GSNO, S-nitrosoglutathione; SNOC, S-nitrosocysteine; SNAP, S-nitroso-N-acetylpenicillamine; DTPA, diethylenetriaminepentaacetic acid; HPLC, high pressure liquid chromatography.

    REFERENCES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
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