(Received for publication, December 11, 1996, and in revised form, March 26, 1997)
From the Department of Surgical Research, Northwick Park Institute for Medical Research, Harrow, Middlesex HA1 3UJ, United Kingdom
Thiols are very important antioxidants that
protect cells against oxidative insults. Recently, a different and new
physiological role has been defined for these compounds because of
their involvement in nitric oxide (NO) binding and transport in
biological systems. In view of these characteristics, we examined the
effect of thiols and NO on the expression of the inducible form of heme
oxygenase (HO-1), a stress protein that degrades heme to carbon
monoxide and biliverdin. Cultured bovine aortic endothelial cells
exposed to the NO donors sodium nitroprusside (SNP) and
S-nitroso-N-acetylpenicillamine (SNAP) resulted
in increased heme oxygenase activity and HO-1 expression. Co-incubation
with N-acetylcysteine, a precursor of glutathione
synthesis, significantly attenuated heme oxygenase induction by SNP and
SNAP, and a reduction in heme oxygenase activity was also observed when
cells were preincubated with N-acetylcysteine for 16 h
prior to exposure to NO donors. This effect appears to be associated
with NO stabilization by thiols through the formation of
S-nitrosothiols. Hydroxocobalamin, a specific NO scavenger, significantly decreased endothelial heme oxygenase activity, indicating a direct involvement of NO released by NO donors to regulate the expression of this stress protein. Moreover, superoxide anion (O2) and its reaction product with NO, peroxynitrite
(ONOO
), were found to partially contribute to the
observed NO-mediated activation of endothelial heme oxygenase. Thus, we
suggest the existence of a dynamic equilibrium among free NO,
O
2, and endogenous glutathione, which might constitute an
interactive signaling mechanism modulating stress and adaptive
responses in tissues.
Heme oxygenase is a widely distributed enzyme in mammalian tissues, and its main function is associated with the degradation of heme to biliverdin, iron, and carbon monoxide (CO).1 Two distinct isoforms of the protein have been characterized revealing that one of the isozymes is constitutive (HO-2), whereas the other is inducible (HO-1) (1). Thus, if the first enzyme is constitutively expressed and is part of the normal cellular metabolism, the second is regarded as a heat shock protein, and its expression is elicited by many conditions and factors that produce an imbalance in the cellular functions. Various agents, including heavy metal ions (2), oxidative stress (3), endotoxins (4), and hemoglobin (5) are capable of inducing HO-1 in different tissues, and recent findings showed that nitric oxide (NO) donors increase HO-1 mRNA in the brain (6) and in cultured hepatocytes (7). Accordingly, we have reported the ability of diverse NO releasing agents to modulate heme oxygenase activity in aortic endothelial cells (8).
The physiological importance of HO-1 induction following stress situations is not fully understood, although it has been hypothesized that the expression of this gene is part of the defensive mechanism that cells and tissues are capable of mounting against different stress stimuli. To sustain this idea are the findings that biliverdin and bilirubin, end products of heme catabolism, possess antioxidant properties (9) and that CO seems to mimic many NO functions. Like NO, CO activates soluble guanylate cyclase and inhibits platelet aggregation (10, 11), and its possible role as a neurotransmitter has been postulated (12, 13). Recent findings also show the participation of CO in the regulation of vascular tone in hepatic sinusoidal cells, suggesting that NO and CO could share the control of relaxation processes (14).
NO is a free radical species with multiple biological functions and has
been identified as endothelium-derived relaxing factor (15-17). It
reacts rapidly with superoxide anion (O2) to form the stable
peroxynitrite anion (ONOO
), which decomposes once
protonated to yield a strong oxidant with reactivity similar to
hydroxyl radical (OH·) (18). In addition, NO has a high affinity
for heme-iron molecules and interacts readily with thiol groups of
proteins and glutathione producing S-nitrosoproteins and
S-nitrosothiols, respectively (19, 20). It has been
suggested that S-nitrosylation of proteins could mediate
signaling functions similar to those of protein phosphorylation (21)
and that thiols may be involved in NO stabilization and metabolism
(22). S-Nitrosothiols indeed possess endothelium-derived relaxing factor-like characteristics and, in virtue of their NO releasing capacities, may invoke many and possibly all NO actions (23).
There is at present a commonly accepted concept that NO diffuses freely
in tissues where it exerts its biological activities. A recent report,
however, considers the perspective that NO, to reach its
pharmacological targets, has to diffuse through the intracellular
environment where glutathione levels are in the range of 5-10
mM (24).
Several important roles distinguish glutathione as the most important cellular nonprotein thiol. It is a cofactor for many glycolytic enzymes, participates in the transport of amino acids, and constitutes the major cellular antioxidant, being present at high concentrations in most animal cells (25). It plays a key function in reacting with harmful free radicals produced during the metabolism contributing to cellular detoxification. However, depletion of intracellular levels of glutathione may occur in conditions of severe and intense oxidant stress leading to increased susceptibility to cytotoxicity. A correlation between heme oxygenase and glutathione has been documented (4, 26) where HO-1 levels are augmented in conditions of decreased intracellular glutathione. Whether decreased glutathione levels affect heme oxygenase via accumulation of reactive oxygen species or by modulating a signaling mechanism is unknown.
The purpose of the present study was to examine the role of exogenous
and endogenous thiol-containing compounds in the regulation of heme
oxygenase induction by NO and other radical species in bovine aortic
endothelial cells. We report that increased thiol levels reduce heme
oxygenase expression and activity mediated by NO donors and that both
O2 and ONOO
appear to partially contribute to
the stimulation of this stress response; the physiological relevance of
these findings will be discussed.
Bovine aortic endothelial cells and human
umbilical vein endothelial cells were purchased from the European
Collection of Animal Cell Culture (Salisbury, UK). Hemin was obtained
from Porphyrin Products Inc. (Logan, UT). Sodium nitroprusside (SNP),
S-nitroso-N-acetylpenicillamine (SNAP),
N-acetylcysteine,
DL-buthionine-[S,R]-sulfoximine
(BSO), S-nitrosoglutathione (GSNO), hydroxocobalamin, and
superoxide dismutase (SOD, bovine liver) were all purchased from Sigma.
3-Morpholinosydnonimine (SIN-1) and sodium peroxynitrite were obtained
from Alexis Corp. (Bingham, Nottingham, UK). Peroxynitrite was prepared
fresh in sodium hydroxide (0.3 mM), shipped via courier on
dry ice and immediately stored at 80 °C. The concentration of
peroxynitrite was monitored each day before use by measuring the
absorbance at 302 nm (extinction coefficient = 1670 M
1 cm
1) after addition of 25 (stock solution) to 975 µl of ice-cold 0.3 M sodium
hydroxide. All the experiments with peroxynitrite were carried out
within 10 days after receiving the drug, and the concentration was
verified to be >95% of the stipulated one. Only small volumes of
peroxynitrite were added to the culture media, and no significant
changes in pH were observed.
Bovine aortic endothelial cells were cultured in 75-cm2 flasks and grown in Iscove's modified Dulbecco's medium supplemented with 8% fetal bovine serum, 2 mM L-glutamine, penicillin (100 units/ml), and streptomycin (0.1 mg/ml). Cells used for the heme oxygenase assay were cultured to reach confluency in 75-cm2 flasks; the glutathione determination method was performed in confluent cells grown in 6-well plates, and for the nitrite and S-nitrosothiols measurements cells were subcultured in 24-well tissue culture plates. Human umbilical vein endothelial cells were cultured in 75-cm2 flasks in Medium 199 supplemented with 10% fetal bovine serum, 2 mM L-glutamine, and antibiotics.
Experimental ProtocolTo investigate the effect of NO and
the role of NO-derived intermediate(s) on endothelial heme oxygenase
activation, several common NO donors were examined either alone or in
the presence of various scavengers and agents. In the first group of
experiments, cells were incubated for 6 h in complete medium
(control) or in medium supplemented with SNP (0.5 and 1 mM), SNAP (0.5 mM), or GSNO (0.5 mM). In a different set of experiments cells were exposed to SNP or SNAP in the presence of the glutathione precursor
N-acetylcysteine (0.25, 1, 2.5, and 5 mM).
Hydroxocobalamin (vitamin B12), known as a NO scavenger (27), was also
used at a final concentration of 0.5 mM in the presence of
SNP or SNAP. A third group of experiments consisted of pre-exposure of
cells for 16 h to 2.5 mM N-acetylcysteine, subsequently followed by 6 h incubation with 1 mM SNP
or 0.5 mM SNAP. To study the possible interaction between
superoxide anion (O2) and NO in the modulation of heme
oxygenase activity, endothelial cells were exposed for 6 h to the
NO releasing agent SIN-1, which is known to generate stoichiometric
amounts of NO and O
2 leading to the formation of the potent
oxidant peroxynitrite (ONOO
) (28). The direct involvement
of ONOO
(150 and 300 µM) was also
investigated, and the contribution of O
2 in the induction of
heme oxygenase was examined in cell cultures to which the various NO
donors (SNP, SNAP, or SIN-1) were added in the presence of SOD (50 units/ml).
Heme
oxygenase activity assay was performed as described previously by
Motterlini et al. (29). Briefly, microsomes from harvested
cells were added to a reaction mixture containing NADPH (0.8 mM), glucose 6-phosphate (2 mM),
glucose-6-phosphate dehydrogenase (0.2 units), 3 mg of rat liver
cytosol prepared from a 105,000 × g supernatant
fraction as a source of biliverdin reductase, potassium phosphate
buffer (PBS, 100 mM, pH 7.4), MgCl2 (0.2 mM), and hemin (20 µM). The reaction was
conducted at 37 °C in the dark for 1 h and terminated by the
addition of 1 ml of chloroform, and the extracted bilirubin was
calculated by the difference in absorbance between 464 and 530 nm ( = 40 mM
1 cm
1). Heme oxygenase
activity was expressed as picomoles of bilirubin/mg of cell protein/h.
The total protein content of confluent cells was determined using a
Bio-Rad DC protein assay (Bio-Rad, Herts, UK) by comparison with a
standard curve obtained with bovine serum albumin.
Samples of endothelial cells treated for the heme oxygenase activity assay were also analyzed by Western immunoblot technique. Cells were lysed in cold phosphate-buffered saline containing 1% Triton X-100. Total protein content was determined as reported above, and an equal protein concentration (30 µg/well) from each sample was then boiled for 5 min in Laemmli buffer (30). Protein separation was carried out by SDS-polyacrylamide gel electrophoresis using a 12% acrylamide resolving gel (Mini Protean II System, Bio-Rad, Herts, UK). Separated proteins were then transferred overnight to nitrocellulose membranes, and the nonspecific binding of antibodies was blocked with 3% non-fat dried milk in PBS, pH 7.4, for 2 h at room temperature. Membranes were then probed with a polyclonal rabbit anti-HO-1 antibody (Stressgen, Victoria, Canada) (1:1000 dilution in Tris-buffered saline, pH 7.4) for 2 h at room temperature. After three washes with PBS containing 0.05% (v/v) Tween 20, blots were visualized using an amplified alkaline phosphatase kit from Sigma (Extra-3A) and the relative density of bands analyzed by an imaging densitometer (model GS-700, Bio-Rad, Herts, UK).
Determination of Endothelial Cell Glutathione ContentThe
5,5-dithiobis-(2-nitrobenzoic acid) colorimetric assay was used for
the measurement of glutathione, the only detectable thiol in
endothelial cells. To assess the sensitivity of the method in our
experimental conditions, cells were incubated for 6 h with BSO
(0.5 and 1 mM), a selective inhibitor of glutathione
biosynthesis, or with increasing concentrations of
N-acetylcysteine (0.25, 1, and 2.5 mM). In
another set of experiments, cells were incubated for 6 h in the
presence of different NO donors with or without N-acetylcysteine. Glutathione levels were also measured
after 16 h exposure of cells to 2.5 mM
N-acetylcysteine. At the end of the incubation period, cells
were washed with PBS, and 600 µl of a 2% (w/v) solution of
5-sulfosalicylic acid was added for cell lysis and deproteinization.
The samples were centrifuged for 5 min at 10,000 × g,
and 500-µl aliquots were reacted with 500 µl of
5,5
-dithiobis-(2-nitrobenzoic acid) solution (0.3 M sodium
phosphate buffer, 10 mM EDTA, and 0.2 mM
5,5
-dithiobis-(2-nitrobenzoic acid), freshly prepared), and after 5 min the absorbance was read at 412 nm (extinction coefficient was 14.3 mM
1 cm
1) (31).
Nitrite levels were measured in the culture medium after 2, 4, and 6 h incubation of confluent endothelial cells with various concentrations of NO donors in the presence or absence of N-acetylcysteine. Where indicated, 100 µl of the culture medium were reacted with an equal volume of Griess reagent (0.5% sulfanilamide, 0.05% N-(1-naphthyl)ethylenediamine dihydrochloride in 2.5% H3PO4) in 96-well plates at room temperature for 10 min with shaking. The resulting azodye product was spectrophotometrically quantitated at 550 nm using a Dynatech MR 700 microplate reader, and nitrite levels were determined as described previously by comparison with standard curves made from a solution of sodium nitrite (32).
S-Nitrosothiols DeterminationThe Saville method was used for the measurement of S-nitrosothiols (33). Confluent cells were incubated for 0, 0.5, 1, 2, and 4 h with SNP (1 mM) plus N-acetylcysteine (1 mM) or SNAP (0.5 mM) plus N-acetylcysteine (2.5 mM). After incubation, 50 µl of the culture supernatant was reacted for 5 min with an equivalent volume of solution A (sulfanilamide 1% dissolved in 0.5 M HCl) or solution B (solution A plus 0.2% HgCl2), allowing the development of the diazonium salt. The formation of the azo dye product was obtained reacting the two samples for an additional 5 min with an equal volume of solution C (0.02% of N-(1-naphthyl)ethylenediamine dihydrochloride dissolved in 0.5 M HCl), and the absorbance was subsequently read at 550 nm with a Dynatech MR 700 microplate reader. To counteract the high nitrite concentration in the background, an equal volume of 0.5% ammonium sulfamate in water was added to the samples 5 min before the addition of sulfanilamide. S-Nitrosothiols were quantified as the difference of absorbance between solution B and A (B-A) comparing the values with a standard curve made from a solution of S-nitrosoglutathione.
Statistical AnalysisDifferences in the data among the groups were analyzed by one-way analysis of variance combined with the Bonferroni's test, and all values were expressed as mean ± S.E. The differences between groups were considered to be significant at p < 0.05.
N-Acetylcysteine, a
well-known glutathione precursor with antioxidant properties,
significantly reduced the activation of heme oxygenase by SNP in a
dose-dependent manner (Fig. 1A).
These results paralleled those obtained with Western blot analysis, showing that the inducible heme oxygenase (HO-1) is the enzymatic form
affected by the presence of SNP (Fig. 1B). Similar effects were observed with another NO donor, SNAP. Although higher
concentrations of N-acetylcysteine (2.5 and 5 mM) were needed to significantly attenuate HO-1 induction
by SNAP, the effect was still dose-dependent (Fig.
2). To examine whether an elevated intracellular
glutathione concentration could also influence HO-1 induction caused by
SNP and SNAP, endothelial cells were pretreated with 2.5 mM
N-acetylcysteine for 16 h prior incubation with NO
donors. Treatment with N-acetylcysteine produced an increase
in intracellular glutathione levels of approximately 100% above the
control values, and under this condition, we observed a marked
attenuation in heme oxygenase activity mediated by SNP and SNAP (Fig.
3). These findings indicate a possible role of thiol-containing compounds in the modulation of HO-1 induction by NO
donors. The interaction between NO released by SNP or SNAP and
O2 produced intracellularly was also considered as a possible mechanism for the increased heme oxygenase activity. As shown in Fig.
3, incubation of cells in the presence of SOD for 6 h resulted in
a partial reduction in heme oxygenase activation by SNP (38%) and SNAP
(56%), respectively.
There is evidence that hydroxocobalamin could have NO binding properties, as does hemoglobin (34). Therefore, the use of hydroxocobalamin has been an important tool in our experiments to determine the direct involvement of NO in mediating HO-1 induction. As shown in Fig. 3, hydroxocobalamin (0.5 mM) produced a significant decrease in heme oxygenase activation by NO donors (p < 0.05). Although these data do not allow us to distinguish if NO per se or an intermediary molecule(s) is the signal for heme oxygenase induction, they do, however, indicate that NO is the initial element in the cascade of events that leads to up-regulation of the enzyme.
Effect of SIN-1 and Peroxynitrite (ONOOBecause of its potential ability to generate
ONOO via simultaneous release of NO and O
2, the
NO releasing agent SIN-1 was considered separately from SNP and SNAP.
As shown in Fig. 4, heme oxygenase activity
significantly increased after 6 h exposure to SIN-1 (750 µM) from 214 ± 11 to 2306 ± 104 pmol of
bilirubin/mg protein/h (p < 0.05). This effect was
almost completely abolished by the presence of SOD in the culture
medium (487 ± 18 pmol of bilirubin/mg protein/h). When
ONOO
was added directly to the culture medium, a
dose-dependent increase in heme oxygenase activity was also
observed. The activity increased from 214 ± 11 to 641 ± 17 and 1019 ± 48 pmol of bilirubin/mg protein/h in the presence of
150 and 300 µM ONOO
, respectively.
Effect of N-Acetylcysteine on Nitrite Production from NO Donors
Because N-acetylcysteine contains sulfhydryl
groups that can react with NO, its effect on nitrite production by NO
donors was examined. If N-acetylcysteine stabilizes NO
released by NO donors, then a lower nitrite production would be
expected in the culture medium supplemented with the sulfhydryl agent.
In contrast, in the present study a substantial enhancement in nitrite
production was observed when N-acetylcysteine was added to
the culture medium containing SNP or SNAP (Fig. 5,
A and B). This enhancement was dose-dependent with SNP and increasing concentrations of
N-acetylcysteine (0.25 and 1 mM); however, in
the case of SNAP the significant (p < 0.05) increase
in nitrite levels was the same with all the concentrations of
N-acetylcysteine used (0.25, 1, and 2.5 mM). Furthermore, at the same concentration of N-acetylcysteine,
nitrite accumulation by NO donors remained unchanged at the time points considered in our experimental protocol. These results suggest that the
apparent reaction between NO donors and N-acetylcysteine occurs in the early period of co-incubation.
Formation of S-Nitrosothiols in the Presence of SNAP (or SNP) and N-Acetylcysteine
S-Nitrosothiols (or thionitrites) are one of the products of the reaction between NO and thiol groups. It was therefore deemed necessary to establish whether the conditions of our experiments were favorable for the formation of S-nitrosothiols. The supernatant of cells incubated with SNP (1 mM) plus N-acetylcysteine (1 mM) showed S-nitrosothiol formation only at time 0; at all following time points there was no detection of S-nitrosothiols according to the Saville method (see Table I). These results suggest that SNP and N-acetylcysteine can react to produce thionitrites; however, the presence of metal traces in the culture medium, the aerobic experimental conditions, and the high concentration of thiols used during the incubation can account for the inability to detect S-nitrosothiols after time 0, since the above factors all strongly accelerate thionitrite decomposition. The supernatant of cells incubated with SNAP (0.5 mM) plus N-acetylcysteine (2.5 mM) showed very high amounts of S-nitrosothiols at time 0 and little at the following time points considered. These data required a different interpretation since SNAP is an S-nitrosothiol. At time 0 we likely measured SNAP and the thionitrite produced by the reaction between the NO donor and N-acetylcysteine. The pronounced decay observed at subsequent times indicated that the half-life of both SNAP and the thionitrite is very short, possibly because of the same factors influencing S-nitrosothiol decomposition when SNP and N-acetylcysteine were used. Moreover, a transnitrosation reaction occurring between SNAP and N-acetylcysteine could also explain the low amount of thionitrites observed after time 0. In these groups of experiments the concentrations chosen for N-acetylcysteine were the ones that exhibited a marked reduction in heme oxygenase activity.
|
The method used for glutathione determination
was very sensitive since, as expected, exposure of cells to BSO or
N-acetylcysteine resulted in a dose-dependent
depletion or accumulation of detectable soluble thiols, respectively
(Fig. 6). The thiol content did not change to any extent
when cells were incubated with SNP or SNAP, but interestingly enough,
the two compounds were able to lower remarkably glutathione
accumulation observed with N-acetylcysteine alone. A 25%
decrease in intracellular thiol levels was measured with
N-acetylcysteine (1 mM) plus SNP (1 mM) in comparison with N-acetylcysteine alone,
whereas in the presence of N-acetylcysteine (2.5 mM) plus SNAP (0.5 mM) the content diminished
approximately 35%.
Effect of Various NO Donors on Endothelial Heme Oxygenase Activity
In a recent paper we have demonstrated that NO donors increase heme oxygenase activity in porcine aortic endothelial cells (8). The following experiments were carried out to examine how the stability of different NO donors and their capability in generating NO could affect the activation of heme oxygenase. SNAP and GSNO, two compounds belonging to the same class of NO donors (thionitrites or S-nitrosothiols), and SNP, an iron nitrosyl substance, were tested at the concentration of 0.5 mM. Although SNAP and GSNO are both thionitrites, we observed that SNAP was more effective in inducing heme oxygenase compared with GSNO (1644 ± 74 and 862 ± 35 pmol of bilirubin/mg of protein/h, respectively); in addition, SNP produced a slightly lower heme oxygenase activation compared with GSNO (769 ± 24 and 862 ± 35 pmol of bilirubin/mg of protein/h, respectively). These results suggest that heme oxygenase induction is dependent upon the rate of decomposition of the NO releasing agent and consequently on the amount of NO delivered into the medium. In fact, the data correlate with published observations showing that GSNO is more stable than SNAP and that SNP releases less NO when compared with SNAP or GSNO (35, 36).
Previous reports demonstrated a clear link between glutathione levels and the enzyme heme oxygenase. Only the inducible form of heme oxygenase (HO-1), but not the constitutive (HO-2), appears to be affected by the intracellular pool of low molecular weight thiols. Studies in vitro have shown that oxidant factors, such as UVA and H2O2, lower the endogenous glutathione levels, and this effect is concomitant with the induction of HO-1 (37, 38). Furthermore, in the absence of additional stimulation, depletion of intracellular glutathione by pharmacological means (BSO) is alone sufficient to regulate the expression of the enzyme (26). Low doses of endotoxin produced an increase in hepatic heme oxygenase in vivo and, under conditions of decreased glutathione levels, an enhancement of HO-1 mRNA accumulation mediated by endotoxin was observed (4). Increased intracellular reactive species, derived either by cellular metabolism and/or oxidative stress-inducing treatments, could account for the activation of the stress protein HO-1 when glutathione is depleted (37). However, the possibility that glutathione may also be involved in signal transduction mechanisms that mediate the tissue stress response cannot be excluded.
The essential observation described in the present work is that increased intra- and extracellular thiol concentrations modulate heme oxygenase induction by NO donors in cultured endothelial cells. We have previously shown that NO donors considerably increased heme oxygenase activity in cultured vascular endothelial cells resulting in a higher resistance to oxidant damage mediated by hydrogen peroxide (8). In this study we report that co-exposure of SNAP or SNP with various concentrations of N-acetylcysteine, a precursor of glutathione with antioxidant properties, resulted in a dose-dependent decrease of HO-1 activity and expression. In addition, augmented intracellular glutathione levels by preincubation with N-acetylcysteine significantly (p < 0.05) attenuated endothelial heme oxygenase activity by both NO donors. These findings suggest that thiols may have crucial buffering capacities in respect to NO, thereby influencing the ability of this gaseous molecule to affect HO-1 induction.
We also observed a higher nitrite production with SNP and SNAP in the presence of N-acetylcysteine compared with that measured when cells were exposed to NO donors alone. These data are in agreement with other published observations showing that thiols enhance NO generation from NO releasing agents (39, 40). Based on our present findings demonstrating that NO donors stimulate heme oxygenase activity, we expected an even greater increase in the expression of this protein when NO released from SNP or SNAP is enhanced by the presence of thiols; however, that assumption is not borne out by the present evidence that heme oxygenase induction by NO donors is dose-dependently inhibited by N-acetylcysteine. One explanation for this apparent controversy could be that relatively low concentrations of NO stimulate the endothelial stress response until a threshold is reached, above which the amount of NO delivered to the tissue is excessive and its signaling effect is abolished by its potential cytotoxic action. Alternatively, a question arises on the significance of the nitrite assay as to whether this parameter has to be taken merely as an index of NO production or can also be interpreted as a result of the reaction (or product decomposition) between N-acetylcysteine and NO donors. The experiments designed for determining the amount of endogenous glutathione in endothelial cells indicate that the latter possibility is the most likely. When cells were exposed to different concentrations of N-acetylcysteine, we observed a dose-dependent accumulation of intracellular glutathione; this increase was not, however, detected by co-exposure of cells to N-acetylcysteine with SNP or SNAP. Thus, a reaction occurred between N-acetylcysteine and NO donors, and neither the product of the reaction nor the end products of its decomposition were suitable as substrates for glutathione synthesis.
Of major significance to the present work is the reaction of NO with thiol-containing compounds leading to the formation of S-nitrosothiols. In biological systems NO reacts with many target molecules exerting a wide variety of activities and effects (41). S-Nitroso proteins, such as S-nitroso serum albumin and S-nitroso hemoglobin, have been detected in in vivo experimental models, and their potential active role in NO transport and delivery to tissues has been investigated lately (22, 42). Moreover, a recent report emphasizes the importance of S-nitrosylation in activating the transcriptional factor Oxy(R) in bacteria (43), implying that the reaction could also have important signaling functions in mammalian cells. S-Nitrosothiols possess endothelial derived relaxing factor-like properties (44) eliciting many NO activities, and they could be involved in NO metabolism, storage, and possibly its mobilization and transport (24, 44).
The results obtained with the Saville method indicate that, although
for only a transitory period of time, S-nitrosothiols are
one of the products of the reaction between NO donors and N-acetylcysteine (see "Results"). Under the conditions
used in our experiments, N-acetylcysteine might therefore
behave as a transient NO scavenger preventing the expression and
activation of heme oxygenase by SNP and SNAP. These findings suggest
that thiols play an important role in the regulation of heme oxygenase and possibly other heat shock proteins expression by stabilizing "free" NO. However, our data could be simply explained by the fact
that NO, by itself or by interacting with oxygen free radicals, induces
heme oxygenase through an oxidative stress-like mechanism. In this
case, the potential cytotoxic action of NO could be prevented by
increasing the antioxidant defenses
(N-acetylcysteine/glutathione) which, when diminished, are
responsible for triggering the tissue stress response (HO-1 induction).
To test further this hypothesis, we showed that the presence of SOD in
the incubation medium partially reduced the activation of endothelial
heme oxygenase by SNP and SNAP. The attenuating effect of SOD on heme
oxygenase induction was more pronounced in experiments carried out with
SIN-1, which is known to generate stoichiometric amounts of NO and
superoxide anion (O2). These results indicate that, under the
conditions used in our experiments, exogenously and endogenously
produced O
2 may contribute to the modulation of the stress
response in vascular endothelial cells. The release of O
2 in
the extracellular medium of endothelial cells following incubation with
NO donors is expected to favor the formation of peroxynitrite
(ONOO
), a powerful and potentially toxic oxidant that
decomposes at physiological pH to form hydroxyl radical (OH·)
and nitrogen dioxide (NO2·) (18).
Interestingly, exposure of cells to freshly prepared ONOO
produced a concentration-dependent increase in endothelial
heme oxygenase activity. In addition, at the concentration used in our
experiments (150 and 300 µM), ONOO
did not
cause any substantial loss in endothelial cell viability after 6 h
of exposure (data not shown). Taken together these findings suggest a
possible involvement of ONOO
in heme oxygenase induction
and indicate that this effect can be attenuated by preventing the
direct interaction between NO and O
2 using scavengers of these
two radical molecules. Recent findings indicated that
ONOO
, besides being recognized as a mediator of NO
toxicity, may also have physiological activity and induce vascular
relaxation as well as inhibition of platelet aggregation (45, 46). In
addition, the biological activity of ONOO
appears to
involve S-nitrosylation of cellular thiols which may slowly
release NO resulting in accumulation of the second messenger cyclic GMP
(31). Although further investigations are required to establish whether
ONOO
itself and/or other decomposition products
(e.g. OH·, NO2·) are
the actual metabolites participating in the signaling mechanism of HO-1
induction, to our knowledge this is the first evidence showing that
ONOO
formation correlates with increased heme oxygenase
activity in vascular endothelial cells.
The results of this study showing that SNP and SNAP did not produce any
change in the intracellular thiol content support the evidence that NO
and/or its reaction products modulate endothelial heme oxygenase for
their intrinsic properties as signaling molecules and not as a
consequence of glutathione depletion caused by oxidative stress. In
agreement with this concept, we have previously reported that at the
concentrations of SNP, SNAP, and SIN-1 used in our protocol (0.5-1
mM) no relevant cytotoxic effects to endothelial cells were
detected (8). In addition, we observed that in vivo administration of a precursor of the NO releasing agent SIN-1 caused a
rapid increase in hepatic HO-1 mRNA expression and activity, and
this effect was not associated with overt damage to liver tissue (32).
Other authors have reported that the cytotoxic activity of SIN-1, which
mediates the formation of ONOO, occurred in human
epithelial cancer cells at high concentrations (5 mM) and
only 48 h after incubation (47).
We wanted to explore further what effect the specific blockade of NO released by NO donors could have on endothelial heme oxygenase. Hemoglobin, a conventional and widely utilized NO scavenger, was not appropriate for this type of study since, per se, it induces HO-1 (5, 8). EPR spectroscopy studies have lately revealed the capacity of cobalamin species to reversely bind NO (34), and the same compounds have been shown to inhibit relaxation of mouse anococcygeus muscle produced by exogenous NO (48). Based on these pieces of evidence, we incubated cells with SNP or SNAP in medium supplemented with hydroxocobalamin; this treatment, indeed, resulted in a reduction of heme oxygenase activity, reinforcing the hypothesis that NO is required for the activation of HO-1. In addition, we observed that SNAP was more potent at inducing heme oxygenase than equivalent concentrations of GSNO and SNP; these findings are consistent with previous reports showing that SNAP decomposes more rapidly than GSNO (36) and releases more NO than SNP (35).
In summary, we have shown that (a) thiols, both exogenous
and endogenous, are capable of modulating endothelial heme oxygenase activation by NO donors; (b) this modulation is possibly
attributable to NO interaction and stabilization by thiols;
(c) free NO released by NO donors and O2 are
essential messengers for the stimulation of HO-1 expression; and
(d) ONOO
, which is generated from the
interaction of O
2 and NO, increases heme oxygenase activity in
vascular endothelial cells. We propose here a mechanism for a dynamic
equilibrium between NO, glutathione, and O
2 in their ability
to regulate the expression of the stress protein heme oxygenase. Under
physiological conditions a balance exists between NO produced, its
intracellular association with glutathione, and its target proteins and
enzymes. Stress situations, such as oxidative stress and endotoxic
shock, may alter this balance leading to glutathione depletion,
enhanced O
2 formation, and up-regulation of the inducible form
of NO synthase. This effect generates NO and NO derivatives which may
act as intracellular signals to mediate the expression of heme
oxygenase. The induction of this protein would increase endogenous CO,
biliverdin, and bilirubin, all catabolites ultimately implicated in
protective defensive mechanisms against injury (49). Interestingly, a
recent study demonstrated the involvement of NO in the synthesis of
heat-induced HSP70 in rat organs, suggesting that the system of NO
generation plays an important role in both stress and adaptive
responses of the organism (50). Although a full understanding of NO
regulation of oxygen radical-dependent reactions is
required to unravel the exact mechanism underlying heme oxygenase
induction, the data reported herein indicate that glutathione may be
regarded as a fine sensor of the NO-mediated stress response in
vascular endothelial cells.
We are grateful to Dr. Martin Feelisch and Dr. Ivan Sammut for helpful discussion and suggestions.