(Received for publication, April 30, 1997)
From the Laboratories of Pharmacology and Chemistry
and ¶ Molecular Carcinogenesis, NIEHS, National Institutes of
Health, Research Triangle Park, North Carolina 27709,
G. D. Searle & Co., St. Louis, Missouri 63167, and
the ** Department of Biochemistry, Vanderbilt University School of
Medicine, Nashville, Tennessee 37232-0146
The determination of protein nitrotyrosine content has become a frequently used technique for the detection of oxidative tissue damage. Protein nitration has been suggested to be a final product of the production of highly reactive nitrogen oxide intermediates (e.g. peroxynitrite) formed in reactions between nitric oxide (NO·) and oxygen-derived species such as superoxide. The enzyme prostaglandin H synthase-2 (PHS-2) forms one or more tyrosyl radicals during its enzymatic catalysis of prostaglandin formation. In the presence of the NO·-generator diethylamine nonoate, the electron spin resonance spectrum of the PHS-2-derived tyrosyl radical is replaced by the spectrum of another free radical containing a nitrogen atom. The magnitude of the nitrogen hyperfine coupling constant in the latter species unambiguously identifies it as an iminoxyl radical, which is likely formed by the oxidation of nitrosotyrosine, a stable product of the addition of NO· to tyrosyl radical. Addition of superoxide dismutase did not alter the spectra, indicating that peroxynitrite was not involved. Western blot analysis of PHS-2 after exposure to the NO·-generator revealed nitrotyrosine formation. The results provide a mechanism for nitric oxide-dependent tyrosine nitration that does not require formation of more highly reactive nitrogen oxide intermediates such as peroxynitrite or nitrogen dioxide.
The detection of nitrotyrosine in proteins or tissues that have been exposed to conditions of oxidative stress is rapidly becoming an assay of choice in the implication of oxidative tissue damage as a mechanism of disease. Nitrotyrosine has been detected in samples from a wide variety of disease states, including acute lung injury (1, 2), atherosclerosis (3, 4), neurodegenerative diseases (5-8), bacterial and viral infections (9-11), aging (12), chronic inflammation (13), and exposure to cigarette smoke (14) or carbon monoxide (15). In most of the above cases, the nitrotyrosine detection was presumed to be the result of the reaction of tyrosine residues with peroxynitrite/peroxynitrous acid. Peroxynitrite is formed in the reaction between nitric oxide (NO·) and superoxide. Recently, however, other mechanisms for the production of nitrotyrosine that are independent of peroxynitrite have been identified (16, 17), raising doubts about the specificity of nitrotyrosine detection as an assay for peroxynitrite (18).
Nitric oxide has been shown to react with the stable tyrosyl radical residue that is involved in the catalytic mechanism of ribonucleotide reductase, quenching the tyrosyl radical signal in the electron spin resonance (ESR) spectrum of the enzyme (19). Nitric oxide, a free radical, is expected to form a radical-radical adduct with organic radicals such as the phenoxyl radical of a tyrosine residue. The inhibition of ribonucleotide reductase and the quenching of its tyrosyl radical ESR spectrum are reversible with time (19-22), suggesting that NO· forms a complex with the radical that can decay back to the radical pair. Oxidation of such a complex, however, would likely lead to the formation of modified tyrosine residues, including nitrotyrosine. Prostaglandin H synthase, like ribonucleotide reductase, has a tyrosine residue oxidized to the corresponding phenoxyl radical during its catalysis. To test the hypothesis that nitrotyrosine can be formed from the NO·-adduct of a tyrosyl radical, the tyrosyl radical formed during the catalytic production of prostaglandins by prostaglandin H synthase-2 was exposed to the nitric oxide-generating compound diethylamine nonoate.
Human prostaglandin H
synthase-2 (PHS-2)1 was expressed in a
baculovirus expression system and purified as the apoprotein (23). Protein concentrations were determined by the method of Bradford (24).
After adjustment of the enzyme concentration to that desired for a
particular experiment, the apoprotein was reconstituted at room
temperature for 10 min with either heme or Mn-heme to a concentration
of 1 heme/subunit. Heme and Mn-heme were dissolved in Me2SO
at sufficient concentration to allow reconstitution of the enzyme with
10 µl of heme stock solution. Protein samples were then frozen and
stored at 70 °C until just before use.
PHS-2 samples were thawed and transferred (sample volume 200 µl) into a 3-mm quartz ESR sample tube using a Hamilton syringe equipped with a long needle. Reactions were performed at room temperature and were initiated by the addition of arachidonic acid (acquired from NuChek Prep, Elysian, MN) at the desired concentration contained in 10 µl of ethanol (arachidonic acid stock solution concentrations varied). After brief mixing with a nichrome wire, the samples were frozen 4 s after addition of arachidonic acid in liquid nitrogen and were transferred to a quartz fingertip Dewar, which was then placed in a TM110 cavity of a Bruker ESP300 ESR spectrometer. Subsequent time points were acquired by thawing the sample to room temperature by immersion in a water bath for the desired interval, followed by refreezing in liquid nitrogen. In that manner, a single sample could be used to follow the time course of the reaction. The NO· donor diethylamine nonoate (DEA/NO; Cayman Chemical, Ann Arbor, MI) was dissolved in water to a concentration of 25 mM immediately before use and was added to the enzyme at a final concentration of 500 µM. Arachidonic acid was added after a 3-min incubation with DEA/NO at room temperature. ESR spectra were acquired using the following instrument settings: modulation amplitude, 1 G; modulation frequency, 100 kHz; time constant, 1.3 s; scan time, 1342 s; receiver gain, 1 × 105 unless otherwise noted. Spectral simulations were calculated using the Powfit program of the NIEHS public ESR software tools package.2 Determination of g values was accomplished by comparison to a Cr3+ in MgO g standard (giso = 1.9800 ± 0.0006) (25).
Western Blot AnalysisPHS-2 was recovered from the ESR sample tubes and was analyzed by Western blot after dilution to 10 µM. Each sample was diluted 1:1 with Laemmli sample buffer, boiled for 5 min, and immediately loaded onto a gel. Samples were run on sodium dodecyl sulfate-polyacrylamide gel electrophoresis and were electrophoretically transferred to pure nitrocellulose membrane in 25 mM Tris, 192 mM glycine, and 20% methanol. Membranes were blocked overnight at 4 °C in Tris-buffered saline containing 0.2% Tween 20 (TBST) with 5% BSA (Life Technologies, Inc.). The blots were then incubated for 1 h with either anti-nitrotyrosine antibody (1 µg/ml) (Upstate Biotechnology Inc., Lake Placid, NY) or anti-human PHS-2 antibody (1:2000) (Oxford Biomedical Research Inc., Oxford, MI) in 1% BSA at room temperature. Blots were then washed five times in TBST with 0.1% BSA, and incubated for 1 h with peroxidase-conjugated anti-rabbit IgG (1:5000 or 1:10000) (Amersham) in 1% BSA at room temperature. The blots were again washed five times in TBST with 0.1% BSA and then visualized using the Enhanced Chemiluminescence detection (ECL) system (Amersham).
The ESR spectrum of PHS-2 acquired 4 s after addition of
arachidonic acid exhibited a single line with a peak-to-trough line width of 27.4 G and with indications of resolved hyperfine structure (Fig. 1, spectrum A), which has been assigned
to a tyrosyl radical residue (26). The ESR spectra obtained after
additional incubation at room temperature maintained the linewidth
observed at the first time point, but the lineshape increased in
doublet character (Fig. 1, spectra B-D). The signal
intensity also decreased at the later time points. No ESR spectrum was
detected in the absence of added arachidonic acid (data not shown).
Inclusion of the NO·-generator DEA/NO in the reaction mixture
resulted in the replacement of the tyrosyl radical spectrum with that
of another species, which exhibited hyperfine coupling to an atom with
a nuclear spin of 1, e.g. a nitrogen atom (Fig. 1, spectrum E). The concentration of this species persisted for
another 10 s at room temperature but decreased to undetectable
levels after further incubation at room temperature (Fig. 1,
spectra G and H). The spectrum detected at 77 K
in the presence of NO· is typical of an immobilized nitroxide,
but the nitrogen hyperfine coupling constants were much larger than
those of simple nitroxides, approximately A = 39 G and A
= 20 G (see Fig.
2). The magnitude of the isotropic nitrogen hyperfine
coupling constant (aiso = (A
+ 2A
)/3 = 26.3 G) identifies the free radical detected in the presence of
NO· as an iminoxyl radical (27). The spectrum was simulated
starting with the nitrogen hyperfine coupling constants measured from
the spectrum by inspection. Slight variations of the hyperfine coupling constants by the computer program to minimize the difference between the experimental and the calculated spectra gave a best-fit simulation with the following parameters: Ax = 19.9 G,
Ay = 23.7 G, and Az = 40.1 G
(Aiso = 27.9 G); gx = 2.0078, gy = 2.0053, gz = 2.0042 (the
simulation is presented in Fig. 2). In some experiments the ESR spectra
obtained from samples that had been exposed to DEA/NO exhibited
characteristics of both the tyrosyl radical and the iminoxyl radical
discussed above, with the iminoxyl radical becoming the dominant
species after longer room temperature incubations. The use of lower
concentrations of DEA/NO resulted in correspondingly increased tyrosyl
radical character of the ESR spectra (data not shown). Depletion of the DEA/NO stock solution by overnight incubation at room temperature (16 h) before use prevented iminoxyl radical formation (data not shown).
Peroxynitrite forms in the reaction between superoxide and NO· under physiological conditions (28). To eliminate the possibility that the iminoxyl radical formation arose from a reaction involving peroxynitrite, superoxide dismutase was added to the reaction mixture to prevent peroxynitrite formation. Inclusion of 1000 units/ml superoxide dismutase in the reaction mixture did not modify either the ESR spectrum or the kinetics of its changes as a function of time in the NO· experiments (data not shown).
Reconstitution of PHS-2 with manganese-heme rather than iron-heme
results in a protein that retains cyclooxygenase activity but has
greatly decreased peroxidase activity (29). Some published evidence has
suggested the formation of an enzymatic tyrosyl radical during the
catalysis of Mn-PHS-1 (29), but that suggestion has not been supported
with unequivocal ESR data (30, 31). To test whether tyrosyl radicals
are formed in the Mn-enzyme and to determine whether iminoxyl radical
formation is a more general phenomenon upon exposure of tyrosyl
radicals to NO·, the experiments were repeated with Mn-PHS-2.
Addition of arachidonic acid to PHS-2 that had been reconstituted with
manganese-heme resulted in the generation of an ESR spectrum with a
peak-to-trough linewidth of 30 G (Fig. 3) and a g value
of 2.005, which is slightly lower than that of the tyrosyl radical of
Fe-PHS (2.006). No hyperfine structure was resolved in the ESR spectrum
of Mn-PHS-2 (Fig. 3, spectra A-E). Previous experiments
have indicated that the signal arises from multiple radicals (30).
Upon reaction of Mn-PHS with arachidonic acid in the presence of
DEA/NO, the ESR spectrum of the protein is much less intense than the
spectrum obtained from Mn-PHS-2 in the absence of DEA/NO (12 ± 6% of the integrated area of the Mn-PHS-2 spectrum). Increasing intensity in the low field region of the spectrum is observed upon
longer incubation at room temperature, with the spectrum detected after
3 min strongly resembling the iminoxyl radical spectrum observed with
Fe-PHS (Fig. 3, spectra F-K). Apparently, the tyrosyl and
the tyrosine iminoxyl radicals coexist at intermediate time points. As
was the case with Fe-PHS-2 in the presence of DEA/NO, hyperfine
coupling to a nitrogen atom with A ~ 38 G
and A
~ 22 G (compare with 39 and 20 G, respectively, for Fe-PHS) was observed, consistent with iminoxyl radical formation. The greater linewidth of the ESR signal detected from Mn-PHS-1 (29, 30)
has been suggested to arise from magnetic coupling between the
paramagnetic manganese heme system and the radical (31). This proposal
is consistent with the greater linewidth observed in the iminoxyl
radical detected from Mn-PHS-2.
The conversion of the tyrosyl radical to an iminoxyl radical to
ESR-silent products in Fe-PHS-2 suggests a continuing series of
oxidations. The 1-electron oxidation of an iminoxyl radical would lead
to nitrotyrosine residues in PHS-2. To test this hypothesis, both
Fe-PHS-2 and Mn-PHS-2 samples, subsequent to the ESR studies, were
subjected to Western analysis using an antibody specific for
nitrotyrosine. A triplet staining pattern was observed for both the
Fe-PHS-2 and Mn-PHS-2 samples that were exposed to NO· at the
appropriate molecular weight for human PHS-2 (Fig. 4). Furthermore, the triplet band was also detected in the Fe-PHS-2 with
NO· sample in the presence of superoxide dismutase (Fig. 4).
Increasing the concentration of superoxide dismutase from 6 µM to 1 mM did not prevent nitrotyrosine
formation (data not shown). However, no nitrotyrosine was detected in
the samples that had not been exposed to NO· (Fig. 4). This is
consistent with the nitration of one or more tyrosine residues on the
protein. The triplet band observed is due to the differential
glycosylation states of the protein (32). The blots were then stripped
and reprobed with an anti-human PHS-2 antibody (data not shown). PHS
protein was observed in all lanes at the same molecular weight as the
nitrotyrosine proteins detected for both the Fe- and Mn-PHS samples,
indicating that the nitrated proteins observed are indeed PHS-2. The
detection of nitrotyrosine in the Mn-PHS samples in the Western blot
indicates that at least part of the ESR signal observed in the absence
of NO· arises from a tyrosyl radical (Fig. 3,
A-E).
The free radical signal detected in the presence of the NO·-donor can be identified as an iminoxyl radical by the magnitude of its isotropic hyperfine coupling constant (27.9 G), which is substantially greater than the 15-16 G normally seen for aminoxyl nitroxides (>NO·) but is similar to those normally seen for iminoxyl radicals (>C=NO·) (33, 34). The relatively large hyperfine coupling constant has been suggested to result from a relatively localized electron density on the nitrogen atom (33). The detected Aiso is markedly similar to the value of 26.12 G detected from the product of the oxidation of 2-nitroso-4-methylphenol, a reasonable analog of tyrosine (27).
The combination of the ESR experiments in which an iminoxyl radical is
detected and the Western analysis for nitrotyrosine residues in PHS-2
strongly suggests the mechanism outlined in Scheme 1.
The reaction occurring between the PHS tyrosyl radical and NO·
results in the formation of an ESR-silent diamagnetic adduct, and has
been shown to occur with free tyrosyl radical at a rate that is nearly
diffusion controlled (35). Formation of the ESR-silent complex between
NO· and tyrosyl radical shown in Scheme 1 has also been
demonstrated in photosystem II (36) and ribonucleotide reductase (19). The initial complex formed between tyrosyl radical and NO· can
be decomposed back to tyrosyl radical and NO· in photosystem II
by evacuation of the sample, which effectively removes NO· (35).
Rearrangement of the initial, reversible adduct between the tyrosyl
radical and NO· to form 3-nitrosotyrosine, as shown in the
scheme, results in the rearomatization of the system, and as such is
highly energetically favored even if it is somewhat slow kinetically
due to the required breakage of a C-H bond (37). The proposal that
3-nitrosotyrosine can decompose to form nitric oxide and tyrosyl
radical (35) is mistaken in that the cleavage of the C-N bond would
form a radical rather than the
-phenoxyl tyrosyl radical.
The 1-electron oxidation of the minor oxime tautomer of nitrosotyrosine shown in Scheme 1 (38, 39) results in the formation of the iminoxyl radical that is detected. Iminoxyl radicals have been chemically synthesized by oxidation of the corresponding oximes (33, 34). Free nitrosophenols and nitrosonaphthols have been shown to be oxidized to the corresponding iminoxyl radicals both chemically (27) and with horseradish peroxidase (40). Iminoxyl radical formation has also been detected in the photosystem II system, although the time scale for iminoxyl radical formation is hours instead of seconds in that system (37).
Further oxidation of the tyrosine iminoxyl radical results in the formation of nitrotyrosine, an ESR-silent product that was detected in Western blots. The source of the oxidizing equivalents for the oxidations of nitrosotyrosine and its corresponding iminoxyl radical has not been identified. The strongly oxidizing peroxidase activity of PHS-2 represents one reasonable source. This conclusion is supported by the data from the Mn-substituted enzyme, in which the conversion of the tyrosyl radical to the iminoxyl radical is greatly slowed (compare Fig. 1 with Fig. 3) since the Mn-enzyme has only 4% of the peroxidase activity of the Fe-enzyme (28), but other oxidants such as nitrogen dioxide may also be important and have not been excluded.
The recently reported detection of a tyrosine iminoxyl radical resulting from the reaction between the tyrosyl radical of photosystem II and NO· (37) and our evidence for tyrosine nitration via an iminoxyl radical in PHS-2 provide at least two examples of this chemistry in biological systems. The absence of inhibition of tyrosine nitration by the addition of a large concentration of superoxide dismutase indicates that the superoxide-dependent peroxynitrite/peroxynitrous acid is not involved in tyrosine nitration by NO· in PHS-2.
There are numerous reports of tyrosyl radical formation in different systems throughout biology. In addition to the unstable tyrosyl radical of prostaglandin H synthase (41), stable tyrosyl radicals in ribonucleotide reductase and photosystem II (42, 43) have been detected. Furthermore, tyrosyl radicals have been detected in oxidatively damaged hemoproteins such as myoglobin (44), hemoglobin (45), and cytochrome c (46). Since NO· is made by a variety of cell types, the opportunity for tyrosine iminoxyl free radical formation exists in any protein where tyrosyl radical formation occurs, making this a potentially general mechanism for tyrosine nitration.