1988
DOI: 10.1021/bi00403a026
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Nitric oxide adducts of the binuclear iron site of hemerythrin: spectroscopy and reactivity

Abstract: Nitric oxide forms adducts with the binuclear iron site of hemerythrin (Hr) at [Fe(II),Fe(II)]deoxy and [Fe(II),Fe(III)]semimet oxidation levels. With deoxyHr our results establish that (i) NO binds reversibly, forming a complex which we label deoxyHrNO, (ii) NO forms a similar but distinct complex in the presence of fluoride, which we label deoxyHrFNO, (iii) NO is directly coordinated to one iron atom of the binuclear pair in these adducts, most likely in a bent end-on fashion, and (iv) the iron atoms in the … Show more

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Cited by 62 publications
(75 citation statements)
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“…The only other vibrational data for a biological {FeNO} 7 unit come from resonance Raman studies of the NO adduct of deoxyhemerythrin by using 647-nm excitation. Although the (N-O) stretching mode was not observed, a band at 433 cm Ϫ1 and a weak shoulder at 421 cm Ϫ1 were assigned to the (Fe-NO) and ␦(Fe-N-O) modes, respectively, of the {FeNO} 7 unit, based on 6-7 cm Ϫ1 15 NO and N 18 O downshifts (29). The frequencies of the (Fe-NO) modes dictate a substantially weaker Fe-NO bond in hemerythrin than in SOR, and this is likely to be a consequence of a strong H-bonding interaction between the bent FeNO and the -hydroxo bridge of the diiron center (29).…”
Section: Discussionmentioning
confidence: 92%
See 1 more Smart Citation
“…The only other vibrational data for a biological {FeNO} 7 unit come from resonance Raman studies of the NO adduct of deoxyhemerythrin by using 647-nm excitation. Although the (N-O) stretching mode was not observed, a band at 433 cm Ϫ1 and a weak shoulder at 421 cm Ϫ1 were assigned to the (Fe-NO) and ␦(Fe-N-O) modes, respectively, of the {FeNO} 7 unit, based on 6-7 cm Ϫ1 15 NO and N 18 O downshifts (29). The frequencies of the (Fe-NO) modes dictate a substantially weaker Fe-NO bond in hemerythrin than in SOR, and this is likely to be a consequence of a strong H-bonding interaction between the bent FeNO and the -hydroxo bridge of the diiron center (29).…”
Section: Discussionmentioning
confidence: 92%
“…However, these intermediates are short lived and difficult to study experimentally. Nitric oxide (NO) has been extensively used as a substrate analog of molecular oxygen to form stable nitrosyl derivatives that provide insight into oxygen transport and activation intermediates in many heme (18)(19)(20)(21) and nonheme (22)(23)(24)(25)(26)(27)(28)(29) iron enzymes. Hence, we report here the formation and spectroscopic characterization of a stable NO-bound derivative of the reduced 1Fe-SOR from P. furiosus using the combination of EPR, UV-visible absorption, and variable-temperature, variable-field magnetic CD (VTVH MCD), resonance Raman, and Fourier transform IR (FTIR) spectroscopies.…”
mentioning
confidence: 99%
“…On a time scale basis, scavenging of R2-Y ⅐ by ⅐ NO occurred first, followed by a slower release of iron from the protein. A direct effect of ⅐ NO on the iron center of mouse R2 is unlikely, as it has been previously shown that the -oxo-bridged diferric center of hemerythrin and bacterial protein R2 do not react with NO (24,45,46). Reduction of Fe 3ϩ has been previously shown to accelerate iron loss from mouse protein R2, since Fe 2ϩ loosely binds to the protein (32).…”
Section: Discussionmentioning
confidence: 99%
“…In contrast, bacterial MarR family transcriptional regulators typically regulate antibiotic resistance, virulence, and oxidative stress (60). Hemerythrins are di-iron-containing proteins that can reversibly bind oxygen or nitric oxide (43). These annotations suggest that the PAE2679-PAE2680 operon encodes a transcriptional regulator that controls either stress responses or denitrification genes in response to nitric oxide.…”
Section: Fig 2 (A To E)mentioning
confidence: 99%