Isocyanide or nitrosyl complexation to hemes with varying tethered axial base ligand donors: synthesis and characterization

Sharma, Savita K.; Kim, Hyun; Rogler, Patrick J.; Siegler, Maxime A.; Karlin, Kenneth D.

doi:10.1007/s00775-016-1369-4

Cited by 8 publications

(15 citation statements)

References 64 publications

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“…Under these conditions, we also do not observe formation of any ferrous/ferric nitrosyl complex. As we have shown earlier, the ferrous nitrosyl 31 complex has characteristic UV–vis and EPR spectroscopic features, shown in Figure S9.…”

Section: Resultssupporting

confidence: 68%

“…For peroxynitrite binding to a metal ion, several possible binding modes and conformations must be considered, including N atom 11 vs O atom ligation, cis vs trans isomers (Figure 6a and b, respectively), and even O,O′-chelation. 31 Peroxynitrite N-binding to a heme-Fe(III) has been proposed based on theoretical calculations, 13 but peroxo anion O atom binding is observed experimentally (and supported by DFT calculations) for several porphyrinate cobalt(III)-peroxynitrite complexes. 19a …”

Section: Resultsmentioning

confidence: 97%

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A Six-Coordinate Peroxynitrite Low-Spin Iron(III) Porphyrinate Complex—The Product of the Reaction of Nitrogen Monoxide (·NO_(g)) with a Ferric-Superoxide Species

et al. 2017

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Peroxynitrite (−OON═O, PN) is a reactive nitrogen species (RNS) which can effect deleterious nitrative or oxidative (bio)chemistry. It may derive from reaction of superoxide anion (O2•−) with nitric oxide (·NO) and has been suggested to form an as-yet unobserved bound heme-iron-PN intermediate in the catalytic cycle of nitric oxide dioxygenase (NOD) enzymes, which facilitate a ·NO homeostatic process, i.e., its oxidation to the nitrate anion. Here, a discrete six-coordinate low-spin porphyrinate-FeIII complex [(PIm)-FeIII(−OON═O)] (3) (PIm; a porphyrin moiety with a covalently tethered imidazole axial “base” donor ligand) has been identified and characterized by various spectroscopies (UV–vis, NMR, EPR, XAS, resonance Raman) and DFT calculations, following its formation at −80 °C by addition of ·NO(g) to the heme-superoxo species, [(PIm)FeIII(O2•−)] (2). DFT calculations confirm that 3 is a six-coordinate low-spin species with the PN ligand coordinated to iron via its terminal peroxidic anionic O atom with the overall geometry being in a cis-configuration. Complex 3 thermally transforms to its isomeric low-spin nitrato form [(PIm)FeIII(NO3−)] (4a). While previous (bio)chemical studies show that phenolic substrates undergo nitration in the presence of PN or PN-metal complexes, in the present system, addition of 2,4-di-tert-butylphenol (2,4DTBP) to complex 3 does not lead to nitrated phenol; the nitrate complex 4a still forms. DFT calculations reveal that the phenolic H atom approaches the terminal PN O atom (farthest from the metal center and ring core), effecting O–O cleavage, giving nitrogen dioxide (·NO2) plus a ferryl compound [(PIm)FeIV═O] (7); this rebounds to give [(PIm)FeIII(NO3−)] (4a).The generation and characterization of the long sought after ferriheme peroxynitrite complex has been accomplished.

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Section: Resultssupporting

confidence: 68%

Section: Resultsmentioning

confidence: 97%

A Six-Coordinate Peroxynitrite Low-Spin Iron(III) Porphyrinate Complex—The Product of the Reaction of Nitrogen Monoxide (·NO_(g)) with a Ferric-Superoxide Species

et al. 2017

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“…The nature and type of interaction with axial ligand has been previously demonstrated to effect the level of NO activation in mononuclear Fe complexes. 16 Analogous shifts in the distance between Fe and axial ligands trans to coordinated N 2 have been reported for monoiron models of nitrogenase. 17 …”

Section: Resultsmentioning

confidence: 53%

Tetranuclear Fe Clusters with a Varied Interstitial Ligand: Effects on the Structure, Redox Properties, and Nitric Oxide Activation

Reed

Agapie

2017

Inorg. Chem.

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A new series of tetranuclear iron clusters displaying an interstitial μ4-F ligand was prepared for comparison to μ4-O analogs. With a single NO coordinated as a reporter of small molecule activation, the μ4-F clusters were characterized in five redox states, from FeII3{FeNO}8 to FeIII3{FeNO}7, with N–O stretching frequencies ranging from 1680 cm−1 to 1855 cm−1, respectively. Despite accessing more reduced states with an F− bridge, a two electron reduction of the distal Fe centers is necessary for the μ4-F clusters to activate NO to the same degree as the μ4-O system; consequently, NO reactivity is observed at more positive potentials with μ4-O than μ4-F. Moreover, the μ4-O ligand better translates redox changes of remote metal centers to diatomic ligand activation. The implication for biological active sites is that the higher charge bridging ligand is more effective in tuning cluster properties, including the involvement of remote metal centers, for small molecule activation

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“…The ferrous heme complex, [(THF) 2 (TPP)Fe II ], exhibited significant electronic absorption perturbations from 426 (Soret; ε = 16 × 10 5 M –1 cm –1 ), 536 (ε = 6.2 × 10 4 M –1 cm –1 ) and 558 (ε = 6.5 × 10 4 M –1 cm –1 ) nm to 416 (Soret; ε = 10 × 10 5 M –1 cm –1 ), and 540 (ε = 9.0 × 10 4 M –1 cm –1 ) nm in 9:1 DCM:THF solvent mixture at −80 °C upon the bubbling of dry O 2(g) , indicating the formation of the EPR-silent, end-on ferric superoxo species, [(THF)(TPP)Fe III (O 2 –• )] (Figure A,B). , Isotope-sensitive ν(Fe–O) and ν(O–O) resonance Raman frequencies for this species were centered at 579 (Δ 18 O 2 = −26) and 1170 (Δ 18 O 2 = −60) cm –1 , respectively (Figure C). Subsequent addition of 2 equiv of 4 methylimidazole (Im) led to the formation of the Im-coordinated superoxo adduct, [(Im)(TPP)Fe III (O 2 –• )] (418 (Soret; ε = 7.5 × 10 5 M –1 cm –1 ) and 543 (ε = 6.5 × 10 4 M –1 cm –1 ) nm); − ν(Fe–O): 577 (Δ 18 O 2 = −23) and ν(O–O): 1170 (Δ 18 O 2 = −56) cm –1 (Figure D). − Similarly, the rest of the ferric superoxo compound series was prepared and characterized: [(THF)(F 20 TPP)Fe III (O 2 –• )], [(Im)(F 20 TPP)Fe III (O 2 –• )], [(THF)(TMPP)Fe III (O 2 –• )] and [(Im)(TMPP)Fe III (O 2 –• )] (Figures S1 and S2). …”

Section: Resultsmentioning

confidence: 99%

Modeling Tryptophan/Indoleamine 2,3-Dioxygenase with Heme Superoxide Mimics: Is Ferryl the Key Intermediate?

Mondal

Wijeratne

2019

J. Am. Chem. Soc.

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Tryptophan oxidation in biology has been recently implicated in a vast array of paramount pathogenic conditions in humans, including multiple sclerosis, rheumatoid arthritis, type-I diabetes, and cancer. This 2,3dioxygenative cleavage of the indole ring of tryptophan with dioxygen is mediated by two heme enzymes, tryptophan 2,3-dioxygenase (TDO) and indoleamine 2,3-dioxygenase (IDO), during its conversion to Nformylkynurenine in the first and rate-limiting step of kynurenine pathway. Despite the pivotal significance of this enzymatic transformation, a vivid viewpoint of the precise mechanistic events is far from complete. A heme superoxide adduct is thought to be the active oxidant in both TDO and IDO, which, following O−O bond cleavage, presumably generates a key ferryl (Fe IV =O) reaction intermediate. This study, for the first time in model chemistry, demonstrates the potential of synthetic heme superoxide adducts to mimic the bioinorganic chemistry of indole dioxygenation by TDO and IDO, challenging the widely accepted categorization of these metal adducts as weak oxidants. Herein, an electronically divergent series of ferric heme superoxo oxidants mediates the facile conversion of an array of indole substrates into their corresponding 2,3-dioxygenated products, while shedding light on an unequivocally occurring, putative ferryl intermediate. The oxygenated indole products have been isolated in ∼31% yield, and characterized by LC-MS, 1 H and 13 C NMR, and FT-IR methodologies, as well as by 18 O 2(g) labeling experiments. Distinctly, the most electron-deficient superoxo adduct is observed to react the fastest, specifically with the most electron-rich indole substrate, underscoring the cruciality of electrophilicity of the heme superoxide moiety in facilitating the initial indole activation step. Comprehensive understanding of such mechanistic subtleties will benefit future attempts in the rational design of salient therapeutic agents, including next generation anticancer drug targets with amplified effectivity.

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Isocyanide or nitrosyl complexation to hemes with varying tethered axial base ligand donors: synthesis and characterization

Cited by 8 publications

References 64 publications

A Six-Coordinate Peroxynitrite Low-Spin Iron(III) Porphyrinate Complex—The Product of the Reaction of Nitrogen Monoxide (·NO_(g)) with a Ferric-Superoxide Species

A Six-Coordinate Peroxynitrite Low-Spin Iron(III) Porphyrinate Complex—The Product of the Reaction of Nitrogen Monoxide (·NO_(g)) with a Ferric-Superoxide Species

Tetranuclear Fe Clusters with a Varied Interstitial Ligand: Effects on the Structure, Redox Properties, and Nitric Oxide Activation

Modeling Tryptophan/Indoleamine 2,3-Dioxygenase with Heme Superoxide Mimics: Is Ferryl the Key Intermediate?

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Isocyanide or nitrosyl complexation to hemes with varying tethered axial base ligand donors: synthesis and characterization

Cited by 8 publications

References 64 publications

A Six-Coordinate Peroxynitrite Low-Spin Iron(III) Porphyrinate Complex—The Product of the Reaction of Nitrogen Monoxide (·NO(g)) with a Ferric-Superoxide Species

A Six-Coordinate Peroxynitrite Low-Spin Iron(III) Porphyrinate Complex—The Product of the Reaction of Nitrogen Monoxide (·NO(g)) with a Ferric-Superoxide Species

Tetranuclear Fe Clusters with a Varied Interstitial Ligand: Effects on the Structure, Redox Properties, and Nitric Oxide Activation

Modeling Tryptophan/Indoleamine 2,3-Dioxygenase with Heme Superoxide Mimics: Is Ferryl the Key Intermediate?

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A Six-Coordinate Peroxynitrite Low-Spin Iron(III) Porphyrinate Complex—The Product of the Reaction of Nitrogen Monoxide (·NO_(g)) with a Ferric-Superoxide Species

A Six-Coordinate Peroxynitrite Low-Spin Iron(III) Porphyrinate Complex—The Product of the Reaction of Nitrogen Monoxide (·NO_(g)) with a Ferric-Superoxide Species