Characterization of a quinone reductase activity for the mitomycin C binding protein (MRD): Functional switching from a drug-activating enzyme to a drug-binding protein

He, Min; Sheldon, Paul J.; Sherman, David H.

doi:10.1073/pnas.98.3.926

Cited by 27 publications

(11 citation statements)

References 20 publications

(14 reference statements)

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“…This NADH requirement led to the discovery that Mrd can, in fact, act as a weak activator of 19 through the Mrd-dependent generation of 1,2-cis-1-hydroxy-2,7-diaminomitosene, a compound that is produced in the reductive 19 activation cascade. 243 The finding of a 19-activating activity appeared to be conflicting with the previously identified protective effect of Mrd. However, the reductive reaction catalyzed by Mrd is slow and results in a prolonged association of 19 and its corresponding reduced product with the protein.…”

Section: Resistance By the Producing Organismsmentioning

confidence: 86%

“…Further characterization revealed that Mrd was able to reversibly bind and sequester 19 with no observable antibiotic modification. 243 However, Mrd was shown to require NADH to exert its protective drugbinding function. This NADH requirement led to the discovery that Mrd can, in fact, act as a weak activator of 19 through the Mrd-dependent generation of 1,2-cis-1-hydroxy-2,7-diaminomitosene, a compound that is produced in the reductive 19 activation cascade.…”

Section: Resistance By the Producing Organismsmentioning

confidence: 99%

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Antitumor Antibiotics: Bleomycin, Enediynes, and Mitomycin

et al. 2005

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Section: Resistance By the Producing Organismsmentioning

confidence: 86%

Section: Resistance By the Producing Organismsmentioning

confidence: 99%

Antitumor Antibiotics: Bleomycin, Enediynes, and Mitomycin

et al. 2005

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“…In order to rationalize the intricate electronic interactions between transition metal ions and quinone redox systems in biochemical environments, there have been considerable investigations at the molecular level of metal complexes with O,O′-chelating o -quinonoid ligands, particularly in assigning the valence state distribution at the metal−quinone interface . However, despite the biochemical significance, , far fewer results have been reported for the coordination chemistry of p -quinonoid ligands, , including those with combined o , p -quinone functions. − The present study is aimed at exploring the electronic structural aspects of two diastereomeric diruthenium compounds, [(acac) 2 Ru(μ-L)Ru(acac) 2 ], 1 and 2 (Scheme ), where L 2− is the two-electron-reduced p -quinonoid ligand 1,4-dioxido-2,3-bis(3,5-dimethylpyrazol-1′-yl)benzene and acac − = acetylacetonate = 2,4-pentanedionate. Although 1,4-dioxido-2,5-bis(pyrazol-1′-yl)benzene, (L′) 2− , has been used previously for the formation of polynuclear complexes, − including [(bpy) 2 Ru(μ-L′)Ru(bpy) 2 ] n , the new compounds 1 and 2 represent the first set of polynuclear metal complexes bridged by L 2− .…”

Section: Introductionmentioning

confidence: 99%

“…However, para -quinones (Chart ) such as vitamin K derivatives, ubiquinones, or plastoquinones also play many important roles in energy conversion (photosynthesis, respiration) and information transfer. , …”

Section: Introductionmentioning

confidence: 99%

Intramolecular Valence and Spin Interaction inmesoandracDiastereomers of ap-Quinonoid-Bridged Diruthenium Complex

Kumbhakar

Sarkar²,

Maji³

et al. 2008

J. Am. Chem. Soc.

110

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The complexes meso- and rac-[(acac)2Ru(mu-L)Ru(acac)2]n, 1 and 2, where L(2-) = 1,4-dioxido-2,3-bis(3,5-dimethylpyrazol-1'-yl)benzene and acac- = 2,4-pentanedionato, were characterized structurally, magnetically, electrochemically, and spectroscopically as well as spectroelectrochemically (UV-vis-NIR, EPR) in the accessible redox states (n = 0, +, -, 2-). Due to steric interference, the neutral compounds contain a severely twisted L(2-) bridging ligand with 43-48 degree dihedral angles between the planes of the hydroquinone dianion and those of the ortho positioned pyrazolyl substituents. The difference between meso and rac isomers is rather pronounced in terms of the redox potentials (easier oxidation and reduction of the rac form 2) and with respect to the absorption spectra of the oxidized states. Susceptibility and EPR measurements confirm the {Ru(III)(mu-L(2-))Ru(III)} configuration of the neutral species, showing J values of -37 and -21 cm(-1) for the spin-spin interaction between the ca. 7.75 A separated metal centers in 1 and 2, respectively. Two-step reduction involves the metals and produces Ru(III)Ru(II) mixed-valent monoanions with comproportionation constants of ca. 10(4), with Ru(III)-type EPR signals, and with broad intervalence charge transfer bands at about 1200-1500 nm absorption maximum, suggesting localized valence (class II). Oxidation produces intense near-infrared absorption at 892 (1+) or 1027 nm (2+) and narrow isotropic EPR spectra at g approximately 2.005, signifying unprecedented spin localization at the p-semiquinone bridge. These results are not compatible with an (L(2-))-bridged {Ru(IV)Ru(III)} situation nor with an {Ru(III)(mu-L(*-))Ru(III)} three-spin arrangement with up-down-up spin configuration in the ground state, which would result in metal-centered spin through antiferromagnetic coupling between the adjacent individual spins. Only the {Ru(III)(mu-L(*-))Ru(III)} situation, with up-up-down spin configuration, leads to ligand-centered resulting spin through the strong antiferromagnetic coupling between the remote metal spins, an unusual situation which is favored here because of weakened metal-radical coupling resulting from the pyrazolyl/p-semiquinone twist.

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“…The donor substituents (O or N) at the 1,4 positions may combine with the quinone oxygen atoms to create a bis(chelate) situation with a noninnocent bridge for dimetal coordination. The combination of various accessible valence states of biochemically relevant noninnocent quinonoid systems (Q 0 = quinone, Q •– = semiquinonate, Q 2– = catecholate) and of ruthenium (Ru II , Ru III , Ru IV ) can result in complex valence and spin distribution patterns at the metal–ligand interface . Close lying and efficiently mixing frontier orbitals are responsible for this behavior, and the high degree of covalent bonding can even preclude specific oxidation state descriptions .…”

Section: Introductionmentioning

confidence: 99%

Sensitivity of the Valence Structure in Diruthenium Complexes As a Function of Terminal and Bridging Ligands

et al. 2014

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The compounds [(acac)2Ru(III)(μ-H2L(2-))Ru(III)(acac)2] (rac, 1, and meso, 1') and [(bpy)2Ru(II)(μ-H2L(•-))Ru(II)(bpy)2](ClO4)3 (meso, [2](ClO4)3) have been structurally, magnetically, spectroelectrochemically, and computationally characterized (acac(-) = acetylacetonate, bpy = 2,2'-bipyridine, and H4L = 1,4-diamino-9,10-anthraquinone). The N,O;N',O'-coordinated μ-H2L(n-) forms two β-ketiminato-type chelate rings, and 1 or 1' are connected via NH···O hydrogen bridges in the crystals. 1 exhibits a complex magnetic behavior, while [2](ClO4)3 is a radical species with mixed ligand/metal-based spin. The combination of redox noninnocent bridge (H2L(0) → → → →H2L(4-)) and {(acac)2Ru(II)} → →{(acac)2Ru(IV)} or {(bpy)2Ru(II)} → {(bpy)2Ru(III)} in 1/1' or 2 generates alternatives regarding the oxidation state formulations for the accessible redox states (1(n) and 2(n)), which have been assessed by UV-vis-NIR, EPR, and DFT/TD-DFT calculations. The experimental and theoretical studies suggest variable mixing of the frontier orbitals of the metals and the bridge, leading to the following most appropriate oxidation state combinations: [(acac)2Ru(III)(μ-H2L(•-))Ru(III)(acac)2](+) (1(+)) → [(acac)2Ru(III)(μ-H2L(2-))Ru(III)(acac)2] (1) → [(acac)2Ru(III)(μ-H2L(•3-))Ru(III)(acac)2](-)/[(acac)2Ru(III)(μ-H2L(2-))Ru(II)(acac)2](-) (1(-)) → [(acac)2Ru(III)(μ-H2L(4-))Ru(III)(acac)2](2-)/[(acac)2Ru(II)(μ-H2L(2-))Ru(II)(acac)2](2-) (1(2-)) and [(bpy)2Ru(III)(μ-H2L(•-))Ru(II)(bpy)2](4+) (2(4+)) → [(bpy)2Ru(II)(μ-H2L(•-))Ru(II)(bpy)2](3+)/[(bpy)2Ru(II)(μ-H2L(2-))Ru(III)(bpy)2](3+) (2(3+)) → [(bpy)2Ru(II)(μ-H2L(2-))Ru(II)(bpy)2](2+) (2(2+)). The favoring of Ru(III) by σ-donating acac(-) and of Ru(II) by the π-accepting bpy coligands shifts the conceivable valence alternatives accordingly. Similarly, the introduction of the NH donor function in H2L(n) as compared to O causes a cathodic shift of redox potentials with corresponding consequences for the valence structure.

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Characterization of a quinone reductase activity for the mitomycin C binding protein (MRD): Functional switching from a drug-activating enzyme to a drug-binding protein

Cited by 27 publications

References 20 publications

Antitumor Antibiotics: Bleomycin, Enediynes, and Mitomycin

Antitumor Antibiotics: Bleomycin, Enediynes, and Mitomycin

Intramolecular Valence and Spin Interaction inmesoandracDiastereomers of ap-Quinonoid-Bridged Diruthenium Complex

Sensitivity of the Valence Structure in Diruthenium Complexes As a Function of Terminal and Bridging Ligands

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