K Steinbach scite author profile

H2‐forming methylenetetrahydromethanopterin dehydrogenase (Hmd) is an unusual hydrogenase present in many methanogenic archaea. The homodimeric enzyme dubbed ‘metal‐free’ hydrogenase does not contain iron–sulfur clusters or nickel and thus differs from [Ni‐Fe] and [Fe‐Fe] hydrogenases, which are all iron–sulfur proteins. Hmd preparations were found to contain up to 1 mol iron per 40 kDa subunit, but the iron was considered to be a contaminant as none of the catalytic and spectroscopic properties of the enzyme indicated that it was an essential component. Hmd does, however, harbour a low molecular mass cofactor of yet unknown structure. We report here that the iron found in Hmd is most probably functional after all. Further investigation was initiated by the discovery that Hmd is inactivated upon exposure to UV‐A (320–400 nm) or blue‐light (400–500 nm). Enzyme purified in the dark exhibited an absorption spectrum with a maximum at approximately 360 nm and which mirrored its sensitivity towards light. In UV‐A/blue‐light the enzyme was bleached. The cofactor extracted from active Hmd was also light sensitive. It showed an UV/visible spectrum similar to that of the active enzyme and was bleached upon exposure to light. Photobleached cofactor no longer had the ability to reconstitute active Hmd from the apoenzyme. When purified in the dark, Hmd consistently contained per monomer about one Fe, which was tightly bound to the cofactor. The iron was released from the enzyme and from the cofactor upon light inactivation. Hmd activity was inhibited by high concentrations of CO and CO protected the enzyme from light inactivation indicating that the iron in Hmd is of functional importance. Therefore, reference to Hmd as ‘metal‐free’ hydrogenase is no longer appropriate.

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Reductive formation of carbon monoxide from carbon tetrachloride and FREONS 11, 12, and 13 catalyzed by corrinoids

Krone¹,

Thauer²,

Hogenkamp³

et al. 1991

Biochemistry

123

121

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In an earlier publication, we reported that corrinoids catalyze the sequential reduction of CCl4 to CHCl3, CH2Cl2, CH3Cl, and CH4 with titanium(III) citrate as electron donor [Krone, U. E., Thauer, R. K., & Hogenkamp, H. P. C. (1989) Biochemistry 28, 4908-4914]. However, the recovery of these products was less than 50%, indicating that other products were formed. We now report that, under the same experimental conditions, CCl4 is also converted to carbon monoxide. These studies were extended to include FREONs 11, 12, 13, and 14. Corrinoids were found to catalyze the reduction of CFCl3, CF2Cl2, and CF3Cl to CO and, in the case of CFCl3, to a lesser extent, to formate. CF4 was not reduced. The rate of CO and formate formation paralleled that of fluoride release. Both rates decreased in the series CFCl3, CF2Cl2, CCl4, and CF3Cl. The reduction of CFCl3 gave, in addition to CO and formate, CHFCl2, CH2FCl, CH3F, C2F2Cl2, and C2F2Cl4. The product pattern indicates that the corrinoid-mediated reduction of halogenated C1-hydrocarbons involves the intermediacy of dihalocarbenes, which may be a reason why these compounds are highly toxic for anaerobic bacteria.

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The Cofactor of the Iron–Sulfur Cluster Free Hydrogenase Hmd: Structure of the Light‐Inactivation Product

et al. 2004

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Psychoneuroimmunological correlates of persisting sciatic pain in patients who underwent discectomy

Geiss

Váradi

Steinbach

et al. 1997

Neuroscience Letters

123

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Evidence for acyl–iron ligation in the active site of [Fe]-hydrogenase provided by mass spectrometry and infrared spectroscopy

et al. 2012

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[Fe]-hydrogenase catalyzes the reversible heterolytic cleavage of H(2) and stereo-specific hydride transfer to the substrate methenyltetrahydromethanopterin in methanogenic archaea. This enzyme contains a unique iron guanylylpyridinol (FeGP) cofactor as a prosthetic group. It has recently been proposed-on the basis of crystal structural analyses of the [Fe]-hydrogenase holoenzyme-that the FeGP cofactor contains an acyl-iron ligation, the first one reported in a biological system. We report here that the cofactor can be reversibly extracted with acids; its exact mass has been determined by electrospray ionization Fourier transform ion cyclotron resonance mass-spectrometry. The measured mass of the intact cofactor and its gas-phase fragments are consistent with the proposed structure. The mass of the light decomposition products of the cofactor support the presence of acyl-iron ligation. Attenuated total reflection infrared spectroscopy of the FeGP cofactor revealed a band near wave number 1700 cm(-1), which was assigned to the C=O (double bond) stretching mode of the acyl-iron ligand.

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K Steinbach

UV‐A/blue‐light inactivation of the ‘metal‐free’ hydrogenase (Hmd) from methanogenic archaea

Reductive formation of carbon monoxide from carbon tetrachloride and FREONS 11, 12, and 13 catalyzed by corrinoids

The Cofactor of the Iron–Sulfur Cluster Free Hydrogenase Hmd: Structure of the Light‐Inactivation Product

Psychoneuroimmunological correlates of persisting sciatic pain in patients who underwent discectomy

Evidence for acyl–iron ligation in the active site of [Fe]-hydrogenase provided by mass spectrometry and infrared spectroscopy

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