Dinuclear nickel complexes modeling the structure and function of the acetyl CoA synthase active site

Ito, Misako; Kotera, Mai; Matsumoto, Tsuyoshi; Tatsumi, Kazuyuki

doi:10.1073/pnas.0900433106

Cited by 48 publications

(48 citation statements)

References 39 publications

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“…Where these electrons reside on the A-cluster is uncertain; indeed the location of these two electrons has been a decade-old puzzle that has not been resolved. One possibility is that both electrons localize on Ni p II to afford a d 10 Ni p 0 species [56 - 59]. Alternatively, one electron may localize on Ni p II and the other on the [Fe 4 S 4 ] 2+ cluster to afford a {Ni p I :[Fe 4 S 4 ] 1+ } spin-coupled structure.…”

Section: 4 Evidence For M-m Bonds In Metalloenzymesmentioning

confidence: 99%

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Metal–metal bonds in biology

Lindahl

2012

Journal of Inorganic Biochemistry

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Nickel-containing carbon monoxide dehydrogenases, acetyl-CoA synthases, nickel-iron hydrogenases, and diron hydrogenases are distinct metalloenzymes yet they share a number of important characteristics. All are O2-sensitive, with active-sites composed of iron and/or nickel ions coordinated primarily by sulfur ligands. In each case, two metals are juxtaposed at the “heart” of the active site, within range of forming metal-metal bonds. These active-site clusters exhibit multielectron redox abilities and must be reductively activated for catalysis. Reduction potentials are milder than expected based on formal oxidation state changes. When reductively activated, each cluster attacks an electrophilic substrate via an oxidative addition reaction. This affords a two-electron-reduced substrate bound to one or both metals of an oxidized cluster. M-M bonds have been established in hydrogenases where they serve to initiate the oxidative addition of protons and perhaps stabilize active sites in multiple redox states. The same may be true of the CODH and ACS active sites – Ni-Fe and Ni-Ni bonds in these sites may play critical roles in catalysis, stabilizing low-valence states and initiating oxidative addition of CO2 and methyl group cations, respectively. In this article, the structural and functional commonalities of these metalloenzyme active sites are described, and the case is made for the formation and use of metal-metal bonds in each enzyme mentioned. As a post-script, the importance of Fe-Fe bonds in the nitrogenase FeMoco active site is discussed.

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Section: 4 Evidence For M-m Bonds In Metalloenzymesmentioning

confidence: 99%

“…Tatsumi, Rauchfuss, Riordan and others have synthesized A-cluster model complexes with two Ni ions and bridging dithiolates [59, 63 - 66], reminiscent of the Hase model compounds (Figure 6, top). These [Ni 0 Ni II ] compounds show flexible Ni-S 2 -Ni hinge angles, ranging from ca .…”

Section: 4 Evidence For M-m Bonds In Metalloenzymesmentioning

confidence: 99%

Metal–metal bonds in biology

Lindahl

2012

Journal of Inorganic Biochemistry

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“…5e, that can be methylated by methyl-cobaloxime, and that can further react with CO to form an acetylthioester compound similar to acetyl-CoA. 51,52 In these studies, the compound Ni(dadt Et )Ni(Me)(SDmp), where dadt Et stands for N , N ′-diethyl-3,7-diazanonane-1,9-dithiolate and Dmp for 2,6-dimesitylphenyl, was synthesized as a Ni II –Ni I complex. It had a S = 1/2 EPR signal ( g x , y , z = 2.62, 2.12, 2.00), could be methylated and then react with CO.…”

Section: (Iv) Non-enzymatic Inorganic Compounds That Catalyze Reactimentioning

confidence: 99%

Metal centers in the anaerobic microbial metabolism of CO and CO2

et al. 2011

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Carbon dioxide and carbon monoxide are important components of the carbon cycle. Major research efforts are underway to develop better technologies to utilize the abundant greenhouse gas, CO2, for harnessing ‘green’ energy and producing biofuels. One strategy is to convert CO2 into CO, which has been valued for many years as a synthetic feedstock for major industrial processes. Living organisms are masters of CO2 and CO chemistry and, here, we review the elegant ways that metalloenzymes catalyze reactions involving these simple compounds. After describing the chemical and physical properties of CO and CO2, we shift focus to the enzymes and the metal clusters in their active sites that catalyze transformations of these two molecules. We cover how the metal centers on CO dehydrogenase catalyze the interconversion of CO and CO2 and how pyruvate oxidoreductase, which contains thiamin pyrophosphate and multiple Fe4S4 clusters, catalyzes the addition and elimination of CO2 during intermediary metabolism. We also describe how the nickel center at the active site of acetyl-CoA synthase utilizes CO to generate the central metabolite, acetyl-CoA, as part of the Wood-Ljungdahl pathway, and how CO is channelled from the CO dehydrogenase to the acetyl-CoA synthase active site. We cover how the corrinoid iron–sulfur protein interacts with acetyl-CoA synthase. This protein uses vitamin B12 and a Fe4S4 cluster to catalyze a key methyltransferase reaction involving an organometallic methyl-Co3+ intermediate. Studies of CO and CO2 enzymology are of practical significance, and offer fundamental insights into important biochemical reactions involving metallocenters that act as nucleophiles to form organometallic intermediates and catalyze C–C and C–S bond formations.

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“…It has been shown that the presence of a CO ligand in the Ni(0) compound (bis(2-diphenylphosphinoethyl)phenylphosphine)-NiCO prevents methylation by methylcobaloxime (55). And, in recent studies on a binuclear Ni(II)-Ni(II) complex bearing methyl and thiol ligands, it was found that thioester formation, initiated by addition of CO, takes place as a single turnover process because of the concomitant formation of an inactive Ni(0)-carbonyl complex that does not react further with methylcobaloxime (56). This was interpreted to indicate that CO addition to Ni p in ACS must be strictly regulated to prevent the formation of such inactive Ni(0)-CO species.…”

Section: Mechanism Of Acetyl C-c Bond Fragmentationmentioning

confidence: 99%