1999
DOI: 10.1074/jbc.274.17.11513
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The Role of an Iron-Sulfur Cluster in an Enzymatic Methylation Reaction

Abstract: This paper focuses on how a methyl group is transferred from a methyl-cobalt(III) species on one protein (the corrinoid iron-sulfur protein (CFeSP)) to a nickel iron-sulfur cluster on another protein (carbon monoxide dehydrogenase/acetyl-CoA synthase). This is an essential step in the Wood-Ljungdahl pathway of anaerobic CO and CO 2 fixation. The results described here strongly indicate that transfer of methyl group to carbon monoxide dehydrogenase/acetyl-CoA synthase occurs by an S N 2 pathway. They also provi… Show more

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Cited by 69 publications
(41 citation statements)
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“…To achieve and maintain the Co 1+ oxidation state, human ATR forces the Co 2+ corrinoid substrate into a four-coordinate conformation, which helps to lower the thermodynamic barrier for cobalt-ion reduction (E° = −490 mV for the Co 2+/1+ couple of Co 2+ Cbi + ) by the in vivo flavodoxin reductant (E° = −285 mV). 74 CFeSP instead employs a low-potential [Fe 4 S 4 ] cluster (E° = −523 mV) as an internal reducing system that is bound to the enzyme through four cysteine residues, 14,15 as further indicated by our resonance Raman (rR) data ( Figure 5). This [Fe 4 S 4 ] 2+/1+ potential is intermediate between that of the C cluster of CODH (−530 mV) 79 and the Co 2+/1+ couple of the bound Factor III m (−504 mV).…”
Section: Reactivation Of Co 2+ Cfespmentioning
confidence: 99%
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“…To achieve and maintain the Co 1+ oxidation state, human ATR forces the Co 2+ corrinoid substrate into a four-coordinate conformation, which helps to lower the thermodynamic barrier for cobalt-ion reduction (E° = −490 mV for the Co 2+/1+ couple of Co 2+ Cbi + ) by the in vivo flavodoxin reductant (E° = −285 mV). 74 CFeSP instead employs a low-potential [Fe 4 S 4 ] cluster (E° = −523 mV) as an internal reducing system that is bound to the enzyme through four cysteine residues, 14,15 as further indicated by our resonance Raman (rR) data ( Figure 5). This [Fe 4 S 4 ] 2+/1+ potential is intermediate between that of the C cluster of CODH (−530 mV) 79 and the Co 2+/1+ couple of the bound Factor III m (−504 mV).…”
Section: Reactivation Of Co 2+ Cfespmentioning
confidence: 99%
“…13 Therefore, it has been postulated that reductive activation begins with the CO-dependent reduction of the CODH C cluster that then transfers an electron to the [Fe 4 S 4 ] 2+ cluster of the CFeSP, which reduces the bound Factor III m to the Co 1+ state. 14,15,80 Reduction activation is enhanced by replacement of the lower axial MBI ligand of Factor III m by a weaker water ligand when the cofactor binds to the CFeSP, generating a fivecoordinate Co 2+ species that resembles Co 2+ Cbi + (see above). This ligand switch has a profound influence in the redox properties of the Co center, increasing the Co 2+/1+ reduction potential by ~120 mV relative to that of the MBI-bound form of the cofactor found in solution (~−620 mV).…”
Section: Reactivation Of Co 2+ Cfespmentioning
confidence: 99%
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“…8,139,140 Acetylcoenzyme A was involved in reaction(s) leading to formation of both a methylnickel linkage in the cofactor and also an iron±carbon monoxide linkage at a nearby site. 140,141 EPR studies suggested that the nickel in methylcoenzyme M reductase existed as nickel(I). 142±145 Like cobalt in II, the nickel±methyl bond must be stabilized by a special chelating environment in order to form without immediate decomposition.…”
Section: Nickelmentioning
confidence: 99%