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Cofactor F430 is porphinoid with a nickel center. Due to the incorporation of a mixture of fundamental components of porphyrins and corrins it can be appropriately classified as a

"tetrahydroderivative of the corphin system"

. ^[1]

Proposed Mechanisms

Two highly debatable mechanisms for the catalytic activity of F₄₃₀ in methane production have been resolved. The active enzyme contains the free cofactor F₄₃₀ with nickel in the Ni (I) oxidation state. Both mechanisms require the binding of methyl-coenzyme M, which stimulates a structural modification of the active site and coenzyme B subsequently binds. The catalytic synthesis of methane occurs within a hydrophobic compartment due to the blocking of the substrate channel opening by the bulky mercaptoheptanoyl group of coenzyme B.^[2]

Mechanism 1

Ni(I)F₄₃₀ initiates the heterolytic cleavage of the methyl-coenzyme M thioether bond, and the nucleophilic attachment of the resulting methyl cation to the cofactor oxidizes the nickel from Ni(I) to Ni(III) in a methyl-Ni(III)F₄₃₀ complex.^[2] The other product of the cleavage, a coenzyme M thiolate, is protonated by coenzyme B in a complimentary reaction.^[3]

CoB-S-H + CH₃-S-CoM + Ni(I)F₄₃₀ → CoB-S^- + H-S-CoM + CH₃-Ni(III)F₄₃₀^+[3]

Ni(III) induces the oxidation of coenzyme M thiolate, in which the methyl-Ni(III) complex gains an electron, reducing Ni(III) to Ni(II) and yielding the thiyl radical of coenzyme M.^[2]

H-S-CoM + CH₃-Ni(III)F₄₃₀⁺ → H-*S-CoM⁺ + CH₃-Ni(II)F₄₃₀ ^[3]

Methane is released upon the protonation of the methyl group of the methyl- Ni(II)F₄₃₀ intermediate by the alcohol side chain of Tyr^B367. A concurrent proton transfer from coenzyme B reprotonates Tyr^B367 and a disulfide bond couples the resultant coenzyme B thiolate anion and the coenzyme M thiyl.^[2] The catalytic cycle is completed by the reduction of Ni(II) back to its initial Ni(I) oxidation state by abstraction of an electron from the coenzyme M-coenzyme B radical anion.^[2]

H-S-CoB + H-*S-CoM⁺ + CH₃-Ni(II)F₄₃₀ → CH₄ + CoB-S-S-CoM + Ni(I)F₄₃₀ ^[3]

Mechanism 2

The second mechanism similarly consists of the Ni(I)F₄₃₀ induced nucleophilic substitution of the methyl-coenzyme M thioether bond, however, the bond is broken homolytically rather than hetereolytically. The homolytic cleavage releases a methyl radical and a coenzyme M radical , the latter of which combines with Ni(I)F₄₃₀, oxidizing Ni(I) to Ni(II).^[2]

CoB-S-H + CH₃-S-CoM + Ni(I)F₄₃₀ → CoB-S-H + *CH₃ + CoM-S-Ni(II)F₄₃₀ ^[3]

Proton transfer from coenzyme B to the methyl radical expels methane and a coenzyme B thiyl radical, which is involved in a substitution reaction with the coenzyme M-Ni(II)F₄₃₀ complex to yield the heterodisulfide radical anion. The reduction of the nickel of the cofactor to its original Ni(I) oxidation state is complimented by the oxidation of the coenzyme M-coenzyme B radical anion, terminating the catalytic cycle.^[2]

CoB-S-H + *CH₃⁺ → CoB-S* + CH₄ ^[3]

CoB-S* + CoM-S-Ni(II)F₄₃₀ → CoB-S-S-CoM + Ni(I)F₄₃₀ ^[3]

References

1. Gilles, Harald; Thauer, Rudolf K. (1983). "Uroporphyrinogen 111, an intermediate in the biosynthesis of the nickel-containing factor F430 in Methanobacterium thermoautotrophicum". European Journal of Biochemistry. 135 (1): 1. doi:10.1039/B506697B.
2. Shima, Seigo; Warkentin, Eberhard; Thauer, Rudolf K.; Ermler, Ulrich (2002). "Structure and Function of Enzymes Involved in the Methanogenic Pathway Utilizing Carbon Dioxide and Molecular Hydrogen". Jounral of Bioscience and Bioengineering. 93 (6): 525–527. doi:10.1016/S1389-1723(02)80232-8.
3. Pelmenschikov, Vladimir; Siegbahn, Per E.M. (July 2003). "Catalysis by Methyl-Coenzyme M Reductase: A Theoretical Study for Heterodisulfide Product Formation". Journal of Biological Inorganic Chemistry. 8: 654–656.