Wolfe cycle

The Wolfe Cycle is a methanogenic pathway used by archaea; the archaeon takes H₂ and CO₂ and cycles them through a various intermediates to create methane.^[1] The Wolfe Cycle is modified in different orders and classes of archaea as per the resource availability and requirements for each species, but it retains the same basic pathway.^[1] The pathway begins with the reducing carbon dioxide to formylmethanofuran.^[1] The last step uses heterodisulfide reductase (Hdr) to reduce heterodisulfide into Coenzyme B and Coenzyme M using Fe₄S₄ clusters.^[1]^[2] Evidence suggests this last step goes hand-in-hand with the first step, and feeds back into it, creating a cycle.^[1] At various points in the Wolfe Cycle, intermediates that are formed are taken out of the cycle to be used in other metabolic processes.^[1]^[3] Since intermediates are being taken out at various points in the cycle, there is also a replenishing (anaplerotic) reaction that feeds into the Wolfe cycle, this is to regenerate necessary intermediates for the cycle to continue.^[1] Overall, including the replenishing reaction, the Wolfe Cycle has a total of nine steps.^[1] While Obligate ${\ce {CO2}}$ reducing methanogens perform additional steps to reduce CO₂ to ${\ce {CH3}}$ .

Discovery edit

In 1971, in a review published by Robert Stoner Wolfe, information regarding methanogenesis in M. bryantii was published. The only thing known about this process, at the time, was that Coenzyme M was involved at some point of the pathway.^[4] It was though that this was done through a linear cycle. It was not until 1986 that the reduction of ${\ce {CO2}}$ to ${\ce {CH4}}$ was proposed as a cycle when it was shown that the Steps 8 and 1 were coupled together.^[4]

Steps edit

The Wolfe Cycle can be run in multiple ways depending on what microbe is using it, multiple pathways are available for different things to be produced. These are a generalized cycle of the Wolfe Cycle.


steps	reactants	Enzymes^[4]	Products used in cycle
1	${\ce {CO2 + MF +2H+}}$	Formyl-methanofuran dehydrogenase	${\ce {Formyl - MFR}}$
2	${\ce {N-Formyl - MFR + H4MPT}}$	Formyltransferase	${\ce {N-Formyl-H4MPT}}$
3	${\ce {Formyl - H4MPT + H+}}$	methenyl-H₄MPT cyclohydrolase	${\ce {methenyl-H4MPT}}$
4	${\ce {Methenyl - H4MPT + F420H2}}$	methylene-H₄MPT dehydrogenase	${\ce {methylene-H4MPT}}$
5	${\ce {Methylene - H4MPT + F420H2}}$	methylene-H₄MPT reductase	${\ce {methyl-H4MPT}}$
6	${\ce {methyl-H4MPT + HS-CoM}}$	methyl-H₄MPT/HSCoM methyl transferase	${\ce {CH3-S-CoM}}$
7	${\ce {CH3-S-CoM + HS-CoB}}$	methyl-S-CoM reductase	${\ce {CoM-S-S-CoB}}$
8	${\ce {CoM-S-S-CoB + Fdx (ferredoxin)}}$	electron bifurcating hydrogenase-heterodisulfide reductase complex	${\ce {Fdx^2- + HS-CoB + HS-CoM}}$
9	${\ce {F420 + H2 + HCO2H}}$	F₄₂₀-reducing hydrogenase	${\ce {CO2 + F420H}}$