One-carbon chemistry of oxalate oxidoreductase captured by X-ray crystallography

Gibson, Marcus I.; Chen, Percival Yang-Ting; Johnson, Aileen C.; Pierce, Elizabeth; Can, Mehmet; Ragsdale, Stephen W.; Drennan, Catherine L.

doi:10.1073/pnas.1518537113

Cited by 16 publications

(30 citation statements)

References 32 publications

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“…Prior to our work, structures of OFORs have been limited to three different types, two PFORs (MtPFOR 7 and the cognate enzyme from Desulfovibiro africanus [DaPFOR] [20][21][22] ), an oxaloacetate oxidoreductase (OOR) from M. thermoacetica (MtOOR), 23,24 and two OFORs from Sulfolobus tokodaii of cryptic function (StOFORs). 25 Even with these structures in hand, many open questions about OFOR chemistry remain, including the issues of electron transfer described above.…”

Section: Context and Scalementioning

confidence: 99%

A Reverse TCA Cycle 2-Oxoacid:Ferredoxin Oxidoreductase that Makes C-C Bonds from CO2

Chen

Drennan

et al. 2019

Joule

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Section: Context and Scalementioning

confidence: 99%

A Reverse TCA Cycle 2-Oxoacid:Ferredoxin Oxidoreductase that Makes C-C Bonds from CO2

Chen

Drennan

et al. 2019

Joule

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“…Crystal structures have been determined of two members of the OFOR superfamily: the PFOR from Desulfovibrio africanus ( Da PFOR) [24–26] and the OOR from M. thermoacetica ( Mt OOR) [21,22]. Both enzymes have similar overall structures despite the fact that Da PFOR is an α 2 homodimer and Mt OOR is a dimer of trimers (αγβ) 2 (Figure 1d,e,g).…”

Section: The Overall Structure Of Oforsmentioning

confidence: 99%

“…Following TPP-adduct formation, however, this additional positive charge may hinder the next mechanistic steps, which are decarboxylation and electron transfer from TPP to the [4Fe-4S] clusters. Interestingly, crystal structures of OOR reveal that in the presence of substrate, a conformational change of a loop (aka the Switch loop) occurs that repositions Phe117α out of the active site (Figure 3b) and moves into the active site a negatively charged residue, Asp116α (Figure 3c) [22]. With this new loop conformation, Asp116α is proximal to the TPP-adduct, such that it could drive decarboxylation and/or electron transfer (Figure 3c).…”

Section: Structure and Function Of Oxalate Oxidoreductase (Oor)mentioning

confidence: 99%

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A structural phylogeny for understanding 2-oxoacid oxidoreductase function

Gibson

Chen

Drennan

2016

Current Opinion in Structural Biology

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2-Oxoacid:ferredoxin oxidoreductases (OFORs) are essential enzymes in microbial one-carbon metabolism. They use thiamine pyrophosphate to reversibly cleave carbon-carbon bonds, generating low potential (~ −500 mV) electrons. Crystallographic analysis of a recently discovered OFOR, an oxalate oxidoreductase (OOR), has provided a second view of OFOR architecture and active site composition. Using these recent structural data along with the previously determined structures of pyruvate:ferredoxin oxidoreductase, structure-function relationships in this superfamily have been expanded and re-evaluated. Additionally, structural motifs have been defined that better serve to distinguish one OFOR subfamily from another and potentially uncover novel OFORs.

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“…18 In the OOR structure with carboxyl-TPP bound (PDB entry 5EXE), ∼50% of the switch loop is in the Asp-in conformation. In forming this Asp-in conformation, Arg109α swings away from its ionic interactions with carboxyl-TPP, observed in the Asp-out state, and Asp112α moves within H-bonding distance of the carboxyl group of carboxyl-TPP (Figure 9).…”

Section: Discussionmentioning

confidence: 99%

Properties of Intermediates in the Catalytic Cycle of Oxalate Oxidoreductase and Its Suicide Inactivation by Pyruvate

et al. 2017

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Oxalate:ferredoxin oxidoreductase (OOR) is an unusual member of the thiamine pyrophosphate (TPP)-dependent 2-oxoacid:ferredoxin oxidoreductase (OFOR) family in that it catalyzes the coenzyme A (CoA)-independent conversion of oxalate into 2 equivalents of carbon dioxide. This reaction is surprising because binding of CoA to the acyl-TPP intermediate of other OFORs results in formation of a CoA ester, and in the case of pyruvate:ferredoxin oxidoreductase (PFOR), CoA binding generates the central metabolic intermediate acetyl-CoA and promotes a 105-fold acceleration of the rate of electron transfer. Here we describe kinetic, spectroscopic, and computational results to show that CoA has no effect on catalysis by OOR and describe the chemical rationale for why this cofactor is unnecessary in this enzymatic transformation. Our results demonstrate that, like PFOR, OOR binds pyruvate and catalyzes decarboxylation to form the same hydroxyethylidine–TPP (HE–TPP) intermediate and one-electron transfer to generate the HE–TPP radical. However, in OOR, this intermediate remains stranded at the active site as a covalent inhibitor. These and other results indicate that, like other OFOR family members, OOR generates an oxalate-derived adduct with TPP (oxalyl-TPP) that undergoes decarboxylation and one-electron transfer to form a radical intermediate remaining bound to TPP (dihydroxymethylidene–TPP). However, unlike in PFOR, where CoA binding drives formation of the product, in OOR, proton transfer and a conformational change in the “switch loop” alter the redox potential of the radical intermediate sufficiently to promote the transfer of an electron into the iron–sulfur cluster network, leading directly to a second decarboxylation and completing the catalytic cycle.

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One-carbon chemistry of oxalate oxidoreductase captured by X-ray crystallography

Cited by 16 publications

References 32 publications

A Reverse TCA Cycle 2-Oxoacid:Ferredoxin Oxidoreductase that Makes C-C Bonds from CO2

A Reverse TCA Cycle 2-Oxoacid:Ferredoxin Oxidoreductase that Makes C-C Bonds from CO2

A structural phylogeny for understanding 2-oxoacid oxidoreductase function

Properties of Intermediates in the Catalytic Cycle of Oxalate Oxidoreductase and Its Suicide Inactivation by Pyruvate

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