X-ray structure of an AdoMet radical activase reveals an anaerobic solution for formylglycine posttranslational modification

X-ray structure of an AdoMet radical activase reveals an anaerobic solution for formylglycine posttranslational modification

Arylsulfatases require a maturating enzyme to perform a co- or posttranslational modification to form a catalytically essential formylglycine (FGly) residue. In organisms that live aerobically, molecular oxygen is used enzymatically to oxidize cysteine to FGly. Under anaerobic conditions, S -adenosy...

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Bibliographic Details
Published in:Proceedings of the National Academy of Sciences - PNAS Vol. 110; no. 21; pp. 8519 - 8524
Main Authors: Goldman, Peter J., Grove, Tyler L., Sites, Lauren A., McLaughlin, Martin I., Booker, Squire J., Drennan, Catherine L.
Format: Journal Article
Language:English
Published: United States National Academy of Sciences 21-05-2013
National Acad Sciences
Subjects:
Active sites
Amino acids
Anaerobiosis - physiology
Bacteria
Bacterial Proteins - genetics
Bacterial Proteins - metabolism
Biological Sciences
Catalysis
Clostridium perfringens - genetics
Clostridium perfringens - metabolism
Electron transfer
Electrons
Enzyme substrates
Enzymes
Free Radicals - metabolism
Glycine - analogs & derivatives
Glycine - genetics
Glycine - metabolism
Hydrogen
Ligation
Mutagenesis
Oxidation
Oxidation-Reduction
Protein Processing, Post-Translational - physiology
Protein Structure, Tertiary
Proteins
S-Adenosylmethionine - genetics
S-Adenosylmethionine - metabolism
Spasms
iron–sulfur cluster fold
radical SAM dehydrogenase
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Summary:Arylsulfatases require a maturating enzyme to perform a co- or posttranslational modification to form a catalytically essential formylglycine (FGly) residue. In organisms that live aerobically, molecular oxygen is used enzymatically to oxidize cysteine to FGly. Under anaerobic conditions, S -adenosylmethionine (AdoMet) radical chemistry is used. Here we present the structures of an anaerobic sulfatase maturating enzyme (anSME), both with and without peptidyl-substrates, at 1.6–1.8 Å resolution. We find that anSMEs differ from their aerobic counterparts in using backbone-based hydrogen-bonding patterns to interact with their peptidyl-substrates, leading to decreased sequence specificity. These anSME structures from Clostridium perfringens are also the first of an AdoMet radical enzyme that performs dehydrogenase chemistry. Together with accompanying mutagenesis data, a mechanistic proposal is put forth for how AdoMet radical chemistry is coopted to perform a dehydrogenation reaction. In the oxidation of cysteine or serine to FGly by anSME, we identify D277 and an auxiliary [4Fe-4S] cluster as the likely acceptor of the final proton and electron, respectively. D277 and both auxiliary clusters are housed in a cysteine-rich C-terminal domain, termed SPASM domain, that contains homology to ∼1,400 other unique AdoMet radical enzymes proposed to use [4Fe-4S] clusters to ligate peptidyl-substrates for subsequent modification. In contrast to this proposal, we find that neither auxiliary cluster in anSME bind substrate, and both are fully ligated by cysteine residues. Instead, our structural data suggest that the placement of these auxiliary clusters creates a conduit for electrons to travel from the buried substrate to the protein surface.
Bibliography:http://dx.doi.org/10.1073/pnas.1302417110
Author contributions: P.J.G., T.L.G., L.A.S., S.J.B., and C.L.D. designed research; P.J.G. and M.I.M. performed the crystallization and crystal structure determination; T.L.G. provided His6 and native protein samples; L.A.S. generated mutant constructs and performed activity assays; and P.J.G. and C.L.D. wrote the paper.
Edited by Vern L. Schramm, Albert Einstein College of Medicine of Yeshiva University, Bronx, NY, and approved April 12, 2013 (received for review February 5, 2013)
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.1302417110