Radical S-adenosylmethionine maquette chemistry: Cx3Cx2C peptide coordinated redox active [4Fe–4S] clusters

The synthesis and characterization of short peptide-based maquettes of metalloprotein active sites facilitate an inquiry into their structure/function relationships and evolution. The [4Fe–4S]-maquettes of bacterial ferredoxin metalloproteins (Fd) have been used in the past to engineer redox active...

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Bibliographic Details
Published in:Journal of biological inorganic chemistry 2019-09, Vol.24 (6), p.793-807
Main Authors: Galambas, Amanda, Miller, Jacquelyn, Jones, Morgan, McDaniel, Elizabeth, Lukes, Molly, Watts, Hope, Copié, Valérie, Broderick, Joan B., Szilagyi, Robert K., Shepard, Eric M.
Format: Article
Language:English
Subjects:
Adenosylmethionine
Biochemistry
Biomedical and Life Sciences
Chemical speciation
Cysteine
Ferredoxin
Joan Broderick: Papers in Celebration of Her 2019 ACS Alfred Bader Award in Bioinorganic or Bioorganic Chemistry
Life Sciences
Microbiology
Original Paper
Peptides
S-Adenosylmethionine
Structure-function relationships
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Summary:The synthesis and characterization of short peptide-based maquettes of metalloprotein active sites facilitate an inquiry into their structure/function relationships and evolution. The [4Fe–4S]-maquettes of bacterial ferredoxin metalloproteins (Fd) have been used in the past to engineer redox active centers into artificial metalloenzymes. The novelty of our study is the application of maquettes to the superfamily of [4Fe–4S] cluster and S -adenosylmethionine-dependent radical metalloenzymes (radical SAM). The radical SAM superfamily enzymes contain site-differentiated, redox active [4Fe–4S] clusters coordinated to Cx 3 Cx 2 C or related motifs, which is in contrast to the Cx 2 Cx 2 C motif found in bacterial ferredoxins (Fd). Under an optimized set of experimental conditions, a high degree of reconstitution (80–100%) was achieved for both radical SAM- and Fd-maquettes. Negligible chemical speciation was observed for all sequences, with predominantly [4Fe–4S] 2+ for the ‘as-reconstituted’ state. However, the reduction of [4Fe–4S] 2+ -maquettes provides low conversion (7–17%) to the paramagnetic [4Fe–4S] + state, independent of either the spacing of the cysteine residues (Cx 3 Cx 2 C vs. Cx 2 Cx 2 C), the nature of intervening amino acids, or the length of the cluster binding motif. In the absence of the stabilizing protein environment, the reduction process is proposed to proceed via [4Fe–4S] 2+ cluster disassembly and reassembly in a more reduced state. UV–Vis and EPR spectroscopic techniques are employed as analytical tools to quantitate the as-reconstituted (or oxidized) and one-electron reduced states of the [4Fe–4S] clusters, respectively. We demonstrate that short Fd and radical SAM derived 7- to 9-mer peptides containing appropriate cysteine motifs function equally well in coordinating redox active [4Fe–4S] clusters. Graphic abstract
ISSN:0949-8257
1432-1327
DOI:10.1007/s00775-019-01708-8