Small protein folds at the root of an ancient metabolic network

Small protein folds at the root of an ancient metabolic network

Life on Earth is driven by electron transfer reactions catalyzed by a suite of enzymes that comprise the superfamily of oxidoreductases (Enzyme Classification EC1). Most modern oxidoreductases are complex in their structure and chemistry and must have evolved from a small set of ancient folds. Ancie...

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Published in:Proceedings of the National Academy of Sciences - PNAS Vol. 117; no. 13; pp. 7193 - 7199
Main Authors: Raanan, Hagai, Poudel, Saroj, Pike, Douglas H., Nanda, Vikas, Falkowski, Paul G.
Format: Journal Article
Language:English
Published: United States National Academy of Sciences 31-03-2020
Subjects:
Biological Sciences
Catalysis
Chemical reactions
Dimensional changes
Electron transfer
Electron Transport
Evolution, Molecular
Ferredoxin
Ferredoxins - metabolism
Flavodoxin - metabolism
Metabolic networks
Metabolism
Oxidoreductases - metabolism
Phylogeny
Protein Conformation
Proteins
Topology
ferredoxin
Rossmann fold
electron transfer
flavodoxin
biological networks
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Summary:Life on Earth is driven by electron transfer reactions catalyzed by a suite of enzymes that comprise the superfamily of oxidoreductases (Enzyme Classification EC1). Most modern oxidoreductases are complex in their structure and chemistry and must have evolved from a small set of ancient folds. Ancient oxidoreductases from the Archean Eon between ca. 3.5 and 2.5 billion years ago have been long extinct, making it challenging to retrace evolution by sequence-based phylogeny or ancestral sequence reconstruction. However, three-dimensional topologies of proteins change more slowly than sequences. Using comparative structure and sequence profile-profile alignments, we quantify the similarity between proximal cofactor-binding folds and show that they are derived from a common ancestor. We discovered that two recurring folds were central to the origin of metabolism: ferredoxin and Rossmann-like folds. In turn, these two folds likely shared a common ancestor that, through duplication, recruitment, and diversification, evolved to facilitate electron transfer and catalysis at a very early stage in the origin of metabolism.
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Edited by Ken A. Dill, Stony Brook University, Stony Brook, NY, and approved February 21, 2020 (received for review August 28, 2019)
Author contributions: H.R., S.P., D.H.P., V.N., and P.G.F. designed research; H.R., S.P., and D.H.P. performed research; H.R., S.P., and D.H.P. contributed new reagents/analytic tools; H.R., S.P., D.H.P., V.N., and P.G.F. analyzed data; and H.R., S.P., D.H.P., V.N., and P.G.F. wrote the paper.
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.1914982117