An evolutionary history of the CoA‐binding protein Nat/Ivy

An evolutionary history of the CoA‐binding protein Nat/Ivy

Nat/Ivy is a diverse and ubiquitous CoA‐binding evolutionary lineage that catalyzes acyltransferase reactions, primarily converting thioesters into amides. At the heart of the Nat/Ivy fold is a phosphate‐binding loop that bears a striking resemblance to that of P‐loop NTPases—both are extended, glyc...

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Bibliographic Details
Published in:Protein science Vol. 31; no. 12; pp. e4463 - n/a
Main Authors: Longo, Liam M., Hirai, Hayate, McGlynn, Shawn Erin
Format: Journal Article
Language:English
Published: Hoboken, USA John Wiley & Sons, Inc 01-12-2022
Wiley Subscription Services, Inc
Subjects:
acetyltransferase
Acyltransferase
Amides
Binding sites
Chemical reactions
coenzyme A
Coevolution
Domains
Enzymes
Evolution
Glycine
GNAT
Metabolites
nucleotide cofactor
phosphate binding loop
P‐loop
Review
Reviews
Rossmann
Thioesters
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Summary:Nat/Ivy is a diverse and ubiquitous CoA‐binding evolutionary lineage that catalyzes acyltransferase reactions, primarily converting thioesters into amides. At the heart of the Nat/Ivy fold is a phosphate‐binding loop that bears a striking resemblance to that of P‐loop NTPases—both are extended, glycine‐rich loops situated between a β‐strand and an α‐helix. Nat/Ivy, therefore, represents an intriguing intersection between thioester chemistry, a putative primitive energy currency, and an ancient mode of phospho‐ligand binding. Current evidence suggests that Nat/Ivy emerged independently of other cofactor‐utilizing enzymes, and that the observed structural similarity—particularly of the cofactor binding site—is the product of shared constraints instead of shared ancestry. The reliance of Nat/Ivy on a β‐α‐β motif for CoA‐binding highlights the extent to which this simple structural motif may have been a fundamental evolutionary “nucleus” around which modern cofactor‐binding domains condensed, as has been suggested for HUP domains, Rossmanns, and P‐loop NTPases. Finally, by dissecting the patterns of conserved interactions between Nat/Ivy families and CoA, the coevolution of the enzyme and the cofactor was analyzed. As with the Rossmann, it appears that the pyrophosphate moiety at the center of the cofactor predates the enzyme, suggesting that Nat/Ivy emerged sometime after the metabolite dephospho‐CoA.
Bibliography:ObjectType-Article-2
SourceType-Scholarly Journals-1
ObjectType-Feature-3
content type line 23
ObjectType-Review-1
Review Editor: John Kuriyan
Funding information Japan Society for the Promotion of Science, Grant/Award Number: 22H01343; National Science Foundation, Grant/Award Number: 1724300
ISSN:0961-8368
1469-896X
DOI:10.1002/pro.4463