Ubiquitin is a Carbon Dioxide-binding Protein

Overview

Journal Sci Adv

Specialties Biology
Science

Date 2021 Sep 24

PMID 34559559

Citations 12

Authors

Victoria L Linthwaite

Wes Pawloski

Hamish B Pegg

Philip D Townsend

Michael J Thomas

Victor K H So

Adrian P Brown

David R W Hodgson

George H Lorimer

David Fushman

Martin J Cann

Affiliations

Soon will be listed here.

Abstract

The identification of CO-binding proteins is crucial to understanding CO-regulated molecular processes. CO can form a reversible posttranslational modification through carbamylation of neutral N-terminal α-amino or lysine ε-amino groups. We have previously developed triethyloxonium (TEO) ion as a chemical proteomics tool for covalent trapping of carbamates, and here, we deploy TEO to identify ubiquitin as a mammalian CO-binding protein. We use C-NMR spectroscopy to demonstrate that CO forms carbamates on the ubiquitin N terminus and ε-amino groups of lysines 6, 33, 48, and 63. We demonstrate that biologically relevant CO levels reduce ubiquitin conjugation at lysine-48 and down-regulate ubiquitin-dependent NF-κB pathway activation. Our results show that ubiquitin is a CO-binding protein and demonstrates carbamylation as a viable mechanism by which mammalian cells can respond to fluctuating CO.

Citing Articles

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Ubiquitin's Conformational Heterogeneity as Discerned by Nuclear Magnetic Resonance Spectroscopy.

Beriashvili D, Folkers G, Baldus M Chembiochem. 2024; 25(24):e202400508.

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Orphan Nuclear Receptor Family 4A (NR4A) Members NR4A2 and NR4A3 Selectively Modulate Elements of the Monocyte Response to Buffered Hypercapnia.

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