AI Article Synopsis
- Acyl-CoAs can modify proteins by attaching acyl groups to cysteine and lysine residues, with N-acylation being a permanent change.
- The presence of nucleotide-binding sites influences the process, as excess nucleotides can reduce N-acetylation of lysine residues in proteins.
- Using glutamate dehydrogenase as an example, the study demonstrates that proximity to these nucleotide-binding sites enhances N-malonylation, indicating that such modifications could play a significant role in protein regulation in living organisms.
Article Abstract
Acyl-CoAs are reactive metabolites that can non-enzymatically S-acylate and N-acylate protein cysteine and lysine residues, respectively. N-acylation is irreversible and enhanced if a nearby cysteine residue undergoes an initial reversible S-acylation, as proximity leads to rapid S → N-transfer of the acyl moiety. We reasoned that protein-bound acyl-CoA could also facilitate S → N-transfer of acyl groups to proximal lysine residues. Furthermore, as CoA contains an ADP backbone this may extend beyond CoA-binding sites and include abundant Rossmann-fold motifs that bind the ADP moiety of NADH, NADPH, FADH and ATP. Here, we show that excess nucleotides decrease protein lysine N-acetylation in vitro. Furthermore, by generating modelled structures of proteins N-acetylated in mouse liver, we show that proximity to a nucleotide-binding site increases the risk of N-acetylation and identify where nucleotide binding could enhance N-acylation in vivo. Finally, using glutamate dehydrogenase as a case study, we observe increased in vitro lysine N-malonylation by malonyl-CoA near nucleotide-binding sites which overlaps with in vivo N-acetylation and N-succinylation. Furthermore, excess NADPH, GTP and ADP greatly diminish N-malonylation near their nucleotide-binding sites, but not at distant lysine residues. Thus, lysine N-acylation by acyl-CoAs is enhanced by nucleotide-binding sites and may contribute to higher stoichiometry protein N-acylation in vivo.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC7680127 | PMC |
| http://dx.doi.org/10.1038/s41598-020-77261-1 | DOI Listing |
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