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Literature DB >> 24419378

Lysine carboxylation: unveiling a spontaneous post-translational modification.

David Jimenez-Morales¹, Larisa Adamian¹, Dashuang Shi², Jie Liang¹.

Abstract

The carboxylation of lysine residues is a post-translational modification (PTM) that plays a critical role in the catalytic mechanisms of several important enzymes. It occurs spontaneously under certain physicochemical conditions, but is difficult to detect experimentally. Its full impact is unknown. In this work, the signature microenvironment of lysine-carboxylation sites has been characterized. In addition, a computational method called Predictor of Lysine Carboxylation (PreLysCar) for the detection of lysine carboxylation in proteins with available three-dimensional structures has been developed. The likely prevalence of lysine carboxylation in the proteome was assessed through large-scale computations. The results suggest that about 1.3% of large proteins may contain a carboxylated lysine residue. This unexpected prevalence of lysine carboxylation implies an enrichment of reactions in which it may play functional roles. The results also suggest that by switching enzymes on and off under appropriate physicochemical conditions spontaneous PTMs may serve as an important and widely used efficient biological machinery for regulation.

Entities: Chemical

Keywords: PreLysCar; Predictor of Lysine Carboxylation; lysine carboxylation; metal-ion centers; spontaneous post-translational modifications; structural motif

Mesh：

Substances：
Proteins
Lysine

Year: 2013 PMID： 24419378 PMCID： PMC3919261 DOI： 10.1107/S139900471302364X

Source DB: PubMed Journal: Acta Crystallogr D Biol Crystallogr ISSN： 0907-4449

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