N-lactoyl-amino Acids Are Ubiquitous Metabolites That Originate from CNDP2-mediated Reverse Proteolysis of Lactate and Amino Acids

Overview

Journal Proc Natl Acad Sci U S A

Specialty Science

Date 2015 May 13

PMID 25964343

Citations 50

Authors

Robert S Jansen

Ruben Addie

Remco Merkx

Alexander Fish

Sunny Mahakena

Onno B Bleijerveld

Maarten Altelaar

Lodewijk Ijlst

Ronald J Wanders

P Borst

Koen van de Wetering

Affiliations

Soon will be listed here.

Abstract

Despite technological advances in metabolomics, large parts of the human metabolome are still unexplored. In an untargeted metabolomics screen aiming to identify substrates of the orphan transporter ATP-binding cassette subfamily C member 5 (ABCC5), we identified a class of mammalian metabolites, N-lactoyl-amino acids. Using parallel protein fractionation in conjunction with shotgun proteomics on fractions containing N-lactoyl-Phe-forming activity, we unexpectedly found that a protease, cytosolic nonspecific dipeptidase 2 (CNDP2), catalyzes their formation. N-lactoyl-amino acids are ubiquitous pseudodipeptides of lactic acid and amino acids that are rapidly formed by reverse proteolysis, a process previously considered to be negligible in vivo. The plasma levels of these metabolites strongly correlate with plasma levels of lactate and amino acid, as shown by increased levels after physical exercise and in patients with phenylketonuria who suffer from elevated Phe levels. Our approach to identify unknown metabolites and their biosynthesis has general applicability in the further exploration of the human metabolome.

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