A Designed Enzyme Promotes Selective Post‐translational Acylation

A computationally designed, allosterically regulated catalyst (CaM M144H) produced by substituting a single residue in calmodulin, a non‐enzymatic protein, is capable of efficient and site selective post‐translational acylation of lysines in peptides with highly diverse sequences. Calmodulin′s binding partners are involved in regulating a large number of cellular processes; this new chemical‐biology tool will help to identify them and provide structural insight into their interactions with calmodulin.     

Front Cover: Chemoselective Labeling and Immobilization of Phosphopeptides with Phosphorimidazolide Reagents (ChemBioChem 4/2023)

Protein phosphorylation is one of the most ubiquitous post-translational modifications, regulating numerous essential processes in cells. Accordingly, the large-scale annotation of phosphorylation sites continues to provide central insight into the regulation of signaling networks. The global analysis of the phosphoproteome typically relies on mass spectrometry analysis of phosphopeptides, with an enrichment step necessary due to the sub-stoichiometric nature of phosphorylation. Several affinity-based methods and chemical modification strategies have been developed to date, but the choice of enrichment method can have a considerable impact on the results. Here, we show that a biotinylated, photo-cleavable phosphorimidazolide reagent permits the immobilization and subsequent cleavage of phosphopeptides. The method is capable of the capture and release of phosphopeptides of varying characteristics, and this mild and selective strategy expands the current repertoire for phosphopeptide chemical modification with the potential to enrich and identify new phosphorylation sites in the future.     

Cover Picture: Semisynthesis and Characterization of the First Analogues of Pro‐Neuropeptide Y (ChemBioChem 5/2003)

The cover picture shows how a combination of recombinant synthesis and chemical synthesis has been used to obtain chemically modified proteins. N‐terminal protein segments of pro‐neuropeptide Y (proNPY) were produced as intein‐fusion proteins in Escherischia coli in order to obtain thioesters. C‐terminal segments were synthesized by parallel automated peptide synthesis and derivatized to obtain carboxyfluorescein‐ (CF) and biotin‐labeled peptides. Native chemical ligation yielded chemically modified full‐length analogues of proNPY that can be used to monitor the biosynthesis of neuropeptide Y. Futher information can be found in the article by Beck‐Sickinger and co‐workers on p. 425 ff.     

Cover Picture: Selective Protein Degradation by Ligand‐Targeted Enzymes: Towards the Creation of Catalytic Antagonists (ChemBioChem 6/2003)

The cover picture shows a ligand‐targeted proteinase enzyme or “catalytic antagonist” acting as a molecular angler fish: By precisely positioning different binding ligands (L) around the active site “mouth” of a degradative proteinase enzyme, target proteins (TP) can be plucked from solution, locked in position adjacent to the catalytic triad “jaws”, and in this way readily and specifically degraded. The hunting strategy of the deep sea angler fish, which uses a lure above its mouth, illustrates this principle. Further details can be found in the article by B. Davis, R. R. Bott, J. B. Jones et. al. on pp. 533–537.