Practical Chemical Synthesis of Atypical Ubiquitin Chains by Using an Isopeptide‐Linked Ub Isomer

Chemical ubiquitination is an effective approach for accessing structurally defined, atypical ubiquitin (Ub) chains that are difficult to prepare by other techniques. Herein, we describe a strategy that uses a readily accessible premade isopeptide‐linked 76‐mer (isoUb), which has an N‐terminal Cys and a C‐terminal hydrazide, as the key building block to assemble atypical Ub chains in a modular fashion. This method avoids the use of auxiliary‐modified Lys and instead employs the canonical and therefore more robust Cys‐based native chemical ligation technique. The efficiency and capacity of this isoUb‐based strategy is exemplified by the cost‐effective synthesis of several linkage‐ and length‐defined atypical Ub chains, including K27‐linked tetra‐Ub and K11/K48‐branched tri‐, tetra‐, penta‐, and hexa‐Ubs.     

An Orthogonal D2O‐Based Induction System that Provides Insights into d‐Amino Acid Pattern Formation by Radical S‐Adenosylmethionine Peptide Epimerases

Radical S‐adenosyl methionine peptide epimerases (RSPEs) are an enzyme family that accomplishes regiospecific and irreversible introduction of multiple d ‐configured residues into ribosomally encoded peptides. Collectively, RSPEs can generate diverse epimerization patterns in a wide range of substrates. Previously, the lack of rapid methods to localize epimerized residues has impeded efforts to investigate the function and applicative potential of RSPEs. An efficient mass spectrometry‐based assay is introduced that permits characterization of products generated in E. coli . Applying this to a range of non‐natural peptide‐epimerase combinations, it is shown that the d ‐amino acid pattern is largely but not exclusively dictated by the core peptide sequence, while the epimerization order is dependent on the enzyme‐leader pair. RSPEs were found to be highly promiscuous, which allowed for modular introduction of peptide segments with defined patterns.     

Werkzeug für die Chemische Biologie. Semisynthese

Semisynthetic techniques have greatly contributed to the rapid development of Chemical Biology in recent years. In this regard the semisynthesis of complex modified proteins as well as the selective derivatization of natural products has evolved into more than mere proof‐of‐principle concepts but powerful tools to probe protein functions. This technology provides a solid basis for further investigations on proteomics and qualitative and quantitative cell biology. The interdisciplinary charter bridging chemistry and biology is the hallmark of semisynthesis. It can be expected that its scientific impact will further increase in the future.     

Mechanism‐Based Inhibitors of the Human Sirtuin 5 Deacylase: Structure–Activity Relationship,Biostructural, and Kinetic Insight

The sirtuin enzymes are important regulatory deacylases in a variety of biochemical contexts and may therefore be potential therapeutic targets through either activation or inhibition by small molecules. Here, we describe the discovery of the most potent inhibitor of sirtuin 5 (SIRT5) reported to date. We provide rationalization of the mode of binding by solving co‐crystal structures of selected inhibitors in complex with both human and zebrafish SIRT5, which provide insight for future optimization of inhibitors with more “drug‐like” properties. Importantly, enzyme kinetic evaluation revealed a slow, tight‐binding mechanism of inhibition, which is unprecedented for SIRT5. This is important information when applying inhibitors to probe mechanisms in biology.