Covalent hitchhikers guide proteins to the nucleus.

In this issue of Cell Chemical Biology, Peng and Weerapana1 report the combination of chemoproteomic and proximity-based labeling approaches to identify cysteines in nuclear proteins that are reactive toward electrophilic probe compounds. They apply this novel technology to identify proteins that are localized to the nucleus and chromatin upon probe labeling.

The semisynthesis of site-specifically modified histones and histone-based probes of chromatin-modifying enzymes.

Histone post-translational modifications (PTMs) on lysine residues, including methylation, ubiquitylation, and sumoylation, have been studied using semisynthetic histones reconstituted into nucleosomes. These studies have revealed the in vitro effects of histone PTMs on chromatin structure, gene transcription, and biochemical crosstalk. However, the dynamic and transient nature of most enzyme-chromatin interactions poses a challenge toward identifying specific enzyme-substrate interactions. To address this, we report methodology for the synthesis of two ubiquitylated activity-based probe histones, H2BK120ub(G76C) and H2BK120ub(G76Dha), that may be used to trap enzyme active-site cysteines as disulfides or in the form of thioether linkages, respectively. The general synthetic method we report for converting ubiquitylated nucleosomes into activity-based probes may also be applied to other histone sites of ubiquitylation in order to facilitate the identification of enzyme-chromatin interactions.

Synthesis of an acyl-acyl carrier protein synthetase inhibitor to study fatty acid recycling.

Fatty acids are essential to most organisms and are made endogenously by the fatty acid synthase (FAS). FAS is an attractive target for antibiotics and many inhibitors are in clinical development. However, some gram-negative bacteria harbor an enzyme known as the acyl-acyl carrier protein synthetase (AasS), which allows them to scavenge fatty acids from the environment and shuttle them into FAS and ultimately lipids. The ability of AasS to recycle fatty acids may help pathogenic gram-negative bacteria circumvent FAS inhibition. We therefore set out to design and synthesize an inhibitor of AasS and test its effectiveness on an AasS enzyme from Vibrio harveyi, the most well studied AasS to date, and from Vibrio cholerae, a pathogenic model. The inhibitor C10-AMS [5'-O-(N-decanylsulfamoyl)adenosine], which mimics the tightly bound acyl-AMP reaction intermediate, was able to effectively inhibit AasS catalytic activity in vitro. Additionally, C10-AMS stopped the ability of Vibrio cholerae to recycle fatty acids from media and survive when its endogenous FAS was inhibited with cerulenin. C10-AMS can be used to study fatty acid recycling in other bacteria as more AasS enzymes continue to be annotated and provides a platform for potential antibiotic development.