Fragments vs the E3 ligase KLHL12

Last week we highlighted work out of Steve Fesik’s lab at Vanderbilt University about PLPro. This week we’ll highlight another paper just published (open access) in J. Med. Chem. on a different subject from Steve, Alex Waterson, and colleagues.

 

Targeted protein degradation has been receiving increasing attention. The most common approach uses bivalent molecules called PROTACs. Imagine a molecular barbell, where the weight plate on each end is a different ligand, one targeting an E3 ligase and the other targeting a protein to degrade. As he discussed at the DDC meeting in 2023, Steve has long been pursuing ligands against previously unexplored E3 ligases with desirable properties, such as tissue-specific expression. A PROTAC using an E3 found predominantly in cancer cells could degrade essential proteins while sparing proteins in normal cells, and so yield safer drugs. The E3 ligase Kelch-like protein 12 (KLHL12) is overexpressed in many cancers but not expressed in heart tissue. The new paper describes fragment screening and optimization of ligands for this ligase.

 

The researchers started with a protein-detected ¹H-¹⁵N correlation NMR screen of 13,824 fragments in pools of 12, each at 0.8 mM. This yielded just 35 hits, of which 15 showed similar chemical shifts to those caused by a peptide substrate, suggesting that they bind in the same site. Dose-response experiments were used to determine affinities, with compound 1 being the best.

A crystal structure of this molecule bound to KLHL12 confirmed that it binds in the substrate-binding cleft, but the resolution was insufficient to determine the precise orientation. Nonetheless, SAR around the aniline moiety led to more potent molecules such as compound 7c, and exploration around the benzimidazole led to compound 7k, with sub-micromolar affinity as assessed both by a fluorescence polarization anisotropy (FPA) assay as well as SPR.

 

A crystal structure of 7k bound to KLHL12 was solved at high resolution, explaining the SAR and also revealing tempting space for further growing. Disappointingly though, most of the dozens of analogs had at best low micromolar affinity, and the few that had comparable activity to compound 7k had significantly worse ligand efficiencies. KLHL12 is homologous to the protein KEAP1, which as we noted last year has also proven challenging for conventionally drug-like ligands.

 

In addition to KEAP1, KLHL12 has more than 35% sequence identity to nine other proteins, so selectivity is a potential concern. Unfortunately, these proteins proved difficult to express. However, one compound tested was selective for KLHL12 over KEAP1.

 

Finally, a small set of compounds was tested for in-cell KLHL12 engagement using a nanoBRET assay. Happily, compound 7k proved active at sub-micromolar concentrations, suggesting that cell permeability would not be an issue.

 

This is a nice fragment to lead story. The relatively flat SAR for many of the compounds, while undoubtedly frustrating, should be useful for further understanding molecular recognition. It is not clear whether compound 7k is sufficiently potent to be useful, but as the researchers conclude, the work “provides a promising foundation for the future design and synthesis of KLHL12-based PROTACs.”