Ubiquitin-Derived Fragment as a Peptide Linker for the Efficient Cleavage of a Target Protein from a Degron.

The chemogenetic control of cellular protein stability using degron tags is a powerful experimental strategy in biomedical research. However, this technique requires permanent fusion of the degron to a target protein, which may interfere with the proper function of the protein. Here, we report a peptide fragment from the carboxyl terminus of ubiquitin as a cleavable linker that exhibits the slow but efficient cleavage of a degron tag via cellular deubiquitinating enzymes (DUBs). We designed a fusion protein consisting of a cleavable linker and a destabilizing domain (DD), which conditionally controls the expression and release of a target protein in a ligand-induced state, allowing the free unmodified protein to perform its function. Insertion of an AGIA epitope at the carboxyl terminus of the linker made space for the DUBs to access the site to assist the cleavage reaction when the amino terminus of the target protein caused steric hindrance. The developed system, termed a cleavable degron using ubiquitin-derived linkers (c-DUB), provides robust and tunable regulation of target proteins in their native forms. The c-DUB system is a useful tool for the regulation of proteins that have terminal sites that are essential for the proper localization and function. In addition, a mechanistic investigation using proximity labeling showed that DUBs associate with the refolded DD to reverse ubiquitination, suggesting a cellular surveillance system for distinguishing the refolded DD from misfolded proteins. The c-DUB method may benefit from this machinery so that DUBs subsequently cleave the neighboring linker.

A strategy for orthogonal deubiquitination using a bump-and-hole approach.

We have successfully applied a bump-and-hole approach to establish orthogonal deubiquitination in which a ubiquitin substrate variant is specifically targeted by an engineered deubiquitinating enzyme (DUB). This makes it possibe to selectively observe and measure a single type of DUB activity in living cells.

A Method for Conditional Regulation of Protein Stability in Native or Near-Native Form.

Here, we report a method to regulate cellular protein levels by introducing a ubiquitin variant between a destabilizing domain (DD) and the regulated protein. When produced in the absence of a stabilizing ligand the DD dominates and the entire fusion protein is processively degraded by the proteasome. In the presence of the stabilizing ligand the fusion protein is metabolically stable and becomes a substrate for abundant ubiquitin-specific proteases, liberating a native, or a near-native protein-of-interest. This technique is thus particularly useful for the study of proteins whose free N terminus is required for proper function. In addition, removal of the DD in the presence of stabilizing ligand leads to higher expression levels of regulated protein when cells experience transient exposure to a stabilizing ligand, such as in a living animal receiving a single dose of a pharmacological agent as the stabilizing ligand.

Importance of the Proximity and Orientation of Ligand-Linkage to the Design of Cinnamate-GW9662 Hybrid Compounds as Covalent PPARγ Agonists.

Covalent agonists of PPARγ cause unique receptor conformational changes and behave as selective PPARγ modulators, whereas there are few covalent agonists other than endogenous unsaturated fatty acids metabolites. Previously, we established a cell-based strategy to identify new PPARγ ligands and synthesized a new-type of covalent agonist that possesses the hybrid structure of a plant-derived cinnamic acid derivative and GW9662, a covalent antagonist. Herein, we report six analogues that differ in how the two fragments are linked together. Compounds with a simplified linker showed potent agonistic activity with improved EC50 values (less than 5 nM), indicating that close proximity between the two fragments improves binding affinity. When the position of cinnamic acid moiety was placed at 4' carbon of aniline ring, PPARγ agonist activity was completely abolished. Docking studies suggested that the activation profile likely depends on interaction with the cavity around helix 3, ß-sheet, and Ω-loop region in the ligand-binding domain. Furthermore, a cell-based assay revealed that agonist-type compounds activate PPARγ transcription in a manner dependent on covalent linkage with the Cys285 residue leading to prolonged transactivation. This activation feature reflects pharmacological benefits of covalent drugs, suggesting that these hybrid compounds may serve as potential leads for a new-class of covalent PPARγ ligands.