A NanoBRET-based assay monitoring interactions in the USP18 signaling hub identifies the first cell-penetrant small molecule compromising USP18/ISG15 binding

Protein modification by interferon-stimulated gene 15 (ISG15), termed ISGylation, exhibits antiviral properties and influences tumorigenesis, genome stability and metabolic processes. ISGylation is counteracted by the specific protease USP18. Likewise, viral proteases such as the papain-like protease (PLpro) from SARS-CoV-2 cleave ISG15 to undermine the host immune response. Beyond its role as a deISGylating enzyme, USP18 acts as a major negative regulator of the IFN signaling pathway in a STAT2-dependent manner. In humans, unconjugated ISG15 secures USP18 stability and the absence of USP18 or impaired STAT2/USP18 binding cause fatal interferonopathies. Thus, the USP18 signaling hub represents a critical checkpoint for type I IFN signaling and ISGylation, qualifying it as a promising immune and cancer drug target. However, suitable assays to monitor protein-protein interactions (PPIs) within the USP18/ISG15/STAT2 signaling hub and to screen for PPI modulators are missing and no specific inhibitors targeting USP18 interactions are available. To address this gap, we developed a method based on the NanoLuc luciferase (NLuc) Bioluminescence Energy Transfer (NanoBRET) assay system to study PPIs. Firstly, we generated stable cell lines suitable to monitor USP18/ISG15 and USP18/STAT2 interactions, providing a semi high-throughput screening (HTS)-compatible platform. In combination with a virtual pre-screen of 60,000 compounds against USP18 in silico, this assay allowed us to identify a first small molecule (ZHAWOC8655) that compromises cellular USP18/ISG15 binding and inhibits USP18 protease activity in vitro. To further explore the potential of using the NanoBRET system for testing PPI modulators, we evaluated the effect of GRL0617, a compound which was shown to disrupt the interaction between SARS-CoV-2 PLpro/ISG15 as well as SARS-CoV-2 PLpro/ubiquitin. NanoBRET based stable cell lines as presented here will be suitable for monitoring PPIs in other multiprotein complexes after various stimuli, mutations or small molecule administration and can be challenged with siRNA or CRISPR/Cas9 libraries to identify previously unrecognized regulators.