Allosteric Covalent Inhibitors of the STAT3 Transcription Factor from Virtual Screening

Tibor Viktor Szalai, Vincenzo di Lorenzo, Nikolett Péczka, Levente M. Mihalovits, László Petri, Qirat F. Ashraf, Elvin D. de Araujo, Viktor Honti, Dávid Bajusz, and György M. Keserű

ACS Medicinal Chemistry Letters 2025 16 (6), 991-997

DOI: 10.1021/acsmedchemlett.4c00622

The STAT family of transcription factors are important signaling hubs, with several of them, particularly STAT3, being emerging oncotargets already investigated in clinical trials. The modular structure of STAT3 nominates several of its protein domains as possible drug targets, but their exploitation with potential small-molecule inhibitors has been unevenly distributed so far, with past efforts highly favoring the conserved SH2 domain. Here, we have targeted a sparsely studied binding site at the junction of the coiled-coil and DNA-binding domains and discovered several new lead-like covalent inhibitors by virtual screening. The most favorable hit compound has been explored via structure-guided hit expansion and optimized into a low micromolar inhibitor. This compound can serve as a chemical biology tool against this site in future exploratory studies or form the basis of a more advanced stage of lead optimization.

Covalent Destabilizing Degrader of AR and AR-V7 in Androgen-Independent Prostate Cancer Cells

Charlotte M. Zammit, Cory M. Nadel, Ying Lin, Sajjan Koirala, Elnaz Ahani, Patrick Ryan Potts, and Daniel K. Nomura

Journal of the American Chemical Society 2025

DOI: 10.1021/jacs.5c02801

Androgen-independent prostate cancers, correlated with heightened aggressiveness and poor prognosis, are caused by mutations or deletions in the androgen receptor (AR) or the expression of truncated variants of AR that are constitutively activated. Currently, drugs and drug candidates against AR target the steroid-binding domain to antagonize or degrade AR. However, these compounds cannot therapeutically access largely intrinsically disordered truncated splice variants of AR, such as AR-V7, which only possess the N-terminal transactivation domain and DNA-binding domain and are missing the ligand-binding domain. Targeting intrinsically disordered regions within transcription factors has remained challenging and is considered “undruggable”. Herein, we leverage a cysteine-reactive covalent ligand library in a cellular screen to identify the degraders of AR and AR-V7 in androgen-independent prostate cancer cells. We identified a covalent compound, EN1441, that selectively degrades AR and AR-V7 in a proteasome-dependent manner through direct covalent targeting of intrinsically disordered cysteine C125 in the N-terminal transactivation domain of AR and AR-V7. EN1441 causes significant and selective destabilization of AR and AR-V7, leading to the aggregation of AR/AR-V7 and subsequent proteasome-mediated degradation. Consistent with targeting both AR and AR-V7, we find that EN1441 completely inhibits total AR transcriptional activity in androgen-independent prostate cancer cells expressing both AR and AR-V7 compared with AR antagonists or degraders that only target the ligand-binding domain of full-length AR, such as enzalutamide and ARV-110. Our results put forth a pathfinder molecule EN1441 that targets an intrinsically disordered cysteine within AR to destabilize, degrade, and inhibit both AR and AR-V7 in androgen-independent prostate cancer cells and highlights the utility of covalent ligand discovery approaches in directly targeting, destabilizing, inhibiting, and degrading classically undruggable transcription factor targets.

Advancing Covalent Ligand and Drug Discovery beyond Cysteine

Gibae Kim, R. Justin Grams, and Ku-Lung Hsu

Chemical Reviews 2025

DOI: 10.1021/acs.chemrev.5c00001

Targeting intractable proteins remains a key challenge in drug discovery, as these proteins often lack well-defined binding pockets or possess shallow surfaces not readily addressed by traditional drug design. Covalent chemistry has emerged as a powerful solution for accessing protein sites in difficult to ligand regions. By leveraging activity-based protein profiling (ABPP) and LC-MS/MS technologies, academic groups and industry have identified cysteine-reactive ligands that enable selective targeting of challenging protein sites to modulate previously inaccessible biological pathways. Cysteines within a protein are rare, however, and developing covalent ligands that target additional residues hold great promise for further expanding the ligandable proteome. This review highlights recent advancements in targeting amino acids beyond cysteine binding with an emphasis on tyrosine- and lysine-directed covalent ligands and their applications in chemical biology and therapeutic development. We outline the process of developing covalent ligands using chemical proteomic methodology, highlighting recent successful examples and discuss considerations for future expansion to additional amino acid sites on proteins.

Kinetic Modeling of Covalent Inhibition: Effects of Rapidly Fluctuating Intermediate States

Kyle Ghaby, Benoît Roux

bioRxiv 2025.05.28.656658; 

doi: https://doi.org/10.1101/2025.05.28.656658

There is increasing interest in the discovery of small-molecule inhibitors that form covalent bonds with their targets for therapeutic applications. Nevertheless, identifying clear rational design principles remains challenging because the action of these molecules cannot be understood as common noncovalent inhibitors. Conventional kinetic models often reduce the binding of covalent inhibitors to a two-step irreversible process, overlooking rapid complex dynamics of the associated unlinked inhibitor before the formation of the covalent bond with its target. In the present analysis, we expand the intermediate state into two conformations—reactive (E·I) and nonreactive (E··I). To illustrate the consequences of such simplification, the expanded kinetic model can be reduced to an effective two-step scheme expressed in terms of the equilibrium probability of the unlinked inhibitor to form either conformation. A mass-action-based numerical workflow is implemented to simulate time-dependent kinetics, overcoming the common limitations of empirical models. The numerical workflow helps relate microscopic states observed in molecular dynamics simulations to macroscopic observables like EC50 and the apparent rate of covalent inhibition, showing the impact of transient intermediates on dissociation rates and potency. The proposed framework refines the interpretation of dose-response data, aiding medicinal chemists in optimizing covalent inhibitors and provides a quantitative platform for relating molecular conformational distributions to empirical parameters.

Use of new approach methodology for hepatic safety assessment of covalent inhibitor drug candidates

Sara Amberntsson, Alison J Foster, Bhavik Chouhan, Stephen Wilkinson, Stephanie Harlfinger, Graham Smith, Jason G Kettle, Michael Niedbala, Stefan Kavanagh, Dominic P Williams

Toxicology Research, 2025, 14, 3, tfaf054, 

https://doi.org/10.1093/toxres/tfaf054

Interest in inhibiting target proteins through covalent binding mechanisms has increased in the last decade due to the potential for beneficial pharmacological properties. However, the inherent targeted covalent inhibitor (TCI) adverse off-target reactivity risk requires a mitigation strategy early during drug discovery. The aim of this research was to design a pre-clinical hepatic safety assessment strategy for TCIs considering risk associated with electrophilic warhead reactivity and reactive metabolites formation at clinically-relevant plasma concentrations.

The mitigation strategy was applied to compound 35, a potent irreversible inhibitor to KRASG12C. Drug induced liver injury was assessed in primary human hepatocyte spheroids. GSH and ATP depletion were investigated for compound 35 and 6 other marketed TCIs containing an acrylamide warhead which binds irreversibly to cysteine-containing target proteins. None of the TCIs showed GSH depletion prior to ATP depletion after 7-days exposure, suggesting that GSH depletion was not driving cytotoxicity in the spheroids. The calculated hepatotoxicity margin towards plasma exposure of 2.5 for compound 35 was found to be in the same range as for the two KRASG12Cinhibitors adagrasib and sotorasib, with clinically reported treatment-related adverse aminotransferase elevations leading to dose modifications. The safety evaluation reported here suggests no negative discrepancy in liver toxicity for compound 35 versus similar approved TCI’s. Finally, the risk associated with detected oxidative metabolites was further mitigated as the pan-CYP450 inhibitor 1-aminobenzotriazole (ABT) had no effect on the cytotoxicity response following incubation of compound 35 in the presence and absence of ABT.

Zongertinib (BI 1810631), an Irreversible HER2 TKI, Spares EGFR Signaling and Improves Therapeutic Response in Preclinical Models and Patients with HER2-Driven Cancers

Birgit Wilding, Lydia Woelflingseder, Anke Baum, Krzysztof Chylinski, Gintautas Vainorius, Neil Gibson, Irene C. Waizenegger, Daniel Gerlach, Martin Augsten, Fiona Spreitzer, Yukina Shirai, Masachika Ikegami, Sylvia Tilandyová, Dirk Scharn, Mark A. Pearson, Johannes Popow, Anna C. Obenauf, Noboru Yamamoto, Shunsuke Kondo, Frans L. Opdam, Annemarie Bruining, Shinji Kohsaka, Norbert Kraut, John V. Heymach, Flavio Solca, Ralph A. Neumüller

Cancer Discov (2025) 15 (1): 119–138.

https://doi.org/10.1158/2159-8290.CD-24-0306

Mutations in ERBB2 (encoding HER2) occur in 2% to 4% of non–small cell lung cancer (NSCLC) and confer poor prognosis. ERBB-targeting tyrosine kinase inhibitors, approved for treating other HER2-dependent cancers, are ineffective in HER2-mutant NSCLC due to dose-limiting toxicities or suboptimal potency. We report the discovery of zongertinib (BI 1810631), a covalent HER2 inhibitor. Zongertinib potently and selectively blocks HER2, while sparing EGFR, and inhibits the growth of cells dependent on HER2 oncogenic driver events, including HER2-dependent human cancer cells resistant to trastuzumab deruxtecan. Zongertinib displays potent antitumor activity in HER2-dependent human NSCLC xenograft models and enhances the activities of antibody–drug conjugates and KRASG12C inhibitors without causing obvious toxicities. The preclinical efficacy of zongertinib translates in objective responses in patients with HER2-dependent tumors, including cholangiocarcinoma (SDC4–NRG1 fusion) and breast cancer (V777L HER2 mutation), thus supporting the ongoing clinical development of zongertinib.

Significance: HER2-mutant NSCLC poses a challenge in the clinic due to limited options for targeted therapies. Pan-ERBB blockers are limited by wild-type EGFR–mediated toxicity. Zongertinib is a highly potent and wild-type EGFR–sparing HER2 inhibitor that is active in HER2-driven tumors in the preclinical and clinical settings.

Design, synthesis and biological evaluation of the activity-based probes for FGFR covalent inhibitor

Dandan Zhu, Zijian Zheng, Huixin Huang, Xiaojuan Chen, Shuhong Zhang, Zhuchu Chen, Ting Liu, Guangyu Xu, Ying Fu, Yongheng Chen,

European Journal of Medicinal Chemistry, 2025

https://doi.org/10.1016/j.ejmech.2025.117795

Fibroblast growth factor receptors (FGFRs) represent promising therapeutic targets in various malignancies, yet the clinical application of FGFR covalent inhibitors has been impeded by several significant challenges, including unquantifiable target engagement, undefined off-target effects, and the emergence of drug resistance. In this study, we designed and synthesized a series of FGFR activity-based probes (ABPs) derived from FIIN-2, a pioneering selective, next-generation irreversible covalent FGFR inhibitor with demonstrated efficacy against gatekeeper mutations. Among them, FP1 exhibited comparable inhibitory potency to FIIN-2. FP1 could facilitate precise in vitro and in situ labeling and visualization of both FGFR1-4 and their mutants. Utilizing FP1, we successfully mapped the target spectrum of FIIN-2 in MDA-MB-453 cells through activity-based protein profiling (ABPP), and established a robust framework for employing our probe as a generalizable tool to systematically evaluate the on- and off-target activities of prospective FGFR covalent inhibitors. Overall, the FGFR ABP offers a promising strategy for elucidating the engagement of FGFR, profiling the target specificity and mechanisms of covalent FGFR inhibitors, and offering potential avenues for overcoming drug resistance.