Heterozygous mutations in IDH1 (isocitrate dehydrogenase 1) are found in most grade II and III brain tumors. A slew of mutant IDH1 inhibitors were identified soon after the discovery of IDH1 mutations in brain tumors. But recent reports show that mutant IDH1 inhibitors reverse therapeutic vulnerabilities and activate the oncogenic transcription factor STAT3 in mutant IDH1-expressing cells. Thus, inhibiting mutant IDH1 using mutant IDH1-specific inhibitors can result in drug resistance. Therefore, to block mutant IDH1, it is imperative to identify alternative modes of therapy. In these lines, recent findings show that PROteolysis TArgeting Chimera (PROTAC) molecules can be designed to degrade target proteins in cancer cells. However, it is unknown whether degrading mutant IDH1 leads to STAT3 activation. Therefore, in this study, we asked if degrading mutant IDH1 by employing a PROTAC-based approach leads to STAT3 activation. To answer the question, we adopted the dTAG system, where we fused FKBP12^F36V to mutant IDH1 proteins and used the FKBP12^F36V-specific PROTAC, dTAG-13, to degrade mutant IDH1-FKBP12^F36V. We assessed STAT3 activation in dTAG-13-treated cells expressing mutant IDH1-FKBP12^F36V. We found that fusing FKBP12^F36V-HA to mutant IDH1 phenocopies mutant IDH1 with similar expression levels, enzyme activity, and cellular localization. We observed that dTAG-13 degrades mutant IDH1-FKBP12^F36V-HA in a dose- and time-responsive manner. Unlike inhibiting, degrading mutant IDH1-FKBP12^F36V-HA did not lead to pSTAT3-Y705 activation. We conclude that degrading mutant IDH1 by employing a PROTAC-based approach impairs STAT3 activation. Based on these observations, we suggest that mutant IDH1-specific PROTACs can be developed to degrade mutant IDH1 in gliomas.

01 Dec 2024·STRUCTURE

PROTAC-mediated activation, rather than degradation, of a nuclear receptor reveals complex ligand-receptor interaction network

Article

Author: Miller, Darcie J ; Huber, Andrew D ; Chen, Taosheng ; Poudel, Shyaron ; Huber, Andrew D. ; Lin, Wenwei ; Miller, Darcie J.

Proteolysis-targeting chimeras (PROTACs) are heterobifunctional molecules containing a ligand for a protein of interest linked to an E3 ubiquitin ligase ligand that induce protein degradation through E3 recruitment to the target protein. Small changes in PROTAC linkers can have drastic consequences, including loss of degradation activity, but the structural mechanisms governing such changes are unclear. To study this phenomenon, we screened PROTACs of diverse targeting modalities and identified dTAG-13 as an activator of the xenobiotic-sensing pregnane X receptor (PXR), which promiscuously binds various ligands. Characterization of dTAG-13 analogs and precursors revealed interplay between the PXR-binding moiety, linker, and E3 ligand that altered PXR activity without inducing degradation. A crystal structure of PXR ligand binding domain bound to a precursor ligand showed ligand-induced binding pocket distortions and a linker-punctured tunnel to the protein exterior at a region incompatible with E3 complex formation, highlighting the effects of linker environment on PROTAC activity.

28 Jun 2023·Toxicological sciences : an official journal of the Society of Toxicology

Use of the dTAG system in vivo to degrade CDK2 and CDK5 in adult mice and explore potential safety liabilities.

Article

Author: Wang, Julia ; Kumpf, Steven W ; Bauchmann, Mary ; Biddle, Kathleen ; Ahn, Youngwook ; Arat, Seda ; Vitsky, Allison ; Wang, Shih-Wen ; Esparza, Carlos ; Paul, Tom ; Scott, Wesley ; Sung, Tae ; Steyn, Stefanus ; Affolter, Tim ; Shirai, Norimitsu ; Winrow, Taylor-Symon ; Liu, Ling ; Oyer, Jon ; Qian, Jessie ; Chang, Stephanie ; Hu, Wenyue ; Thibault, Stephane ; Frey, Jessica ; Sacaan, Aida ; Yenerall, Paul ; Palyada, Kiran ; Yang, Amy ; Collette, Walter ; Lum, Lawrence

The degradation tag (dTAG) system for target protein degradation can remove proteins from biological systems without the drawbacks of some genetic methods, such as slow kinetics, lack of reversibility, low specificity, and the inability to titrate dosage. These drawbacks can make it difficult to compare toxicity resulting from genetic and pharmacological interventions, especially in vivo. Because the dTAG system has not been studied extensively in vivo, we explored the use of this system to study the physiological sequalae resulting from CDK2 or CDK5 degradation in adult mice. Mice with homozygous knock-in of the dTAG sequence onto CDK2 and CDK5 were born at Mendelian ratios despite decreased CDK2 or CDK5 protein levels in comparison with wild-type mice. In bone marrow cells and duodenum organoids derived from these mice, treatment with the dTAG degrader dTAG-13 resulted in rapid and robust protein degradation but caused no appreciable change in viability or the transcriptome. Repeated delivery of dTAG-13 in vivo for toxicity studies proved challenging; we explored multiple formulations in an effort to maximize degradation while minimizing formulation-related toxicity. Degradation of CDK2 or CDK5 in all organs except the brain, where dTAG-13 likely did not cross the blood brain barrier, only caused microscopic changes in the testis of CDK2dTAG mice. These findings were corroborated with conditional CDK2 knockout in adult mice. Our results suggest that the dTAG system can provide robust protein degradation in vivo and that loss of CDK2 or CDK5 in adult mice causes no previously unknown phenotypes.

100 Deals associated with FKBP12 PROTAC dTAG-13(Dana-Farber Cancer Institute)

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Indication	Highest Phase	Country/Location	Organization	Date
Leukemia	Preclinical	United States	Dana-Farber Cancer Institute, Inc.	26 Mar 2018
Leukemia	Preclinical	United States	Harvard Medical School	26 Mar 2018

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