Summary
Traditional drug design relies on inhibition of enzymes or receptors with accessible hydrophobic pockets. The concept of proteolysis targeting chimeras (PROTACs) promised to overcome this limitation. Following our discovery of the first PROTAC that induced selective protein degradation in vivo, this technology has seen a boost in academia and industry. Despite global research efforts, advances are so far incremental: (i) most focus is on degrading targets that can be liganded and are druggable with conventional inhibitors; (ii) currently, only 3 out of 600 E3 ligases can be exploited. Glue2Degrade aims to transform the pharmacologically targetable space of the proteome. The project is built on the hypothesis that molecular glues (MGs), non-chimeric small molecules that degrade target proteins by inducing cooperative binding to E3 ligases, are much more prevalent than anticipated. Lenalidomide and related immunomodulatory drugs (IMiDs) are prime examples of the potential of MGs. Without a specific targeting moiety, IMiDs induce cooperative binding of the E3 ligase CRBN to undruggable proteins like IKZF1/3, thereby inducing their degradation. However, no technologies exist to rationally develop MGs that hijack other E3 ligases. ERC-funding would allow us to address this limitation. Based on data generated in my laboratory, we will systematically identify novel MGs and their E3 ligases by innovating (i) phenotypic discovery strategies, and (ii) an orthogonal chemical genetics pipeline. To elucidate the mechanisms of novel MGs, we will (iii) conduct target identification via unbiased proteomics followed by (iv) chemical optimization and initial translational characterization. Glue2Degrade, if successful, will transform the engageable E3 space and identify novel MGs, thereby opening up the potential for therapeutic development of cell-, tissue-, and cancer-type specific chemical degraders for undruggable proteins.
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| Web resources: | https://cordis.europa.eu/project/id/851478 |
| Start date: | 01-01-2020 |
| End date: | 31-12-2024 |
| Total budget - Public funding: | 1 331 340,00 Euro - 1 331 340,00 Euro |
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Original description
Traditional drug design relies on inhibition of enzymes or receptors with accessible hydrophobic pockets. The concept of proteolysis targeting chimeras (PROTACs) promised to overcome this limitation. Following our discovery of the first PROTAC that induced selective protein degradation in vivo, this technology has seen a boost in academia and industry. Despite global research efforts, advances are so far incremental: (i) most focus is on degrading targets that can be liganded and are druggable with conventional inhibitors; (ii) currently, only 3 out of 600 E3 ligases can be exploited. Glue2Degrade aims to transform the pharmacologically targetable space of the proteome. The project is built on the hypothesis that molecular glues (MGs), non-chimeric small molecules that degrade target proteins by inducing cooperative binding to E3 ligases, are much more prevalent than anticipated. Lenalidomide and related immunomodulatory drugs (IMiDs) are prime examples of the potential of MGs. Without a specific targeting moiety, IMiDs induce cooperative binding of the E3 ligase CRBN to undruggable proteins like IKZF1/3, thereby inducing their degradation. However, no technologies exist to rationally develop MGs that hijack other E3 ligases. ERC-funding would allow us to address this limitation. Based on data generated in my laboratory, we will systematically identify novel MGs and their E3 ligases by innovating (i) phenotypic discovery strategies, and (ii) an orthogonal chemical genetics pipeline. To elucidate the mechanisms of novel MGs, we will (iii) conduct target identification via unbiased proteomics followed by (iv) chemical optimization and initial translational characterization. Glue2Degrade, if successful, will transform the engageable E3 space and identify novel MGs, thereby opening up the potential for therapeutic development of cell-, tissue-, and cancer-type specific chemical degraders for undruggable proteins.Status
SIGNEDCall topic
ERC-2019-STGUpdate Date
27-04-2024
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