Molecular Glues: Capable Protein-Binding Small Molecules That Can Change Protein–Protein Interactions and Interactomes for the Potential Treatment of Human Cancer and Neurodegenerative Diseases

Abstract: Molecular glue (MG) compounds are a type of unique small molecule that can change the protein–protein interactions (PPIs) and interactomes by degrading, stabilizing, or activating the target protein after their binging. These small-molecule MGs are gradually being recognized for their potential application in treating human diseases, including cancer. Evidence suggests that small-molecule MG compounds could essentially target any proteins, which play critical roles in human disease etiology, where many of thes… Show more

“…Molecular glue degraders have emerged as a powerful therapeutic modality, as demonstrated by the clinical successes of thalidomide analogs in the treatment of hematological malignancies 4,5 . These small molecule degraders stabilize the protein-protein interface between ubiquitin ligases and disease-relevant neosubstrates, resulting in ubiquitination and proteasomal degradation of the targets 6 . Unlike traditional occupancy-driven pharmacology of inhibitors, the event-driven pharmacology of degraders can result in more potent and sustained drug activity 7 .…”

“…The clinical efficacy of thalidomide derived drugs, such as lenalidomide, and the broad utility of targeted protein degradation in research and drug discovery has inspired numerous efforts to explore proximity-driven pharmacology 10-12 . While bi-functional molecules such as PROTACs can lead to rapid proof of concept and highly potent chemical probes, molecular glues are favorable for clinical development due to reduced size and overall chemical properties 6,9 . Despite these advantages, to date, only a small number of ubiquitin ligases have been exploited by molecular glue degraders, including CRBN 1,2 , DCAF15 13 and DDB1 14-16 .…”

“… Abstract Small molecules that induce protein-protein interactions to exert proximity-driven pharmacology such as targeted protein degradation are a powerful class of therapeutics 1-3 . Molecular glues are of particular interest given their favorable size and chemical properties and represent the only clinically approved degrader drugs 4-6 . The discovery and development of molecular glues for novel targets, however, remains challenging.…”

Template-assisted covalent modification of DCAF16 underlies activity of BRD4 molecular glue degraders

“…Molecular glue degraders have emerged as a powerful therapeutic modality, as demonstrated by the clinical successes of thalidomide analogs in the treatment of hematological malignancies 4,5 . These small molecule degraders stabilize the protein-protein interface between ubiquitin ligases and disease-relevant neosubstrates, resulting in ubiquitination and proteasomal degradation of the targets 6 . Unlike traditional occupancy-driven pharmacology of inhibitors, the event-driven pharmacology of degraders can result in more potent and sustained drug activity 7 .…”

“…The clinical efficacy of thalidomide derived drugs, such as lenalidomide, and the broad utility of targeted protein degradation in research and drug discovery has inspired numerous efforts to explore proximity-driven pharmacology 10-12 . While bi-functional molecules such as PROTACs can lead to rapid proof of concept and highly potent chemical probes, molecular glues are favorable for clinical development due to reduced size and overall chemical properties 6,9 . Despite these advantages, to date, only a small number of ubiquitin ligases have been exploited by molecular glue degraders, including CRBN 1,2 , DCAF15 13 and DDB1 14-16 .…”

“… Abstract Small molecules that induce protein-protein interactions to exert proximity-driven pharmacology such as targeted protein degradation are a powerful class of therapeutics 1-3 . Molecular glues are of particular interest given their favorable size and chemical properties and represent the only clinically approved degrader drugs 4-6 . The discovery and development of molecular glues for novel targets, however, remains challenging.…”

Template-assisted covalent modification of DCAF16 underlies activity of BRD4 molecular glue degraders

“…15,16 Further, multiple weak noncovalent interactions such as electrostatics, hydrogen-bonding and van der Waals forces cause adhesion aiding in various biological processes such as the recruitment of white blood cells to inamed tissue, 17 adherence of inuenza virus, 18 and cell division. 19 Synthetic supramolecular systems featuring multivalent non-covalent interactions, termed "molecular glues", 20 provide an efficient scaffold for biomolecular adhesion 21 that have been useful to tailor various natural processes including protein-protein interactions, 22,23 protein-ligand interactions, 24 enzyme inhibition, 25,26 viral inhibition 27 and actomyosin sliding motion 21 in a site-selective manner. However, the utility of such molecular glues in the augmentation of the activity of biocatalytic cascades is non-existent.…”

A transient vesicular glue for amplification and temporal regulation of biocatalytic reaction networks

“…[15][16] Further, multiple weak non-covalent interactions such as electrostatics, hydrogen-bonding and van der Waals forces cause adhesion aiding in various biological processes such as the recruitment of white blood cells to inflamed tissue, 17 adherence of influenza virus, 18 and cell division. 19 Synthetic supramolecular systems featuring multivalent non-covalent interactions, termed "molecular glue", 20 provides an efficient scaffold for biomolecular adhesion 21 that have been useful to tailor various natural processes including protein-protein interactions, [22][23] protein-ligand interactions, 24 enzyme inhibition, [25][26][27] viral inhibition [28][29] and actomyosin sliding motion 21 in a site-selective manner. However, the utility of such molecular glues in the augmentation of the activity of biocatalytic cascades is non-existent.…”

A Dissipative Supramolecular Glue for Temporal Control of Amplified Enzyme Activity and Biocatalytic Cascades