Research Reveals Trivalent PROTACs More Potent in Targeted Protein Degradation

by Lucy Shaw Contributor

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University of Dundee and Promega researchers show three heads are better than two in novel drug discovery concept

Researchers from the University of Dundee and Promega Corporation have shown how a “three-headed hydra” significantly improves efficacy in targeted protein degradation. This discovery opens new possibilities in a field that is revolutionizing drug discovery for cancer and other targets. The research is published today in Nature Chemical Biology.

Targeted Protein Degradation

Targeted protein degradation is an area of chemical biology that is revolutionizing drug discovery. It involves co-opting the cell’s natural disposal systems to also remove disease-causing proteins. This system is applicable to diverse therapeutic areas including oncology, inflammation, dermatology, immunology, and respiratory diseases.

Degrading a target protein offers several advantages over traditional inhibitors. This type of drug may show a greater response even at lower doses, and it is more precise with potentially reduced side effects and disease resistance. The first compounds in this class, termed Proteolysis-targeting chimeras (PROTACs), are being trialed as candidate medicines against various cancers and progressing through clinical trials.

PROTACs are conventionally small molecules designed with two heads, called bivalent or heterobifunctional compounds. However, new research carried out by Dundee’s Centre for Targeted Protein Degradation (CeTPD) in collaboration with biotechnology company Promega broke away from this conventional design and showed that degraders can be significantly improved by making them trivalent, i.e., consisting of three heads.

Novel Trivalent PROTACs

The best trivalent PROTAC designed by the researchers proved to be remarkably more potent than their bivalent predecessor compounds, showing in cellular studies stronger anti-cancer activity at a much lower dose and improved pharmacological responses over a wider dose range.

“Three heads can be better than two in PROTACs,” says Dr. Alessio Ciulli, Director of the Center for Targeted Protein Degradation. “We hypothesized that we could improve degraders by latching onto the target protein more productively. To do this, we designed trivalent PROTACs by adding an additional protein-binding ligand, in effect creating a three-headed monster that destroys cancer-causing proteins more effectively.”

The Dundee/Promega team demonstrated that the new PROTAC works due to the combined effect of two important features of protein and small molecule molecular recognition – avidity and cooperativity. Avidity refers to the combined strength of multiple interactions between two molecules. Cooperativity is a phenomenon shown by molecules with multiple binding sites in which the affinity of the remaining binding sites is increased after a ligand binds to one of them.

The researchers conclude that the trivalent PROTAC concept offers a new strategy that is shown to improve on many aspects of degrader drug action and could in future be applied to a wider range of protein targets, including those thought to be undruggable. If this is shown to be the case, it raises the possibility of scientists being able to develop drugs more easily for diseases for which there are currently no effective treatments, greatly expanding the number of available therapeutics.

“We took a significant risk with this project, but its success has opened new doors for the design of highly potent degraders, as well as other multi-specific compounds,” says Dr. Danette Daniels, Senior Research Scientist and Group Leader at Promega Corporation.

Learn More

For more information, read the paper published today in Nature Chemical Biology.

To learn more about Targeted Protein Degradation at Promega, visit www.promega.com/NatureTPD

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