Targeted and directed degradation of MYC mRNA with non-enzymatic peptide nucleic acid degraders

Navn på bevillingshaver

Bengt Herbert Gless

Institution

University of Cambridge, Department of Chemistry with Professor Goncalo Bernardes

Beløb

DKK 820,000

År

2021

Bevillingstype

Internationalisation Fellowships

Hvad?

Certain types of cancer can occur as a result of the dysregulated production of a specific oncogenic protein, which can lead to uncontrolled growth and disease. If the dysregulated protein is a so-called "undruggable" target for conventional therapeutics, alternative strategies are required to treat the disease. In this project, I aim to develop novel molecules that target and degrade the mRNA of such an "undruggable" oncogenic protein, which prevents its translation and results in reduced production of the protein. This approach can potentially attenuate uncontrolled cell growth and give benefits for cancer and tumor treatments.

Hvorfor?

The oncogenic protein target in this project is involved in a large amount of cancers and has strong implications in tumor growth. Nevertheless, no approved treatment options are available to date and therefore new ways of targeting this protein are highly desirable. The anticipated approach of applying molecules that degrade mRNA chemically through a novel mechanism represents an exciting opportunity to pave the way for new therapeutics and to establish a more general platform that could enable us to target specific proteins in a precise manner as an addition to known biology-based methods.

Hvordan?

The project will be carried out with Prof. Gonçalo Bernardes at the University of Cambridge. His world-leading chemical biology group has made important contributions in the fields of protein chemistry and bioconjugation, cancer biology, drug release and RNA technology. This research environment represents the ideal combination of chemistry and biology to conduct this ambitious project, which will involve the synthesis and optimization of novel degrader molecules and their evaluation in various cancer models as potential anti-cancer therapeutics.

Tilbage til oversigtssiden