Bioactive Peptides as Pharmacological Tools and Novel Drug Leads. Bioactive peptides are produced by all organisms and play numerous critical physiological roles, including in cellular communication, host defence and capture of prey. Peptides have huge potential as tools for studying roles of signalling pathways and as novel drugs due to their high affinity and selectivity for various therapeutically relevant targets. However their use has been limited by poor in vivo stability. This project is ....Bioactive Peptides as Pharmacological Tools and Novel Drug Leads. Bioactive peptides are produced by all organisms and play numerous critical physiological roles, including in cellular communication, host defence and capture of prey. Peptides have huge potential as tools for studying roles of signalling pathways and as novel drugs due to their high affinity and selectivity for various therapeutically relevant targets. However their use has been limited by poor in vivo stability. This project is focused on studying structural features of a range of peptides and their contributions to both activity and to resistance against degradation, with the aim to develop stabilised bioactive peptide sequences for in vivo applications, allowing the full potential of peptides as drugs to be realised.Read moreRead less
Genetic code expansion of a eukaryotic in vitro translation system. The genetic code programs biosynthesis of polypeptides with efficiency vastly superior to chemical engineering. As the chemical diversity of natural amino acids in proteins is limited, finding ways to include “unnatural” amino acids can supercharge biology with a range of new protein activities. While the genetic code can be expanded to make space for unnatural amino acids, the rarity of free codons and reliance on prokaryotic ....Genetic code expansion of a eukaryotic in vitro translation system. The genetic code programs biosynthesis of polypeptides with efficiency vastly superior to chemical engineering. As the chemical diversity of natural amino acids in proteins is limited, finding ways to include “unnatural” amino acids can supercharge biology with a range of new protein activities. While the genetic code can be expanded to make space for unnatural amino acids, the rarity of free codons and reliance on prokaryotic organisms limit the applicability of this approach. We will develop a new higher-organism cell-free protein production system that can incorporate multiple unnatural amino acids into defined points of proteins. This, enabling and broadly applicable technology, will be tested by constructing opioid biosensors.Read moreRead less