Identification and engineering of potent cyclic peptides with selective or promiscuous binding through biochemical profiling and bioinformatic data analysis

As our understanding of biological systems grows, so does the need to selectively target individual or multiple members of specific protein families in order to probe their function. Many targets of current biological and pharmaceutical interest are part of a large family of closely related proteins and achieving ligand selectivity often remains either an elusive or time-consuming endeavour. Cyclic peptides (CPs) occupy a key niche in ligand space, able to achieve high affinity and selectivity while retaining synthetic accessibility. De novo cyclic peptide ligands can be rapidly generated against a given target using mRNA display. In this study we harness mRNA display technology and the wealth of next generation sequencing (NGS) data generated to explore both experimental approaches and bioinformatic, statistical data analysis of peptide enrichment in cross-screen selections to rapidly generate high affinity CPs with differing intra-family protein selectivity profiles against fibroblast growth factor receptor (FGF-R) family proteins. Using these methods, CPs with distinct selectivity profiles can be generated which can serve as valuable tool compounds to decipher biological questions. In this work different methods stemming from mRNA display were investigated toward developing potent binding cyclic peptides with distinct selectivity profiles against targets of a related protein family.

Automated summary

As our understanding of biological systems increases, there is a growing need to selectively target individual or multiple members of specific protein families in order to investigate their function. Cyclic peptides play a crucial role in achieving high affinity and selectivity. This study utilizes mRNA display technology and next generation sequencing data to rapidly generate high affinity cyclic peptides with different selectivity profiles against a family of closely related proteins.