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University of Cambridge > Talks.cam > Biological Chemistry Research Interest Group > Discovery of cyclotides and their applications in peptide-based drug design
Discovery of cyclotides and their applications in peptide-based drug designAdd to your list(s) Download to your calendar using vCal
If you have a question about this talk, please contact spring. Our work focuses on the discovery of cyclic peptides in plants and their applications in drug design and agriculture. We have a particular interest in a family of proteins called cyclotides, which comprise ~30 amino acids and incorporate three disulfide bonds arranged in a cystine knot topology, which makes them exceptionally stable.1 Cyclotides occur in all plants from the Violaceae family and in certain plants from the Rubiaceae, Cucurbitaceae, Solanaceae and Fabaceae, where they are present as host defence agents against insects and nematodes.2 A single plant may contain dozens to hundreds of cyclotides expressed in a wide range of tissues, including leaf, flower, stem and roots. Their stability and compact structure makes cyclotides an attractive protein framework onto which bioactive peptide epitopes can be grafted to stabilise them.3 Because plants produce cyclotides in large quantities (up to 2g/kg plant weight) we are using crop plants as expression systems for the production of pharmaceutically active cyclotides. This presentation will give an overview on the discovery, biosynthesis and applications of cyclotides and also describe the use of transgenic plants as vehicles for the production of cyclotide-based drug leads for cancer, cardiovascular disease and pain.4 1. Craik D J : Seamless proteins tie up their loose ends. Science, 311, 1563-1564 (2006). 2. Gilding E K , Jackson M A , Poth A G , Henriques S T , Prentis P J , Mahatmanto T, Craik D J : Gene coevolution and regulation lock cyclic plant defence peptides to their targets. New Phytologist (2016) 210, 717-730. 3. Wang C K , Craik D J : A designer’s guide to the making of macrocycles. Nature Chemical Biology (2018) 14, 417-427. 4. Jackson M A , Gilding E K , Shafee T, Harris K, Kaas Q, Poon S, Yap K, Jia H, Guarino R, Chan L Y , Durek T, Anderson M A , Craik D J : Molecular basis for the production of cyclic peptides by plant asparaginyl endopeptidases. Nature Communications (2018) 9, 2411. This talk is part of the Biological Chemistry Research Interest Group series. This talk is included in these lists:
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Monday 27 February 2023, 16:00-17:00