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Characterization of the Fast and Promiscuous Macrocyclase from Plant PCY1 Enables the Use of Simple Substrates.
Ludewig, Hannes; Czekster, Clarissa M; Oueis, Emilia; Munday, Elizabeth S; Arshad, Mohammed; Synowsky, Silvia A; Bent, Andrew F; Naismith, James H.
Afiliação
  • Ludewig H; Biomedical Sciences Research Complex , University of St. Andrews , North Haugh , St. Andrews , KY16 9ST , United Kingdom.
  • Czekster CM; Biomedical Sciences Research Complex , University of St. Andrews , North Haugh , St. Andrews , KY16 9ST , United Kingdom.
  • Oueis E; Biomedical Sciences Research Complex , University of St. Andrews , North Haugh , St. Andrews , KY16 9ST , United Kingdom.
  • Munday ES; EaStChem, School of Chemistry , University of St. Andrews , North Haugh , St. Andrews , KY16 9ST , United Kingdom.
  • Arshad M; Institute of Mechanical, Process and Energy Engineering , Heriot-Watt University , Edinburgh , EH14 4AS , United Kingdom.
  • Synowsky SA; Biomedical Sciences Research Complex , University of St. Andrews , North Haugh , St. Andrews , KY16 9ST , United Kingdom.
  • Bent AF; Biomedical Sciences Research Complex , University of St. Andrews , North Haugh , St. Andrews , KY16 9ST , United Kingdom.
  • Naismith JH; Biomedical Sciences Research Complex , University of St. Andrews , North Haugh , St. Andrews , KY16 9ST , United Kingdom.
ACS Chem Biol ; 13(3): 801-811, 2018 03 16.
Article em En | MEDLINE | ID: mdl-29377663
Cyclic ribosomally derived peptides possess diverse bioactivities and are currently of major interest in drug development. However, it can be chemically challenging to synthesize these molecules, hindering the diversification and testing of cyclic peptide leads. Enzymes used in vitro offer a solution to this; however peptide macrocyclization remains the bottleneck. PCY1, involved in the biosynthesis of plant orbitides, belongs to the class of prolyl oligopeptidases and natively displays substrate promiscuity. PCY1 is a promising candidate for in vitro utilization, but its substrates require an 11 to 16 residue C-terminal recognition tail. We have characterized PCY1 both kinetically and structurally with multiple substrate complexes revealing the molecular basis of recognition and catalysis. Using these insights, we have identified a three residue C-terminal extension that replaces the natural recognition tail permitting PCY1 to operate on synthetic substrates. We demonstrate that PCY1 can macrocyclize a variety of substrates with this short tail, including unnatural amino acids and nonamino acids, highlighting PCY1's potential in biocatalysis.
Assuntos

Texto completo: 1 Base de dados: MEDLINE Assunto principal: Peptídeos Cíclicos / Plantas / Descoberta de Drogas Idioma: En Ano de publicação: 2018 Tipo de documento: Article

Texto completo: 1 Base de dados: MEDLINE Assunto principal: Peptídeos Cíclicos / Plantas / Descoberta de Drogas Idioma: En Ano de publicação: 2018 Tipo de documento: Article