BACKGROUND: Herein we report the discovery of a cystine-crosslinked peptide from Porifera along with high-quality spatial details accompanied by the description of its unique effect on neuronal calcium influx. METHODS: Asteropsin A (ASPA) was isolated from the marine sponge Asteropus sp., and its structure was independently determined using X-ray crystallography (0.87 angstroms) and solution NMR spectroscopy. RESULTS: An N-terminal pyroglutamate modification, uncommon cis proline conformations, and absence of basic residues helped distinguish ASPA from other cystine-crosslinked knot peptides. ASPA enhanced Ca2+ influx in murine cerebrocortical neuron cells following the addition of the Na+ channel activator veratridine but did not modify the oscillation frequency or amplitude of neuronal Ca2+ currents alone. Allosterism at neurotoxin site 2 was not observed, suggesting an alternative to the known Na+ channel interaction. CONCLUSIONS: Together with a distinct biological activity, the origin of ASPA suggests a new subclass of cystine-rich knot peptides associated with Porifera. GENERAL SIGNIFICANCE: The discovery of ASPA represents a distinctive addition to an emerging subclass of cystine-crosslinked knot peptides from Porifera.
BACKGROUND: Herein we report the discovery of a cystine-crosslinked peptide from Porifera along with high-quality spatial details accompanied by the description of its unique effect on neuronal calcium influx. METHODS:Asteropsin A (ASPA) was isolated from the marine sponge Asteropus sp., and its structure was independently determined using X-ray crystallography (0.87 angstroms) and solution NMR spectroscopy. RESULTS: An N-terminal pyroglutamate modification, uncommon cis proline conformations, and absence of basic residues helped distinguish ASPA from other cystine-crosslinked knot peptides. ASPA enhanced Ca2+ influx in murine cerebrocortical neuron cells following the addition of the Na+ channel activator veratridine but did not modify the oscillation frequency or amplitude of neuronal Ca2+ currents alone. Allosterism at neurotoxin site 2 was not observed, suggesting an alternative to the known Na+ channel interaction. CONCLUSIONS: Together with a distinct biological activity, the origin of ASPA suggests a new subclass of cystine-rich knot peptides associated with Porifera. GENERAL SIGNIFICANCE: The discovery of ASPA represents a distinctive addition to an emerging subclass of cystine-crosslinked knot peptides from Porifera.
Authors: B M Olivera; L J Cruz; V de Santos; G W LeCheminant; D Griffin; R Zeikus; J M McIntosh; R Galyean; J Varga; W R Gray Journal: Biochemistry Date: 1987-04-21 Impact factor: 3.162
Authors: Rohan A Davis; Gina C Mangalindan; Zenaida P Bojo; Rowena R Antemano; Nell O Rodriguez; Gisela P Concepcion; Shiela C Samson; Dennis de Guzman; Lourdes J Cruz; Deniz Tasdemir; Mary Kay Harper; Xidong Feng; Guy T Carter; Chris M Ireland Journal: J Org Chem Date: 2004-06-11 Impact factor: 4.354
Authors: Lauren R H Krumpe; Brice A P Wilson; Christophe Marchand; Suthananda N Sunassee; Alun Bermingham; Wenjie Wang; Edmund Price; Tad Guszczynski; James A Kelley; Kirk R Gustafson; Yves Pommier; K Johan Rosengren; Christina I Schroeder; Barry R O'Keefe Journal: J Am Chem Soc Date: 2020-12-02 Impact factor: 15.419
Authors: Alejandro M S Mayer; Abimael D Rodríguez; Orazio Taglialatela-Scafati; Nobuhiro Fusetani Journal: Mar Drugs Date: 2017-08-29 Impact factor: 5.118