1. Selective membrane disruption by the cyclotide kalata B7: complex ions and essential functional groups in the phosphatidylethanolamine binding pocket
Adam A Strömstedt, Per Eugen Kristiansen, Sunithi Gunasekera, Nathalie Grob, Lars Skjeldal, Ulf Göransson Biochim Biophys Acta. 2016 Jun;1858(6):1317-27. doi: 10.1016/j.bbamem.2016.02.013. Epub 2016 Feb 12.
The cyclic cystine knot plant peptides called cyclotides are active against a wide variety of organisms. This is primarily achieved through membrane binding and disruption, in part deriving from a high affinity for phosphatidylethanolamine (PE) lipids. Some cyclotides, such as kalata B7 (kB7), form complexes with divalent cations in a pocket associated with the tyrosine residue at position 15 (Tyr15). In the current work we explore the effect of cations on membrane leakage caused by cyclotides kB1, kB2 and kB7, and we identify a functional group that is essential for PE selectivity. The presence of PE-lipids in liposomes increased the membrane permeabilizing potency of the cyclotides, with the potency of kB7 increasing by as much as 740-fold. The divalent cations Mn(2+), Mg(2+) and Ca(2+) had no apparent effect on PE selectivity. However, amino acid substitutions in kB7 proved that Tyr15 is crucial for PE-selective membrane permeabilization on various liposome systems. Although the tertiary structure of kB7 was maintained, as reflected by the NMR solution structure, mutating Tyr into Ser at position 15 resulted in substantially reduced PE selectivity. Ala substitution at the same position produced a similar reduction in PE selectivity, while substitution with Phe maintained high selectivity. We conclude that the phenyl ring in Tyr15 is critical for the high PE selectivity of kB7. Our results suggest that PE-binding and divalent cation coordination occur in the same pocket without adverse effects of competitive binding for the phospholipid.
2. Divalent cation coordination and mode of membrane interaction in cyclotides: NMR spatial structure of ternary complex Kalata B7/Mn2+/DPC micelle
Zakhar O Shenkarev, Kirill D Nadezhdin, Ekaterina N Lyukmanova, Vladimir A Sobol, Lars Skjeldal, Alexander S Arseniev J Inorg Biochem. 2008 May-Jun;102(5-6):1246-56. doi: 10.1016/j.jinorgbio.2008.01.018. Epub 2008 Jan 21.
The cyclotides are the family of hydrophobic bioactive plant peptides, characterized by a circular protein backbone and three knot forming disulfide bonds. It is believed that membrane activity of the cyclotides underlines their antimicrobial, cytotoxic and hemolytic properties, but the specific interactions with divalent cations can be also involved. To assess the mode of membrane interaction and divalent cation coordination in cyclotides, the spatial structure of the Möbius cyclotide Kalata B7 from the African perennial plant Oldenlandia affinis was determined in the presence of anisotropic membrane mimetic (dodecylphosphocholine micelles). The model of peptide/cation/micelle complex was built using 5-doxylstearate and Mn2+ relaxation probes. Results show that the peptide binds to the micelle surface with relatively high affinity by two hydrophobic loops (loop 2 - Thr6-Leu7 and loop 5 - Trp19-Ile21). The partially hydrated divalent cation is coordinated by charged side-chain of Glu3, aromatic side chain of Tyr11 and free carbonyls of Thr4 and Thr9, and is located in direct contact with the polar head-groups of detergent. The comparison with data about other cyclotides indicates that divalent cation coordination is the invariant property of all cyclotides, but the mode of peptide/membrane interactions is varied. Probably, the specific cation/peptide interactions play a major, but yet not known, role in the biological activity of the cyclotides.
3. From ethnopharmacology to drug design
Johannes Koehbach, Christian W Gruber Commun Integr Biol. 2013 Nov 1;6(6):e27583. doi: 10.4161/cib.27583. Epub 2014 Jan 8.
Nature's diversity is one of the biggest resources of therapeutic lead compounds. Traditionally-used herbal remedies harbor a variety of bioactive compounds providing researchers with starting points for drug development. Ethnopharmacological investigations of uterotonic plant preparations identified a class of circular and disulfide-rich peptides, called cyclotides, to exhibit strong uterine contractions. In humans one of the physiological regulators of the myometrial contractility is the nonapeptide oxytocin acting on its cognate G protein-coupled receptors. They are considered to represent one of the most promising drug targets with ~30% of all currently marketed drugs acting on these transmembrane receptors. Based on observed similarities regarding the activity and structure of plant cyclotides with human oxytocin we analyzed the pharmacological principle of their action and identified the oxytocin and vasopressin 1a receptors as molecular targets of cyclotides from the Rubiaceae plant Oldenlandia affinis. Using a synthetic approach, the sequence of the native cyclotide kalata B7 was used to design oxytocin-like nonapeptides with nanomolar affinity and selectivity for the oxytocin receptor. This provides formal proof for the use of cyclotides as templates in peptide ligand design. At a more general level, mining of naturally-occurring peptides is a promising tool for the identification and the design of novel G protein-coupled receptor ligands.