Mutagenesis of bracelet cyclotide hyen D reveals functionally and structurally critical residues for membrane binding and cytotoxicity.

Cyclotides have a wide range of bioactivities relevant for agricultural and pharmaceutical applications. This large family of naturally occurring macrocyclic peptides is divided into three subfamilies, with the bracelet subfamily being the largest and comprising the most potent cyclotides reported to date. However, attempts to harness the natural bioactivities of bracelet cyclotides and engineer-optimized analogs have been hindered by a lack of understanding of the structural and functional role of their constituent residues, which has been challenging because bracelet cyclotides are difficult to produce synthetically. We recently established a facile strategy to make the I11L mutant of cyclotide hyen D that is as active as the parent peptide, enabling the subsequent production of a series of variants. In the current study, we report an alanine mutagenesis structure-activity study of [I11L] hyen D to probe the role of individual residues on peptide folding using analytical chromatography, on molecular function using surface plasmon resonance, and on therapeutic potential using cytotoxicity assays. We found that Glu-6 and Thr-15 are critical for maintaining the structure of bracelet cyclotides and that hydrophobic residues in loops 2 and 3 are essential for membrane binding and cytotoxic activity, findings that are distinct from the structural and functional characteristics determined for other cyclotide subfamilies. In conclusion, this is the first report of a mutagenesis scan conducted on a bracelet cyclotide, offering insights into their function and supporting future efforts to engineer bracelet cyclotides for biotechnological applications.

Cyclotides: Disulfide-rich peptide toxins in plants.

Cyclotides are a plant-derived family of peptides that comprise approximately 30 amino acid residues, a cyclic backbone and a cystine knot. Due to their unique structure, cyclotides are exceptionally stable to heat or proteolytic degradation and are tolerant to amino acid substitutions in their backbone loops between conserved cysteine residues. Their toxicity to insect pests and their make-up of natural amino acids has led to their applications in eco-friendly crop protection. Furthermore, their stability and cell penetrating properties make cyclotides ideal scaffolds for bioactive epitope grafting. This article gives a brief overview of cyclotide discovery, characterization, distribution, synthesis and mode of action mechanisms. We focus on their toxicities to insect pests and their medical and agricultural applications.

Structural and functional characterization of chimeric cyclotides from the Möbius and trypsin inhibitor subfamilies.

Cyclotides are plant-derived host defense peptides displaying exceptional stability due to their cyclic cystine knot comprising three intertwined disulfide bonds and a cyclic backbone. Their six conserved cysteine residues are separated by backbone loops with diverse sequences. Prototypical cyclotides from the Möbius (kalata B1) and trypsin inhibitor (MCoTI-II) subfamilies lack sequence homology with one another, but both are able to penetrate cells, apparently via different mechanisms. To delineate the influence of the sequences of the loops on the structure and cell internalization of these two cyclotide subfamilies, a series of Möbius/trypsin inhibitor loop-chimeras of kalata B1 and MCoTI-II were synthesized, and structurally and functionally characterized. NMR analysis showed that the structural fold of the majority of chimeric peptides was minimally affected by the loop substitutions. Substituting loops 3, 5, or 6 of MCoTI-II into the corresponding loops of kalata B1 attenuated its hemolytic and cytotoxic activities, and greatly reduced its cell-penetrating properties. On the other hand, replacing loops of MCoTI-II with the corresponding loops of kalata B1 did not introduce cytotoxicity into the chimeras. Loops 2, 3, and 4 of MCoTI-II were found to contribute little to cell-penetrating properties. Overall, this study provides valuable insights into the structural basis for the hemolytic, cytotoxic, and cell-penetrating properties of kalata B1 and MCoTI-II, which could be useful for future engineering of cyclotides to carry bioactive epitopes to intracellular targets.

Anticancer and toxic properties of cyclotides are dependent on phosphatidylethanolamine phospholipid targeting.

Cyclotides, ultrastable disulfide-rich cyclic peptides, can be engineered to bind and inhibit specific cancer targets. In addition, some cyclotides are toxic to cancer cells, though not much is known about their mechanisms of action. Here we delineated the potential mode of action of cyclotides towards cancer cells. A novel set of analogues of kalata B1 (the prototypic cyclotide) and kalata B2 and cycloviolacin O2 were examined for their membrane-binding affinity and selectivity towards cancer cells. By using solution-state NMR, surface plasmon resonance, flow cytometry and bioassays we show that cyclotides are toxic against cancer and non-cancerous cells and their toxicity correlates with their ability to target and disrupt lipid bilayers that contain phosphatidylethanolamine phospholipids. Our results suggest that the potential of cyclotides as anticancer therapeutics might best be realised by combining their amenability to epitope engineering with their ability to bind cancer cell membranes.

Genotoxicity and cellular uptake of cyclotides: evidence for multiple modes of action.

Cyclotides are a family of ultra-stable, head-to-tail cyclic mini-proteins from plants, with each member comprising about 30 amino acid residues. Their stability derives from the unique structural topology where the cyclic backbone and two disulfide bonds make up an embedded ring, which is knotted by a third disulfide bond. The cyclotides find potential applications in the pharmaceutical industry as stable peptide-based scaffolds for unstable drugs, and also as medicinal agents, due to the wide range of their inherent pharmacological activities. However, there is a lack of fundamental toxicological studies on this type of compound. The current study determined the possible DNA-damaging effects of three cyclotides, i.e., cycloviolacin O2, vaby D, and kalata B1, in human lymphoma cells by use of the alkaline version of the comet assay. The three cyclotides induced massive DNA fragmentation at lethal concentrations. At a sub-lethal concentration, cycloviolacin O2 and vaby D gave a bell-shaped dose-response curve for their DNA-damaging effect. Kalata B1 caused no significant DNA damage at sub-cytotoxic concentrations. Single-cell micro-autoradiography was carried out on tritium-labeled cycloviolacin O2 in order to understand the mechanism behind the dose-response curve. The results revealed that the peptide is taken up into the cell, both at cytotoxic and at low concentrations. Most biological effects of the cyclotides have been taken to follow from the disruption of cell membranes, but even if the intracellular mechanisms and targets still remain unknown, the current study has unequivocally demonstrated that cyclotides also must have other dose-dependent modes of action.

A Synthetic mirror image of kalata B1 reveals that cyclotide activity is independent of a protein receptor.

Featuring a circular, knotted structure and diverse bioactivities, cyclotides are a fascinating family of peptides that have inspired applications in drug design. Most likely evolved to protect plants against pests and herbivores, cyclotides also exhibit anti-cancer, anti-HIV, and hemolytic activities. In all of these activities, cell membranes appear to play an important role. However, the question of whether the activity of cyclotides depends on the recognition of chiral receptors or is primarily modulated by the lipid-bilayer environment has remained unknown. To determine the importance of lipid membranes on the activity of the prototypic cyclotide, kalata B1, we synthesized its all-D enantiomer and assessed its bioactivities. After the all-D enantiomer had been confirmed by (1)H NMR to be the structural mirror image of the native kalata B1, it was tested for anti-HIV activity, cytotoxicity, and hemolytic properties. The all-D peptide is active in these assays, albeit with less efficiency; this reveals that kalata B1 does not require chiral recognition to be active. The lower activity than the native peptide correlates with a lower affinity for phospholipid bilayers in model membranes. These results exclude a chiral receptor mechanism and support the idea that interaction with phospholipid membranes plays a role in the activity of kalata B1. In addition, studies with mixtures of L and D enantiomers of kalata B1 suggested that biological activity depends on peptide oligomerization at the membrane surface, which determines affinity for membranes by modulating the association-dissociation equilibrium.

Biomedicine in the environment: cyclotides constitute potent natural toxins in plants and soil bacteria.

Bioactive compounds produced by plants are easily transferred to soil and water and may cause adverse ecosystem effects. Cyclotides are gene-encoded, circular, cystine-rich mini-proteins produced in Violaceae and Rubiaceae in high amounts. Based on their biological activity and stability, cyclotides have promising pharmaceutical and agricultural applications. We report the toxicity of the cyclotides: kalata B1, kalata B2, and cycloviolacin O2 extracted from plants to green algae (Pseudokirchneriella subcapitata), duckweed (Lemna minor L.), lettuce (Lactuca sativa L.), and bacteria extracted from soil measured as [³H]leucine incorporation. Quantification by liquid chromatography-mass spectrometry demonstrated up to 98% loss of cyclotides from aqueous solutions because of sorption to test vials. Sorption was prevented by adding bovine serum albumin (BSA) to the aqueous media. Cyclotides were toxic to all test organisms with EC50 values of 12 through 140 µM (algae), 9 through 40 µM (duckweed), 4 through 54 µM (lettuce), and 7 through 26 µM (bacteria). Cycloviolacin O2 was the most potent cyclotide in all assays examined. This report is the first to document toxic effects of cyclotides in plants and soil bacteria and to demonstrate that cyclotides are as toxic as commonly used herbicides and biocides. Hence, cyclotides may adversely affect soil and aquatic environments, which needs to be taken into account in future risk assessment of cropping systems for production of these highly bioactive compounds.

Backbone cyclised peptides from plants show molluscicidal activity against the rice pest Pomacea canaliculata (golden apple snail).

Golden apple snails ( Pomacea canaliculata) are serious pests of rice in South East Asia. Cyclotides are backbone cyclized peptides produced by plants from Rubiaceae and Violaceae. In this study, we investigated the molluscicidal activity of cyclotides against golden apple snails. Crude cyclotide extracts from both Oldenlandia affinis and Viola odorata plants showed molluscicidal activity comparable to the synthetic molluscicide metaldehyde. Individual cyclotides from each extract demonstrated a range of molluscicidal activities. The cyclotides cycloviolacin O1, kalata B1, and kalata B2 were more toxic to golden apple snails than metaldehyde, while kalata B7 and kalata B8 did not cause significant mortality. The toxicity of the cyclotide kalata B2 on a nontarget species, the Nile tilapia ( Oreochromis niloticus), was three times lower than the common piscicide rotenone. Our findings suggest that the existing diversity of cyclotides in plants could be used to develop natural molluscicides.

The alpine violet, Viola biflora, is a rich source of cyclotides with potent cytotoxicity.

The cyclotides are currently the largest known family of head-to-tail cyclic proteins. The complex structure of these small plant proteins, which consist of approximately 30 amino acid residues, contains both a circular peptide backbone and a cystine knot, the combination of which produces the cyclic cystine knot motif. To date, cyclotides have been found in plants from the Rubiaceae, Violaceace and Cucurbitaceae families, and are believed to be part of the host defence system. In addition to their insecticidal effect, cyclotides have also been shown to be cytotoxic, anti-HIV, antimicrobial and haemolytic agents. In this study, we show that the alpine violet Viola biflora (Violaceae) is a rich source of cyclotides. The sequences of 11 cyclotides, vibi A-K, were determined by isolation and MS/MS sequencing of proteins and screening of a cDNA library of V. biflora in parallel. For the cDNA screening, a degenerate primer against a conserved (AAFALPA) motif in the cyclotide precursor ER signal sequence yielded a series of predicted cyclotide sequences that were correlated to those of the isolated proteins. There was an apparent discrepancy between the results of the two strategies as only one of the isolated proteins could be identified as a cDNA clone. Finally, to correlate amino acid sequence to cytotoxic potency, vibi D, E, G and H were analysed using a fluorometric microculture cytotoxicity assay using a lymphoma cell line. The IC(50)-values of the bracelet cyclotides vibi E, G and H ranged between 0.96 and 5.0 microM while the Möbius cyclotide vibi D was not cytotoxic at 30 microM.

Plant cyclotides disrupt epithelial cells in the midgut of lepidopteran larvae.

Several members of the Rubiaceae and Violaceae plant families produce a series of cyclotides or macrocyclic peptides of 28-37 aa with an embedded cystine knot. The cyclic peptide backbone together with the knotted and strongly braced structure confers exceptional chemical and biological stability that has attracted attention for potential pharmaceutical applications. Cyclotides display a diverse range of biological activities, such as uterotonic action, anti-HIV activity, and neurotensin antagonism. In plants, their primary role is probably protection from insect attack. Ingestion of the cyclotide kalata B1 severely retards the growth of larvae from the Lepidopteran species Helicoverpa armigera. We examined the gut of these larvae after consumption of kalata B1 by light, scanning, and transmission electron microscopy. We established that kalata B1 induces disruption of the microvilli, blebbing, swelling, and ultimately rupture of the cells of the gut epithelium. The histology of this response is similar to the response of H. armigera larvae to the Bacillus thuringiensis delta-endotoxin, which is widely used to control these insect pests of crops such as cotton.