Unveiling the diversity of cyclotides by combining peptidome and transcriptome analysis

Circular peptides have attracted much interest in recent drug development efforts, particularly due to their increased stability over linear counterparts. The family of plant cyclotides represents one of the largest classes of naturally-occurring backbone-cyclized peptides displaying exceptional sequence variability and plasticity around three knotted disulfide bonds. Accordingly, a multitude of pharmaceutically as well as agrochemically relevant bioactivities has been ascribed to them. Their abundance across various species within flowering plants is highlighted by estimated numbers of up to 150,000 different sequences present in single plant families and over 160 at the species level. However, this vast diversity impedes thorough sequence characterization by standard analytical methods using mass spectrometry and thus limits access to a wealth of potentially bioactive compounds that may represent novel lead molecules. Recently the ribosomal origin of cyclotides has been exploited as an alternative way to discover novel sequences. The analysis at nucleotide level allows not only the identification of peptides but also their parent precursor proteins. This combined approach opens access to the discovery of sequences that can provide novel structural templates for a variety of pharmaceutical as well as agrochemical applications. Here we review recent literature related to the discovery of cyclotides. Challenges and opportunities using classical mass spectrometry workflows and novel approaches such as in silico mining will be discussed

Comparison of a Short Linear Antimicrobial Peptide with Its Disulfide-Cyclized and Cyclotide-Grafted Variants against Clinically Relevant Pathogens.

According to the World Health Organization (WHO) the development of resistance against antibiotics by microbes is one of the most pressing health concerns. The situation will intensify since only a few pharmacological companies are currently developing novel antimicrobial compounds. Discovery and development of novel antimicrobial compounds with new modes of action are urgently needed. Antimicrobial peptides (AMPs) are known to be able to kill multidrug-resistant bacteria and, therefore, of interest to be developed into antimicrobial drugs. Proteolytic stability and toxicities of these peptides are challenges to overcome, and one strategy frequently used to address stability is cyclization. Here we introduced a disulfide-bond to cyclize a potent and nontoxic 9mer peptide and, in addition, as a proof-of-concept study, grafted this peptide into loop 6 of the cyclotide MCoTI-II. This is the first time an antimicrobial peptide has been successfully grafted onto the cyclotide scaffold. The disulfide-cyclized and grafted cyclotide showed moderate activity in broth and strong activity in 1/5 broth against clinically relevant resistant pathogens. The linear peptide showed superior activity in both conditions. The half-life time in 100% human serum was determined, for the linear peptide, to be 13 min, for the simple disulfide-cyclized peptide, 9 min, and, for the grafted cyclotide 7 h 15 min. The addition of 10% human serum led to a loss of antimicrobial activity for the different organisms, ranging from 1 to >8-fold for the cyclotide. For the disulfide-cyclized version and the linear version, activity also dropped to different degrees, 2 to 18-fold, and 1 to 30-fold respectively. Despite the massive difference in stability, the linear peptide still showed superior antimicrobial activity. The cyclotide and the disulfide-cyclized version demonstrated a slower bactericidal effect than the linear version. All three peptides were stable at high and low pH, and had very low hemolytic and cytotoxic activity

Inhibition of human prolyl oligopeptidase activity by the Cyclotide Psysol 2 isolated from Psychotria solitudinum

Cyclotides are head-to-tail cyclized peptides comprising a stabilizing cystine-knot motif. To date, they are well known for their diverse bioactivities such as anti-HIV and immunosuppressive properties. Yet little is known about specific molecular mechanisms, in particular the interaction of cyclotides with cellular protein targets. Native and synthetic cyclotide-like peptides from Momordica plants are potent and selective inhibitors of different serine-type proteinases such as trypsin, chymotrypsin, matriptase, and tryptase-beta. This study describes the bioactivity-guided isolation of a cyclotide from Psychotria solitudinum as an inhibitor of another serine-type protease, namely, the human prolyl oligopeptidase (POP). Analysis of the inhibitory potency of Psychotria extracts and subsequent fractionation by liquid chromatography yielded the isolated peptide psysol 2 (1), which exhibited an IC50 of 25 μM. In addition the prototypical cyclotide kalata B1 inhibited POP activity with an IC50 of 5.6 μM. The inhibitory activity appeared to be selective for POP, since neither psysol 2 nor kalata B1 were able to inhibit the proteolytic activity of trypsin or chymotrypsin. The enzyme POP is well known for its role in memory and learning processes, and it is currently being considered as a promising therapeutic target for the cognitive deficits associated with several psychiatric and neurodegenerative diseases, such as schizophrenia and Parkinson's disease. In the context of discovery and development of POP inhibitors with beneficial ADME properties, cyclotides may be suitable starting points considering their stability in biological fluids and possible oral bioavailability

Tick holocyclotoxins trigger host paralysis by presynaptic inhibition

Ticks are important vectors of pathogens and secreted neurotoxins with approximately 69 out of 692 tick species having the ability to induce severe toxicoses in their hosts. The Australian paralysis tick (Ixodes holocyclus) is known to be one of the most virulent tick species producing a flaccid paralysis and fatalities caused by a family of neurotoxins known as holocyclotoxins (HTs). The paralysis mechanism of these toxins is temperature dependent and is thought to involve inhibition of acetylcholine levels at the neuromuscular junction. However, the target and mechanism of this inhibition remain uncharacterised. Here, we report that three members of the holocyclotoxin family; HT-1 (GenBank AY766147), HT-3 (GenBank KP096303) and HT-12 (GenBank KP963967) induce muscle paralysis by inhibiting the dependence of transmitter release on extracellular calcium. Previous study was conducted using extracts from tick salivary glands, while the present study is the first to use pure toxins from I. holocyclus. Our findings provide greater insight into the mechanisms by which these toxins act to induce paralysis

The vast structural diversity of antimicrobial peptides

Antimicrobial peptides (AMPs) occur in all kingdoms of life and are integral to host defense. They have diverse structures and target a variety of organisms, both by nonspecific membrane interactions and via specific targets. Here we discuss the structures of AMPs from the four main classes currently recognized – that is, peptides with (i) α-helical, (ii) β-sheet, (iii) αβ, or (iv) non-αβ elements – as well as the growing pool of complex topologies including various post-translational modifications (PTMs). We propose to group these latter peptides into a fifth class of AMPs. Such peptides exhibit high stability and amenability to chemical engineering, making them of interest for the development of novel antimicrobial agents. Advances and challenges in the development of these peptides towards therapeutic leads are presented