Evaluation of Chemical Strategies for Improving the Stability and Oral Toxicity of Insecticidal Peptides

Spider venoms are a rich source of insecticidal peptide toxins. Their development as bioinsecticides has, however, been hampered due to concerns about potential lack of stability and oral bioactivity. We therefore systematically evaluated several synthetic strategies to increase the stability and oral potency of the potent insecticidal spider-venom peptide ω-HXTX-Hv1a (Hv1a). Selective chemical replacement of disulfide bridges with diselenide bonds and N- to C-terminal cyclization were anticipated to improve Hv1a resistance to proteolytic digestion, and thereby its activity when delivered orally. We found that native Hv1a is orally active in blowflies, but 91-fold less potent than when administered by injection. Introduction of a single diselenide bond had no effect on the susceptibility to scrambling or the oral activity of Hv1a. N- to C-terminal cyclization of the peptide backbone did not significantly improve the potency of Hv1a when injected into blowflies and it led to a significant decrease in oral activity. We show that this is likely due to a dramatically reduced rate of translocation of cyclic Hv1a across the insect midgut, highlighting the importance of testing bioavailability in addition to toxin stability.

Cyto-insectotoxins, a novel class of cytolytic and insecticidal peptides from spider venom

Eight linear cationic peptides with cytolytic and insecticidal activity, designated cyto-insectotoxins (CITs), were identified in Lachesana tarabaevi spider venom. The peptides showed antibiotic activity towards Gram-positive and Gram-negative bacteria at micromolar concentrations as well as toxicity to insects. The primary structures of the toxins were established by direct Edman sequencing in combination with enzymatic and chemical polypeptide degradation and MS. CITs represent a novel class of cytolytic molecules and spider venom toxins. They are the first example of molecules showing equally potent antimicrobial and insecticidal effects. Analysis of L. tarabaevi venom gland expressed sequence tag database revealed the primary structures of the protein precursors; eight peptides homologous with the purified toxins were additionally predicted. CIT precursors share a conventional prepropeptide structure with an acidic prosequence and a processing motif common to most spider toxin precursors. The most abundant peptide, CIT 1a, was chemically synthesized, and its lytic activity on different bacterial strains, human erythrocytes and lymphocytes, insect cells, planar lipid bilayers and lipid vesicles was characterized. The spider L. tarabaevi is suggested to have evolved to rely on a unique set of linear cytolytic toxins, as opposed to the more common disulfide-containing spider neurotoxins.