Identification and Functional Characterization of a Novel Insecticidal Decapeptide from the Myrmicine Ant Manica rubida.

John Heep,Henrike Schmidtberg,Marisa Skaljac,Maximilian Seip,Jens Grotmann,Tobias Kessel,Andreas Vilcinskas

doi:10.3390/toxins11100562

Abstract

Ant venoms contain many small, linear peptides, an untapped source of bioactive peptide toxins. The control of agricultural insect pests currently depends primarily on chemical insecticides, but their intensive use damages the environment and human health, and encourages the emergence of resistant pest populations. This has promoted interest in animal venoms as a source of alternative, environmentally-friendly bio-insecticides. We tested the crude venom of the predatory ant, Manica rubida, and observed severe fitness costs in the parthenogenetic pea aphid (Acyrthosiphon pisum), a common agricultural pest. Therefore, we explored the M. rubida venom peptidome and identified a novel decapeptide U-MYRTX-MANr1 (NH2-IDPKVLESLV-CONH2) using a combination of Edman degradation and de novo peptide sequencing. Although this myrmicitoxin was inactive against bacteria and fungi, it reduced aphid survival and reproduction. Furthermore, both crude venom and U-MYRTX-MANr1 reversibly paralyzed injected aphids and induced a loss of body fluids. Components of M. rubida venom may act on various biological targets including ion channels and hemolymph coagulation proteins, as previously shown for other ant venom toxins. The remarkable insecticidal activity of M. rubida venom suggests it may be a promising source of additional bio-insecticide leads.

Highlights

Ants (Hymenoptera: Formicidae) are a taxonomically diverse group of insects with more than13,500 extant species [1]
We explored the M. rubida venom peptidome to identify new peptides, using a combination of liquid chromatography/mass spectrometry (LC-MS) and Edman degradation
Pooled M. rubida worker venom was analyzed by LC-MS

Summary

Introduction

13,500 extant species [1] They have evolved a venom apparatus derived from the ancestral reproductive system [2], but in contrast to other venomous phyla (e.g., snakes, spiders and scorpions) there have been few studies of ant venoms to functionally characterize their components [3]. Examples of linear peptides include dinoponeratoxins from the giant neotropical hunting ant, Dinoponera australis [11], ponericins from the predatory ant, Neoponera goeldii [12,13], and bicarinalin from Tetramorium bicarinatum [7]. These are classed as antimicrobial peptides (AMPs) because they show activity against microbial pathogens, but they may possess paralytic, cytolytic, hemolytic and/or insecticidal properties [6,7,12,14,15], as ponericins do [12]

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Results

Conclusion