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Article

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

1
Branch for Bioresources, Fraunhofer Institute for Molecular Biology and Applied Ecology (IME), Winchesterstrasse 2, 35394 Giessen, Germany
2
Institute for Insect Biotechnology, Justus Liebig University of Giessen, Heinrich-Buff- Ring 26-32, 35392 Giessen, Germany
*
Author to whom correspondence should be addressed.
Submission received: 26 August 2019 / Revised: 16 September 2019 / Accepted: 23 September 2019 / Published: 25 September 2019

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.
Key Contribution: Venom of the predatory ant, Manica rubida, contains a short peptidyl toxin (U-MYRTX-MANr1) that severely affects the fitness of a key agricultural pest (the pea aphid, Acyrthosiphon pisum), suggesting that ant venoms contain promising toxins for pest control.

1. Introduction

Ants (Hymenoptera: Formicidae) are a taxonomically diverse group of insects with more than 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]. This reflects the challenging taxonomy of ants, the limited amount of venom that can be extracted, and the common misconception that ant venoms are simple, consisting mainly of formic acid [4,5].
Recent transcriptomic and proteomic studies have shown that ant venoms are mixtures of many bioactive molecules with an impressive array of biological properties [2]. Although rich in short linear peptides (<5 kDa), ant venoms also contain complex peptides with disulfide bonds, as well as oligomeric proteins with a broad spectrum of activities [2,6,7,8,9,10]. 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 also possess paralytic, cytolytic, hemolytic and/or insecticidal properties [6,7,12,14,15], as ponericins do [12].
Insect pests reduce crop yields by feeding and transmitting plant pathogens, but they also act as vectors for many human and livestock pathogens [16,17]. Despite the increasing use of biological control methods, chemical insecticides remain the primary strategy for pest control in both agricultural and public health settings [18,19]. Over the past decade, the number of registered chemical insecticides has fallen due to the emergence of resistant pest populations and the de-registration of key insecticides by regulatory authorities, based on evidence of harm to the environment, to beneficial organisms, and to human health [20,21,22,23]. This has increased the demand for new and safe insecticidal lead compounds, novel insecticidal targets, and alternative methods for effective pest control.
Venom-derived peptidyl toxins have been fine-tuned by evolution to improve their selectivity and efficacy in the context of prey capture and defense against predators [2]. Insecticidal toxins derived from predatory arthropods therefore offer a promising source of novel bio-insecticides, and these frequently include peptidyl neurotoxins derived from venoms of arachnids, such as scorpions and spiders [24,25]. Ants also use venom for predation and/or defense against predators and competitors. For example, the linear peptide, poneratoxin, isolated from Paraponera clavata, targets the central nervous system of insects by blocking synaptic transmission [2,26,27]. In contrast, peptides with disulfide bonds often target ion channels, causing paralysis or incapacitation. For example, poneritoxin Ae1a from the predatory ant, Anochetus emarginatus, and MIITX1-Mg1a from the giant red bull ant, Myrmecia gulosa, antagonize ion channels in sheep blowflies (Lucilia cuprina) and crickets (Acheta domesticus) [4,28].
Aphids (Hemiptera: Aphididae) are devastating insect pests that damage plants by feeding and by transmitting many important plant pathogens [19,29,30,31]. Aphid control relies predominantly on chemical insecticides such as carbamates, organophosphates, neonicotinoids and pyrethroids [18,29,32]. These insecticides mainly act on insect nerve and muscle targets, whereas other pesticides impair respiration, lipid synthesis, or cuticle formation during insect growth and development [18]. The long-term and frequent use of these insecticides have applied selective pressure to aphid populations, and multiple resistant forms have emerged, making some aphid species very difficult to control [18,33]. The polyphagous aphids, Myzus persicae and Aphis gossypii, are among the 12 most resistant insect species, with resistance to 75 and 48 chemical insecticidal compounds, respectively [18].
Recent studies have shown that both linear and disulfide-bonded toxins from venoms of spiders, scorpions, and ants are promising molecules for aphid control [34,35,36,37,38,39]. Some peptidyl toxins from scorpions (e.g., Urodacus yaschenkoi and Urodacus manicatus) and the ant Myrmica rubra act against aphids as stand-alone compounds [34,39]. Other scorpion and spider toxins are more active when fused to carrier proteins (e.g., Galanthus nivalis agglutinin) that mediate transport through the insect gut [37] or by engineering entomopathogenic fungi to express insecticidal proteins [36].
Manica rubida (Myrmicinae) is a stinging ant of moderate size (workers ~6–9 mm in length) that is prevalent in middle and southern Europe [40], favoring mountainous regions of 500–2000 m altitude [41]. Colony founding in M. rubida is semi-claustral [42], a strategy in which the founding queen actively preys upon other insects to enhance early colony development [42]. This species inflicts a painful sting and uses its potent venom to prevent nest invasions and to subdue prey [40]. Although M. rubida venom contains predominantly small, linear peptides (<5 kDa) [43], the peptide sequences are unknown and their activities and that of the crude venom have not been investigated in detail.
We explored the M. rubida venom peptidome to identify new peptides, using a combination of liquid chromatography/mass spectrometry (LC-MS) and Edman degradation. We also isolated one of the most abundant linear peptides in the crude venom (U-MYRTX-MANr1) and tested its antimicrobial activity and potency against the pea aphid (Acyrthosiphon pisum), a common agricultural pest.

2. Results

2.1. LC-MS Analysis of Crude Venom

Pooled M. rubida worker venom was analyzed by LC-MS. We identified 180 molecular features representing a set of 96 different peptides, most of which eluted between 25 and 55 min (23–50% acetonitrile) revealing low to moderate hydrophobicity (Figure 1). The mass range of the peptides was 368–3026 Da, representing sequences of 3–27 amino acids (Figure S1). The sequence length was calculated using an average amino acid molecular mass of 111.1254 Da [44].
Crude venom was reduced and alkylated to identify peptides with disulfide bonds. Among the most abundant peptides in the venom peptidome (relative peak intensity ≥ 3%), linear peptides were prevalent, but there were also some peptides with a single, intramolecular disulfide bond (Table 1).

2.2. Peptide Sequencing

A fraction from the crude venom containing a peptide with a molecular weight of 1110.67 Da, eluting at 32.1 min, was isolated and enriched. This fraction was selected for further analysis because it contained no co-eluting peptides.
The amino acid sequence of the peptide was determined using a combination of Edman degradation and de novo peptide sequencing. Stepwise Edman degradation revealed the decapeptide sequence IDPKVLESLV (monoisotopic mass = 1111.65 Da). The difference of ~1 Da between the theoretical and experimental masses reflected C-terminal amidation. The structure of the novel peptide was confirmed by mass determination in the sub-3 ppm region and de novo peptide sequencing. The MS/MS fingerprint of the natural peptide and a synthetic analog achieved very high sequence coverage (Figure S2) and produced an exact match in terms of retention time.
The peptide was named U-MYRTX-MANr1, according to the proposed nomenclature system for ant venom peptides [2]. We added the tag “MAN” for Manica to avoid ambiguity, given the existence of several genera with similar names (e.g., Myrmica, Malagidris and Mayriella). The tag “r” is sufficient to denote the specific epithet, rubida within the genus Manica. The prefix “U” was added to indicate that the biological activity and pharmacological target of the peptide remain unidentified [45].

2.3. Antimicrobial Activity

Synthetic analogs of the decapeptide U-MYRTX-MANr1 (M. rubida) and the decapeptide U-MYRTX-MRArub1 from the myrmicine ant, M. rubra [39], were tested in antimicrobial assays against a range of bacteria and fungi. Neither decapeptide showed any activity against any strains we tested at concentrations up to 512 µg·mL−1.

2.4. Effects of Crude Venom and Peptidyl Toxins on Aphid Survival and Reproduction

Insecticidal activities of crude M. rubida venom and the peptide U-MYRTX-MANr1 were determined by tracking A. pisum survival (Figure 2) and offspring production daily until 10 days post-injection (Table S1). In a previous study, the M. rubra peptide U-MYRTX-MYRrub1 was active against A. pisum [39]. Therefore, crude M. rubra venom and U-MYRTX-MYRrub1 were used as positive controls to determine the relative activity of M. rubida and M. rubra venom components on aphid fitness (Figure S3, Table S1).
In most treatments, aphid survival was reduced in a concentration-dependent manner by the crude venom and peptidyl toxins from both species (Table 2). M. rubida venom was more potent than M. rubra venom (Table 2, Tables S2 and S3; Figure 2 and Figure S3). The highest concentration (1 mg·mL−1) of M. rubida venom caused 100% mortality within 24 h, whereas ~20% of aphids were still alive 10 days after exposure to the same concentration of M. rubra venom (Figure 2A and Figure S3A). Furthermore, M. rubida and M. rubra venoms at a concentration of 0.1 mg·mL−1 reduced aphid survival to ~72% and ~30%, respectively (Table 2). All concentrations of the bovine serum albumin (BSA) control (1, 4 and 16 mg·mL−1) and low concentrations of crude venom (0.01 mg·mL−1) or peptide (1 mg·mL−1) from either species had no significant effect on aphid survival (Table 2 and Table S4; Figure 2, Figures S3 and S4).
To determine the effect of venom/peptide injection on aphid reproduction, the number of offspring was scored for aphids that survived the treatments. Due to the strong effect of high concentrations of the crude venom/peptide on aphid survival, we only counted the number of offspring for aphids exposed to medium and low concentrations (Table S1). Medium concentrations of crude venom (0.1 mg·mL−1) and peptidyl toxin (4 mg·mL−1) from M. rubida both reduced the number of offspring by ~26%, whereas other treatments, including all treatments with the M. rubra venom/peptide, did not reduce aphid reproduction (Table S1).

2.5. Effects of Crude Venom and Peptide Toxins on Aphid Behavior and Injection Wound Healing

The strong toxicity of M. rubida crude venom and toxin U-MYRTX-MANr1 on aphid survival and reproduction persuaded us to investigate the effects of crude venom or toxin on the behavior of A. pisum immediately and 1 h after injection (Table 3). Interestingly, aphids placed on their backs immediately after injection with crude M. rubida venom displayed an inability or delayed ability (>3 min) to right themselves. Similar, but much less severe effects, were observed following the injection of U-MYRTX-MANr1 (Table 3). Aphids in the control group (water injection) showed normal movement and rapidly righted themselves when placed on their backs. Observations recorded for crude venom, peptide, and water immediately after injection remained unchanged after 1 h, but a massive loss of body fluids from the injection site occurred in aphids treated with M. rubida crude venom and U-MYRTX-MANr1 (Figure 3, B1–C3). This suggests that both the venom and the peptide impair wound healing and hemolymph coagulation.
To understand the effectiveness of M. rubida venom components in more detail, injections using crude venom and toxin U-MYRTX-MYRrub1 from M. rubra were repeated. In contrast to injections of M. rubida venom, paralysis and fluid loss were significantly less severe for both crude venom and the M. rubra toxin (Table S5). Nevertheless, we observed differences between control aphids and those injected with crude M. rubra venom or peptidyl toxin (Figure S5, Table S5). Aphids injected with crude M. rubra venom experienced mild paralysis and required 10–30 s to right themselves. Paralytic effects were still evident 1 h post-injection, and were associated with mildly impaired wound healing/coagulation (Figure S5, C1–C3). In agreement with the M. rubida experiments, the effects on movement and wound healing/coagulation were weaker for toxin U-MYRTX-MYRrub1 than for crude venom. Aphids injected with the peptide were able to right themselves immediately and showed only mild paralysis (Table S5). Furthermore, the mild paralysis was maintained 1 h post-injection and wound healing/coagulation was only slightly impaired (Figure S5, B1–B3).
To further investigate the effectiveness of M. rubida venom components against aphids, histological investigations were also conducted. Histological sections of aphids injected with crude M. rubida venom showed the significant retardation of embryonic development, degradation of fat bodies, and dissociation of bacteriocytes (Figure S6). In addition, impaired wound healing following crude M. rubida venom injections was confirmed, as observed in other injection assays (Figure 3, C1–C3; Figure S6). Histological sections of aphids injected with water and peptide U-MYRTX-MANr1 did not show obvious effects (Figures S6–S8). Aphids injected with M. rubra venom components were not subjected to histological investigation.

2.6. Effects of Peptide U-MYRTX-MANr1 on Aphid Susceptibility to Chemical Insecticides

The oral activity of toxin U-MYRTX-MANr1 was determined by tracking aphid survival during 3 days of feeding (Figure S9). Aphid survival was not significantly affected following oral delivery of the peptide at a concentration of 500 µg·mL−1, as used in previous studies [34,39]. Aphids that survived 3 days on the control or peptide-supplemented diet were exposed to insecticide-treated bean plant leaf discs to determine the effect of U-MYRTX-MANr1 on aphid tolerance to three frequently used chemical insecticides: imidacloprid, spirotetramat, and methomyl. Each insecticide was tested at a sub-lethal concentration, determined in a previous study [46] (Table S6). Aphids previously exposed to peptide U-MYRTX-MANr1 were not significantly more sensitive to any of the chemical insecticides, compared to control aphids (Table S6). The peptide U-MYRTX-MYRrub1 from M. rubra was not included in this experiment because its effect on the susceptibility of A. pisum to chemical insecticides was previously reported [39].

3. Discussion

Manica rubida is not very aggressive, but workers respond promptly to disturbances and defend their colonies with powerful stings, which can be painful to humans. Although very little is known about the natural feeding preferences of M. rubida, N-isotope data have shown that this species is zoophagous [47]. This indicates that these ants are predominately scavengers and predators, using their potent venom to subdue prey. Our LC-MS analysis of M. rubida venom revealed significant heterogeneity of the venom peptidome, with numerous peptides varying in molecular weight, structure, and physochemical properties. We also determined the first sequence of a peptidyl toxin isolated from M. rubida venom and characterized its biological activity.
Ant venoms are widely assumed to be simple mixtures, consisting mainly of formic acid, but this is only true for species of the subfamily Formicinae [4]. In contrast, species such as M. gulosa [4] and Odontomanchus monticola [48] produce venoms comprising complex mixtures of peptides with diverse biological activities, which is also true of other subfamilies (e.g., Myrmeciinae, Ponerinae and Myrmicinae) [7,49,50,51].
Touchard et al. [43] investigated venom characteristics of M. rubida and 81 other stinging ant species using MALDI-TOF-MS. Our LC-MS analysis of M. rubida crude venom is broadly consistent with these earlier results, revealing that its venom is a heterogeneous mixture of 96 distinct peptides. Interestingly, peptide lengths and molecular weights fall within a remarkably narrow window (Figure S1), ranging from 368 to 3026 Da, with the vast majority (82 peptides, 85.4%) between 1000 and 3000 Da and 9–27 amino acids (Figure S1). The average peptide in crude M. rubida venom has a molecular weight of 1855 (mean) or 1965 Da (median) and comprises 17 or 18 amino acids (Figure S1). Reduction and alkylation revealed that most peptides are linear and cysteine-free (Table 1). Surprisingly, the three most abundant peptides, all of which have a single intramolecular disulfide bond, co-eluted, suggesting that they have similar amino acid compositions. These findings support our earlier observations [39] and those of others [43] concerning the venom of the ruby ant, M. rubra, which consists predominantly of linear peptides with molecular weights of 1000–3500 Da. Indeed, small linear peptides in the 500–4000 Da range predominate in the venoms of many ants [43]. Furthermore, peptides from cone snails (Conus spp.) are also small (12–30 amino acids), but in contrast to those found in ant venoms, peptides from cone snails tend to be extremely rich in disulfide bonds [52]. Peptidyl toxins from snakes or scorpions are typically longer than those of ants, varying between 40 and 100 amino acids [53]. Even so, ant peptides could nevertheless possess interesting and useful biological activities.
Although the landscape of M. rubida venom peptides has been investigated, no studies have attempted to characterize individual peptide toxins. We used a combination of Edman degradation, accurate mass measurement, and de novo peptide sequencing to reveal the decapeptide sequence NH2-IDPKVLESLV-CONH2, and named this peptide, U-MYRTX-MANr1, according to current nomenclature rules for ant venom peptidyl toxins [2]. This peptide features mostly (60%) hydrophobic amino acids, but also contains both acidic (aspartic acid, glutamic acid) and basic (lysine) residues, resulting in amphipathic properties. Characteristics most often associated with anti-microbial peptides (AMPs) are amphipathicity, hydrophobicity and the presence of (multiple) positive charges [54], enabling them to pass through the bacterial outer membrane, initiated by attachment to anionic lipopolysaccharides [55]. U-MYRTX-MANr1 has a net neutral charge, which may explain its lack of antimicrobial activity in vitro. This result was supported by in silico predictions of negligible antimicrobial activity when the sequence was screened against the Database for Antimicrobial Activity and Structure of Peptides [56]. The absence of antimicrobial activity was also reported for the structurally similar peptide toxins U-MYRTX-MYRrub1 from the ruby ant M. rubra (sequence identity 80%, sequence similarity 100%) [39] and temporin-H, a so-called AMP isolated from the defensive skin secretions of the frog Rana temporaria (sequence identity 40%, sequence similarity 80%) [57].
A full understanding of the antimicrobial potential of U-MYRTX-MANr1 will require further studies to define its activity on bacterial membranes, as well as tests against a wider panel of microbes. A multiple alignment of U-MYRTX-MANr1 with other AMPs and peptide toxins, especially ant venom peptides, is shown in Figure S10. U-MYRTX-MANr1 and U-MYRTX-MYRrub1 are from different species of the Myrmicinae, but share a highly conserved domain, with 1Ile 2Asp 3Pro 4Lys 6Leu 7Glu 8Ser 9Leu as a common motif. They differ only at positions 5 (Val→Leu) and 10 (Val→Ala), and both substitutions are conservative (hydrophobic). Interestingly, this motif seems to be unique among peptide domains discovered thus far in ant venoms, with little structural conservation compared to other ant venom peptides such as pilosulins [51] and ponericins [12]. However, the recently discovered myrmicitoxin U12-MYRTX-Tb1a from the myrmicine ant, Tetramorium bicarinatum, is an exception, in that it also shares the 3Pro 6Leu 8Ser 9Leu motif with U-MYRTX-MANr1 and U-MYRTX-MYRrub1. Such sequence alignments must be approached with some caution because only a limited number of peptide sequences from ant venom are known thus far. Further research is needed to characterize additional ant venom peptides to understand their structure–function relationships and modes of action.
Peptide toxins isolated from scorpion and spider venoms have exhibited diverse biological activities against aphids [34,35,36,37,38]. We tested M. rubida crude venom and the peptide U-MYRTX-MANr1 against A. pisum, expanding the portfolio of peptides that may be suitable for pest management applications. Both the crude venom and the peptide U-MYRTX-MANr1 significantly reduced aphid survival and reproduction (Table 2 and Table S1; Figure 2). Interestingly, the closely related peptide U-MYRTX-MYRrub1 from M. rubra [39] had lower potency against aphids than U-MYRTX-MANr1 (Table 2 and Table S1, Figure S3). These peptides differ at only two residues (Figure S10), but such small differences have a profound effect on bioactivity [58]. For example, the AMPs UyCT1 and D5 derived from the scorpion Urodacus yaschenkoi differ at only two residues, but likewise show vastly different activities against A. pisum [34].
Our previous study showed that U-MYRTX-MYRrub1 is orally active against A. pisum and that sublethal concentrations of this peptide increased the susceptibility of aphids to chemical insecticides [39]. Interestingly, although injected U-MYRTX-MANr1 was more potent than U-MYRTX-MYRrub1, it did not show any direct oral effect and it did not influence the insecticide susceptibility of A. pisum (Figure S6, Table S6). Orally delivered scorpion AMPs isolated from U. yaschenkoi and U. manicatus show remarkable activity against aphids, but this is probably associated with their net positive charge and non-selectivity for cell membranes [58,59]. The natural properties of U-MYRTX-MANr1 suggest that its insecticidal activity (Figure 2) does not involve membrane disruption, but has a different molecular target. Although considered rare in ant venoms, neurotoxic peptides are often found in animal venoms and their role is to achieve rapid prey immobilization [2]. These peptides typically block ion channels, with varying degrees of specificity and efficacy [2]. For example, the P. clavata peptide, poneratoxin, modulates voltage-gated sodium channels in both vertebrates and invertebrates, whereas the dimeric ectatomin Et-1 peptide from the neotropical ant, Ectatomma tuberculatum, blocks voltage-gated calcium channels and acts as a pore-forming peptide in eukaryotic cells [2,50]. Our behavioral assay revealed that crude M. rubida venom or the U-MYRTX-MANr1 peptide triggered severe paralysis after injection (Table 3 and Figure 3), with a much stronger effect than M. rubra venom components (Table S5 and Figure S5). This suggests that U-MYRTX-MANr1 may be a neurotoxin, although further studies are needed to confirm its activity against ion channels.
In addition to paralysis, we observed significant body fluid loss in aphids injected with either crude M. rubida venom or the isolated peptide (Figure 3 and Figure S6). This indicates that hemolymph coagulation may be impaired, which is an important component of wound healing [60,61]. Venom components of the endoparasitoid wasp, Pimpla turionellae (Hymenoptera: Ichneumonidae), suppress hemocyte-mediated immune responses at the cellular level [62]. Therefore, further studies should examine the correlation between ant venom components and the inactivation of hemocytes and/or clotting factors that may be essential for wound healing in aphids. Furthermore, it would be interesting to investigate the observed cessation of aphid embryonic development and tissue alterations after exposure to M. rubida venom (Figure S6).
Although potent peptide toxins can be integrated directly into pest management strategies by spraying the toxins onto plants (e.g., Spear-T developed by Vestaron), the more typical approach is the development of insect-resistant transgenic crops or engineered entomopathogens (e.g., fungi or baculoviruses) [24,25]. The development of bio-insecticides based on venom peptides frequently fails due to their lack of stability or low oral activity, as shown for U-MYRTX-MANr1 [63]. Therefore, natural peptides are usually replaced with synthetic versions that are more stable, as with the U. yaschenkoi AMPs discussed above [58,64,65]. Chemical modifications such as the replacement of individual disulfide bonds with diselenide bonds can improve the oral activity of venom peptides, making them more suitable for the development of bio-insecticides [63].
In summary, the proteomic analysis of M. rubida venom and functional characterization of the novel peptide U-MYRTX-MANr1 make a significant contribution to the underrepresented field of ant venom research. Our insect bioassays suggest that the M. rubida peptide toxin may act simultaneously against several molecular targets (e.g., ion channels or hemolymph coagulation proteins) as previously shown for the ant venom toxin, ectatomin Et-1 [2]. The remarkable insecticidal activity of crude M. rubida venom indicates that additional peptide toxins could also be suitable as leads for the development of novel bio-insecticides.

4. Materials and Methods

4.1. Ant Collection and Taxonomy

Ants identified as M. rubida workers based on their morphology, according to Seifert’s identification key [66], were collected from a sunny open habitat with a rocky-loamy soil in a forest >500 meters above sea level, located near Tambach-Dietharz, Thuringia, Germany. In the laboratory, foraging workers were kept in a plastic box (180 × 135 × 60 mm) containing soil and plant litter from the environment as an artificial nest, fitted with a test tube water reservoir (160 × 16 mm). Ants were provided with 20% sucrose solution and mealworms (Tenebrio molitor) twice a week and maintained under constant conditions (~23 °C, 40% relative humidity, and a 16 h photoperiod).

4.2. Crude Venom Extraction

M. rubida workers were anesthetized with CO2 and the sting apparatus was removed from the abdominal segment. Venom glands and reservoirs of five foraging workers were gently transferred to a 1.5 mL microcentrifuge tube and pooled in 100 µL of chilled methanol. The crude extract was immediately centrifuged for 30 min at 18,000× g. The supernatant was transferred to a new tube for crude venom analysis and fractionation. We used different solvents for crude venom extraction, for reduction and alkylation, and for injection.

4.3. Reduction and Alkylation

Crude venom was extracted in 100 µL of 50 mM ammonium bicarbonate containing 5% acetonitrile and was supplemented with 5 mM dithiothreitol before incubation for 30 min at 56 °C. After cooling the mixture to room temperature, cysteine residues were alkylated with 15 mM iodoacetamide for 30 min in the dark.

4.4. LC-MS Analysis of Venom and Peptides

Conditions and settings for reversed-phase LC and MS data acquisition were modified slightly from our previous study [39]. Peptides were separated with 0.1% formic acid in water (eluent A) and 0.1% formic acid in acetonitrile (eluent B). The starting concentration (5% B) was maintained for 5 min, increased to 60% B in 60 min, then steeply increased to 95% B in 5 min, held for 9 min, then reduced to the starting concentration (5% B) in 1 min, followed by a re-equilibration step (10 min). The following MS instrument settings were used: capillary voltage 3200 V, Hexapole RF 200 Vpp, ion energy 5.0 eV, and collision RF 460 Vpp.

4.5. Edman Degradation

Automated N-terminal sequencing was performed by stepwise Edman degradation (Proteome Factory AG, Berlin, Germany) using a Procise Model 492 cLc protein sequencer (Applied Biosystems, Foster City, CA, USA) according to the manufacturer’s protocol.

4.6. Peptide Synthesis

The U-MYRTX-MANr1 peptide was synthesized by Romer Labs (Butzbach, Germany) according to the manufacturer’s protocol (purity > 98%).

4.7. Determination of Total Protein Concentration for Injection Assays

Peptides from six M. rubida venom glands or 12 M. rubra venom glands were extracted in 50 µL water as described above. Total protein concentration was determined using a NanoDrop 2000 spectrophotometer (Thermo Fisher Scientific, Waltham, MA, USA). The absorbance of a 1.5 µL droplet of crude venom was determined at 205 nm and the total protein concentration was calculated using an extinction coefficient (ε205) of 31 mL·mg−1·cm−1 [67] and Scopes’ method [68]. We used 1 mg·mL−1 solutions of BSA and the synthetic M. rubra decapeptide NH2-IDPKLLESLA-CONH2 [39] as controls. Crude extracts were further diluted to 1.0, 0.1 and 0.01 mg·mL−1 for aphid injection assays.

4.8. Antimicrobial Assay

The minimal inhibition concentration (MIC) was determined by broth dilution assay in a 384-well plate with a final working volume of 20 µL as previously described [69]. Antibacterial and antifungal activity were screened against the following test strains: Bacillus megaterium ATCC 14945, Bacillus subtilis DSM 10, Escherichia coli D31, Listeria fleischmannii DSM 24998, Listeria monocytogenes ATCC 15313, Micrococcus luteus DSM 20030, Staphylococcus aureus ATCC 25923, Moraxella catarrhalis DSM 9143, Pseudomonas aeruginosa ATCC 27853, Staphylococcus epidermidis ATCC 35984, and Candida albicans ATCC 90028. We also used the synthetic analog of the M. rubra decapeptide U-MYRTX-MRArub1 [39]. Microbial strains were cultivated in Mueller–Hinton II or brain heart infusion broth, as appropriate. Peptides were serially diluted (two-fold), resulting in a concentration range from 512 to 0.016 µg·mL−1. Endpoint MIC values were read after 16 h of incubation at 37 °C (C. albicans 28 °C) with continuous shaking on a LUMIstar Omega plate reader (BMG Labtech, Ortenberg, Germany). We measured absorbance at 600 nm (B. megaterium, B. subtilis, E. coli, P. aeruginosa and S. epidermidis) or luminescence (L. fleischmanii, L. monocytogenes, M. luteus, M. catarrhalis, S. aureus and C. albicans) using BacTiter-Glo (Promega, Mannheim, Germany). All experiments were conducted in technical and biological triplicates, including sterility and growth controls (gentamycin and rifampicin).

4.9. Maintenance of Aphids, Injection and Incapacitation Assays

The parthenogenetic A. pisum clone LL01 was reared under constant conditions on broad beans, Vicia faba var. minor, as previously described [34,70]. Age-synchronized aphids (5 days old) were used in all experiments [71]. Aphids were injected laterally, between the middle and hind legs, with 25 nL of crude venom extract or peptides, using glass capillaries held on a M3301 micromanipulator (World Precision Instruments, Hitchin, UK). Crude M. rubida and M. rubra venoms were tested at concentrations of 0.01, 0.1 and 1 mg·mL−1, whereas peptide toxins U-MYRTX-MANr1 and U-MYRTX-MYRrub1 were tested at concentrations of 1, 4 and 16 mg·mL−1. The M. rubra peptide U-MYRTX-MYRrub1 was used as a control because its insecticidal activity had already been confirmed [39]. Water and BSA (1, 4 and 16 mg·mL−1) were used as negative controls. We injected 60 aphids in three biological replicates of 20 individuals per treatment. Injected aphids were reared individually for 10 days in Petri dishes with V. faba leaves on 1% agarose gel [71,72]. Aphid survival and offspring production were monitored daily [46]. Newly emerged nymphs were counted daily and removed. Fresh Petri dishes with V. faba leaves were provided every 5 days to ensure the aphids were maintained in an optimal environment.
Aphid behavior was observed after injections with crude venom (1 mg·mL−1) or the pure peptides (16 mg·mL−1) compared to a water control, with 30 individuals injected per treatment group. Injected aphids were placed on their backs and the time they took to correct their position was recorded [4]. Aphid fitness and behavior were assessed immediately after and 1 h after injection and images were acquired using a Leica M125 C stereomicroscope.

4.10. Feeding Assays and Insecticide Bioassays

The oral activity of toxin U-MYRTX-MANr1 and its effect on aphid susceptibility to chemical insecticides were tested as previously described [39] with minor modifications. Briefly, we fed A. pisum nymphs (5 days old) for 3 days in modified chambers [73] on an artificial diet [74] mixed with U-MYRTX-MANr1 (500 µg·mL−1) or a negative control diet in which the peptide solution was replaced with water. Survival was scored daily over the 3 days of feeding. We tested ~1300 aphids per treatment in three biological replicates.
Aphids that survived the 3 day feeding treatment with U-MYRTX-MANr1 or the control were transferred to insecticide bioassays. We tested three chemical insecticides: imidacloprid (neonicotinoid), methomyl (carbamate) and spirotetramat (tetramic acid derivative) [18,32]. All were acquired from Chem Service Inc. (West Chester, PA, USA). For each insecticide, a stock solution of 1000 µg·mL−1 was prepared in acetone and working solutions (imidacloprid = 0.0975 µg·mL−1; methomyl = 6.25 µg·mL−1; spirotetramat = 1.56 µg·mL−1) were prepared in water. Sub-lethal concentrations of each compound were used, based on previous studies [46].
Insecticide bioassays were carried out as previously described [39,46]. Briefly, V. faba stems with roots (2–3 weeks old) were dipped into Falcon tubes (50 mL) containing each insecticide working solution for 24 h. Petri dishes were then prepared with bean leaf discs prepared from the treated stems, as recommended by the Insecticide Resistance Action Committee (IRAC) [75]. Ten aphids, previously treated with the peptide or control diet, were transferred to each leaf disc in 6–8 replicates for each insecticide. Each experiment was conducted with three biological replicates, along with corresponding solvent and water controls. Aphid mortality was scored after exposure for 3 days.

4.11. Histological Preparations

For light microscopy, 30 aphids (5 days old) 12 h after each treatment were pre-fixed in 2.5% glutaraldehyde in 0.1 M phosphate buffer (pH 7.4) for 1 h. Treatment groups were assigned as follows: (I) water injection, (II) peptide toxin U-MYRTX-MANr1 (16 mg·mL−1), and (III) crude M. rubida venom (1 mg·mL−1). After washing in phosphate buffer, aphids were post-fixed in 1% OsO4 in the same buffer for 1 h. After dehydration in a graded ethanol series, aphids were embedded in Araldite epoxy resin (Plano, Germany). Semi-thin sections were prepared from five randomly chosen specimens representing each treatment using a Reichert Om/U3 ultramicrotome. Sections were stained with 1% toluidine blue in 1% sodium borate and examined using a Leica DM 4 B microscope.

4.12. Data Analysis

Molecular features were extracted from acquired mass spectra using Compass DataAnalysis v4.2 (Bruker Daltonics, Billerica, MA, USA) as previously described [39]. MS data were analyzed and visualized using SigmaPlot v12.5 (Systat Software, San Jose, CA, USA). We analyzed aphid fitness data using IBM SPSS Statistics v17 (Armonk, New York, NY, USA). Statistical significance was defined as p < 0.05. Survival data were analyzed by Kaplan–Meier survival analysis and comparisons between groups were based on log-rank tests. The total number of offspring was analyzed using the Mann–Whitney U test for non-parametric data and Student’s t-test for normally distributed data. For insecticide bioassays, total mortality for each insecticide treatment was corrected according to Abbott’s formula, based on mortality scored in control groups [76]. The mortality in solvent control groups was 4–12%. We used the Mann–Whitney U test to compare mortality between the two feeding treatments (peptide toxin and diet control). For sequence alignment, we used Clustal Omega v1.2.4 from the European Bioinformatics Institute (Hinxton, UK) [77] and the online tool Sequence Identity And Similarity (SIAS) [78].

Supplementary Materials

The following are available online at https://0-www-mdpi-com.brum.beds.ac.uk/2072-6651/11/10/562/s1, Figure S1: Distribution of peptides in the venom of Manica rubida (n = 96 peptides) according to amino acid sequence length and molecular weight. Figure S2: Fragmentation pattern of the peptide U-MYRTX-MANr1. Table S1: Effect of crude venom and peptide toxins on the total number of offspring in Acyrthosiphon pisum. Table S2: Statistical data for the Kaplan–Meier survival analysis shown in Figure 2. Figure S3: Insecticidal activity of Myrmica rubra crude venom and peptide U-MYRTX-MRArub1 in Acyrthosiphon pisum. Table S3: Statistical data for Kaplan–Meier survival analysis shown in Figure S3. Figure S4: Insecticidal activity of bovine serum albumin (BSA) control in Acyrthosiphon pisum. Table S4: Statistical data for Kaplan–Meier survival analysis shown in Figure S4. Table S5: Aphid behavior and fitness after the injection of water, U-MYRTX-MYRrub1, or Myrmica rubra crude venom. Figure S5: Injection wound healing in Acyrthosiphon pisum 1 h post-injection of water, U-MYRTX-MYRrub1, or crude Myrmica rubra venom. Figure S6: Semi-thin cross-section through the abdomen of Acyrthosiphon pisum injected with crude Manica rubida venom. Figure S7: Semi-thin cross-section through abdomen of Acyrthosiphon pisum injected with Manica rubida peptide U-MYRTX-MANr1. Figure S8: Semi-thin cross-section through the abdomen of Acyrthosiphon pisum injected with water. Figure S9: Insecticidal activity of orally delivered Manica rubida peptide U-MYRTX-MANr1. Table S6: Summary of statistical data for the insecticidal activity of orally delivered Manica rubida peptide U-MYRTX-MANr1 and its effect on the susceptibility of aphids to chemical insecticides. Figure S10: Alignment of U-MYRTX-MANr1 with peptide sequences found in the venom of other arthropods or defensive skin secretions of frogs.

Author Contributions

Conceptualization, J.H., M.S.(Marisa Skaljac) and A.V.; Formal analysis, J.H. and M.S.(Marisa Skaljac); Funding acquisition, A.V.; Investigation, J.H., J.G., T.K., M.S.(Maximilian Seip) and H.S.; Methodology, J.H., M.S.(Marisa Skaljac) and H.S.; Project administration, M.S.(Marisa Skaljac) and A.V.; Resources, A.V.; Software, J.H. and M.S.(Marisa Skaljac); Supervision, M.S.(Marisa Skaljac) and A.V.; Validation, J.H., M.S.(Marisa Skaljac), H.S. and A.V.; Visualization, J.H., M.S.(Marisa Skaljac) and H.S.; Writing—original draft, J.H. and M.S.(Marisa Skaljac); Writing—review and editing, A.V.

Funding

The authors acknowledge generous funding by the Hessen State Ministry of Higher Education, Research and the Arts (HMWK) via the “LOEWE Center for Insect Biotechnology and Bioresources”.

Acknowledgments

We would like to thank Olga Lang, Svenja Thöneböhn, Benedikt Leis and Sanja Mihajlovic from Fraunhofer IME (Giessen, Germany) for their valuable help and support in this study. We thank the “Imaging Unit” of the Biomedical Research Center Senckenberg (Justus-Liebig University of Giessen) for providing the ultramicrotome equipment. We are grateful to Richard M. Twyman for editing the manuscript.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. AntWeb. Available online: https://www.antweb.org (accessed on 1 July 2019).
  2. Touchard, A.; Aili, R.S.; Fox, G.E.; Escoubas, P.; Orivel, J.; Nicholson, M.G.; Dejean, A. The Biochemical Toxin Arsenal from Ant Venoms. Toxins 2016, 8, 30. [Google Scholar] [CrossRef] [PubMed]
  3. Aili, S.R.; Touchard, A.; Petitclerc, F.D.R.; Dejean, A.; Orivel, J.R.M.; Padula, M.P.; Escoubas, P.; Nicholson, G.M. Combined peptidomic and proteomic analysis of electrically stimulated and manually dissected venom from the South American bullet ant Paraponera clavata. J. Proteome Res. 2017, 16, 1339–1351. [Google Scholar] [CrossRef] [PubMed]
  4. Robinson, S.D.; Mueller, A.; Clayton, D.; Starobova, H.; Hamilton, B.R.; Payne, R.J.; Vetter, I.; King, G.F.; Undheim, E.A.B. A comprehensive portrait of the venom of the giant red bull ant, Myrmecia gulosa, reveals a hyperdiverse hymenopteran toxin gene family. Sci. Adv. 2018, 4, eaau4640. [Google Scholar] [CrossRef] [PubMed]
  5. Osman, M.F.H.; Brander, J. Weitere Beiträge zur Kenntnis der chemischen Zusammensetzung des Giftes von Ameisen aus der Gattung Formica. Z. Naturforsch. B 1961, 16, 749–753. [Google Scholar] [CrossRef]
  6. Pluzhnikov, K.A.; Kozlov, S.A.; Vassilevski, A.A.; Vorontsova, O.V.; Feofanov, A.V.; Grishin, E.V. Linear antimicrobial peptides from Ectatomma quadridens ant venom. Biochimie 2014, 107, 211–215. [Google Scholar] [CrossRef] [PubMed]
  7. Rifflet, A.; Gavalda, S.; Tene, N.; Orivel, J.; Leprince, J.; Guilhaudis, L.; Genin, E.; Vetillard, A.; Treilhou, M. Identification and characterization of a novel antimicrobial peptide from the venom of the ant Tetramorium bicarinatum. Peptides 2012, 38, 363–370. [Google Scholar] [CrossRef] [PubMed]
  8. Aili, S.R.; Touchard, A.; Escoubas, P.; Padula, M.P.; Orivel, J.; Dejean, A.; Nicholson, G.M. Diversity of peptide toxins from stinging ant venoms. Toxicon 2014, 92, 166–178. [Google Scholar] [CrossRef] [PubMed]
  9. Kazuma, K.; Masuko, K.; Konno, K.; Inagaki, H. Combined Venom Gland Transcriptomic and Venom Peptidomic Analysis of the Predatory Ant Odontomachus monticola. Toxins 2017, 9, 323. [Google Scholar] [CrossRef] [PubMed]
  10. Bouzid, W.; Klopp, C.; Verdenaud, M.; Ducancel, F.; Vétillard, A. Profiling the venom gland transcriptome of Tetramorium bicarinatum (Hymenoptera: Formicidae): The first transcriptome analysis of an ant species. Toxicon 2013, 70, 70–81. [Google Scholar] [CrossRef]
  11. Johnson, S.R.; Copello, J.A.; Evans, M.S.; Suarez, A.V. A biochemical characterization of the major peptides from the venom of the giant neotropical hunting ant Dinoponera australis. Toxicon 2010, 55, 702–710. [Google Scholar] [CrossRef]
  12. Orivel, J.; Redeker, V.; Le Caer, J.P.; Krier, F.; Revol-Junelles, A.M.; Longeon, A.; Chaffotte, A.; Dejean, A.; Rossier, J. Ponericins, new antibacterial and insecticidal peptides from the venom of the ant Pachycondyla goeldii. J. Biol. Chem. 2001, 276, 17823–17829. [Google Scholar] [CrossRef] [PubMed]
  13. Schmidt, C.A.; Shattuck, S.O. The higher classification of the ant subfamily Ponerinae (Hymenoptera: Formicidae), with a review of ponerine ecology and behavior. Zootaxa 2014, 3817, 1–242. [Google Scholar] [CrossRef] [PubMed]
  14. Lima, D.B.; Torres, A.F.C.; Mello, C.P.; de Menezes, R.; Sampaio, T.L.; Canuto, J.A.; da Silva, J.J.A.; Freire, V.N.; Quinet, Y.P.; Havt, A.; et al. Antimicrobial effect of Dinoponera quadriceps (Hymenoptera: Formicidae) venom against Staphylococcus aureus strains. J. Appl. Microbiol. 2014, 117, 390–396. [Google Scholar] [CrossRef] [PubMed]
  15. Schluns, H.; Crozier, R.H. Molecular and chemical immune defenses in ants (Hymenoptera: Formicidae). Myrmecol. News 2009, 12, 237–249. [Google Scholar]
  16. Pimentel, D. Pesticides and Pest Control. In Integrated Pest Management: Innovation-Development Process: Volume 1; Peshin, R., Dhawan, A.K., Eds.; Springer: Dordrecht, The Netherlands, 2009; pp. 83–87. [Google Scholar]
  17. Oerke, E.C. Crop losses to pests. J. Agric. Sci. 2005, 144, 31–43. [Google Scholar] [CrossRef]
  18. Sparks, T.C.; Nauen, R. IRAC: Mode of action classification and insecticide resistance management. Pestic. Biochem. Physiol. 2015, 121, 122–128. [Google Scholar] [CrossRef] [Green Version]
  19. King, G.F.; Hardy, M.C. Spider-venom peptides: Structure, pharmacology, and potential for control of insect pests. Annu. Rev. Entomol. 2013, 58, 475–496. [Google Scholar] [CrossRef] [PubMed]
  20. Herzig, V.; Ikonomopoulou, M.; Smith, J.J.; Dziemborowicz, S.; Gilchrist, J.; Kuhn-Nentwig, L.; Rezende, F.O.; Moreira, L.A.; Nicholson, G.M.; Bosmans, F.; et al. Molecular basis of the remarkable species selectivity of an insecticidal sodium channel toxin from the African spider Augacephalus ezendami. Sci. Rep. 2016, 6, 29538. [Google Scholar] [CrossRef]
  21. Jørgensen, P.S.; Aktipis, A.; Brown, Z.; Carrière, Y.; Downes, S.; Dunn, R.R.; Epstein, G.; Frisvold, G.B.; Hawthorne, D.; Gröhn, Y.T.; et al. Antibiotic and pesticide susceptibility and the Anthropocene operating space. Nat. Sustain. 2018, 1, 632–641. [Google Scholar] [CrossRef]
  22. Barzman, M.; Bàrberi, P.; Birch, A.N.E.; Boonekamp, P.; Dachbrodt-Saaydeh, S.; Graf, B.; Hommel, B.; Jensen, J.E.; Kiss, J.; Kudsk, P.; et al. Eight principles of integrated pest management. Agron. Sustain. Dev. 2015, 35, 1199–1215. [Google Scholar] [CrossRef]
  23. European Parliament. Think Thank. Farming without Plant Protection Products. Available online: https://www.europarl.europa.eu/RegData/etudes/IDAN/2019/634416/EPRS_IDA(2019)634416_EN.pdf (accessed on 1 July 2019).
  24. Windley, M.J.; Herzig, V.; Dziemborowicz, S.A.; Hardy, M.C.; King, G.F.; Nicholson, G.M. Spider-Venom Peptides as Bioinsecticides. Toxins 2012, 4, 191–227. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  25. King, G.F. Tying pest insects in knots: The deployment of spider-venom-derived knottins as bioinsecticides. Pest Manag. Sci. 2019. [Google Scholar] [CrossRef] [PubMed]
  26. Piek, T.; Duval, A.; Hue, B.; Karst, H.; Lapied, B.; Mantel, P.; Nakajima, T.; Pelhate, M.; Schmidt, J.O. Poneratoxin, a novel peptide neurotoxin from the venom of the ant, Paraponera clavata. Comp. Biochem. Physiol. C Comp. Pharmacol. 1991, 99, 487–495. [Google Scholar] [CrossRef]
  27. Piek, T.; Hue, B.; Mantel, P.; Terumi, N.; Schmidt, J.O. Pharmacological characterization and chemical fractionation of the venom of the ponerine ant, Paraponera clavata (F.). Comp. Biochem. Physiol. C Comp. Pharmacol. 1991, 99, 481–486. [Google Scholar] [CrossRef]
  28. Touchard, A.; Brust, A.; Cardoso, F.C.; Chin, Y.K.Y.; Herzig, V.; Jin, A.H.; Dejean, A.; Alewood, P.F.; King, G.F.; Orivel, J.; et al. Isolation and characterization of a structurally unique β-hairpin venom peptide from the predatory ant Anochetus emarginatus. Biochim. Biophys. Acta 2016, 1860, 2553–2562. [Google Scholar] [CrossRef] [PubMed]
  29. Van Emden, H.F.; Harrington, R. Aphids as Crop Pests; CABI: Wallingford, UK, 2017. [Google Scholar]
  30. Will, T.; Vilcinskas, A. Aphid-proof plants: Biotechnology-based approaches for aphid control. In Yellow Biotechnology II; Springer: Berlin/Heidelberg, Germany, 2013; pp. 179–203. [Google Scholar]
  31. Vilcinskas, A. Biology and Ecology of Aphids; CRC Press: Boca Raton, FL, USA, 2016. [Google Scholar]
  32. IRAC—Insecticide Resistance Action Committee. Available online: http://www.irac-online.org/documents/sucking-pests-moa-poster/ (accessed on 1 July 2019).
  33. Bass, C.; Puinean, A.M.; Zimmer, C.T.; Denholm, I.; Field, L.M.; Foster, S.P.; Gutbrod, O.; Nauen, R.; Slater, R.; Williamson, M.S. The evolution of insecticide resistance in the peach potato aphid, Myzus persicae. Insect Biochem. Mol. Biol. 2014, 51, 41–51. [Google Scholar] [CrossRef] [PubMed]
  34. Luna-Ramirez, K.; Skaljac, M.; Grotmann, J.; Kirfel, P.; Vilcinskas, A. Orally delivered scorpion antimicrobial peptides exhibit activity against Pea Aphid (Acyrthosiphon pisum) and its bacterial symbionts. Toxins 2017, 9, 261. [Google Scholar] [CrossRef] [PubMed]
  35. Pal, N.; Yamamoto, T.; King, G.F.; Waine, C.; Bonning, B. Aphicidal efficacy of scorpion-and spider-derived neurotoxins. Toxicon 2013, 70, 114–122. [Google Scholar] [CrossRef]
  36. Xie, M.; Zhang, Y.J.; Zhai, X.M.; Zhao, J.J.; Peng, D.L.; Wu, G. Expression of a scorpion toxin gene BmKit enhances the virulence of Lecanicillium lecanii against aphids. J. Pest Sci. 2015, 88, 637–644. [Google Scholar] [CrossRef]
  37. Yang, S.; Fitches, E.; Pyati, P.; Gatehouse, J.A. Effect of insecticidal fusion proteins containing spider toxins targeting sodium and calcium ion channels on pyrethroid-resistant strains of peach-potato aphid (Myzus persicae). Pest Manag. Sci. 2015, 71, 951–956. [Google Scholar] [CrossRef]
  38. Bonning, B.C.; Pal, N.; Liu, S.; Wang, Z.; Sivakumar, S.; Dixon, P.M.; King, G.F.; Miller, W.A. Toxin delivery by the coat protein of an aphid-vectored plant virus provides plant resistance to aphids. Nat. Biotechnol. 2014, 32, 102. [Google Scholar] [CrossRef] [PubMed]
  39. Heep, J.; Klaus, A.; Kessel, T.; Seip, M.; Vilcinskas, A.; Skaljac, M. Proteomic Analysis of the Venom from the Ruby Ant Myrmica rubra and the Isolation of a Novel Insecticidal Decapeptide. Insects 2019, 10, 42. [Google Scholar] [CrossRef] [PubMed]
  40. Wheeler, G.C.; Wheeler, J. The Natural History of Manica (Hymenoptera: Formicidae). J. Kans. Entomol. Soc. 1970, 43, 129–162. [Google Scholar]
  41. Lenoir, A.; Devers, S.; Marchand, P.; Bressac, C.; Savolainen, R. Microgynous queens in the Paleartic ant, Manica rubida: Dispersal morphs or social parasites? J. Insect Sci. 2010, 10. [Google Scholar] [CrossRef] [PubMed]
  42. Brown, M.J.F.; Bonhoeffer, S. On the evolution of claustral colony founding in ants. Evol. Ecol. Res. 2003, 5, 305–313. [Google Scholar]
  43. Touchard, A.; Koh, J.M.; Aili, S.R.; Dejean, A.; Nicholson, G.M.; Orivel, J.; Escoubas, P. The complexity and structural diversity of ant venom peptidomes is revealed by mass spectrometry profiling. Rapid Commun. Mass Spectrom. 2015, 29, 385–396. [Google Scholar] [CrossRef]
  44. Senko, M.W.; Beu, S.C.; McLaffertycor, F.W. Determination of monoisotopic masses and ion populations for large biomolecules from resolved isotopic distributions. J. Am. Soc. Mass Spectrom. 1995, 6, 229–233. [Google Scholar] [CrossRef] [Green Version]
  45. King, G.F.; Gentz, M.C.; Escoubas, P.; Nicholson, G.M. A rational nomenclature for naming peptide toxins from spiders and other venomous animals. Toxicon 2008, 52, 264–276. [Google Scholar] [CrossRef] [Green Version]
  46. Skaljac, M.; Kirfel, P.; Grotmann, J.; Vilcinskas, A. Fitness costs of infection with Serratia symbiotica are associated with greater susceptibility to insecticides in the pea aphid Acyrthosiphon pisum. Pest Manag. Sci. 2018, 74, 1829–1836. [Google Scholar] [CrossRef]
  47. Fiedler, K.; Kuhlmann, F.; Schlick-Steiner, B.C.; Steiner, F.M.; Gebauer, G. Stable N-isotope signatures of central European ants—Assessing positions in a trophic gradient. Insectes Soc. 2007, 54, 393–402. [Google Scholar] [CrossRef]
  48. Tani, N.; Kazuma, K.; Ohtsuka, Y.; Shigeri, Y.; Masuko, K.; Konno, K.; Inagaki, H. Mass Spectrometry Analysis and Biological Characterization of the Predatory Ant Odontomachus monticola Venom and Venom Sac Components. Toxins 2019, 11, 50. [Google Scholar] [CrossRef] [PubMed]
  49. Pan, J.; Hink, W.F. Isolation and characterization of myrmexins, six isoforms of venom proteins with anti-inflammatory activity from the tropical ant, Pseudomyrmex triplarinus. Toxicon 2000, 38, 1403–1413. [Google Scholar] [CrossRef]
  50. Szolajska, E.; Poznanski, J.; Ferber, M.L.; Michalik, J.; Gout, E.; Fender, P.; Bailly, I.; Dublet, B.; Chroboczek, J. Poneratoxin, a neurotoxin from ant venom: Structure and expression in insect cells and construction of a bio-insecticide. Eur. J. Biochem. 2004, 271, 2127–2136. [Google Scholar] [CrossRef] [PubMed]
  51. Wanandy, T.; Gueven, N.; Davies, N.W.; Brown, S.G.A.; Wiese, M.D. Pilosulins: A review of the structure and mode of action of venom peptides from an Australian ant Myrmecia pilosula. Toxicon 2015, 98, 54–61. [Google Scholar] [CrossRef] [PubMed]
  52. Terlau, H.; Olivera, B.M. Conus venoms: A rich source of novel ion channel-targeted peptides. Physiol. Rev. 2004, 84, 41–68. [Google Scholar] [CrossRef] [PubMed]
  53. Olivera, B.M.; Rivier, J.; Clark, C.; Ramilo, C.A.; Corpuz, G.P.; Abogadie, F.C.; Mena, E.E.; Hillyard, D.R.; Cruz, L.J. Diversity of Conus neuropeptides. Science 1990, 249, 257–263. [Google Scholar] [CrossRef]
  54. Chen, Y.; Guarnieri, M.T.; Vasil, A.I.; Vasil, M.L.; Mant, C.T.; Hodges, R.S. Role of Peptide Hydrophobicity in the Mechanism of Action of α-Helical Antimicrobial Peptides. Antimicrob. Agents Chemother. 2007, 51, 1398. [Google Scholar] [CrossRef]
  55. Hale, J.D.F.; Hancock, R.E.W. Alternative mechanisms of action of cationic antimicrobial peptides on bacteria. Expert Rev. Anti-Infect. Ther. 2007, 5, 951–959. [Google Scholar] [CrossRef]
  56. Pirtskhalava, M.; Gabrielian, A.; Cruz, P.; Griggs, H.L.; Squires, R.B.; Hurt, D.E.; Grigolava, M.; Chubinidze, M.; Gogoladze, G.; Vishnepolsky, B.; et al. DBAASP v.2: An enhanced database of structure and antimicrobial/cytotoxic activity of natural and synthetic peptides. Nucleic Acids Res. 2015, 44, D1104–D1112. [Google Scholar] [CrossRef]
  57. Simmaco, M.; Mignogna, G.; Canofeni, S.; Miele, R.; Mangoni, M.L.; Barra, D. Temporins, Antimicrobial Peptides from the European Red Frog Rana temporaria. Eur. J. Biochem. 1996, 242, 788–792. [Google Scholar] [CrossRef]
  58. Luna-Ramirez, K.; Tonk, M.; Rahnamaeian, M.; Vilcinskas, A. Bioactivity of Natural and Engineered Antimicrobial Peptides from Venom of the Scorpions Urodacus yaschenkoi and U. manicatus. Toxins 2017, 9, 22. [Google Scholar] [CrossRef] [PubMed]
  59. Sani, M.A.; Separovic, F. How membrane-active peptides get into lipid membranes. Acc. Chem. Res. 2016, 49, 1130–1138. [Google Scholar] [CrossRef] [PubMed]
  60. Dushay, M.S. Insect hemolymph clotting. Cell. Mol. Life Sci. 2009, 66, 2643–2650. [Google Scholar] [CrossRef] [PubMed]
  61. Altincicek, B.; Gross, J.; Vilcinskas, A. Wounding-mediated gene expression and accelerated viviparous reproduction of the pea aphid Acyrthosiphon pisum. Insect Mol. Biol. 2008, 17, 711–716. [Google Scholar] [CrossRef]
  62. Er, A.; Sak, O.; Ergin, E.; Uçkan, F.; Rivers, D.B. Venom-induced immunosuppression: An overview of hemocyte-mediated responses. Psyche A J. Entomol. 2011, 2011, 276376. [Google Scholar] [CrossRef]
  63. Herzig, V.; De Araujo, D.A.; Greenwood, P.K.; Chin, K.Y.; Windley, J.M.; Chong, Y.; Muttenthaler, M.; Mobli, M.; Audsley, N.; Nicholson, M.G.; et al. Evaluation of Chemical Strategies for Improving the Stability and Oral Toxicity of Insecticidal Peptides. Biomedicines 2018, 6, 90. [Google Scholar] [CrossRef] [PubMed]
  64. Keymanesh, K.; Soltani, S.; Sardari, S. Application of antimicrobial peptides in agriculture and food industry. World J. Microbiol. Biotechnol. 2009, 25, 933–944. [Google Scholar] [CrossRef]
  65. Marcos, J.F.; Muñoz, A.; Pérez-Payá, E.; Misra, S.; López-García, B. Identification and Rational Design of Novel Antimicrobial Peptides for Plant Protection. Annu. Rev. Phytopathol. 2008, 46, 273–301. [Google Scholar] [CrossRef]
  66. Seifert, B. Die Ameisen Mittel-und Nordeuropas; Lutra Verlag-u. Vertriebsges: Görlitz/Tauer, Germany, 2007. [Google Scholar]
  67. Anthis, N.J.; Clore, G.M. Sequence-specific determination of protein and peptide concentrations by absorbance at 205 nm. Protein Sci. 2013, 22, 851–858. [Google Scholar] [CrossRef] [Green Version]
  68. Scopes, R.K. Measurement of protein by spectrophotometry at 205 nm. Anal. Biochem. 1974, 59, 277–282. [Google Scholar] [CrossRef]
  69. Hirsch, R.; Wiesner, J.; Marker, A.; Pfeifer, Y.; Bauer, A.; Hammann, P.E.; Vilcinskas, A. Profiling antimicrobial peptides from the medical maggot Lucilia sericata as potential antibiotics for MDR Gram-negative bacteria. J. Antimicrob. Chemother. 2018, 74, 96–107. [Google Scholar] [CrossRef] [PubMed]
  70. Will, T.; Schmidtberg, H.; Skaljac, M.; Vilcinskas, A. Heat shock protein 83 plays pleiotropic roles in embryogenesis, longevity, and fecundity of the pea aphid Acyrthosiphon pisum. Dev. Genes Evol. 2017, 227, 1–9. [Google Scholar] [CrossRef] [PubMed]
  71. Sapountzis, P.; Duport, G.; Balmand, S.; Gaget, K.; Jaubert-Possamai, S.; Febvay, G.; Charles, H.; Rahbé, Y.; Colella, S.; Calevro, F. New insight into the RNA interference response against cathepsin-L gene in the pea aphid, Acyrthosiphon pisum: Molting or gut phenotypes specifically induced by injection or feeding treatments. Insect Biochem. Mol. Biol. 2014, 51, 20–32. [Google Scholar] [CrossRef] [PubMed]
  72. Will, T.; Vilcinskas, A. The structural sheath protein of aphids is required for phloem feeding. Insect Biochem. Mol. Biol. 2015, 57, 34–40. [Google Scholar] [CrossRef] [PubMed]
  73. Sadeghi, A.; Van Damme, E.J.M.; Smagghe, G.; Cullen, E. Evaluation of the susceptibility of the pea aphid, Acyrthosiphon pisum, to a selection of novel biorational insecticides using an artificial diet. J. Insect Sci. 2009, 9. [Google Scholar] [CrossRef] [PubMed]
  74. Akey, D.H.; Beck, S.D. Continuous Rearing of the Pea Aphid, Acyrthosiphon pisum, on a Holidic Diet. Ann. Entomol. Soc. Am. 1971, 64, 353–356. [Google Scholar] [CrossRef]
  75. IRAC—Insecticide Resistance Action Committee. Susceptibility Test Method 019. Available online: https://www.irac-online.org/methods/aphids-adultnymphs/ (accessed on 1 July 2019).
  76. Abbott, W.S. A method of computing the effectiveness of an insecticide. J. Econ. Entomol. 1925, 18, 265–267. [Google Scholar] [CrossRef]
  77. Madeira, F.; Park, Y.M.; Lee, J.; Buso, N.; Gur, T.; Madhusoodanan, N.; Basutkar, P.; Tivey, A.R.N.; Potter, S.C.; Finn, R.D.; et al. The EMBL-EBI search and sequence analysis tools APIs in 2019. Nucleic Acids Res. 2019, 47, W636–W641. [Google Scholar] [CrossRef] [Green Version]
  78. Immunomedicine Group. Sequence Identity and Similarity (SIAS). Available online: http://bio.med.ucm.es/Tools/sias.html (accessed on 1 July 2019).
Figure 1. (A) Crude venom of the myrmicine ant, Manica rubida, was analyzed by LC-MS on a C18 reversed-phase column with gradient elution (dashed line) using water and acetonitrile supplemented with 0.1% formic acid as mobile phases. The asterisk indicates the peptide that was isolated for further characterization. (B) The mass spectrum of the corresponding decapeptide U-MYRTX-MANr1 acquired on a high-resolution micrOTOF-QII instrument (Bruker Daltonics, Billerica, MA, USA).
Figure 1. (A) Crude venom of the myrmicine ant, Manica rubida, was analyzed by LC-MS on a C18 reversed-phase column with gradient elution (dashed line) using water and acetonitrile supplemented with 0.1% formic acid as mobile phases. The asterisk indicates the peptide that was isolated for further characterization. (B) The mass spectrum of the corresponding decapeptide U-MYRTX-MANr1 acquired on a high-resolution micrOTOF-QII instrument (Bruker Daltonics, Billerica, MA, USA).
Toxins 11 00562 g001
Figure 2. Low pea aphid survival reveals the strong insecticidal activity of crude Manica rubida venom (100% mortality) and peptide U-MYRTX-MANr1 at high (~93% mortality) and medium concentrations (~30% mortality) after 10 days. Survival (60 aphids in three biological replicates of 20 individuals per treatment) was monitored for 10 days following the injection of crude venom (A) or the peptide (B) into pea aphids, Acyrthosiphon pisum. Survival data were analyzed using Kaplan–Meier statistics and comparisons between the treatment and control were based on log-rank tests. Statistical data are shown in Table 2 and Table S2.
Figure 2. Low pea aphid survival reveals the strong insecticidal activity of crude Manica rubida venom (100% mortality) and peptide U-MYRTX-MANr1 at high (~93% mortality) and medium concentrations (~30% mortality) after 10 days. Survival (60 aphids in three biological replicates of 20 individuals per treatment) was monitored for 10 days following the injection of crude venom (A) or the peptide (B) into pea aphids, Acyrthosiphon pisum. Survival data were analyzed using Kaplan–Meier statistics and comparisons between the treatment and control were based on log-rank tests. Statistical data are shown in Table 2 and Table S2.
Toxins 11 00562 g002
Figure 3. Injection wound healing in Acyrthosiphon pisum 1 h post-injection with water (A1–A3), U-MYRTX-MANr1 (16 mg·mL−1) (B1–B3), or crude Manica rubida venom (1 mg·mL−1) (C1–C3) (30 individuals injected per treatment). Hemolymph coagulation was impaired in aphids injected with U-MYRTX-MANr1, but the effects were more severe with crude venom, resulting in a massive loss of hemolymph. The injection site and melanization of exposed hemolymph are indicated with red arrows.
Figure 3. Injection wound healing in Acyrthosiphon pisum 1 h post-injection with water (A1–A3), U-MYRTX-MANr1 (16 mg·mL−1) (B1–B3), or crude Manica rubida venom (1 mg·mL−1) (C1–C3) (30 individuals injected per treatment). Hemolymph coagulation was impaired in aphids injected with U-MYRTX-MANr1, but the effects were more severe with crude venom, resulting in a massive loss of hemolymph. The injection site and melanization of exposed hemolymph are indicated with red arrows.
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Table 1. The most abundant peptides (relative peak intensity ≥ 3%) in the venom of Manica rubida. The venom peptidome is dominated by linear peptides, but contains a few peptides with one intramolecular disulfide bond. RT = retention time, Int. = relative peak intensity, MW = molecular weight, S-S = disulfide bond.
Table 1. The most abundant peptides (relative peak intensity ≥ 3%) in the venom of Manica rubida. The venom peptidome is dominated by linear peptides, but contains a few peptides with one intramolecular disulfide bond. RT = retention time, Int. = relative peak intensity, MW = molecular weight, S-S = disulfide bond.
No.RT [min]Int. [%]MWcrude [Da]MWred. [Da]MWalk. [Da]S-SLength a
126.381314.711314.711314.72012
226.371352.661352.661352.66012
326.341336.691336.701336.70012
427.0771434.801436.831550.87113
527.181208.641210.661324.70111
627.131472.751474.771588.81113
732.1151132.641132.651132.65010
832.1281093.641093.641093.64010
932.1171148.611148.611148.61010
1032.17920.50920.50920.5008
1132.14994.57994.57994.5709
1232.11001110.671110.681110.66010
1338.941136.681136.681136.68010
1443.4622739.632739.642739.64025
1543.4122569.522569.532569.53023
1643.6172978.602978.612978.61027
1744.752850.722850.722850.73026
1846.332987.792987.792987.79027
1951.532823.762823.772823.77025
2051.5192840.792840.802840.80026
2154.5922174.272174.272174.28020
2254.632218.222218.232218.23020
2354.6452196.242196.252196.25020
2454.6182212.212212.212212.21020
2554.642042.102042.112042.11018
2655.272840.792840.802840.80026
a The amino acid sequence length was calculated using averagine (111.1254) [44].
Table 2. Crude ant venoms and associated peptidyl toxins strongly reduced the survival of injected aphids (Acyrthosiphon pisum) (60 aphids in three biological replicates of 20 individuals per treatment).
Table 2. Crude ant venoms and associated peptidyl toxins strongly reduced the survival of injected aphids (Acyrthosiphon pisum) (60 aphids in three biological replicates of 20 individuals per treatment).
Treatment Concentration (mg·mL−1)% SurvivalSignificance a
Bovine serum albumin (BSA) b1678.3ns
484.7ns
191.7p < 0.05
Crude venomManica rubida10.0p < 0.0001
0.133.3p < 0.0001
0.0166.7ns
Myrmica rubra120.0p < 0.0001
0.171.7ns
0.0166.7ns
PeptidesU-MYRTX-MANr1
(Manica rubida)
166.7p < 0.0001
430.0p < 0.0001
175.0ns
U-MYRTX-MYRrub1
(Myrmica rubra)
1641.7p < 0.0001
460.0p < 0.01
180.0ns
a Compared to water (survival ~78%, 10 days post-injection); b BSA was used as peptide/protein control; ns = not significant.
Table 3. Aphid behavior and fitness after the injection of water, U-MYRTX-MANr1 (16 mg·mL−1) or Manica rubida crude venom (1 mg·mL−1) (30 individuals injected per treatment). Observations were recorded immediately after injection and 1 h later.
Table 3. Aphid behavior and fitness after the injection of water, U-MYRTX-MANr1 (16 mg·mL−1) or Manica rubida crude venom (1 mg·mL−1) (30 individuals injected per treatment). Observations were recorded immediately after injection and 1 h later.
TreatmentImmediately Post-Injection1 h Post-Injection
Control
(water)
Immediate righting;
responsiveness < 10 s;
fast and active movement
No visible impact on vitality or fitness
U-MYRTX-MANr1
16 mg·mL−1
Delayed righting
Response; ~1 min;
Disoriented and slow movement (mild paralysis)
Moderate reduction of vitality and fitness;
continuous mild paralysis
Crude venom
1 mg·mL−1
Delayed or no righting (>3 min);
very limited movement (strong paralysis)
Extreme reduction of vitality and fitness
(~40% with no physiological reactions);
continuous strong paralysis;
necrosis and extensive loss of hemolymph

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Heep, J.; Skaljac, M.; Grotmann, J.; Kessel, T.; Seip, M.; Schmidtberg, H.; Vilcinskas, A. Identification and Functional Characterization of a Novel Insecticidal Decapeptide from the Myrmicine Ant Manica rubida. Toxins 2019, 11, 562. https://0-doi-org.brum.beds.ac.uk/10.3390/toxins11100562

AMA Style

Heep J, Skaljac M, Grotmann J, Kessel T, Seip M, Schmidtberg H, Vilcinskas A. Identification and Functional Characterization of a Novel Insecticidal Decapeptide from the Myrmicine Ant Manica rubida. Toxins. 2019; 11(10):562. https://0-doi-org.brum.beds.ac.uk/10.3390/toxins11100562

Chicago/Turabian Style

Heep, John, Marisa Skaljac, Jens Grotmann, Tobias Kessel, Maximilian Seip, Henrike Schmidtberg, and Andreas Vilcinskas. 2019. "Identification and Functional Characterization of a Novel Insecticidal Decapeptide from the Myrmicine Ant Manica rubida" Toxins 11, no. 10: 562. https://0-doi-org.brum.beds.ac.uk/10.3390/toxins11100562

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