Abstract
Ant species have specialized venom systems developed to sting and inoculate a biological cocktail of organic compounds, including peptide and polypeptide toxins, for the purpose of predation and defense. The genus Dinoponera comprises predatory giant ants that inoculate venom capable of causing long-lasting local pain, involuntary shaking, lymphadenopathy, and cardiac arrhythmias, among other symptoms. To deepen our knowledge about venom composition with regard to protein toxins and their roles in the chemical–ecological relationship and human health, we performed a bottom-up proteomics analysis of the crude venom of the giant ant D. quadriceps, popularly known as the “false” tocandiras. For this purpose, we used two different analytical approaches: (i) gel-based proteomics approach, wherein the crude venom was resolved by denaturing sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) and all protein bands were excised for analysis; (ii) solution-based proteomics approach, wherein the crude venom protein components were directly fragmented into tryptic peptides in solution for analysis. The proteomic data that resulted from these two methodologies were compared against a previously annotated transcriptomic database of D. quadriceps, and subsequently, a homology search was performed for all identified transcript products. The gel-based proteomics approach unequivocally identified nine toxins of high molecular mass in the venom, as for example, enzymes [hyaluronidase, phospholipase A1, dipeptidyl peptidase and glucose dehydrogenase/flavin adenine dinucleotide (FAD) quinone] and diverse venom allergens (homologous of the red fire ant Selenopsis invicta) and venom-related proteins (major royal jelly-like). Moreover, the solution-based proteomics revealed and confirmed the presence of several hydrolases, oxidoreductases, proteases, Kunitz-like polypeptides, and the less abundant inhibitor cysteine knot (ICK)-like (knottin) neurotoxins and insect defensin. Our results showed that the major components of the D. quadriceps venom are toxins that are highly likely to damage cell membranes and tissue, to cause neurotoxicity, and to induce allergic reactions, thus, expanding the knowledge about D. quadriceps venom composition and its potential biological effects on prey and victims.
Highlights
Ants (Vespoidea, Formicidae) belong to the class Insecta and the order Hymenoptera, which include the families Formicidae, Apidae, and Vespidae among others [1]
The in-solution digestion of the total protein content in a homogeneous sample, like crude venom, is performed, and the resulting tryptic peptides are analyzed by liquid chromatography–mass spectrometry (LC–MS); this is a direct, associated approach [27]. Based on these facts and considering that the transcriptome of D. quadriceps venom gland predicted a predominant venom component not completely and functionally characterized yet, the aim of this work was to examine the polypeptide toxins of D. quadriceps expressed in the venom, by means of a bottom-up proteomic analysis, including in gel- and in-solution venom proteomics and comparison of toxin identifiers with products encoded by the transcripts expressed in D. quadriceps venom gland
We studied the protein content of D. quadriceps venom using two proteomic strategies: (1) in-gel digestion and (2) in-solution digestion, followed by analysis with two different mass spectrometers
Summary
Ants (Vespoidea, Formicidae) belong to the class Insecta and the order Hymenoptera, which include the families Formicidae (ants), Apidae (bees), and Vespidae (wasps) among others [1]. The family Formicidae comprises more than 13,000 species of ants, most of which have an intricate social organization, form colonies with thousands of individuals, and are often distributed in every type of ecosystems on Earth [2]. The majority of ant species have a specialized venom apparatus to sting prey and victims, inoculating a cocktail of biological and pharmacological active substances for predation and defense [3]. The structure of the venom systems of ants share similar ontogenetic and evolutive relationship with the venom systems of wasps, which are characterized by free secretory tubules, a convoluted gland, and a venom gland reservoir [4]. The venom composition of several ant species has been investigated more recently at molecular and pharmacological levels, revealing unique repertories of toxins and venom-related polypeptides that differ considerably from the toxic components of other venomous animals. To mention a few examples, the venom polypeptide contents of the giant red bull ant Myrmecia gulosa [5], the bullet ant Paraponera clavata [6] and the fire ant Solenopsis invicta [7,8]
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
