Proteomic analyses of venom from a Spider Hawk, <i>Pepsis decorata</i>

Nolasco, Matheus; Mariano, Douglas O. C.; Pimenta, Daniel C.; Biondi, Ilka; Branco, Alexsandro

doi:10.1590/1678-9199-JVATITD-2022-0090

Abstract

Background:

The composition of the venom from solitary wasps is poorly known, although these animals are considered sources of bioactive substances. Until the present moment, there is only one proteomic characterization of the venom of wasps of the family Pompilidae and this is the first proteomic characterization for the genus Pepsis.

Methods:

To elucidate the components of Pepsis decorata venom, the present work sought to identify proteins using four different experimental conditions, namely: (A) crude venom; (B) reduced and alkylated venom; (C) trypsin-digested reduced and alkylated venom, and; (D) chymotrypsin-digested reduced and alkylated venom. Furthermore, three different mass spectrometers were used (Ion Trap-Time of Flight, Quadrupole-Time of Flight, and Linear Triple Quadruple).

Results:

Proteomics analysis revealed the existence of different enzymes related to the insect’s physiology in the venom composition. Besides toxins, angiotensin-converting enzyme (ACE), hyaluronidase, and Kunitz-type inhibitors were also identified.

Conclusion:

The data showed that the venom of Pepsis decorata is mostly composed of proteins involved in the metabolism of arthropods, as occurs in parasitic wasps, although some classical toxins were recorded, and among them, for the first time, ACE was found in the venom of solitary wasps. This integrative approach expanded the range of compounds identified in protein analyses, proving to be efficient in the proteomic characterization of little-known species. It is our understanding that the current work will provide a solid base for future studies dealing with other Hymenoptera venoms.

Keywords:
Wasp; solitary wasp; venomics; toxins; proteins

Background

The order Hymenoptera is one of the four large orders that make up the phylum Arthropoda, with about 150,000 described species [11. Nastasi LF. Introduction to wasps. In: Nastasi LF, Kresslein RL, Fowler KO, Flores SRF, editors. Biodiversity & Classification of Wasps,. 1st ed. Pennsylvania: WaspID Course; 2023. p. 15-25. ]. It is currently estimated that there are 33,000 sting wasps species worldwide [22. Brock RE, Cini A, Sumner S. Ecosystem services provided by aculeate wasps. Biol Rev Camb Philos Soc. 2021 Aug;96(4):1645-75.]. The majority of this group has predatory or pollinating habits. In general, their way of life is divided between social and solitary animals [33. Piek T, Spanjer W. Chemistry and pharmacology of solitary wasp venoms. In: Piek T, editor. Venoms of the Hymenoptera. London: Academic Press; 1986. p. 161-307. ]. Solitary Hymenoptera are responsible for capturing insects or spiders to feed their larvae [44. Costa FG, Pérez-Miles F, Mignone A. Pompilid Wasp Interactions with Burrowing Tarantulas : Pepsis cupripennis versus Eupalaestrus weijenberghi and Acanthoscurria suina ( Araneae , Theraphosidae ). Stud Neotrop Fauna Environ. 2004;39(1):37-43.]; the adults feed on nectar, which they obtain from several different plant species [55. Evans HE. The Larvae of Pompilidae (Hymenoptera). Ann Entomol Soc Am. 1959;52:430-44.]. Within this group, we find the wasp Pepsis decorata (Figure 1), popular in Brazil as Cavalo-do-Cão (Demon’s Horse) or Tarantula hawk in the United States.

Figure 1.
(A) Female Pepsis decorata feeding on pollen from a Mimosoideae plant. One can notice the spots on the wings and the bluish-black coloration. (B) Female Pepsis decorata in captivity feeding on a mixture of honey, sucrose, and water.

Although these wasps are well known due to their oviposition mechanism and the pain of their sting, there is only one proteomic study of the composition of its venom in the literature. This study was made with the species Cyphononyx dorsalis and identified three proteins: arginine kinase-like protein, elastase-like protein, and a still unknown protein. The recombinant arginine kinase showed paralytic activity in spiders [66. Yamamoto T, Arimoto H, Kinumi T, Oba Y, Uemura D. Identification of proteins from venom of the paralytic spider wasp, Cyphononyx dorsalis. Insect Biochem Mol Biol. England; 2007 Mar;37(3):278-86.]. Tests with Pepsis mexicana venom showed metalloproteinase and hyaluronidase activity and also demonstrated possible specificity in paralyzing spiders since the venom caused paralysis in lepidopteran larvae [77. Huicab-Uribe MA, Verdel-Aranda K, Martínez-Hernández A, Zamudio FZ, Jiménez-Vargas JM, Lara-Reyna J. Molecular composition of the paralyzing venom of three solitary wasps (Hymenoptera: Pompilidae) collected in southeast Mexico. Toxicon. 2019 Oct;168:98-102. ].

The proteomics study relates the total or fraction of proteins in an organism that are expressed under external influences at a given time to their respective cellular functions [88. Aebersold R, Mann M. Mass spectrometry-based proteomics. Nature. 2003 Mar;422:198-207., 99. Zimmer JSD, Monroe ME, Qian W-J, Smith RD. Advances in proteomics data analysis and display using an accurate mass and time tag approach. Mass Spectrom Rev. 2006 May-Jun;25(3):450-82.]. Modern methods of proteomic analysis, such as shotgun label-free proteomics, where the digestion and analysis of the protein pool occur without prior separation, allow, in addition to the identification, the quantitative comparison of the set of proteins in independent biological samples [1010. Megger DA, Bracht T, Meyer HE, Sitek B. Label-free quantification in clinical proteomics. Biochim Biophys Acta. 2013 Aug;1834(8):1581-90.]. Different mass analyzers tend to modify the results found, for example, IT-ToF, besides performing multiple-stage mass spectrometry, presents a higher sensitivity and selectivity, possessing also a high precision and mass resolution (10,000 to 1000 m/z), thus allowing a larger amount of qualitative data to be generated in a single analysis [1111. Hyakkoku K, Hamanaka J, Tsuruma K, Shimazawa M, Hara H. Proteomic approach with LCMS-IT-TOF identified an increase of Rab33B after transient focal cerebral ischemia in mice. Exp Transl Stroke Med. 2010 Nov 23;2(1):20.]. Q-ToF can generate data in a short time (≥ 20 spectra/s), mass accuracy in the range of ≤ 5 ppm, and a resolution in the 10,000. The LTQ has a lower accuracy than the analyzers already mentioned, in the range of 100 ppm, but its resolution allows it to perform high-throughput analysis [1212. Yates JR, Ruse CI, Nakorchevsky A. Proteomics by Mass Spectrometry: Approaches, Advances, and Applications. Annu Rev Biomed Eng. 2009;11:49-79., 1313. Xie C, Zhong D, Yu K, Chen X. Recent advances in metabolite identification and quantitative bioanalysis by LC-Q-TOF MS. Bioanalysis. 2012 May;4(8):937-59.].

The use of complementary analytical platforms, depending on the reproducibility of each platform, can identify different sets of peptides in shotgun analyses, where the LTQ and Q-ToF mass analyzers showed a data overlap in the range of 50-60% [1414. Elias JE, Haas W, Faherty BK, Gygi SP. Comparative evaluation of mass spectrometry platforms used in large-scale proteomics investigations. Nat Methods. 2005 Sep;2(9):667-75.]. So, our paper aimed to make an extensive proteomic characterization of Pepsis decorata venom that, besides contributing to the knowledge regarding the protein constituents of this venom, may help the evolutionary knowledge of its toxin arsenals. The proteomic analyses were performed on four treatments: crude venom, reduced and alkylated venom, trypsin-digested venom, and chymotrypsin-digested venom. The venoms were analyzed on three different mass spectrometers: Electrospray-Ion Trap-Time of Flight (ESI-IT-TOF), Electrospray-linear triple quadrupole (ESI-LTQ), and Electrospray-quadrupole-Time of Flight (ESI-Q-TOF).

Methods

Biological material

P. decorata females (twenty specimens) were captured on the campus of the State University of Feira de Santana (UEFS), in the city of Feira de Santana, state of Bahia (12°16'00” S and 38°58'00” W Authorization SISBIO 62813), when foraging flowers or tarantulas. Catch and venom extraction was carried out according to [1515. Nolasco M, Biondi I, Pimenta DC, Branco A. Extraction and preliminary chemical characterization of the venom of the spider wasp Pepsis decorata (Hymenoptera: Pompilidae). Toxicon. 2018 Aug;150:74-6.].

Reagents

All reagents were purchased from Sigma-Aldrich (MO, USA) unless otherwise stated. Sigma-Aldrich Trypsin singles (proteomic grade) were employed in this study.

Sample preparation

Crude venom (experimental condition 1)

About 0.65 mg of P. decorata venom was solubilized in 0.1% formic acid and centrifuged at 1,000 g for 10 min. The supernatant was collected and reserved for further processing or direct proteomic analyses. Sample code: XP1.

Reduced and alkylated venom (experimental condition 2)

Sample XP1 was incubated with 8 M urea (in 100 mM Tris-HCl, pH 8.5) and Tris(2-carboxyethyl)phosphine hydrochloride (TCEP) (dissolved in water) (3 mM, final concentration) for 1h, at room temperature; then, Iodoacetamide (IAA, dissolved in water) (10 mM final concentration) was added and the sample was incubated for 1h, protected from light. Sample code: XP2.

Trypsin-digested reduced and alkylated venom (experimental condition 3)

Sample XP2 was incubated with 100 mM Tris-HCl (pH 8.5) (to dilute urea to 2M) and 10 µL trypsin (10 ng.µL^-1 in 100 mM Tris-HCl, pH 8.5) at 30°C overnight. Finally, the enzymatic reaction was stopped by adding 50% acetonitrile (ACN) / 5% trifluoroacetic acid (TFA) and the sample was dried. Sample code: XP3.

Chymotrypsin-digested reduced and alkylated venom (experimental condition 4)

Sample XP2 was incubated with 100 mM Tris-HCl (pH 8.5) (to dilute urea to 2M) and 10 µL chymotrypsin (20 ng.µL^-1 in 100 mM Tris-HCl, pH 8.5) at 30°C overnight. Finally, the enzymatic reaction was stopped by adding 50% ACN / 5% TFA and the sample was dried. Sample code: XP4.

Mass spectrometry analyses

IT-TOF

An Electrospray-Ion Trap-Time of Flight (ESI-IT-TOF) (Shimadzu Co., Japan) equipped with a binary Ultra-Fast Liquid Chromatography system (UFLC, 20A Prominence, Shimadzu) was employed. Samples were loaded in a C18 column (Discovery C18, 5 μm; 50 × 2.1 mm) in a binary solvent system: (A2) water/acetic acid (999/1, v/v) and (B2) ACN/water/acetic acid (900/99/1, v/v/v). The column was eluted at a constant flow rate of 0.2 mL.min−1 with a 0 to 40% gradient of solvent B2 over 35 min. The eluates were monitored by a Shimadzu SPD-M20A PDA detector before introduction into the mass spectrometer. The interface voltage was adjusted to 4.5 KV and the capillary voltage was 1.8 KV, at 200 °C. MS spectra were acquired under positive mode and collected in the 350-1400 m/z. MS/MS spectra were collected in the 50-1950 m/z range. Instrument control, data acquisition, and data processing were performed with LabSolutions (LCMS solution 3.60.361 version, Shimadzu).

Q-TOF

An Electrospray-quadrupole-Time of Flight (ESI-Q-TOF) (Micromass, UK) equipped with a binary Ultra-Performance Liquid Chromatography system (UPLC, Acquity, Waters, MA, USA) was employed. Samples (5 μl) were separated on a C18 column, using the following mobile phase: (A) 0.1% Formic acid (FA) (1:999, v/v) and (B) 0.1% FA in 90% Acetonitrile (ACN) (1:900:99, v/v/v). The gradient condition was: 2% B in 0-5 min; 2-40% B in 5-60 min, under a flow rate of 10 µL per minute. The mass spectrometry (MS) was equipped with a locked ESI probe and operated in positive mode (ESI+). The electrospray capillary voltage was 3.1 kV, with a cone voltage of 113 V. The cone and desolvation gas flows were 185 and 600 l h−1, respectively. The desolvation temperature was 150°C. MS scans were acquired at 350-1600 mass charge rate (m/z) and MS/MS scans at 50-2000 m/z. The collision energy of the MS/MS analysis was 10-10.6 eV. The software selected automatically ions with a threshold intensity of ≥ 10 for fragmentation.

LTQ

The tryptic peptides were extracted by zip tip C-18 (Merck Millipore, Germany), dried, and then dissolved into 0.1% acetic acid for LC-MS/MS analysis, performed in LTQ-XL mass spectrometer (Thermo Fisher Scientific, USA). Sample aliquots were separated by a C-18 column, on a NanoLC-1D system (Eksigent). The elution was performed by a linear gradient of B over A, from 0 to 30% in 45 min, 30-80% in 10 min, and 80% of B in 5 min, under a flow rate of 600 mL per minute. The solvents were: A - water containing 0.1% acetic acid and B - acetonitrile containing 0.1% acetic acid.

Data Processing

Software

Peaks Studio V7.0 (BSI, Canada) was used for data processing. LCD Shimadzu raw data were converted (LCMS Protein Postrun, Shimadzu) to MGF files prior to Peaks analyses. Micromass and Thermo RAW files were directly loaded into Peaks.

Proteomic Identification

An Arthropoda (taxid:6656) protein database was built by retrieving all UniProt entries associated with this taxon. The raw processed data (according to 3.2.1) were analyzed against the custom database by Peaks default algorithm as well as Peaks PTM and Spider algorithms. The Spider proteomic identification was chosen for data interpretation. Enzyme specificity (trypsin, chymotrypsin, or none), fixed (none or carbamidomethyl cysteine) and variable (none or oxidized methionine) amino acid modifications, maximum missed cleavages (2), maximum variable PTMs per peptide (3) and non-specific cleavage (both) parameters were set according to each experimental condition.

Results

IT-TOF analysis

To study the proteins present in P. decorata venom, we performed a classical proteomic approach based on chymotrypsin or trypsin digestion. Tables 1-3 combine the top 5 proteins identified, considering the different mass spectrometers and experimental conditions. Regardless of the instrument, most of the identified proteins were classified as housekeeping proteins. Besides, we identified several uncharacterized proteins. Figures 2-4 present the compilation of all identified proteins, using a common color code for better data visualization. The pie charts were conceived as follows: in the three figures, the left pie is divided between uncharacterized proteins (gray) and annotated proteins (green), according to the UniProt. The annotated protein slice was then subdivided according to the following annotated functions (also based on UniProt): housekeeping proteins (light blue), hydrolases (red), oxidoreductases (yellow), ribonucleoproteins (blue), transferases (orange) and toxins (pink).

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Table 1.
Summarized^§ proteomic identification of venom components of Pepsis decorata venom, as identified by ESI-IT-TOF mass spectrometry, under different experimental conditions.

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Table 2.
Summarized^§ proteomic identification of venom components of Pepsis decorata venom, as identified by ESI-Q-TOF mass spectrometry, under different experimental conditions.

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Table 3.
Summarized§ proteomic identification of venom components of Pepsis decorata venom, as identified by LTQ mass spectrometry, under different experimental conditions.

The overall graphic interpretation of the IT-TOF mass spectrometric analyses of the P. decorata venom (XP1-4) is presented in Figure 2. One can observe that roughly ⅔ of the identified proteins are UniProt annotated proteins. Within this dataset, 16% are hydrolases. We also found proteins with other functions such as regulation of alternative splicing, bifunctional arginine demethylase, and lysyl-hydroxylase, proteins responsible for regulating post-translational modifications, and protein-tyrosine sulfotransferase. We also found several proteins responsible for glucose metabolism like Glyceraldehyde-3-phosphate dehydrogenase, Glucose dehydrogenase, Pyruvate kinase, and Alanine aminotransferase.

Figure 2.
Molecular function keyword¹ percentage distribution of the proteomic² identified proteins present in the Pepsis decorata crude venom, as analyzed by the IT-TOF mass spectrometer. ¹ According to the Gene Ontology (GO) project. ² The proteomic identification was performed on the reduced, alkylated, and trypsin-digested crude venom. Color code: (Gray) uncharacterized proteins; (Green) Proteins with GO annotation. (Blue) Ribonucleproteins; (Red) Hydrolases; (Orange) tranferase; (Yellow) Oxidoreductases; (Light blue) others.

Q-TOF analysis

Table 2 lists all the de novo Q-TOF sequenced peptides for XP1 and 2, based on the same rationale already presented. Following the proposed scheme, trypsin and chymotrypsin-based proteomic analyses (XP3 and 4) were performed. The identified proteins are listed in Table 2, alongside the proteomic identification for XP1 and 2. One can observe that the proteomic interpretation of XP1 and 2 data yielded high-scored identified proteins; however, only cytoskeletal and housekeeping molecules (tubulin, mainly). Q-TOF XP3, on the other hand, led to the identification of two very interesting - from a Toxinology perspective - proteins: a Kunitz inhibitor and an angiotensin-converting enzyme (ACE).

LTQ analysis

As a final attempt to enhance the biological meaning of the data derived from the available samples, we submitted XP1-4 to an LTQ-ETD mass spectrometer coupled to a UPLC. Despite the less accurate mass measurement - in comparison to the TOF MS’s already utilized - the ETD fragmentation would provide much richer MS² spectra that would be better explored by Peaks Studio. In LTQ analysis, following the workflow already employed for the previous analyses, XP1-4 data were submitted to proteomic identification. The top-scored identified proteins are listed in Table 3. XP1 yielded very high-scored identified proteins; however, a Na⁺/K⁺ channel ATPase, tubulin (α and β), and two metabolic enzymes (Pyruvate kinase and Glyceraldehyde-3-phosphate dehydrogenase). XP2 - the reduced and alkylated sample - led to the identification of the same Na⁺/K⁺ channel ATPase, two histones (H2 and H4), an ATP carrier protein, and an ATP synthase.

Once again, only housekeeping molecules. The ‘classical’ trypsin-based proteomic analyses (XP3) led to identifying the Na⁺/K⁺ channel ATPase, tubulin, ADP/ATP translocase, and prohibitin. This protein acts as a mediator of transcriptional repression by nuclear hormone receptors via recruitment of histone deacetylases. XP4, the chymotrypsin-digested sample, was responsible for the identification of Putative pseudouridine synthase, Putative ribosomal RNA methyltransferase NOP2, La-related protein (a protein possibly related to the regulation of translation, according to the UniProt annotation), FERM and PDZ domain-containing protein (present in the tight junctions), and one Alanine aminotransferase. The complete list of identified proteins is provided as supplemental material.

The overall graphic interpretation of the LTQ mass spectrometric analyses of the P. decorata venom (XP1-4) is presented in Figure 3. One can observe that the LTQ rate of identification of annotated proteins is around 50%. Among the annotated proteins (green slice), the larger pizza is color-coded just like the other MS analyses, i.e., red: hydrolases; yellow: oxidoreductases; blue: ribonucleoproteins, pink: toxins and light blues: others. The toxin identified in this experiment is an antimicrobial peptide. The combined XP1-4 proteomic analyses led to the identification of 584 proteins when using the LTQ. The complete list is supplied as supplemental material.

Figure 3.
Molecular function keyword¹ percentage distribution of the proteomic² identified proteins present in the Pepsis decorata crude venom, as analyzed by the LTQ mass spectrometer. ¹ According to the Gene Ontology (GO) project. ² The proteomic identification was performed on the reduced, alkylated, and trypsin-digested crude venom. Color code: Gray: uncharacterized proteins; Green: Proteins with GO annotation. Blue: Ribonucleoproteins; Red: Hydrolases; Orange: transferase; Yellow: Oxidoreductases; Light blue: others; Pink: Venom-related molecules (antimicrobial).

Tubulin (α and β chains) was the most identified protein by the Q-TOF and LTQ, whereas other structural proteins, such as Papilin, Cell division cycle protein, and COPII coat assembly protein were mainly identified by the IT-TOF. Moreover, many nuclear proteins (ribonucleoproteins and histones) were also identified in the venom proteome.

All results were submitted to the jPOST repository, under the PXD040919 for ProteomeXchange and JPST002090 for jPOST accession numbers [1616. Okuda S, Watanabe Y, Moriya Y, Kawano S, Yamamoto T, Matsumoto M, Takami T, Kobayashi D, Araki N, Yoshizawa AC, Tabata T, Sugiyama N, Goto S, Ishihama Y. jPOSTrepo: an international standard data repository for proteomes. Nucleic Acids Res. 2017 Jan 4;45(D1):D1107-111.].

Discussion

IT-TOF analysis

Venom analysis in IT-ToF mass spectrometer reached 16% of identified proteins as hydrolases. These enzymes are common in parasitic wasp venom, being in some cases the most abundant protein group [1717. Laurino S, Grossi G, Pucci P, Flagiello A, Bufo SA, Bianco G, et al. Identification of major Toxoneuron nigriceps venom proteins using an integrated transcriptomic/proteomic approach. Insect Biochem Mol Biol. 2016 Sep;76:49-61.-1919. Teng ZW, Xiong SJ, Xu G, Gan SY, Chen X, Stanley D, Yan ZC, Ye GY, Fang Q. Protein Discovery: Combined Transcriptomic and Proteomic Analyses of Venom from the Endoparasitoid Cotesia chilonis (Hymenoptera: Braconidae). Toxins (Basel). 2017 Apr;9(4):135.]. Since hydrolases are diverse, e.g. proteases, hyaluronidases, phosphatases, nucleotidases, and phospholipases, they have a range of functions such as paralysis, facilitation of poison spreading, pain induction, or antimicrobial activity [2020. Nakajima T. Pharmacological Biochemistry of Vespid Venoms. In: Piek, T, editor. Venoms of the Hymenoptera. London: Academic Press ; 1986. p. 309-27.-2222. Sarhan M, El-Bitar AMH, Mohammadein A, Elshehaby M, Hotta H. Virucidal activity of oriental hornet Vespa orientalis venom against hepatitis C virus. J Venom Anim Toxins incl Trop Dis. 2021 Nov 19;27:e2021-0039. doi: 10.1590/1678-9199-JVATITD-2021-0039. eCollection 2021.
https://doi.org/10.1590/1678-9199-JVATIT... ].

This approach led us to the identification of the toxin hyaluronidase. This enzyme is an essential constituent of social and solitary wasp venom, acting on hyaluronic acid hydrolysis (an important biopolymer constituent of the extracellular matrix) and facilitating the diffusion of molecules in the sting site to the circulation, it is an enzyme known as "spreading factor", as it degrades hyaluronic acid allowing the rapid spread of venom compounds through the interstitial space [2323. de Lima PR, Brochetto-Braga M. Hymenoptera venom review focusing on Apis mellifera. J Venom Anim Toxins incl Trop Dis. 2003;9(2). https://doi.org/10.1590/S1678-91992003000200002.
https://doi.org/10.1590/S1678-9199200300... , 2424. Girish KS, Kemparaju K. The magic glue hyaluronan and its eraser hyaluronidase: a biological overview. Life Sci. 2007 May 1;80(21):1921-43.]. In addition, hyaluronic acid fragments are one of the major allergens from wasp venom and are associated with other systemic responses in accidents related to humans [2424. Girish KS, Kemparaju K. The magic glue hyaluronan and its eraser hyaluronidase: a biological overview. Life Sci. 2007 May 1;80(21):1921-43.-2626. El-Safory NS, Fazary AE, Lee CK. Hyaluronidases, a group of glycosidases: Current and future perspectives. Carbohydr Polym. 2010 Jun 11;81(2):165-81.]. In bee venom, this enzyme has oligosaccharides linked to asparagine [2727. Kubelka V, Altmann F, März L. The asparagine-linked carbohydrate of honeybee venom hyaluronidase. Glycoconj J. 1995 Feb;12(1):77-83.]. Hyaluronidase is an allergenic factor in wasp venoms and is capable of inducing serious anaphylactic reactions in humans, causing death [2828. Justo Jacomini DL, Campos Pereira FD, dos Santos Pinto JR, dos Santos LD, da Silva Neto AJ, Giratto DT, Palma MS, Zollner RL, Braga MRB. Hyaluronidase from the venom of the social wasp Polybia paulista (Hymenoptera, Vespidae): Cloning, structural modeling, purification, and immunological analysis. Toxicon. 2013 Mar 15;64:70-80.-3030. Lu G, Kochoumian L, King TP. Sequence identity and antigenic cross-reactivity of white face hornet venom allergen, also a hyaluronidase, with other proteins. J Biol Chem. 1995 Mar 3;270(9):4457-65.].

The other proteins found are part of the metabolism of insects, two of which can play an important role in the action of the venom. The identified protein Papilin, which regulates the ontogenic development of insects, and can also modulate metalloproteases [3131. Kramerova IA, Kramerov AA, Fessler JH. Alternative splicing of papilin and the diversity of Drosophila extracellular matrix during embryonic morphogenesis. Dev Dyn. 2003 Apr;226(4):634-42.], this protein has already been found expressed in the arachnids' venom gland [3232. Salabi F, Jafari H. Differential venom gland gene expression analysis of juvenile and adult scorpions Androctonus crassicauda. BMC Genomics. 2022 Sep 8;23(1):636., 3333. Baza-Moreno JD, Vega-Alvarado L, Ibarra-Núñez G, Guillén-Navarro K, García-Fajardo LV, Jiménez-Jacinto V, Diego-Garcia E. Transcriptome analysis of the spider Phonotimpus pennimani reveals novel toxin transcripts. J Venom Anim Toxins incl Trop Dis. 2023 Jan 23;29:e20220031. https://doi.org/10.1590/1678-9199-JVATITD-2022-0031.
https://doi.org/10.1590/1678-9199-JVATIT... ] and may play a role in the innate immune of insects [3434. Pantha P, Chalivendra S, Oh D-H, Elderd BD, Dassanayake M. A Tale of Two Transcriptomic Responses in Agricultural Pests via Host Defenses and Viral Replication. Int J Mol Sci. 2021 Mar 30;22(7):3568., 3535. Campbell AG, Fessler LI, Salo T, Fessler JH. Papilin: a Drosophila proteoglycan-like sulfated glycoprotein from basement membranes. J Biol Chem. 1987 Dec 25;262(36):17605-12.]. and Sterile Alpha and TIR Motif-Containing Protein 1, which is an important protein for the immune response against bacterial infections [3636. Belinda LWC, Wei WX, Hanh BTH, Lei LX, Bow H, Ling DJ. SARM: a novel Toll-like receptor adaptor, is functionally conserved from arthropod to human. Mol Immunol. 2008 Mar;45(6):1732-42., 3737. Trung NB, Nguyen T-P, Hsueh H-Y, Loh J-Y, Wangkahart E, Wong ASF, Lee PT. Sterile alpha and TIR motif-containing protein 1 is a negative regulator in the anti-bacterial immune responses in nile tilapia (Oreochromis niloticus). Front Immunol. 2022 Jul 19;13:940877.]. This protein may be involved in the venom's mechanism of action, helping the host spider's immune system to modulate defense against possible bacterial infections.

Q-TOF analysis

In Q-Tof analysis, from a Toxinology perspective, it is noteworthy to mention the identification of one Hyaluronidase, one Kunitz peptidase inhibitor (annotated as a toxin), and one ACE (Angiotensin-converting enzyme). Serine peptidase inhibitors are classical toxins found in the most diverse groups of venomous animals [3838. Mourão CBF, Schwartz EF. Protease inhibitors from marine venomous animals and their counterparts in terrestrial venomous animals. Mar Drugs. 2013 Jun;11(6):2069-112.-4242. Tsujimoto H, Kotsyfakis M, Francischetti IMB, Eum JH, Strand MR, Champagne DE. Simukunin from the Salivary Glands of the Black Fly Simulium vittatum Inhibits Enzymes That Regulate Clotting and Inflammatory Responses. PLoS One. 2012;7(2):e29964.]. Kunitz inhibitors are part of serine peptidase inhibitors and present about 60 amino acid residues and three disulfide bonds in their structure; also, they are characterized by the inhibitory activity of trypsin and/or chymotrypsin The function that the Kunitz inhibitor has in the venom depends on the animal group in which it is found: it can act as trypsin and/or chymotrypsin blockers in the venom or blocking potassium channels [4343. He YY, Liu SB, Lee WH, Qian JQ, Zhang Y. Isolation, expression and characterization of a novel dual serine protease inhibitor, OH-TCI, from king cobra venom. Peptides. 2008 Oct;29(10):1692-9., 4444. Shafqat J, Zaidi ZH, Jörnvall H. Purification and characterization of a chymotrypsin Kunitz inhibitor type of polypeptide from the venom of cobra (Naja naja naja). FEBS Lett. 1990 Nov 26;275(1-2):6-8.].

Kunitz inhibitors have been identified in some social and solitary wasps. In Vespa bicolor, a bicolin, which belongs to BPTI/Kunitz inhibitor family, was isolated and has thrombin-inhibitory activity and anticoagulation function [4545. Yang X, Wang Y, Lu Z, Zhai L, Jiang J, Liu J, Yu H. A novel serine protease inhibitor from the venom of Vespa bicolor Fabricius. Comp Biochem Physiol Part B Biochem Mol Biol. 2009 May;153(1):116-20.]. In the parasitic wasp Pimpla hypochondriaca, several molecules with homology to the Kunitz inhibitor have been identified, but their function has not been tested [4646. Parkinson NM, Conyers C, Keen J, MacNicoll A, Smith I, Audsley N, Weaver R. Towards a comprehensive view of the primary structure of venom proteins from the parasitoid wasp Pimpla hypochondriaca. Insect Biochem Mol Biol. 2004 Jun;34(6):565-71.-4848. Parkinson N, Richards EH, Conyers C, Smith I, Edwards JP. Analysis of venom constituents from the parasitoid wasp Pimpla hypochondriaca and cloning of a cDNA encoding a venom protein. Insect Biochem Mol Biol. 2002 Jul;32(7):729-35.]. In solitary wasps, possible peptides were also identified belonging to the Kunitz inhibitor family, possibly functioning as an ion blocker helping in the paralysis of host spiders [4949. Baek JH, Lee SH. Differential gene expression profiles in the venom gland/sac of Eumenes pomiformis (Hymenoptera: Eumenidae). Toxicon. 2010 Jun 1;55(6):1147-56., 5050. Hisada M, Satake H, Masuda K, Aoyama M, Murata K, Shinada T, Iwashita T, Ohfune Y, Nakajima T. Molecular components and toxicity of the venom of the solitary wasp, Anoplius samariensis. Biochem Biophys Res Commun. 2005 May 20;330(4):1048-54. ].

Angiotensin-converting enzymes have been described in the venom of two parasitic wasps: Chelonus inanitus and Nasonia vitripennis. In Pimpla hypochondriaca, a strong ACE activity was identified and the enzyme was evidenced by western blot [5151. Dani MP, Richards EH, Isaac RE, Edwards JP. Antibacterial and proteolytic activity in venom from the endoparasitic wasp Pimpla hypochondriaca (Hymenoptera: Ichneumonidae). J Insect Physiol. 2003 Oct;49(10):945-54.-5353. de Graaf DC, Aerts M, Brunain M, Desjardins CA, Jacobs FJ, Werren JH, Devreese B. Insights into the venom composition of the ectoparasitoid wasp Nasonia vitripennis from bioinformatic and proteomic studies. Insect Mol Biol. 2010 Feb;19(Suppl 1):11-26.]. ACE is responsible for catalyzing the two C-terminal amino acids of Angiotensin I to transform it into Angiotensin II [5454. Ondetti MA, Cushman DW. Enzymes of the renin-angiotensin system and their inhibitors. Annu Rev Biochem. 1982;51:283-308. ]. This enzyme has already been described in Drosophila and Anopheles, for example, and its function - rather than controlling ‘blood’ pressure - would be the extracellular metabolism of peptide hormones, and a role in reproduction [5555. Burnham S, Smith JA, Lee AJ, Isaac RE, Shirras AD. The angiotensin-converting enzyme (ACE) gene family of Anopheles gambiae. BMC Genomics. 2005 Dec 5;6:172.-5858. Taylor CA, Coates D, Shirras AD. The Acer gene of Drosophila codes for an angiotensin-converting enzyme homologue. Gene. 1996 Nov 28;181(1-2):191-7. ]. ACE may also be related to the metabolic inactivation of neuropeptides in the central nervous system of insects, and in processing precursor peptides in the wasp venom reservoir [5151. Dani MP, Richards EH, Isaac RE, Edwards JP. Antibacterial and proteolytic activity in venom from the endoparasitic wasp Pimpla hypochondriaca (Hymenoptera: Ichneumonidae). J Insect Physiol. 2003 Oct;49(10):945-54., 5959. Isaac RE, Bland ND, Shirras AD. Neuropeptidases and the metabolic inactivation of insect neuropeptides. Gen Comp Endocrinol. 2009 May 15;162(1):8-17.]. XP4 Q-TOF analyses (Table 2) successfully led to the identification of hyaluronidase, which had been already identified in the XP3 IT-TOF scheme, corroborating the presence of this enzyme in the venom and its toxin-spreading associated function [2525. Lee SH, Baek JH, Yoon KA. Differential Properties of Venom Peptides and Proteins in Solitary vs. Social Hunting Wasps. Toxins (Basel). 2016 Jan;8(2):32.].

The 7DB Family Member is found in the tick saliva and may be involved in anti-hemostatic, anti-inflammatory, and immunomodulatory activities in the Ornithodoros parkeri, O. coriaceus, and O. savignyi species [6060. Díaz-Martín V, Manzano-Román R, Oleaga A, Pérez-Sánchez R. New salivary anti-haemostatics containing protective epitopes from Ornithodoros moubata ticks: Assessment of their individual and combined vaccine efficacy. Vet Parasitol. 2015 Sep 15;212(3-4):336-49.-6363. Francischetti IMB, Mans BJ, Meng Z, Gudderra N, Veenstra TD, Pham VM, Ribeiro JMC. An insight into the sialome of the soft tick, Ornithodorus parkeri. Insect Biochem Mol Biol. 2008 Jan;38(1):1-21. ]. This protein does not yet have a well-characterized function and may play a role in the action of the wasp venom on the host spider The remaining top-scored proteins for this XP are housekeeping or uncharacterized.

The overall graphic interpretation of the Q-TOF mass spectrometric analyses of the P. decorata venom (XP1-4) is presented in Figure 4. One can observe that, differently from the IT-TOF analyses, only ~15% of the identified proteins (green slice) are annotated at the UniProt, the vast majority of the identified proteins are ‘uncharacterized’ proteins.

Figure 4.
Molecular function keyword¹ percentage distribution of the proteomic² identified proteins present in the Pepsis decorata crude venom, as analyzed by the Q-TOF mass spectrometer. ¹ According to the Gene Ontology (GO) project. ² The proteomic identification was performed on the reduced, alkylated, and trypsin-digested crude venom. Color code: (Gray) uncharacterized proteins; (Green) Proteins with GO annotation. (Red) Hydrolases; (Yellow) Oxidoreductases; (Light blue) others; (Pink) Venom-related molecules (toxins and protease inhibitors).

Among the annotated proteins (expanded pizza slice), and employing the same color code, one can observe that hydrolases and oxidoreductases were also identified. Interestingly, no ribonucleoproteins - which were abundant for the IT-TOF analyses - were identified. On the other hand, the pink slices call attention to the Kunitz inhibitor that is tagged either as a serine peptidase inhibitor or as a toxin. According to the UniProt annotation, this molecule “may exert inhibitory effects on serine proteases and on potassium and/or calcium channels and then participate in the long-term non-lethal paralysis on the prey”; therefore, the two keywords are associated with this molecule for both effects do lead to an imbalance in the physiology of the attacked organism, i.e., a toxin.

The augmented grey slice reflects an increase in the absolute number of identified proteins (51 for the IT-TOF vs 105 for the Q-TOF) and not a decrease in the identification of the annotated proteins. This fact is likely to be associated with the more sensitive chromatographic conditions (UPLC vs narrow-bore HPLC) and with the average longer fragmented peptides. Moreover, we have expanded the proteomics search to the Arthropoda phylum (~4M UniProt entries) and not limited it to the Insecta order (~3M) so that the Spider algorithm used by Peaks Studio would increase the number of identified proteins. The drawback of this approach is the ‘identification’ of several uncharacterized proteins that are basically automated translations of high throughput genetic sequencing.

LTQ analysis

In LTQ analysis only housekeeping proteins are identified, but Histone H4 may play a role in host envenomation. The main role attributed to histones is that of transcription regulation, DNA repair, DNA replication, and chromosomal stability, but antimicrobial activities have also been reported, such as in shrimp Litopenaeus vannamei, where the mixture of histones HSB and H4 showed activities against Gram-Positive bacteria [6464. Patat SA, Carnegie RB, Kingsbury C, Gross PS, Chapman R, Schey KL. Antimicrobial activity of histones from hemocytes of the Pacific white shrimp. Eur J Biochem. 2004 Dec;271(23-24):4825-33.]. Histone H4 is also an important factor for parasitoid wasps, often endosymbiosis with bracovirus, being able to control the host's immune system [6565. Espagne E, Dupuy C, Huguet E, Cattolico L, Provost B, Martins N, Poirié M, Periquet G, Drezen JM. Genome sequence of a polydnavirus: insights into symbiotic virus evolution. Science. 2004 Oct 8;306(5694):286-9.-7070. Zuki AA, Mohammed MA, Badrul BM, Yaakop S. Determination of host adaptation for wild highland population of Microgastrinae (Hymenoptera: Braconidae) using viral Histone H4. J Asia Pac Entomol. 2016;19:811-9.]. As it can also modify the chromosomal structure and the control of gene expression, it implies the epigenetic control of the host [6666. Gad W, Kim Y. A viral histone H4 encoded by Cotesia plutellae bracovirus inhibits haemocyte-spreading behaviour of the diamondback moth, Plutella xylostella. J Gen Virol. England; 2008 Apr;89(Pt 4):931-8., 6767. Gad W, Kim Y. N-terminal tail of a viral histone H4 encoded in Cotesia plutellae bracovirus is essential to suppress gene expression of host histone H4. Insect Mol Biol. 2009 Feb;18(1):111-8.].

Constituents of solitary wasp venom are different from those found in other groups of venomous animals. They can cause paralysis, and manipulate the metabolism, development, and behavior of their hosts. Many of these proteins have homology with common metabolic molecules in insects. In Nasonia vitripennis wasp, a joint study of transcriptomics and proteomics, revealed the functional groups present in its venom, which are: immune-related proteins, proteases and peptidases, protease inhibitors, DNA metabolism, glutathione metabolism, esterases, carbohydrate metabolism and recognition and binding proteins [5353. de Graaf DC, Aerts M, Brunain M, Desjardins CA, Jacobs FJ, Werren JH, Devreese B. Insights into the venom composition of the ectoparasitoid wasp Nasonia vitripennis from bioinformatic and proteomic studies. Insect Mol Biol. 2010 Feb;19(Suppl 1):11-26., 7171. Mrinalini, Werren JH. Parasitoid Wasps and Their Venoms BT - Evolution of Venomous Animals and Their Toxins. In: Gopalakrishnakone P, Malhotra A, editors. Dordrecht: Springer Netherlands; 2015. p. 1-26., 7272. Asgari S, Rivers DB. Venom proteins from endoparasitoid wasps and their role in host-parasite interactions. Annu Rev Entomol. 2011;56:313-35.]. The occurrence of proteins with higher molecular mass that are structurally similar to enzymes of insect metabolism also reveals the similarity between Pepsis decorata venom and parasitic wasps venom [5252. Vincent B, Kaeslin M, Roth T, Heller M, Poulain J, Cousserans F, Schaller J, Poirié M, Lanzerein B, Drezen JM, Moreau SJM. The venom composition of the parasitic wasp Chelonus inanitus resolved by combined expressed sequence tags analysis and proteomic approach. BMC Genomics. 2010;11:693., 7171. Mrinalini, Werren JH. Parasitoid Wasps and Their Venoms BT - Evolution of Venomous Animals and Their Toxins. In: Gopalakrishnakone P, Malhotra A, editors. Dordrecht: Springer Netherlands; 2015. p. 1-26.-7575. Scieuzo C, Salvia R, Franco A, Pezzi M, Cozzolino F, Chicca M, Scapoli C, Vogel H, Monti M, Ferracini C, Pucci P, Alma A, Falabella P. An integrated transcriptomic and proteomic approach to identify the main Torymus sinensis venom components. Sci Rep. 2021 Mar 3;11(1):5032.].

Conclusion

Applying this methodology, we identified more than 40 different proteins present in this wasp venom. Our work was the first to identify ACE in the venom of solitary wasps. Before, this enzyme had only been described in parasitic wasps. The effects of ACE and Kunitz inhibitors on Pepsis venom still need to be analyzed in vitro. Most of the proteins found are correlated with enzymes that act on normal insect metabolism and are usually found in the venom of parasitic wasps, showing the evolutionary proximity between the groups. Since studies with the venom of solitary wasps of the family Pompilidae identify peptides, peptidomics analysis is necessary to report on the importance of proteins and peptides in the paralysis process and host homeostasis.

Our results may signal the evolutionary link between these two groups, since biologically, this distinction between parasitic and solitary wasps is artificial. The comparison of the results herein presented shows that the overall interpreted data do not vary much depending on the instrumental setup, i.e., roughly were the same biological classes of proteins identified. On the other hand, individual results do vary and little superimposition among identified proteins occurs. Individually, each result does not invalidate the other; rather, they complement each other.

Abbreviations

ACE: Angiotensin-Converting Enzyme; ATP: Adenosine triphosphate; ADP: Adenosine diphosphate; COPII: Coat Protein Complex II; DNA: Deoxyribonucleic Acid; ESI: Electrospray ionization; FERM: Four-point-one, ezrin, radixin, moesin domain; PDZ: Postsynaptic density-95/discs large/zona occludens-1 domain; IT-ToF: Ion Trap-Time of Flight; Q-ToF: Quadrupole-Time of Flight; KV: Kilovolts; LTQ: Linear Triple Quadrupole; M: Molar; mM: millimolar; m/z: Charge mass ratio; min: Minute; mm: Millimeter; MS: Mass spectrometer; ppm: Particle per million; PTM: Post-translational modification; RNA: Ribonucleic acid; NOP2: Nucleolar protein 2; TCEP: Tris(2-carboxyethyl)phosphine hydrochloride; TFA: Trifluoroacetic acid; TIR: Toll-interleukin-1 receptor; TRIS-HCl: 2-amino-2-(hydroxymethyl)propane-1,3-diol hydrochloride; UPLC: Ultra Perfomance Liquid Chromatography; HPLC: High Perfomance Liquid Chromatography; μm: micrometer.

Acknowledgments

This work was supported by CNPq (406385/2018-1, DCP), FAPESP, FAPESB, CAPES, FINEP (01.09.0278.04 and 01.12.0450.03), and UEFS ( FINAPESQ 058/2021). AB is a CNPq fellow researcher (308469/2022-4-PQ2). DCP is a CNPq fellow researcher (303792/2016-7). CETICS: supported by FAPESP 2013/07467-1, Dr. Eduardo Santos, Laboratório de Aculeata, IBILCE-UNESP, for the identification of the specimens collected and thanks to Elen Azevedo da Costa, for reviewing the manuscript.

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58. Taylor CA, Coates D, Shirras AD. The Acer gene of Drosophila codes for an angiotensin-converting enzyme homologue. Gene. 1996 Nov 28;181(1-2):191-7.
59. Isaac RE, Bland ND, Shirras AD. Neuropeptidases and the metabolic inactivation of insect neuropeptides. Gen Comp Endocrinol. 2009 May 15;162(1):8-17.
60. Díaz-Martín V, Manzano-Román R, Oleaga A, Pérez-Sánchez R. New salivary anti-haemostatics containing protective epitopes from Ornithodoros moubata ticks: Assessment of their individual and combined vaccine efficacy. Vet Parasitol. 2015 Sep 15;212(3-4):336-49.
61. Mans BJ, Andersen JF, Francischetti IMB, Valenzuela JG, Schwan TG, Pham VM, et al. Comparative sialomics between hard and soft ticks: Implications for the evolution of blood-feeding behavior. Insect Biochem Mol Biol. 2008 Jan;38(1):42-58.
62. Francischetti IMB, Meng Z, Mans BJ, Gudderra N, Hall M, Veenstra TD, Pham VM, Kotsyfakis M, Ribeiro JMC. An insight into the salivary transcriptome and proteome of the soft tick and vector of epizootic bovine abortion, Ornithodoros coriaceus J Proteomics. 2008 Dec 2;71(5):493-512.
63. Francischetti IMB, Mans BJ, Meng Z, Gudderra N, Veenstra TD, Pham VM, Ribeiro JMC. An insight into the sialome of the soft tick, Ornithodorus parkeri Insect Biochem Mol Biol. 2008 Jan;38(1):1-21.
64. Patat SA, Carnegie RB, Kingsbury C, Gross PS, Chapman R, Schey KL. Antimicrobial activity of histones from hemocytes of the Pacific white shrimp. Eur J Biochem. 2004 Dec;271(23-24):4825-33.
65. Espagne E, Dupuy C, Huguet E, Cattolico L, Provost B, Martins N, Poirié M, Periquet G, Drezen JM. Genome sequence of a polydnavirus: insights into symbiotic virus evolution. Science. 2004 Oct 8;306(5694):286-9.
66. Gad W, Kim Y. A viral histone H4 encoded by Cotesia plutellae bracovirus inhibits haemocyte-spreading behaviour of the diamondback moth, Plutella xylostella J Gen Virol. England; 2008 Apr;89(Pt 4):931-8.
67. Gad W, Kim Y. N-terminal tail of a viral histone H4 encoded in Cotesia plutellae bracovirus is essential to suppress gene expression of host histone H4. Insect Mol Biol. 2009 Feb;18(1):111-8.
68. Ibrahim AMA, Choi JY, Je YH, Kim Y. Structure and Expression Profiles of Two Putative Cotesia plutellae Bracovirus Genes (CpBV-H4 and CpBV-E94a) in Parasitized Plutella xylostella J Asia Pac Entomol. 2005 Dec;8(4):359-66.
69. Kim Y, Hepat R. Baculoviral p94 homologs encoded in Cotesia plutellae bracovirus suppress both immunity and development of the diamondback moth, Plutellae xylostella Insect Sci. 2016 Apr;23(2):235-44.
70. Zuki AA, Mohammed MA, Badrul BM, Yaakop S. Determination of host adaptation for wild highland population of Microgastrinae (Hymenoptera: Braconidae) using viral Histone H4. J Asia Pac Entomol. 2016;19:811-9.
71. Mrinalini, Werren JH. Parasitoid Wasps and Their Venoms BT - Evolution of Venomous Animals and Their Toxins. In: Gopalakrishnakone P, Malhotra A, editors. Dordrecht: Springer Netherlands; 2015. p. 1-26.
72. Asgari S, Rivers DB. Venom proteins from endoparasitoid wasps and their role in host-parasite interactions. Annu Rev Entomol. 2011;56:313-35.
73. Zhu JY, Fang Q, Wang L, Hu C, Ye GY. Proteomic analysis of the venom from the endoparasitoid wasp Pteromalus puparum (Hymenoptera: Pteromalidae). Arch Insect Biochem Physiol. 2010 Jul 20;75(1):28-44.
74. Liu NY, Wang JQ, Zhang ZB, Huang JM, Zhu JY. Unraveling the venom components of an encyrtid endoparasitoid wasp Diversinervus elegans Toxicon. 2017 Sep 15;136:15-26.
75. Scieuzo C, Salvia R, Franco A, Pezzi M, Cozzolino F, Chicca M, Scapoli C, Vogel H, Monti M, Ferracini C, Pucci P, Alma A, Falabella P. An integrated transcriptomic and proteomic approach to identify the main Torymus sinensis venom components. Sci Rep. 2021 Mar 3;11(1):5032.

Availability of data and materials

The datasets generated during and/or analyzed during the current study are available from the corresponding author upon reasonable request.
Funding

This work was supported by Coordenação de Aperfeiçoamento de Pessoal de Nível Superior - Brasil (CAPES; Finance Code 001), Fundação de Amparo à Pesquisa do Estado da Bahia (FAPESB; grant APP0029/2016; DTE17/2015) and the Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq) (301974/2019-5). AB is a CNPq fellow researcher (grant 307996/2018-2) and DCP is a fellow researcher (grant 406385/2018-1 ). This work was supported also by Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP), CAPES, and Financiadora de Estudos e Projetos (FINEP) (01.09.0278.00). DCP is a CNPq fellow researcher (303792/2016-7). CETICS: supported by FAPESP 2013/07467-1.
Authors’ contributions

MN performed the breeding of the animals in captivity and the extraction of the venom. DOCM and DCP performed proteomic analysis and designed experiments. MN, DOCM, and DCP were responsible for writing the article. IB supported the maintenance of captive wasps and the venom’s extraction. MN, DOCM, DCP, and AB were in charge of revising the manuscript. AB and DCP obtained the funding, designed and coordinated the work, and reviewed the manuscript. All authors read and approved the final manuscript.
Ethics approval

Not applicable.
Consent for publication

Not applicable.

Publication Dates

Publication in this collection
10 Nov 2023
Date of issue
2023

History

Received
05 Jan 2023
Accepted
12 June 2023

This is an open-access article distributed under the terms of the Creative Commons Attribution License

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[62] 62. Francischetti IMB, Meng Z, Mans BJ, Gudderra N, Hall M, Veenstra TD, Pham VM, Kotsyfakis M, Ribeiro JMC. An insight into the salivary transcriptome and proteome of the soft tick and vector of epizootic bovine abortion, Ornithodoros coriaceus J Proteomics. 2008 Dec 2;71(5):493-512.

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[66] 66. Gad W, Kim Y. A viral histone H4 encoded by Cotesia plutellae bracovirus inhibits haemocyte-spreading behaviour of the diamondback moth, Plutella xylostella J Gen Virol. England; 2008 Apr;89(Pt 4):931-8.

[67] 67. Gad W, Kim Y. N-terminal tail of a viral histone H4 encoded in Cotesia plutellae bracovirus is essential to suppress gene expression of host histone H4. Insect Mol Biol. 2009 Feb;18(1):111-8.

[68] 68. Ibrahim AMA, Choi JY, Je YH, Kim Y. Structure and Expression Profiles of Two Putative Cotesia plutellae Bracovirus Genes (CpBV-H4 and CpBV-E94a) in Parasitized Plutella xylostella J Asia Pac Entomol. 2005 Dec;8(4):359-66.

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[72] 72. Asgari S, Rivers DB. Venom proteins from endoparasitoid wasps and their role in host-parasite interactions. Annu Rev Entomol. 2011;56:313-35.

[73] 73. Zhu JY, Fang Q, Wang L, Hu C, Ye GY. Proteomic analysis of the venom from the endoparasitoid wasp Pteromalus puparum (Hymenoptera: Pteromalidae). Arch Insect Biochem Physiol. 2010 Jul 20;75(1):28-44.

[74] 74. Liu NY, Wang JQ, Zhang ZB, Huang JM, Zhu JY. Unraveling the venom components of an encyrtid endoparasitoid wasp Diversinervus elegans Toxicon. 2017 Sep 15;136:15-26.

[75] 75. Scieuzo C, Salvia R, Franco A, Pezzi M, Cozzolino F, Chicca M, Scapoli C, Vogel H, Monti M, Ferracini C, Pucci P, Alma A, Falabella P. An integrated transcriptomic and proteomic approach to identify the main Torymus sinensis venom components. Sci Rep. 2021 Mar 3;11(1):5032.

Result			Peptide(s)			Identified Protein
Protein¹	-10lgP²	XP³	Sequence	-10lgP⁴	ppm⁵	Description	Organism
A0A1W6EVV2_9HYME	38.01	3	R.QNWASLTPYK.D	38.01	3.4	Hyaluronidase	Ampulex compressa
A0A1B0CWQ4_LUTLO	36.43	2	C.PPPPNVPAV.S	36.43	-32.5	Uncharacterized protein	Lutzomyia longipalpis
A0A2A3EQT3_APICC	30.59	4	L.TDSITL.S	30.59	5.3	COPII coat assembly protein	Apis cerana cerana
A0A0A9XY89_LYGHE	29.50	4	A.VPEAY.K	29.50	59.2	Bifunctional arginine demethylase and lysyl-hydroxylase	Lygus hesperus
A0A0L0CEB7_LUCCU	28.69	4	E.GSFERW.Y	28.69	2.5	Papilin	Lucilia cuprina
A0A0A9X7A0_LYGHE	27.47	4	L.KAAATL.E	27.47	1.1	Putative cytosol aminopeptidase	Lygus hesperus
A0A182SXW9_9DIPT	26.37	3	S.LTVENR.K	26.37	3.1	Uncharacterized protein	Anopheles maculatus
A0A2A3EK85_APICC	26.27	4	F.DLSSY.R	26.27	2.4	Protein-tyrosine sulfotransferase	Apis cerana cerana
A0A2A3EFD7_APICC	25.97	2	I.TDSLLT.F	25.97	59.9	Hemolymph protein	Apis cerana cerana
A0A0P5SWM5_9CRUS	25.56	2	E.TNSPVPT.S	25.56	29.8	Ubiquitin-associated protein	Daphnia magna
A0A2A3EBV7_APICC	25.55	2	L.YIGLE.C	17.51	2.0	Cell division cycle protein	Apis cerana cerana
A0A2A3EBV7_APICC	25.55	2	M.LSAAE.E	16.08	58.4	Cell division cycle protein	Apis cerana cerana
A0A182N577_9DIPT	25.11	3	G.GRNVLRQGDR.T	25.11	-13.2	Uncharacterized protein	Anopheles dirus
A0A1A9Y4N1_GLOFF	23.84	3	M.YTEHLR.T	23.84	13.3	Uncharacterized protein	Glossina fuscipes fuscipes
W5JTY5_ANODA	23.83	2	S.RAPAQH.G	23.83	-29.6	Uncharacterized protein	Anopheles darlingi
A0A0L7LEM8_9NEOP	23.54	1	R.CKMDTER.K	23.54	-23.2	Sterile alpha and TIR motif-containing protein 1	Operophtera brumata
A0A0M8ZN23_9HYME	23.40	1	L.TPNVSPT.L	23.40	119.4	Cysteine and histidine-rich domain-containing protein	Melipona quadrifasciata
K7J505_NASVI	23.40	1	G.TPGGSVPT.I	22.61	-38.6	Uncharacterized protein	Nasonia vitripennis
A0A0M8ZQP9_9HYME	22.87	3	K.C*NVKFNR.D	22.87	-80.0	Uncharacterized protein	Melipona quadrifasciata
A0A2A3EFD7_APICC	22.04	1	I.TDSLLT.F	22.04	133.6	Putative 116 kDa U5 small nuclear ribonucleoprotein component	Apis cerana cerana
A0A1Y1MNG8_PHOPY	22.09	1	Q.FYPPPF.S	22.09	-26.8	Uncharacterized protein	Photinus pyralis

Result			Peptide(s)			Biological contextualization
Protein¹	-10lgP²	XP³	Sequence	-10lgP⁴	ppm	Description	Organism
A0A023ETG9_AEDAL	128.71	1	K.GHYTEGAELVDSVLDVVRK.E	68.54	-32.4	Tubulin beta chain	Aedes albopictus
			K.MSSTFIGNSTAIQEIFKR.I	65.32	-32.6
			K.GHYTEGAELVDSVLDVVR.K	55.51	-18.0
			R.YLTVAAIFR.G	36.00	-21.0
A0A0P5ZYN7_9CRUS	126.44	1	R.FDGALNVDLTEFQTNLVPYPR.I	63.91	-15.4	Tubulin alpha chain	Daphnia magna
			R.GHYTIGKEIIDLVLDR.I	53.63	-30.0
			R.LISQIVSSITASLR.F	52.65	-17.5
			R.AVFVDLEPTVIDEVR.T	45.87	-18.4
			R.FDGALNVDLTEFQ*TNLVPYPR.I	24.08	-12.7
			R.LISQ*IVSSITASLR.F	22.80	-19.1
			R.GHYTIGKEIIDLVLDRIR.K	20.91	-34.4
A0A0P5F7I2_9CRUS	123.31	1	R.VALTGLTVAEYFRDQEGQDVLLFIDNIFR.F	92.63	-8.2	ATP synthase subunit beta	Daphnia magna
			D.PAPATTFAHLDATTVLSR.A	38.04	-25.0
			K.TVLIMELINNVAK.A	34.97	-12.1
VKT19_ANOSM	67.94	3	R.FTFGGC*EGNDNNFMTR.R	67.94	-17.7	Kunitz-type serine protease inhibitor	Anoplius samariensis
A0A1W7R9B8_9SCOR	63.31	2	R.LISQIVSSITASLR.F	51.37	-17.9	Tubulin alpha chain	Hadrurus spadix
A0A1W7R9B8_9SCOR	63.31	2	R.FDGALNVDLTEFQTNLVPYPR.I	23.88	-19.3	Tubulin alpha chain	Hadrurus spadix
A0A0P6CCE9_9CRUS	58.88	1	K.VIHDNFGIVEGLMTTVHAITATQK.T	50.94	-31.0	Glyceraldehyde-3-phosphate dehydrogenase	Daphnia magna
A0A0P6CCE9_9CRUS	58.88	1	R.VVDLMAYMASKE	15.88	-23.3	Glyceraldehyde-3-phosphate dehydrogenase	Daphnia magna
A0A293LN19_ORNER	51.75	1	M.AAVIEYLTAEILELAGNAAR.D	51.75	-29.3	Histone H2A	Ornithodoros erraticus
A0A0N0BEI9_9HYME	48.38	3	K.IISDMENIYSTAK.I	35.63	-15.8	Angiotensin-converting enzyme	Melipona quadrifasciata
A0A0N0BEI9_9HYME	48.38	3	K.C*DLALEPELTELLMK.S	25.49	-27.5	Angiotensin-converting enzyme	Melipona quadrifasciata
E2BSK5_HARSA	39.35	3	K.NLGGC*TAHHGMAYHR.G	39.35	-31.4	Glucose dehydrogenase	Harpegnathos saltatory
E0W1G3_PEDHC	38.97	2	R.VALTGLTVAEYFRDQEGQDVLLFIDNIFR.F	38.97	-24.5	ATP synthase subunit beta	Pediculus humanus
A0A224Y123_9ACAR	31.46	2	L.TPGGSVTP.S	31.46	15.3	7DB family member	Rhipicephalus zambeziensis
A0A1V9X4S6_9ACAR	31.12	4	L.FVGLPLEM*.L	31.12	21.4	Rhomboid-like protein	Tropilaelaps mercedesae
A0A212FPD9_DANPL	29.77	3	R.YPSETEIVTYTK.H	29.77	-24.2	Uncharacterized protein	Danaus plexippus plexippus
A0A0J7KCY6_LASNI	26.74	4	L.AVTHQNIVSGF.E	26.74	-35.0	Kinesin family member 21a	Lasius niger
A0A0M9A8V0_9HYME	26.73	4	Y.WNVPTFM.C	26.73	-12.4	Hyaluronidase	Melipona quadrifasciata
Q2Q0U9_9DIPT	26.58	4	Y.VAGPVM*.T	26.58	45.8	Glutathione S-transferase	Anopheles sacharovi
A0A1B6CHY3_9HEMI	24.65	2	R.TDLSGIT.L	24.65	24.6	Uncharacterized protein	Clastoptera arizonana
M9VSG2_9ARAC	24.1	2	K.LC*YVALDFEQEMATAASSSSLEK.S	24.10	-31.0	Actin	Tylogonus yanayacu
A0A0P5A3B7_9CRUS	21.89	3	K.ALAFAK.V	21.89	-1.9	Pentatricopeptide repeat-containing protein 2	Daphnia magna

Result			Peptide(s)			Biological contextualization
Protein¹	-10lgP²	XP³	Sequence	-10lgP⁴	ppm⁵	Description	Organism
A0A087ZTA6_APIME	195.71	1	K.KADIGVAMGIAGSDVSK.Q	83.33	-15.4	Sodium/potassium-transporting ATPase subunit alpha	Apis mellifera
			K.LTLKAEELVLGDVVEVK.F	79.02	661.7
			K.KADIGVAM*GIAGSDVSK.Q	78.72	47.7
			R.MGAIVAVTGDGVNDSPALK.K	77.71	-48.5
			K.SVGIISEGNETVEDIAQR.L	73.56	525.9
			R.TDNLEDLKQELDIDFHK.I	54.10	7.8
			K.NLEAVETLGSTSTIC*SDK.T	41.97	117.0
			K.S(+43.01)VGIISEGNETVEDIAQR.L	41.36	561.7
			K.GVVIC(+114.04)CGDQTVMGR.I	33.79	-72.9
			R.EVNGDASEAALLK.C	31.11	856.3
			R.LNIPVSEVNPR.E	18.31	-237.8
A0A131ZV00_SARSC	138.7	1	R.AFVHWYVGEGMEEGEFSEAR.E	73.99	2.2	Tubulin alpha chain	Sarcoptes scabiei
			R.LIGQIVSSITASLR.F	60.25	372.6
			R.AVC*MLSNTTAIAEAWAR.L	50.61	17.0
			R.AVCMW(sub L)SNTTAIAEAWAR.L	42.44	629.3
			K.AYHEQLTVGEITNACFEPQNQMVK.C	35.49	392.3
			R.A(+57.02)VCMLSNTTAIAEAWAR.L	19.84	423.1
			R.AVC(+209.02)MLSNTTAIAEAWAR.L	16.76	509.9
E2DV16_9HYME	117.8	3	K.NLAFFSTNAVEGTAK.G	59.61	523.3	Sodium/potassium-transporting ATPase subunit alpha	Townsendiella sp.
			K.NLEAVETLGSTSTIC*SDK.T	55.70	455.0
			R.AEELVLGDVVEVK.F	50.45	742.1
			R.M*TVAHMWFDNQIIEADTTEDQSGLQYDR.T	38.71	68.6
T1GUQ6_MEGSC	117.75	1	K.MSATFIGNSTAIQELFK.R	68.73	53.0	Tubulin beta chain	Megaselia scalaris
			R.YLTVAAIFR.G	45.92	449.0
			K.GHYTEGAELVDSVLDVVR.K	30.47	628.1
			K.GHYTEGAELVDSVLDVVRK.E	30.25	407.1
			R.INVYYNEASGGK.Y	26.20	59.7
			H.SLGGGT(+79.97).G	18.60	2000.2
A0A088A5I8_APIME	117.06	1	K.GTSSIVYVDYENITK.V	71.73	596.8	Pyruvate kinase	Apis mellifera
			R.TGLLEGGGAAEVELKK.D	53.71	85.9
			K.AIPPIDATHAVAIAVVEASVK.C	32.74	-58.4
			K.TISHALYAQTQLDHVC*ALDIDAPIGAVR.L	30.21	391.8
V9IK50_APICE	115.31	1	K.AGAEYIVESTGVYTTK.E	80.18	-14.2	Glyceraldehyde-3-phosphate dehydrogenase	Apis cerana
			K.VIHDNFEIVEGLMTTVHAVTATQK.V	38.63	367.9
			R.VPVHN(+.98)VSVVDLTVR.L	32.30	729.7
			R.VPVHNVSVVDLTVR.L	30.21	420.3
			K.GILGYTEDEVVSSDFIGDDHASIFDAK.A	20.19	289.0
V9I6A9_APICE	113.19	2	K.QAADMILLDDNFASIVTGVEEGR.L	62.72	397.2	Sodium/potassium-transporting ATPase subunit alpha	Apis cerana
			K.LTLKAEELVLGDVVEVK.F	58.42	447.0
			K.AEELVLGDVVEVK.F	46.90	-204.1
			R.MTVAHM*WFDNQIIEADTTEDQSGLQYDR.T	22.50	364.3
			K.LMLRAA(sub E)ELVLGDVVEVK.F	19.21	465.5
E2DV16_9HYME	113.14	3	K.NLAFFSTNAVEGTAK.G	59.61	523.3	Tubulin alpha chain	Anopheles atroparvus
			K.NLEAVETLGSTSTIC*SDK.T	55.70	455.0
			R.AEELVLGDVVEVK.F	50.45	742.1
			R.M*TVAHMWFDNQIIEADTTEDQSGLQYDR.T	38.71	68.6
			K.LMLRAA(sub E)ELVLGDVVEVK.F	19.21	465.5
A0A0P6A3S1_9CRUS	92.88	2	R.KESYSVYVYK.V	44.49	-24.7	Histone H2B	Daphnia magna
			K.Q(-17.03)VHPDTGISSK.A	41.98	-120.8
			K.HAVSEGTK.A	41.46	950.0
			R.LAHYNKR.S	25.90	592.2
			K.Q(+27.99)VHPDTGISSK.A	21.77	929.7
			K.ESYSVYVYK.V	21.62	874.9
			K.RSTITSR.E	16.66	842.3
V9IK47_APICE	83.52	2	K.DFLAGGVAAAISK.T	53.51	-165.5	ADP,ATP carrier protein 2	Apis cerana
			R.YFVGNLASGGAAGATSLC*FVYPLDFAR.T	44.88	332.4
			R.LAADVGK.A	22.71	1358.1
A0A182FLZ7_ANOAL	82.6	2	R.DNIQGITKPAIR.R	37.13	738.5	Histone H4	Anopheles albimanus
			K.TVTAM*DVVYALK.R	33.79	747.8
			K.TVTAM*DVVYALKR.Q	30.97	-6.3
			R.TLYGFGG	30.03	-39.9
			R.DNIQGITKPAIR(+14.02).R	26.53	-83.7
			R.DAVTYTEHAK.R	24.64	-116.7
			R.TLY(+31.99)GFGG	22.56	-37.3
			R.DNIQGITK.P	21.75	-116.8
			R.ISGLIYEETR.G	15.23	-111.5
A0A0P6CE35_9CRUS	77.77	3	M.T(+42.01)DAAVSFAK.D	41.70	-120.0	ADP/ATP translocase	Daphnia magna
			G.FNVSVQGIIIYR.A	35.92	17.5
			K.IYKSDGIK.G	27.01	-58.0
			K.TAVAPIER.V	20.32	-65.7
			R.MMMQSGR.K	20.09	776.6
A0A1W4W573_AGRPL	74.53	3	K.QVAQQEAQR.A	40.62	153.3	Prohibitin-2	Agrilus planipennis
			K.Q(-17.03)VAQQEAQ*R.A	34.21	104.9
			Q.Q(-17.03)KIVQAEGEAEAAK.M	33.78	-46.6
			R.NPGYLK.L	32.94	-166.1
			K.EYTAAVEAK.Q	24.15	323.4
			K.Q(-17.03)VAQQEAQR.A	20.21	-46.3
V9IID0_APICE	70.05	3	K.TNMLLQLDGTTAIC*EDIGR.Q	70.05	-78.4	Mitochondrial-processing peptidase subunit beta	Apis cerana
A0A087ZQI5_APIME	69.91	2	K.NIQADEMVEFSSGLK.G	61.14	-81.2	ATP synthase subunit alpha	Apis mellifera
A0A087ZQI5_APIME	69.91	2	R.LTELLK.Q	17.53	-109.0	ATP synthase subunit alpha	Apis mellifera
L7M2G6_9ACAR	48.98	4	F.VTIEGSVSSGVDL.T	48.98	20.5	Putative pseudouridine synthase	Rhipicephalus pulchellus
A0A0L7LF47_9NEOP	40.41	4	L.QGASSY.L	40.41	-151.0	Putative ribosomal RNA methyltransferase NOP2	Operophtera brumata
A0A0J7L789_LASNI	28.97	4	Y.GLEKF.W	28.97	53.3	La-related protein	Lasius niger
A0A0P5PN82_9CRUS	27.72	4	S.HSSGY.G	19.20	-263.0	FERM and PDZ domain-containing protein	Daphnia magna
A0A0P5PN82_9CRUS	27.72	4	T.SSLLS.D	17.03	-2450.2	FERM and PDZ domain-containing protein	Daphnia magna
A0A1D2MK27_ORCCI	27.57	4	L.H(sub I)PVPEYPL.Y	27.57	95.3	Alanine aminotransferase	Orchesella cincta

Brasil

Brasil

Proteomic analyses of venom from a Spider Hawk, Pepsis decorata

Abstract

Background:

Methods:

Results:

Conclusion:

Background

Methods

Biological material

Reagents

Sample preparation

Mass spectrometry analyses

Data Processing

Results

IT-TOF analysis

Q-TOF analysis

LTQ analysis

Discussion

IT-TOF analysis

Q-TOF analysis

LTQ analysis

Conclusion

Abbreviations

Acknowledgments

References

Availability of data and materials

Funding

Authors’ contributions

Ethics approval

Consent for publication

Publication Dates

History