Next Article in Journal
Safety of Onabotulinumtoxin A in Chronic Migraine: A Systematic Review and Meta-Analysis of Randomized Clinical Trials
Previous Article in Journal
Investigation on Fermentation Characteristics and Microbial Communities of Wheat Straw Silage with Different Proportion Artemisia argyi
 
 
Search for Articles:
Title / Keyword
Author / Affiliation / Email
Journal
Article Type
 
 
Advanced Search
 
Section
Special Issue
Volume
Issue
Number
Page
 
Journals
Toxins
Volume 15
Issue 5
10.3390/toxins15050331
toxins-logo
Submit to this Journal Review for this Journal Propose a Special Issue
Article Menu

Article Menu

share Share announcement Help format_quote Cite question_answer Discuss in SciProfiles thumb_up
...
Endorse textsms
...
Comment
first_page
settings
Order Article Reprints
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Article

Characterization of the Molecular Diversity and Degranulation Activity of Mastoparan Family Peptides from Wasp Venoms

by
Xiangdong Ye
1,2,
Xin Liu
1,
Xudong Luo
1,2,
Fang Sun
1,2,
Chenhu Qin
1,2,
Li Ding
3,
Wen Zhu
1,2,
Huajun Zhang
1,
Haimei Zhou
1 and
Zongyun Chen
1,2,*
1
Department of Biochemistry and Molecular Biology, Institute of Basic Medical Sciences, College of Basic Medicine, Hubei Key Laboratory of Embryonic Stem Cell Research, Hubei University of Medicine, Shiyan 442000, China
2
Hubei Key Laboratory of Wudang Local Chinese Medicine Research, Hubei University of Medicine, Shiyan 442000, China
3
Department of Clinical Laboratory, Dongfeng Hospital, Hubei University of Medicine, Shiyan 442000, China
*
Author to whom correspondence should be addressed.
Toxins 2023, 15(5), 331; https://doi.org/10.3390/toxins15050331
Submission received: 23 March 2023 / Revised: 21 April 2023 / Accepted: 22 April 2023 / Published: 12 May 2023
Browse Figures
Review Reports Versions Notes

Abstract

:
Wasp stings have become an increasingly serious public health problem because of their high incidence and mortality rates in various countries and regions. Mastoparan family peptides are the most abundant natural peptides in hornet venoms and solitary wasp venom. However, there is a lack of systematic and comprehensive studies on mastoparan family peptides from wasp venoms. In our study, for the first time, we evaluated the molecular diversity of 55 wasp mastoparan family peptides from wasp venoms and divided them into four major subfamilies. Then, we established a wasp peptide library containing all 55 known mastoparan family peptides by chemical synthesis and C-terminal amidation modification, and we systematically evaluated their degranulation activities in two mast cell lines, namely the RBL-2H3 and P815 cell lines. The results showed that among the 55 mastoparans, 35 mastoparans could significantly induce mast cell degranulation, 7 mastoparans had modest mast cell degranulation activity, and 13 mastoparans had little mast cell degranulation activity, suggesting functional variation in mastoparan family peptides from wasp venoms. Structure–function relationship studies found that the composition of amino acids in the hydrophobic face and amidation in the C-terminal region are critical for the degranulation activity of mastoparan family peptides from wasp venoms. Our research will lay a theoretical foundation for studying the mechanism underlying the degranulation activity of wasp mastoparans and provide new evidence to support the molecular design and molecular optimization of natural mastoparan peptides from wasp venoms in the future.
Keywords:
wasp venom; mastoparan; degranulation; structure–function relationship
Key Contribution: In our study, for the first time, we evaluated the molecular diversity of 55 wasp mastoparan family peptides from wasp venoms, systematically evaluated degranulation activities of 55 mastoparans in two mast cell lines, and explored the structure–function relationship of wasp mastoparans and degranulation activity. Our research will lay a theoretical foundation for studying the mechanism underlying the degranulation activity of wasp mastoparans and provide new evidence to support the molecular design and molecular optimization of natural mastoparan peptides from wasp venoms in the future.

1. Introduction

In recent years, wasp stings have become an increasingly serious public health problem because of their high incidence and mortality rates in various countries and regions [1,2,3]. Anaphylaxis is one of the most common and prominent clinical symptoms of wasp stings, the clinical features of which are extensive, from painful local swelling to systemic anaphylactic reactions and shock symptoms. Allergic reactions to wasp venom are also a devastating problem due to progressive immune responses in different systems, including the respiratory system, circulatory system, nervous system, digestive system, blood system, and urinary system, which may lead to multiple organ dysfunction and even death [4,5]. Mast cells (MCs) are innate immune cells that are scattered in tissues throughout the organism and are particularly abundant at sites exposed to the environment, such as the skin and mucosal surfaces. MCs are well known for their pivotal role in allergic responses, where allergens trigger MC activation by crosslinking IgE bound to the high-affinity IgE receptor (FcεRI) leading to the initiation of the allergic cascade. In addition, MCs express a great armamentarium of receptors (such as toll-like receptors and G-protein-coupled receptors) enabling them to respond to a wide variety of cellular, viral, and bacterial triggers [6,7]. Venom allergies may be mediated by both immunological mechanisms and nonimmunological mechanisms [8].
Mastoparan family peptides are the main component of wasp venom, accounting for approximately 50–60% of the dry weight of wasp venom [9], and they were originally described as factors that promote the degranulation of mast cells; these peptides play a pivotal role in allergy reactions and inflammation induced by wasp venom [10]. Some studies found that Mastoparan-L induced the degranulation of connective tissue mast cells (CTMCs) via a G protein-coupled receptor named MRGPRX2 (Mas-related G protein-coupled receptor member X2) and the Gαq/PLCγ1/IP3/Ca2+ flux signaling pathway [11,12]. Several researchers have identified many mastoparans in various wasp venoms, most of which have been reported to have different abilities to induce mast cell degranulation [13]. However, the molecular diversity and functional differences of mastoparan family peptides that induce allergic-reaction-mediated organ dysfunction remain unclear.
Here, based on the mastoparan family peptides that have been reported in the previous literature [1,2], and the NCBI PubMed public database, we systematically identified mastoparan family peptides in wasp venoms by bioinformatics methods. Fifty-five mastoparan family peptides derived from 31 wasp species in five wasp families were identified, suggesting the molecular diversity of mastoparan family peptides from wasp venoms. To systematically and comprehensively investigate the degranulation activity of wasp venom mastoparans, we analyzed all the reported mastoparans and established the first wasp mastoparan library by chemical synthesis. We comprehensively evaluated the degranulation activity of 55 mastoparans in RBL-2H3 cells and P815 cells and preliminarily explored the relationship between the structure and mast cell degranulation activity of these mastoparans. Our results will lay a theoretical foundation for research on the mechanism underlying the degranulation activity of wasp mastoparans and provide new evidence to support the molecular design and molecular optimization of natural mastoparan peptides from wasp venoms.

2. Results

2.1. Molecular Diversity and Physical Properties of Mastoparan Family Peptides from Wasp Venoms

Based on the reported mastoparan peptide sequences and the NCBI PubMed public database, we systematically identified mastoparan family peptides from wasp venoms with bioinformatics methods. Fifty-five mastoparan family peptides derived from 31 wasp species in five wasp families were identified (Table 1), suggesting the molecular diversity of mastoparan family peptides from wasp venoms. As shown in Figure 1A, 13 mastoparans were derived from 7 wasp species of Eumenidae, 22 mastoparans were derived from 12 wasp species of Vespidae, 9 mastoparans were identified in 5 wasp species of Polistidae, 10 mastoparans were identified in 4 wasp species of Polybiidae, and only 1 mastoparan was found in Ropalidia speciosa of Ropalidiidae. Further analysis showed that 17 out of 31 wasp species venom contained only one mastoparan, 8 out of 31 wasp species venom contained two mastoparans, and 4 out of 31 wasp species venom contained three mastoparans. These data indicated that most wasp venom contained only one mastoparan. However, both Vespa tropica and Polybia paulista contained five mastoparans (Figure 1B).
Among the 55 mastoparan family peptides, 83.6% of mastoparans (46/55) were composed of 14 amino acids, and only 6 mastoparans had 15 amino acids and 2 mastoparans had 17 amino acids (Table 1), which was consistent with previous research that wasp mastoparans were mainly composed of 14 amino acids [9]. Physical property analysis also showed that 54 mastoparans are cationic peptides with one to five positive charges, and only 1 mastoparan is electrically neutral. The amphipathic analysis showed that the mean hydrophobicity of mastoparans was between 0.377 and 0.829, and there were 43 mastoparans with hydrophobic moments between 0.400 and 0.600, 11 mastoparans with hydrophobic moments lower than 0.400, and only 1 with a hydrophobic moment greater than 0.600. As described in previous articles [9], each mastoparan contains two to four lysine residues whose position along the amino acid chain allows the formation of a stable helical structure, which was also consistent with our present analyses. Interestingly, among the 55 mastoparan family peptides, most mastoparans (92.7%, 51/55) had amidation modifications in the C-terminal regions, but there were seven mastoparans without amidation modifications in the C-terminal regions. These results suggest the molecular diversity of mastoparan family peptides from wasp venoms in terms of molecular size, molecular charge, hydrophobicity, hydrophilicity, and C-terminal amidation modification (Table 1).

2.2. Classification of Diverse Mastoparan Family Peptides from Wasp Venoms Based on Sequence Alignments

Next, we investigated the relationship of 55 mastoparan family peptides based on their primary structures. The results of the homologous amino acid sequence alignment of 55 mastoparans showed that the N-terminal amino acids of mastoparans are highly conserved, mainly dominated by INW/LK/L (Supplementary Figure S1 and Figure 2A). The C-terminus of mastoparans is less conserved, mainly due to the difference in the number of amino acids. The C-terminal amino acid sequence of mastoparans, which is composed of 14 amino acids, is also conserved and predominantly terminated by amidated leucine (Figure 2A). Based on our sequence alignments, mastoparan family peptides could further be divided into four subfamilies: Subfamily 1 (SF1), Subfamily 2 (SF2), Subfamily 3 (SF3), and Subfamily 4 (SF4) (Figure 2B). The amino acid homology of mastoparans in each subfamily was further analyzed, and the results showed that the amino acid sequences of mastoparan peptides in SF1, SF2, and SF3 are very conserved (Figure 2C–F), and conserved sequence motifs could be found in each subfamily. Mastoparans in SF1 are characterized by the conserved sequence motif INWKKI····K··L, with amino acid difference concentrated in the 7th to 10th and 12th to 13th amino acid residues (Figure 2C). Mastoparan peptides in SF2 are characterized by the sequence motifs IN·K··AA··KK·L (Figure 2D), and amino acid differences are mainly distributed in positions 3, 5, 6, 9, 10, and 13, which is observed throughout the whole polypeptide chain. Mastoparans in SF3 are characterized by the sequence motif INWLKLGK····AL (Figure 2E), and the amino acid differences are mainly concentrated in the 9th to 12th amino acids. The mastoparan peptides in SF4 had the least well-conserved amino acids, and no conserved motif was found in this subfamily (Figure 2F); only the C-terminal amino acids retained some conserved properties. We also observed that some mastoparans that originated from the same wasp venom belong to different subfamilies, such as Pm-R2 belonging to SF2 and Pm-R1/3 belonging to SF3. In conclusion, the known mastoparan family peptides can be divided into four subfamilies. Among them, mastoparan peptides in three subfamilies had conserved motifs, further indicating the molecular diversity and structural conservation of mastoparan family peptides from wasps.

2.3. Characterization of the Degranulation Activity of Mastoparan Peptides from Wasp Venoms

Our current work revealed the molecular diversity and classification of mastoparan family peptides from wasp venoms. It is well known that molecular diversity is the foundation of functional differentiation. Mastoparan(-L) was the first cationic α-helical peptide identified in Vespula lewisii venom that could induce significant mast cell degranulation; hence, it was also named Mastoparan. Later, multiple studies identified a variety of mastoparans with similar structures and mast cell degranulation activities from different wasp venoms. However, the degranulation effects of mastoparans on mast cells have not been systematically studied. Therefore, it was difficult to analyze the structure and functional relationships of mastoparan family peptides from wasp venoms. To systematically and comprehensively study the influence of different mastoparan peptide families on the detailed functions of these peptides, the degranulation activity of 55 wasp mastoparans was further characterized. First, we established a wasp venom mastoparan library containing all 55 known mastoparan family peptides by chemical synthesis and mass spectrometric identification. Second, we designed a degranulation activity evaluation assay with two representative cell lines, RBL-2H3 cells and P815 cells. RBL-2H3 cells (rat basophil leukemia cells) have been widely used to study the functions of mast cells. We used the 50% effective concentration (EC50) and degranulation rate at 80 μg/mL (the lowest dose of mastoparan that reaches 100% degranulation rate) as two indexes to evaluate the degranulation activity of mastoparans in RBL-2H3 cells. The 55 mastoparans were divided into three groups: a high-activity group (EC50 ≤ 100 μM), a modest-activity group (100 μM < EC50 ≤ 200 μM), and a low-activity group (EC50 > 200 μM). As shown in Table 2, there were 35 mastoparans in the high-activity group, which accounted for 63.6% of the mastoparans. Agelaia-MPI, Polybia-MPII, Pm-R3, Protopolybia-MPIII, and EpVP2b induced significant degranulation of RBL-2H3 cells in a dose-dependent manner, and the EC50 values were 5.25 ± 0.87 μM, 6.79 ± 0.40 μM, 7.60 ± 0.76 μM, 22.47 ± 2.96 μM, and 25.93 ± 2.88 μM, respectively (Figure 3A–E). Mastoparan(-L) is a widely used agonist for mast cell degranulation, and the EC50 was 52.13 ± 3.21 μM (Figure 3F). Seven mastoparans were in the modest-activity group, and 13 mastoparans were in the low-activity group. These results indicated that not all mastoparans have the ability to induce mast cell degranulation and that the activity of different mastoparans varies greatly. Further analysis showed that high-activity mastoparans in Polistidae accounted for 88.9% (8/9), which was much higher than the 63.6% (35/55) among all mastoparans, 68.2% (15/22) in Polybiidae, 60% (6/10) in Vespidae, and 46.15% (6/13) in Eumenidae (Figure 4A). Moreover, we investigated the low-activity mastoparans that were identified in five wasp families and found that the low-activity mastoparans identified in Eumenidae accounted for 38.5% (5/13), which is much higher than the 23.6% (13/55) among all mastoparans, 31.8% (7/22) in Vespidae, 20% (2/10) in Polybiidae, and 11.1% (1/9) in Polistidae. These results suggest that the number of mastoparans with degranulation activity in Polistidae venom is much higher than that in the other four wasp families, while that from Eumenidae venom was the lowest. Next, we investigated the degranulation activity of wasp venom peptides in different subfamilies. The results showed that the proportion of high-activity mastoparans in Subfamily 1 (9/11, 81.8%) was much higher than that in SF4 (50%), SF2 (70.6%), and SF3 (71.4%) (Figure 4B).
We also evaluated the degranulation activity of 55 mastoparans in the P815 cell line (mouse mast cell line). The results showed that at the same mastoparan concentration (80 μg/mL), the degranulation activity of all mastoparans in P815 cells was much lower than that in RBL-2H3 cells. However, Agelaia-MPI, Polybia-MPII, Pm-R3, EpVP2b, Protopolybia-MPIII, and Mastoparan-T1 could still induce significant degranulation of P815 cells. These results suggest that the degranulation activity of mastoparans might vary in different cells (Table 2).

2.4. Structure–Activity Relationship Studies of Wasp Mastoparan Peptides

Considering the molecular diversity and functional variation of wasp mastoparan family peptides in degranulation activity, we investigated the detailed structure–activity relationship of wasp mastoparans.
In SF1, mastoparan amino acid differences are located at the 7th to 10th and 12th to 13th amino acid residues (Figure 5A) and distributed in both the hydrophilic and hydrophobic surface of α-helical (Figure 5B). We found two pairs of mastoparans with similar amino acid sequences and distinct degranulation activity. The amino acid sequences of Dominulin A and Dominulin B (EC50 > 200 μM vs. 94.80 ± 32.77 μM) were different at sites 9, 11, 12, 13, and 16, and those of MP-V1 and MP-V2 (130.24 ± 46.56 μM vs. 88.86 ± 61.29 μM) were different at sites 9 and 15 (Table 2). These results suggest that the amino acid at site 9 of the mastoparans in SF1 may play a pivotal role in degranulation.
In SF2, 12 mastoparans had EC50 values lower than 100 μM (red-labeled), and 4 mastoparans had EC50 values higher than 200 μM (black-labeled, Figure 6A). The amino acid differences were mainly found in positions 3, 5, 6, 9, 10, and 13, which was observed throughout the whole polypeptide chain. Considering that the secondary structure of mastoparans was a cationic α-helical structure (Figure 6B), we further analyzed the spatial distribution of these amino acid differences in the secondary structure by using the helical wheel. The results showed that the amino acid differences (sites 3, 5, 6, 9, 10, and 13) were all distributed on the hydrophobic surface of the α-helical wheel (Figure 6C,D), which indicated that the hydrophobicity of mastoparans plays a critical role in degranulation activity.
In SF3, 10 mastoparans had EC50 values lower than 100 μM. The sequence alignment showed that mastoparans in Subfamily 3 were most conserved, and the amino acid differences were mainly concentrated in the 9th to 12th amino acids (Figure 7A–C). Moreover, in Subfamilies 1–3, the amino acid at site 9 may play a critical role in the degranulation of mast cells.
In addition, although the mastoparans in subfamily 4 are also typical cationic α-helical peptides, we found no significant relationship between their degranulation activities and structures (Figure 8A–C). Interestingly, we found that all mastoparans without amidated modifications (EpVP, Eumenitin, Eumenitin-F, and Eumenitin-R; Table 1) belonged to Subfamily 4, and the EC50 of degranulation activity was higher than 100 μM (Table 2); these results mean that the amidation of mastoparans plays an important role in their degranulation activity.
To further explore the amino acids that play a key role in degranulation activity, two mastoparan peptides, Protopolybia-MPIII and Protopolybia-MPI, from the wasp species Protopolybia exigua were selected. Both peptides were from Subfamily 3 (SF3), which was the most conserved subfamily, and the peptides had the conserved motif sequence INWLKLGK (Figure 2E). There are only four different residue sites, sites 9 and 11 to 13 (Figure 9A). All the other sites between Protopolybia-MPIII and Protopolybia-MPI were the same. Interestingly, the degranulation activities of Protopolybia-MPIII and Protopolybia-MPI were significantly different. Therefore, we mutated the amino acids at positions 9 and 11–13 of Protopolybia-MPIII to the corresponding sequences of Protopolybia-MPI, and 14 new mutant peptides (Figure 9B) were designed and synthesized with methods similar to those used for the wild-type mastoparan peptides. The degranulation activity of 14 new mutant peptides was further evaluated. The results showed that degranulation activity was significantly decreased after the mutation of Protopolybia-MPIII-9A to 9K (Protopolybia-MPIII-1) and the mutation of Protopolybia-MPIII-13I to 13S (Protopolybia-MPIII-2, -8, -9, -11). When both 9A and 11I were mutated, the degranulation of mast cells was almost lost (Protopolybia-MPIII-5, -13, -14) (Table 3). These results suggest that 9A and 11I are key sites for the mast cell degranulation activity of Protopolybia-MPIII.

3. Discussion

Wasp venom is rich in various bioactive substances, such as peptides and proteins [33]. Among these compounds, mastoparans stand out because of their abundance, accounting for 50% of the dry weight of the venom, and their various biological activities, such as their G protein-activating, antimicrobial, anticancer, and hemolytic activities, as well as their mast cell degranulation activity; these features are iconic characteristics of this group of wasp venom peptides [10,13]. Since the discovery of the first mastoparan in wasp venom in 1979 [1], scientists have identified a variety of mastoparans from different wasp venoms. Here, we first studied the molecular diversity of mastoparan family peptides and found that all the known mastoparan family peptides can be divided into four subfamilies: Subfamily 1 (SF1), Subfamily 2 (SF2), Subfamily 3 (SF3), and Subfamily 4 (SF4) (Figure 2). Based on their molecular diversity, we established a polypeptide library containing the 55 wasp mastoparans and systemically evaluated the degranulation activity of the whole family of wasp mastoparans. The ability to induce mast cell degranulation was greatly different among the 55 mastoparans; only 35 mastoparans could induce significant mast cell degranulation (EC50 < 100 μM), and 13 mastoparans could hardly induce mast cell degranulation. The degranulation activity of mastoparans varies in different wasp species, such as Vespa tropicavs. Vespa bicolor (Mastoparan-T4, T2 vs. Mastoparan-VB1, VB2) and Polistes rothneyiiwataivs. Polistes dominulus (Pm-R1, R3 vs. Dominulin A, B), as well as in different wasp families, such as Polistidae vs. Eumenidae. The degree of allergic reactions to wasp stings depends on multiple factors, such as the number of stings, the patients’ constitution, and the wasp species (the toxicity of venom) [34]. The venom toxicity of different wasp species has not been reported to date. Our results provide a basis for the preliminary evaluation of the toxicity of different wasp venoms.
The degranulation activity of some mastoparans derived from the same wasp venom differs greatly; for example, Protopolybia-MPI/MPII/MPIII were identified in Protopolybia exigua, and the EC50 values were 116.76 ± 38.30 μM, 77.85 ± 9.08 μM, and 22.47 ± 2.96 μM, respectively. Pm-R1, Pm-R2, and Pm-R3 were identified in Polistes rothneyiiwatai, and the EC50 values of Pm-R1, Pm-R2, and Pm-R3 in inducing RBL-2H3 cell degranulation were 22.95 ± 4.77 μM, 94.79 ± 73.52 μM, and 7.60 ± 0.76 μM, respectively (Table 2). Interestingly, the content of Protopolybia-MPIII was significantly higher than that of Protopolybia-MPI/MPII in Protopolybia exigua [14], and the contents of Pm-R1 and Pm-R3 were comparable and significantly higher than that of Pm-R2 in Polistes rothneyiiwatai venom [15], which suggested the difference in degranulation activity among these mastoparans from the same wasp may be related to their relative contents in wasp venom, and the role of different mastoparans in the same wasp venom played in degranulation activity needs further investigation. In some wasp venom, we also found that not all mastoparans induced mast cell degranulation; for example, there were two mastoparans (Mastoparan-VB1 and Mastoparan-VB2) identified in Vespa bicolor, but neither of them could induce the degranulation of RBL-2H3 cells, which suggest that these mastoparans may have other biological activities and need further investigations.
To explore the relationship between mast cell degranulation activity and the structure of mastoparan peptides, two representative mastoparan peptides, Protopolybia-MPIII and Protopolybia-MPI, from the wasp species Protopolybia exigua were selected. We found that the C-terminal amino acid residues, especially the 9th to 12th amino acids, play a critical role in mast cell degranulation induced by mastoparans of the SF3. Mutations in both A9K and I11S of Protopolybia-MPIII can significantly decrease degranulation activity. The relationship of mutations in Protopolybia-MPIII and its interactions with intracellular targets needs further investigation. Different subfamilies of mastoparans have different structural characteristics, which might also influence their degranulation activities. For example, amino acid differences were mainly distributed in the hydrophobic surface of α-helices in Subfamily 2 (SF2), which suggests that hydrophobic surfaces may play a pivotal role in inducing mast cell degranulation. However, the relationship between mastoparan hydrophobicity and mast cell degranulation activity has not been reported. Multiple studies have shown that hydrophobicity is critical for multiple biological activities, such as antimicrobial, anticancer, and hemolytic activities [16,17]. The hydrophobic surface of the α-helix can insert into the phospholipid bilayer of cell membranes and generate pores to kill bacteria and some tumor cells. Delazari dos Santos et al. found that Protopolybia-MPIII can cross the cell membrane into the plasma and contribute to the degranulation of mast cells [18], but there is a lack of molecular dynamic analysis for Protopolybia-MPIII and cell membrane interactions, and further investigation is needed.
C-terminal amidation is one of the typical characteristics of wasp mastoparans. In our wasp mastoparan library, four mastoparans were unmodified, among which Eumenitin, Eumenitin-R, and Eumenitin-F hardly induced mast cell degranulation, and EpVP1 had slight degranulation activity (EC50 = 171.20 ± 77.20 μM). The relationship between the amidation modification and degranulation activity of mastoparans is still unknown. Ashley L et al. showed that tumor cells (Jurkat T cells) are more sensitive to Mastoparan-NH2 than Mastoparan-COOH, and Mastoparan-COOH had almost no antitumor activity toward Jurkat T cells [19]. Da Silva, A. V. et al. also found that C-terminal amidation promotes the stabilization of the secondary structure of Protonectarina-MP, with a relatively high content of helical conformations, facilitating a deeper interaction with the phospholipid constituents of animal and bacterial cell membranes [35]; this favors biological activities that depend on peptide structure recognition by GPCRs (such as exocytosis) and activities that depend on membrane disruption (such as hemolysis and antibiosis).
Mastoparan(-L) is the most widely studied wasp mastoparan, and multiple studies have shown that mast cell activation induced by Mastoparan(-L) is related to G proteins [21]. Mastoparan(-L) activates mast cells via Mas-related G protein-coupled receptor member X2 (MRGPRX2) and then activates the Gαq/PLCγ1/IP3/Ca2+ flux signaling pathway, inducing the degranulation of mast cells [11]. The detailed mechanism underlying the interaction of mastoparan(-L) and MRGPRX2 is still unknown, and no other mastoparans have been found that can activate mast cells via MRGPRX2. Our results showed that the mast cell degranulation activity of 22 mastoparans (EC50 > 52.13 ± 3.21 μM) was higher than that of Mastoparan(-L), which suggests that mastoparans may activate mast cells via other more effective pathways. Dos Santos, L. D et al. found that Mastoparan could immediately cross cell membranes and then specifically recognize intracellular proteins and directly activate endosomes, leading to mast cell degranulation [36]. Based on our wasp mastoparan peptide library and the functional data in this current study, it is important to further evaluate the mast cell degranulation induced by wasp mastoparans and explore the pathway and mechanism underlying mast cell activation induced by mastoparans in the future; such studies could provide a theoretical basis for the clinical treatment of wasp-sting-induced allergic reactions and multiple organ dysfunction and the research and development of anti-venom drugs for the treatment of wasp stings.
In conclusion, the amino acids in the C-termini of mastoparans (such as sites 7, 8, 9, 10, 12, and 13 in Subfamily 1 and sites 9, 10, 11, and 12 in Subfamily 3), the composition of amino acids in the hydrophobic surface of the helical wheel structure, and the C-terminal amidation of mastoparans are pivotal for the degranulation activities of wasp mastoparans; these results provide new evidence to support the molecular design and molecular optimization of natural mastoparan peptides from wasp venoms in the future.

4. Materials and Methods

4.1. Peptide Synthesis and Bioinformatic Analysis

All the peptides were synthesized and purified by ChinaPeptides Corporation (Shanghai, China) by solid-phase methods using standard N-9-fluorenylmethyloxycarbonyl (Fmoc) chemistry [22]. Peptide purity (>95%) was determined by reverse-phase high-performance liquid chromatography (RP-HPLC) with a Kromasil 100-5 C18 column (4.6 mm × 250 mm) at 220 nm at a flow rate of 1.0 mL/min using a linear water/acetonitrile gradient that contained 0.1% trifluoroacetic acid. Peptides were stored as lyophilized powders before use. The theoretical relative molecular mass, isoelectric points (pI), helical-wheel plots, net charge, and hydrophobic moments were calculated online using the HeliQuest server [23]. The conservatism of amino acid sequence of mastoparans using the WebLogo generator (https://weblogo.threeplusone.com/ (accessed on 17 September 2022)) [37]. The PDB structure of mastoparans was obtained with I-TASSER Online Server (https://seq2fun.dcmb.med.umich.edu//I-TASSER/ (accessed on 12 December 2022)) [38]. Multiple amino acid sequence alignments of wasp mastoparans and homology trees were analyzed using DNAMAN software [39]. Fourteen mutations of Protopolybia-MPIII were obtained based on the different amino acids A9K, I11S, D12A, and A13I between Protopolybia-MPIII and Protopolybia-MPI.

4.2. Cell Culture

RBL-2H3 cells (rat mucosal-type mast cell line) and P815 cells (mouse mast cell tumor cell line) were obtained from the BeNa Culture Collection (Xinyang, China). RBL-2H3 cells were cultured in DMEM (Gibco, Wuhan, China) supplemented with 15% FBS (Gibco), and P815 cells were maintained in RPMI 1640 basic medium supplemented with 10% FBS and antibiotics (100 mg/L streptomycin and 1 × 105 U/L penicillin) in a humidified atmosphere (5% CO2, 37 °C).

4.3. Mast Cell Degranulation Activity

Degranulation was analyzed by measuring the release of the granule marker N-acetyl-D-glucosaminidase (β-hexosaminidase), which colocalizes with histamine, as described in [24]. For this, 2 × 105 P815 cells/mL or 1.5 × 105 RBL-2H3 cells/mL were seeded in 96-well cell culture plates. Twelve hours later, the cells were incubated with various concentrations of mastoparans dissolved in 100 μL HEPES buffer (137 mM NaCl, 2.7 mM KCl, 1 mM MgCl2, 1.8 mM CaCl2, 20 mM HEPES, 1 mg/mL BSA, and 1 mg/mL glucose, pH 7.4) for 15 min at 37 °C and 5% CO2. Then, the reactions were quenched by the addition of 0.15 mL of ice-cold HEPES buffer. After centrifugation, the supernatants were sampled for the β-hexosaminidase assay. Briefly, 50 μL samples of the cell culture supernatants and 50 μL of the substrate, 5 mM p-nitrophenyl-N-acetyl-b-D-glucosaminide (Sigma) in 0.2 M citrate, pH 4.5, were incubated in 96-well plates at 37 °C and 5% CO2 for 16–18 h to yield the chromophore p-nitrophenol, and the reactions were stopped by the addition of 100 μL of 0.2 M glycine solution, pH 10.7. The absorbance of the colored product was assessed at 405 nm using a microtiter plate reader. The values for β-hexosaminidase released in the medium are expressed as the percentage of total β-hexosaminidase, which was measured in the cells after lysis in 0.1% Triton X-100. The experiment was repeated three times, and the results represent the mean and standard deviation (SD) of quadruplicate tests. The percent degranulation was calculated according to the following equation:
Degranulation Rate (%) = 100% × (Amastoparans − AHEPES)/(ATriton X-100 − AHEPES).

4.4. Statistical Analysis

Statistical analysis was performed with GraphPad Prism software. The curve of mast cell degranulation induced by wasp mastoparans was generated in SigmaPlot 12.5 software, and the EC50 was calculated according to the following equation (Four-Parameter Logistic Curve): y = min + (max − min)/(1 + (x/EC50) − Hillslope).

Supplementary Materials

The following supporting information can be downloaded at https://www.mdpi.com/article/10.3390/toxins15050331/s1, Figure S1: Sequence alignment of 55 wasp venom mastoparans.

Author Contributions

Conceptualization, Z.C.; Data curation, X.Y., X.L. (Xin Liu) and H.Z. (Huajun Zhang); Formal analysis, X.Y.; Investigation, X.Y., C.Q. and F.S.; Methodology, X.L. (Xudong Luo) and L.D.; Resources, W.Z.; Software, X.Y.; Validation, X.Y., H.Z. (Huajun Zhang) and H.Z. (Haimei Zhou); Visualization, L.D. and W.Z.; Writing—original draft, X.Y.; Writing—review and editing, Z.C. All authors have read and agreed to the published version of the manuscript.

Funding

This work was supported by grants from the National Natural Sciences Foundation of China (82204407 and 81973321), Natural Science Foundation of Hubei Provincial Department of Education (Q20202103), Foundation of Health Commission of Hubei Province (WJ2021M060), and Cultivating Project for Young Scholar at the Hubei University of Medicine (2020QDJZR011).

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

All data supporting the results can be found within the manuscript.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Hirai, Y.; Yasuhara, T.; Yoshida, H.; Nakajima, T.; Fujino, M.; Kitada, C. A new mast cell degranulating peptide “mastoparan” in the venom of Vespula lewisii. Chem. Pharm. Bull. 1979, 27, 1942–1944. [Google Scholar] [CrossRef] [PubMed]
  2. Abd El-Wahed, A.; Yosri, N.; Sakr, H.H.; Du, M.; Algethami, A.F.M.; Zhao, C.; Abdelazeem, A.H.; Tahir, H.E.; Masry, S.H.D.; Abdel-Daim, M.M.; et al. Wasp Venom Biochemical Components and Their Potential in Biological Applications and Nanotechnological Interventions. Toxins 2021, 13, 206. [Google Scholar] [CrossRef] [PubMed]
  3. Konno, K.; Hisada, M.; Naoki, H.; Itagaki, Y.; Kawai, N.; Miwa, A.; Yasuhara, T.; Morimoto, Y.; Nakata, Y. Structure and biological activities of eumenine mastoparan-AF (EMP-AF), a new mast cell degranulating peptide in the venom of the solitary wasp (Anterhynchium flavomarginatum micado). Toxicon 2000, 38, 1505–1515. [Google Scholar] [CrossRef]
  4. Rangel, M.; Cabrera, M.P.; Kazuma, K.; Ando, K.; Wang, X.; Kato, M.; Nihei, K.; Hirata, I.Y.; Cross, T.J.; Garcia, A.N.; et al. Chemical and biological characterization of four new linear cationic alpha-helical peptides from the venoms of two solitary eumenine wasps. Toxicon 2011, 57, 1081–1092. [Google Scholar] [CrossRef] [PubMed]
  5. Konno, K.; Hisada, M.; Naoki, H.; Itagaki, Y.; Fontana, R.; Rangel, M.; Oliveira, J.S.; Cabrera, M.P.; Neto, J.R.; Hide, I.; et al. Eumenitin, a novel antimicrobial peptide from the venom of the solitary eumenine wasp Eumenes rubronotatus. Peptides 2006, 27, 2624–2631. [Google Scholar] [CrossRef]
  6. Baek, J.H.; Ji, Y.; Shin, J.S.; Lee, S.; Lee, S.H. Venom peptides from solitary hunting wasps induce feeding disorder in lepidopteran larvae. Peptides 2011, 32, 568–572. [Google Scholar] [CrossRef]
  7. Konno, K.; Kazuma, K.; Rangel, M.; Stolarz-de-Oliveira, J.; Fontana, R.; Kawano, M.; Fuchino, H.; Hide, I.; Yasuhara, T.; Nakata, Y. New Mastoparan Peptides in the Venom of the Solitary Eumenine Wasp Eumenes micado. Toxins 2019, 11, 155. [Google Scholar] [CrossRef]
  8. Silva, O.N.; Torres, M.D.T.; Cao, J.; Alves, E.S.F.; Rodrigues, L.V.; Resende, J.M.; Liao, L.M.; Porto, W.F.; Fensterseifer, I.C.M.; Lu, T.K.; et al. Repurposing a peptide toxin from wasp venom into antiinfectives with dual antimicrobial and immunomodulatory properties. Proc. Natl. Acad. Sci. USA 2020, 117, 26936–26945. [Google Scholar] [CrossRef]
  9. King, T.P.; Jim, S.Y.; Wittkowski, K.M. Inflammatory role of two venom components of yellow jackets (Vespula vulgaris): A mast cell degranulating peptide mastoparan and phospholipase A1. Int. Arch. Allergy Immunol. 2003, 131, 25–32. [Google Scholar] [CrossRef]
  10. Chen, W.; Yang, X.; Yang, X.; Zhai, L.; Lu, Z.; Liu, J.; Yu, H. Antimicrobial peptides from the venoms of Vespa bicolor Fabricius. Peptides 2008, 29, 1887–1892. [Google Scholar] [CrossRef]
  11. Henriksen, J.R.; Etzerodt, T.; Gjetting, T.; Andresen, T.L. Side chain hydrophobicity modulates therapeutic activity and membrane selectivity of antimicrobial peptide mastoparan-X. PLoS ONE 2014, 9, e91007. [Google Scholar] [CrossRef] [PubMed]
  12. Lin, C.H.; Tzen, J.T.; Shyu, C.L.; Yang, M.J.; Tu, W.C. Structural and biological characterization of mastoparans in the venom of Vespa species in Taiwan. Peptides 2011, 32, 2027–2036. [Google Scholar] [CrossRef] [PubMed]
  13. Argiolas, A.; Pisano, J.J. Isolation and characterization of two new peptides, mastoparan C and crabrolin, from the venom of the European hornet, Vespa crabro. J. Biol. Chem. 1984, 259, 10106–10111. [Google Scholar] [CrossRef]
  14. Tuichibaev, M.U.; Akhmedova, N.U.; Kazakov, I.; Korneev, A.S.; Gagel’gans, A.I. Low molecular weight peptides from the venom of the giant hornet Vespa orientalis. Structure and function. Biokhimiia 1988, 53, 219–226. [Google Scholar]
  15. Nakao, S.; Komagoe, K.; Inoue, T.; Katsu, T. Comparative study of the membrane-permeabilizing activities of mastoparans and related histamine-releasing agents in bacteria, erythrocytes, and mast cells. Biochim. Biophys. Acta 2011, 1808, 490–497. [Google Scholar] [CrossRef]
  16. Rungsa, P.; Peigneur, S.; Jangpromma, N.; Klaynongsruang, S.; Tytgat, J.; Daduang, S. In Silico and In Vitro Structure-Activity Relationship of Mastoparan and Its Analogs. Molecules 2022, 27, 561. [Google Scholar] [CrossRef] [PubMed]
  17. Baek, J.H.; Oh, J.H.; Kim, Y.H.; Lee, S.H. Comparative transcriptome analysis of the venom sac and gland of social wasp Vespa tropica and solitary wasp Rhynchium brunneum. J. Asia-Pac. Entomol. 2013, 16, 497–502. [Google Scholar] [CrossRef]
  18. Xu, X.; Li, J.; Lu, Q.; Yang, H.; Zhang, Y.; Lai, R. Two families of antimicrobial peptides from wasp (Vespa magnifica) venom. Toxicon 2006, 47, 249–253. [Google Scholar] [CrossRef]
  19. Yang, X.; Wang, Y.; Lee, W.H.; Zhang, Y. Antimicrobial peptides from the venom gland of the social wasp Vespa tropica. Toxicon 2013, 74, 151–157. [Google Scholar] [CrossRef]
  20. Goncalves, J.; Rangel, M.; Biolchi, A.; Alves, E.; Moreira, K.; Silva, L.; Mortari, M. Antinociceptive properties of the mastoparan peptide Agelaia-MPI isolated from social wasps. Toxicon 2016, 120, 15–21. [Google Scholar] [CrossRef]
  21. Baptista-Saidemberg, N.B.; Saidemberg, D.M.; Palma, M.S. Profiling the peptidome of the venom from the social wasp Agelaia pallipes pallipes. J. Proteom. 2011, 74, 2123–2137. [Google Scholar] [CrossRef] [PubMed]
  22. Cerovsky, V.; Slaninova, J.; Fucik, V.; Hulacova, H.; Borovickova, L.; Jezek, R.; Bednarova, L. New potent antimicrobial peptides from the venom of Polistinae wasps and their analogs. Peptides 2008, 29, 992–1003. [Google Scholar] [CrossRef] [PubMed]
  23. Mendes, M.A.; de Souza, B.M.; Palma, M.S. Structural and biological characterization of three novel mastoparan peptides from the venom of the neotropical social wasp Protopolybia exigua (Saussure). Toxicon 2005, 45, 101–106. [Google Scholar] [CrossRef] [PubMed]
  24. de Souza, B.M.; Dos Santos Cabrera, M.P.; Neto, J.R.; Palma, M.S. Investigating the effect of different positioning of lysine residues along the peptide chain of mastoparans for their secondary structures and biological activities. Amino Acids 2011, 40, 77–90. [Google Scholar] [CrossRef]
  25. Souza, B.M.; Mendes, M.A.; Santos, L.D.; Marques, M.R.; Cesar, L.M.; Almeida, R.N.; Pagnocca, F.C.; Konno, K.; Palma, M.S. Structural and functional characterization of two novel peptide toxins isolated from the venom of the social wasp Polybia paulista. Peptides 2005, 26, 2157–2164. [Google Scholar] [CrossRef]
  26. de Souza, B.M.; Marques, M.R.; Tomazela, D.M.; Eberlin, M.N.; Mendes, M.A.; Palma, M.S. Mass spectrometric characterization of two novel inflammatory peptides from the venom of the social wasp Polybia paulista. Rapid Commun. Mass Spectrom. 2004, 18, 1095–1102. [Google Scholar] [CrossRef]
  27. Ribeiro, S.P.; Mendes, M.A.; Dos Santos, L.D.; de Souza, B.M.; Marques, M.R.; de Azevedo, W.F., Jr.; Palma, M.S. Structural and functional characterization of N-terminally blocked peptides isolated from the venom of the social wasp Polybia paulista. Peptides 2004, 25, 2069–2078. [Google Scholar] [CrossRef]
  28. Dias, N.B.; de Souza, B.M.; Gomes, P.C.; Brigatte, P.; Palma, M.S. Peptidome profiling of venom from the social wasp Polybia paulista. Toxicon 2015, 107, 290–303. [Google Scholar] [CrossRef]
  29. Cerovsky, V.; Pohl, J.; Yang, Z.; Alam, N.; Attygalle, A.B. Identification of three novel peptides isolated from the venom of the neotropical social wasp Polistes major major. J. Pept. Sci. 2007, 13, 445–450. [Google Scholar] [CrossRef]
  30. Raynor, R.L.; Kim, Y.S.; Zheng, B.; Vogler, W.R.; Kuo, J.F. Membrane interactions of mastoparan analogues related to their differential effects on protein kinase C, Na, K-ATPase and HL60 cells. FEBS Lett. 1992, 307, 275–279. [Google Scholar] [CrossRef]
  31. Turillazzi, S.; Mastrobuoni, G.; Dani, F.R.; Moneti, G.; Pieraccini, G.; la Marca, G.; Bartolucci, G.; Perito, B.; Lambardi, D.; Cavallini, V.; et al. Dominulin A and B: Two new antibacterial peptides identified on the cuticle and in the venom of the social paper wasp Polistes dominulus using MALDI-TOF, MALDI-TOF/TOF, and ESI-ion trap. J. Am. Soc. Mass Spectrom. 2006, 17, 376–383. [Google Scholar] [CrossRef] [PubMed]
  32. Murata, K.; Shinada, T.; Ohfune, Y.; Hisada, M.; Yasuda, A.; Naoki, H.; Nakajima, T. Novel biologically active peptides from the venom of Polistes rothneyi iwatai. Biol. Pharm. Bull. 2006, 29, 2493–2497. [Google Scholar] [CrossRef] [PubMed]
  33. Herrera, C.; Leza, M.; Martinez-Lopez, E. Diversity of compounds in Vespa spp. venom and the epidemiology of its sting: A global appraisal. Arch. Toxicol. 2020, 94, 3609–3627. [Google Scholar] [CrossRef] [PubMed]
  34. Sahiner, U.M.; Durham, S.R. Hymenoptera Venom Allergy: How Does Venom Immunotherapy Prevent Anaphylaxis From Bee and Wasp Stings? Front. Immunol. 2019, 10, 1959. [Google Scholar] [CrossRef] [PubMed]
  35. da Silva, A.V.; De Souza, B.M.; Dos Santos Cabrera, M.P.; Dias, N.B.; Gomes, P.C.; Neto, J.R.; Stabeli, R.G.; Palma, M.S. The effects of the C-terminal amidation of mastoparans on their biological actions and interactions with membrane-mimetic systems. Biochim. Biophys. Acta 2014, 1838, 2357–2368. [Google Scholar] [CrossRef]
  36. dos Santos, L.D.; Aparecido dos Santos Pinto, J.R.; Menegasso, A.R.; Saidemberg, D.M.; Caviquioli Garcia, A.M.; Palma, M.S. Proteomic profiling of the molecular targets of interactions of the mastoparan peptide Protopolybia MP-III at the level of endosomal membranes from rat mast cells. Proteomics 2012, 12, 2682–2693. [Google Scholar] [CrossRef]
  37. Crooks, G.E.; Hon, G.; Chandonia, J.M.; Brenner, S.E. WebLogo: A sequence logo generator. Genome Res. 2004, 14, 1188–1190. [Google Scholar] [CrossRef]
  38. Zhou, X.; Zheng, W.; Li, Y.; Pearce, R.; Zhang, C.; Bell, E.W.; Zhang, G.; Zhang, Y. I-TASSER-MTD: A deep-learning-based platform for multi-domain protein structure and function prediction. Nat. Protoc. 2022, 17, 2326–2353. [Google Scholar] [CrossRef]
  39. Kanehisa, M. Grand challenges in bioinformatics. Bioinformatics 1998, 14, 309. [Google Scholar] [CrossRef]
Toxins 15 00331 g001 550
Figure 1. The constitution of mastoparans from different wasp species and families in the wasp mastoparans library. (A) The number of mastoparans from wasp species in five wasp families. (B) Statistical analysis of the proportion and number of mastoparans from each wasp species.
Figure 1. The constitution of mastoparans from different wasp species and families in the wasp mastoparans library. (A) The number of mastoparans from wasp species in five wasp families. (B) Statistical analysis of the proportion and number of mastoparans from each wasp species.
Toxins 15 00331 g001
Toxins 15 00331 g002 550
Figure 2. Classification of mastoparan family peptides from wasp venoms according to the different subfamilies. The amino acid sequence alignments of mastoparans using the WebLogo generator. (A) The amino acid consensus sequence of 55 mastoparans; (B) the subfamily classification of 55 mastoparans; (CF) the amino acid consensus sequence of Subfamilies 1, 2, 3, and 4; the overall height in the graph of each stack indicates the sequence conservation at that position (measured in bits), and the height of the symbols within the stack reflects the relative frequency of the corresponding amino acid at that position.
Figure 2. Classification of mastoparan family peptides from wasp venoms according to the different subfamilies. The amino acid sequence alignments of mastoparans using the WebLogo generator. (A) The amino acid consensus sequence of 55 mastoparans; (B) the subfamily classification of 55 mastoparans; (CF) the amino acid consensus sequence of Subfamilies 1, 2, 3, and 4; the overall height in the graph of each stack indicates the sequence conservation at that position (measured in bits), and the height of the symbols within the stack reflects the relative frequency of the corresponding amino acid at that position.
Toxins 15 00331 g002
Toxins 15 00331 g003 550
Figure 3. Characterization of the degranulation activity of six representative wasp mastoparan peptides with high activity in RBL-2H3 cells. (AF) Curve of RBL-2H3 cell degranulation induced by Agelaia-MPI, Polybia-MPII, Pm-R3, Protopolybia-MPIII, Mastoparan(-L), and EpVP2b. Curves were generated in SigmaPlot 12.5 software, and EC50 values were calculated according to the following equation (Four-Parameter Logistic Curve): y = min + (max − min)/(1 + (x/EC50) − Hillslope).
Figure 3. Characterization of the degranulation activity of six representative wasp mastoparan peptides with high activity in RBL-2H3 cells. (AF) Curve of RBL-2H3 cell degranulation induced by Agelaia-MPI, Polybia-MPII, Pm-R3, Protopolybia-MPIII, Mastoparan(-L), and EpVP2b. Curves were generated in SigmaPlot 12.5 software, and EC50 values were calculated according to the following equation (Four-Parameter Logistic Curve): y = min + (max − min)/(1 + (x/EC50) − Hillslope).
Toxins 15 00331 g003
Toxins 15 00331 g004 550
Figure 4. Characterization of degranulation activity and statistical analysis. (A) Statistical analysis of the proportion and number of 55 mastoparan family peptides from different wasp species with different degranulation activities in RBL-2H3 cells. (B) Statistical analysis of the proportion and number of 55 mastoparan family peptides from different subfamilies.
Figure 4. Characterization of degranulation activity and statistical analysis. (A) Statistical analysis of the proportion and number of 55 mastoparan family peptides from different wasp species with different degranulation activities in RBL-2H3 cells. (B) Statistical analysis of the proportion and number of 55 mastoparan family peptides from different subfamilies.
Toxins 15 00331 g004
Toxins 15 00331 g005 550
Figure 5. Structure–activity relationship analyses of wasp mastoparan peptides from Subfamily 1 in mast cell degranulation. (A) Multiple amino acid sequence alignment analysis of Subfamily 1; mastoparans labeled with red (high degranulation activity), blue (modest degranulation activity), and black (low degranulation activity). Amino acid residues were marked with dark blue (100% identity), pink (>75% identity), light blue (>50% identity), and blank (<50% identity); (B) helical wheel projections of a representative of Subfamily 2 (Agelaia-MPII).
Figure 5. Structure–activity relationship analyses of wasp mastoparan peptides from Subfamily 1 in mast cell degranulation. (A) Multiple amino acid sequence alignment analysis of Subfamily 1; mastoparans labeled with red (high degranulation activity), blue (modest degranulation activity), and black (low degranulation activity). Amino acid residues were marked with dark blue (100% identity), pink (>75% identity), light blue (>50% identity), and blank (<50% identity); (B) helical wheel projections of a representative of Subfamily 2 (Agelaia-MPII).
Toxins 15 00331 g005
Toxins 15 00331 g006 550
Figure 6. Structure–activity relationship analysis of wasp mastoparan peptides from Subfamily 2 in mast cell degranulation. (A) Multiple amino acid sequence alignment analysis of Subfamily 2; mastoparans labeled with red (high degranulation activity), blue (modest degranulation activity), and black (low degranulation activity); amino acid residues were marked with dark blue (100% identity), pink (>75% identity), and blank (<50% identity). (B) The exhibition of the PDB structure of Mastoparan L. (C) Helical wheel projection of a representative of Subfamily 2 (Mastoparan L). (D) The exhibition of side chain of amino acid residues at sites 3, 5, 6, 9, 10, and 13 of Mastoparan (L).
Figure 6. Structure–activity relationship analysis of wasp mastoparan peptides from Subfamily 2 in mast cell degranulation. (A) Multiple amino acid sequence alignment analysis of Subfamily 2; mastoparans labeled with red (high degranulation activity), blue (modest degranulation activity), and black (low degranulation activity); amino acid residues were marked with dark blue (100% identity), pink (>75% identity), and blank (<50% identity). (B) The exhibition of the PDB structure of Mastoparan L. (C) Helical wheel projection of a representative of Subfamily 2 (Mastoparan L). (D) The exhibition of side chain of amino acid residues at sites 3, 5, 6, 9, 10, and 13 of Mastoparan (L).
Toxins 15 00331 g006
Toxins 15 00331 g007 550
Figure 7. Structure–activity relationship analyses of wasp mastoparan peptides from Subfamily 3 in mast cell degranulation. (A) Multiple amino acid sequence alignment analysis of Subfamily 3; mastoparans labeled with red (high degranulation activity), blue (modest degranulation activity), and black (low degranulation activity). Amino acid residues were marked with dark blue (100% identity), pink (>75% identity), light blue (>50% identity), and blank (<50% identity). (B) Helical wheel projection of a representative of Subfamily 3 (Agelaia-MPI). (C) The exhibition of the PDB structure of Agelaia-MPI.
Figure 7. Structure–activity relationship analyses of wasp mastoparan peptides from Subfamily 3 in mast cell degranulation. (A) Multiple amino acid sequence alignment analysis of Subfamily 3; mastoparans labeled with red (high degranulation activity), blue (modest degranulation activity), and black (low degranulation activity). Amino acid residues were marked with dark blue (100% identity), pink (>75% identity), light blue (>50% identity), and blank (<50% identity). (B) Helical wheel projection of a representative of Subfamily 3 (Agelaia-MPI). (C) The exhibition of the PDB structure of Agelaia-MPI.
Toxins 15 00331 g007
Toxins 15 00331 g008 550
Figure 8. Structure–activity relationship analyses of wasp mastoparan peptides from Subfamily 4 in mast cell degranulation. Multiple amino acid sequence alignment analysis of Subfamily 4; mastoparans labeled with red (high degranulation activity), blue (modest degranulation activity), and black (low degranulation activity); amino acid residues were marked with dark blue (100% identity), pink (>75% identity), light blue (>50% identity), and blank (<50% identity). (A) Multiple sequence alignment analysis of Subfamily 4. (B) Helical wheel projections of a representative of Subfamily 4 (EpVP2a). (C) The exhibition of the PDB structure of EpVP2a.
Figure 8. Structure–activity relationship analyses of wasp mastoparan peptides from Subfamily 4 in mast cell degranulation. Multiple amino acid sequence alignment analysis of Subfamily 4; mastoparans labeled with red (high degranulation activity), blue (modest degranulation activity), and black (low degranulation activity); amino acid residues were marked with dark blue (100% identity), pink (>75% identity), light blue (>50% identity), and blank (<50% identity). (A) Multiple sequence alignment analysis of Subfamily 4. (B) Helical wheel projections of a representative of Subfamily 4 (EpVP2a). (C) The exhibition of the PDB structure of EpVP2a.
Toxins 15 00331 g008
Toxins 15 00331 g009 550
Figure 9. Structure–activity relationship analyses of the effects of two mastoparan wasp peptides, Protopolybia-MPIII and Protopolybia-MPI, on mast cell degranulation. (A) The helical wheel projections and PDB structures of Protopolybia-MPIII and Protopolybia-MPI. (B) Mutation of a representative member (Protopolybia-MPIII) of Subfamily 3. * and red box: The different amino acids between Protopolybia-MPIII and Protopolybia-MPI.
Figure 9. Structure–activity relationship analyses of the effects of two mastoparan wasp peptides, Protopolybia-MPIII and Protopolybia-MPI, on mast cell degranulation. (A) The helical wheel projections and PDB structures of Protopolybia-MPIII and Protopolybia-MPI. (B) Mutation of a representative member (Protopolybia-MPIII) of Subfamily 3. * and red box: The different amino acids between Protopolybia-MPIII and Protopolybia-MPI.
Toxins 15 00331 g009
Table
Table 1. The physical property of 55 wasp mastoparans according to different subfamilies and species studied.
Table 1. The physical property of 55 wasp mastoparans according to different subfamilies and species studied.
FamilyWasp SpeciesPeptidesSequencez a<H> b<μH> caa dMr eRef
EumenidaeAnterhynchium flavormarginatum micadoEMP-AFINLLKIAKGIIKSL-NH2+40.6430.559141522.97[3]
Eumenes fraterculusEumenine mastoparan-EFFDVMGIIKKIASAL-NH2+20.6550.489141504.88[4]
Eumenes rubrofemoratusEumenine mastoparan-ERFDIMGLIKKVAGAL-NH2+20.6510.493141475.85[4]
Eumenes rubronotatusEumenitin-RLNLKGLIKKVASLLN *+30.5080.498151624.04[4]
Eumenitin-FLNLKGLFKKVASLLT *+30.5650.461151645.06[4]
EumenitinLNLKGIFKKVASLLT *+30.5710.465151645.06[5]
Eumenes pomiformisEpVP1INLKGLIKKVASLLT *+30.5720.455151611.04[6]
EpVP2aFDLLGLVKKVASAL-NH2+20.6330.457141472.82[6]
EpVP2bFDLLGLVKSVVSAL-NH2+10.7660.439141459.78[6]
Eumenes micadoEMP-EM1LKLMGIVKKVLGAL-NH2+40.6860.520141481.97[7]
EMP-EM2LKLLGIVKKVLGAI-NH2+40.7270.540141463.94[7]
Orancistrocerus drewseniEMP-OD (OdVP1)GRILSFIKGLAEHL-NH2+20.5890.632141552.87[6]
OdVP3aKDLHTVVSAILQAL-NH2+10.5950.562141506.79[6]
VespidaeVespula lewisiiMastoparan (L)INLKALAALAKKIL-NH2+40.5760.398141478.91[8]
Vespula vulgarisMastoparan-V1INWKKIKSIIKAAMN-NH2+50.4070.428151757.20[9]
Mastoparan-V2INWKKIKSLIKAAMS-NH2+50.4370.388151730.17[9]
Vespa bicolorMP-VB1INMKASAAVAKKLL-NH2+40.3770.234141457.84[10]
MP-VB2INMKAVAAVAKKPL-NH2+40.3970.261141452.85[10]
Vespa xanthopteraMastoparan-X(V)INWKGIAAMAKKLL-NH2+40.5600.419141555.97[11]
Vespa analisMastoparan-AIKWKAILDAVKKVL-NH2+40.5410.538141624.07[12]
Vespa basalisMastoparan-BLKLKSIVSWAKKVL-NH2+50.4610.404141624.07[12]
Vespa crabroMastoparan-CINLKALLAVAKKIL-NH2+50.6410.392141506.97[13]
Vespa orientalisMastoparan-IIINLKALAALVKKVL-NH2+40.6000.416141492.94[14]
HR1INLKAIAALVKKVL-NH2+40.6070.423141492.94[15]
Vespa tropicaMastoparan-T(D)INLKAIAAFAKKLL-NH2+40.5830.402141512.93[16]
Mastoparan-T1INLKVFAALVKKFL-NH2+40.7120.442141603.05[17]
Mastoparan-T2INLKVFAALVKKLL-NH2+40.7060.436141569.04[17]
Mastoparan-T3INLRGFAALVKKFL-NH2+40.6240.466141588.99[17]
Mastoparan-T4INLFGFAALVKKFL-NH2+30.8240.310141579.98[17]
Vespa magnificaMastoparan-like Peptide 12bINWKGIAAMKKLL-NH2+40.5790.348131484.89[18]
Vespa mandariniaMastoparan-MINLKAIAALAKKLL-NH2+40.5760.399141478.91[19]
Vespa affinisMastoparan AFINLKAIAALAKKLF-NH2+40.5830.400141512.93[12]
Agelaia pallipes pallipesAgelaia MP-IINWLKLGKAIIDAL-NH2+20.7160.538141566.93[20]
Agelaia MP-IIINWKAILQRIKKML-NH2+50.5560.568141754.24[21]
Mischocyttarus phthisicusMPINWLKLGKKMMSAL-NH2+40.5940.510141632.09[22]
PolybiidaeProtopolybia exiguaProtopolybia-MP IINWLKLGKKVSAIL-NH2+50.6340.439141581.99[23]
Protopolybia-MP IIINWKAIIEAAKQAL-NH2+20.5110.389141567.88[23]
Protopolybia-MP IIIINWLKLGKAVIDAL-NH2+20.6740.506141552.91[23]
Protonectarina sylveiraeProtonectarina-MPINWKALLDAAKKVL-NH2+30.4970.474141581.95[24]
PolybiapaulistaPolybia-MP IIDWKKLLDAAKQIL-NH2+20.4890.511141654.01[25]
Polybia-MP IIINWLKLGKMVIDAL-NH2+20.7400.457141613.02[26]
Polybia-MP IIIIDWLKLGKMVMDVL-NH2+10.7520.448141660.09[27]
Polybia-MP IVIDWLKLRVISVIDL-NH2+10.8290.222141682.07[28]
Polybia-MP VINWHDIAIKNIDAL-NH200.5840.420141634.88[28]
Parapolybia indicaParapolybia-MPINWKKMAATALKMI-NH2+40.5450.412141618.06[24]
PolistidaePolistes dorsalisPDD-AINWKKIFQKVKNLV-NH2+50.4570.565141757.18[22]
PDD-BINWLKLGKKILGAL-NH2+50.6710.555141565.99[22]
Polistes major majorPMM2INWKKIASIGKEVLKAL-NH2+40.4500.499171910.36[29]
Polistes jadwigaeMastoparan-JVDWKKIGQHILSVL-NH2+20.6290.519141634.97[30]
Polistes dominulusDominulin AINWKKIAEVGGKILSSL-NH2+30.4880.493171855.24[31]
Dominulin BINWKKIAEIGKQVLSAL-NH2+30.4950.462171910.32[31]
Polistes rothneyi iwataiPm-R1INWLKLGKKILGAI-NH2+40.6780.563141565.99[32]
Pm-R2LNFKALAALAKKIL-NH2+40.5760.408141512.93[32]
Pm-R3INWLKLGKQILGAL-NH2+30.7260.511141565.95[32]
RopalidiidaeRopalidiaRopalidia-MPINWAKLGKLALQAL-NH2+30.6410.340141537.90[23]
a: net charges were measured at pH 7.4; b. <H>: mean hydrophobicity value represents the sum of all residue hydrophobicity indices divided by the number of residues; c. <μH>: the hydrophobic moment of each peptide is a value that is relative to the hydrophobic moment of the peptide with perfect amphipathicity; d. aa: amino acids; e. Mr: relative molecular mass of the peptides was measured by mass spectrometry; *. the peptides without amidation at C-terminal.
Table
Table 2. The degranulatory activity of 55 mastoparans from wasp venom in RBL-2H3 and P815 cell lines.
Table 2. The degranulatory activity of 55 mastoparans from wasp venom in RBL-2H3 and P815 cell lines.
MastoparansRBL-2H3RBL-2H3P815
EC50 (μg/mL)EC50 (μM)R2Degranulation at 80 μg/mLDegranulation at 80 μg/mL
Agelaia-MPI8.22 ± 1.365.25 ± 0.870.985100%68%
Polybia-MPII10.96 ± 0.656.79 ± 0.400.99798%91%
Pm-R311.89 ± 1.197.60 ± 0.760.99688%61%
Mastoparan-AF27.44 ± 5.9518.13 ± 3.940.98670%28%
Mastoparan-T428.77 ± 5.5518.21 ± 3.520.98487%49%
PDD-B33.95 ± 5.9221.68 ± 3.780.99477%37%
Protopolybia-MPIII34.90 ± 4.6022.47 ± 2.960.98497%56%
Pm-R135.94 ± 7.4722.95 ± 4.770.99276%33%
EMP-EF37.80 ± 2.4025.12 ± 1.590.99782%39%
EpVP2b37.86 ± 4.2025.93 ± 2.880.98996%65%
Mastoparan-T238.02 ± 12.3824.23 ± 7.890.97176%29%
Polybia-MPI38.34 ± 3.4623.18 ± 2.090.99775%44%
Mastoparan-A46.18 ± 2.5228.43 ± 1.550.99972%41%
EpVP2a46.58 ± 6.3531.63 ± 4.310.98770%30%
Mastoparan-C49.19 ± 12.9032.64 ± 8.560.97958%35%
Ropalidia-MP50.68 ± 8.9132.95 ± 5.790.99368%21%
Mastoparan-T151.48 ± 16.0832.11 ± 10.030.97464%58%
Agelaia-MPII60.88 ± 15.8434.71 ± 9.030.98459%27%
Mastoparan-J60.92 ± 8.3937.26 ± 5.130.98557%31%
PMM269.93 ± 8.8136.60 ± 4.610.99955%22%
HR172.86 ± 5.3348.80 ± 3.570.99852%32%
Protonectarina-MP73.43 ± 4.9046.42 ± 3.100.99752%30%
Mastoparan(-L)77.09 ± 4.7452.13 ± 3.210.99651%24%
Mastoparan-II87.62 ± 37.0358.69 ± 24.800.98150%28%
EMP-EM2106.57 ± 28.9972.80 ± 19.800.99445%<20%
MP109.03 ± 50.0666.80 ± 30.670.97335%<20%
EMP-ER112.43 ± 8.5876.18 ± 5.810.99932%<20%
PDD-A115.53 ± 34.3165.75 ± 19.520.99238%<20%
EMP-AF117.13 ± 29.9076.91 ± 19.640.99439%<20%
Protopolybia-MPII122.06 ± 14.2477.85 ± 9.080.99928%<20%
Mastoparan-X(V)122.54 ± 23.3078.75 ± 14.970.99737%<20%
Pm-R2143.4 ± 111.2494.79 ± 73.520.98643%<20%
Parapolybia-MP144.60 ± 32.2089.36 ± 19.900.99631%<20%
Dominulin B148.45 ± 51.3194.80 ± 32.770.99624%<20%
MP-V2153.7 ± 106.088.86 ± 61.290.97633%<20%
Protopolybia-MPI184.71 ± 60.59116.76 ± 38.300.99530%<20%
Polybia-MPIII188.6 ± 98.37113.62 ± 59.260.98829%<20%
Mastoparan-B203.9 ± 110.9125.58 ± 68.270.98929%<20%
Mastoparan-T209.0 ± 103.6138.15 ± 68.440.99128%<20%
MP-V1228.86 ± 81.81130.24 ± 46.560.99828%<20%
EpVP1275.81 ± 124.37171.20 ± 77.200.99630%<20%
MP-EM1291.47 ± 243.29196.68 ± 164.20.99644%<20%
Eumenitin-R>300>200-14%<20%
Dominulin A>300>200-11%<20%
Mastoparan-like peptide 12b>300>200-11%<20%
Mastoparan-M>300>200-10%<20%
Eumenitin>300>200-8%<20%
Polybia-MPIV>300>200-6%<20%
OdVP3>300>200-5%<20%
EMP-OD>300>200-4%<20%
Polybia-MPV>300>200-1%<20%
Mastoparan-VB1>300>200-−1%<20%
Mastoparan-VB2>300>200-0%<20%
Eumenitin-F>300>200-2%<20%
Table
Table 3. The statistical analysis of the degranulation activity of Protopolybia-MPIII and mutations.
Table 3. The statistical analysis of the degranulation activity of Protopolybia-MPIII and mutations.
MastoparansSequencesEC50 (μg/mL)EC50 (μM)R2
Protopolybia-MP IIIINWLKLGKAVIDAL-NH233.65 ± 5.3421.67 ± 3.440.9943
Protopolybia-MPIINWLKLGKKVSAIL-NH2184.71 ± 60.59116.76 ± 38.300.995
Protopolybia-MP III-1INWLKLGKKVIDAL-NH2158.35 ± 13.5798.35 ± 8.430.9968
Protopolybia-MP III-2INWLKLGKAVSDAL-NH2294.3 ± 44.02192.77 ± 28.830.9983
Protopolybia-MP III-3INWLKLGKAVIAAL-NH223.06 ± 5.3315.28 ± 3.530.9812
Protopolybia-MP III-4INWLKLGKAVIDIL-NH244.89 ± 5.9228.14 ± 3.710.9958
Protopolybia-MP III-5INWLKLGKKVSDAL-NH2>500>325-
Protopolybia-MP III-6INWLKLGKKVIAAL-NH2108.22 ± 19.369.11 ± 12.320.9887
Protopolybia-MP III-7INWLKLGKKVIDIL-NH241.62 ± 2.5725.19 ± 1.560.998
Protopolybia-MP III-8INWLKLGKAVSAAL-NH2206.95 ± 10.47139.56 ± 7.060.9991
Protopolybia-MP III-9INWLKLGKAVSDIL-NH277.82 ± 2.7149.6 ± 1.730.9993
Protopolybia-MP III-10INWLKLGKAVIAIL-NH213.02 ± 1.448.39 ± 0.930.998
Protopolybia-MP III-11INWLKLGKAVSAIL-NH2>500>325-
Protopolybia-MP III-12INWLKLGKKVIAIL-NH276.73 ± 22.6647.72 ± 14.090.9584
Protopolybia-MP III-13INWLKLGKKVSDIL-NH2235.17 ± 39.62144.63 ± 24.370.9953
Protopolybia-MP III-14INWLKLGKKVSAAL-NH2>500>325-
Disclaimer/Publisher’s Note: The statements, opinions and data contained in all publications are solely those of the individual author(s) and contributor(s) and not of MDPI and/or the editor(s). MDPI and/or the editor(s) disclaim responsibility for any injury to people or property resulting from any ideas, methods, instructions or products referred to in the content.

Share and Cite

MDPI and ACS Style

Ye, X.; Liu, X.; Luo, X.; Sun, F.; Qin, C.; Ding, L.; Zhu, W.; Zhang, H.; Zhou, H.; Chen, Z. Characterization of the Molecular Diversity and Degranulation Activity of Mastoparan Family Peptides from Wasp Venoms. Toxins 2023, 15, 331. https://doi.org/10.3390/toxins15050331

AMA Style

Ye X, Liu X, Luo X, Sun F, Qin C, Ding L, Zhu W, Zhang H, Zhou H, Chen Z. Characterization of the Molecular Diversity and Degranulation Activity of Mastoparan Family Peptides from Wasp Venoms. Toxins. 2023; 15(5):331. https://doi.org/10.3390/toxins15050331

Chicago/Turabian Style

Ye, Xiangdong, Xin Liu, Xudong Luo, Fang Sun, Chenhu Qin, Li Ding, Wen Zhu, Huajun Zhang, Haimei Zhou, and Zongyun Chen. 2023. "Characterization of the Molecular Diversity and Degranulation Activity of Mastoparan Family Peptides from Wasp Venoms" Toxins 15, no. 5: 331. https://doi.org/10.3390/toxins15050331

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop