Next Article in Journal
mRNA Interferase Bacillus cereus BC0266 Shows MazF-Like Characteristics Through Structural and Functional Study
Next Article in Special Issue
A Role of Newly Found Auxiliary Site in Phospholipase A1 from Thai Banded Tiger Wasp (Vespa affinis) in Its Enzymatic Enhancement: In Silico Homology Modeling and Molecular Dynamics Insights
Previous Article in Journal
Harmful Algal Bloom Toxicity in Lithobates catesbeiana Tadpoles
 
 
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Communication

Functional Profile of Antigen Specific CD4+ T Cells in the Immune Response to Phospholipase A1 Allergen from Polybia paulista Venom

by
Luís Gustavo Romani Fernandes
1,*,
Amilcar Perez-Riverol
2,
Murilo Luiz Bazon
3,
Débora Moitinho Abram
1,
Márcia Regina Brochetto-Braga
3,4 and
Ricardo de Lima Zollner
1
1
Laboratory of Translational Immunology, Medicine School, FCM, University of Campinas (UNICAMP), Campinas 13083-888, Brazil
2
Center of the Study of Social Insects, Department of General and Applied Biology, Institute of Biosciences of Rio Claro, Institute of Biosciences of Rio Claro, São Paulo State University, Rio Claro 13500, Brazil
3
Laboratory of Arthropods Molecular Biology - LBMA-IBRC-UNESP (São Paulo State University), Rio Claro 13506-900, Brazil
4
Venoms and Venomous Animal Studies Center-CEVAP, São Paulo State University (UNESP), Botucatu 18610-307, Brazil
*
Author to whom correspondence should be addressed.
Toxins 2020, 12(6), 379; https://doi.org/10.3390/toxins12060379
Submission received: 25 March 2020 / Revised: 3 April 2020 / Accepted: 6 April 2020 / Published: 8 June 2020
(This article belongs to the Special Issue Application of Venom Phospholipase in the Treatment of Diseases)

Abstract

:
Insect venom can cause systemic allergic reactions, including anaphylaxis. Improvements in diagnosis and venom immunotherapy (VIT) are based on a better understanding of an immunological response triggered by venom allergens. Previously, we demonstrated that the recombinant phospholipase A1 (rPoly p 1) from Polybia paulista wasp venom induces specific IgE and IgG antibodies in sensitized mice, which recognized the native allergen. Here, we addressed the T cell immune response of rPoly p 1-sensitized BALB/c mice. Cultures of splenocytes were stimulated with Polybia paulista venom extract and the proliferation of CD8+ and CD4+ T cells and the frequency of T regulatory cells (Tregs) populations were assessed by flow cytometry. Cytokines were quantified in cell culture supernatants in ELISA assays. The in vitro stimulation of T cells from sensitized mice induces a significant proliferation of CD4+ T cells, but not of CD8+ T cells. The cytokine pattern showed a high concentration of IFN-γ and IL-6, and no significant differences to IL-4, IL-1β and TGF-β1 production. In addition, the rPoly p 1 group showed a pronounced expansion of CD4+CD25+FoxP3+ and CD4+CD25-FoxP3+ Tregs. rPoly p 1 sensitization induces a Th1/Treg profile in CD4+ T cell subset, suggesting its potential use in wasp venom immunotherapy.
Key Contribution: To our knowledge, this is the first report on the evaluation of the cellular response and the induction of a specific functional profile of antigen-stimulated CD4+ T cells by a venom allergen from a clinically relevant Neotropical wasp.

1. Introduction

Insect sting allergy accounts for 14% of severe cases of allergic reactions in Latin America, resulting in considerable morbidity and significant expenses for the treatment of patients [1]. The most clinically relevant venom allergies involve the Hymenoptera order such as bees (Apoidea), wasps (Vespoidea) and ants (Formicidae) [2]. Polybia paulista (Hymenoptera: Polistinae), also known as the Southern American paper wasp, is one of the 320 neotropical social wasp species in Brazil, located mainly in the southeastern region. It presents a highly aggressive behavior and is related to most cases of allergic reactions, including anaphylaxis, involving wasp sting accidents in this region [3]. Similarly to other clinically relevant insects, the venom of P. paulista is a complex mix of low molecular weight compounds, linear polycationic peptides and allergens [4]. While small compounds and peptides are involved in toxic and local reactions, venom allergens often cause moderate to severe systemic hypersensitivity reactions, including life-threatening anaphylaxis.
The aetiology of the allergic response is complex and influenced by several factors, including genetic susceptibility, the route of exposure and allergen doses, and, in some cases, the structural feature of the molecule itself [5]. In this sense, the molecular and immunological characterization of the majority allergens from Hymenoptera’s venom is intensive [6]. These investigations provided the basis for the production of recombinant allergens, which could improve the Hymenoptera’s venom allergy diagnosis, such as the Component-Resolved Diagnosis (CRD), and reduction in the risk of anaphylactic reactions in allergen-based immunotherapy (AIT) protocols [7].
In recent years, the use of traditional and advanced proteomic approaches, bioinformatic tools and molecular biology techniques enabled the identification and isolation of the three major allergens from P. paulista venom: phospholipase A1 (Poly p 1) [8], hyaluronidase (Poly p 2) [9,10], and antigen 5 (Poly p 5) [11]. The PLA1 and antigen 5 are abundant, whereas hyaluronidase represents a minor venom compound. Particularly, Poly p 1 is a predominant allergen (6%–10% of venom dry weight) that shows a high sensitization prevalence in Brazilian allergic patients [12]. Insect PLA1 represents a marker allergen commonly used in component-resolved diagnosis (CRD) for the unequivocal differentiation of honeybee venom (HBV) from Vespinae or Polistinae sensitizations [13]. In addition, venom PLA1 has diagnostic value for the detection of allergic patients with negative IgE to antigen 5 [14].
Previously, we demonstrated that the expression of Poly p 1 in E. coli resulted in an immunologically active allergen. rPoly p 1 reactivity with sera from P. paulista-allergic patients was similarly compared with P. paulista venom extract and purified native Poly p 1 (nPoly p 1) [12]. Remarkably, we also showed that rPoly p 1 induces the activation of humoral response in BALB/c mice after intradermal immunization [15]. Sera from rPoly p 1-sensitized mice reacted with the native allergen as well as its homologous in venom from other clinically relevant Neotropical and European wasp. In contrast, the cellular response to the recombinant allergen remains largely unexplored. The study of the T-cell response and cytokines production triggered by rPoly p 1 could help understand the molecular mechanism involved in tolerance induction during VIT and the rational design of allergen-based treatment of allergic patients [16].
Venom immunotherapy (VIT) is the only intervention that provides long-term benefits in the management of allergic reactions caused by Hymenoptera stings [14,17]. For wasp venom allergy, subcutaneous immunotherapy (SIT) prevents the occurrence of severe reactions in 90%–95% of patients after a subsequent field insult [18]. Although SIT using venom extracts has proven to be a highly effective procedure to treat Hymenoptera venom allergy, meta-analysis studies have shown a significant risk of systemic adverse reactions outcomes [19]. The heterologous expression of allergens could be an alternative to overcome this problem and may lead to the development of personalized panels of allergens with a reduced incidence of severe adverse reactions and nonspecific sensitization during VIT [14]. The characterization of an immune response profile drive specific to these recombinant allergens is an important prerequisite for the development of novel systems for component-based treatment.
The generation of allergen-specific regulatory cells populations of T (Tregs) and B cells (Bregs), which mediate the suppression of allergen-specific T effector cells’ subsets, is critical for the success of VIT [20]. In the context of the complex system of Tregs, the CD4+ T cells expressing the transcription factor forkhead box P3 (FoxP3) are key to this effect [21,22]. The suppressive activity of Tregs in the inflammatory events of the allergic response is related to different mechanisms, such as the production of inhibitory cytokines, induction of cytolysis and metabolic disruption of effector cells, and suppression of the activation of dendritic cells (DCs) [21]. However, the immunomodulatory mechanisms elicited by VIT that are responsible for the development of tolerogenic responses to allergens remain partially unclear.
This study investigated the capability of rPoly p 1 to induce the activation of antigen-specific T cell populations in sensitized mice. Furthermore, we evaluated the functional profile of CD4+ T cell population after antigenic stimulation in vitro. rPoly p 1 was able to induce a Th1/Treg profile on the CD4+ T cell from sensitized mice, suggesting that rPoly p 1 could be a potential candidate for the development of new strategies of novel allergen-based immunotherapy for the treatment of P. paulista-sensitized patients.

2. Results

The immunogenicity of rPoly p 1 was assessed after intradermal injection in BALB/c mice (n = 6) and in vitro stimulus of spleen cells with P. paulista venom extract. We investigated the proliferation of the T cell subsets (CD4 and CD8) and the CD4+ T cell functional profile.

2.1. Antigen-Specific T Cell Proliferation

Flow cytometry analysis, using a CFSE probe and labelling with antibodies to specific surface markers, were performed to assess the antigen-specific proliferation of CD4 and CD8 T cell subsets. As demonstrated in Figure 1, we observed a significant expansion of antigen-specific CD4+ T cells (CSFElow) (panels a,b) in the rPoly p 1-sensitized mice in comparison with mice immunized with E. coli protein extract (control group) (17.83 ± 3.04% vs. 4.91 ± 0.12%, p = 0.0293). In contrast, no significant proliferation of antigen-specific CD8 T cells (panels c,d) was detected in comparison with the control (7.80 ± 1.16% vs. 5.76 ± 0.93%, p = 0.3153). These results indicate that rPoly p 1 preferentially induces the expansion of antigen-specific CD4+ T cells.

2.2. Antigen-Specific CD4+ T Cells Functional Profile

Aiming to investigate the functional profile of the antigen-specific CD4+ T cells that proliferated in response to antigenic stimulation, we conducted flow cytometry assays to evaluate the frequency of the Tregs populations CD25+FoxP3+ and CD25-FoxP3+ (Figure 2, panels b and c, respectively) and the quantification of IL-6, IFN-γ, IL-1β, IL-4 and TGF-β1 cytokines in cell culture supernatants (Table 1). As demonstrated in Figure 2, rPoly p 1-sensitized mice presented increased frequency of both Tregs subsets in comparison with control: CD25+FoxP3+ (15.99 ± 2.21% vs. 6.88 ± 1.91%; p = 0.0076—Panel b) and CD25-FoxP3+ (8.16 ± 1.86% vs. 2.03 ± 0.70%; p = 0.0225—Panel c).
The analysis of cytokine production of in vitro stimulated cells is presented in Table 1, which shows the significant production of IFN-γ and IL-6 in cultures from cells obtained from sensitized mice in comparison with the control group. However, there were no significant differences among IL-4, IL-1 and TGF-β1 productions.

3. Discussion

Venom immunotherapy is the gold standard for the long-term disease-modifying treatment of HVA allergy. Vespid VIT leads to complete protection to anaphylaxis in about 96% of allergic patients [23,24]. However, the frequency of systemic adverse events resulting from VIT ranges between 8% and 20%, as demonstrated by multicenter studies [25]. In order to improve the safety of Vespid VIT, the characterization and the heterologous expression of the major allergenic proteins from Hymenoptera´s venom represent an important alternative to obtain immunotherapeutic products with good effectiveness and minimal undesirable side effects [14].
In our previous work, we verified the heterologous production and the allergenicity of the PLA1 allergen from P. paulista wasp venom [12]. The recombinant allergen showed similar reactivity compared with native Poly p 1 and was extensively recognized in immunoblotting by the antigen-specific IgE (sIgE) presented in the serum from wasp-sensitized patients [12]. Furthermore, we showed that sIgE and sIgG in the sera from rPoly p1-sensitized mice recognized relevant epitopes of homologous PLA1 in venom of the Neotropical wasps P. lanio, P. scutellaris and P. ignobilis, Apoica pallens and Agelaia pallipes, as well as the European paper wasp P. dominula [15]. The capacity of the sera from rPoly p 1-sensitized mice to recognize the natural form of PLA1 presented in venom from other wasp species suggests that this recombinant allergen can induce specific immune response directed to the shared epitopes presented in PLA1 from different wasp species. This property suggests its potential use in VIT for patients sensitized to other wasps, even for those sensitized to species from a different habitat.
In this study, we analyzed the cellular immune response induced by rPoly p 1 sensitization, in particular the activation and the functional profile of the antigen-specific T cell subpopulations. As shown in Figure 1, there was significant activation of antigen-specific CD4+ T cell in rPoly p 1-sensitized mice in comparison with control mice. In contrast, there was no significant activation of the CD8+ population. Similar results were demonstrated using recombinant allergens from other wasp species, such as antigen 5 from Vespula vulgaris (Ves v 5) [26], and hornet (Dolichovespula maculata) hyaluronidase (Dol m 2) [27] and antigen 5 (Dol m 5) [28]. Similarly to these studies, our findings show that rPoly p 1 retains the T cell epitopes of the native counterpart (nPoly p 1) [27]. Corroborating these findings, the in vitro stimulation of human T cells obtained from allergic patients to V. vulgaris with rVes v 5 leads to the significant proliferation of specific T cell clones that expressed TCRαβ and were predominantly CD4+CD8- [29].
Since CD4+ T cells can differentiate in populations with different functional profiles, we analyzed the cytokines produced after in vitro stimulation of the cells with P. paulista venom extract. We observed that, after 96 hours of stimulation, there was an elevated production of IFN-γ but no significant production of IL-4, compared with non-sensitized mice, indicating a Th1-dominant profile in rPoly p 1 after in vitro stimulation with the antigen. Interestingly, and as mentioned before, we previously demonstrated that rPoly p 1-sensitized mice presented a significant production of sIgE and sIgG that were able to recognize Poly p 1 presented in different wasp species [15]. Corroborating these findings, Bohle et al. [29] demonstrated that the response of the antigen-specific CD4+ T cell clones of allergic patients stimulated in vitro with rVes v 5 were not a Th2 phenotype, evidenced by the non-significant production of IL-4. Furthermore, in some patients we detected a significant production of IFN-γ, although all patients of this study had a Ves v 5-specific IgE in their sera, indicating that T cell response to Hymenoptera allergens differs from the typical Th2-dominant profile observed for aeroallergens [29].
The activation of regulatory cells evolved in the suppression of T effector cells is one of the most significant events to evaluate in VIT immunotherapy [20,21]. Here, we demonstrated that rPoly p 1 sensitization induces significant increase in Tregs, represented by CD25+Foxp3+ and CD25-Foxp3+ subpopulations. Kerstan et al. [30] demonstrated that allergic patients submitted to subcutaneous VIT protocols using aluminum hydroxide-adsorbed wasp venom presented a significant activation of CD4+CD25+Foxp3+ Tregs, which, by the increase in lymph-node-homing receptors such as CD62L, CD11a and CCR7, preferentially migrates to secondary lymphoid organs to suppress T-cell effector responses. This fact could evidence the importance of this Treg population to the efficiency of VIT protocols.
Moreover, we also observed a significant increase in Foxp3+ Tregs that do not express the CD25 marker in the CD4+ T cell population from rPoly p 1-sensitized mice. In this context, Coleman et al. [31] demonstrated in an experimental mouse model of Bordetella pertussis infection that the CD4+Foxp3+CD25- Treg population could have an important immunoregulatory function suppressing CD4+ T effector cells, which was partially mediated by IL-10 production and not dependent on cell contact. In agreement with this, Nishioka T. et al. demonstrated that this same population could suppress T effectors cell proliferation in vitro even in aged mice [32].
Here, the analysis of cell culture showed a significant production of IL-6 in sensitized mice, but no differences in TGF-β1 and IL-1β, when compared with the production of splenocyte cultures in control mice. This fact could be related to the expansion of the Foxp3+ Tregs populations in cultures from rPoly p1-sensitized mice, since it was demonstrated in a transgenic mice model, which constitutively overexpress IL-6, that these animals presented increased CD4+ Foxp3+ cells in the thymus and spleen with a preserved suppressive function. Furthermore, the authors demonstrated that TGF-β1 induced Tregs, which was differentiated from naïve CD4+ T in the periphery, (iTregs), was significantly reduced in transgenic mice, whereas the natural Tregs (nTregs) were not affected, suggesting that IL-6 acts differently on iTregs and nTregs populations [33]. However, considering the limitations of the in vitro analyses presented here, and due to the high variability of phenotypes and functional mechanisms by which Tregs exert their suppressive properties, future investigations should be conducted to better evaluate the immunomodulatory effects of rPoly p 1 to induce Tregs activation.

4. Conclusions

We demonstrated that the recombinant form of PLA1 from P. paulista wasp venom was able to induce a significant expansion of antigen-specific CD4+ T cells, but not of CD8+ T cells in sensitized mice. These cells were polarized to a Th1/Treg functional profile, demonstrated by a high production of IFN-γ and by the pronounced expansion of CD4+CD25+FoxP3+ and CD4+CD25-FoxP3+ Tregs populations, respectively. These results suggest that rPoly p 1 could be a promising eligible candidate to help develop new strategies of wasp VIT, which could supplant the risk of severe adverse allergic reactions with the use of wasp crude venom extracts.

5. Materials and Methods

5.1. Animals

Specific Pathogen Free (SPF) female BALB/c mice (four weeks old) were obtained from the Multidisciplinary Center for Biological Research (CEMIB) of the University of Campinas (UNICAMP) Campinas, SP, Brazil. They were maintained in an SPF environment at 24 °C ± 1 for a photoperiod of 12/12 hours, and fed with autoclaved Nuvilab CR-diet and water ad libitum for at least four weeks before being used in experiments. The methods described in this manuscript were carried out in accordance with the ‘Guide for the Care and Use of Laboratory Animals,’ as promoted by the Brazilian College of Animal Experimentation (COBEA), and approved by the Ethics Committee for Animal Experimentation of the University of Campinas (CEUA/UNICAMP. Protocol #3476-1, approval date 3 September 2014).

5.2. Polybia Paulista Venom Extracts and Recombinant PLA1

The venom extracts and rPoly p 1 were obtained expressing the PLA1 cDNA cloned in specific vectors and expressed in E. coli-competent cells using the previously described protocols [12,15]. For the rPoly p1 purification, the soluble fractions were applied to a prepacked column HisTrap HP™ (Ni+2 Sepharose™ High Performance; GE Healthcare, Sweden) as described before [12], followed by SDS-PAGE (15%) analysis for monitoring the efficiency of the purification process.

5.3. Mice Sensitization

Mice sensitization to rPoly p 1 was conducted as previously described [15]. Briefly, the mice (n = 6) were immunized intradermally with six weekly doses of 20 µg of rPoly p 1 in phosphate-buffered saline (PBS) with 5% of Al(OH)3 (rPoly p 1 group). The control group (n = 4) was immunized with 20 µg of solubilized proteins from E. coli BL21 (DE3) cytoplasmatic content transformed with an empty pET-28a vector serving as negative control. Seven days after the last immunization dose, the mice from both the rPoly p1 and control group were bled and sacrificed. The sera were separated and stored at −20 °C until their use in ELISA assays, and spleens were aseptically removed for antigen-specific T cell proliferation assays. Figure 3 represents a summary of the experimental procedures.

5.4. Antigen-Specific T Cell Proliferation Assay

In order to stimulate the activation of the antigen-specific T cell, proliferation assays were conducted as described below. Briefly, mice spleens were collected aseptically, and the splenocytes were obtained after homogenizing the organs in cell dissociation sieves in RPMI 1640 medium (Vitrocell, Campinas, SP, Brazil) supplemented with sodium bicarbonate (2 g/L, Sigma-Aldrich®, St. Louis, MO, USA), HEPES buffer (25mM, Sigma-Aldrich®, St. Louis, MO, USA), 10 UI/mL of penicillin, 10 μg/mL of streptomycin, and 5 μg/mL of Fungizone (all from Gibco, Invitrogen Corporation, Grand Island, NY, USA). Erythrocytes were lysed with the lysis solution (150mM NH4Cl, 10mM KHCO3 and 0.1mM EDTA) at room temperature, cells were pelleted at 400× g for 5 min, and cells were resuspended in RPMI cell culture medium. Splenocytes were previously stained with 2.5 µM of the probe 5(6)-CFDA; 5(6)-Carboxyfluorescein diacetate (CFSE, Biolegend, San Diego, CA, USA), seeded in 96-well plates at 2.5 × 105 cells/well in the presence of 4 µg/mL of venom extracts from P. paulista, and then incubated for 96 h at 37 °C in humidified incubator with CO2 5%. After this period, the cell cultures’ supernatants were collected for the quantification of cytokines, as described in Section 5.5, and the cells were then stained with phenotypic specific markers for CD4+ T cells, CD8+ T cells or T regulatory cells, as described below. The proliferation and the frequency of Tregs were assessed by flow cytometry, as described in Section 5.6.

5.5. Measurement of Cytokines

The cultures’ supernatants were collected for the dosage of cytokines through ELISA using commercial kits (ELISA Ready Set-Go™ e-Bioscience, Thermo Fischer Scientific, Waltham, MA, USA) according to the manufacturer’s recommendations. We analyzed the following mouse cytokines: IL-6, IFN-γ, IL-1β, IL-4 and TGF-β1.

5.6. Flow Cytometry

Following cultivation of the splenocytes in the antigen-specific T cell proliferation assays, single-cell suspensions were firstly stained with the viability probe Zoombie NIR™ fixable viability kit (BioLegend, San Diego, CA, USA). After washing with flow cytometry cell staining buffer (FCSB—phosphate-buffered saline pH 7.4 containing 5% SFB, 2mM EDTA and 2 mM NaN3) the cells were labelled with anti-CD4-APC (Biolegend), and anti-CD8-PercPCy5. (Biolegend). For the Tregs analysis, the cells were labelled with anti-CD4-Fitc (Biolegend) and anti-CD25-APC (Biolegend); additionally, the samples were incubated with fixation/permeabilization buffers (Foxp3 Fix/Perm Buffer Set—eBioscience-Affymetrix, Santa Clara, CA, USA), according to the manufacturer’s instructions, and stained with anti-mouse—Foxp3 PE, antibody (Biolegend). The cells were also stained with irrelevant isotype controls for each cell marker analyzed. The samples were acquired using FACsVerse™ Flow Cytometer (BD-Bioscience San Jose, CA, USA), where 10,000 events gated on viable cells for each tube were established as the minimum number of events for the acquisitions. Adjustments to the photomultiplier tubes (PMTs) voltage and compensation were determined by the examination of non-marked cells and single-stained cells using the antibodies described above. The compensation matrix was stablished manually using the FACSuite acquisition software version 1.0.6 (Becton Dickinson, San Jose, CA, USA). The results were analyzed with FCS Express 6 Flow Research Edition Software (DeNovo Software, Los Angeles, CA, USA) and the gating strategy used in the analysis of T cell proliferation and Tregs frequency are shown in Figure A1 and Figure A2 in Appendix A, respectively.

5.7. Statistical Analyses

Data were statistically analyzed using Mann–Whitney U test. The software Prism (version 6.0, Graphpad Software, Inc., San Diego, CA, USA) was used for statistical and graphic analysis. Significant differences were set at p ≤ 0.05. Data from flow cytometry analyses are represented as Tukey box plots, and the mean ± S.E.M. expresses data from cytokines quantification.

Author Contributions

L.G.R.F. conducted most of the experiments. D.M.A. collaborated in immunization procedures. A.P.-R. and M.L.B. collaborated with proteins expression and purification, and M.R.B.-B. led and supervised these processes. R.d.L.Z. advised and led each stage of the research. L.G.R.F. wrote the first draft of the manuscript, while all authors including provided valuable comments to the draft. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by the Council of Technological and Scientific Development (CNPq)—Brazil (Grant No. 455422/2014-1 to L.G.R.F.) and São Paulo Research Foundation (FAPESP) (Grant No. 2019/00729-7 to L.G.R.F. and Grant No. 2014/13936-7 to M.R.B.B.). The authors also acknowledge CAPES-DS (Coordination for the Improvement of Higher Education Personnel), Postgraduate Program in Internal Medicine at the State University of Campinas (UNICAMP), Campinas-SP and FAPESP (Grant #2017/22405-3; #2018/24834-1) for providing Post-Doctoral scholarship to A.P.R.

Acknowledgments

The authors thank Patricia Janino for helping in animal care. The authors thank Espaço da Escrita—Pró-Reitoria de Pesquisa—UNICAMP—for the language services provided.

Conflicts of Interest

The authors declare no conflict of interest.

Appendix A. Supplementary Data

Figure A1. Gating hierarchy of T cell proliferation analysis. The FSC-Area vs. FSC-Height dot plots (a) was used to eliminate doublets (doublets negative-purple gate) and within double negative gated events the viable lymphocytes population was identified in SSC and APC-Cy7 density plots (b) as SSClow and APC-Cy7neg population (red gate). Histograms gated on viable cells (c) were used to identify the CD8+ population (left histogram) and CD4+ population (right histogram). Within the CD8+ or CD4+ populations the proliferating cells were identified as CSFElow cells (upper left quadrants) in the dot plots (d) of the CD8-Percp-Cy5.5 vs. CSFE (left dot plot) and CD4-APC vs. CSFE, respectively.
Figure A1. Gating hierarchy of T cell proliferation analysis. The FSC-Area vs. FSC-Height dot plots (a) was used to eliminate doublets (doublets negative-purple gate) and within double negative gated events the viable lymphocytes population was identified in SSC and APC-Cy7 density plots (b) as SSClow and APC-Cy7neg population (red gate). Histograms gated on viable cells (c) were used to identify the CD8+ population (left histogram) and CD4+ population (right histogram). Within the CD8+ or CD4+ populations the proliferating cells were identified as CSFElow cells (upper left quadrants) in the dot plots (d) of the CD8-Percp-Cy5.5 vs. CSFE (left dot plot) and CD4-APC vs. CSFE, respectively.
Toxins 12 00379 g0a1
Figure A2. Gating hierarchy of T regs analysis. The FSC-Area vs. FSC-Height dot plots (a) was used to eliminate doublets (doublets negative-purple gate) and, within double negative gated events, the viable lymphocytes population was identified in SSC and APC-Cy7 density plots (b) as SSClow and APC-Cy7- population (red gate). The histogram gated on viable cells (c) was used to identify the CD4+ population. Within the CD4+cells the CD25+FoxP3+ (upper right quadrant) and CD25-FoxP3+ (lower right quadrant) Tregs were identified by plotting CD25-APC vs. FoxP3-PE (d).
Figure A2. Gating hierarchy of T regs analysis. The FSC-Area vs. FSC-Height dot plots (a) was used to eliminate doublets (doublets negative-purple gate) and, within double negative gated events, the viable lymphocytes population was identified in SSC and APC-Cy7 density plots (b) as SSClow and APC-Cy7- population (red gate). The histogram gated on viable cells (c) was used to identify the CD4+ population. Within the CD4+cells the CD25+FoxP3+ (upper right quadrant) and CD25-FoxP3+ (lower right quadrant) Tregs were identified by plotting CD25-APC vs. FoxP3-PE (d).
Toxins 12 00379 g0a2

References

  1. Sole, D.; Ivancevich, J.C.; Borges, M.S.; Coelho, M.A.; Rosario, N.A.; Ardusso, L.R.F.; Bernd, L.A.G. Anaphylaxis in Latin America: A report of the online Latin American survey on anaphylaxis (OLASA). Clinics 2011, 66, 943–947. [Google Scholar] [CrossRef] [Green Version]
  2. Peters, R.S.; Krogmann, L.; Mayer, C.; Donath, A.; Gunkel, S.; Meusemann, K.; Kozlov, A.; Podsiadlowski, L.; Petersen, M.; Lanfear, R.; et al. Evolutionary History of the Hymenoptera. Curr. Biol. 2017, 27, 1013–1018. [Google Scholar] [CrossRef] [Green Version]
  3. Locher, G.A.; Togni, O.C.; Silveira, O.T.; Giannotti, E. The social wasp fauna of a riparian forest in southeastern Brazil (hymenoptera, vespidae). Sociobiology 2014, 61, 225–233. [Google Scholar] [CrossRef] [Green Version]
  4. Dos Santos-Pinto, J.R.A.; Perez-Riverol, A.; Lasa, A.M.; Palma, M.S. Diversity of peptidic and proteinaceous toxins from social Hymenoptera venoms. Toxicon 2018, 148, 172–196. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  5. Larché, M.; Akdis, C.A.; Valenta, R. Immunological mechanisms of allergen-specific immunotherapy. Nat. Rev. Immunol. 2006, 6, 761–771. [Google Scholar] [CrossRef]
  6. Jakob, T.; Müller, U.; Helbling, A.; Spillner, E. Component resolved diagnostics for hymenoptera venom allergy. Curr. Opin. Allergy Clin. Immunol. 2017, 17, 363–372. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  7. Perez-Riverol, A.; dos Santos-Pinto, J.R.A.; Lasa, A.M.; Palma, M.S.; Brochetto-Braga, M.R. Wasp venomic: Unravelling the toxins arsenal of Polybia paulista venom and its potential pharmaceutical applications. J. Proteom. 2017, 161, 88–103. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  8. Santos, L.D.; Santos, K.S.; de Souza, B.M.; Arcuri, H.A.; Cunha-Neto, E.; Castro, F.M.; Kalil, J.E.; Palma, M.S. Purification, sequencing and structural characterization of the phospholipase A1 from the venom of the social wasp Polybia paulista (Hymenoptera, Vespidae). Toxicon 2007, 50, 923–937. [Google Scholar] [CrossRef]
  9. Roberto Aparecido dos Santos Pinto, J.; Delazari dos Santos, L.; Andrade Arcuri, H.; Baptista Dias, N.; Sergio Palma, M. Proteomic Characterization of the Hyaluronidase (E.C. 3.2.1.35) from the Venom of the Social Wasp Polybia paulista. Protein Pept. Lett. 2012, 19, 625–635. [Google Scholar] [CrossRef] [PubMed]
  10. Justo Jacomini, D.L.; Campos Pereira, F.D.; Aparecido dos Santos Pinto, J.R.; dos Santos, L.D.; da Silva Neto, A.J.; Giratto, D.T.; Palma, M.S.; de Lima Zollner, R.; Brochetto Braga, M.R. Hyaluronidase from the venom of the social wasp Polybia paulista (Hymenoptera, Vespidae): Cloning, structural modeling, purification, and immunological analysis. Toxicon 2013, 64, 70–80. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  11. Dos Santos-Pinto, J.R.A.; Dos Santos, L.D.; Andrade Arcuri, H.; Castro, F.M.; Kalil, J.E.; Palma, M.S. Using proteomic strategies for sequencing and post-translational modifications assignment of antigen-5, a major allergen from the venom of the social wasp Polybia paulista. J. Proteome Res. 2014, 13, 855–865. [Google Scholar] [CrossRef] [PubMed]
  12. Perez-Riverol, A.; Campos Pereira, F.D.; Musacchio Lasa, A.; Romani Fernandes, L.G.; dos Santos-Pinto, J.R.A.; Justo-Jacomini, D.L.; Oliveira de Azevedo, G.; Bazon, M.L.; Palma, M.S.; de Lima Zollner, R.; et al. Molecular cloning, expression and IgE-immunoreactivity of phospholipase A1, a major allergen from Polybia paulista (Hymenoptera: Vespidae) venom. Toxicon 2016, 124, 44–52. [Google Scholar] [CrossRef] [PubMed]
  13. Jakob, T.; Rafei-Shamsabadi, D.; Spillner, E.; Müller, S. Diagnostics in Hymenoptera venom allergy: Current concepts and developments with special focus on molecular allergy diagnostics. Allergo J. Int. 2017, 26, 93–105. [Google Scholar] [CrossRef] [PubMed]
  14. Perez-Riverol, A.; Justo-Jacomini, D.L.; de Lima Zollner, R.; Brochetto-Braga, M.R. Facing hymenoptera venom allergy: From natural to recombinant allergens. Toxins 2015, 7, 2551–2570. [Google Scholar] [CrossRef] [PubMed]
  15. Perez-Riverol, A.; Fernandes, L.G.R.; Musacchio Lasa, A.; dos Santos-Pinto, J.R.A.; Moitinho Abram, D.; Izuka Moraes, G.H.; Jabs, F.; Miehe, M.; Seismman, H.; Palma, M.S.; et al. Phospholipase A1-based cross-reactivity among venoms of clinically relevant Hymenoptera from Neotropical and temperate regions. Mol. Immunol. 2018, 93, 87–93. [Google Scholar] [CrossRef]
  16. Akdis, C.A.; Akdis, M. Mechanisms of allergen-specific immunotherapy and immune tolerance to allergens. World Allergy Organ. J. 2015, 8, 1–12. [Google Scholar] [CrossRef] [Green Version]
  17. Steinke, J.W.; Lawrence, M.G. T-cell biology in immunotherapy. Ann. Allergy Asthma Immunol. 2014, 112, 195–199. [Google Scholar] [CrossRef] [Green Version]
  18. Golden, D.B.K. Anaphylaxis to insect stings. Immunol. Allergy Clin. N. Am. 2015, 35, 287–302. [Google Scholar] [CrossRef]
  19. Antonicelli, L.; Bilò, M.B.; Bonifazi, F. Epidemiology of hymenoptera allergy. Curr. Opin. Allergy Clin. Immunol. 2002, 2, 341–346. [Google Scholar] [CrossRef]
  20. Akdis, M.; Akdis, C.A. Mechanisms of allergen-specific immunotherapy: Multiple suppressor factors at work in immune tolerance to allergens. J. Allergy Clin. Immunol. 2014, 133, 621–631. [Google Scholar] [CrossRef]
  21. Palomares, O.; Akdis, M.; Martín-Fontecha, M.; Akdis, C.A. Mechanisms of immune regulation in allergic diseases: The role of regulatory T and B cells. Immunol. Rev. 2017, 278, 219–236. [Google Scholar] [CrossRef] [PubMed]
  22. Calzada, D.; Baos, S.; Cremades-Jimeno, L.; Cárdaba, B. Immunological mechanisms in allergic diseases and allergen tolerance: The role of Treg cells. J. Immunol. Res. 2018, 2018, 6012053. [Google Scholar] [CrossRef]
  23. Sahiner, U.M.; Durham, S.R. Hymenoptera venom allergy: How does venom immunotherapy prevent anaphylaxis from bee and wasp stings? Front. Immunol. 2019, 10, 01959. [Google Scholar] [CrossRef]
  24. Dhami, S.; Zaman, H.; Varga, E.M.; Sturm, G.J.; Muraro, A.; Akdis, C.A.; Antolín-Amérigo, D.; Bilò, M.B.; Bokanovic, D.; Calderon, M.A.; et al. Allergen immunotherapy for insect venom allergy: A systematic review and meta-analysis. Allergy Eur. J. Allergy Clin. Immunol. 2017, 72, 342–365. [Google Scholar] [CrossRef] [Green Version]
  25. Mosbech, H.; Muller, U. Side-effects of insect venom immunotherapy: Results from an EAACI multicenter study. Allergy Eur. J. Allergy Clin. Immunol. 2000, 55, 1005–1010. [Google Scholar] [CrossRef] [PubMed]
  26. Winkler, B.; Bolwig, C.; Seppälä, U.; Spangfort, M.D.; Ebner, C.; Wiedermann, U. Allergen-specific immunosuppression by mucosal treatment with recombinant Ves v 5, a major allergen of Vespula vulgaris venom, in a murine model of wasp venom allergy. Immunology 2003, 110, 376–385. [Google Scholar] [CrossRef] [PubMed]
  27. Lu, G.; Kochoumian, L.; King, T.P. Sequence identity and antigenic cross-reactivity of white face hornet venom allergen, also a hyaluronidase, with other proteins. J. Biol. Chem. 1995, 270, 4457–4465. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  28. Kochoumian, L.; Lu, G. Murine T and B cell responses to natural and recombinant hornet venom allergen Dol m 5.02 and its recombinant fragments. J. Immunol. 1995, 154, 577–584. [Google Scholar]
  29. Bohle, B.; Zwölfer, B.; Fischer, G.F.; Seppälä, U.; Kinaciyan, T.; Bolwig, C.; Spangfort, M.D.; Ebner, C. Characterization of the human T cell response to antigen 5 from Vespula vulgaris (Ves v 5). Clin. Exp. Allergy 2005, 35, 367–373. [Google Scholar] [CrossRef] [PubMed]
  30. Kerstan, A.; Albert, C.; Klein, D.; Bröcker, E.B.; Trautmann, A. Wasp venom immunotherapy induces activation and homing of CD4 +CD25+ forkhead box protein 3-positive regulatory T cells controlling TH1 responses. J. Allergy Clin. Immunol. 2011, 127, 495–501. [Google Scholar] [CrossRef] [PubMed]
  31. Coleman, M.M.; Finlay, C.M.; Moran, B.; Keane, J.; Dunne, P.J.; Mills, K.H.G. The immunoregulatory role of CD4 +FoxP3 +CD25-regulatory T cells in lungs of mice infected with Bordetella pertussis. FEMS Immunol. Med. Microbiol. 2012, 64, 413–424. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  32. Nishioka, T.; Shimizu, J.; Iida, R.; Yamazaki, S.; Sakaguchi, S. CD4 + CD25 + Foxp3 + T Cells and CD4 + CD25 − Foxp3 + T Cells in Aged Mice. J. Immunol. 2006, 176, 6586–6593. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  33. Fujimoto, M.; Nakano, M.; Terabe, F.; Kawahata, H.; Ohkawara, T.; Han, Y.; Ripley, B.; Serada, S.; Nishikawa, T.; Kimura, A.; et al. The Influence of Excessive IL-6 Production In Vivo on the Development and Function of Foxp3 + Regulatory T Cells. J. Immunol. 2011, 186, 32–40. [Google Scholar] [CrossRef] [PubMed] [Green Version]
Figure 1. Antigen-specific T cell proliferation. Cells obtained from mice spleens were previously stained with a CFSE probe and, after the culture period, were harvested and stained with anti-CD4 (a,b) and anti-CD8 (c,d) monoclonal antibodies conjugated to fluorochromes APC and Percp-Cy5.5, respectively. Panels (a) and (c) are a representative dot plot showing the frequency (%) of CFSElow (proliferating cells) in CD4 (a) or CD8 (c) T cell subsets, and the boxplots (b) and (d) represent their corresponding data, obtained in Control and rPoly p1 groups. *p < 0.05 Mann–Whitney U test.
Figure 1. Antigen-specific T cell proliferation. Cells obtained from mice spleens were previously stained with a CFSE probe and, after the culture period, were harvested and stained with anti-CD4 (a,b) and anti-CD8 (c,d) monoclonal antibodies conjugated to fluorochromes APC and Percp-Cy5.5, respectively. Panels (a) and (c) are a representative dot plot showing the frequency (%) of CFSElow (proliferating cells) in CD4 (a) or CD8 (c) T cell subsets, and the boxplots (b) and (d) represent their corresponding data, obtained in Control and rPoly p1 groups. *p < 0.05 Mann–Whitney U test.
Toxins 12 00379 g001
Figure 2. Tregs population frequency after in vitro antigenic stimulation. Cells stained with monoclonal antibodies conjugated to fluorochromes to Tregs markers: CD4, CD25 and FoxP3. Panel (a) presents a representative dot plot showing the frequency (%) of CD4+CD25+FoxP3+ Tregs (upper right quadrant) and CD4+CD25-FoxP3+ Tregs (lower right quadrant), and the boxplots (b) and (c) represent their corresponding data obtained in Control and rPoly p 1 groups. *p < 0.05 Mann–Whitney U test.
Figure 2. Tregs population frequency after in vitro antigenic stimulation. Cells stained with monoclonal antibodies conjugated to fluorochromes to Tregs markers: CD4, CD25 and FoxP3. Panel (a) presents a representative dot plot showing the frequency (%) of CD4+CD25+FoxP3+ Tregs (upper right quadrant) and CD4+CD25-FoxP3+ Tregs (lower right quadrant), and the boxplots (b) and (c) represent their corresponding data obtained in Control and rPoly p 1 groups. *p < 0.05 Mann–Whitney U test.
Toxins 12 00379 g002
Figure 3. Timeline for sensitization with rPoly p 1 and experimental procedures description. Mice were sensitized to rPoly p 1 by weekly intradermal injections (six doses—20 µg/dose), the control group received a 20 µg/dose of E. coli BL21 (DE3) cells’ lysate proteins. Seven days after the last dose, the mice were sacrificed, and the splenocytes were cultured for 96 hours in the presence of P. paulista venom extract (4 µg/mL) for antigen-specific stimulation of T cells. After this period, the cells were stained for flow cytometry analysis to evaluate the proliferation of T cells and the frequency of regulatory T cells populations. The cell culture supernatants were collected for cytokines quantification by ELISA assays. Polybia paulista photo was kindly provided by Dr. Mario S. Palma. BALB/c mouse photo is from Staton K. Short, The Jackson Laboratory (https://www.jax.org/strain/000651).
Figure 3. Timeline for sensitization with rPoly p 1 and experimental procedures description. Mice were sensitized to rPoly p 1 by weekly intradermal injections (six doses—20 µg/dose), the control group received a 20 µg/dose of E. coli BL21 (DE3) cells’ lysate proteins. Seven days after the last dose, the mice were sacrificed, and the splenocytes were cultured for 96 hours in the presence of P. paulista venom extract (4 µg/mL) for antigen-specific stimulation of T cells. After this period, the cells were stained for flow cytometry analysis to evaluate the proliferation of T cells and the frequency of regulatory T cells populations. The cell culture supernatants were collected for cytokines quantification by ELISA assays. Polybia paulista photo was kindly provided by Dr. Mario S. Palma. BALB/c mouse photo is from Staton K. Short, The Jackson Laboratory (https://www.jax.org/strain/000651).
Toxins 12 00379 g003
Table 1. Cytokine quantification in cell culture supernatants of in vitro stimulated T cells with Polybia paulista venom extract.
Table 1. Cytokine quantification in cell culture supernatants of in vitro stimulated T cells with Polybia paulista venom extract.
Cytokine
(pg/mL)
Control 1
(n = 4)
rPoly p1 1
(n = 6)
Statistical
Significance 2
IFN-γ 135.30 ± 74.671040 ± 172.50p = 0.0006 *
IL-44.36 ± 0.444.99 ± 0.37p = 0.28
IL-637.22 ± 19.25265.10 ± 57.48p = 0.0048 *
IL-1β5.94 ± 0.486.35 ± 1.06p = 0.91
TGF-β1643.8 ± 140.4488.3 ± 145.2p = 0.474
1 Data presented as mean ± SEM, 2 Mann–Whitney U test, * Statistically significant (p < 0.05).

Share and Cite

MDPI and ACS Style

Fernandes, L.G.R.; Perez-Riverol, A.; Bazon, M.L.; Abram, D.M.; Brochetto-Braga, M.R.; Zollner, R.d.L. Functional Profile of Antigen Specific CD4+ T Cells in the Immune Response to Phospholipase A1 Allergen from Polybia paulista Venom. Toxins 2020, 12, 379. https://doi.org/10.3390/toxins12060379

AMA Style

Fernandes LGR, Perez-Riverol A, Bazon ML, Abram DM, Brochetto-Braga MR, Zollner RdL. Functional Profile of Antigen Specific CD4+ T Cells in the Immune Response to Phospholipase A1 Allergen from Polybia paulista Venom. Toxins. 2020; 12(6):379. https://doi.org/10.3390/toxins12060379

Chicago/Turabian Style

Fernandes, Luís Gustavo Romani, Amilcar Perez-Riverol, Murilo Luiz Bazon, Débora Moitinho Abram, Márcia Regina Brochetto-Braga, and Ricardo de Lima Zollner. 2020. "Functional Profile of Antigen Specific CD4+ T Cells in the Immune Response to Phospholipase A1 Allergen from Polybia paulista Venom" Toxins 12, no. 6: 379. https://doi.org/10.3390/toxins12060379

APA Style

Fernandes, L. G. R., Perez-Riverol, A., Bazon, M. L., Abram, D. M., Brochetto-Braga, M. R., & Zollner, R. d. L. (2020). Functional Profile of Antigen Specific CD4+ T Cells in the Immune Response to Phospholipase A1 Allergen from Polybia paulista Venom. Toxins, 12(6), 379. https://doi.org/10.3390/toxins12060379

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