Stings by hymenoptera, namely bees, wasps, yellow jackets, hornets and ants, usually cause just local reactions. However, in some cases, they can induce systemic symptoms, and even fatal reactions.1,2

Reactions to hymenoptera venom are also responsible for decreased quality of life and significant anxiety about future stings.1,3 The results of the quality-of-life questionnaire demonstrated that a well-tolerated sting challenge test improves the quality of life of venom-allergic patients by reducing the anticipatory anxiety associated with the fear of being stung.4,5

Diagnosis of hymenoptera venom allergy forms the basis of treatment.6 Venom immunotherapy is the only treatment that addresses the cause of the anaphylactic reaction. It has proven very effective in inducing tolerance, with a protection rate ranging from 75% to 98%.7

Diagnosis of hymenoptera allergy is based on a systemic reaction after a sting, a positive skin test result and detection of specific IgE antibodies. Both skin test and specific IgE frequently reveal multiple sensitisations, which complicates the choice of the venom for immunotherapy (VIT).8 Double-positive results are a common issue when diagnosing Hymenoptera venom allergy based on crude venom extracts, since up to 59% of patients react to both honey bee venom and yellow jacket venom. Moreover, there is an increasing pattern of double sensitisation to Vespula and Polistes in southern European countries.9,10 On the other hand, cases of double positivity of IgE to bee and Vespula venom are often caused by clinically irrelevant cross-reactive antibodies against cross-reacting carbohydrate residues or by homologue allergens expressed in different Hymenoptera venoms.10,11

Component-resolved diagnosis (CRD) based on the use of well-defined, properly characterised and purified natural and recombinant allergens constitutes a new approach in venom allergy diagnosis.12–14

The best characterised venom is that of Apis mellifera, whose main allergens are phospholipase A2 (Api m1), hyaluronidase (Api m2) and melittin (Api m4).2,15 Additionally, allergens of Vespula vulgaris have been identified, as phospholipase A1 (Ves v1), hyaluronidase (Ves v2) and antigen 5 (Ves v5).16Polistes species are becoming an increasing cause of allergy in Europe, although only few allergens have been identified to date.

In this paper, we analyse the current knowledge about molecular diagnosis in hymenoptera venom allergy.

Bee venom is a complex mixture of allergenic proteins with enzymatic function, together with other pharmacologically-active molecules, such as biogenic amines and basic peptides.

The complete genome sequencing of the bee has allowed the study of the composition of its venom, making it a model for the study of these insects. The most recent proteomic analysis of bee venom reveals that there must be more than 100 different components. Currently, 12 allergens have been identified in the bee, most of them in the venom17,18 (Table 1).

The best-known bee venom allergens so far are phospholipase A2 (Api m 1), hyaluronidase (Api m 2) and melittin peptide (Api m 4), which constitute the majority of the dry weight of venom.

Phospholipase A2 (Api m 1) has been considered the most important and potent allergen of bee venom since 1976.19 It is the most abundant enzyme capable of sensitising the vast majority of patients allergic to bee venom.10,20 Its enzymatic activity causes the hydrolysis of membrane phospholipids, producing a significant increase in arachidonic acid and leukotrienes; these are responsible for bronchoconstriction, mucus production and vascular permeability.21 Phospholipase A2 was cloned in 1989.22 In 1992, it was recombinantly expressed through a prokaryotic system using the E. coli bacteria, achieving an enzymatic activity and skin reactivity similar to the natural purified form.23,24

In the bee venom compound-based diagnosis, it has been observed that use of allergen Api m 1 has different sensitivity according to the technique and sources used.25–28

Technique sensitivities vary ranging from 95.6 to 97% of ADVIA Centaur,10,29 to 61.8–91% of ImmunoCAP,8,20,25–28 being the highest observed prevalence of sensitisation using native Api m 1. In contrast, Immulite technique has shown a sensitivity of 83.1% with the recombinant form of Api m 1.30

Hyaluronidase (Api m 2) is a glycosylated enzyme considered a major allergen of bee venom.20,29 It hydrolyses the hyaluronic acid in the target tissue, enhancing the penetration of the other components of the venom.21

Bee hyaluronidase shares 55% sequence identity with vespid hyaluronidase,32 which may explain the cross-reactivity between them, together with carbohydrate determinants.33

Hyaluronidase was isolated in 198434 and cloned in 1993.35 It is recombinantly produced in prokaryotic (E. coli) and eukaryotic (Baculovirus) systems, the latter having an enzymatic activity and IgE binding capacity similar to that of the natural purified allergen.31

The most abundant peptide of the venom is melittin (Api m 4); with a very low molecular weight it represents the major toxic component of bee venom. Schröder et al. achieved its synthesis in 197136 and in recent years it has been confirmed that melittin is an allergen in highly purified preparations, through the detection of specific IgE antibody by radioallergosorbent test (RAST).37 It is currently available in native and synthetic form.

It is considered a minor allergen with sensitisation prevalence ranging around 22.9%–29%.20,37 However, it has recently been described as a major allergen in a population (69 patients) in the south of Spain with allergy to A. mellifera venom whose prevalence of sensitisation to Api m 4 was of 53.6%. Sensitisation to Api m 4 has behaved as a biomarker in patients with poor tolerance to the start of the bee venom immunotherapy with very low s-IgE values.29

Use of IgE-Api m 4 as the single discrimination criterion demonstrated different ways of being allergic to bee venom. Patients with sIgE-Api m 4 ≥0.98kU/L had more severe reactions with stings, higher skin sensitivity, and baseline sIgE-Apis-rApi m 1 than patients with sIgE-Api m 4 <0.98kU/L. Patients with high sensitisation to melittin experienced 41% of the SRs during the build-up phase, and the sting challenge success rate was 82% in the second year.38

In recent years, advances in molecular characterisation have made it possible to identify other less abundant proteins in the venom, some had already been described as potentially allergenic, such as acid phosphatase (Api m 3). Its prevalence of sensitisation to purified native allergen is 60% in sera from patients allergic to bee venom, which decreases to 37% when the recombinant protein is used.39 However, in a recent publication, sensitivity to the recombinant protein was detected in 50% of patients studied.20Dipeptidyl Peptidase 4 (Api m 5) has been identified as one of the proteins of higher molecular weight (102kDa) of bee venom20 and appears to be responsible for the cross-reactivity between bees and wasps.40 It is a glycosylated enzyme, with a described prevalence of sensitisation to the recombinant molecule of 58.3%. A new protein, Icarapin (Api m 10) has proven to be a genuine bee venom allergen with high diagnostic and therapeutic potential, being considered as a marker of failure in bee venom immunotherapy, although the presence of this allergen detected in therapeutic extracts of bee venom remains controversial.20,41,42

Api m 6, namely a Protease Inhibitor, and Api m 4 are the only unglycosylated allergens of bee venom, and are considered as minor allergens. The rate of recognition of Api m 6 in its natural purified form is 40%, using the Immunoblot method43; however, only 26% of allergic patients show specific IgE reactivity to the recombinant protein.43,44Api m 7, namely a protease with unknown enzymatic activity, was detected by means of specific IgE in 80% of the studied serum, using a immunoblot assay.45 There are few data on Carboxylesterase (Api m 8) and carboxypeptidase (Api m 9); to our knowledge, a recombinant protein Api m8 captured sIgE present in 46% of sera from 28 allergic patients, by ELISA method.46 One of the most recently characterised bee allergens is Major royal jelly protein (Api m11), which presents two isoallergens: MRJP 8 and MRJP 9. The prevalence of sensitisation in its natural form is 50% for MRJP8, and 60% for MRJP 9. It seems that the contribution of carbohydrates is present, as in their recombinant form they show a much lower power of sensitisation, being 15% and 34%, respectively.47

Vitellogenin (Api m 12), is the highest molecular weight protein of bee venom known. It has recently been shown that approximately 40% of patients allergic to bee venom showed specific IgE to the recombinant protein.48 On the other hand, Api m 12 may be involved in cross-reactivity with vespids due to its similarities with an allergen that is also present in this venom (Ves v 6).

Bumblebee venom closely resembles honeybee venom and has two allergens of known sequence, phospholipase A2, and a protease. The honeybee and bumblebee venom phospholipases A1 show no sequence identity,68 which differs in its specificity of the catalytic mechanism. The bumblebee has gained significantly in importance, since it is increasingly used for pollination in greenhouses.69

Although for many years bee venom has been used to treat patients who experienced systemic reactions to bumblebee, due to the existence of some studies which warranted its efficacy, it has been recently reported that Bombus terrestris and bee show a low or very low degree of cross-reactivity. Bumblebee phospholipase A2 has shown a cross-reactivity of just 53% with bee phospholipase A2.70

Therefore, bee venom immunotherapy could be not as effective for this kind of patients as it was reported in the past. Cruz et al. described two phenotypes of patients allergic to bumblebee: 1) patients who had not been exposed to bumblebee and that were sensitised to bee venom; 2) patients who were primarily sensitised to bumblebee and that worked in greenhouses. For the latter kind of patients, the European Academy of Allergology and Clinical Immunology recommends using specific bumblebee venom immunotherapy.71

Severino et al. reported 17 patients who had suffered from a severe reaction after Vespa crabro (VC) sting and proved skin and CAP positive also to Vespula. In 11/17 patients, Vespula venom completely inhibited IgE binding to VC venom, whereas VC venom inhibited binding to Vespula venom only partially (<75%). In six subjects the CAP-inhibition provided inconclusive results and their sera were analysed by immunoblotting. The SDS-PAGE identified hyaluronidase, phospholipase A1 and antigen 5 as the main proteins of the venoms.72 With these results, it seems probable that patients with allergy to VC shall benefit from vespula venom immunotherapy.73

In the absence of commercial Vespa orientalis venom, the practice of treating patients allergic to this insect with available commercial venoms seems to be efficacious and Vespula venom is probably responsible for this effect.72

Moreover, fire ant venoms show high similarity with vespid venoms and contain a phospholipase A1 and an antigen 5. Varying from all other known Hymenoptera venoms, the major allergens of the Myrmecia venom are small peptides (pilosulins) which partially form homo- or heterodimers,73 but additionally, phospholipase and hyaluronidase activity have been reported.

In South-eastern Australia, ant sting allergy is relatively common being predominantly due to Myrmecia pilosula (Jack Jumper Ant, JJA). JJA venom immunotherapy has been shown to be effective in preventing anaphylaxis to the sting of the JJA.74

In Asia, there seems to be an increasing importance of fire ants. As beforehand stated, venom allergens of fire ants and jack jumper ants have been characterised and studied elsewhere (Table 4). Some studies of Pachycondyla venoms have been fulfilled, with the major allergen Pac c 3, being related to Sol i 3 from fire ants. Although ants seem to share some common proteins in venoms, each group appears to have a number of possibly unique components.75

CRD has the potential to establish individual sensitisation profiles6,8,14,67,76 and contributes by improving discrimination between sensitisation and genuine allergy.6,67,76 Moreover, CRD enables an individual risk assessment of severity and possibly prediction of persistence,6,67,76 and may expedite the selection of patients for VIT.

Given all CRD potentialities, it may generate a great deal of data whose clinical relevance could be elusive, and shall be used as a complementary diagnostic tool, linked to patient's history, skin-prick testing, and specific-IgE determination, rather than a first-line choice, principally in difficult cases.67,76 Furthermore, additional components will surely optimise both the performance and suitability of CRD in venom allergy diagnosis, because despite the efficiency of VIT, the biomarkers associated with clinical efficacy remain elusive.

Insect stings are the leading known cause of anaphylaxis (after idiopathic causes) among patients with systemic mastocytosis (SM), and mainly appear (89%) in indolent systemic mastocytosis (ISM).77,78 Hymenoptera venom anaphylaxis (HVA) episodes are much more frequent in patients without skin involvement (ISMs−) than in those with skin lesions (ISMs+) (67% vs 15.4%).77

Immunotherapy in mast cell activation syndromes (MCAS) is only recommended for those patients who demonstrate sensitisation mediated by IgE following skin tests and/or the determination of a specific IgE in vitro.79–81 In up to 15% of the patients with SM, no IgE mechanism is observed following the determination of serum IgE in a complete extract.82,83 Therefore, studies have been conducted using new diagnostic techniques: basophil-activation tests have shown contradictory results.84,85 Component-based determination of serum specific IgE antibodies to major Hymenoptera venom allergens among cases with a negative allergy study by means of skin tests and CAP determinations was carried out in a study with 14 patients.84 They found positive results (>0.35kU/L) in 7 of 11 patients (64%) who were studied by the ADVIA Centaur® system (ADVIA) (Siemens Medical Solutions Diagnostics, Tarrytown, NY, USA) with the use of natural (n) allergens (nApi m1, nApi m2, nPol d1, nPol d2, nVes v1, and nVes v5), but none of the three who were studied by ImmunoCAP (Thermo Fisher Scientific, Inc) with the use of recombinant (r) antigens (rApi m1, rPol d5, and rVes v5) showed a positive result. All tests were performed in ALK-Abelló (Madrid, Spain), using venom extracts from ALK-Abelló, Source Materials, Inc. (Spring Mills, PA, USA) except for nApi m1 (SIGMA, St Louis, MO, USA). These differences suggest the potentially greater sensitivity of biotinylated natural allergens subjected to ADVIA analyses versus recombinant allergens in component-based allergy testing reported by other groups,14 but further demonstration is needed in future prospective studies.

Patients with ISMs− may often present with normal baseline tryptase values. This fact, together with the absence of skin lesions, the similarity between these patients’ symptoms and those observed in allergic processes, and the absence of mast cells aggregates (the only major diagnostic criteria accepted by the current WHO classification) in the early stages of ISM, makes the diagnosis, especially of ISMs−, complex in many cases, and can only be established in specialised monographic networks that have all of the resources needed to provide a diagnosis. The Spanish Network on Mastocytosis (REMA), based on the comprehensive study of a large number of cases, has developed a Score that is capable of predicting the clonality (the probability that a patient with MCAS has of suffering from an ISMs− or a clonal-MCAS) with high sensitivity and specificity, based only on demographic data (gender), symptoms and signs during the acute episodes and the serum baseline tryptase level.83–89 In patients with a Score ≥2 (suspicion of clonality) it is recommendable to start the appropriate treatment and to conduct a study of the main complications of the mast cell disease. The application of this Score in patients with hymenoptera venom anaphylaxis should be the first step in their management to detect possible underlying diseases.90

In the last years recombinant technologies have represented a great advance in the diagnosis of hymenoptera venom allergy as they provide a profile of sensitisation to specific allergens. Molecular diagnosis helps to discriminate between true sensitisation and cross-reactivity in multiple-venom sensitisation, which is crucial in order to prescribe the appropriate venom immunotherapy. It has also been useful in cases of undetectable sensitisation, due to the higher sensitivity than sIgE to the whole venom.

Hymenoptera venom is a complex mixture of proteins and carbohydrates, although only a small part of them are relevant in the diagnosis of venom allergy. Cross-reactive carbohydrate determinants (CCD) are present in hymenoptera venom, especially in bee venom, and are an important cause of cross-reactivity between them. Recombinant CCD-free allergens solve this problem and allow the differentiation between true sensitisation and cross-reactivity.

Bee venom has been the best characterised by recombinant technologies and currently 12 allergens have been identified. Moreover, several major allergens such as Api m 1, Api m 2, Api m 3, Api m 5 and Api m 10 have been described, which taken together show a diagnostic sensitivity of 95%.20 Apart from CCDs, other allergens have been identified as being responsible for cross-reactivity between bee and wasp venoms, like Api m 2 (hyaluronidase), Api m 5 (dipeptidyl peptidase IV) and Api m 12 (vitellogenin).

Vespid venoms have been less studied, and currently only a few allergens have been described, being phospholipase A1 and Antigen 5 the main allergens. CCDs are responsible for cross-reactivity between bee and wasp venoms, and also between Vespula and Polistes venoms.

Polistes species are very common in southern European countries, and they are spreading all over Europe. European Polistes venom has shown significant differences from American species.

Of special interest is the fact that there seems to be regional patterns in the vespid sensitisation profile, as in the Mediterranean area the sensitisation to phospholipase A1 is predominant compared to antigen 5 sensitisation in contrast with other European regions.3,14

Further investigations are needed in order to identify new allergens especially in vespid venoms, including Polistes which is becoming an increasing cause of allergy in Europe. New studies shall be carried out, to show the role of molecular allergens in the assessment of venom immunotherapy and their utility to identify risk profiles for severe reactions after field stings or venom immunotherapy or even to prevent treatment failures.89,90

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  Molecular diagnosis helps to discriminate between true sensitisation and cross-reactivity.

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  It can also be useful in cases of undetectable sensitisation.

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  Complex patterns of allergen sensitisation are present in bee venom allergic patients.

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  Regional patterns of vespid allergens sensitisation have been found in the Mediterranean area.

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  New investigations are needed to find new allergens specially in vespid venoms.

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  More studies are needed to analyse the utility of recombinant technologies in the monitoring of venom immunotherapy and in the identification of high risk profiles.

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  New recombinant molecules are needed to improve the diagnosis of allergy to vespid venoms.

This work was partially supported by a grant from Comunidad de Madrid S2010/BMD-2502 MITIC

Teresa Alfaya Arias received lecture fees from Alk-Abelló and a research grant from Diater; Elisa Boni received lecture fees from Allergy Therapeutics; Arantza Vega received lecture fees from Alk-Abelló, Leti, Diater, Mundipharma and Novartis; Darío Antolín-Amérigo has received lecture fees from ALK-Abelló, Allergy Therapeutics, AstraZeneca, GlaxoSmithKline and Mundipharma, a research grant from Merck-Serono-Fundación 2000, educational grants from Merck and Pfizer and honoraria for articles from Meda and Mundipharma. María José Sánchez-González received fees from ALK-Abelló, AstraZeneca and Chiesi.

Mercedes Rodríguez-Rodríguez, José Barbarroja-Escudero, Berta Ruiz-León, Carmen Moreno-Aguilar, Leticia Sánchez Morillas, David González-de-Olano and Melchor Álvarez-Mon have no conflicts of interest.