N‐glycan in cockroach allergen regulates human basophil function

Abstract Introduction Cockroach allergen exposure elicits cockroach sensitization and poses an increased risk for asthma. However, the major components in cockroach allergen and the mechanisms underlying the induction of cockroach allergen‐induced allergy and asthma remain largely elusive. We sought to examine the role of cockroach‐associated glycan in regulating human basophil function. Methods N‐linked glycans from naturally purified cockroach allergen Bla g 2 were characterized by MALDI‐TOF mass spectrometry. Binding of cockroach allergen to serum IgE from cockroach allergic subjects was determined by solid‐phase binding immunoassays. Role of cockroach associated glycan in histamine release and IL‐4 production from human basophils was examined. Expression of C‐type lectin receptors (CLRs) and their role in mediating glycan‐uptake in the basophils was also investigated. Results MALDI‐TOF mass spectrometric analysis of N‐glycan from Bla g 2 showed complex hybrid‐types of glycans that terminated with mannose, galactose, and/or N‐acetyl glucosamine (GlcNAc). Deglycosylated Bla g 2 showed reduced binding to IgE and was less capable of inducing histamine release from human basophils. In contrast, N‐glycan derived from Bla g 2 significantly inhibited histamine release and IL‐4 production from basophils passively sensitized with serum from cockroach allergic subjects. An analysis of CLRs revealed the expression of DC‐SIGN and DCIR, but not MRC1 and dectin‐1, in human basophils. Neutralizing antibody to DCIR, but not DC‐SIGN, significantly inhibited Bla g 2 uptake by human basophils. A dose‐dependent bindings of cockroach allergen to DCIR was also observed. Conclusions These observations indicate a previously unrecognized role for cockroach allergen‐associated glycans in allergen‐induced immune reactions, and DCIR may play a role in mediating the regulation of glycan on basophil function.

have also been used to establish an experimental mouse model of allergic diseases [8][9][10]. Importantly, immunotherapy for cockroach allergy has shown the promise as a treatment strategy with improved immune-modulatory and clinical effects in a limited number of trials [11][12][13][14]. This highlights the importance of identifying all major allergenic components in allergens and understanding the mechanisms of cockroachinduced allergy as well as developing therapeutic strategies. So far, a number of cockroach allergens have been identified, sequenced, purified, and produced as biologically active recombinant proteins. These include nine German (Bla g 1-8 and Bla g 11) and nine American cockroach allergens (Per a 1-3, Per a 6-7, and Per a 9-12) [6]. These characterized cockroach allergens have led to an improvement in knowledge of the structure and function of cockroach allergens, and are crucial for the development of improved reagents for both diagnosis and therapy. However, the contribution of other potential virulence factors (i.e. macromolecules such as lipids and carbohydrates) that could be released by the cockroach may also contribute to the development of asthma.
Glycans are sugar notifications attached to glycoproteins and glycolipids. Recent studies have suggested that glycans may be crucial in allergen-induced allergic responses [15,18,19]. More specifically, glycans from Fasciola hepatica have been shown to modulate the host immune response and TLR-induced maturation of dendritic cells [16]. Complex carbohydrates have been considered potent inducers of Th2 responses, and carbohydrate antigens can stimulate the production of different isotypes of glycanspecific antibodies [17]. In particular, surface epitopes mapped from Bla g 2 demonstrated the presence of a surface carbohydrate moiety [18,19] and the removal of this moiety by nucleotide point mutation significantly reduces IgE binding, IL-13 production, and increased levels of IL-10 [20,21]. Furthermore, glycan on allergens may be directly involved in the uptake of allergens by carbohydrate lectin receptors on antigen presenting cells [22]. Our previous works have demonstrated that Bla g 2 contains complex glycans, many of which are mannose terminated, and that they play a critical role in its interaction with the Bla g 2-mannose receptor (MRC1) in cockroach allergen induced allergic immune responses [23]. MRC1 encodes the mannose receptor C-type lectin, a cell surface protein that belongs to a family of C-type lectin receptors (CLRs). Several other CLRs, such as dendritic cell-specific intercellular adhesion molecule-3-grabbing non-integrin receptor (DC-SIGN) and dendritic cell immunoreceptor (DCIR), have demonstrated recognition for particular glycan moieties on various pathogens and facilitate their endocytosis and presentation as pathogens [22,[24][25][26][27]. However, little is known about the function of glycans on cockroach allergens in both antibody-mediated responses and CLR-mediated allergen recognition and modulation of the immune response.
In the present study, we provide further evidence that N-glycans from Bla g 2 are complex hybrid glycans that are terminated with mannose-, galactose-, and/or N-acetyl glucosamine. Moreover, we demonstrate that N-glycan is critical in IgE antibody binding and the induction of histamine release from basophils. Furthermore, N-glycan purified from Bla g 2 is able to inhibit cockroach allergic serum-induced histamine release and IL-4 production. Importantly, while no MRC1 is expressed on basophils, we provide evidence supporting a critical role of DCIR on the human basophil in mediating cockroach allergen uptake.

Protein and glycoprotein staining
Cockroach whole body extract from Blattella germanica (Greer) was separated by SDS-PAGE and stained for total protein using Colloidal Coomassie Blue (Thermo Fisher, Waltham, MA, USA) as directed by the manufacturer. Glycoproteins were stained using the periodic acid-Schiff stain as described elsewhere [28]. Images were then taken of the gel and quantified using ImageJ, Bethesda, MD, USA v1.49u (NIH).
Protein immobilization, N-glycan release, and de-glycosylation of native Bla g 2 Purified Bla g 2 (Indoor Biotechnology, Charlottesville, VA, USA) was immobilized and coupled to a solid support by Glycoprotein Immobilization for Glycan extract (GIG) as previously described [29,30]. In brief, native Bla g 2 was immobilized on Aminolink resin in 500 mL of binding buffer (100 mM sodium citrate and 50 mM sodium carbonate) with the addition of 400 mL of 1 M p-toluidine in 1 N HCl with 40 mL EDC (N- [3-dimethylaminopropyl]-N 0ethylcarbodiimide) and 25 mL concentrated HCl. After immobilization, the active aldehyde sites on Aminolink resin was blocked with 50 mM NaCNBH 3 in 1 M Tris-HCl; 30 min, p-toluidine was added and the sample was incubated at room temperature for 4 h. The resin was washed with 1% formic acid, 10% ACN (0.1% TFA), 1 M NaCl, and DI water. To release N-glycan from resin immobilized Bla g 2, the resin was treated with PNGase F (NEB) overnight at 378C. The supernatant was collected and further purified with Carbograph cartridge [31]. A 500 mL solution consisting of 80% ACN in 0.1% TFA was used to elute N-glycans from the Carbograph cartridge. The eluted sample was dried in a vacuum (Savant SPD SpeedVac) for MALDI-MS (Shimadzu Resonance Axima, Kyoto, Japan). In contrast, to deglycosylate native Bla g 2, PNGase F was immobilized on Aminolink resin as described above. The resin was incubated with native Bla g 2 in GlycoBuffer 2 (NEB) and incubated at 378C overnight. The reaction was passed through a Carbograph cartridge and the eluted samples (containing deglycosylated Bla g 2) were dried in a vacuum (Savant SPD SpeedVac) and then re-suspended in PBS.

MALDI-MS
N,N-dimethylaniline (4 mL) was added to 200 mL DHB (2,5-dihydroxybenzoic acid) (prepared by dissolving 200 mg DHB in 200 mL solution consisting of 0.1 mM NaCl in 50% ACN). The N-linked glycans were dissolved in 40 mL DI in 0.2% TFA, in which 5 mL sample was deposited on m-Focus MALDI plate together with 1 mL of DHB-DMA matrix. The laser power was set to observe typical glycan profiles using either human serum or bovine fetuin with minimum glycan fragmentation in MS1 [30]. Mass range was focused on m/z 850-2200, respectively, while the average MS spectrum was acquired from 400 MS profiles using Shimadzu Biotech Launchpad (version 2.9.1). Glycan assignment was based on accurate mass, GlycoWorkBench [32], and the Consortium of Functional Glycomics (CFG).

Cockroach allergic subjects
De-identified serum samples used in this study were provided by the Johns Hopkins University Dermatology, Allergy and Clinical Immunology (DACI) Reference Laboratory directed by Dr. Robert G. Hamilton. Information for these study subjects are presented in Table 2. All studies presented in these studies were reviewed and approved by the Johns Hopkins University Institution Review Board.

IgE antibody measurement by solid-phase binding assay
Solid-phase binding assays were performed using EIA/RIA 96-well flat bottom plate (Costar, Columbia, MD, USA) coated with 0.5 mg/mL of CRE, glycosylated, or deglycosylated Bla g 2 in PBS overnight at 48C. The plate was blocked with 5% w/v bovine serum albumin in TBST (50 mM Tris, 150 mM NaCl, and 0.05% v/v Tween 20) for 1 h and probed with undiluted serum from German cockroach allergic donor subjects for 4 h. The plate was washed and bound IgE antibody was detected using biotinylated monoclonal anti-human IgE and streptavidinhorseradish peroxidase. Optical density at 480 nm was measured after the addition of 3,3 0 ,5,5 0 -tetramethylbenzidine and H 2 O 2 .

Cell preparation and culture
Venous blood specimens were anti-coagulated with EDTA and subjected to double Percoll density centrifugation, as described elsewhere [33]. The isolated basophils were quantified by Alcian blue stain and cultured in media consisting of Iscove's modified Dulbecco's medium supplemented with 5% FCS, nonessential amino acids, and 10 mg/mL gentamicin (C-IMDM).

Basophil sensitization and challenge
Surface-bound IgE from donor basophils was removed using cold lactic acid solution (pH, 3.9) [34], washed, and passively sensitized for 30 min with total IgE levels of 500 ng/mL from cockroach allergic serum (as determined by ImmunoCap, Thermofisher Scientific, Halethorpe, MD, USA). It was then challenged with 100 ng/mL of Bla g 2 or deglycosylated Bla g 2 in C-IMDM in a humidified incubator at 378C, 5% CO 2 . Cultures were performed in a total volume of 250 mL. Histamine release was measured after 30 min by taking the top 0.05 mL of culture supernatant, diluting in 1 mL acid solution for overnight protein precipitation, and assaying using automated fluorimetry as previously described [34]. IL-4 protein was measured after 4 h incubation by taking the remaining cell-free supernatant and assaying by ELISA using the Read-Set-Go! ELISA set (eBioscience, San Diego, CA, USA).

Binding of cockroach allergen to DCIR
EIA/RIA 96-well flat bottom plates (Costar) were coated in duplicate with 10 ug/mL of CRE, mannan-BSA, or BSA for 18 h at 48C, blocked with 1% BSA in TBST with 100 ug/mL of CaCl 2 for 1 h at room temperature. Purified recombinant human DCIR-6xHis (Sino Biological, Beijing, P.R.China) dissolved in blocking buffer was incubated for 1 h at room temperature, washed, and incubated with horseradish peroxidase-conjugated anti-6xHis (Santa Cruz Biotechnology, Santa Cruz, CA, USA). The absorbance was recorded at 450 nm in an ELISA reader (BioRad, Hercules, CA, USA).

Uptake of cockroach allergen by basophils through DCIR
For allergen uptake assays, the purified native Bla g 2 was labeled with Lightning-Link FITC Antibody Labelling Kit (Odenton, MD, USA). Different doses of FITC labeled purified Bla g 2 were co-incubated with the cultured basophils (2 Â 10 5 ) for 1 h at 378C. Bla g 2 uptake was detected by immunofluorescence staining and flow cytometry, an isotype IgG2a was used as a control.

Statistical analysis
Statistical significance for normally-distributed samples was assessed using an independent two-tailed Student's t-test by using GraphPad Prism version 5.1 software (GraphPad Prism, La Jolla, CA, USA). Data are expressed as the means AE SEM for each group. Differences with P < 0.05 were considered statistically significant.

Characterization of cockroach glycoproteins
To define the glycosylated proteins in cockroach extract (CRE), CRE was separated on SDS-PAGE. Both proteins and glycoproteins were assessed by Coomassie Brilliant Blue and periodic acid-Schiff staining, respectively (Fig. 1A). Similar to fetuin (Fet), a control for the glycosylated blood protein, several major bands were identified in CRE. When these visualized glycoprotein bands were quantified by densitometric analysis with ImageJ v1.49 (Fig. 1B), several peaks were noted at approximate MWs of 27, 37, 47, 55, and 75 KD. These prominent bands correspond with known cockroach allergens such as Bla g 2 (37 KD) [35], Bla g 3 (75 KD) [36], and Bla g 11 (55 KD) (unpublished) with one or multiples Asn-X-Ser/Thr N-glycosylated sequon (Fig. 1C). These data provide evidence that the cockroach extract contains multiple glycosylated proteins.

Profiling of N-glycan from purified natural Bla g 2 using MALDI-MS
To determine the importance of N-glycans in cockroach allergen, we investigated the N-glycan structure of purified Bla g 2. N-glycan was cleaved by PNGase F and a shifted glycosylated allergen in Bla g 2 was observed at an approximate MW of 37 (lower band) ( Fig. 2A). N-glycans were analyzed by MALDI-MS (Fig. 2B). A total of 51 distinct N-glycan fragments were identified in a mass range of m/z 850-2200 from the average of 400 mass spectra profiles using Shimadzu Biotech Launchpad, Kyoto, Japan (version 2.9.1) (Table S1). These identified N-glycans were of two general types: complex and hybrid, with core fucose oligosaccharide modifications. In particular, these complex N-glycans with the core fucose oligosaccharide modifications are ubiquitously found in plants and insects (i.e. cockroaches) [37]. For example, the N-glycans at m/z 1914.7, 1834.7, 2279.8, and 2361.9 contain di-fucose moieties linked to N-acetyl-glucosamine residues. In addition, many of these N-glycans terminated with galactose (32/51). Among these, several identified glycans have shown unique terminated carbohydrate moieties and associations with allergic immune responses [23,26,[38][39][40] (Table 1). Together, these data indicate that several major N-glycans in Bla g 2 may be involved in cockroach allergen-induced allergic responses.

Deglycosylated Bla g 2 had a reduced IgE binding and histamine release in basophils
To determine the role of N-glycans in cockroach allergeninduced allergic responses, we examined the binding of Bla g 2 or deglycosylated Bla g 2 to German cockroach specific IgE antibody. We quantified the levels of Bla g 2 specific IgE (sIgE) in a total of 39 subjects who are allergic to cockroach allergen ( Table 2). Among these, serum from 9 subjects had higher levels of specific IgE antibodies (e.g. OD > 0.10, Fig. 3A). We next selected those subjects with higher levels of sIgE and examined the difference in binding capability of Bla g 2 or deglycosylated Bla g 2 to those specific IgE antibodies (Fig. 3B). Compared to glycosylated Bla g 2, deglycosylated Bla g 2 showed a significant reduction in the levels of sIgE binding. To confirm the importance of glycan in IgEmediated responses, we passively sensitized human basophils with serum from subject 1867 and challenged with either glycosylated or deglycosylated Bla g 2 (Fig. 3C). We observed that deglycosylated Bla g 2 induced significantly less histamine release compared to glycosylated Bla g 2 (Fig. 3D). Taken together, these results indicate that N-glycan is important for the interaction of IgE antibody with cockroach allergen.

N-glycan inhibits spontaneous histamine release
Given that complex carbohydrate has been shown to have immune modulatory properties [41,42], we tested whether N-glycan could modify histamine release from basophils using the experimental approach described in Figure 4A. Interestingly, we found that N-glycan significantly inhibited the spontaneous histamine release from basophils sensitized with serum from cockroach allergic subjects (Fig. 4B). Interestingly, similar results were found when serum from milk allergic subjects was used (Fig. 4C). Furthermore, IL-4 production, which typically correlated with IgE-dependent histamine release, but is generated de novo 1-4 h after degranulation, was also measured. Consistent with histamine release, we found that N-glycan significantly inhibited IL-4 secretion spontaneously released from basophils passively sensitized by serum from cockroach (Fig. 4D) and milk allergic subjects (Fig. 4E). However, N-glycan did not affect histamine release in basophils activated by either a-IgE or N-Formylmethionine (fMET) or by IgE cross-linking (Fig. 4F). Taken together, these results support the conclusion that N-glycan can alter basophil function by suppressing spontaneous histamine release and IL-4 production.

Expression of C-type lectin receptor on human basophil
Glycan-lectin interactions have been shown to be important for allergen-uptake and the induction of allergen-induced

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Th2 responses [22]. We detected several major C-type lectin receptors (CLRs) on human basophils. Basophils were isolated from the blood of human donors and selected with Alcian Blue staining (Fig. 5A) to >%95 purity (Fig. 5B). CLR expression on these isolated basophils was assessed by flow cytometry. DC-SIGN (Fig. 5C) and DCIR (Fig. 5D) were significantly expressed on human basophils. In contrast, there was no expression for MRC1 (Fig. 5E) and dectin-1 (Fig. 5F). These data indicate that DC-SIGN and DCIR may be major CLRs contributing to the mediation of allergeninduced basophil activation.

DCIR mediates cockroach allergen uptake by human basophils
CLRs expressed on basophils may be involved in mediating allergen-uptake. Indeed, we found that FITC-Bla g 2 was taken up by basophils as determined by immunostaining (Fig. 6A). The Bla g 2 uptake by basophils was further confirmed by flow cytometry analysis (Fig. 6B). To determine whether cockroach allergen uptake is dependent on surface CLRs, we pre-treated basophils with either a-DC-SIGN or a-DCIR antibody, and then co-cultured with FITC-Bla g 2 at 378C for 30 min. While no clear reduction in FITC-Bla g 2 uptake was observed for basophils pre-treated with a-DC-SIGN ( Fig. 6C and E), a significant reduction was observed when basophils were pre-treated with a-DCIR ( Fig. 6D and E). To further test whether cockroach allergen can bind to DCIR, cockroach extract (CRE) was incubated with different doses of purified recombinant human DCIR (Fig. 6F). Consistent with the Man-BSA, a positive control, CRE showed a dose-dependent binding to DCIR. No binding was seen for BSA, a negative control. These results demonstrate that DCIR may be one of the major CLRs that has the capacity to alter allergeninduced activation of basophils.

Discussion
Bla g 2 has been identified as one of the most important cockroach allergens as it elicits IgE antibody responses in 40-70% of cockroach allergic individuals [37,45,46]. Compared to cat and mite allergens, Bla g 2 is able to induce IgE production, even at 10 to 100-fold lower exposure [43]. Furthermore, exposure to Bla g 2 has been linked with wheezing among infants in the first three months of life and with increased T cell proliferation [44]. It was assumed that Bla g 2's proteolytic activity contributes to its allergenicity, but structural analysis suggests that Bla g 2 is an inactive aspartic protease [45,46]. Thus, it is important to identify the potential virulence factors in cockroach allergens, particularly in Bla g 2, which could contribute to the development of asthma.
Here, we demonstrate that a number of glycosylated proteins are present in CRE. Interestingly, we found that one of the most prominent glycosylated proteins corresponded to Bla g 2 [35]. Using glycomic studies, we revealed that Bla g 2 contain N-glycans that are complex hybrid-types that are terminated with mannose-, galactose-, and/or GlcNAc. While we have previously reported predominately high mannose N-glycans in Bla g2 [23], this work provides further validation and more extensive analyses by providing a comprehensive list of glycans with more complex structures in Bla g 2. As expected, many of Figure 3. Cockroach allergen specific IgE binding and histamine release for Bla g 2 with or without N-glycan. (A) Serum from cockroach allergic subjects (n ¼ 39) were tested for the levels of Bla g 2 specific IgE (sIgE, OD 480 nm) using ELISA. Dash line indicates mean (2SEM). 1096 was used as a negative control (non-allergic). (B) Bla g 2 specific IgE antibody was measured using Bla g 2 with (glycan-Bla g 2) or without glycan (no glycan-Bla g 2) using sera from cockroach allergic subjects (A) with higher levels of specific IgE. (C) Experimental protocol testing the effect of glycan on histamine release (HR). (D) Histamine release (HR) from basophils that were sensitized with cockroach allergic serum and challenged with Bla g 2 or deglycosylated Bla g 2. C-IMDM: conditioned Iscove's Modified Dulbecco's Medium. Data represent mean AE SEM. ÃÃ P < 0.01, ÃÃÃ P < 0.001. N-glycan and basophil function D. C. Do et al. these identified N-glycans are common variants of the core fucose oligosaccharide modifications that are ubiquitously found in plants and insects [37]. These glycan structures are distinct from human endogenous glycans. It is likely that some of these glycans may contribute to the allergenicity of cockroach allergen. Indeed, the immunogenicity of some of these identified glycans have been reported in human and mouse models [47,48]. More specifically, glycans terminated with mannose are able to modulate fibrocyte function through interacting with MRC1 [23], or regulate myeloid DCs through DC-SIGN [38], or trigger cysteinyl leukotriene generation via Dectin-2 [49]. Glycans terminated with galactose, for example, galactose alpha-1, 3-galactose (alpha-gal), have been associated with delayed type anaphylaxis to red meat in patients with a-Gal specific IgE [39]. a-Gal is a sugar chain commonly found as part of glycoproteins and glycolipids in mammals [50]. In addition, glycans terminated with GlcNAc are critical in egg-white ovalbumin-induced IgE production and Th2 cytokine secretion [51]. Taken together, these findings provide evidence supporting a role of glycans in allergic immune responses to cockroaches. We next examined the role of N-glycans in Bla g 2 in bindng IgE antibody using serum from cockroach allergic subjects with high levels of Bla g 2-specific IgE. Interestingly, we observed a significant reduction in IgE binding to Bla g 2 with the removal of its N-glycan compared to binding to native glycosylated Bla g 2. These data indicate that N-glycan may be a critical component involved in IgE antibody binding to Bla g 2. This raises the possibility that N-glycan present in Bla g 2 is able to induce anti-glycan IgE responses. Indeed, we found that Bla g 2-derived N-glycan alone can directly bind to IgE in the serum from cockroach allergic subjects (Data not shown). This observation is also consistent with previous reports that $15-30% of allergic patients produce specific anti-glycan IgE [52][53][54][55]. The core-3-linked fucose is one of the most common epitopes in allergens that is recognized by human IgE antibodies [40].
We also investigated whether reduced binding to IgE antibody occurs when N-glycans are removed from Bla g 2. Moreover, does reduced binding alter the ability of IgE antibody to trigger mediator release from sensitized basophils? We observed that deglycosylated Bla g 2 induced less histamine release when compared to glycosylated Bla g 2. These findings are further supported by recent studies showing that anti-glycan IgE from allergic patients can induce mediator release from mast cells. Anti-CCD (crossreactive carbohydrate determinant) IgE is also sufficient to trigger mediator release from basophils [17,[56][57][58]. Collectively, these results suggested that N-glycan is important for allergen binding to IgE antibody and potentially alter down-stream mediator release from human basophils.
Given the significance of glycans in allergen binding to IgE antibody and activation of basophils, it was of interest to see whether glycans on their own could contribute to the induction of allergic responses, particularly histamine release from basophils. Basophils from food allergic children have been shown to release histamine ''spontaneously'' during incubation of suspensions in vitro without the addition of antigen [59]. We therefore pre-treated basophils with N-glycan directly to see whether glycan could induce spontaneous histamine release as well as that induced by allergen. Unexpectedly, basophils treated with glycan spontaneously released much lower levels of histamine when compared with those that were un-treated (Data not shown), suggesting that glycan may have a suppressive role in this response. In contrast, allergen-induced histamine release was not affected by pretreatment with glycan. It's recently been reported that spontaneous histamine is transferable to basophils of non-allergic subjects following passive sensitization with serum from allergic subjects-a reaction dependent on IgE [60]. We further confirmed this finding by using basophils passively sensitized with serum from a cockroach allergic individual. Whereas spontaneous histamine release was transferred following this sensitization, basophils pre-treated with glycan released significantly less histamine in medium alone. This finding was further replicated using the same experimental approach but with serum from milk allergic subjects. Like histamine, a similar pattern was observed for IL-4 in supernatants of these treated basophils. These results indicate that glycan alone can modify basophil function by suppressing spontaneous histamine release and IL-4 production. However, we did not find the inhibition of histamine release by glycan when basophils were activated by a-IgE or fMET or IgE-dependent cross-linking. We assumed that the dose of glycan used may not have been sufficient to inhibit basophil activation triggered by via IgE cross-linking. Also, it is likely that the glycan inhibition may be through non-IgE-mediated signaling pathways such as the glycan-CLR axis.
CLRs are abundantly expressed on the surface of antigenpresenting cells [61]. Lectin-carbohydrate interactions are critical in pathogen recognition and stimulation of innate immune responses and it can modulate glycan immunogenicity [22,62]. For instance, glycans in house dust mite extract induce Th2 differentiation through interaction with Dectin-2 on DCs and lead to the generation of cysteinyl leukotrienes [49]. Our previous studies also demonstrated that MRC1 on fibrocytes mediate cockroach allergen binding, internalization, and down-stream immune reactions [23]. To determine the role of CLRs in basophils, we analyzed several major CLRs that have been reported for their interactions with glycans terminated with mannose (MRC1 [23]), galactose (DC-SIGN [38]), and/or GlcNAc (Dectin-2 [49]). Another important CLR, DCIR, was also included in our analysis. DCIR, containing immunoreceptor tyrosine-based inhibitory motifs in their cytoplasmic tails, has been shown to regulate the suppression of TLR-induced IL-12 and TNF production by DCs [63][64][65]. We found that human basophils predominately express DCIR and DC-SIGN, but not MRC1 and Dectin-2. Furthermore, DCIR, but not DC-SIGN, mediates cockroach allergen-uptake by basophils, suggesting that DCIR may be one of the major CLRs contributing to the allergen-induced activation of basophils.
Collectively, we report that Bla g 2 contains glycans with complex structures, and that N-glycan is critical in IgE binding and histamine release from basophils. Furthermore, we have demonstrated, for the first time, that N-glycan purified from Bla g 2 has a suppressive role in spontaneous histamine release and IL4 production from basophils sensitized with cockroach allergic serum. Importantly, DCIR may serve as a target for future investigation into its role in mediating allergen recognition, particularly for selected glycans that may modulate basophil function. As a result, these studies suggest a new conceptual framework for the role of glycan in allergen-induced allergic responses by linking the glycan/allergen-DCIR axis to basophil activation and development of allergic disease and asthma.

Author Contributions
PG and DCD designed experiments. DCD performed the experiments and analyzed the data. SY, XY, RGH, and JTS helped with the experiments and data analysis. PG and DCD wrote the manuscript.