Heterogeneity of antibody responses among clinical responders during grass pollen sublingual immunotherapy.

BACKGROUND: During allergen-specific sublingual immunotherapy (SLIT), the relevance of changes in specific IgE and IgG antibody titres to treatment efficacy remains to be evaluated at an individual patient level. OBJECTIVE: To investigate whether antibody responses can be used as biomarkers for SLIT efficacy. METHODS: Comprehensive quantitative, qualitative and functional analyses of allergen-specific IgA, IgE, IgG1-4 and IgM responses were performed using purified Phl p 1 to 12 allergens in sera, saliva and nasal secretions from 82 grass pollen allergic patients. These patients were enrolled in a randomized, double-blind placebo-controlled study and assessed in an allergen challenge chamber (ClinicalTrials.gov NCT00619827). Antibody responses were monitored in parallel to clinical responses before and after daily sublingual treatment for 4 months with either a grass pollen or a placebo tablet. RESULTS: A significant mean improvement (i.e. 33-40.6%) in rhinoconjunctivitis total symptom scores was observed in SLIT recipients, irrespective of their baseline patterns of IgE sensitization (i.e. narrow, intermediate, broad) to grass pollen allergens. SLIT did not induce any de novo IgE sensitization. Clinical responders encompassed both immunoreactive patients who exhibited strong increases in titres, affinity and/or blocking activity of grass-pollen-specific IgGs (representing 17% of treated patients), as well as patients with no detectable antibody responses distinguishing them from the placebo group. No significant changes were detected in antibody titres in saliva and nasal washes, even in clinical responders. CONCLUSIONS AND CLINICAL RELEVANCE: Sublingual immunotherapy with a grass pollen tablet is efficacious irrespective of the patients' baseline sensitization to either single or multiple grass pollen allergens. Seric IgG responses may contribute to SLIT-induced clinical tolerance in a fraction (i.e. 17%) of patients, but additional immune mechanisms are involved in most patients. Consequently, antibody responses cannot be used as a marker of SLIT efficacy at an individual patient level.

Prevalence of sensitisation to oilseed rape and maize pollens in France: a multi-center study carried out by the Allergo-Vigilance Network.

BACKGROUND: Oilseed rape and maize crops represent a large part of agriculture fields in European countries. OBJECTIVE: To establish the actual prevalence of sensitization to oilseed rape and maize pollen, and to determine if this is correlated to the amount of exposure as well as to the patient's history of atopy or asymptomatic atopy. METHODS: The study was conducted by 69 allergists belonging to the Allergo-Vigilance Network, in collaboration with the French Agency for Safety of food, and compiles the results of skin prick-tests using oilseed rape and maize pollens and seeds, as well as common aeroallergens. The patients were classified into 3 groups: nonatopic, asymptomatic atopy, and actual atopic diseases. RESULTS: Among the 5372 subjects studied (2515 children, 2857 adults), 62.3% had an atopic disease, 10.2% had an asymptomatic atopy, and 27.5% were non-atopic. The level of sensitization was higher in the subjects with atopic disease, as compared to those with asymptomatic atopy: oilseed rape pollen: 11.8% vs 8%, maize pollen, 26% vs 19%, oilseed rape seeds, 7.7% vs 6.9%, corn seeds: 8.3% vs 4.8% (p < 0.001). The rate of sensitization was significantly increased in those living in high crop density regions. The association of an atopic disease with a high rate of exposure yielded a higher rate of sensitization of 13.8% and 21.3% for rapeseed pollen, and 22.9% and 30.7% for maize pollen in both children and adults, respectively. CONCLUSIONS: The incidence of sensitisation to rapeseed and maize pollen is positively correlated to the level of exposure. This prevalence is higher in patients with actual atopic disease as compared to those with asymptomatic atopy. The frequency of sensitization confirms the allergenicity of these plants destined for food supply and demonstrates the importance of monitoring for respiratory allergies to these pollens, not only in workers exposed to these types of crops, but also in atopic patients living in regions that contain a high density of rapeseed and maize fields. Cross-reactivities between pollens and seeds could potentially elicit cross-reacting food allergies.

Characterization of peptidic and carbohydrate cross-reactive determinants in pollen polysensitization.

BACKGROUND: Cross-reactivity may be due to protein sequence or domain homologies and/or the existence of cross-reactive carbohydrate determinants (CCDs). The clinical relevance of peptidic cross-reactivities is well known, whereas that of CCDs is still a question of debate. The aim of this study is to characterize the IgE specificity of various patients suffering from pollen polysensitization to identify both peptidic and carbohydrate cross-reactive determinants. MATERIAL AND METHODS: Rapeseed, grass and Arabidopsis proteins were separated by isoelectric focusing, followed by SDS-PAGE, and transferred to a nitrocellulose sheet. The sheets were incubated either with an individual serum from a birch+grass-sensitive patient, followed by anti-human IgE, or with labelled Concanavalin A (ConA). Binding inhibition was tested by incubation of the sera with a mixture of sugar residues. RESULTS: The results showed two different patterns of cross-reacting sera: a pattern that implies few proteins, not always glycosylated and known as allergens, and a pattern that implies numerous proteins with molecular masses over 30 kDa. This second pattern was very close to the ConA -binding pattern. The IgE binding was abolished by pre-incubation with sugar residues only in the case of the second pattern. DISCUSSION: This study shows that multiple pollen sensitizations could result from multiple sensitizations to specific proteins or from a cross-sensitization to a wide range of glycoproteins. Two-D blots allow to characterize a cross-sensitization due to carbohydrate determinants, and thus to improve the diagnosis of allergy and its medical treatment.

Modifications of Phleum pratense grass pollen allergens following artificial exposure to gaseous air pollutants (O(3), NO(2), SO(2)).

BACKGROUND: Air pollution is frequently proposed as a potential cause of the increased incidence of allergy in industrialised countries. Our objective was to investigate the impact of the major gaseous air pollutants on grass pollen allergens. METHODS: Timothy grass pollen was exposed to ozone (O(3)), nitrogen dioxide (NO(2)) and sulphur dioxide (SO(2)) alone or in combination. Allergen contents were analysed by 2-dimensional immunoblot using grass pollen-sensitive patient sera. RESULTS: For O(3)-treated pollen, immunoblotting showed an acidification of allergens Phl p 1b, Phl p 4, Phl p 5 and Phl p 6 and an IgE recognition decrease in Phl p 1, Phl p 2, Phl p 6 and Phl p 13. NO(2) exposure induced a decrease in Phl p 2, Phl p 5b and Phl p 6 recognition, and SO(2) treatment induced a decrease in Phl p 2, Phl p 6 and Phl p 13 recognition. Moreover, samples treated with a mix of NO(2)/O(3) or NO(2)/SO(2) showed a higher decrease in allergen content, compared with samples treated with only one pollutant. The O(3) acidification was also observed with the NO(2)/O(3) mix. CONCLUSION: Exposure of pollen to gaseous pollutants induced a decrease in allergen detection in pollen extracts. This decrease could be due to a mechanical loss of allergens from the altered pollen grains and/or post-translational modifications affecting allergen recognition by IgE.

Traffic-related air pollutants induce the release of allergen-containing cytoplasmic granules from grass pollen.

BACKGROUND/AIM: Pollen cytoplasmic granules (PCG) are loaded with allergens. They are released from grass pollen grains following contact with water and can form a respirable allergenic aerosol. On the other hand, the traffic-related air pollutants NO2 and O3 are known to be involved in the current increase in the prevalence of allergic diseases via their adjuvant effects. Our objective was to determine the effects of air pollutants on the release of PCG from Phleum pratense (timothy grass) pollen. METHODS: P. pratense pollen was exposed to several concentrations of NO2 and O3. The induced morphological damages were observed by environmental scanning electron microscopy, and the amount of PCG released from the pollen upon contact with water was measured. RESULTS: The percentages of damaged grain were 6.4% in air-treated controls, 15% after treatment with the highest NO2 dose (50 ppm) and 13.5% after exposure to 0.5 ppm O3. In treated samples, a fraction of the grains spontaneously released their PCG. Upon subsequent contact with water, the remaining intact grains released more PCG than pollen exposed to air only. CONCLUSIONS: Traffic-related pollutants can trigger the release of allergen-containing granules from grass pollen, and increase the bioavailability of airborne pollen allergens. This is a new mechanism by which air pollution concurs with the current increase in the prevalence of allergic diseases.

Cloning, expression and immunological characterization of full-length timothy grass pollen allergen Phl p 4, a berberine bridge enzyme-like protein with homology to celery allergen Api g 5.

BACKGROUND: Timothy grass pollen is a common cause of respiratory allergy in the temperate regions. The major group 4 allergen, Phl p 4, has previously been purified and studied biochemically and immunologically, but has so far not been produced and characterized as a recombinant protein. OBJECTIVE: To clone and characterize timothy grass pollen allergen Phl p 4. METHODS: Full-length Phl p 4 cDNA was cloned using a PCR-based strategy including 3'-and 5'-RACE. Recombinant Phl p 4 was expressed in Escherichia coli and purified by immobilized metal ion affinity chromatography. Its immunological activity was investigated using experimental ImmunoCAP tests, sera from Phl p 4 sensitized individuals and Phl p 4 reactive polyclonal and monoclonal animal antibodies. RESULTS: Five full-length Phl p 4 cDNA clones were analysed. Sequence deviations between the clones were present at nine amino acid positions, and the consensus sequence comprised an open reading frame of 525 amino acids, including a predicted 25-residue signal peptide. The calculated molecular weight of the deduced mature protein was 55.6 kDa and the isoelectric point 9.9, both consistent with previously observed properties of purified nPhl p 4. Close sequence similarity was found to genomic clones from several other Pooideae grass species and to Bermuda grass pollen allergen BG60. Further, similarity was found to members of the berberine bridge enzyme (BBE) family, including celery allergen Api g 5. Recombinant Phl p 4 bound specific immunoglobulin (Ig)E from 31 of 32 nPhl p 4-reactive sera, and the IgE binding to rPhl p 4 could be inhibited by nPhl p 4 in a dose-dependent manner. CONCLUSIONS: Full-length Phl p 4 cDNA was cloned and showed sequence similarity to members of the BBE family. Recombinant Phl p 4 was produced and shared epitopes with natural Phl p 4.

Intratracheal instillation of cytoplasmic granules from Phleum pratense pollen induces IgE- and cell-mediated responses in the Brown Norway rat.

BACKGROUND: Release of cytoplasmic granules from grass pollen upon contact with water is thought to be an important source of airborne allergens. OBJECTIVES: To investigate the humoral and cellular responses to intratracheal instillation of Phleum pratense (timothy grass) pollen cytoplasmic granules (PCG) in the Brown Norway rat. METHODS: PCG were purified from timothy grass pollen by filtration through 5-microm-mesh filters. Rats were sensitized (day 0) and challenged (day 21) intratracheally with purified PCG suspended in saline (6 x 10(6) PCG/rat). Rats were then challenged 4 weeks later (1.5 x 10(6) PCG/rat). Blood samples, bronchial lymph nodes and lungs were collected from the rats 4 days after the second challenge. PCG-specific IgE and IgG1 levels and specificity were determined by ELISA and Western blotting. Pollen, pollen extract and PCG-induced proliferation of lymph node cells were monitored by [(3)H]-thymidine incorporation in a lymph node assay. Histopathological examination was carried out on the lungs. RESULTS: Specific IgE and IgG1 were present in the sera. Cultured lymph node cells proliferated in the presence of pollen, pollen extract and PCG. Western blots showed that all major pollen allergens are recognized by IgE and IgG1 from PCG-treated rats. Histopathological examination revealed features of a mild allergic reaction. CONCLUSIONS: In our rat model of allergy, purified timothy grass PCG instillation induced specific antibodies and lymph node cell responses, comparable to those obtained with intact pollen.

Phleum pratense pollen starch granules induce humoral and cell-mediated immune responses in a rat model of allergy.

BACKGROUND: Timothy grass (Phleum pratense) pollen allergens are an important cause of allergic symptoms. However, pollen grains are too large to penetrate the deeper airways. Grass pollen is known to release allergen-bearing starch granules (SG) upon contact with water. These granules can create an inhalable allergenic aerosol capable of triggering an early asthmatic response and are implicated in thunderstorm-associated asthma. OBJECTIVE: We studied the humoral (IgE) and bronchial lymph node cells reactivities to SG from timothy grass pollen in pollen-sensitized rats. METHODS: Brown-Norway rats were sensitized (day 0) and challenged (day 21) intratracheally with intact pollen and kept immunized by pollen intranasal instillation by 4 weeks intervals during 3 months. Blood and bronchial lymph nodes were collected 7 days after the last intranasal challenge. SG were purified from fresh timothy grass pollen using 5 microm mesh filters. To determine the humoral response (IgE) to SG, we developed an original ELISA inhibition test, based on competition between pollen allergens and purified SG. The cell-mediated response to SG in the bronchial lymph node cells was determined by measuring the uptake of [3H]thymidine in a proliferation assay. RESULTS: An antibody response to SG was induced, and purified SG were able to inhibit the IgE ELISA absorbance by 45%. Pollen extract and intact pollen gave inhibitions of 55% and 52%, respectively. A cell-mediated response was also found, as pollen extract, intact pollen and SG triggered proliferation of bronchial lymph node cells. CONCLUSIONS: It was confirmed that timothy grass pollen contains allergen-loaded SG, which are released upon contact with water. These granules were shown to be recognized by pollen-sensitized rats sera and to trigger lymph node cell proliferation in these rats. These data provide new arguments supporting the implication of grass pollen SG in allergic asthma.

Lipid transfer protein 1 is a possible allergen in Arabidopsis thaliana.

BACKGROUND: The Arabidopsis thaliana genome was recently fully sequenced, and this plant is now considered as the most useful model to study the effects of genetic engineering. The aim of the present study was to identify A. thaliana IgE-binding molecules and to localize their genes in order to evaluate the potential effect of gene insertion on the expression of IgE-binding molecules. METHODS: A. thaliana flower proteins were separated by two-dimensional gel electrophoresis and transferred onto a nitrocellulose sheet. The nitrocellulose sheet was successively incubated with human sera known to contain IgE that binds to rapeseed proteins, alkaline phosphatase-conjugated goat anti-human IgE and 5-bromo-4-chloro-3-indolyl phosphate and nitroblue tetrazolium. One allergen was further identified by N-terminal amino acid microsequencing. RESULTS: The results showed that some individuals possessed IgE that recognized numerous proteins with high molecular masses and various isoelectric points. This binding pattern strongly suggests that the epitopes recognized by these IgE could be, at least partly, sugar residues. Otherwise, out of the 10 sera that possessed IgE to Arabidopsis flower proteins, one serum strongly recognized a unique basic protein with an apparent molecular mass of around 14 kD. This protein was identified by amino acid microsequencing as the lipid transfer protein 1 (LTP1). CONCLUSION: We have demonstrated that A. Thaliana LTP1 is IgE reactive. The gene encoding this protein is located on chromosome 2, but it has been described that family 1 of A. Thaliana LTPs constitutes a multigenic family with genes located on various chromosomes.

Polygalacturonase (pectinase), a new oilseed rape allergen.

BACKGROUND: Type I hypersensitivity to rapeseed pollen allergens was described as the result of a cross-sensitization with various pollens that could constitute an aggravating factor in birch or grass pollen allergies. Recently, a few rapeseed pollen allergens were described. The aim of the present work was to identify new rapeseed pollen allergens by using two-dimensional gel analysis, microsequencing, and mass spectrometry. METHODS: Water extractable proteins from oilseed rape pollen or stamen were separated by two-dimensional gel electrophoresis. The proteins were then electroblotted onto a nitrocellulose (NC) sheet. The NC sheets were successively incubated with (1) individual human sera pre-selected for their immunoglobulin E (IgE) reactivity to rapeseed pollen proteins, (2) alkaline phosphatase (AP)-conjugated goat anti-human IgE and (3) AP substrate. The allergens localized by this method were then identified by microsequencing and MALDI-TOF mass spectrometry analysis. RESULTS: Of the 18 sera studied, five recognized a wide multispot zone with a molecular mass around 43 kD and pIs between 6.5 and 8.5. The results obtained with two representative sera are shown. From this zone, two isoforms of the polygalacturonase enzyme were identified by microsequencing. Confirmation was obtained through MALDI-TOF mass spectrometry analysis. CONCLUSION: The present results allow the identification of a new rapeseed allergen that can be the main allergen for some patients.

Effects of birch pollen and traffic particulate matter on Th2 cytokines, immunoglobulin E levels and bronchial hyper-responsiveness in mice.

BACKGROUND: Health effects due to air pollution arising from motor vehicles are a major public and political concern world-wide. Epidemiological studies have shown that the manifestations of asthma are increased by air pollution in already affected individuals. OBJECTIVE: To investigate the potential role of air-polluted tunnel dust (traffic particulate matter, TPM) or pure carbon core particles in the initiation and persistence of experimental allergic inflammation. METHODS: BP2 mice were immunized with birch pollen alone (group B) or pollen together with TPM (group A), or with birch pollen and Al(OH)3 (group C), or with birch pollen and carbon core particles (group D). Before methacholine challenge they were challenged intranasally and thereafter bronchial hyper-reactivity (BHR) was evaluated in a whole-body plethysmograph. Levels of Th2 cytokines, fibronectin and lactate dehydrogenase (LDH) were determined, and differential counts were performed in the bronchoalveolar lavage (BAL) fluid. Sera were collected for determination of antibody titres and cytokine levels. RESULTS: Specific IgE titres, BHR, the number of recruited eosinophils and levels of fibronectin and LDH in BAL were increased in mice immunized and challenged with a mixture of birch pollen and TPM. However, mice immunized with birch pollen alone and challenged intranasally with pollen or a mixture of pollen and TPM demonstrated the highest levels of IL-4 and IL-5. CONCLUSION: This study highlights the importance of the exposure to a combination of particulate matters and pollen allergens, in the induction of allergic disease in the airways, and we have demonstrated that polluted tunnel dust has an effect on both the inflammatory and immunological components of experimental allergy. Immunization and challenge with carbon core particles together with birch pollen increased neither the BHR nor the specific IgE production significantly. Our results therefore strongly suggest that it is most likely to be the organic phase bound to the carbon core of the diesel exhaust particles that might have an important adjuvant effect in the induction of experimental allergy.

Characterization of high-molecular-mass allergens in oilseed rape pollen.

BACKGROUND: Oilseed rape pollen allergies have been previously described as the result of cross-sensitization with various pollens. Recently, several proteins have been identified as oilseed rape allergens. The aim of the present work was the characterization of oilseed rape pollen allergens by two-dimensional (2-D) gel analysis and amino acid microsequencing. METHODS: Water extractable proteins from oilseed rape pollen were separated by isoelectrofocusing and then transferred onto a nitrocellulose sheet. Twenty-one human sera from pollen- or mustard-allergic individuals were screened for their reactivity to oilseed rape proteins. Eleven sera possessed IgE which recognized oilseed rape pollen proteins and one serum was selected for further 2-D characterization and amino acid microsequencing of the allergens. RESULTS: The results showed that three molecules from oilseed rape pollen were identified as oilseed rape allergens which have not yet been described. These three proteins were molecules of 70 kD with a pI >8, 40 kD with a pI around 10 and 80 kD with a pI around 5. These proteins displayed identities with the berberine bridge protein, a receptor-like protein kinase and the cobalamin-independent methionine synthetase from Arabidopsis thaliana, respectively. The genes encoding the putative Arabidopsis molecules are located on chromosome 1 (berberine bridge protein) and chromosomes 3 and 4 (receptor-like protein kinases). CONCLUSION: These results show that certain high-molecular-mass proteins from oilseed rape pollen are allergens.

Genetics and specific immune response in allergy to birch pollen and food: evidence of a strong, positive association between atopy and the HLA class II allele HLA-DR7.

BACKGROUND: In some geographic areas birch pollen represents the most prominent cause for airborne allergic diseases. Up to 70% of patients allergic to birch pollen are hypersensitive to fruits, especially apples. Associations have been found, in some instances, with a sensitivity to aeroallergens and HLA class II genes. OBJECTIVES: We investigated whether susceptibility or resistance to birch pollen allergy with and without food allergy was associated with HLA class II genes. METHODS: Blood samples were obtained from 2 groups of unrelated European-born white adults: 42 atopic patients (31 of them with asthma) and 42 healthy control subjects with no personal or familial history of asthma or atopy. Their antibody responses to birch pollen, apples, grass, and weed pollens were evaluated by skin tests, RASTs, and immunoprints. Genomic DNA was extracted from PBLs. The exons of DQA1, DQB1, DRB1, and DPB1 genes were selectively amplified by using the PCR method. Genotyping was carried out by digestion of the amplified DNA products with allele-specific endonucleases (PCR-RFLP), which recognize allelic variations in the polymorphic exon. RESULTS: We found no significant differences in the frequency of DPB1 alleles between patients and control subjects. HLA class II DR4 and/or DR7 alleles were present in 42.6% of the patients and in only 2.4% of the healthy subjects. These results confirm a previous study of a group of polysensitized atopic patients, which showed that DR4 and DR7 alleles were rare in healthy control subjects and frequently observed in atopic subjects with or without concomitant asthma. CONCLUSION: We conclude that the allele HLA-DR7 is significantly involved in the presentation of apple and pollen allergens. However, we suggest that this susceptibility is more related to atopy than to specific responses to allergens.

[Inter-relationship between allergenic pollens and air pollution]. / Interrelation entre les pollens allergisants et la pollution de l'air.

Morbidity to pollens is increasing in the French population. Pollen is the vector of the male genome of the plant. It is the wind-borne pollens that are the most allergenic by release of allergen molecules that make contact with the mucosae. So every individual who is genetically allergic (atopic) may develop rhinitis and/or conjunctivitis and/or asthma.... More than 200 allergens have been identified, of which the three-dimensional structure is well-known. The urban pollution that is specific to a quarter under consideration (residential zone, pedestrianised, mid-town roadway and industrial zone) plays an important role in morbidity to pollen allergy. A significant coating of pollens is to be found on urban roads. Pollen sensitisation is increased by exposure to pollutants from 24 to 48 hours. The pollutants seem to make the surface of the exine more fragile, so triggering a mucosal reaction, making them more exposed to pollen allergens. The pollutant also plays the role of an adjuvant to the pollen allergen, and so is the origin of a greater production of IgE.

Characterization of Dac g 4, a major basic allergen from Dactylis glomerata pollen.

Monoclonal antibodies were produced against Dac g 4, a purified major basic allergen from Dactylis glomerata pollen. Their ability to be used for immunopurification of Dac g 4 was studied on a BIAcore apparatus (Pharmacia). The allergen was purified by affinity chromatography with one monoclonal antibody. Its precise molecular mass, 59,185 +/- 30 d, was determined by mass spectrometry. Its isoelectric point is 10.4. Sodium dodecylsulfate-polyacrylamide gel electrophoresis and immunoblotting showed that Dac g 4-related proteins of similar molecular mass were detected in the majority of allergenic grass pollen species. By double-site ELISAs, we have estimated that Dac g 4 represents about 6% of the total proteins from a water-soluble extract. One monoclonal antibody (mAb H) recognized a 60 kd cross-reactive protein in other grass pollens, though none in any of the tree or weed pollens tested. Inhibition studies of IgE antibody binding to Dac g 4 with pollen extracts confirmed the presence of cross-reactive allergens in Secale cereale, Lolium perenne, Festuca elatior, Holcus lanatus, Bromus arvensis, Poa pratense, Hordeum sativum, and Phleum pratense.

Isotypic analysis of grass pollen-specific antibodies in human plasma. 4. Biological activity of allergen-specific and autoanti-IgE antibody fractions on basophil histamine release.

BACKGROUND: Blocking antibodies are defined as antibodies that compete with IgE for binding to allergens due to their specificity for those allergens. Thus, they may inhibit allergen-induced basophil and mast cell IgE-dependent mediator release both in vivo and in vitro. OBJECTIVE: The present study was designed to evaluate the ability of antibodies isolated from human plasma samples on a Dactylis glomerata (Cocksfoot) pollen affinity-column to inhibit the Dactylis pollen-induced histamine release from human basophils (BHR) in vitro. METHODS: Antibodies from Ig pools containing either high or low IgG4 anti-Dactylis pollen were purified on a Dactylis pollen affinity-column and then separated on an antihuman IgE column. Obtained Ig fractions were incubated for 30 min with Dactylis pollen allergens prior to incubation with basophils from Dactylis pollen-allergic donors. Cell supernatants were assessed for histamine content and the inhibition of BHR was calculated. RESULTS: Unlike control non-isolated Igs, the antibodies isolated on the Dactylis pollen column were able to inhibit efficiently and in a dose-dependent manner Dactylis pollen-induced BHR. The inhibitory activity was increased in isolated antibody samples that had high IgG4 levels. Antibodies isolated on the Dactylis pollen column, however, consisted not only of true allergen-specific (potentially blocking) antibodies but also of autoanti-IgE binding to allergen-specific IgE and mistaken for allergen-specific antibodies thus opening to question the involvement of the true allergen-specific antibodies in the BHR-inhibitory activity. Unlike the true allergen-specific antibodies, the autoanti-IgE were retained on and eluted from the anti-IgE column. Results showed that both the autoanti-IgE-depleted and the autoanti-IgE-containing fractions accounted for the inhibition observed with the related non-depleted sample that had been isolated on the Dactylis pollen column. CONCLUSION: For the first time, the true blocking activity of allergen-specific antibodies is demonstrated, that is, in the absence of the autoanti-IgE which can also inhibit BHR.

Isotypic analysis of grass-pollen-specific antibodies in human plasma. III. Relationship to autoantibodies to IgE.

Since it has been shown that autoanti-IgE may be mistaken for antiallergen antibodies, thus appearing as pseudo-allergen-specific antibodies, it is crucial to separate true-from pseudo-allergen-specific antibodies and to determine to what extent autoanti-IgE appeared as pseudo-allergen-specific antibodies. For this purpose, human Ig pools were affinity-purified successively on a grass-pollen column and then on an antihuman-IgE column. IgG1-4, IgA, and IgM antibodies that were eluted from the grass-pollen column separated into pseudo- (approximately 30-40%) and true-allergen-specific antibodies that were coretained and not coretained, respectively, with the IgE on the anti-IgE column. Levels of autoanti-IgE were determined in individual plasma samples by surface plasmon resonance and statistically compared to the concentrations of allergen-specific antibodies obtained previously in the same plasma samples. A positive correlation between IgM autoanti-IgE levels and grass-pollen- "specific" IgM concentrations (P < 0.0002), and negative correlations between IgA autoanti-IgE and both IgE anti-grass pollen and IgG2 autoanti-IgE levels (P < 0.03, in both cases) were observed for the first time. This supports the contentions that: (1) autoanti-IgE antibodies appeared as pseudo-grass-pollen-specific antibodies, (2) they hid IgE antibodies when the latter were measured, and (3) they compete with one another in binding IgE. Lastly, a model of large Ig complexes is discussed.

Cloning, sequencing and immunological characterization of Dac g 3, a major allergen from Dactylis glomerata pollen.

Preliminary work showed that a 14-kDa allergen with a pI of 9 was recognized by more than 60% of sera from Dactylis glomerata (Dac g) pollen-allergic individuals. The N-terminal amino acid sequence of this Dac g allergen was determined by Edman degradation and compared with that of Lol p 3, a major allergen of Lolium perenne. A sequence identity of 65% was found, suggesting that the Dac g allergen could be the homologue of Lol p 3 and therefore named Dac g 3. We report the cloning and sequence analysis of a cDNA encoding the Dac g 3 pollen allergen. The recombinant allergen (rDac g 3) expressed in plasmid vector pGEX-2T contained IgE-reactive epitopes found in its natural counterpart, and induced histamine release from basophils of Dac g-allergic individuals, confirming that the recombinant protein has biological properties similar to the pollen extracted allergen. Computer analyses showed that, in spite of a high degree of sequence homology, even closely related allergens such as Dac g 3 and Lol p 3 have dissimilar predictive secondary structures and potential different antigenicity. Because it possesses the properties of the native counterpart, rDac g 3 could be a relevant tool for molecular studies in allergy.

Comparison of the IgE titers to bovine colostral G immunoglobulins and their F(ab')2 fragments in sera of patients allergic to milk.

Colostral G immunoglobulins (IgGs) are described in many recent studies as having a beneficial effect for the treatment of viral, bacterial and parasitic diarrhea in animals and humans. The specific IgE titers to bovine colostral IgG, to bovine serum IgG, and to F(ab')2 fragments of IgG were immunoenzymatically quantified in sera of patients allergic to milk, to statistically evaluate and compare their relative immunoreactivity towards these purified antigens. The results clearly indicated that 36% of the population tested was potentially allergic to colostral IgG, and serum IgG globally elicited significantly lower IgE titers. The F(ab')2 fragments lead to a significantly decreased immunoreactivity as compared to colostral IgG. This study shows the interesting use of peptic hydrolysis of IgG in producing fragments with preserved therapeutic immunoactivity and reduced potential allergenicity.

Biochemical features of grain legume allergens in humans and animals.

Peanuts and soybeans are the major legumes involved in human food allergy, although some data exist on adverse reactions to temperate legumes including pea, green bean, sweet lupin, and lentil. An increasing number of legume proteins or glycoproteins have been characterized as food allergens. Limited data tend to indicate that they are usually different from legume inhalent allergens. Cross-recognition among legume allergens is immunochemically frequent but clinically less common. A common feature to most legume allergens is their natural resistance to thermal, chemical, and in some way, proteolytic denaturation. Finally, other mammals including preruminant calves, and piglets at the time of weaning, are prone to gut immune-mediated reactions to soybean and pea proteins.