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Notes: Background An olive allergen-like protein has been detected in privet pollen. This protein could be involved in the allergenic cross-reactivity described for privet and olive tree pollen extracts.Objective Isolation and characterization of natural Lig v 1. Cloning and expression of its cDNA in order to assess its structural similarity with the olive allergen.Methods Current chromatographic methods were used to isolate the privet counterpart of Ole e 1. A pool of sera from subjects allergic to olive tree pollen was used to immunodetect the protein in the elution profiles. Ole e 1-specific polyclonal antibody and allergic sera were used in immunoblotting assays of the isolated protein, Polymerase chain reaction amplification of the first strand cDNA synthesized from the privet pollen total RNA was carried out to prepare a full-length fragment encoding Lig v 1. After nucleotide sequencing, expression of one clone was performed in Escherichia coli, under the form of a fusion protein with glutathione S-transferase. The IgE binding capability of the recombinant protein was also analysed.Results The major allergen from privet pollen, Lig v 1, was purified to homogeneity by two gel filtration chromatographies and one reverse-phase high-performance liquid chromatography. Its amino acid composition and N-terminal amino acid sequence were determined. Two different clones encoding Lig v 1 were sequenced. Strong sequence similarity between Lig v 1 and Ole e 1 was observed, the identity being 85 and 96%. One of the sequenced clones was expressed and the recombinant product exhibited IgG and IgE binding activities against both anti-Ole e 1 polyclonal antibodies and olive-allergic sera.Conclusion Privet pollen contains a protein structurally and immunologically related to the major allergen of ohve pollen. The similarity exhibited by these proteins could explain the cross-reactivity observed between the two pollen extracts. Since these allergens are highly polymorphic, the expression of an immunologically active recombinant Lig V 1 will permit the preparation of well defined molecules for both research and chnical purposes.

Notes: Background Seed proteins have been found to cause hypersensitivity by ingestion or inhalation. Rapeseed fiour was responsible for allergic symptoms in a patient, who develops into allergy to mustard spice.Objective To determine the presence of allergenic proteins in rapeseed fiour, and analyse the structure of the main component and its crossreactivity with the mustard allergeti.Methods SDS-PAGE (sodium dodecyl sulfate-polyacrylamide gel electrophoresis) and subsequent immunoblotting with a serum from a rapeseed allergic patient were performed to detect IgE-binding proteins. Proteolytic digestiotis and high performance liquid chromatography were used to obtain the peptides from the allergenic BnIII napin from rapeseed flour. Automatic Edman degradations were carried out to determine their amino acid sequences, which were compared with other sequences in nucleotide and amino acid sequence databases. Crossreactivity assays were carried out by ELISA inhibition using sera from a rapeseed allergic patient and from patients allergic to mustard.Results The 2S albumins of rapeseed were recognized by the serum from a patient allergic to this seed. The most abundant isoform of the allergenic napins, Bnlll, was used for structural and immunological analysis. The protein consists of two different chains of 9.5 and 4,5 kDa. Their complete amino acid sequences were determined. The protein exhibited structural relationships with other napin-like storage proteins from seeds. IgE and IgG crossreactivity between rapeseed and mustard allergens was also demonstrated. Considering the structural and immunological data, certain polypeptide regions are suggested to be involved in the allergenicity of these proteins.Conclusions Rapeseed contains 2S storage proteins which may cause allergy in hypersensitive individuals. These proteins exhibit great sequence similarity with 2S albumins from different seeds. Crossreactivity between mustard and rapeseed flours can be explained by sequetice homology.

Notes: A great number of allergenic proteins have been detected in olive pollen extracts. To date, nine allergens have been isolated and characterized, which have been called Ole e 1 to Ole e 9. The most prevalent olive allergen is Ole e 1, which affects more than 70% of patients hypersensitive to olive pollen, but others, such as Ole e 2, Ole e 8, and Ole e 9, have been demonstrated to be major allergens, and Ole e 6 or Ole e 7 reach high values of clinical incidence. Many of these allergens, such as Ole e 2 (profilin) and Ole e 3 (polcalcin), are involved in cross-reactivities, which agrees with their adscription to panallergenic families. Among the many olive allergens of high molecular mass, only Ole e 9 (46 kDa) has been characterized. The allergen is a polymorphic and glycosylated β-1,3-glucanase, which belongs to a pathogenesis-related (PR-2) protein family. In addition to the polypeptide epitopes, Ole e 1 also exhibits IgE-binding determinants in the carbohydrate, which are recognized by more than 60% of the sera from patients sensitive to the whole allergen, although the level of such glycan-specific IgE seems not to be clinically relevant in the overall content of the sera. Recent advances in the elucidation of the structure of the Ole e 1-oligosaccharide component allows us to explain the antigenicity of the molecule. Finally, the recombinant production of several allergens from olive pollen in both bacterial and eukaryotic cells has allowed us to resolve problems derived from the polymorphism and scarcity of the natural forms of these allergens. The biological equivalence between the natural and recombinant forms lets us initiate studies on the design of mixtures for clinical purposes, in which hypoallergenic derivatives of these allergens could play a definitive role.