Diverse and highly cross-reactive T-cell responses in ragweed allergic patients independent of geographical region.

BACKGROUND: Ragweed frequently causes seasonal allergies in North America and Europe. In the United States, several related ragweed species with diverse geographical distribution cause allergic symptoms. Cross-reactivity towards related ragweed species of IgE and treatment-induced IgG4 has been demonstrated previously. However, less is known about the underlying T-cell cross-reactivity. METHODS: The allergen content of ragweed extracts was determined by mass spectrometry and related to T-cell epitopes of Amb a allergens (group 1, 3, 4, 5, 8 and 11) in 20 American ragweed allergic patients determined by FluoroSpot and proliferation assays. T-cell responses to 50 frequently recognized Amb a-derived T-cell epitopes and homologous peptides from western ragweed (Amb p), giant ragweed (Amb t) and mugwort (Art v) were investigated in an additional 11 American and 14 Slovakian ragweed allergic donors. RESULTS: Ragweed extracts contained all known allergens and isoallergens thereof. Donor T-cell responses were diverse and directed against all Amb a 1 isoallergens and to most minor allergens investigated. Similar response patterns were seen in American and Slovakia donors. Several epitopes were cross-reactive between isoallergens and ragweed species, some even including mugwort. T-cell cross-reactivity generally correlated with allergen sequence homology. CONCLUSION: T-cell epitopes of multiple allergens/isoallergens are involved in the diverse T-cell responses in ragweed allergic individuals. T-cell lines were highly cross-reactive to epitopes of related ragweed species without any apparent geographical response bias. These data support that different ragweed species can be considered an allergen homology group with Amb a as the representative species regarding diagnosis as well as allergy immunotherapy.

Emerging pollen allergens.

Numerous pollen allergens have been reported over the last few years. Most of them belong to well-known families of proteins but some others constitute the first member of new allergenic families. Some of the factors that can contribute to the detection and identification of new pollen allergens are: a) advances in the technology tools for molecular analysis; and b) the deep knowledge of many allergenic sources. The combination of these factors has provided vast information on the olive pollen allergogram and the identification of minor allergens that become major ones for a significant population. The close taxonomical relationship between olive tree and ash -both Oleaceae- has permitted to identify Fra e 1 (the Ole e 1-like allergen) in ash pollen and to detect the presence of protein homologues of Ole e 3 and Ole e 6. In the other hand, extensive areas of south Europe are suffering an increasing desertification. As a consequence of this, new botanical species are spontaneously growing in these areas or being used in greening ground programs: Chenopodium album and Salsola kali are some examples recently recognized as allergenic woods. The identification of the complete panel of allergens from the hypersensitizing sources might help to develop more accurate diagnosis, and efficient and safer therapy tools for Type-I allergic diseases.

Pectin methylesterases of pollen tissue, a major allergen in olive tree.

Olive tree (Olea europaea) pollen is a main cause of allergy in Mediterranean areas and North America. A novel allergen, Ole e 11, has been detected by proteomic techniques. Protein bands binding IgE from allergic sera were excised from a 2D electrophoresis gel and analysed by Edman degradation and MALDI-TOF MS. Four peptides were sequenced and used for designing primers to clone the cDNA codifying the protein. Ole e 11 consists of a 342 amino acid length polypeptide with a molecular mass of 37.4 kDa and a pI of 7.8. The allergen was identified as a pectin methylesterase and showed low identity with other members of this family from foods such as those from carrot (23%), orange (25%) and tomato (24%), and higher identity with those from Arabidopsis thaliana (57%) and Salsola kali (54%) pollen. The protein was overproduced in Pichia pastoris, purified, and characterized as an active enzyme. CD analysis rendered 3%alpha-helix, 50%beta-sheet and 27%beta-turns for its secondary structure, which is in agreement with other pectin methylesterase structures. The recombinant protein was demonstrated to be immunologically equivalent to the natural form by immunoblotting, indirect ELISA and inhibition experiments, using polyclonal antiserum and sera from olive pollen allergic patients. The prevalence fluctuated between 55.9% and 75.6% in three different allergic populations. The availability of this new olive pollen allergen could improve the component-resolved diagnosis. Its allergenic relevance is stepped up by the biotechnological use of these enzymes to improve organoleptic properties in processing foods and further confirms the need to include it in an accurate diagnosis.