Characterization of api g 1.0201, a new member of the Api g 1 family of celery allergens.

BACKGROUND: The association of pollinosis with allergy to plant foods occurs in up to 70% of tree pollen-allergic patients. In recent years, some of the relevant cross-reacting proteins have been characterized at the molecular and immunological level. Api g 1 has been identified as the celery homologue of the major birch pollen allergen, Bet v 1. Although a number of Bet v 1 isoforms have been characterized from birch pollen, little is known about isoforms of food allergens and their allergenic features. METHODS: Api g 1.0201, an isoform of Api g 1, was isolated from a cDNA library, cloned and sequenced. The cDNA was expressed in Escherichia coli and the purified recombinant protein was tested in immunoblots. RESULTS: Api g 1.0201 displays 72% sequence similarity to the previously identified Api g 1.0101 and consists of 159 amino acid residues. The sequence of Api g 1.0201 has five additional amino acid residues at the carboxy-terminus as compared to Api g 1.0101. Purified recombinant Api g 1.0201 is recognized by IgE from the sera of celery-allergic patients, as well as by the murine monoclonal anti-Bet v 1 antibody. In general, this isoform displays a weaker IgE-binding capacity than Api g 1.0101, as concluded from immunoblotting experiments. Results from inhibition assays revealed that IgE-binding to Api g 1.0201 is only slightly reduced by preincubation with either purified recombinant Api g 1.0101 or purified recombinant Bet v 1a. Total inhibition was only achieved when using purified natural Bet v 1. CONCLUSIONS: At present, little is known about the IgE-binding capacity of isoforms of Bet v 1 homologues of food allergens. Identification and characterization of such isoforms may help to contribute to a better understanding of food allergy and the observed cross-reactivity to pollen allergy.

Use of an ultrasound cell retention system for the size fractionation of somatic embryos of woody species.

The potential of ultrasonic standing waves for trapping suspended particles was utilized successfully for differential size fractionation of plant somatic embryos. In a flow-through resonator equipped with a 200-kHz piezoceramic transducer, embryos of different sizes corresponding to different developmental stages could be retained by varying the electric power input and flow speed. The system was initially established for carrot (Daucus carota) somatic embryos and subsequently adapted for the larger-sized embryos of the woody species cork oak (Quercus suber), grapevine (Vitis Berlandieri × rupestris) and cherry (Prunus incisa × serrula). Separation performance was confirmed by analysing the different fractions for the expression of homeobox genes which are differentially expressed during embryogenesis. No inhibitory effects of embryos on short- and long-term development could be observed.

IgE reactivity to Api g 1, a major celery allergen, in a Central European population is based on primary sensitization by Bet v 1.

BACKGROUND: Up to 70% of patients with tree pollen allergy display allergic symptoms when eating certain fruits and vegetables. Homologous proteins with allergenic features are present in a wide range of plant species and can cause allergic reactions. OBJECTIVE: The aim of this study was to evaluate recombinant Api g 1, a major celery allergen, for in vivo and in vitro diagnosis of celery allergy in populations from Davos, Switzerland, and Montpellier, France. METHODS: A group of patients with celery and birch pollen allergy from Davos was tested, and the results from those tests were compared with results from a group of patients allergic to celery from Montpellier. Skin prick tests were performed with a commercial celery extract, crude celery, and purified recombinant Api g 1. Quantitative and qualitative serology was done with natural and recombinant allergens by means of RASTs and immunoblotting. RESULTS: Recombinant Api g 1 allowed accurate in vivo diagnosis of celery allergy in all patients from the Swiss group. RAST results with celery extract were negative in 8 of 24 patients; results of immunoblotting with celery extract were negative in 4 of 24 patients, and results of immunoblotting with recombinant (r)Api g 1 were negative in 8 of 24 patients. In the French group 11 of 12 patients had a positive skin reaction with crude celery extract, but only 2 patients reacted with rApi g 1. RAST results for celery were positive in 8 of 12 patients. In immunoblotting experiments 8 patient sera displayed IgE directed against various celery allergens, whereas no patients sera had rApi g 1-specific IgE. CONCLUSION: Our results document that rApi g 1 allows accurate in vivo diagnosis only in areas where birch trees are common. In areas where no birch trees grow, primary sensitization takes place through different pollen allergens (eg, mugwort pollen). Moreover, it became evident that birch pollen and celery allergy are highly related in Central Europe, whereas in Southern Europe the mugwort-celery type is predominant.

Molecular characterization of Dau c 1, the Bet v 1 homologous protein from carrot and its cross-reactivity with Bet v 1 and Api g 1.

BACKGROUND: Up to 70% of patients with birch pollen allergy exhibit the so-called oral allergy syndrome, an IgE-mediated food allergy. The most frequent and therefore best characterized pollen-fruit syndrome is apple allergy in patients suffering from tree pollen-induced pollinosis. The occurrence of adverse reactions to proteins present in vegetables such as celery and carrots in patients suffering from pollen allergy has also been reported. cDNAs for Bet v 1 homologous proteins have been cloned from celery, apple and cherry. Objective The aim of the study was to identify Bet v 1 homologues from carrot (Daucus carota), to isolate the respective cDNA, to compare the IgE-binding capacity of the natural protein to the recombinant allergen and determine the cross-reactivity to Api g 1 and Bet v 1. METHODS: Molecular characterization of the carrot allergen was performed using IgE-immunoblotting, cross-inhibition assays, N-terminal sequencing, PCR-based cDNA cloning and expression of the recombinant protein in Escherichia coli. RESULTS: A 16-kDa protein from carrot was identified as a major IgE-binding component and designated Dau c 1. Sequencing corresponding cDNAs revealed three extremely similar sequences (Dau c 1.1, 1.2 and 1.3) with an open reading frame of 462 bp coding for 154 amino acid residues. CONCLUSIONS: Purified recombinant Dau c 1.2 was tested in immunoblots displaying IgE-binding capacity comparable to its natural counterpart. Cross-inhibition assays verified the existence of common B-cell epitopes present on Dau c 1, Api g 1 as well as on Bet v 1.

Localization of fruit tree viruses by immuno-tissue printing in infected shoots of Malus sp. and Prunus sp.

Immuno-tissue printing protocols for the localization of apple chlorotic leaf spot virus (ACLSV), stem grooving virus (SGV) and plum pox virus (PPV) in shoots of Prunus and Malus in vitro have been established for routine diagnosis in a virus elimination program. Since these viruses belong to different virus genera, the protocols were adapted according to the properties of the virus under investigation. Accumulation of ACLSV was highest in the base of the stem and decreased towards the apex of the shoots. ACLSV was found in the epidermis, the cortex, in the vascular bundles, but seldom in the pith tissue of in vitro apple shoots. ACLSV immuno-tissue printing was as sensitive as ELISA and the intensity of color signals in immuno-tissue prints correlated with absorbance values by two-step ELISA. SGV could be detected by immuno-tissue prints at infectivity levels, where it reacted negative in ELISA. SGV accumulated in the vascular bundles, occurred locally in the parenchymatic tissue, was found in high amounts in young leaves near the meristem, but not within the meristem. PPV was detected in all tissue types of stem sections with an irregular pattern reflecting the in vivo situation causing problems with detection. Discrimination of poorly and heavily infected shoots was possible with the naked eye.

Cloning and sequencing of Mal d 1, the major allergen from apple (Malus domestica), and its immunological relationship to Bet v 1, the major birch pollen allergen.

The number of tree-pollen-allergic patients showing allergic reactions to apples, various vegetables and nuts is increasing. In this paper the molecular characterization of the major apple allergen, Mal d 1, is reported. The cDNA coding for Mal d 1 was cloned and sequenced. Its open reading frame codes for a protein of 159 amino acids with a predicted molecular mass of 17.7 kDa and a predicted pI of 5.9. Sequence comparison to Bet v 1, the major birch pollen allergen, revealed 64.5% identity on the amino acid level and 55.6% identity on the nucleic acid level. Recombinant Mal d 1 was expressed in the plasmid pMW 175 in E. coli BL 21 (DE3) and its immunological properties were tested. Crossreactivity with Bet v 1 was shown by inhibition assays.

Somatic embryogenesis of Prunus subhirtella autumno rosa and regeneration of transgenic plants after Agrobacterium-mediated transformation.

Embryogenic lines of Prunus subhirtella autumno rosa were established on a modified MS medium supplemented with 1 mg/l NAA, 0.06 mg/l IBA and 0.04 mg/l BA from petioles of axenically grown shoots of adult origin. To induce normal development of plantlets we compared a range of approaches on solid culture media as well as in suspension cultures including treatments with ABA, GA3, zeatin, darkness, and cold. A series of experiments were conducted to follow the temporal pattern of somatic embryo development.Separation of embryos at different stages of development was carried out by sieving the suspension cultures through nylon nets. While the embryogenic masses were used for further subcultures, well formed embryos were used for germination experiments.Transformed Prunus subhirtella plants were regenerated from somatic embryos by inoculating an embryogenic callus with Agrobacterium strain LBA 4404 containing the ß-glucuronidase (GUS) gene on plasmid pBinGUSint. Several putative transformed embryogenic calli were selected for continued proliferation on kanamycin containing media. Finally transgenic plants were regenerated on shoot multiplication medium containing kanamycin. Embryos and plants were shown to express the GUS gene by histochemical assays and northern blot analysis. With a yield of 110 transgenic lines from a single transformation experiment this approach appears ideal for the study of the influence on level of expression caused by different copy number, site of insertion etc. This will be helpful in establishing parameters according to which the best transgenic line for a chosen purpose should be selected.