Allergy to Gibberellin-regulated proteins in an adolescent: A case of orange-induced anaphylaxis mediated by cofactors.

This report is a case of anaphylaxis in an adolescent due to allergy to gibberellin-regulated proteins mediated by cofactors, in probable relation to a pollen/food allergy syndrome. It should also emphasizes the importance of obtaining a faithful clinical history, especially when it comes to adolescent patients as they tend to initiate toxic habits.

Gibberellin-regulated protein allergy: Clinical features and cross-reactivity.

Gibberellin-regulated proteins (GRPs)/GASA proteins are members of cysteine-rich antimicrobial peptide families and are conserved in a broad range of plants. Some GRPs in fruits and pollens have been identified as allergens including peach Pru p 7, Japanese apricot Pru m 7, orange Cit s 7, pomegranate Pun g 7, and cypress pollen GRP. The clinical features of fruit-derived GRP allergies frequently include systemic reactions, multiple fruit allergies regardless of plant kingdom classifications and, less frequently, cofactor-dependence. Multiple fruit allergies might be related to cross-reactivity between GRPs. Clinical cross-reactivity, at least between the four fruit-derived GRPs, has been proven. In addition, GRP allergy induces peculiar clinical symptoms, such as laryngeal tightness and facial swelling, especially eyelid edema, which was proposed to be a predictive factor for Pru p 7 allergy. Fruit-derived GRPs have an unusually high content of cysteine, resulting in high stability to heat and resistance to digestive enzymes. Therefore, GRPs are considered "true" food allergens that induce severe allergic reactions. As an alternative mechanism of fruit-derived GRP allergies, cross-reactivity between fruit GRP and cypress pollen GRP, which might play a role as a sensitizer, is suspected. Taken together, these characteristics indicate GRPs are clinically relevant plant allergens. This review article summarizes our current knowledge of the clinical features and important aspects of GRP sensitization and allergy.

Evaluation of serum IgE in peach-allergic patients with systemic reaction by using recombinant Pru p 7 (gibberellin-regulated protein).

BACKGROUND: Lipid transfer protein (LTP) is a major fruit allergen. It has, however, recently been revealed that the systemic reaction in peach-allergic patients is related not only to LTP (Pru p 3) but also to gibberellin-regulated protein (Pru p 7). We investigated recombinant Pru p 7 (rPru p 7) for its potential use in worldwide standardization for the diagnosis of peach allergy. METHODS: Natural Pru p 7 (nPru p 7) was purified from peach crude extract using a monoclonal antibody affinity column. Complementary DNA for Pru p 7 was cloned and expressed in Escherichia coli and Pichia pastoris. Serum immunoglobulin (Ig) E in peach-allergic patients was examined by enzyme-linked immunosorbent assay (ELISA) using nPru p 7 and rPru p 7 (E. coli product: erPru p 7 and P. pastoris product: prPru p 7). RESULTS: Peach-allergic patients (n=27) were diagnosed and categorized into oral reaction (n=10) or systemic reaction (n=17). The nPru p 7 positivity based on serum IgE levels was 52% in the systemic-reaction group and 0% in the oral-reaction group (P<0.05). In the systemic-reaction group, there was no significant difference in reactivity between nPru p 7 and prPru p 7, but the reactivity of erPru p 7 was significantly lower than those of nPru p 7 and prPru p 7 (P<0.05). CONCLUSIONS: We found that prPru p 7 exhibited reactivity in ELISA comparable to that of nPru p 7 for the diagnosis of peach allergy with systemic reaction.

Gibberellin and the plant growth retardant Paclobutrazol altered fruit shape and ripening in tomato.

Fruit shape and ripening are major horticultural traits for many fruits and vegetable crops. Changes in fruit shape and ripening are often accomplished by altered cell division or cell expansion patterns. Gibberellic acids (GAs) are essential for tomato fruit development; however, the exact role and the underlying mechanism are still elusive. To elucidate the relationship between gibberellins and fruit shape and ripening in tomato, GA3 and gibberellin biosynthesis inhibitor paclobutrazol (PAC) were applied to tomato. Fruit shape index was increased when GA3 was applied, which was mainly attributed to the increased organ elongation. The expression levels of genes involved in cell elongation and expansion were altered at the same time. In addition, GA delayed the ripening time by regulating the transcript levels of ethylene-related genes. By contrast, PAC application decreased fruit shape index and shortened fruit ripening time. These results demonstrate that manipulation of GA levels can simultaneously influence tomato fruit shape and ripening. Further studies aimed to regulate fruit shape and ripening can be achieved by altering GA levels.

Reguladores de crescimento vegetal no cultivo in vitro de Mentha x Piperita L / Plant growth regulators on in vitro culture of Mentha x piperita L

A micropropagação é uma técnica muitas vezes indicada para a multiplicação em larga escala de plantas com propriedades medicinais. Dentre elas, destaca-se a hortelã-pimenta (Mentha x Piperita L.), cujo óleo essencial é utilizado no tratamento de transtornos digestivos e respiratórios. Para otimizar o protocolo de micropropagação dessa espécie são necessários estudos, principalmente quanto à suplementação do meio de cultura para garantir a produção massal in vitro e posterior extração do óleo essencial. Nesse contexto, objetivou-se avaliar o efeito de concentrações e combinações de reguladores de crescimento vegetal na morfogênese in vitro de hortelã-pimenta. Segmentos nodais provenientes de plântulas estabelecidas in vitro foram utilizados como fonte de explante e inoculados em meio de cultura MS suplementado com 0; 2,0 e 4,0 mg L-1 de BAP (6-benzilaminopurina), 0; 0,5 e 1,5 mg L-1 de ANA (ácido naftaleno-acético) e 0; 0,5 e 1,0 mg L-1 de GA3 (ácido giberélico). O delineamento experimental adotado foi inteiramente casualizado, com os tratamentos distribuídos em esquema fatorial 3x3x3 com oito repetições. Concluiu-se que o BAP favoreceu a sobrevivência de segmentos nodais de M. x Piperita inoculados in vitro e, quando combinado ao GA3, promoveu a brotação dos explantes. Essas características, no entanto, não foram estimuladas pela adição de ANA ao meio de cultura. Conclui-se que após a multiplicação dos brotos in vitro estes devem ser transferidos para meio sem reguladores para seu desenvolvimento. Apesar dos efeitos benéficos do BAP na organogênese de M. x Piperita, elevadas concentrações deste regulador de crescimento vegetal promoveram a formação de calos.

Micropropagation is a technique used for the large-scale production of medicinal plants. Among them, peppermint (Mentha x piperita L.) may be mentioned because of the pharmacological importance of its essential oil, which is used on the treatment of digestive and respiratory disorders. Studies are needed in order to optimize the micropropagation protocol of this species, especially concerning the culture medium, to ensure the in vitro mass clonal production and to enable the future extraction of the plant essential oil. Therefore, this work aimed to evaluate the effects of concentrations and combinations of different plant growth regulators on the in vitro morphogenesis of peppermint. Nodal segments from plantlets already established in vitro were used as explants and inoculated on MS medium supplemented with 0, 2.0 and 4.0 mg L-1 of BAP (6-benzylaminopurine), 0, 0.5 and 1.5 mg L-1 of NAA (naphthalene acetic acid) and 0; 0.5 and 1.0 mg L-1 of GA3 (gibberellic acid). The experiment was in a completely randomized design, set up as a 3x3x3 factorial design with eight replicates. We concluded that BAP increases the survival rate of in vitro inoculated nodal segments of M. x piperita. In addition, its combination with GA3 stimulates explants shooting. Those aspects, however, are not promoted by the addition of NAA into the culture medium. Also, the results indicate that, after in vitro multiplication, peppermint shoots must be transferred to another medium without plant growth regulators for shoot elongation. High concentrations of BAP promote calli induction, despite having beneficial effects on the organogenesis of M. piperita.