Angela Bonura

The Allergens of Parietaria

Parietaria is a genus of dicotyledonous weeds of the Urticaceae family including several species and its pollen grain is one of the most important allergenic sources in the Mediterranean area. Species belonging to this genus induce IgE responses in approximately 10 million people. Identification of allergens by means of independent strategies suggest that the allergens of the two more common species, Parietaria judaica and Parietaria officinalis, show molecular weights ranging between 10 and 14 kD and that the allergens of the two extracts are highly cross-reactive. Biochemical analysis and molecular cloning allowed the isolation and immunological characterization of the two major allergens of the P. judaica pollen, Par j 1 and Par j 2. Sequence comparison suggests that the P j major allergens of P. judaica belong to the nonspecific lipid transfer protein family, and three-dimensional modeling by homology has revealed that both proteins present a very conserved structural motif composed of four α-helices. Immunological analysis has shown that Par j 1 and Par j 2 are able to bind most of the P. judaica-specific IgE and some of their IgE determinants have been mapped. Recombinant Par j 1 and Par j 2 allergens have been shown to possess immunological properties equivalent to their natural counterpart and their availability represents a fundamental tool for the diagnosis and therapy of Parietaria pollen allergy.

Hypoallergenic variants of the Parietaria judaica major allergen Par j 1: a member of the non-specific lipid transfer protein plant family.

Background: Par j 1 represents a major allergenic component of Parietaria judaica (Pj) pollen, since it is able to induce an immunoglobulin E (IgE) response in 95% of Pj-allergic patients. It belongs to the non-specific lipid transfer protein family, sharing with them a common three-dimensional structure. Methods: Disulphide bond variants of the recombinant Par j 1 (rPar j 1) allergen were generated by site-directed mutagenesis, and the immunological activity of rPar j 1 and its conformational mutants was compared with the use of the skin prick test (SPT). The ability to bind IgE antibodies was evaluated by Western blot, ELISA and ELISA inhibition. T cell reactivity was measured by peripheral blood mononuclear cell proliferation assay. Results: The disruption of Cys14–Cys29 and Cys30–Cys75 bridging (PjA mutant) caused the loss of the majority of specific IgE-binding activity. Additional disruption of the Cys4–Cys52 bridge (PjC mutant) and the latter Cys50–Cys91 bridge (PjD mutant) led to the abolition of IgE-binding activity. On the SPT, PjB (lacking the Cys4–Cys52 and Cys50–Cys91 bridges) was still capable of triggering a type I hypersensitive reaction in 9 out of 10 patients, and PjA in 3 out of 10 patients, while PjC and PjD did not show any SPT reactivity. All the mutants preserved their T cell reactivity. Conclusion: Recombinant hypoallergenic variants of the rPar j 1 allergen described herein may represent a useful tool for improved immunotherapy.

The recombinant major allergen of Parietaria judaica and its hypoallergenic variant: in vivo evaluation in a murine model of allergic sensitization.

Background  Par j 1 represents the major allergenic component of Parietaria judaica pollen. Its three‐dimensional structure is stabilized by four disulphide bridges. A family of three‐dimensional mutants of the recombinant Par j 1 (rPar j 1) allergen, showing reduced allergenicity and retained T cell recognition has been recently developed by site‐directed mutagenesis.

Isolation and expression of a novel MBL-like collectin cDNA enhanced by LPS injection in the body wall of the ascidian Ciona intestinalis

Collectins are a family of calcium-dependent lectins that are characterized by their collagen-like domains. Considerable interest has been focused on this class of proteins because of their ability to interact with components of the complement system activating a cascade of events responsible for the activation of the innate immune system. A differential screening between LPS-challenged and naïve Ciona intestinalis has been performed allowing the isolation of a full length cDNA encoding for a 221 AA protein. In silico analysis has shown that this polypeptide displays protein domains with similarities to mannose-binding lectins. A phylogenetic analysis suggested that C. intestinalis MBL has evolved early as a prototype of vertebrate MBL. Real-time PCR assay demonstrated that this gene is strongly activated after LPS injection in the tunica. In situ hybridization performed in LPS-induced animals has shown that this gene is expressed in granular amoebocytes and large granules hemocytes in the inflamed body wall tissue. Finally, an antimicrobial activity of the C. intestinalis MBL has been demonstrated.

A Hybrid Expressing Genetically Engineered Major Allergens of the Parietaria Pollen as a Tool for Specific Allergy Vaccination

Background: Allergy is an immunological disorder affecting about 25% of the population living in the industrialized countries. Specific immunotherapy is the only treatment with a long-lasting relief of allergic symptoms and able to reduce the risk of developing new allergic sensitizations and inhibiting the development of clinical asthma in children treated for allergic rhinitis. Methods: By means of DNA recombinant technology, we were able to design a head to tail dimer expressing disulphide bond variants of the major allergen of the Parietaria pollen. IgE binding activity was studied by Western blot, ELISA inhibition assays and the skin prick test. T cell recognition was studied by peripheral blood mononuclear cell proliferation. The immunogenicity of the hybrid was studied in a mouse model of sensitization. Results: In vitro and in vivo analysis showed that the disruption of specific cysteine residues in both allergens caused a strong reduction in IgE binding activity of the PjEDcys hybrid. In addition,we were able to show that a reduction in the IgE epitope content profoundly reduced the anaphylactic activity of the hybrid (from 100 to 1,000 times less than wild-type allergens) without interfering with the T cell recognition. Sera from BALB/c mice immunized with the hybrid were able to bind the natural Parietaria allergens and to inhibit the binding of human IgE to wild-type Par j 1 and Par j 2 allergens up to 90%. Conclusion: Our results demonstrate that hybrid-expressing disulphide bond variants of the major allergens of the Parietaria pollen displayed reduced allergenicity and maintained T cell reactivity for induction of protective antibodies.

Effects of Live and Inactivated VSL#3 Probiotic Preparations in the Modulation of in vitro and in vivo Allergen-Induced Th2 Responses

Background: The immunological mechanisms responsible for the immunomodulatory and anti-allergic effects of probiotic bacteria are still poorly defined. The combined effects of mixtures of different species of probiotic bacteria have been explored only in part. The present study describes the immunomodulatory activity of the VSL#3 probiotic preparation in in vitro and in vivo systems. Methods: The activation and cytokine production by in vitro probiotic-stimulated bone-marrow dendritic cells (BM-DCs) and spleen cells isolated from naïve or Par j 1-sensitized mice were investigated. Mice were intranasally administered a sonicate preparation of VSL#3 before immunization with rPar j 1. Serum antibody levels and cytokine expression in the lung were determined. Results: Both live and sonicated VSL#3 preparations induced maturation and cytokine production by BM-DCs. Cytokine production by spleen cells from naïve or Par j 1-sensitized mice was modulated by the probiotic preparations towards a Treg/Th0 profile, characterized by increased IL-10 and IFN-γ production. In vivo prophylactic treatment with VSL#3 induced a significant reduction of serum specific IgG1. At lung level, VSL#3 pre-treatment remarkably reduced IL-13 and IL-4 mRNA expression and increased IL-10 expression. Conclusions: The VSL#3 preparations have not only the capacity to bias primary immune responses towards a Treg/Th0-type profile, but also to modify in the same way the functional characteristics of established in vitro Th2 responses. In vivo studies on a mouse model of Par j 1 sensitization indicate that the prophylactic intranasal treatment with probiotic bacteria is able to modulate the development of Th2-biased responses.

Characterization of a Par j 1/Par j 2 mutant hybrid with reduced allergenicity for immunotherapy of Parietaria allergy.

Parietaria pollen is one of the major cause of pollinosis in the southern Europe. Specific immunotherapy is the only treatment able to modify the natural outcome of the disease restoring a normal immunity against allergens.

An allergen-polymeric nanoaggregate as a new tool for allergy vaccination

A recombinant hybrid composed of the two major allergens of the Parietaria pollen Par j 1 and Par j 2 has been generated by DNA recombinant technology (PjED). This hybrid was produced in E. coli at high levels of purity. Then, the engineered derivative has been combined with a synthetic polyaminoacidic derivative having a poly(hydroxyethyl)aspartamide (PHEA) backbone and bearing both butyryl groups (C4) and succinyl (S) moieties in the side chain (PHEA-C4-S). The allergen-copolymer nanoaggregate was characterized by means of DLS, zeta potential, electrophoretic mobility and atom force microscopy analysis displaying the formation of a stable complex. Its safety has been proved in vitro on a murine cell line, human erythrocytes and basophils. Moreover, the formation of the complex did not alter the ability of the allergens to cross-link surface bound specific IgE demonstrating that the combination of an engineered hybrid with a copolymer did not interfere with its biological activity suggesting its employment as potential vaccine against Parietaria-induced allergies.

The major allergen of the Parietaria pollen contains an LPS-binding region with immuno-modulatory activity

The major allergens in Parietaria pollen, Par j 1 and Par j 2, have been identified as lipid transfer proteins. The family of the Par j 1 allergens is composed of two isoforms, which differ by the presence of a 37 amino acid peptide (Par37) exclusive to the Par j 1.0101 isoform. The goal of this study was to elucidate the biological properties of the Par37 peptide.

Folding and binding activity of the 3′UTRs of Paracentrotus lividus bep messengers

Bep mRNAs are localized at the animal pole of P. lividus eggs. In the present communication the secondary structures of the 3′UTRs of the bep1, bep3 and bep4 mRNAs are reported. The minimal lenghts of these regions required to bind the 54‐kDa protein, previously shown to be involved in localization and anchoring of these RNAs, is estimated. Microinjection of the bep3 3′UTR into egg shows that this RNA fragment is also able to become localized to one of the egg poles, as happens for the entire bep3 RNA.