Petra Verdino

Recombinant Carp Parvalbumin, the Major Cross-Reactive Fish Allergen: A Tool for Diagnosis and Therapy of Fish Allergy

IgE-mediated reactions to fish allergens represent one of the most frequent causes of food allergy. We have constructed an expression cDNA library from carp (Cyprinus carpio) muscle in phage λgt11 and used serum IgE from a fish allergic patient to isolate 33 cDNA clones that coded for two parvalbumin isoforms (Cyp c 1.01 and Cyp c 1.02) with comparable IgE binding capacities. Both isoforms represented calcium-binding proteins that belonged to the β-lineage of parvalbumins. The Cyp c 1.01 cDNA was overexpressed in Escherichia coli, and rCyp c 1.01 was purified to homogeneity. Circular dichroism analysis and mass spectroscopy showed that rCyp c 1.01 represented a folded protein with mainly α-helical secondary structure and a molecular mass of 11,416 Da, respectively. rCyp c 1.01 reacted with IgE from all fish-allergic patients tested (n = 60), induced specific and dose-dependent basophil histamine release, and contained most of the IgE epitopes (70%) present in natural allergen extracts from cod, tuna, and salmon. Therefore, it may be used to identify patients suffering from IgE-mediated fish allergy. The therapeutic potential of rCyp c 1.01 is indicated by our findings that rabbit Abs raised against rCyp c 1.01 inhibited the binding of IgE (n = 25) in fish-allergic patients to rCyp c 1.01 between 35 and 97% (84% mean inhibition) and that depletion of calcium strongly reduced IgE recognition of rCyp c 1.01. The latter results suggest that it will be possible to develop strategies for immunotherapy for fish allergy that are based on calcium-free hypoallergenic rCyp c 1.01 derivatives.

X-Ray Structure, Conformational Analysis, Enantioseparation, and Determination of Absolute Configuration of the Mitotic Kinesin Eg5 Inhibitor Monastrol

Abstract The conformational features of the mitotic kinesin Eg5 inhibitor monastrol were investigated by computational (AM1, HF/3-21G∗), X-ray diffraction, and NMR studies showing that monastrol is a conformationally highly flexible molecule. Racemic monastrol was resolved by direct enantioselective HPLC and the absolute configuration of the first eluting (S)-(+) enantiomer was established by CD spectroscopy.

A Recombinant Hypoallergenic Parvalbumin Mutant for Immunotherapy of IgE-Mediated Fish Allergy

IgE-mediated allergy to fish is a frequent cause of severe anaphylactic reactions. Parvalbumin, a small calcium-binding protein, is the major fish allergen. We have recently isolated a cDNA coding for carp parvalbumin, Cyp c 1, and expressed in Escherichia coli a recombinant Cyp c 1 molecule, which contained most IgE epitopes of saltwater and freshwater fish. In this study, we introduced mutations into the calcium-binding domains of carp parvalbumin by site-directed mutagenesis and produced in E. coli three parvalbumin mutants containing amino acid exchanges either in one (single mutants; Mut-CD and Mut-EF) or in both of the calcium-binding sites (double mutant; Mut-CD/EF). Circular dichroism analyses of the purified derivatives and the wild-type allergen showed that Mut-CD/EF exhibited the greatest reduction of overall protein fold. Dot blot assays and immunoblot inhibition experiments performed with sera from 21 fish-allergic patients showed that Mut-CD/EF had a 95% reduced IgE reactivity and represented the derivative with the least allergenic activity. The latter was confirmed by in vitro basophil histamine release assays and in vivo skin prick testing. The potential applicability for immunotherapy of Mut-CD/EF was demonstrated by the fact that mouse IgG Abs could be raised by immunization with the mutated molecule, which cross-reacted with parvalbumins from various fish species and inhibited the binding of fish-allergic patients’ IgE to the wild-type allergen. Using the hypoallergenic carp parvalbumin mutant Mut-CD/EF, it may be possible to treat fish allergy by immunotherapy.

The Junctional Adhesion Molecule JAML Is a Costimulatory Receptor for Epithelial γδ T Cell Activation

Skin Reaction Lymphocytes in the skin known as γδ T cells provide an important barrier against infection and injury. Unlike classical αβ T cells, less is known about the molecular requirements of γδ T cell activation. Two studies demonstrate that the junctional adhesion molecule–like protein (JAML) is a costimulatory molecule for mouse γδ T. Witherden et al. (p. 1205; see the Perspective by Shaw and Huang) showed that JAML, binding to its ligand Coxsackie and adenovirus receptor (CAR), leads to proliferation, as well as cytokine and growth factor production by γδ T cells. In vivo, JAML-CAR interactions contributed to the wound healing response in mice. Verdino et al. (p. 1210; see the Perspective by Shaw and Huang) present a crystal structure of CAR/JAML, which revealed an intracellular signaling motif similar to that known for the αβ T cell costimulatory receptor that signals through phosphoinositide 3-kinase. A costimulatory receptor for immune cells in the skin is identified. γδ T cells present in epithelial tissues provide a crucial first line of defense against environmental insults, including infection, trauma, and malignancy, yet the molecular events surrounding their activation remain poorly defined. Here we identify an epithelial γδ T cell–specific costimulatory molecule, junctional adhesion molecule–like protein (JAML). Binding of JAML to its ligand Coxsackie and adenovirus receptor (CAR) provides costimulation leading to cellular proliferation and cytokine and growth factor production. Inhibition of JAML costimulation leads to diminished γδ T cell activation and delayed wound closure akin to that seen in the absence of γδ T cells. Our results identify JAML as a crucial component of epithelial γδ T cell biology and have broader implications for CAR and JAML in tissue homeostasis and repair.

The molecular interaction of CAR and JAML recruits the central cell signal transducer PI3K.

Skin Reaction Lymphocytes in the skin known as γδ T cells provide an important barrier against infection and injury. Unlike classical αβ T cells, less is known about the molecular requirements of γδ T cell activation. Two studies demonstrate that the junctional adhesion molecule–like protein (JAML) is a costimulatory molecule for mouse γδ T. Witherden et al. (p. 1205; see the Perspective by Shaw and Huang) showed that JAML, binding to its ligand Coxsackie and adenovirus receptor (CAR), leads to proliferation, as well as cytokine and growth factor production by γδ T cells. In vivo, JAML-CAR interactions contributed to the wound healing response in mice. Verdino et al. (p. 1210; see the Perspective by Shaw and Huang) present a crystal structure of CAR/JAML, which revealed an intracellular signaling motif similar to that known for the αβ T cell costimulatory receptor that signals through phosphoinositide 3-kinase. Ligand engagement and initiation of signaling has been imaged for a costimulatory receptor for immune cells in the skin. Coxsackie and adenovirus receptor (CAR) is the primary cellular receptor for group B coxsackieviruses and most adenovirus serotypes and plays a crucial role in adenoviral gene therapy. Recent discovery of the interaction between junctional adhesion molecule–like protein (JAML) and CAR uncovered important functional roles in immunity, inflammation, and tissue homeostasis. Crystal structures of JAML ectodomain (2.2 angstroms) and its complex with CAR (2.8 angstroms) reveal an unusual immunoglobulin-domain assembly for JAML and a charged interface that confers high specificity. Biochemical and mutagenesis studies illustrate how CAR-mediated clustering of JAML recruits phosphoinositide 3-kinase (P13K) to a JAML intracellular sequence motif as delineated for the αβ T cell costimulatory receptor CD28. Thus, CAR and JAML are cell signaling receptors of the immune system with implications for asthma, cancer, and chronic nonhealing wounds.

Formation of Disulfide Bonds and Homodimers of the Major Cat Allergen Fel d 1 Equivalent to the Natural Allergen by Expression in Escherichia coli

Dander from the domestic cat (Felis domesticus) is one of the most common causes of IgE-mediated allergy. Attempts to produce tetrameric folded major allergen Fel d 1 by recombinant methods with structural features similar to the natural allergen have been only partially successful. In this study, a recombinant folded Fel d 1 with molecular and biological properties similar to the natural counterpart was produced. A synthetic gene coding for direct fusion of the Fel d 1 chain 2 N-terminally to chain 1 was constructed by overlapping oligonucleotides in PCR. Escherichia coli expression resulted in a non-covalently associated homodimer with an apparent molecular mass of 30 kDa defined by size exclusion chromatography. Furthermore, each 19,177-Da subunit displayed a disulfide pattern identical to that found in the natural Fel d 1, i.e. Cys3(1) Cys73(2), Cys44(1)-Cys48(2), Cys70(1)-Cys7(2), as determined by electrospray mass spectrometry after tryptic digestion. Circular dichroism analysis showed identical folds of natural and recombinant Fel d 1. Furthermore, recombinant Fel d l reacted specifically with serum IgE, inducing expression of CD203c on basophils and lymphoproliferative responses in cat-allergic patients. The results show that the overall fold and immunological properties of the recombinant Fel d 1 are very similar to those of natural Fel d 1. Moreover, the recombinant Fel d 1 construct provides a tool for defining the three-dimensional structure of Fel d 1 and represents a reagent for diagnosis and allergen-specific immunotherapy of cat allergy.

Dimerization of the Major Birch Pollen Allergen Bet v 1 Is Important for its In Vivo IgE-Cross-Linking Potential in Mice

In type I allergy, the cross-linking of membrane IgE on B lymphocytes and of cytophilic IgE on effector cells by their respective allergens are key events. For cross-linking two IgE molecules, allergens need at least two epitopes. On large molecules, these could be different epitopes in a multivalent, or identical epitopes in a symmetrical, fashion. However, the availability of epitopes may be limited on small allergens such as Bet v 1, the major birch pollen allergen. The present work analyzes whether dimerization is required for the cross-linking capacity of this allergen. In immunoblots, murine monoclonal and polyclonal human Bet v 1-specific Abs detected, besides a Bet v 1 monomer of 17 kDa, a dimer of 34 kDa. In dynamic light scattering, Bet v 1 appeared as dimers and even multimers, but a single condition could be defined where it behaved exclusively monomerically. Small-angle x-ray scattering of the monomeric and dimeric samples resulted in diagrams agreeing with the calculated models. Circular dichroism measurements indicated that the structure of Bet v 1 was preserved under monomeric conditions. Skin tests in Bet v 1-allergic mice were positive with Bet v 1 dimer, but remained negative using the monomer. Furthermore, in contrast to dimeric Bet v 1, the monomer was less capable of activating murine memory B cells for IgE production in vivo. Our data indicate that the presentation of two identical epitopes by dimerized allergens is a precondition for cross-linking of IgE on mast cells and B lymphocytes.

Mutants of the major ryegrass pollen allergen, Lol p 5, with reduced IgE-binding capacity: candidates for grass pollen-specific immunotherapy.

More than 400 million individuals are sensitized to grass pollen allergens. Group 5 allergens represent the most potent grass pollen allergens recognized by more than 80 % of grass pollen allergic patients. The aim of our study was to reduce the allergenic activity of group 5 allergens for specific immunotherapy of grass pollen allergy. Based on B‐ and T‐cell epitope mapping studies and on sequence comparison of group 5 allergens from different grasses, point mutations were introduced by site‐directed mutagenesis in highly conserved sequence domains of Lol p 5, the group 5 allergen from ryegrass. We obtained Lol p 5 mutants with low IgE‐binding capacity and reduced allergenic activity as determined by basophil histamine release and by skin prick testing in allergic patients. Circular dichroism analysis showed that these mutants exhibited an overall structural fold similar to the recombinant Lol p 5 wild‐type allergen. In addition, Lol p 5 mutants retained the ability to induce proliferation of group 5 allergen‐specific T cell lines and clones. Our results demonstrate that a few point mutations in the Lol p 5 sequence yield mutants with reduced allergenic activitythat represent potential vaccine candidates for immunotherapy of grass pollen allergy.

The junctional adhesion molecule JAML is a costimulatory receptor for epithelial gammadelta T cell activation.

Skin Reaction Lymphocytes in the skin known as γδ T cells provide an important barrier against infection and injury. Unlike classical αβ T cells, less is known about the molecular requirements of γδ T cell activation. Two studies demonstrate that the junctional adhesion molecule–like protein (JAML) is a costimulatory molecule for mouse γδ T. Witherden et al. (p. 1205; see the Perspective by Shaw and Huang) showed that JAML, binding to its ligand Coxsackie and adenovirus receptor (CAR), leads to proliferation, as well as cytokine and growth factor production by γδ T cells. In vivo, JAML-CAR interactions contributed to the wound healing response in mice. Verdino et al. (p. 1210; see the Perspective by Shaw and Huang) present a crystal structure of CAR/JAML, which revealed an intracellular signaling motif similar to that known for the αβ T cell costimulatory receptor that signals through phosphoinositide 3-kinase. A costimulatory receptor for immune cells in the skin is identified. γδ T cells present in epithelial tissues provide a crucial first line of defense against environmental insults, including infection, trauma, and malignancy, yet the molecular events surrounding their activation remain poorly defined. Here we identify an epithelial γδ T cell–specific costimulatory molecule, junctional adhesion molecule–like protein (JAML). Binding of JAML to its ligand Coxsackie and adenovirus receptor (CAR) provides costimulation leading to cellular proliferation and cytokine and growth factor production. Inhibition of JAML costimulation leads to diminished γδ T cell activation and delayed wound closure akin to that seen in the absence of γδ T cells. Our results identify JAML as a crucial component of epithelial γδ T cell biology and have broader implications for CAR and JAML in tissue homeostasis and repair.

The cross‐reactive calcium‐binding pollen allergen, Phl p 7, reveals a novel dimer assembly

The timothy grass pollen allergen Phl p 7 assembles most of the IgE epitopes of a novel family of 2 EF‐hand calcium‐binding proteins and therefore represents a diagnostic marker allergen and vaccine candidate for immunotherapy. Here we report the first three‐dimensional structure of a representative of the 2 EF‐hand allergen family, Phl p 7, in the calcium‐bound form. The protein occurs as a novel dimer assembly with unique features: in contrast to well known EF‐hand proteins such as calmodulin, parvalbumin or the S100 proteins, Phl p 7 adopts an extended conformation. Two protein monomers assemble in a head‐to‐tail arrangement with domain‐swapped EF‐hand pairing. The intertwined dimer adopts a barrel‐like structure with an extended hydrophobic cavity providing a ligand‐binding site. Calcium binding acts as a conformational switch between an open and a closed dimeric form of Phl p 7. These findings are interesting in the context of lipid‐ and calcium‐dependent pollen tube growth. Furthermore, the structure of Phl p 7 allows for the rational development of vaccine strategies for treatment of sensitized allergic patients.