Allergies are caused by the immune reaction to commonly harmless proteins, allergens. This reaction is typified by immunoglobulin E (IgE) antibodies. We report the crystal structure of an IgE Fab fragment in complex with beta-lactoglobulin (BLG), one of the major allergens of bovine milk. The solved structure shows how two IgE/Fab molecules bind the dimeric BLG. The epitope of BLG consists of six different short fragments of the polypeptide chain, which are located especially in the beta strands, covering a flat area on the allergen surface. All six CDR (complementary-determining region) loops of the IgE Fab participate in the binding of BLG. The light chain CDR loops are responsible for the binding of the flat beta sheet region of BLG. The IgE epitope is different from common IgG epitopes that are normally located in the exposed loop regions of antigens and observed also in the two recently determined allergen-IgG complexes.
In Vivo Detection of Vascular Adhesion Protein-1 in Experimental Inflammation
Vascular adhesion protein-1 (VAP-1) is an inflammation-inducible endothelial glycoprotein which mediates leukocyte-endothelial cell interactions. To study the pathogenetic significance of VAP-1 in inflammatory disorders, an in vivo immunodetection method was used to detect the regulation of luminally expressed VAP-1 in experimental skin and joint inflammation in the pig and dog. Moreover, VAP-1 was studied as a potential target to localize inflammation by radioimmunoscintigraphy. Up-regulation of VAP-1 in experimental dermatitis and arthritis could be visualized by specifically targeted immunoscintigraphy. Moreover, the translocation of VAP-1 to the functional position on the endothelial surface was only seen in inflamed tissues. These results suggest that VAP-1 is both an optimal candidate for anti-adhesive therapy and a potential target molecule for imaging inflammation. Leukocyte migration into tissues is vital for efficient defense against insulting pathogens and foreign antigens. Nevertheless, the same phenomenon is also crucial to inappropriate inflammation and tissue destruction in several types of acute and chronic inflammatory and autoimmune diseases such as rheumatoid arthritis, inflammatory bowel diseases, organ transplant rejection, and ischemia-reperfusion injury. Leukocytes enter from the blood circulation into the tissues by passing through the walls of blood vessels. An essential step in this process is binding of leukocytes to the innermost layer of the blood vessel wall, the endothelium, by adhesion molecules. Multiple adhesion molecules on the leukocytes interact concertedly with their counter-receptors on the endothelium during the adhesion and the subsequent transmigration process.1,2 A change in the functional expression of adhesion molecules on the endothelial surface is an early and specific indicator of inflammation. In fact, recent studies suggest that radioactively labeled monoclonal antibodies against specific endothelial adhesion molecules can be used in the diagnosis of inflammation by nuclear imaging methods. 3,4Human vascular adhesion protein-1 (VAP-1), originally defined by 1B2 monoclonal antibody, is a 170-kd endothelial sialoglycoprotein.5 VAP-1 is inflammation inducible and mediates the early phases of interaction between lymphocytes and endothelium. 6 The expression pattern of VAP-1 in normal and inflamed human tissues has been described 7,8 and the role of VAP-1 in human leukocyte adhesion has been shown in vitro. 5,9 However, practically nothing is known about the translocation of VAP-1 from the inside of the cells to the functional position on the cell surface as well as the significance of VAP-1 in leukocyteendothelium interactions in vivo.The anti-human-VAP-1 mAb 1B2 does not recognize VAP-1 of small laboratory animals such as mouse, rat, or rabbit. However, preliminary screening experiments revealed that 1B2 antibody does recognize porcine and canine blood vessels. That encouraged us to study whether the antigens recognized by 1B2 are the porcine and canine homologues o...
BackgroundAllergen-mediated cross-linking of IgE antibodies bound to the FcεRI receptors on the mast cell surface is the key feature of the type I allergy. If an allergen is a homodimer, its allergenicity is enhanced because it would only need one type of antibody, instead of two, for cross-linking.Methodology/Principal FindingsAn analysis of 55 crystal structures of allergens showed that 80% of them exist in symmetric dimers or oligomers in crystals. The majority are transient dimers that are formed at high protein concentrations that are reached in cells by colocalization. Native mass spectrometric analysis showed that native allergens do indeed form transient dimers in solution, while hypoallergenic variants of them exist almost solely in the monomeric form. We created a monomeric Bos d 5 allergen and show that it has a reduced capability to induce histamine release.Conclusions/SignificanceThe results suggest that dimerization would be a very common and essential feature for allergens. Thus, the preparation of purely monomeric variants of allergens could open up novel possibilities for specific immunotherapy.
Recombinant pharmaceutical proteins expressed in hairy root cultures can be secreted into the medium to improve product homogeneity and to facilitate purification, although this may result in significant degradation if the protein is inherently unstable or particularly susceptible to proteases. To address these challenges, we used a design of experiments approach to develop an optimized induction protocol for the cultivation of tobacco hairy roots secreting the full-size monoclonal antibody M12. The antibody yield was enhanced 30-fold by the addition of 14 g/L KNO3 , 19 mg/L 1-naphthaleneacetic acid and 1.5 g/L of the stabilizing agent polyvinylpyrrolidone. Analysis of hairy root cross sections revealed that the optimized medium induced lateral root formation and morphological changes in the inner cortex and pericycle cells, indicating that the improved productivity was at least partially based on the enhanced efficiency of antibody secretion. We found that 57% of the antibody was secreted, yielding 5.9 mg of product per liter of induction medium. Both the secreted and intracellular forms of the antibody could be isolated by protein A affinity chromatography and their functionality was confirmed using vitronectin-binding assays. Glycan analysis revealed three major plant complex-type glycans on both forms of the antibody, although the secreted form was more homogeneous due to the predominance of a specific glycoform. Tobacco hairy root cultures therefore offer a practical solution for the production of homogeneous pharmaceutical antibodies in containment.
Granulocyte extravasation from the blood into tissues is a prerequisite for a proper inflammatory response. It is regulated by a multistep adhesion cascade consisting of successive contacts between leukocyte surface receptors and their endothelial ligands on vessels. Vascular adhesion protein 1 (VAP-1) is an endothelial surface glycoprotein with two functions. It is an enzyme (monoamine oxidase) and an adhesion molecule for lymphocytes. Its function in binding of granulocytes or in leukocyte trafficking into sites of inflammation in vivo has remained unknown. Here we show that treatment of rabbits with anti-VAP-1 monoclonal antibodies abrogates approximately 70% of granulocyte extravasation into a site of an experimental inflammation. Using intravital microscopy, VAP-1 blockade is shown to increase the velocity of the rolling granulocytes and the frequency of their jerky skippings during the rolling. In addition, the number of firmly bound leukocytes decreased by 44% when VAP-1 was rendered nonfunctional. Our results suggest that VAP-1 functions as a molecular brake early in the adhesion cascade and consequently decreases the firm adherence; it may also directly influence the transmigration step. These data elucidate a new interplayer in the granulocyte extravasation process and provide a novel physiological function for a member of the monoamine oxidase family.
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