For years, the use of polyhistidine
tags (His-tags) has been a
staple in the isolation of recombinant proteins in immobilized metal
affinity chromatography experiments. Their usage has been widely beneficial
in increasing protein purity from crude cell lysates. For some recombinant
proteins, a consequence of His-tag addition is that it can affect
protein function and stability. Functional proteins are essential
in the elucidation of their biological, kinetic, structural, and thermodynamic
properties. In this study, we determine the effect of N-terminal His-tags
on the thermal stability of select proteins using differential scanning
fluorimetry and identify that the removal of the His-tag can have
both beneficial and deleterious effects on their stability.
Der p 2 is one of the most important allergens from the house dust mite Dermatophagoides pteronyssinus. Identification of human IgE Ab binding epitopes can be used for rational design of allergens with reduced IgE reactivity for therapy. Antigenic analysis of Der p 2 was performed by site-directed mutagenesis based on the x-ray crystal structure of the allergen in complex with a Fab from the murine IgG mAb 7A1 that binds an epitope overlapping with human IgE binding sites. Conformational changes upon Ab binding were confirmed by nuclear magnetic resonance using a 7A1-single-chain variable fragment. In addition, a human IgE Ab construct that interferes with mAb 7A1 binding was isolated from a combinatorial phage-display library constructed from a mite-allergic patient and expressed as two recombinant forms (single-chain Fab in Pichia pastoris and Fab in Escherichia coli). These two IgE Ab constructs and the mAb 7A1 failed to recognize two Der p 2 epitope double mutants designed to abolish the allergen-Ab interaction while preserving the fold necessary to bind Abs at other sites of the allergen surface. A 10-100-fold reduction in binding of IgE from allergic subjects to the mutants additionally showed that the residues mutated were involved in IgE Ab binding. In summary, mutagenesis of a Der p 2 epitope defined by x-ray crystallography revealed an IgE Ab binding site that will be considered for the design of hypoallergens for immunotherapy.
Der p 1 is a major allergen from the house dust mite Dermatophagoides pteronyssinus that belongs to the papain-like cysteine protease family. To investigate the antigenic determinants of Der p 1, we determined two crystal structures of Der p 1 in complex with the Fab fragments of mAbs 5H8 or 10B9. Epitopes for these two Der p 1-specific antibodies are located in different, non-overlapping parts of the Der p 1 molecule. Nevertheless, surface area and identity of the amino acid residues involved in hydrogen bonds between allergen and antibody are similar. The epitope for mAb 10B9 only, showed a partial overlap with the previously reported epitope for mAb 4C1, a cross-reactive mAb that binds Der p 1 and its homolog Der f 1 from D. farinae. Upon binding to Der p 1, the Fab fragment of mAb 10B9 was found to form a very rare alpha-helix in its third CDR of the heavy chain. In order to provide an overview of the surface properties of the interfaces formed by the complexes of Der p 1-10B9 and Der p 1-5H8, along with the complexes of 4C1 with Der p 1 and Der f 1, a broad analysis of the surfaces and hydrogen bonds of all complexes of Fab-protein or Fab-peptide was performed. This work provides detailed insight into the cross-reactive and specific allergen-antibody interactions in Group 1 mite allergens. The surface data of Fab-protein and Fab-peptide interfaces can be used in the design of less potent conformational epitopes for immunotherapy.
Nonspecific
lipid transfer proteins (nsLTPs) are basic proteins,
stabilized by four disulfide bonds, and are expressed throughout the
plant kingdom. These proteins are also known as important allergens
in fruits and tree nuts. In this study, the nsLTP from hazelnuts,
Cor a 8, was purified and its crystal structure determined. The protein
is stable at low pH and refolds after thermal denaturation. Molecular
dynamics simulations were used to provide an insight into conformational
changes of Cor a 8 upon ligand binding. When known epitope areas from
Pru p 3 were compared to those of Cor a 8, differences were obvious,
which may contribute to limited cross-reactivity between peach and
hazelnut allergens. Differences in epitope regions may contribute
to limited cross-reactivity between Cor a 8 and nsLTPs from other
plant sources. The structure of Cor a 8 represents the first resolved
structure of a hazelnut allergen.
Kiwellin (Act d 5) is an allergenic protein contained in kiwifruit pulp in high amounts. The aim of this study was to investigate the three-dimensional structure of the natural molecule from green kiwifruit and its possible function. Kiwellin was crystallized, and its structure, including post-translational modifications, was elucidated. The molecular weight and structural features, in solution, were analyzed by gel filtration and circular dichroism, respectively. Although structurally similar to expansin, kiwellin lacks expansin activity and carbohydrate binding. A specific algorithm was applied to investigate any possible IgE reactivity correlation between kiwellin and a panel of 102 allergens, including expansins and other carbohydrate-binding allergens. The available data suggest a strong dependence of the kiwellin structure on the environmental/experimental conditions. This dependence therefore poses challenges in detecting the correlations between structural, functional, and immunological features of this protein.
Bla g 4 is a male cockroach specific protein and is one of the major allergens produced by Blattella germanica (German cockroach). This protein belongs to the lipocalin family that comprises a set of proteins that characteristically bind small hydrophobic molecules and play a role in a number of processes such as: retinoid and pheromone transport, prostaglandin synthesis and mammalian immune response. Using NMR and Isothermal Titration Calorimetry we demonstrated that Bla g 4 binds tyramine and octopamine in solution. In addition, crystal structure analysis of the complex revealed details of tyramine binding. As tyramine and octopamine play important roles in invertebrates, and are counterparts to vertebrate adrenergic transmitters, we speculate that these molecules are physiological ligands for Bla g 4. The nature of binding these ligands to Bla g 4 sheds light on the possible biological function of the protein. In addition, we performed a large-scale analysis of Bla g 4 and Per a 4 (an allergen from American cockroach) homologs to get insights into the function of these proteins. This analysis together with a structural comparison of Blag 4 and Per a 4 suggests that these proteins may play different roles and most likely bind different ligands.
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