Modeling the three-dimensional structures of an unbound single-chain variable fragment (scFv) and its hypothetical complex with a Corynespora cassiicola toxin, cassiicolin.

Rubber trees infected with a host-specific cassiicolin toxin often experience considerable leaf fall, which in turn results in loss of crop productivity. It was recently revealed that cassiicolin-specific single-chain variable fragments (scFv) can successfully reduce the toxic effects of cassiicolin. However, the detailed mechanism of antibody action remains poorly understood. The primary sequence of the newly sequenced cassiicolin-specific scFv was highly homologous to several members of single-chain antibodies in the 14B7 family. In this study, with the aid of homology modeling, the three-dimensional structure of cassiicolin-specific scFv was elucidated, and was found to exhibit a characteristic immunoglobulin fold that mainly consists of ß sheets. Additionally, molecular docking between the modeled scFv antibody and the available three-dimensional crystal structure of cassiicolin toxin was also performed. The predicted structural complex and the change in accessible surface area between the toxin and the scFv antibody upon complexation reveal the potential role of certain complementarity determining region (CDR) amino acid residues in the formation of the complex. These computational results suggest that mutagenesis experiments that are aimed at validating the model and improving the binding affinity of cassiicolin-specific scFv antibodies for the toxin should be performed.

A molecular and in silico characterization of Hev b 4, a glycosylated latex allergen.

Hev b 4 is a heavily glycosylated latex allergen with seven attached N-glycans, comprising of both oligomannose and complex type structures. Treatment with a mixture of N-glycosidase A and N-glycosidase F resulted in lowering Hev b 4 protein on SDS-gel from 53 to 55kDa to circa 40kDa, this being comparable to the 38.53kDa mass predicted by its cDNA. In Western-immunoblots, the enzymatically deglycosylated Hev b 4 showed negligible binding to IgE from latex allergic patients; the results indicated that IgE essentially binds to Hev b 4 via its N-glycan moiety. Structural modelling of the Hev b 4 was carried out based on the template protein and carbohydrate crystal coordinates of rhamnogalacturonan acetylesterase (PDB ID 1DEO). We managed to link four N-glycan structures on to the Hev b 4 model; the glycans were scattered over the surface of the model. The structural and functional features of Hev b 4 could prove useful to elucidate its exposed epitopes which are important for IgE binding.

Structural analysis of the glycoprotein allergen Hev b 4 from natural rubber latex by mass spectrometry.

The lecithinase homolog (Hev b 4) from Hevea brasiliensis (Q6T4P0_HEVBR) is an important natural rubber latex allergen. Hev b 4 is a highly glycosylated protein and its carbohydrate moiety has been implicated in the binding of IgE from natural rubber latex allergic patients. The cDNA for Hev b 4 has recently been cloned and sequenced. Here, we have analyzed the post-translational modifications of natural Hev b 4 by liquid chromatography/electrospray ionization-mass spectrometry of tryptic peptides. Seven of the eight potential glycosylation sites were found to be occupied. One site, however, was only partially glycosylated. Asn224 was substituted by complex type N-glycans with fucose and xylose, whereas all other sites carried either oligomannose glycans or a mixture of oligomannose and complex N-glycans. Glycosylation site Asn308, the most C-terminal one of the eight sites, was only found in the non-glycosylated form. The complex type N-glycans apparently form the molecular basis for the immune reaction with patients' sera. A large fraction of Hev b 4 molecules contains two or more complex N-glycans and thus a physiological reaction against these polyvalent allergens on the basis of the carbohydrate is in theory possible. Aside from allowing glycosylation analysis, the mass spectrometric data defined the N-terminal cleavage site of Hev b 4. This study once more demonstrates the outstanding analytical potential of electrospray ionization-mass spectrometry coupled with liquid chromatographic separation.