ABSTRACT
A three-dimensional (3D) graphic model of a single-chain Fv (scFv) which was derived from an anti-human placental acidic isoferritin (PAF) monoclonal antibody (Mab) was constructed by a homologous protein-predicting computer algorithm on Silicon graphic computer station.The structure, surface static electricity and hydrophobicity of scFv were investigated. Computer graphic modelling indicated that all regions of scFv including the linker, variable regions of the heavy (VH) and light (VL) chains were suitable. The VH region and the VL region were involved in composing the "hydrophobic pocket". The linker was drifted away VH and VL regions. The complementarity determining regions (CDRs) of VH and VL regions surrounded the "hydrophobic pocket". This study provides a theory basis for improving antibody affinity, investigating antibody structure and analyzing the functions of VH and VL regions in antibody activity.
ABSTRACT
A three-dimensional (3D) graphic model of a single-chain Fv (scFv) which was derived from an anti-human placental acidic isoferritin (PAF) monoclonal antibody (Mab) was constructed by a homologous protein-predicting computer algorithm on Silicon graphic computer station.The structure, surface static electricity and hydrophobicity of scFv were investigated. Computer graphic modelling indicated that all regions of scFv including the linker, variable regions of the heavy (VH) and light (VL) chains were suitable. The VH region and the VL region were involved in composing the "hydrophobic pocket". The linker was drifted away VH and VL regions. The complementarity determining regions (CDRs) of VH and VL regions surrounded the "hydrophobic pocket". This study provides a theory basis for improving antibody affinity, investigating antibody structure and analyzing the functions of VH and VL regions in antibody activity.
ABSTRACT
Bowman-Birk inhibitors (BBI) isolated from plant seeds are small proteins active against trypsin and/or chymotrypsin. These inhibitors have been extensively studied in terms of their structure, interactions, function and evolution. Examination of the known three-dimensional structures of BBIs revealed similarities and subtle differences. The hydrophobic core, deduced from surface accessibility and hydrophobicity plots, corresponding to the two tandem structural domains of the double headed BBI are related by an almost exact two-fold, in contrast to the reactive site loops which depart appreciably from the two-fold symmetry. Also, the orientations of inhibitory loops in soybean and peanut inhibitors were different with respect to the rigid core. Based on the structure of Adzuki bean BBI-trypsin complex, models of trypsin and chymotryspin bound to the monomeric soybean BBI (SBI) were constructed. There were minor short contacts between the two enzymes bound to the inhibitor suggesting near independence of binding. Binding studies revealed that the inhibition of one enzyme in the presence of the other is associated with a minor negative cooperativity. In order to assess the functional significance of the reported oligomeric forms of BBI, binding of proteases to the crystallographic and non-crystallographic dimers as found in the crystal structure of peanut inhibitor were examined. It was found that all the active sites in these oligomers cannot simultaneously participate in inhibition.
ABSTRACT
The possible B-cell epitopes of the outer membrane porin OmpC of Salmonella typhi have been identified, using the primary structure of the protein, by means of multiple sequence alignment and the known molecular structure of two other porins. From the analysis, 8 regions were identified as immunodominant and these were ranked based on antigenic index and the ratio of the number of nonconserved residues to the fragment length. Model building of the top two ranked regions show the tendency to form loop structures supporting the possibility of these being candidate epitopes.
ABSTRACT
The possible modes of binding of kojibiose, nigerose, maltose and ManPα(1 →2)Man to concanavalin A have been investigated using computer modelling studies. While α12 linked disaccharides bind to concanavalin A in two modes, i.e. by placing the reducing as well as non-reducing sugar units in the sugar binding site, nigerose or maltose can bind only in one mode, i.e. by placing the non-reducing sugar unit in the binding site. Though, both the sugar residues in α 12 linked disaccharides can reach the binding site, the preference is high for the non-reducing unit. When the non-reducing residue, in any of these disaccharides, enters the binding site, the allowed orientations and the possible hydrogen bonds with the protein seem to be independent of the glycosidic linkage. However, the number of hydrogen bonds the outward sugar residue forms with the protein are dependent on the type of linkage. Atleast one of the hydroxyl groups adjacent to the glycosidic linkage on the outward sugar residue is involved in the formation of a hydrogen bond with the protein suggesting the presence of an extended binding site. The orientation of the reducing sugar residue in the extended binding site is dependent on the linkage. Its orientation in nigerose is flipped when compared to that found in kojibiose or maltose leading to different non-covalent interactions with the protein which affect their binding affinities.
ABSTRACT
A review is presented focussing attention on the structural molecular biology of polysaccharides and complex carbohydrates, using examples obtained from terraqueous plants, animals, bacteria and insects The type and sequence of the condensation linkages in polysaccharides dominate their conformation, flexibility and interactions The extensive variety of geometries is overlaid by the constituent saccharide units themselves, decoration by side appendages and post-polymerisation chemical and structural modification X-ray diffraction information from oriented samples and computerised modelling has been used to analyse molecular conformation and geometry In general the relationship between glycosidic linkage geometry and conformation for the chemically simpler polysaccharides is understood In the case of more complex carbohydrates, unique solutions using diffraction methods alone are harder to establish In mixed protein carbohydrate systems, such as the glycoprotein antifreezes and protein-polysaccharide fibrous composites in insect cuticle, novel features in structure, morphology and interactions can usefully be explored and examined.