Abstract
Bauhinia variegata lectins (BVL-I and BVL-II) are single chain lectins isolated from the plant Bauhinia variegata. Single chain lectins undergo post-translational processing on its N-terminal and C-terminal regions, which determines their physiological targeting, carbohydrate binding activity and pattern of quaternary association. These two lectins are isoforms, BVL-I being highly glycosylated, and thus far, it has not been possible to determine their structures. The present study used prediction and validation algorithms to elucidate the likely structures of BVL-I and -II. The program Bhageerath-H was chosen from among three different structure prediction programs due to its better overall reliability. In order to predict the C-terminal region cleavage sites, other lectins known to have this modification were analysed and three rules were created: (1) the first amino acid of the excised peptide is small or hydrophobic; (2) the cleavage occurs after an acid, polar, or hydrophobic residue, but not after a basic one; and (3) the cleavage spot is located 5-8 residues after a conserved Leu amino acid. These rules predicted that BVL-I and –II would have fifteen C-terminal residues cleaved, and this was confirmed experimentally by Edman degradation sequencing of BVL-I. Furthermore, the C-terminal analyses predicted that only BVL-II underwent α-helical folding in this region, similar to that seen in SBA and DBL. Conversely, BVL-I and -II contained four conserved regions of a GS-I association, providing evidence of a previously undescribed X4+unusual oligomerisation between the truncated BVL-I and the intact BVL-II. This is the first report on the structural analysis of lectins from Bauhinia spp. and therefore is important for the characterisation C-terminal cleavage and patterns of quaternary association of single chain lectins.
Highlights
Lectins, known as agglutinins, are proteins or glycoproteins capable of binding mono- or oligosaccharides in a specific, reversible, manner [1]
This type of post-translational modification does not involve rebinding polypeptide chains and results in the production of single chain lectins such as the soybean agglutinin (SBA) [21], Dolichos biflorus lectin (DBL) [22,23], peanut agglutinin (PNA) [20], Erythrina corallodendron lectin (EcorL) and others from
Of the five structures generated by this program for each protein, the most reliable was selected based on the analysis of four parameters: Z-score, QMEAN score, Ramachandran plot (RP) and root-mean-square deviation (RMSD)
Summary
Known as agglutinins, are proteins or glycoproteins capable of binding mono- or oligosaccharides in a specific, reversible, manner [1]. Numerous experiments have demonstrated their diverse applications, including e.g.: insecticidal, antifungal, antiviral, antitumor, and immunomodulatory activities [3,4,5] As their recognition of sugars is highly specific, lectins are used in glycobiology to study protein-carbohydrate interactions. Lectins are primarily synthesized as inactive precursors and are activated by two distinct processes Legume lectins such as Concanavalin A (ConA) and Canavalia brasiliensis lectin (ConBr) undergo a complex post-translational modification process of deglycosylation, endoproteolytic cleavage, and polypeptide chain rebind. In this process, after excision of the N-terminal signal sequence, a linker and a C-terminal extension peptides, the β and γ chains, are linked by a peptide bond to form an inverted active lectin called the α chain [7,8,9]. This type of post-translational modification does not involve rebinding polypeptide chains and results in the production of single chain lectins such as the soybean agglutinin (SBA) [21], Dolichos biflorus lectin (DBL) [22,23], peanut agglutinin (PNA) [20], Erythrina corallodendron lectin (EcorL) and others from
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