Showing papers on "Galectin published in 1993"

The family of metazoan metal-independent β-galactoside-binding lectins: structure, function and molecular evolution

Abstract: Animal metal-independent beta-galactoside-binding lectins were initially found in vertebrates, but they have recently been isolated from much lower invertebrates, such as nematode and sponge, as well. Further, an eosinophilic lysophospholipase associated with various inflammatory reactions was very recently found to be a new member of this protein family. It appears that beta-galactoside-binding lectins and some non-lectin proteins form a superfamily whose members are widely distributed from vertebrates to invertebrates. From the viewpoints of protein architecture, the superfamily members can be subdivided into three types; i.e. 'proto type' (the relatively well-studied 14 kDa lectins), 'chimera type' (29-35 kDa lectins also known as epsilon BP/CBP35/Mac2/laminin-binding protein) and 'tandem-repeat type' (a newly found nematode 32 kDa lectin). Comparison of their amino acid sequences and mutagenesis studies have suggested the functional importance of some conservative hydrophilic residues (His44, Asn46, Arg48, Glu71 and Arg73 of human 14 kDa lectin). Several non-charged residues (Gly14, Phe45, Pro47, Phe49, Val59, Trp68, Pro78 and Phe79) are also well conserved, and are probably important to maintain the structural framework of these proteins. A consideration of molecular evolution suggests that lectins belonging to this family probably existed in the Precambrian era. Ubiquitous occurrence of these homologous lectins with shared sugar specificity suggests that they are involved in 'essential minimum' functions of multicellular animals, possibly in cooperation with their partner glycoconjugates.

Structure-function relationship of a recombinant human galactoside-binding protein.

Abstract: A galactoside-binding lectin (hL-31) containing a collagen-like sequence was identified in human tumor cells. It was found to be the homologue of the IgE-binding protein, the macrophage cell-surface Mac-2 antigen, and the murine CBP35, RL-29, and mL-34 lectins. Here we report on the expression in Escherichia coli and functional analysis of recombinant hL-31 (rhL-31). The rhL-31 was purified in one step through an asialofetuin affinity column. The rhL-31 was reactive to anti-lectin antibodies and retained its lactose-dependent hemagglutination of trypsin-treated glutaraldehyde-fixed rabbit erythrocytes. The rhL-31 elutes from an affinity column as a 31-kDa monomer and undergoes homodimerization at relatively high protein concentrations, comparable to those used to mediate hemagglutination. Electron microscopy showed that the rhL-31 appears as a Y-shaped structure. Lactoperoxidase-catalyzed iodination of murine tumor cell-surface proteins followed by collagenase treatment revealed that the lectin is probably a peripheral membrane protein whereby both the amino and the carboxy termini are exposed on the outer cell membrane. These results point to the membrane disposition and orientation of the lectin and suggest a mechanism for a structure-function relationship of lectin activity.

Galaptin-mediated Adhesion of Human Ovarian Carcinoma A121 Cells and Detection of Cellular Galaptin-binding Glycoproteins

Abstract: Previously, we have shown that galaptin, an endogenous beta-galactoside-binding lectin, is present in extracellular matrix where it may participate in the adhesion of A121 human ovarian carcinoma cells to extracellular matrix via interaction with specific cell surface carbohydrate receptors. We now report that A121 cells adhere to polystyrene plates coated with polymerized human splenic galaptin. The carbohydrate-mediated specificity of this adhesive interaction was demonstrated by inhibition with lactose. Additionally, treatment of A121 cells with neuraminidase increased cellular adherence by 30%, while beta-galactosidase treatment of cells decreased adherence by 65%. These findings prompted us to isolate and identify the cell surface galaptin receptor. In a Western blot of A121 cell extracts separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, 125I-labeled polymerized galaptin bound [corrected] to a unique cellular protein having a molecular mass of 110 kDa. This receptor was enriched by affinity chromatography using polymerized galaptin-Sepharose. Treatment of this material with N-glycanase ablated its galaptin-binding activity. In related studies, A121 cells metabolically labeled with [3H]glucosamine demonstrated a radiolabeled polymerized galaptin-binding protein with an identical molecular mass of 110 kDa. These studies confirmed the glycoprotein nature of this putative endogenous cellular galaptin receptor. Further studies with antibodies directed against two lysosomal associated membrane proteins, lamp-1 and lamp-2, demonstrated specific reactivity in Western blots with the 110-kDa glycoprotein. Additionally, 125I-polymerized galaptin recognized a 110-kDa protein in Western blots of material immunoprecipitated from A121 cell lysates by lamp-1 and lamp-2 antibodies. Finally, indirect immunofluorescence using antibodies directed against lamps detected cell surface antigenicity. Therefore, lamp-1 and/or lamp-2 appear to be the putative cell surface receptors involved in the adhesion of ovarian carcinoma cells to extracellular matrix mediated by galaptin.