Samuel H. Barondes

X-ray Crystal Structure of the Human Galectin-3 Carbohydrate Recognition Domain at 2.1-Å Resolution

Galectins are a family of lectins which share similar carbohydrate recognition domains (CRDs) and affinity for small beta-galactosides, but which show significant differences in binding specificity for more complex glycoconjugates. We report here the x-ray crystal structure of the human galectin-3 CRD, in complex with lactose and N-acetyllactosamine, at 2.1-A resolution. This structure represents the first example of a CRD determined from a galectin which does not show the canonical 2-fold symmetric dimer organization. Comparison with the published structures of galectins-1 and -2 provides an explanation for the differences in carbohydrate-binding specificity shown by galectin-3, and for the fact that it fails to form dimers by analogous CRD-CRD interactions.

Developmentally regulated lectin in embryonic chick muscle and a myogenic cell line

Abstract Soluble extracts of embryonic chick pectoral muscle and myoblast clone L6 agglutinated trypsin treated glutaraldehyde fixed rabbit erythrocytes. Agglutination activity was blocked by thiodigalactoside, lactose and related saccharides but not by many other saccharides. Agglutination activity of chick pectoral muscle extracts increased at least one order of magnitude between 8 and 16 days of chick embryo development, as the pectoral muscle differentiated. With L6 myoblasts there was a three-fold increase in activity of the extracts as the myoblasts fused to form multinucleated myotubes.

Discoidin I is implicated in cell-substratum attachment and ordered cell migration of dictyostelium discoideum and resembles fibronectin

All three forms of discoidin I, an endogenous N-acetylgalactosamine-binding lectin from D. discoideum, contain the amino acid sequence gly-arg-gly-asp also found in fibronectin and implicated in its attachment to cells. Synthetic peptides containing these and adjacent amino acids of discoidin I block organized streaming during aggregation of D. discoideum and, at higher concentrations, block cell attachment and spreading on a plastic surface and formation of fruiting bodies. Pure discoidin I (with or without N-acetylgalactosamine) and univalent anti-discoidin I also block formation of streams during aggregation. Two mutants of D. discoideum with low levels of discoidin I apparently reflect the deficiency of this endogenous lectin by failing to form streams or to spread on plastic and by a partial failure to enter aggregates. Together, the results indicate that discoidin I functions like fibronectin to promote cell attachment and spreading as well as ordered cellular migration during morphogenesis.

Electromotive phenomena in partition of erythrocytes in aqueous polymer two phase systems.

Measurement was made of the electrical potential between the two phases formed in an aqueous solution containing 5% dextran, 4% polyethylene glycol and varying concentrations of sodium chloride and sodium phosphate. Partition of the polycation DEAE-dextran-glycyltyrosine-125I in such systems containing varying salt composition could be correlated with the measured electrical potential. Partion of human erythrocytes which have a negative surface charge was also correlated related with the measured electrical potential. Binding of DEAE-dextran-glycyltyrosine-125I to human erythrocytes had less effect on their partitioning than might be expected from the number of positive charges bound to their surface.

Lectin activity from embryonic chick brain, heart, and liver: Changes with development

Abstract Extracts of embryonic chick brain, heart, and liver agglutinate glutaraldehyde-fixed trypsinized or pronase-treated rabbit erythrocytes. Agglutination activity of extracts from each organ was inhibited by a number of saccharides. Lactose was the most potent saccharide inhibitor of those tested. The specific agglutination activity of the extracts from each of the organs studied changed with development of the embryo. In general, specific agglutination activity declined later in embryogenesis, and after hatching. However, the pattern of developmental change differed for each of the organs tested. Liver was unusual in that, after hatching, agglutination activity rose again; and the agglutinin found at this time was apparently different from that found in the embryo.

Strikingly Different Localization of Galectin-3 and Galectin-4 in Human Colon Adenocarcinoma T84 Cells GALECTIN-4 IS LOCALIZED AT SITES OF CELL ADHESION

Two β-galactoside-binding proteins were found to be prominently expressed in the human colon adenocarcinoma T84 cell line. Cloning and sequencing of one, a 36-kDa protein, identified it as the human homolog of galectin-4, a protein containing two carbohydrate binding domains and previously found only in the epithelial cells of the rat and porcine alimentary tract. The other, a 29-kDa protein, is galectin-3, containing a single carbohydrate binding domain, previously found in a number of different cell types including human intestinal epithelium. Despite the marked similarities in the carbohydrate binding domains of these two galectins, their cellular distribution patterns are strikingly different and vary with cellular conditions. In confluent T84 cells, galectin-4 is mostly cytosolic and concentrated at the basal membrane, whereas galectin-3 tends to be concentrated in large granular inclusions mostly at the apical membrane. In subconfluent T84 cells, each galectin is distributed to specific domains of lamellipodia, with galectin-4 concentrated in the leading edge and galectin-3 more proximally. Such different localization of galectins-4 and -3 within T84 cells implies different targeting mechanisms, ligands, and functions. The localization of galectin-4 suggests a role in cell adhesion which is also supported by the ability of immobilized recombinant galectin-4 to stimulate adhesion of T84 cells.

Agglutinin from Limulus polyphemus. Purification with formalinized horse erythrocytes as the affinity adsorbent.

We have purified an agglutinin from the hemolymph of Limulus polyphemus about 1500-3000-fold by adsorption to formalinized horse erythrocytes, elution with N-acetylneuraminic acid and subsequent fractionation on Sephadex G-200. Recovery was in the range of 50 percent. On ultracentrifugation the agglutinin behaves as an homogenous protein with a molecular weight of about 460 000. On polyacrylamide gel electrophoresis of the dissociated protein in sodium dodecylsulfate we found a single prominent diffuse band with an apparent molecular weight of 22 000 plus or minus 2000. This band contained carbohydrate as determined by periodic acid-Schiff staining. The intensity of staining compared with standards suggested a carbohydrate content of less than 4 percent. The protein contains a preponderance of acidic amino acids and has an isoelectric point of 4.83.5 residues per 1000 of glucosamine were detected on amino acid analysis. Agglutination of formalinized horse erythrocytes by the purified protein is inhibited not only by N-acetylneuraminic acid but also by D-glucuronic acid; but not by a number of other monosaccharides. D-Glucuronic acid may be used in place of N-acetylneuraminic acid as the eluting sugar in the purification procedure.

Receptor for the cell binding site of discoidin I

Discoidin I, a developmentally regulated lectin in Dictyostelium discoideum, has been implicated in cell-substratum adhesion and ordered cell migration during aggregation. This depends on the cell binding site of discoidin I, which is distinct from its carbohydrate binding site. We have isolated a receptor for the cell binding site by affinity chromatography. The receptor binds immobilized discoidin I in the presence of 0.3 M galactose and can be eluted with gly-arg-gly-asp-his-asp, a synthetic peptide the sequence of which is found in discoidin I, and which blocks cell migration into aggregates. The receptor is a developmentally regulated cell-surface glycoprotein of apparent Mr approximately 67,000. Univalent antibodies specific for this glycoprotein block aggregation.

Assessing the Feasibility of Linkage Disequilibrium Methods for Mapping Complex Traits: An Initial Screen for Bipolar Disorder Loci on Chromosome 18

Linkage disequilibrium (LD) analysis has been promoted as a method of mapping disease genes, particularly in isolated populations, but has not yet been used for genome-screening studies of complex disorders. We present results of a study to investigate the feasibility of LD methods for genome screening using a sample of individuals affected with severe bipolar mood disorder (BP-I), from an isolated population of the Costa Rican central valley. Forty-eight patients with BP-I were genotyped for markers spaced at approximately 6-cM intervals across chromosome 18. Chromosome 18 was chosen because a previous genome-screening linkage study of two Costa Rican families had suggested a BP-I locus on this chromosome. Results of the current study suggest that LD methods will be useful for mapping BP-I in a larger sample. The results also support previously reported possible localizations (obtained from a separate collection of patients) of BP-I-susceptibility genes at two distinct sites on this chromosome. Current limitations of LD screening for identifying loci for complex traits are discussed, and recommendations are made for future research with these methods.

Cycloheximide: Its Effects on Activity Are Dissociable from Its Effects on Memory

Cycloheximide, when injected subcutaneously or intracerebrally, produces changes in the activity level of mice. Isocycloheximide, injected intracerebrally, produces identical effects on activity, but it does not produce inhibition of cerebral protein synthesis or amnesia. Amphetamine, in doses that can antagonize the amnesic action of cycloheximide, does not antagonize the effect of cycloheximide on activity. Effects of cycloheximide on activity do not appear to be responsible for its amnesic action.