Ion dependence of the discoidin I lectin from Dictyostelium discoideum

The lectin discoidin I from Dictyostelium discoideum requires divalent cations for binding activity. The data indicate that calcium is the preferred ion in vitro. In contrast, the lectin activity of discoidin II is independent of divalent ions.     

Assay and characterization of carbohydrate binding by the lectin discoidin I immobilized on nitrocellulose

Discoidin I is the most abundant galactose binding lectin produced by the cellular slime mold Dictyostelium discoideum and has been implicated in cell-substratum adhesion. We have developed an assay of carbohydrate binding activity utilizing binding of 125I-asialofetuin to discoidin I, or to other lectins, immobilized on nitrocellulose. Among the proteins examined, only lectins exhibited the ability to bind asialofetuin. Specificity of asialofetuin binding was demonstrated by competition with monosaccharides, which inhibited binding consistent with the known sugar specificity of the lectins examined. Experiments with fetuin and derivatives differing in their oligosaccharide structure indicated a requirement for terminal galactosyl residues for probe binding to discoidin I. We have used this assay to characterize the carbohydrate binding behavior of discoidin I. The extent of asialofetuin binding to discoidin I was dependent on the concentrations of both lectin and ligand. Interpretation of equilibrium binding data suggested that, under saturating conditions, 1 mol of oligosaccharide was bound per mole discoidin I monomer. Furthermore, discoidin I in solution and discoidin I on nitrocellulose were equally effective at competing for soluble asialofetuin, suggesting that immobilization had no effect on the carbohydrate binding behavior of discoidin I. Binding was strongly inhibited by ethylenediaminetetraacetic acid; both Ca2+ and Mn2+ could overcome that inhibition, but Mg2+ could not. Preincubation of discoidin I at 60 degrees C stimulated asialofetuin binding 2-fold by increasing the affinity, while preincubation at higher temperatures resulted in a complete loss of activity.(ABSTRACT TRUNCATED AT 250 WORDS)     

Multiple regulatory genes control expression of a gene family during development of Dictyostelium discoideum.

Mutant strains of Dictyostelium discoideum carrying dis mutations fail to transcribe specifically the family of developmentally regulated discoidin lectin genes during morphogenesis. The phenotypes of these mutants strongly suggested that the mutations reside in regulatory genes. Using these mutant strains, we showed that multiple regulatory genes are required for the expression of the lectin structural genes and that these regulatory genes (the dis+ alleles) act in trans to regulate this gene family. These regulatory genes fall into two complementation groups (disA and disB) and map to linkage groups II and III, respectively. A further regulatory locus was defined by the identification of an unlinked supressor gene, drsA (discoidin restoring), which is epistatic to disB, but not disA, and results in the restoration of lectin expression in cells carrying the disB mutation. Mutant cells carrying the drsA allele express the discoidin lectin gene family during growth and development, in contrast to wild-type cells which express it only during development. Therefore, the suppressor activity of the drsA allele appears to function by making the expression of the discoidin lectins constitutive and no longer strictly developmentally regulated. The data indicate that normal expression of the discoidin lectins is dependent on the sequential action of the disB+, drsA+, and disA+ gene products. Thus, we described an interacting network of regulatory genes which in turn controls the developmental expression of a family of genes during the morphogenesis of D. discoideum.     

Differential scanning calorimetric studies of aqueous dispersions of phosphatidylcholines containing two polyenoic chains

The structure of the lectin discoidin I has been studied by circular dichroism and fluorescence spectroscopy. A positive ellipticity band at 224 nm is detected in the CD spectrum of discoidin I. The fluorescence spectra show a defined shoulder at 325 nm that through acrylamide quenching has been associated with a displaced tryptophan residue partly buried in the discoidin I molecule. This tryptophan could also be responsible for the 224 nm positive band of the CD spectrum. These spectroscopic characteristics of discoidin I indicate the existence of structural homologies with fibronectin, where the optical activity of aromatic chromophores has been associated with the positive ellipticity band at 227 nm. The CD adjust parameters and theoretical secondary structure predictions show that discoidin I is a molecule with a low content of alpha-helix and beta-strand and high content of beta-turn structures, similar to other lectins.     

Spectroscopic studies on the structural organization of the lectin discoidin I: homologies with fibronectin

The structure of the lectin discoidin I has been studied by circular dichroism and fluorescence spectroscopy. A positive ellipticity band at 224 nm is detected in the CD spectrum of discoidin I. The fluorescence spectra show a defined shoulder at 325 nm that through acrylamide quenching has been associated with a displaced tryptophan residue partly buried in the discoidin I molecule. This tryptophan could also be responsible for the 224 nm positive band of the CD spectrum. These spectroscopic characteristics of discoidin I indicate the existence of structural homologies with fibronectin, where the optical activity of aromatic chromophores has been associated with the positive ellipticity band at 227 nm. The CD adjust parameters and theoretical secondary structure predictions show that discoidin I is a molecule with a low content of α-helix and β-strand and high content of β-turn structures, similar to other lectins.     

Localization of soluble endogenous lectins and their ligands at specific extracellular sites

Soluble lectins of chicken, rat, frog, and the cellular slime mold, Dictyostelium discoideum, were purified and specific antibodies raised against these proteins were used to immunohistochemically localize the lectins in and around the tissues in which they were synthesized. Within cells, some of these soluble lectins (chicken-lactose-lectin-II in intestinal goblet cells, discoidin II in prespore cells) appear to be concentrated within vesicles whereas others (e.g., rat beta-galactoside lectin in pulmonary alveolar and smooth muscle cells) appear to be free in the cytoplasm. All of these lectins are eventually secreted to extracellular sites in developing or adult tissues. The sites include mucin (chicken-lactose-lectin-II in intestine); developing extracellular matrix (chicken-lactose-lectin-I in muscle; Xenopus laevis lectin in blastula stage embryos); slime (discoidin I); developing spore coat (discoidin II); and a specialized extracellular matrix, elastic fibers (rat beta-galactoside lectin in lung). In cases where this has been studied in detail (discoidin I, discoidin II, and chicken-lactose-lectin-II), the lectin is associated with a complementary extracellular ligand, at least transiently. Lectin-ligand interactions presumably confer specialized properties in these particular extracellular domains.     

Developmental changes in the structural organization of the lectin discoidin I detected by limited proteolysis

Digestion of discoidin I with several proteolytic enzymes reveals the existence of structural domains in this lectin. Significative differences have been detected in the pattern of fragments generated by V8 protease on discoidin I of various developmental situations. The changes observed can be related to the presence of various types of tetrameric structures in discoidin I. Together with the presence of different types of isoforms in vegetative vs. differentiated cells, the results presented here suggest the involvement of different structural organizations in discoidin I which can be related to the biological functions of this lectin.     

Bacterial glycoconjugates are natural ligands for the carbohydrate binding site of discoidin I and influence its cellular compartmentalization

Klebsiella pneumoniae, Escherichia coli, and Bacillus subtilis, bacteria commonly eaten by Dictyostelium discoideum, contain glycoconjugates that bind discoidin I, a lectin synthesized by the slime mold as it differentiates. In cells fed bacteria that contain abundant discoidin I-binding glycoconjugates, these ligands and endogenous discoidin I accumulated in specialized structures called multilamellar bodies. In contrast, in cells fed bacteria that had been treated to thoroughly deplete them of discoidin I-binding glycoconjugates, neither endogenous discoidin I nor complementary glycoconjugates were found in the multilamellar bodies. In such cells discoidin I was located in the cytoplasm, as indicated by both immunohistochemistry with the electron microscope and immunoassay of subcellular fractions. The results indicate that a function of the carbohydrate-binding site of discoidin I is to interact with bacterial glycoconjugates, which the slime mold does not degrade. This interaction directs compartmentalization of the lectin in multilamellar bodies and its externalization from the cell in these structures.     

Common Cell-Surface Receptors for Discoidin I and Discoidin II in Dictyostelium discoideum

Following nutrient depletion, cells of the cellular slime mould Dictyostelium discoideum become cohesive and aggregate to form multicellular complexes. Several proteins that accumulate on the cell surface during this period have been implicated in mediating aggregative-phase cell cohesion, namely contact sites A (CsA), gp 150, and two endogenous lectins (discoidin I and discoidin II). The aggregating cells also possess receptors for both discoidin I and discoidin II but these have not yet been isolated and characterised for both lectins.
In the present study we investigated the relationship between the receptors for these lectins, in particular to what extent discoidin I and discoidin II receptors are common. Radio-iodinated discoidin I and discoidin II were purified and used in binding assays for lectin receptors on the surface of aggregated (10 h stage of development) D. discoideum NC4 cells. Sugar competition of ¹²⁵I-labelled discoidin I and ¹²⁵I-labelled discoidin II binding indicated distinct but overlapping sugar specificities for these lectins when binding to their in vivo receptors. Competition of the binding of radio-iodinated lectin with either unlabelled discoidin I or unlabelled discoidin II showed that at least 50% of the cell-surface binding sites for these lectins are in common and for these receptors the binding affinity of discoidin I is 9–20 times higher than for discoidin II. Approximately 35% of discoidin II binding sites appear to be unavailable for discoidin I binding.     

Mutants of Dictyostelium discoideum blocked in expression of all members of the developmentally regulated discoidin multigene family

Mutant strains of D. discoideum are described that can complete morphogenesis and cytodifferentiation but which express vastly reduced levels of the galactose-binding lectins discoidin I and II (less than 1% and 1%-2% respectively) compared to the wild-type control. Mutant cells proceeding through development lack lectin activity, lectin protein, and specific lectin mRNA. In contrast, the genes encoding these proteins are present in their wild-type configurations in the genome. Since these proteins are encoded by four to five discrete genes, the mutations in these strains are most likely in genes involved in the regulation of the expression of members of this multigene family. The results also indicate that the discoidin lectins may not be required for fruiting body construction in this organism. Finally, coupled with the recent ability to transform D. discoideum, these mutants open the way to identification and isolation of regulatory genes and their products.     

Cell-surface discoidin in aggregating cells of Dictyostelium discoideum.

Both discoidin I and discoidin II have been detected on the surface of aggregating (10 h developmental stage) cells of Dictyostelium discoideum NC4 by radioiodination of the cell-surface followed by immunoprecipitation and sodium dodecyl sulphate/polyacrylamide-gel-electrophoretic analysis. Approx. 92% of cell-surface discoidin I and 72% of cell-surface discoidin II can be eluted with 0.5 M-galactose, showing that most of each endogenous lectin is not present as integral membrane protein but rather is bound to cell-surface discoidin receptors. Two-dimensional polyacrylamide-gel-electrophoretic analysis of discoidin I suggests that the native tetramer may be a hetero-multimer composed of both Ia and Ib subunits. Cell-surface discoidin I also contains both types of subunit, but it is not clear whether both subunits have corresponding cell-surface receptors.     

Affinity labeling of the carbohydrate binding site of the lectin discoidin I using a photoactivatable radioiodinated monosaccharide

N-(4-Azidosalicyl)galactosamine (GalNASA), a photoactivatable, radioiodinatable analogue of N-acetylgalactosamine (GalNAc), has been prepared and characterized. We have used this reagent for labeling of the carbohydrate binding site of discoidin I, an endogenous lectin produced by Dictyostelium discoideum. GalNASA behaved as a ligand for discoidin I, as judged by its ability to compete in an assay measuring the carbohydrate binding activity of discoidin I. In this assay, it exhibited a Ki,app of 800 microM, comparable to that of GalNAc. The Ki,app of GalNASA decreased to 40 microM upon prior photolysis with ultraviolet light. In contrast, N-(4-azidosalicyl)ethanolamine produced no inhibition of carbohydrate binding regardless of photolysis. Covalent labeling of discoidin I with 125I-GalNASA was entirely dependent upon ultraviolet light. A portion of the labeling, representing 40-60% of the total, was sensitive to reagents which were known to inhibit carbohydrate binding by discoidin I, including GalNAc, asialofetuin, and ethylenediaminetetraacetic acid. N-Acetylglucosamine, which is not a ligand of discoidin I, was without effect. As a control, no carbohydrate-sensitive labeling was observed upon incubation of 125I-GalNASA with bovine serum albumin. The carbohydrate-sensitive fraction of discoidin I photolabeling with 125I-GalNASA exhibited a Kd of 15-40 microM, in agreement with the Ki,app of prephotolyzed GalNASA observed in the carbohydrate binding assay. Some labeling occurred if 125I-GalNASA was photolyzed prior to incubation with discoidin I, suggesting the involvement of long-lived species in the labeling reaction. Partial proteolytic digestion of photolabeled discoidin I revealed specific fragments whose labeling was completely blocked by GalNAc.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

Discoidin I, an endogenous lectin, is externalized from Dictyostelium discoideum in multilamellar bodies

Discoidin I, a soluble lectin synthesized by aggregating Dictyostelium discoideum and implicated in their adhesion to the substratum, is localized in multilamellar bodies both intracellularly and upon externalization. These structures also contain a glycoconjugate that binds discoidin I. The multilamellar bodies apparently serve to package the lectin for externalization, and may then gradually release it to function extracellularly.     

Colocalization of discoidin-binding ligands with discoidin in developing Dictyostelium discoideum

The Dictyostelium discoideum lectins, discoidin I and discoidin II, and the endogenous ligands to which they bind were immunohistochemically localized in sections of this organism at successive stages of development. For these studies, an axenic strain, AX3, was grown in a macromolecule-depleted medium rather than on bacteria, which themselves contain discoidin-binding ligands. Discoidin I-binding sites (endogenous ligands) in sections of D. discoideum were concentrated in the slime coat around aggregates, whereas discoidin II-binding sites were observed in a vesicle-like distribution in prespore cells and also in spore coats. In contrast, discoidin II did not bind to the slime coat and discoidin I bound relatively poorly to prespore cells and spore coats. The distributions of the endogenous lectins themselves were the same in axenically grown cells as previously reported for cells raised on bacteria. Discoidin I was concentrated in the slime coat and around stalk cells, and discoidin II was prominent in and around prespore cells. The congruent localization of each lectin with its endogenous ligand suggests that discoidin I normally functions in association with glycoconjugates in the slime around aggregates, and discoidin II with the galactose-rich spore coat polysaccharide.     

Density-dependent induction of discoidin-I synthesis in exponentially growing cells of Dictyostelium discoideum

The synthesis of the lectin, discoidin I, by vegetative cells of Dictyostelium discoideum (strain NC4) was monitored using immunoblot analysis and indirect immunofluorescence. Suspension cultures were used, so that the D. discoideum cell density and the concentration of bacteria could be controlled. Discoidin-I production was found to be a function of the relative densities of D. discoideum cells and food bacteria. Synthesis was initiated in exponentially growing D. discoideum cells approximately three generations before depletion of the food supply. In the growth medium of cells producing discoidin I, a soluble activity was detected that caused low-density cells to begin discoidin-I synthesis. This activity was not dialyzable and was destroyed by heat. A similar activity was produced by AX3 cells during axenic growth. Density-dependent induction of other 'early developmental' proteins was also detected in wild-type cells. These findings suggest that the expression of several 'early developmental' genes is regulated by a mechanism that measures cell density relative to food supply, not by starvation per se.     

Lectins from seeds of Crotalaria pallida (smooth rattlebox)

A lectin from the seeds of Crotalaria pallida (CPL), with an apparent molecular mass of 30 kDa, determined by SDS-polyacrylamide gel electrophoresis, showed human type A and B erythrocytes agglutination activity, which is inhibited by raffinose and galactose. The lectin requirement for divalent cation was demonstrated with EDTA/EGTA blocking hemagglutination activity. Although the N-terminal amino acid sequence of CPL is identical to another lectin from Crotalaria striata, which is taxonomically synonymous to Crotalaria pallida, these lectins differ in amino acid composition and hemagglutination properties.