Douglas N.W. Cooper

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.

Expression of the 67-kD laminin receptor, galectin-1, and galectin-3 in advanced human uterine adenocarcinoma

Alterations of tumor cell interactions with laminin, a basement membrane glycoprotein, are consistent features of the invasive and metastatic phenotype. Qualitative and quantitative changes in the expression of cell surface laminin-binding proteins have been correlated with the ability of cancer cells to cross basement membranes during the metastatic cascade. Such phenotypic modifications are usually associated with poor prognosis. In this study, the authors examined the possibility that expression of three laminin-binding proteins, the 67-kD laminin receptor (67LR), galectin-1, and galectin-3, is altered in human endometrial cancer in a fashion similar to that reported in other carcinomas, such as breast, colon, and ovarian cancer. Twenty advanced uterine adenocarcinomas were analyzed for expression of these three molecules using immunoperoxidase staining and specific antibodies. The authors found a significant increase in the expression of the 67LR and galectin-1 in cancer cells compared with normal adjacent endometrium (P = .0004 and .0022, respectively). As observed in other carcinomas, a significant down-regulation of galectin-3 expression was found in endometrial cancer cells compared with normal mucosa (P = .02). In the galectin-3 positive tumors, galectin-3 was detected in the cytoplasm and/or nucleus of cancer cells. Interestingly, tumors in which galectin-3 was detected only in the cytoplasm were characterized by deeper invasion of the myometrium than lesions where galectin-3 was found both in nucleus and cytoplasm (P = .02). This study shows an alteration of nonintegrin laminin-binding protein expression in advanced human endometrial cancer. Further studies on larger populations should determine the prognostic value of the detection of these laminin-binding proteins in endometrial carcinoma. Inverse modulation of the 67LR and galectin-3 appears to be a phenotypical feature of invasive carcinoma.

Fungal galectins, sequence and specificity of two isolectins from Coprinus cinereus

Galectins are members of a genetically related family of β-galactoside-binding lectins. At least eight distinct mammalian galectins have been identified. More distantly related, but still conserving amino acid residues critical for carbohydrate-binding, are galectins in chicken, eel, frog, nematode, and sponge. Here we report that galectins are also expressed in a species of fungus, the inky cap mushroom, Coprinus cinereus. Two dimeric galectins are expressed during fruiting body formation which are 83% identical to each other in amino acid sequence and conserve all key residues shared by members of the galectin family. Unlike most galectins, these have no N-terminal post-translational modification and no cysteine residues. We expressed one of these as a recombinant protein and studied its carbohydrate-binding specificity using a novel nonradioactive assay. Binding specificity has been well studied for a number of other galectins, and like many of these, the recombinant C. cinereus galectin shows particular affinity for blood group A structures. These results demonstrate not only that the galectin gene family is evolutionarily much older than previously realized but also that fine specificity for complex saccharide structures has been conserved. Such conservation implies that galectins evolved to perform very basic cellular functions, presumably by interaction with glycoconjugates bearing complex lactoside carbohydrates resembling blood group A.

Multiple soluble vertebrate galactoside-binding lectins

All vertebrates synthesize soluble galactoside-binding lectins. Many are expressed at high levels in the embryo and at lower levels in the adult, whereas others show an inverse pattern of expression. Most lectins tend to be concentrated in one or a number of specific cell types. In the past few years, the multiplicity of these lectins has become more apparent. For example, in Xenopus laevis 3 galactoside-binding lectins, 2 with a preference for alpha-galactosides, have been purified and partially characterized. They have subunit molecular weights ranging from 16,000 to 69,000. More detailed studies have been done in mammals. For example, rat lung contains 3 soluble beta-galactoside-binding lectins, RL-14.5, RL-18 and RL-29, with subunit molecular weights, respectively, of 14,500, 18,000 and 29,000. A notable feature of these lectins is that, although they all bind lactose about equally well, their carbohydrate-binding sites are actually quite different, as shown by competitive binding studies with a range of complex mammalian glycoconjugates. Human lung also contains several beta-galactoside-binding lectins, including HL-14, HL-22 and HL-29 with subunit molecular weights, respectively, of 14,000, 22,000 and 29,000. They too show significant differences in their carbohydrate-binding sites when analyzed with naturally occurring mammalian glycoconjugates. Sequencing of purified lectins and cDNA clones indicates that at least 4 distinct genes code for what appears to be a family of HL-14. Heterogeneity is also indicated from isoelectric focusing studies which resolve at least 6 acidic forms of HL-14 and 5 acidic forms of HL-29.(ABSTRACT TRUNCATED AT 250 WORDS)

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

Abstract 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.

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.

Chapter 21 Discoidins I and II: Endogenous Lectins Involved in Cell—Substratum Adhesion and Spore Coat Formation

Publisher Summary This chapter discusses the basic biochemical and biological techniques in identifying the functions of discoidins I and II. Like soluble lectins from vertebrates, they are apparently designed to play extracellular roles—discoidin I in cell–substratum adhesion and discoidin II in spore coat formation. A number of lines of evidence point to a role for discoidin I in a specific form of cell–substratum adhesion. Antibodies against the lectin and against a 67-kDa glycoprotein with properties of a discoidin I receptor both block ordered cell migration into aggregates. A mutant deficient in discoidin I does not aggregate normally. Nor does an antisense transformant in which there is a >90% reduction in discoidin I. One interesting conclusion from studies of the cellular role of discoidin 1 is that this lectin shares several properties with fibronectin, a vertebrate molecule implicated in the adhesion of fibroblasts to substrata. Like Fibronectin, discoidin I contains the sequence Arg-Gly-Asp-x, which has been implicated in the cell-binding properties of both molecules. Both molecules also have carbohydrate-binding sites. Firbronectins binding sites for glycosaminoglycans may participate in anchoring it to the substratum. A role for discoidin II in spore coat formation is indicated by (1) its localization in vesicles which also contain a polysaccharide to bind well to this lectin, and (2) the secretion of lectin and the polysaccharide into the spore coat.

Gene design, expression, crystallization and preliminary diffraction analysis of two isolectins from the fungus Coprinus cinereus: a model for studying functional diversification of galectins in the same organism and their evolutionary pathways

It is the aim of comparative structural biology to define the evolutionarily important traits of protein function and the points of diversification. Consequently, structural analysis, especially of distant members in a family which in this case are lectins involved in cell adhesion and growth regulation in animals (i.e. galectins), is required. For this purpose, recent work has been focused on the first galectins known from outside the animal kingdom. These are the two isolectins from the basidiomycete Coprinus cinereus (inky cap mushroom), termed Cgl-1 and Cgl-2. Additionally, the close similarity (83% deduced amino-acid identity) but the pronounced difference in the expression patterns of these two fungal lectins during fruiting-body formation affords a suitable object for study of the relation of structural difference to the observed functional disparity in the same organism. Both galectins were crystallized after recombinant production. Crystals belong to either the orthorhombic space group C222(1) (Cgl-1) or the monoclinic space group P2(1) (Cgl-2). The latter crystals diffracted to 1.6 A resolution using synchrotron radiation. To solve the phasing problem, a selenomethionine-containing variant of Cgl-1 was designed. Crystals isomorphous to those of the native counterpart were obtained. Their structural analysis will also be crucial to solving the structure of Cgl-2.