Externalization of an endogenous chicken muscle lectin with in vivo development

Chicken-lactose-lectin-I (CLL-I), an endogenous lectin that is developmentally regulated in embryonic muscle, was localized by immunohistochemical techniques in tissue samples taken at various stages of in vivo development and in primary muscle cultures. Lectin, which was diffusely distributed in myoblasts, became localized in myotubes in a distribution similar to that of the sarcoplasmic reticulum and T tubules. Later in development, lectin was predominantly extracellular. This sequence suggests that externalization may have occurred by migration in the T tubules, which are continuous with the extracellular space, although alternative explanations are possible. Only traces of lectin were found in the adult. These studies did not reveal the function of CLL-I in muscle development. However, we infer that it acts by organizing complementary glycoconjugates in the intracellular tubular network, on the muscle surface, and/or in extracellular materials.     

Quantitation of two endogenous lactose-inhibitable lectins in embryonic and adult chicken tissues

Two lactose-binding lectins from chicken tissues, chicken-lactose- lectin-1 (CLL-1) and chicken-lactose-lectin-11 (CLL-11) were quantified with a radioimmunoassay in extracts of a number of developing and adult chicken tissues. Both lectins could be measured in the same extract without separation, because they showed not significant immunological cross-reactivity. Many embryonic and adult tissues, including brain, heart, intestine, kidney, liver, lung, muscle, pancreas, and spleen, contained one or both lectins, although their concentrations differed markedly. For example, embryonic muscle, the richest source of CLL-1 contained only traces of CLL-11 whereas embryonic kidney, a very rich source of CLL-11 contained substantial CLL-1. In both muscle and kidney, lectin levels in adulthood were much lower than in the embryonic state. In contrast, CLL-1 in liver and CLL-11 in intestine were 10-fold to 30-fold more concentrated in the adult than in the 15-d embryo. CLL-1 and CLL-11 from several tissues were purified by affinity chromatography and their identity in the various tissues was confirmed by polyacrylamide gel electrophoresis, isoelectric focusing, and peptide mapping. The results suggest that these lectins might have different functions in the many developing and adult tissues in which they are found.     

Endogenous lectins in chickens and slime molds: Transfer from intracellular to extracellular sites

Endogenous lectins in both cellular slime molds and chicken tissues have been localized primarily intracellularly, in contrast with the predominantly extracellular localization of the glycoproteins, glycolipids, and glycosaminoglycans with which they might interact. Here we present evidence that lectins in both of these organisms may be externalized and become associated with the cell surface and/or extracellular materials. In chicken intestine, chicken-lactose-lectin-II is shown to be localized in the secretory granules of the goblet cells, along with mucin, and to be secreted onto the intestinal surface. In embryonic muscle, chicken-lactose-lectin-I is shown to be externalized with differentiation, ultimately becoming localized on the surface of myotubes and in the extracellular spaces. In a cellular slime mold, Dictyostelium purpureum, externalization of lectin is elicited by either polyvalent glycoproteins that bind the small amount of endogenous cell surface lectin, or by slime mold or plant lectins that bind unoccupied complementary cell surface oligosaccharides. These results suggest that externalization of endogenous lectin may be a response to specific external signals. We conclude that lectins are frequently held in intracellular reserves awaiting release for specific external functions.     

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.     

Localization of an endogenous lectin in chicken liver, intestine, and pancreas

Extracts of adult chicken liver, pancreas, and intestine contain high levels of a lectin which appears to be identical to one previously purified from embryonic chick muscle. This lectin is virtually absent from adult muscle, but is highly concentrated in cells lining liver sinusoids, intestinal goblet cells, and the extracellular spaces surrounding pancreatic acini. These findings suggest that the lectin may play different roles in different tissues and at different times in the life of a chicken.     

Expression of sialic acid on the alveolar surface of adult and fetal human lungs

Lung alveoli are coated by a thin layer of extracellular material rich in anionic charges. The nature of this acid layer and its relationship to the phospholipid surfactant are not known. We investigated the possible presence of sialic acid groups by light and electron microscopy in tissues from normal fetal and adult lungs, using neuraminidase treatment followed by staining with the galactose-binding lectin from peanut, labeled with peroxidase. Our results showed that adult lung does not bear peanut lectin-reactive sites but that a very thin and distinct reactive layer becomes evident after neuraminidase treatment, especially on type II pneumocytes. In fetal lung, the entire surface of the developing respiratory tree is outlined by a strongly peanut lectin-reactive layer even if neuraminidase digestion is not performed. We conclude that the acid coat of the alveolar lining is in part composed of sialic acid residues and that sialic acid is added to the fetal lung as the alveoli mature.     

Secretion of endogenous lectin by chicken intestinal goblet cells

The two lactose-binding lectins found in adult chicken intestine, chicken-lactose-lectin-1 (CLL-1) and chicken-lactose-lectin-11 (CLL- 11), were localized within the vesicles of the mucin-secreting goblet cells by indirect immunofluorescence and immunoperoxidase staining methods. Attention was concentrated on CLL-11 which is 200 time more abundant than CLL-1 in adult intestine. The localization of CLL-11 in secretory vesicles, combined with its demonstration on the intestinal epithelial surface by immune staining methods and by specific elution with lactose, suggested that at least a portion of the CLL-11 in the vesicles was secreted by the goblet cells and then became associated with the mucosal surface. In support of this, treatment of isolated intestinal strips with a cholinergic agent, bethanechol (10(-7 M) produced a small but significant increase in the amount of CLL-11 that could be eluted from their surface with lactose. Secretion of lectin may occur in conjunction with mucin because both are localized in the secretory vesicles and CLL-1 and CLL-11 apparently bind to purified chicken intestinal mucin, which is a potent inhibitor of their hemagglutination activities. The mucin is six orders of magnitude more potent than lactose as a hemagglutination inhibitor of CLL-1 or CLL-11 on a molar basis, and three orders of magnitude more potent when expressed per mole of hexose. These results suggest that CLL-11, and perhaps CLL-1, are secreted from the goblet cells along with mucin. They may function in the organization of mucin for secretion and/or in its association with the intestinal mucosal surface.     

Xenopus laevis L-14 lectin is expressed in a typical pattern in the adult, but is absent from embryonic tissues

Soluble, dimeric, lactose-binding lectins with subunit Mr ofñ 14–16 x 10³, here called L-14s, are expressedin multiple tissues in all vertebrates that have been examined.L-14s have particular affinity for polylactosamine chains onlaminin, co-localize with laminin in some basement membranes,and influence adhesion to laminin and proliferation for somecultured cells. In previous studies of mammals and chickens,L-14s have been found at high levels in a variety of adult tissues,such as muscle and peripheral nerve, but at much higher levelsin many embryonic tissues, suggesting a special role in development.To further explore possible roles of L-14 in embryogenesis,we have studied the expression of L-14 in embryonic and adultXenopus laevis tissues. Except for the abundant L-14 in poisonglands in adult Xenopus skin, we find that Xenopus L-14 is expressedin the same general distribution as its mammalian homologues.However, we could detect no expression of L-14 in Xenopus embryosusing either a sensitive immunoassay for the protein or a sensitiveRNase protection assay for its mRNA. Furthermore, use of affinitychromatography to identify other lactose-binding lectins inembryonic tissue revealed only scarce proteins with higher subunitmolecular weights. These results suggest that in X.laevis L-14functions in adult tissues and is not involved in embryogenesis. ß-galactoside-binding lectin L-14 lectin Xenopus laevis.     

Different immunoreactivities of anti-soluble lactose lectin antisera to tissues from early chick embryos: a histochemical study

The location of soluble lactose-binding proteins (S-lac lectins) has been studied by immunohistochemical methods during morphogenesis of the chick embryo, when segregation and early differentiation of organ primordia was occurring. Using a panel of polyclonal antisera raised to various purified lectin preparations, we observed striking differences in the antigenic properties of these antisera, indicating that diverse versions of the lectins may be expressed during development. The antisera referred to as anti-L-16, anti-M-16, anti-S-14 and anti-I-14 were respectively raised to native or denatured 16 kDa lectins from adult liver and embryonic muscle and to 14 kDa lectins from embryonic skin and adult intestine. Having determined the optimal immunohistochemical conditions in the preparation of embryo sections (fixation, embedding, sectioning) we show that anti-L-16, anti-S-14 and anti-I-14 mostly bind the lectins expressed at the cell surface, in the extracellular matrix and in some released secretion. As previously shown, anti-L-16 and anti-S-14 are also able to recognize the cytoplasmic form of some migrative lectin-rich cells (primitive streak, neural crest cells, germ cells). Anti-M-16 was bound exclusively to the cytoplasmic form of the 16 kDa lectin in the same cell lines as above and also in some others, such as in the notochord, the myotomal part of the somites, the pharyngeal endoderm and the cardiac muscle. These different antigenic properties may be applied to the accurate mapping of various lectin isoforms and evaluation of the respective contribution of their intra-and extracellular variants during development and differentiation.     

Prototype chicken galectins revisited: characterization of a third protein with distinctive hydrodynamic behaviour and expression pattern in organs of adult animals

Prototype galectins are versatile modulators of cell adhesion and growth via their reactivity to certain carbohydrate and protein ligands. These functions and the galectins' marked developmental regulation explain their attractiveness as models to dissect divergent evolution after gene duplication. Only two members have so far been assumed to constitute this group in chicken, namely the embryonic muscle/liver form {C-16 or CLL-I [16 kDa; chicken lactose lectin, later named CG-16 (chicken galectin-16)]} and the embryonic skin/intestine form (CLL-II or C-14; later named CG-14). In the present study, we report on the cloning and expression of a third prototype CG. It has deceptively similar electrophoretic mobility compared with recombinant C-14, the protein first isolated from embryonic skin, and turned out to be identical with the intestinal protein. Hydrodynamic properties unusual for a homodimeric galectin and characteristic traits in the proximal promoter region set it apart from the two already known CGs. Their structural vicinity to galectin-1 prompts their classification as CG-1A (CG-16)/CG-1B (CG-14), whereas sequence similarity to mammalian galectin-2 gives reason to refer to the intestinal protein as CG-2. The expression profiling by immunohistochemistry with specific antibodies discerned non-overlapping expression patterns for the three CGs in several organs of adult animals. Overall, the results reveal a network of three prototype galectins in chicken.     

Sequence and specificity of a soluble lactose-binding lectin from Xenopus laevis skin.

A 16-kDa lactose-binding lectin comprises 5% or more of the soluble protein in Xenopus laevis skin. This lectin is mainly localized in the cytoplasm of granular gland cells. In response to stress, the lectin along with a variety of toxic and antibiotic peptides are released onto the skin surface by holocrine secretion. We have purified the lectin, sequenced tryptic peptides using tandem mass spectrometry and Edman degradation, and isolated full-length cDNA using a deduced oligonucleotide. Comparison of the cDNA and peptide sequences revealed expression of at least two isolectins, which differ in sequence at only two or three amino acids. Comparison of cDNA with complementary message by ribonuclease protection confirmed expression in approximately equal abundance of two nearly identical messages. The major soluble lactose-binding lectin expressed in Xenopus muscle is composed of these same isolectins, but at 100-fold lower levels. Similarities and distinctions in sequence and carbohydrate-binding specificity indicate that this lectin is a novel member of a family of soluble lactose-binding lectins expressed in a wide range of vertebrate tissues.     

Soluble lactose-binding vertebrate lectins: a growing family

Extracts of rat intestine contain nine soluble lactose-binding lectins with subunit molecular weights ranging from 14,500 to 19,000 that were purified by affinity chromatography and ion-exchange chromatography. Two of them are either identical with or closely related to other known rat lectins. A third appears to be the isolated carbohydrate-binding C-terminal domain of a known lectin but lacks the N-terminal domain presumed to mediate a different function. The others have not been described previously. Among them, the major rat intestinal lectin, RI-H, and a related protein, RI-G, have N-terminal amino acid sequences with similarities to sequences found in other known rat lectins. Therefore, these results introduce new members of a growing family of these structurally homologous soluble lactose-binding proteins.     

鸡胚凝集因子在发育过程中的活性变化

人们认为,细胞表面含碳水化合物的蛋白质可能在细胞相互作用中起着重要作用。从脊椎动物中分离出凝集因子以后(Teichberg et al., 1975;Nowak et al., 1977),许多研究表明这类凝集因子是与膜相结合的。这些发现支持了人们原先的设想。Beyer等人(1979;1980)从成体鸡肠中分离出一种结合乳糖的凝集因子,这种凝集因子似乎存在于粘液分泌小粒之中。1980年Pitts和Yang又从鸡胚肾脏中分离出一种结合乳糖的凝集因子,它可能是一种外周蛋白质。尽管他们的实验证明了成体鸡肾和肠这两种器官,同视网膜、肝脏、肌肉、心脏、脑和脊髓一样,存在着结合乳糖的凝集因子。但凝集因子在这两     

Effects of retinoic acid on the distribution of glycoconjugates during mouse tail bud development

Retinoic acid (RA), a potent teratogen of caudal axial development in rodents, has been shown to alter glycoconjugates in a variety of embryonic tissues and teratocarcinomas. In this study, we examined its effects on the expression of cell surface and extracellular matrix glycoconjugates during tail bud development in mouse embryos by using lectin histochemistry. The lectins WGA, sWGA, and PNA showed striking differences in binding between RA-exposed and control embryos. Computer-assisted densitometry revealed a significant increase in binding of all three lectins to the extracellular material of the luminal and abluminal borders of the secondary neural tube and surrounding the notochord in RA-exposed embryos. RA-treated embryos also showed an increased binding affinity for the lectins sWGA and PNA to the cells of the notochord, while WGA showed increased binding to the neuroepithelial cells of the secondary neural tube. The results suggest that RA affects the expression of lectin binding sites during the early development of RA-induced caudal axial defects.     

Identification of a chicken CLEC-2 homologue, an activating C-type lectin expressed by thrombocytes

Receptors on natural killer (NK) cells are classified as C-type lectins or as Ig-like molecules, and many of them are encoded by two genomic clusters designated natural killer gene complex (NKC) and leukocyte receptor complex, respectively. Here, we describe the analysis of an NKC-encoded chicken C-type lectin, previously annotated as homologue to CD94 and NKG2 and thus designated chicken CD94/NKG2. To further elucidate its potential function on NK cells, we produced a specific mab by immunizing with stably transfected HEK293 cells expressing this lectin. Staining of various chicken tissues revealed minimal reactivity with bursal, or thymus cells. In peripheral blood mononuclear cell and spleen, however, the mab reacted with virtually all thrombocytes, whereas most NK cells in organs such as embryonic spleen, lung and intestine were found to be negative. These findings indicate that the gene may not resemble CD94/NKG2, but rather a CLEC-2 homologue, a claim further supported by sequence features such as an additional extracellular cysteine residue and the presence of a cytoplasmic motif known as a hem immunoreceptor tyrosine-based activation motif, found in C-type lectins such as Dectin-1, CLEC-2, but not CD94/NKG2. The biochemical analyses demonstrated that CLEC-2 is present on the cell surface as heavily glycosylated homodimer, which upon mab crosslinking induced thrombocyte activation, as measured by CD107 expression. These analyses reveal that the chicken NKC may not encode NK cell receptor genes, in particular not CD94 or NKG2 genes, and identifies a chicken CLEC-2 homologue.     

Distribution of basic fibroblast growth factor binding sites in various tissue membrane preparations from adult guinea pig

In order to localize a rich source of basic FGF receptor, we examined the distribution of basic FGF binding sites in brain, stomach, lung, spleen, kidney, liver and intestine membrane preparations from adult guinea pig. Comparative binding studies using iodinated basic FGF showed that a specific binding was detected in all the membrane preparations tested. Scatchard plots from iodinated basic FGF competition experiment with native basic FGF in various membrane preparations, suggested the presence of one class of binding sites in some tissues such as liver, kidney, spleen, lung, stomach, and intestine with an apparent dissociation constant (appKD) value ranging from 4 to 7.5 nM and the existence of a second class of higher affinity sites in brain membranes with appKD value of 15 pM. Characterization of these basic FGF high affinity interaction sites was performed using a cross-linking reagent. These results show for the first time that specific interaction sites for basic FGF are widely distributed, suggesting that this growth factor might play a role in the physiological functions of a number of adult organs.     

Binding of wheat germ agglutinin to extracellular network produced by cultured human fibroblasts

The occurrence of diverse carbohydrate moieties on the cell surface and in the extracellular matrix, makes lectins the suitable probes to study the distribution of appropriate determinants produced in cell culture. Biotin-labelled wheat germ agglutinin (WGA) was used in microscopic and photometric detection of lectin binding to monolayer of human skin fibroblasts. The incubation of confluent fibroblast monolayer with labelled WGA reveals two principal patterns of binding of this lectin: to cell surface structures and, predominantly, to extracellular fibres; the alignment and density of extracellular network are not uniform. After binding of WGA to confluent culture, light microscopic analysis revealed the ubiquitous fibrillar network between and over cells, with some regions of increased compactness and altered orientation of fibrils. Binding to cell surfaces (manifested as specks) was predominant for the fibroblasts at the logarithmic phase of growth. N-acetylglucosamine (0.2 M) and native lectin (100 microg/ml) had a partial inhibitory effect on WGA binding to the extracellular network. Treatment with neuraminidase (0.1 unit/ml) of untreated or prefixed monolayers resulted in a significant decrease in WGA binding to fibrils (and increase in PNA binding), indicating that terminal sialic acid residues are mainly involved in the network-WGA interaction. Mild trypsinization (10 microg/ml) removed the target sites, which retained the ability to bind WGA, being spotted on hydrophobic Immobilon P paper; biotinylated lectin, bound to adsorbed glycopeptides, could be eluted and quantified in solid-phase inhibition assay.     

Evidence for export of a muscle lectin from cytosol to extracellular matrix and for a novel secretory mechanism

A soluble lactose-binding lectin with subunit Mr of 14,500 is believed to function by interacting with extracellular glycoconjugates, because it has been detected extracellularly by immunohistochemistry. This localization has been questioned, however, since the lectin lacks a secretion signal sequence, which challenges the contention that it is secreted. We have demonstrated externalization of this lectin from C2 mouse muscle cells by both immunoprecipitation of metabolically labeled protein and immunohistochemical localization. We further show that externalization of the lectin is a developmentally regulated process that accompanies myoblast differentiation and that the lectin codistributes with laminin in myotube extracellular matrix. Immunohistochemical localization during intermediate stages of externalization suggests that the lectin becomes concentrated in evaginations of plasma membrane, which pinch off to form labile lectin-rich extracellular vesicles. This suggests a possible mechanism for lectin export from the cytosol to the extracellular matrix.     

The enteric parasite Entamoeba uses an autocrine catecholamine system during differentiation into the infectious cyst stage.

Enteric amoebae of the genus Entamoeba travel from host to host in an encysted form. We previously showed that in vitro cyst development of Entamoeba invadens requires the addition of defined amounts of multivalent galactose-terminated molecules, such as mucin, to the cultures. The amoeba surface lectin that binds mucin is presumed to convey transmembrane signals when clustered by the ligand, but the signaling molecules that function downstream of the lectin are not known. We report here that Entamoeba encystation was induced in the absence of galactose ligand when catecholamines were added to the encystation medium. Micromolar amounts of both epinephrine and norepinephrine induced encystation. Of a variety of synthetic catecholamine agonists tested, only beta(1)-adrenergic receptor agonists supported encystation, whereas alpha- and beta(2)-adrenergic receptor agonists did not. Only beta(1)-adrenergic receptor antagonists inhibited encystation, and did so even when exogenous catecholamines were not added, indicating that catecholamine binding is required for encystation and suggesting an endogenous source of the ligand. High performance liquid chromatography analysis of Entamoeba extracts showed that the amoebae themselves contain catecholamines and at least one of these is released when the cells are stimulated to encyst with galactose-terminated ligands. The presence of catecholamine binding sites on the surface of amoeba trophozoites was confirmed using radiolabeled catecholamine antagonist. Amoeba encystment was inhibited by addition of beta(1)-adrenergic receptor antagonist to cells that were stimulated to differentiate with either galactose ligand or catecholamines, but not with dibutyryl cAMP. This suggests that the amoeba catecholamine receptor functions downstream of the galactose lectin and upstream of adenylyl cyclase. This enteric protozoan parasite, therefore, contains the components of an autocrine catecholamine ligand-receptor system that may act in conjunction with a galactose lectin to regulate differentiation into the infectious cyst stage.     

The proteoglycans aggrecan and Versican form networks with fibulin-2 through their lectin domain binding

Aggrecan, versican, neurocan, and brevican are important components of the extracellular matrix in various tissues. Their amino-terminal globular domains bind to hyaluronan, but the function of their carboxyl-terminal globular domains has long remained elusive. A picture is now emerging where the C-type lectin motif of this domain mediates binding to other extracellular matrix proteins. We here demonstrate that aggrecan, versican, and brevican lectin domains bind fibulin-2, whereas neurocan does not. As expected for a C-type lectin, the interactions are calcium-dependent, with K(D) values in the nanomolar range as measured by surface plasmon resonance. Solid phase competition assays with previously identified ligands demonstrated that fibulin-2 and tenascin-R bind the same site on the proteoglycan lectin domains. Fibulin-1 has affinity for the common site on versican but may bind to a different site on the aggrecan lectin domain. By using deletion mutants, the interaction sites for aggrecan and versican lectin domains were mapped to epidermal growth factor-like repeats in domain II of fibulin-2. Affinity chromatography and solid phase assays confirmed that also native full-length aggrecan and versican bind the lectin domain ligands. Electron microscopy confirmed the mapping and demonstrated that hyaluronan-aggrecan complexes can be cross-linked by the fibulins.