The endogenous lectins of the chick blastoderm are present in association with an apolipoprotein in distinct organelles and in the extracellular matrix

Summary Affinity purified preparations of the galactose-binding lectin from gastrulating chick blastoderms consist of three main polypeptides. Two of these have been identified as the 14 kD and 16 kD galactose-binding lectins. A third one migrates in SDS-PAGE gels with a relative molecular weight of 6,500±500 and has been identified as an apolipoprotein (Apo) of plasma very low density lipoproteins, Apo-VLDL-II. We have studied the localization of these polypeptides using immunofluorescence and ultrastructural immunocytochemistry with peroxidase and protein-A gold. The 14 kD lectin occurs in the intracellular yolk where it is mainly present within the electron lucent component. The 16 kD is also present in the intracellular yolk platelets, but tends to predominate in the electron-dense component. In addition, the 16 kD lectin is also present in pleiomorphic yolk-associated organelles and in the extracellular matrix. Apo-VLDL-II is also localized in the electron-lucent component of the yolk platelet and in the extracellular matrix. Our results suggest that the lectin(s) are associated with Apo-VLDL-II in the yolk platelet, and may subsequently become externalized.     

Expression of the 14 kDa and 16 kDa galactoside-binding lectins during differentiation of the chick yolk sac

The gastrulating chick embryo expresses two galactoside-binding lectins of 14 kDa and 16 kDa. These lectins are present in the area pellucida and area opaca, and in the latter are concentrated in the endoderm. Since the area opaca is the progenitor of the yolk sac, we studied the galactose-binding lectins during the development of this extraembryonic organ. In the yolk sac, lectin expression surges between 2 and 4 days, and thereafter remains constant throughout development. Using monoclonal antibodies (mAbs) specific to the 16 kDa yolk sac lectin, and a panel of polyclonal antibodies to the 14 kDa and 16 kDa lectins we studied lectin expression. The mAbs inhibit the hermagglutinating activity of extracts from chick yolk sac, embryonic pectoral muscle, and adult liver, but have no effect on the hemagglutinating activity of extracts from the adult intestine. Immunolocalization studies with the mAbs and polyclonal antibodies indicate that in the less differentiated endodermal cells of the area vitellina the 16 kDa lectin is present in discrete lectin-rich inclusions. In contrast, within the maturing endodermal epithelium of area vasculosa the 16 kDa lectin is present around the intracellular yolk platelets, and is associated with the cytoplasmic matrix. The 16 kDa lectin is also found at the apical cell surface of the yolk sac epithelium, in some regions closely associated with the plasma membrane. The 14 kDa lectin is distributed intracellularly surrounding the yolk platelets of the maturing yolk sac endoderm. The surge in expression of the 16 kDa lectin at the time of expansion of the area opaca suggests that it may be involved in the spreading of this area. Our findings also indicate that as the yolk sac endoderm differentiates into an epithelium intracellular lectin expression changes from predominantly organelle associated to cytoplasm associated. The association of both lectins with yolk suggest that the lectins may also be involved in the processing of intracellular and extracellular yolk proteins. These results, in con junction with previous findings indicating the presence of these lectins in the extracellular matrix (Didier et al., Histochemistry 100:485, 1993; Zalik et al., Intl J Dev Biol 38:55–68, 1994) indicate that these lectins play multiple roles in embryonic development.     

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.     

Immunological cross-reactivity between beta-galactoside-binding lectins of vertebrates. Possible relationship of antigenicity to oligomeric structure

Structural relationships among five beta-galactoside-binding lectins isolated from human, mouse and chick were studied using immunochemical methods. The lectins examined were human placenta lectin with a 14-kDa subunit (human 14K lectin), two types of mouse lectin (mouse 15K and mouse 16K lectin), and two types of chick lectin (chick 14K and chick 16K lectin). Five polyclonal antibodies raised against these lectins were used. Antibody to human 14K lectin cross-reacted with mouse 15K and chick 14K lectins. Antibodies to both mouse 15K and chick 14K lectins cross-reacted with human 14K and chick 16K lectins. Antibody to chick 16K lectin cross-reacted with mouse 15K lectin. An immunological relationship was not found between human 14K and chick 16K lectins, or between mouse 15K and chick 14K lectins. Mouse 16K lectin did not show any immunological relationship with any of the other lectins. A monoclonal antibody raised against chick 14K lectin cross-reacted with chick 16K lectin. These results cannot be explained simply in terms of phylogenic distance but suggest that vertebrate beta-galactoside-binding lectins can be classified into two structural groups on the basis of their antigenicities. One group, which is characterized as a monomer type, includes human 14K and chick 14K lectins. The other group, which is characterized as a dimer type, includes mouse 15K and chick 16K lectins.     

Structure of chicken 16-kDa beta-galactoside-binding lectin. Complete amino acid sequence, cloning of cDNA, and production of recombinant lectin

The complete primary structure of chicken 16-kDa beta-galactoside-binding lectin (C-16) was determined. It was composed of 134 amino acid residues and has an acetylated NH2 terminus. A cDNA was also cloned, but no signal sequence was found in the initiator region. The initiator methionine remained as the NH2 terminus of the mature lectin. Although C-16 is distinct from chicken 14-kDa beta-galactoside-binding lectin (C-14), it proved to be a member of the vertebrate 14-kDa-type lectin family. Comparison of the primary structures between the vertebrate 14-kDa-type lectins suggests that C-14 and C-16 were produced by gene duplication of an ancestral lectin gene at a time close to the divergence of birds and mammals. Northern and Southern blot analysis indicated that these isolectins are encoded by individual genes which are differently regulated during the development of the embryo. A recombinant C-16 lectin was produced in Escherichia coli. The product was indistinguishable from the authentic C-16 lectin except that the NH2 terminus of the former was found to begin with free methionine.     

Changes in expression of two endogenous β-galactoside-binding isolectins in the dermis of chick embryonic skin during development in ovo and in vitro

In order to elucidate the roles of metal-independent animal lectins, we systematically investigated changes in expression of 2 kinds of -galactoside-binding isolectins (MW 14 and 16 kDa) in the dermis of chick embryonic tarsometatarsal skin during the course of development. These lectins were immunohistochemically located at different stages of development both in ovo and in vitro by light and electron microscopy. Light-microscopic observation showed that while positive staining for the 14-kDa lectin was weak at days 8 and 10 it became intense after day 13. In contrast, staining for the 16-kDa lectin was intense at days 8, 10, and 13, but it became weak after day 17 when keratinization of the epidermis was completed. Immuno-electron-microscopic observation revealed that both the 14 and 16-kDa lectins were located on the basement membrane, in the extracellular matrix, and in both the cytoplasm and the nucleus of dermal fibroblasts. Distribution of the 2 isolectins was also examined in cultured skin explants in vitro. The results were almost the same as those obtained in ovo when the skin explant was keratinized in the presence of hydrocortisone. However, in the skin explant where keratinization was prevented and mucous metaplasia was induced by the addition of vitamin A, the distribution of the 14-kDa lectin in the epidermis was significantly affected. These results indicate that (1) the expression of the 2 isolectins is differently regulated in both the dermis and epidermis, (2) the 16-kDa lectin is involved in the early stage of the formation of the dermis and the basement membrane and is replaced by the 14-kDa lectin as keratinization of the epidermis occurs, and (3) the expression of the 2 isolectins in the dermis is not significantly affected by the induction of mucous metaplasia, in contrast to their drastic changes in the epidermis.     

Rat lung 29 kD beta-galactoside-binding lectin is secreted by bronchiolar Clara cells into airways

We isolated a mixture of beta-galactoside-binding lectins from rat lung and raised polyclonal antibody against 14 kD lectin purified from the mixture of lectins. Immunoblotting of the mixture of lectins, which was separated with SDS-PAGE under reducing condition and transferred onto a NC paper, showed that the antibody reacted with two bands at 14 and 29 kD, indicating that these two lectins have common antigenic determinants(s). Immunohistochemically, the antibody recognized only bronchiolar Clara cells with intense immunofluorescence in their apical cytoplasmic protrusions where the secretory granules of the cells are known to be stored. Thus, to determine if the lectin(s) might be secreted into airways, we next raised antibody against airway secretions free from serum as well as surfactant proteins. By immunoblot analysis, the resulting antibody stained 29,45 and 55 kD bands, but not 14 kD band, on a NC paper transferred with the mixture of lectins. These findings suggest that at least 29 kD lung lectin is located in bronchiolar Clara cells and secreted by these cells into airways.     

Rat lung 29 kD β-galactoside-binding lectin is secreted by bronchiolar Clara cells into airways

Summary We isolated a mixture of -galactoside-binding lectins from rat lung and raised polyclonal antibody against 14 kD lectin purified from the mixture of lectins. Immunoblotting of the mixture of lectins, which was separated with SDS-PAGE under reducing condition and transferred onto a NC paper, showed that the antibody reacted with two bands at 14 and 29 kD, indicating that these two lectins have common antigenic determinant(s). Immunohistochemically, the antibody recognized only bronchiolar Clara cells with intense immunofluorescence in their apical cytoplasmic protrusions where the secretory granules of the cells are known to be stored. Thus, to determine if the lectin(s) might be secreted into airways, we next raised antibody against airway secretions free from serum as well as surfactant proteins. By immunoblot analysis, the resulting antibody stained 29,45 and 55 kD bands, but not 14 kD band, on a NC paper transferred with the mixture of lectins. These findings suggest that at least 29 kD lung lectin is located in bronchiolar Clara cells and secreted by these cells into airways.     

Hepten inhibitors of the endogenous galactose binding lectins and anti-lectin antibodies inhibit primitive streak formation in the early chick embryo

The early chick blastoderm expresses two endogenous galactose-bindinglectins of 14 kDa and 16 kDa. We have studied the effect thelectin hapten inhibitors thiodigalactoside and the syntheticneoglycoprotein lactosyl-bovine serum albumin as well as polyclonalanti-lectin antibodies on the development of early chick embryoscultured in a defined medium. Controls consisted of maltose,maltosyl bovine serum albumin and rabbit IgG. Embryos treatedat the onset of cell migration during early gastrulation underwentblastoderm retraction with decrease in surface area. In addition,they exhibited a lack of demarcation between the presumptiveembryonic area (area pellucida) and the presumptive extraembryonicarea (area opaca). These blastoderms also lacked a primitivestreak, that is, the structure that forms in the area pellucidaduring gastrulation as cell migrate to form the endodermal andmesodermal layers of the embryo. Embryos treated at later stagesof gastrulation showed development similar to that of controlsin that they were able to undergo early organogenesis. The resultssuggest that lectin mediated mechanisms are essential for themigratory movements of early gastrulation and that, at lategastrulation, other mechanisms exist in the embryo to compensatefor lectin function. blastoderm chick embryo galectin     

An ultrastructural study of adhesive junctions in reaggregates of unincubated chick embryos.

Cell suspensions obtained by the dissociation of unincubated chick embryo blastoderms were allowed to reaggregate on a gyratory shaker for 24-48 hours. The reaggregates which form during this period consist of an inner phase of tightly packed cohesive cells surrounded by an external phase of loosely packed cells. This sorted out arrangement achieves its definitive form between 24 and 48 hours of rotation culture. It was determined that the external phase consists of primitive ectoderm and that the internal phase consists of primitive endoderm. Both 24- and 48-hour reaggregates were examined in the electron microscope and observations were directed to areas of close membrane apposition between cells. In 48-hour reaggregates, primitive endoderm cells were joined by many specialized junctions (desmosomes). The formation of desmosomes in reaggregates of dissociated unincubated chick embryo cells was correlated with the sorting out process.     

Inositol- and Galactose-Binding Lectins of Chicken Brain Fractions Enriched with Glial Cells

Galactose- and inositol-binding proteins with lectin activity (GL-GAL and GL-I, respectively) were isolated from membranes enriched with cells of chicken brain fractions. Both lectins are glycoproteins of molecular mass 13.5 and 11.5 kDa, respectively; they show a high affinity to EDTA (GL-I) and EGTA (GL-GAL, GL-I), which indicates an important role of Ca⁺² in molecular organization of these lectins. In brain glial cells of chick embryos, unlike adult chickens, a soluble form of lectins has been revealed; it is easily extracted with 2 mM EDTA and shows sensitivity to L-lactose, D-galactose, and N-acetyl-D-galactosamine. It is suggested that in the course of embryonal and postembryonal development of the chicken brain, a transformation and qualitative changes of the lectin spectrum occur due to a change of function of glial cells.     

Primitive streak-forming cells of the chick invaginate through a basement membrane

Summary Recently fibronectin was shown to appear in the development of the chick for the first time as a thin band on the epiblastic side facing the hypoblast just prior to primitive streak formation. It was thus suggested that fibronectin might be instrumental in the migration of cells that lead to axis formation during primitive streak formation. In the present work we have examined simultaneously for the presence of fibronectin and the specific basement membrane glycoprotein laminin during primitive streak formation using immunofluorescence methods. Laminin was found to be expressed between the epiblast and the hypoblast of stage XIII¹ chick blastoderms. During the immediately following process of streak formation the laminin was found to be continuously detectable throughout the area covered by the hypoblast, but disrupted on the streak area. Fibronectin was found to co-distribute with laminin in stage XIII and in the early primitive streak chick blastoderms. It is concluded that at stage XIII laminin and fibronectin form part of a basement membrane that is partially disrupted during the immediately following process of primitive streak formation in order to allow the migration of the streak-forming epiblastic cells during this morphogenetic process.     

Immunochemical detection of unique proteolytic fragments of the chick 1,25-dihydroxyvitamin D3 receptor. Distinct 20-kDa DNA-binding and 45-kDa hormone-binding species

We have characterized proteolytic fragments of the chick intestinal 1,25-dihyroxyvitamin D3 (1,25-(OH)2D3) receptor, produced through either exogenous or endogenous protease action, utilizing a variety of physical and functional assays coupled to immunoblot detection methodology. Treatment of intestinal cytosol with increasing concentrations of trypsin resulted in a progressive diminishment of the 60-kDa receptor concomitant with the appearance of a 20-kDa fragment reactive by Western blot analysis to an anti-1,25-(OH)2D3 receptor monoclonal antibody. Cleveland analysis supported the receptor-origin of this 20-kDa fragment: a common immunoreactive species of 12 kDa could be generated by Staphylococcus aureus V8 protease treatment of the intact 60-kDa receptor as well as the 20-kDa proteolytic product. The 20-kDa fragment did not bind hormone but was capable of interacting with DNA-cellulose in a fashion identical to that of the 60-kDa receptor and, therefore, may contain the functional DNA-binding domain of the chick 1,25-(OH)2D3 receptor. Thus, this fragment likely represents the complement of a larger hormone-bound fragment that we have previously described (Allegretto, E. A., and Pike, J.W. (1985) J. Biol. Chem. 260, 10139-10145). In contrast to the exogenous effect of trypsin, incubation of cytosol resulted in the time-dependent formation of an endogenous protease-derived fragment of 45 kDa. Cleveland analysis was consistent with the 60-kDa receptor derivation of the 45-kDa fragment. This species retained the hormone-binding site and the antibody determinant but was devoid of DNA-binding activity. Moreover, it generated neither the trypsin-dependent 20-kDa fragment nor the V8 protease-dependent 12-kDa species and, therefore, was derived from the opposite end of the receptor molecule. These data have facilitated the construction of a schematic model of the chick receptor in which the immunoreactive epitope is located between the functional domains for hormone binding and DNA binding.     

Localization of a 215-kDa tyrosine-phosphorylated protein that cross-reacts with tensin antibodies.

Tyrosine phosphorylation of cytoskeletal proteins at adhesive junctions has been speculated to play a role in the regulation of cell signaling at these sites. Previously, monoclonal antibodies were generated against phosphotyrosine-containing proteins from Rous sarcoma virus-transformed chick embryo fibroblasts, resulting in two antibodies which recognized antigens of 76 and 215 kDa that localized to focal contacts. We have now localized the 215-kDa antigen to a number of adhesive junctions in vivo, including the zonula adherens, intercalated discs, and myotendinous and neuromuscular junctions. In sections of skeletal muscle and in isolated myofibrils, the 215-kDa protein was localized to the I-band. By immunoprecipitation and immunoblot analysis, we determined that the 215-kDa antigen cross-reacts with a polyclonal anti-tensin antibody.     

Effect of amino acid substitution by sited-directed mutagenesis on the carbohydrate recognition and stability of human 14-kDa beta-galactoside-binding lectin.

The roles of selected amino acid residues of human 14-kDa beta-galactoside-binding lectin were studied by site-directed mutagenesis. Ten mutant lectin proteins were produced, in each of which one of the residues regarded as possibly related to the stability of the lectin (6 cysteine residues) or one of those highly conserved in the vertebrate beta-galactoside-binding lectin family (Asn46, Trp68, Glu71, and Arg73), was substituted. All the mutant lectins in which one of the cysteine residues had been substituted with serine (C2S, C16S, C42S, C60S, C88S, and C130S) proved to have sugar binding ability comparable with that of the wild-type lectin. In addition, one of the mutants in which Cys2 was substituted (C2S) was found to have become considerably more stable under non-reducing conditions. It retained asialofetuin binding activity for over a week in the absence of beta-mercaptoethanol, while the wild-type lectin lost it within a day. This suggests that oxidation of Cys2 could be a key process in the inactivation of human 14-kDa lectin. Substitution of highly conservative Trp68 to tyrosine (W68Y) slightly reduced lactose binding ability, but the mutant was still adsorbed strongly on asialofetuin-agarose. Other mutant lectins in which conservative hydrophilic amino acids were substituted (N46D, E71Q, and R73H) failed to bind to the asialofetuin agarose, with no sign of retardation. Thus, conservative hydrophilic residues proved to be more important in carbohydrate recognition than the cysteine and tryptophan residues, contrary to the widely accepted concept that these latter residues are essential.     

Evidence that Caenorhabditis elegans 32-kDa beta-galactoside-binding protein is homologous to vertebrate beta-galactoside-binding lectins. cDNA cloning and deduced amino acid sequence.

We have cloned a full-length cDNA for a beta-galactoside-binding protein with a relative molecular mass of 32 kDa (32-kDa GBP), recently purified from a nematode, Caenorhabditis elegans (Hirabayashi, J., Satoh, M., Ohyama, Y., and Kasai, K. (1992) J. Biochem. 111, 553-555). The clone contained a single open reading frame encoding 279 amino acids, including the initiator methionine. Significant sequence homology to metal-independent beta-galactoside-binding lectins (25-30% identities), which had previously been found only in vertebrates, was observed. Moreover, the nematode 32-kDa GBP proved to have a unique polypeptide architecture; that is, it is composed of two tandemly repeated homologous domains, each consisting of about 140 amino acids. The internal homology was about 32%. Thus, this protein is constructed with a duplicated fundamental unit which is similar to the subunit of vertebrate 14-kDa lectins. In spite of the extreme phylogenic distance between nematodes and vertebrates (divergence greater than 6 x 10(8) years ago), both of the two repeated domains of the nematode 32-kDa GBP retained most of the amino acid residues conserved in vertebrate lectins. This means that members of the metal-independent animal lectin family are distributed much more widely than had been believed: from nematodes to vertebrates. The implication is that proteins belonging to this family have fundamental roles which are not restricted to vertebrates but are common to almost all animals.     

Molecular cloning, characterization, and expression of a human 14-kDa lectin

Full length cDNAs coding for a 14-kDa beta-galactoside binding lectin have been isolated from HL-60 cells and human placenta. Oligonucleotide probes based on a pentapeptide present in several partial sequences of homologous human lectins were used to screen a lambda GT10 HL-60 cDNA library. The HL-60 cDNA clones that were isolated were used to design a synthetic primer representing the 3'-untranslated region of the HL-60 lectin. This primer was then used to synthesize a lambda GT10 human placenta cDNA library, and restriction fragments of the HL-60 cDNA clones were used to screen the library. The cDNA clones for both HL-60 and placenta lectin had identical sequences with short 5'- and 3'-untranslated regions and coded for a 135-amino acid protein which lacks a hydrophobic signal peptide sequence. Biochemical data show that, despite the presence of a possible N-linked glycosylation site, the protein is not glycosylated. Northern and Southern blot analyses indicate that the 14-kDa lectin is encoded for by a single gene. The lectin cDNA was expressed in Escherichia coli and biologically active protein was purified from cell lysates by affinity chromatography.     

Lectin receptors on the peri- and early post-implantation mouse embryo

Summary Mouse embryos at the blastocyst, blastocyst outgrowth, and primitive streak (day 7.5) stages of development were analysed for expression of lectin receptors using a panel of six FITC-conjugated lectins with affinities for five distinct saccharides (BSL, ConA, DBA, LTL, UEA and WGA). Blastocyst trophoblast expressed receptors for all the lectins but later tissues of the trophectoderm lineage lost receptors for distinct but overlapping subsets of the lectin panel. The inner cell mass (ICM) of the early blastocyst lacked receptors only for UEA. Differentiation of primary endoderm was accompanied by the aquisition of UEA receptors but subsequent differentiation into visceral and parietal endoderm involved the loss of receptors for both fucose binding lectins (UEA and LTL). Embryonic ectoderm in the day 7.5 egg cylinder retained receptors only for ConA and WGA. Thus, in general, differentiation during the peri- and early post-implantation period was associated with a differential loss of lectin receptors in all cell lineages of the mouse conceptus.     

The sequence of the mouse 14 kDa beta-galactoside-binding lectin and evidence for its synthesis on free cytoplasmic ribosomes.

The partial amino acid sequence of the mouse 14 kDa beta-galactoside-binding lectin has been deduced from cDNA clones corresponding to 86% of the coding sequence and extending to the polyadenylation signal. The deduced amino acid sequence for the murine lectin shows 94% identity with the rat, 89% with human, 86% with bovine and 46% with the chicken 14 kDa lectins. A cDNA probe has been used to analyse genomic DNA and identify a single mRNA of approx. 570 bp in 3T3 fibroblasts, murine erythroleukaemia cells and the murine basement-membrane-secreting Engelbreth-Holm-Swarm tumour. Analysis of free and bound polyribosomes has shown that the lectin message is translated on free cytoplasmic ribosomes.     

Further characterization and structural studies on human placenta lectin

The properties of a previously purified beta-galactoside-binding lectin of human placenta were studied in detail. Isoelectric focusing gave multiple bands around pH 4.9, although the lectin preparation was homogenous in SDS-polyacrylamide gel electrophoresis. High-performance gel chromatography suggested that the lectin exists mainly as the monomer and that a small fraction forms a dimer. From all the criteria examined, human placenta lectin resembles one of the chick lectins obtained from embryonic skin or adult intestine (subunit molecular weight: 14,000). The lectin was inactivated by thiol-modifying reagents, p-chloromercuribenzoic acid and N-ethylmaleimide. Reduced and carboxymethylated lectin contained five carboxymethylated cysteines per subunit, and five free thiol groups were titrated by using 5,5'-dithio-bis(2-nitrobenzoic acid). Preliminary sequence analysis showed the presence of a region highly homologous to the corresponding region of the chick lectin (13 identical residues out of 18 from number 70 to 87 of the chick lectin), suggesting a close evolutionary relation between these lectins and the importance of this conserved region in the function of the lectins.