The gastrulating chick blastoderm contains 16-kDa and 14-kDa galactose-binding lectins possibly associated with an apolipoprotein

Endogenous galectins and effect of galectin hapten inhibitors on the differentiation of the chick mesonephros

Galectins are galactoside-binding lectins. In the mesonephros of the chick embryo, the 16-kDa galectin is abundant in the glomerular and tubular basement membranes where it colocalizes with fibronectin and laminin. To test whether galectin-glycoprotein interactions could play a role in mesonephric development, the effects of the galectin hapten inhibitors thiodigalactoside (TDG) and lactose on the differentiation of the cultured mesonephros were investigated. When compared to control saccharide-free or maltose-treated cultures, mesonephroi cultured in the presence of TDG and lactose exhibited defects in tissue organization. These included a distorted tubule shape, pseudo-stratification of the tubular epithelium, and detachment of glomerular podocytes from the basement membrane. The presence of molecular differentiation markers in the developing mesonephros was investigated. In vivo, expression of the epithelial-specific cell adhesion molecule E-cadherin is restricted to differentiated tubular epithelial cells, whereas the intermediate filament protein vimentin is present in mesonephrogenic mesenchyme and is undetectable in tubular epithelial cells. In mesonephroi cultured in the absence of sugars or in the presence of maltose, the expression pattern of these two marker molecules resembles that found in the mesonephros in vivo. In contrast, in the mesonephroi cultured in the presence of TDG and lactose, the epithelial tubular cells expressing E-cadherin also express vimentin. Re-expression of vimentin in the tubular epithelial cells could indicate a partial reversal to a mesenchymal phenotype. Results suggest that galectin-glycoprotein interactions in the basement membrane are important in the maintenance of the renal epithelial phenotype. Dev Dyn 1999;215:248-263.

Immunohistochemical localisation of a galectin from Bufo arenarum ovary

Galectins are a group of soluble animal lectins that exhibit specificity for beta-galactosides and conserve sequence homology in the carbohydrate-recognition domain. The galectin from Bufo arenarum ovary showed a strong cross-reaction with the lectin of 14.5 kDa purified from embryos at early blastula stage. In this paper, we studied the immunohistochemical localisation of the galectin of 14.5 kDa from ovary of the toad B. arenarum in adult ovary sections. We also analysed the immunohistochemical localisation of the embryonic lectin during early development using the antiserum anti-ovary galectin. In the ovary, oocytes in the previtellogenic stage showed strong reactivity in the nucleus and the cortex but not in the cytoplasm. Oocytes in the stage of primary vitellogenesis exhibited a similar pattern in the nuclear and cortical areas but showed immunostaining in the cytoplasm. Intense nuclear staining was detected in oocytes in the stage of late vitellogenesis and in mature oocytes, which also presented strong reactions in the yolk platelets that completely covered the cytoplasm. In blastula embryos the staining was found in the blastomeres, the yolk platelets and the blastocoele. Each lectin localisation is discussed in relation to potential biological roles in the corresponding tissues.

Molecular characterization of quail apolipoprotein very-low-density lipoprotein II: disulphide-bond-mediated dimerization is not essential for inhibition of lipoprotein lipase

As part of the avian reproductive effort, large quantities of triglyceride-rich very-low-density lipoprotein (VLDL) particles are transported by receptor-mediated endocytosis into the female germ cells. Although the oocytes are surrounded by a layer of granulosa cells harbouring high levels of active lipoprotein lipase, non-lipolysed VLDL is transported into the yolk. This is because VLDL particles from laying chickens are protected from lipolysis by apolipoprotein (apo)-VLDL-II, a potent dimeric lipoprotein lipase inhibitor [Schneider, Carroll, Severson and Nimpf (1990) J. Lipid Res. 31, 507-513]. To determine whether this protection depends on dimer formation and constitutes a general mechanism to ensure high levels of yolk triglycerides for embryonic utilization in birds, we have now molecularly characterized apo-VLDL-II in the Japanese quail, a frequently used avian species. Quail apo-VLDL-II shows 72% amino acid identity with the chicken protein, with most replacements being in the C-terminal region. Importantly, quail apo-VLDL-II lacks the single cysteine residue present eight residues from the C-terminus of chicken apo-VLDL-II, which is responsible for dimerization of the chicken lipoprotein lipase inhibitor. Nevertheless, monomeric quail and dimeric chicken apo-VLDL-II display, on a molar basis, identical inhibitory effects on lipoprotein lipase, underscoring the biological importance of their function. Furthermore secondary structure prediction of the 3'-untranslated region of the quail message supports a role for loop structures in the strictly oestrogen-dependent production of the lipoprotein lipase inhibitors. Our findings shed new light on the essential role of this small, hormonally regulated, protein in avian reproduction.

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.

Development of bile canaliculi between chicken embryo liver cells in vivo and in vitro

The development of an organized network of bile canaliculi is essential for the normal functioning of the liver. We have characterized bile canaliculus development in situ from Days 3-19 and in vitro in cultured hepatocyte monolayers using electron microscopical and immunofluorescent staining with antibodies that specifically recognize antigens of the bile canaliculus. Although the liver first forms as a discrete epithelial bud of endodermal tissue at stage 12-14 (45-53 h after laying), canaliculi were first detected by our antibodies at low levels in 4-day embryos and at high levels in stage 27 (5 days after laying) and later embryos. During Days 4, 5, and 6 the canaliculi near the periphery of the rudiment do not stain while canaliculi in central areas, closer to the gut, are strongly stained. During this transition period the ultrastructure of the canaliculi in the peripheral regions is also less developed than the central canaliculi where the antigens appear. By 7 days post laying, canaliculi throughout the entire liver rudiment express the marker antigens equally and have the ultrastructural characteristics of mature, functional canaliculi. Cells prepared from liver of embryos of 11 days incubation and grown in monolayer culture reformed discernible canalicular specializations, as determined by immunofluorescent staining and electron microscopy, but only transiently (for 1 to 3 days after plating). Not all of the antigens were expressed or polarized in these cultures. The capacity of the embryonic parenchymal cells to develop and maintain polarity appears to depend on factors possibly including age-dependent changes in the cells themselves, interactions with other cell types or extracellular matrix, or the shape of the cells.

Structural variants of the neural cell adhesion molecule (N-CAM) in developing feathers

The neural cell adhesion molecule (N-CAM) is expressed in a specific spatiotemporal pattern during feather development, suggesting that adhesion mediated by this molecule is involved in feather morphogenesis. To begin to investigate N-CAM's function in developing feathers, we determined what forms of N-CAM polypeptide are present and the distribution of polysialic acid (PSA), a carbohydrate moiety that decreases N-CAM-mediated cellular adhesion. N-CAM in skin appears as a Mr 145-kDa polypeptide compared to the 140-kDa brain N-CAM polypeptide, and is encoded by a 6.4-kb mRNA, compared to the 6.1-kb mRNA in brain. Polymerase chain reaction analysis of the exon splicing pattern of skin N-CAM shows that the 6.4-kb mRNA band represents two transcripts, with and without a 93-bp insert between exons 12 and 13. Thus, two N-CAM polypeptides are expressed in skin, but the 93-bp insert does not account for the larger size of the skin mRNAs and polypeptides. We show that the size difference of the polypeptides is instead due to N-linked oligosaccharides attached to the skin N-CAM proteins. The larger size of the skin mRNAs may be due to use of a different transcriptional start site. Staining of skin sections and wholemounts confirms previous descriptions of N-CAM in developing feathers, but reveals that N-CAM is also present at low levels on epidermal cells as early as stage 29 (E6). We find that PSA is expressed only on a subset of the cells that express N-CAM, in particular on dermal cells in the feather rudiments from stage 35-36 (E9-10) and on smooth muscle cells at the base of the filaments from stage 37 (E11) until the latest stage examined (stage 44, E18). The known effects on cell-cell adhesion of amount of N-CAM and PSA suggest that the variations we observe in skin may regulate cell-cell interactions that are important in feather development.