Summary
The binding of six different FITC-labelled lectins to mesenchyme, blastemal cells and cartilage was investigated in limb buds of mouse embryos during their development from day 10 to day 13. Concanavalin A, wheat germ agglutinin and phaseolus vulgaris agglutinin labelled mesenchymal cells of earlier stages, day 10 or 11, distinctly more than those of later stages. Chondrogenic blastema, basement membrane and muscle were always strongly stained. The galactosamine-specific ricinus communis agglutinin (RCA) bound preferentially to the blastema, whereas the mesenchyme was only weakly labelled. The galactose-specific peanut agglutinin (PNA), however, stained solely the blastema. In the mesenchyme, no binding was detectable light microscopically with this lectin. In cartilage, RCA-and PNA-staining was found to a lesser extent. With the fucose-specific lectin Lotus A, no staining was detectable.
Due to the apparent differences in the binding of PNA in mesenchyme and blastema, peroxidase-labelled PNA was used to study the binding behaviour electron microscopically. It is shown that peroxidase-PNA very strongly labelled the intercellular matrix and the plasma membrane of cells in the late blastemal stages, whereas in young blastema no reaction product was detectable. In, contrast to light microscopic findings, some label could be demonstrated also in the mesenchyme. The results show, a general reduction of lectin receptors in more developed mesenchyme of later stages and the occurrence of galactose and galactose derivatives during early chondrogenesis in the matrix and at the cell membrane. The significance of these changes for chondrogenesis, however, remains to be elucidated.
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References
Asao MI, Oppenheimer SB (1979) Inhibition of cell aggregation by specific carbohydrates. Exp Cell Res 120:101–110
Barrach HJ, Grundmann K, Hinz N, Felies A (1980) Immunofluorescence microscopic investigations of intercellular substances during limb development. In: Merker HJ, Nau H, Neubert D (eds) Teratology of the limbs. IVth Symposium on prenatal development. Walter de Gruyter, Berlin, pp 273–293
Beyer EC, Tokuyasu KT, Barondes SS (1979) Localization of an endogenous lectin in chicken liver, intestine, and pancreas. J Cell Biol 82:565–571
Beyer EC, Zweig SE, Barondes SH (1980) Two lactose binding lectins from chicken tissues: Purified lectin from intestine is different from those in liver and muscle. J Biol Chem 255:4236–4239
Borck Ch (1977) Elektronenmikroskopische Untersuchungen an Mäuseembryonen über die Differenzierung des Blastems in den Extremitäten zum embryonalen Vorknorpel. Acta Anat 97:423–434
Bowles DJ (1979) Lectins as membrane components: Implications of lectin-receptor interaction. FEBS Lett 102/1:1–3
Brownell AG (1977) Cell surface carbohydrates of preimplantation embryos as assessed by lectin binding. J Supramol Struct 7:223–234
Burger MM (1973) Surface changes in transformed cells detected by lectins. Fed Proc 32:91–101
Cook GMW, Zalik SE, Milos N, Scott V (1979) A lectin which binds specifically to β-D-galactoside groups is present at the earliest stages of chick embryo development. J Cell Sci 38:293–304
Den H, Chin JH (1981) Endogenous lectin from chick embryo skeletal muscle is not involved in myotube formation in vitro. J Biol Chem 256:8069–8073
Den H, Malinzak DA, Rosenberg A (1976) Lack of evidence for the involvement of a β-D-galactosyl-specific lectin in the fusion of chick myoblasts. Biochem Biophys Res Commun 69:621–627
DeWaard A, Hickman S, Kornfeld S (1976) Isolation and properties of β-galactoside binding lectins of calf heart and lung. J Biol Chem 251:7581–7587
Ede DA, Flint OP, Wilby OK, Colquhoun P (1977) The development of precartilage condensations in limb bud mesenchyme in vivo and in vitro. In: Ede DA, Hinchliffe JR, Balls M (eds) vertebrate limb and somite morphogenesis. Cambridge University Press. Cambridge, pp 161–179
Font J, Aubery M (1983) Inaccessibility of certain Ricinus lectin binding sites due to the increase in hyaluroine acid during chick embryo development. Differentiation 25:23–26
Gahmberg CG, Hakomori SI (1973) Altered growth behaviour of malignant cells associated with changes in, externally labelled glycoprotein and glycolipid. Proc Natl Acad Sci USA 70/12:3329–3333
Glant TT (1982) Concanavalin A-binding link protein in the proteoglycan aggregate of hyaline cartilage. Biochem Biophys Res Commun 106:158–163
Hewitt AT, Elmer WA (1976) Reactivity of normal and brachypod mouse limb mesenchymal cells with Con A. Nature 264:177–178
Hewitt AT, Elmer WA (1978) Developmental modulation of lectin-binding sites on the surface membranes of normal and brachypod mouse limb mesenchymal cells. Differentiation 10:31–38
Howe CC, Solter D (1981) Changes in cell surface proteins during differentiation of mouse embryonal carcinoma cells. Dev Biol 84/1:239–243
Jamieson JD, Ingber DE, Muresan V, Hull BE, Sarras MP, Maylie-Pfenninger MF, Iwanij V (1981) Cell surface properties of normal, differentiating, and neoplastic pancreatic acinar cells. Cancer 47:1516–1525
Kaufman SJ, Lawless ML (1980) Thiogalactoside binding lectin and skeletal myogenesis. Differentiation 16:41–48
Kelley RO, Fallon JF (1978) Identification and distribution of gap junctions in the mesoderm of developing chick limb buds. J Embryol Exp Morphol 46:99–110
Kobiler D, Beyer EC, Barondes SH (1978) Developmentally regulated lectins from chick muscle, brain and liver have similar chemical and immunological properties. Dev Biol 64:265–272
MacBride RG, Przybylski RJ (1980) Purified lectin from skeletal muscle inhibits myotube formation in vitro. J Cell Biol 85:617–625
Matsutani E, Kuroda Y (1982) Effect of lectins on chondrogenesis of cultured quail limb bud cells. Dev Biol 89/2:521–526
Matsutani E, Yamagata T (1982) Chick endogenous lectin enhances chondrogenesis of cultured chick limb bud cells. Dev Biol 92/2:544–548
McLean RJ (1977) Membrane specialisation in the course of differentiation. In: Jamieson GA, Robinson DM (eds) Mammalian cell membranes. Vol 3: Surface membranes of specific cell types. Butterworth, London Boston, pp 250–265
Monroy A (1979) Surface differentiations and cell interactions in development. Differentiation 13:23–24
Moscona AA (1974) Surface specification of embryonic cells: Lectin receptors, cell recognition and specific cell ligands In: Moscona AA (ed) The cell surface in development. J Wiley and Sons, New York London, pp 67–99
Neubert D, Merker H-J, Tapken S (1974) Comparative studies on the prenatal development of mouse extremities in vivo and in organ culture. Naunyn-Schmiedeberg's Arch Pharmacol 268:251–270
Newman RA, Klein PJ, Rudland PS (1979) Binding of peanut lectin to breast epithelium, human carcinomas, and a cultured rat mammary stem cell: Use of the lectin as a marker of mammary differentiation. J Natl Cancer Inst 63:1339–1346
Nowak TP, Kobiler D, Roel LE, Barondes SH (1977) Developmentally regulated lectin from embryonic chick pectoral muscle. J Biol Chem 252:6026–6030
Paulsen DF, Finch RA (1977) Age- and region-dependent concanavalin A ractivity of chick wing bud mesoderm cells. Nature 268:639–641
Paulsen DF, Finch RA, Parker CL (1980) Age- and region-dependent redistribution, of Con A binding sites on chick wing bud mesoderm cells. J Exp Zool 213:369–376
Podleski TR, Greenberg I, Nichols SC (1979) Studies on lectin activity during myogenesis. Exp Cell Res 122:305–316
Roseman S (1970) The synthesis of complex carbohydrates by multiglycosyl-transferase systems and their potential function in intercellular adhesion. Chem Phys Lipids 5:270–297
Rosen SD, Chang CM, Barondes SH (1977) Intercellular adhesion in the cellular slime mold polysphondylium pallidum inhibited by interaction, of asialofetuin or specific univalent antibody with endogenous cell surface lectin. Dev Biol 61:202–213
Roth S (1973) A molecular model for cell interactions. Qu Rev Biol 48/4:541–561
Searls RL, Hilfer SR, Mirow SM (1972) An ultrastructural study of early chondrogenesis in the chick wing bud. Dev Biol 28:123–137
Sénéchal H, Delain D, Shapira G, Wahrmann JP (1983) Alterations in glycosylation of plasma membrane proteins during myogenesis. Exp Cell Res 147/2:341–350
Shur BD, Vogler M, Kosher RA (1982) Changes in the endogenous cell surface galactosyltransferase activity during in vitro limb bud chondrogenesis. Exp Cell Res 137:229–237
Toole BP (1973) Hyaluronate and hyaluronidase in morphogenesis and differentiation. Am Zool 13:1061–1065
Vasan NS, Lash JW (1979) Monomeric and aggregate proteoglycans in the chondrogenic differentiation of embryonic chick limb buds. J Embryol Exp Morphol 49:47–59
Walsh FS, Phillips E (1981) Specific changes in cellular glycoprotein and surface proteins during myogenesis in clonal muscle cells. Dev Biol 81:229–237
Wild J, Robinson D, Winchester B (1983) Isolation of mannose-binding proteins from human and rat liver. Biochem J 210/1:167–174
Wu JT (1980) Concanavalin A binding capacity of preimplantation rat embryos. J Exp Zool 213:377–382
Yamagata T, Nishiwaki T (1979) Chick embryonic cartilage has a developmentally regulated lectin specific for galactose-containing saccharides. Proc Jpn Acad 55:393–397
Zalik SE, Milos N, Ledsham I (1982) Distribution of a galactose-specific lectin in endoderm cells from early chick embryos. Cell Tissue Res 225:223–228
Zimmermann B (1980) Effects of surface coat influencing substances in the limb bud blastema in vitro. In: Merker HJ, Nau H, Neubert D (eds) Teratology of the limbs. Walter de Gruyter, Berlin, pp 153–162
Zimmermann B (1984) Assembly and disassembly of cell contacts during chondrogenesis in limb buds of mouse embryos. J Anat 138:351–363
Zimmermann B, Scharlach E, Kaatz R (1982) Cell contact and surface coat alterations of limb bud mesenchymal cells during differentiation. J Embryol Exp Morphol 72:1–18
Zisapel N, Littauer UZ (1979) Expression of external surface membrane proteins in differentiated and undifferentiated mouse neuroblastoma cells. Eur J Biochem 95/1:51–59
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This work contains parts of a doctoral thesis by Micheal Thies
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Zimmermann, B., Thies, M. Alterations of lectin binding during chondrogenesis of mouse limb buds. Histochemistry 81, 353–361 (1984). https://doi.org/10.1007/BF00514329
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DOI: https://doi.org/10.1007/BF00514329