Abstract
During preparation of cells for experimentation a considerable amount of bound substance is lost. Our aim was to develop a protocol which retained lectin binding to an extent similar to living cells. This procedure would use fixation procedures suited for fluorescent lectin conjugates and gold-conjugates to be visualized by light- and electron microscopy, respectively. We tested glutaraldehyde and paraformaldehyde in different concentrations before and after lectin binding, different buffers and divalent cations, as additives, to determine the effects on preservation of lectin binding. Lectin binding was visualized and semiquantitatively evaluated by image analysis in the light microscope after silver enhancement of lectin-gold conjugates and by using tetramethyl rhodaminyl isothiocyanate (TRITC)-conjugated lectins. Preservation of lectin binding was best visualized with fluorescent lectin conjugates, whereas during silver enhancement procedures of gold-conjugated lectins, a considerable amount of bound lectins was lost. In general, lectin binding to living cells followed by fixation is superior to fixation before lectin binding. Unfavourable combinations of fixatives and buffers can cause a loss of more than 90% bound lectin. In our experiments with freshly isolated guinea pig cardiomyocytes, lectin binding was best when we used Na-cacodylate buffer with glutaraldehyde fixation (0.1%) after binding of lectins to the living cells.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Allison RT (1987). The effects of various fixatives on subsequent lectin binding to tissue sections. Histochem J 19: 65–74.
Augustin-Voss HG (1993). Use of lectins for the phenotypic characterization of cultured cell monolayers. In: Gabius HJ, Gabius S (eds), Lectins and glycobiology. Berlin/Heidelberg: Springer Verlag, pp 272–277.
Buxton RS, Magee AI (1992). Structure and interactions of desmosomal and other cadherins. Sem Cell Biol 3: 157–167.
Damjanov I (1987). Lectin cytochemistry and histochemistry. Lab Invest 57: 5–20.
Goldstein IJ, Poretz RD (1986). Isolation, physicochemical characterization, and carbohydrate-binding specificity of lectins. In: Liener IE, Sharon N, Goldstein IJ (eds), The lectins-properties, functions, and applications in biology and medicine. London: Academic Press, pp 33–247.
Li WP, Zuber C, Roth J (1993). Use of Phaseolus vulgaris leukoagglutinating lectin in histochemical and blotting techniques: A comparison of digoxigenin-and biotin-labelled lectins. Histochem 100: 347–356.
Nathan RD, Fung FJ, Stocco DM, Barron EA, Markwald RR (1980). Sialic acid: Regulation of electrogenesis in cultured heart cells. Am J Physiol 239: C197–C207.
Roth J (1993). Cellular sialoglycoconjugates: A histochemical perspective. Histochem J 25: 687–710.
Sharon N, Lis H (1993). Carbohydrates in cell recognition. Sci Am 268: 82–89.
Sinowatz F, Plendl J, Gabius HJ, Neumüller C, Amselgruber W (1993). Lectin and neoglycoprotein binding to cells. In: Gabius HJ, Gabius S (eds), Lectins and glycobiology. Berlin/Heidelberg: Springer Verlag, pp 260–271.
Stegemann M, Meyer R, Haas HG, Robert-Nicoud M (1990). The cell surface of isolated cardiac myocytes. J Mol Cell Cardiol 22: 787–803.
Yee HF, Weiss JN, Langer GA (1989). Neuraminidase selectively enhances transient Ca2+ current in cardiac myocytes. Am J Physiol 256: C1267–C1272.
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Meyer, R., Kirch, D. & Achenbach, F. Quantification and preservation of lectin binding by isolated cardiomyocytes. Methods Cell Sci 19, 101–106 (1997). https://doi.org/10.1023/A:1009752727251
Issue Date:
DOI: https://doi.org/10.1023/A:1009752727251