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A simple fixation procedure for immunofluorescent detection of different cytoskeletal components within the same cell

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Summary

In recent studies on the cytoskeletal organization of T51B rat liver cells by indirect immunofluorescence microscopy, we have been unable to achieve double-staining of microtubules and intermediate filaments within the same cell. In acetone-fixed cells, microtubules were poorly preserved, and two out of three monoclonal antibodies tested did not stain them properly. In formaldehyde-fixed cells, the monoclonal anti-cytokeratin produced an incomplete staining pattern against a diffuse background. We have now developed a fixation protocol which includes simultaneous fixation and extraction with formaldehyde and nonionic detergent in the present of microtubule stabilization buffer. Although developed for a specific purpose, it is of general application as it yields excellent preservation of all cytoskeletal components tested so far, without masking antigenic determinants. The procedure is both simple and fast and will, therefore, be valuable for efficient processing of samples from large-scale experiments, such as the screening for cytoskeletal changes during longterm treatment of cells with drugs or carcinogens.

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References

  • Aitchison WA, Brown DL (1986) Dublication of the flagellar apparatus and cytoskeletal microtubule system in the alga Polytomella. Cell Motil Cytoskeleton 6:122–127

    Google Scholar 

  • Berlin RD, Oliver JM, Walter RJ (1979) Surface functions during mitosis. I: phagocytosis, pinocytosis and mobility of surface-bound ConA. Cell 15:327–341

    Google Scholar 

  • Bershadsky AD, Gelfand VI, Svitkina TM, Tint IS (1978) Microtubules in mouse embryo fibroblasts extracted with Triton X-100. Cell Biol Int Rep 2:425–432

    Google Scholar 

  • Brinkley BR (1982) The cytoskeleton: a perspective. Methods Cell Biol 24:1–8

    Google Scholar 

  • Falconer M, Vielkind U, Brown DL (1987) Alterations in microtubule stability and composition following commitment of embryonal carcinoma cells into neurons. J Cell Biol 105:203a

    Google Scholar 

  • Franke WW, Schmid E, Grund C, Geiger B (1982) Intermediate filament proteins in nonfilamentous structures: transient disintegration and inclusion of subunit proteins in granular aggregates. Cell 30:103–113

    Google Scholar 

  • Geiger B, Singer SJ (1980) Association of microtubules and intermediate filaments in chicken gizzard cells as detected by double immunofluorescence. Proc Natl Acad Sci USA 77:4769–4773

    Google Scholar 

  • Heimer GV, Taylor CED (1974) Improved mountant for immunofluorescence preparations. J Clin Pathol 27:254–256

    Google Scholar 

  • Hilwig I, Gropp A (1972) Staining of constitutive heterochromatin in mammalian chromosomes with a new fluorochrome. Exp Cell Res 75:122–126

    Google Scholar 

  • Hynes RO, Destree AT (1978) Relationships between fibronectin (LETS protein) and actin. Cell 15:875–886

    Google Scholar 

  • Johnson GD, Davidson RS, McNamee KC, Russel G, Goodwin D, Holborow EJ (1982) Fading of immunofluorescence during microscopy: a study of the phenomenon and its remedy. J Immunol Methods 55:231–242

    Google Scholar 

  • Joseph SK, Coll KE, Cooper RH, Marks JS, Williamson JR (1983) Mechanisms underlying calcium homeostasis in isolated hepatocytes. J Biol Chem 258:731–741

    Google Scholar 

  • Kilmartin JV, Wright B, Milstein C (1982) Rat monoclonal antitubulin antibodies derived by using a new nonsecreting rat cell line. J Cell Biol 93:576–582

    Google Scholar 

  • Kirschner M, Mitchison T (1986) Beyond self-assembly: from microtubules to morphogenesis. Cell 45:329–342

    Google Scholar 

  • Lane EB, Goodman SL, Trejdosiewicz LK (1982) Disruption of the keratin filament network during epithelial cell division. EMBO J 1:1365–1372

    Google Scholar 

  • Marceau N, Swierenga SHH (1985) Cytoskeletal events during calcium-or EGF-induced initiation of DNA synthesis in cultured cells. Role of protein phosphorylation and clues in the transformation process. In: Shaw JW (ed) Cell and muscle motility, vol 6. Plenum Press, New York London, pp 97–140

    Google Scholar 

  • Marceau N, Germain L, Goyette R, Noël M, Gourdeau H (1986) Cell of origin of distinct cultured rat liver epithelial cells, as typed by cytokeratin and surface component selective expression. Biochem Cell Biol 64:788–802

    Google Scholar 

  • Olmstedt JB, Borisy GG (1973) Microtubules. Annu Rev Biochem 42:507–540

    Google Scholar 

  • Osborn M, Weber K (1977 a) The display of microtubules in transformed cells. Cell 12:561–571

    Google Scholar 

  • Osborn M, Weber K (1977 b) The detergent-resistent cytoskeleton of tissue culture cells includes the nucleus and the microfilament bundles. Exp Cell Res 106:339–349

    Google Scholar 

  • Osborn M, Weber K (1982) Immunofluorescence and immunocytochemical procedures with affinity purified antibodies: tubulin-containing structures. Methods Cell Biol 24:97–132

    Google Scholar 

  • Puck TT, Cieciura SJ, Robinson A (1958) Genetics of somatic mammalian cells. III. Long-term cultivation of euploid cells from human and animal subjects. J Exp Med 108:945–956

    Google Scholar 

  • Schliwa M, van Blerkom J (1981) Structural interaction of cytoskeletal components. J Cell Biol 90:222–235

    Google Scholar 

  • Schliwa M, Euteneuer U, Bulinski JC, Izant JG (1981) Calcium lability of cytoplasmic microtubules and its modulation by microtubule-associated proteins. Proc Natl Acad Sci USA 78:1037–1041

    Google Scholar 

  • Singer SJ, Ball EH, Geiger B, Chen WT (1982) Immunolabeling studies of cytoskeletal associations in cultured cells. Cold Spring Harbor Symp Quant Biol 46:303–316

    Google Scholar 

  • Soltys BJ, Borisy GG (1985) Polymerization of tubulin in vivo: direct evidence for assembly onto microtubule ends and from centrosomes. J Cell Biol 100:1682–1689

    Google Scholar 

  • Viklický V, Oráber P, Hašek J, Bártek J (1982) Production and characterization of a monoclonal antitubulin antibody. Cell Biol Int Rep 6:725–731

    Google Scholar 

  • Weber K, Rathke PC, Osborn M (1978) Cytoplasmic microtubular images in glutaraldehyde-fixed tissue culture cells by electron microscopy and by immunofluorescence microscopy. Proc Natl Acad Sci USA 75:1820–1824

    Google Scholar 

  • Wulf E, Deboben A, Bautz FA, Faulstich H, Wieland T (1979) Fluorescent phallotoxin, a tool for the visualization of cellular actin. Proc Natl Acad Sci USA 76:4498–4502

    Google Scholar 

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Author notes

  1. U. Vielkind

    Present address: Department of Neurobiology and Anatomy, University of Rochester, School of Medicine, 14642, Rochester, NY, USA

Authors and Affiliations

  1. Drug Toxicology Division, Health and Welfare Canada, K1A OL2, Ottawa, Ontario, Canada

    U. Vielkind & S. H. Swierenga

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  1. U. Vielkind
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  2. S. H. Swierenga
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Vielkind, U., Swierenga, S.H. A simple fixation procedure for immunofluorescent detection of different cytoskeletal components within the same cell. Histochemistry 91, 81–88 (1989). https://doi.org/10.1007/BF00501916

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  • DOI: https://doi.org/10.1007/BF00501916

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