Summary
To understand the earliest phases of epidermal cell spreading we have sought a defined in vitro system. We studied the divalent cation dependence of guinea pig epidermal cell spreading in media containing varying concentrations of cations. No spreading occurred in calcium-magnesium-free Dulbecco's modified Eagle's medium (CMF-DME) in the presence of cation-free fetal bovine serum; however, significant spreading occurred if the medium was supplemented with Mg++ plus Ca++ or Mg++ alone. Supplementing with Ca++ alone led to much less spreading. These cations in CMF-DME did not support spreading in the absence of serum or the presence of serum albumin.
Assaying cell spreading in a simple salt solution consisting of NaCl, KCl, Tris buffer, pH 7.4 plus dialyzed serum and a series of divalent cation supplements (Ca++, Mg++, Mn++, Co++, Zn++, Ni++), showed that only Mg++ and Mn++, and to a lesser extent, Ca++, supported cell spreading. In contrast to Mg++, however, Mn++ could support spreading in the absence of whole serum if serum albumin were present. Although Mn++ plus serum albumin supported more rapid spreading at lower cation concentrations than Mg++ plus serum, equal concentrations of Ca++ completely blocked the Mn++ effect. In contrast to the increasing cell spreading, which occurred in Mg++-containing medium with time, cell death occurred in Mn++-containing medium by 24 h. Consonant with studies from other laboratories, human foreskin fibroblasts spread in Mn++-containing salt solution in the absence of protein supplements.
These experiments indicate for epidermal cell spreading that Mg++ is the important cation in tissue culture media, that under proper cation conditions epidermal cells do not need a specific spreading protein (i.e. a protein that has been demonstrated to support cell spreading), that Mn++ and Mg++-induced spreading seem to represent different mechanisms, that fibroblastic and epidermal cells have different cation requirements for in vitro spreading, and that the crucial role cations play in cell spreading remains to be elucidated.
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References
Anderson, M. Mn ions pass through calcium channels. A possible explanation, J. Gen. Physiol. 81:805–827; 1983.
Chao, S. H.; Suzuki, Y.; Zysk, J. R., et al. Activation of calmodulin by various metal cations as a function of ionic radius. Mol. Pharmacol. 26:75–82; 1984.
Evans, P. M.; Jones, B. M. Mn++-stimulated adhesion and spreading of Ehrlich ascites cells are separate processes. Cell Biol. Int. Res. 6:681–685; 1982.
Fritsch, P.; Tappeiner, G.; Huspek, G. Keratinocyte substrate adhesion is magnesium-dependent and calcium independent. Cell Biol. Int. Rep. 3:593–598; 1979.
Garvin, J. E. Effects of divalent cations on adhesiveness of rat polymorphonuclear neutrophilsin vitro. J. Cell Physiol. 72:197–212; 1968.
Grinnell, F. Manganese-dependent cell-substratum adhesion. J. Cell Sci. 65:61–72; 1984.
Houslay, M. D.; Heyworth, C. M.; Whetton, A. D. Mechanism of glucagon activation of adenylate cyclase in the presence of Mn++. FEBS Lett. 155:311–316; 1983.
Lowry, O. H.; Rosenbrough, N. J.; Farr, A. L., et al. Protein measurement with the folin phenol reagent. J. Biol. Chem. 193:265–275; 1951.
Maroudas, N. G. Adhesion and spreading of cells on charged surfaces. J. Theor. Biol. 49:417–424; 1975.
Okada, T. S.; Takeichi, M.; Yasuda, K., et al. The role of divalent cations in cell adhesion. Adv. Biophys. 6:157–181; 1974.
Putt, F. A. Manual of histological staining methods. New York: John Wiley & Sons; 1972: 226.
Rabinovitch, M.; DeStefano, M. J. Macrophage spreadingin vitro. I. Inducers of spreading. Exp. Cell Res. 77:323–334; 1973.
Rabinovitch, M.; DeStefano, M. J. Macrophage spreadingin vitro. II. Manganese and other metals as inducers or as cofactors for induced spreading. Exp. Cell Res. 79:423–430; 1973.
Rabinovitch, M.; DeStefano, M. J. Manganese stimulates adhesion and spreading of mouse sarcoma. I. Ascites cells. J. Cell Biol. 59:165–176; 1973.
Sefton, B. M.; Hunter, T.: Tyrosine protein kinases. Adv. Cyclic Nucleotide Protein Phosphylation Res. 18 195–226; 1984.
Stenn, K. S.; Dvoretzky, I. Human serum and epithelial spread in tissue culture. Arch. Dermatol. Res. 264;3–15; 1979.
Stenn, K. S.; Madri, J. A.; Tinghitella, T., et al. Multiple mechanisms of dissociated epidermal cell spreading. J. Cell Biol. 96:63–67; 1983.
Takeichi, M.; Okada, T. S. Roles of magnesium and calcium ions in cell to substrate adhesion. Exp. Cell Res. 74:51–60; 1972.
Triggle, D. J. Calcium antagonists: Basic chemical and pharmacological aspects. In: Weiss, G. W., ed. New perspectives on calcium antagonists. Bethesda, MD: American Physiological Society; 1981:1–18.
Trinkaus, J. P. Cells into organs. The forces that shape the embryo, 2nd ed. Englewood, NJ: Prentice-Hall Inc.; 1984:131
Utter, M. F. The biochemistry of manganese. Med. Clin. N. Am. 60:713–727; 1976.
Vasiliev, J. M.; Gelfand, I. M. Neoplastic and normal cells in culture. Cambridge, UK: Cambridge University Press; 1981:13.
Yasuda, K. Studies on the factors affecting cellular spreading upon culture-substrate. I. The effects of divalent cations and conditioned medium on cellular spreading. J. Cell Sci. 15:269–278; 1974.
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This work was supported in part by Public Health Service grant CA34470-01 (KSS) awarded by the National Cancer Institute, Bethesda, Md.