The botanical magazine = Shokubutsu-gaku-zasshi

, Volume 88, Issue 3, pp 219–229 | Cite as

Cytoplasmic streaming and ionic regulation inNitella flexilis having artificial cell saps of low ionic strength

  • Masashi Tazawa
Article
Received:

Abstract

The cell sap of the internode ofNitella flexilis was replaced with the isotonic artificial pond water of high Ca2+-concentration (0.1 mM KCl, 0.1 mM NaCl, 10 mM CaCl2 and 275 mM mannitol) and changes in osmotic value and concentrations of K+, Na+ and Cl of the cells were followed. When the operated cells were incubated in the artificial pond water containing 0.1 mM each of KCl, NaCl, CaCl2, they survived for only a short period of time (<10 hr). The cells did not absorb ions from the artificial pond water and showed a conspicuous decrease in the rate of cytoplasmic streaming. In such cell the concentration of K+ in the protoplasm decreased significantly.

In order to reverse normal concentration gradients of K+ and Na+ across the protoplasmic layer, the cells of low vacuolar ionic concentrations were incubated in the artificial cell sap (90 mM KCl, 40 mM NaCl, 15 mM CaCl2, 10 mM MgCl2). It was found that the cells rapidly absorbed much K+, Na+ and Cl and survived for a longer period (1–2 days). During this period the rate of cytoplasmic streaming was nearly normal. Furthermore, the cell lost much mannitol, indicating an enormous increase in permeability to it. Since both absorption of ions and leakage of mannitol at 1 C occurred at nearly the same rates as at 22 C, the processes are assumed to be passive.

Keywords

Mannitol External Medium Ionic Regulation Cytoplasmic Streaming Bathing Medium 
These keywords were added by machine and not by the authors. This process is experimental and the keywords may be updated as the learning algorithm improves.
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References

  1. Blinks, L.R. 1935. Protoplasmic potentials inHalicystis. IV. Vacuolar perfusion with artifiical and sea water. J. Gen. Physiol.18: 409–420.CrossRefGoogle Scholar
  2. Blount, R.W. andB.H. Levedahl. 1960. Active sodium and chloride transport in the single celled marine algaHalicystis ovalis. Acta Physiol. Scand.49: 1–9.PubMedCrossRefGoogle Scholar
  3. Dainty, J. 1962. Ion transport and electrical potentials in plant cells. Ann. Rev. Plant Physiol.13: 379–402.CrossRefGoogle Scholar
  4. —. 1964. The permeability of the cell membranes ofNitella translucens to urea, and the effect of high concentrations of sucrose on permeability. Biochim. Biophys. Acta79: 112–121.PubMedGoogle Scholar
  5. Gutknecht, J. 1967. Ion fluxes and short-circuit current in internally perfused cells ofValonia ventricosa. J. Gen. Physiol.50: 1821–1834.PubMedCrossRefGoogle Scholar
  6. Kamiya, N. andM. Tazawa. 1966. Surgical operations on Characean cells with special reference to cytoplasmic streaming. Ann. Rep. Biol. Works, Fac. Sci., Osaka Univ.14: 95–106.Google Scholar
  7. Kishimoto, U. 1965. Voltage clamp and internal perfusion studies onNitella internodes. J. Cell. Comp. Physiol.66: 43–54.CrossRefGoogle Scholar
  8. —. 1965. Plasmalemma potential inNitella. Plant & Cell Physiol.6: 519–528.Google Scholar
  9. —. 1965. Ionic composition of the cytoplasm ofNitella flexilis. Plant & Cell Physiol.6: 507–518.Google Scholar
  10. Nakagawa, S., H. Kataoka andM. Tazawa. 1974. Osmotic and ionic regulation inNitella. Plant & Cell Physiol.15: 457–468.Google Scholar
  11. Strunk, T.H. 1970. Vacuolar perfusion technique forNitella internodal cells. Science169: 84–87.PubMedGoogle Scholar
  12. —. 1971. Correlation between metabolic parameters of transport and vacuolar perfusion results inNitella clavata. J. Exp. Bot.22: 863–874.Google Scholar
  13. Tazawa, M. 1957. Neue Methode zur Messung des osmotischen Wertes einer Zelle. Protoplasma48: 342–359.CrossRefGoogle Scholar
  14. —. 1964. Studies onNitella having artificial cell sap. I. Replacement of the cell sap with artificial solutions. Plant & Cell Physiol.5: 33–43.Google Scholar
  15. —. 1968. Motive force of the cytoplasmic streaming inNitella. Protoplasma65: 207–222.PubMedCrossRefGoogle Scholar
  16. —. 1975. Open-vacuole method for measuring membrane potential and membrane resistance of Characeae cells. Plant & Cell Physiol.16: 611–621.Google Scholar
  17. —. 1964. Studies onNitella having artificial cell sap. II. Rate of cyclosis and electric potential. Plant & Cell Physiol.5: 45–59.Google Scholar
  18. ——. 1974. Potassium, sodium and chloride in the protoplasm of Characeae. Plant & Cell Physiol.15: 103–110.Google Scholar
  19. —. 1966. Studies on osmoregulation ofNitella internode with modified cell saps. Z. Pflanzenphysiol.54: 333–344.Google Scholar

Copyright information

© The Botanical Society of Japan 1975

Authors and Affiliations

  • Masashi Tazawa
    • 1
  1. 1.Department of Biology, Faculty of ScienceOsaka UniversityToyonaka, Osaka

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