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Na transport compartment in rabbit urinary bladder

  • Transport Processes, Metabolism and Endocrinology; Kidney, Gastrointestinal Tract, and Exocrine Glands
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Abstract

Electron microprobe analysis was used to determine cellular electrolyte concentrations in rabbit urinary bladder. Under control conditions the mean cellular electrolyte concentrations were for Na 11.6±2.0, for K 124.1±15.3, and for Cl 26.0±5.1 mmol/kg wet weight. The dry weight content was 19.0±2.0 g/100 g. Inhibition of the Na/K-pump with ouabain resulted in drastic changes of the cellular element concentrations. Similar changes also occurred when in addition to ouabain the apical side was kept Na-free. In all epithelial layers the Na and Cl concentrations increased by 90 and 30 mmol/kg wet weight, whereas the K concentration and the dry weight content decreased by 90 mmol/kg wet weight and 6 g/100 g wet weight, respectively. With Na-free choline-Ringer's solution on the basal side ouabain led to a decrease in the K concentration by about 60 mmol/kg wet weight while the Na and Cl concentrations remained unchanged. These data indicate that the basolateral membrane is permeable to Na, choline, Cl, and K. Nystatin produced drastic changes in the cellular electrolyte concentrations when Na- or Rb-sulfate Ringer's solutions were present on the apical side. With Na-sulfate Ringer's solution the Na concentration increased by about 25, the Cl concentration by 30 mmol/kg wet weight and the dry weight content decreased by 4.5 g/100 g, respectively. With Rb-Ringer's solution about 20 mmol/kg wet weight of the cellular K was exchanged against Rb. The concentration changes were identical in all epithelial layers supporting the idea that the rabbit urinary bladder represents a functional syncytium with regard to the transepithelial Na transport.

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References

  1. Bauer R, Rick R (1978) Computer analysis of X-ray spectra (EDS) from thin biological specimens. X-ray Spectrom 7:63–69

    Google Scholar 

  2. Beck F, Bauer R, Bauer U, Mason J, Dörge A, Rick R, Thurau K (1980) Electron microprobe analysis of intracellular elements in the rat kidney. Kidney Int 17:756–763

    Google Scholar 

  3. Beck F, Dörge A, Mason J, Rick R, Thurau K (1982) Element concentrations of renal and hepatic cells under potassium depletion. Kidney Int 22:250–256

    Google Scholar 

  4. Clausen C, Lewis SA, Diamond JM (1979) Impedance analysis of a tight epithelium using a distributed resistance model. Biophys J 26:291–318

    Google Scholar 

  5. DeLong J, Civan MM (1983) Microelectrode study of K+ accumulation of tight epithelia. I. Baseline values of split frog skin and toad urinary bladder. J Membr Biol 72:183–193

    Google Scholar 

  6. Dörge A, Rick R, Gehring K, Thurau K (1978) Preparation of freeze-dried cryosections for quantitative X-ray microanalysis of electrolytes in biological soft tissues. Pflügers Arch 373: 85–97

    Google Scholar 

  7. Eaton DC (1981) Intracellular sodium ion activity and sodium transport in rabbit urinary bladder. J Physiol 316:527–544

    Google Scholar 

  8. Eaton DC, Frace AM, Silverthorn SU (1982) Active and passive Na+ fluxes across the basolateral membrane of rabbit urinary bladder. J Membr Biol 67:219–229

    Google Scholar 

  9. Edelman A, Curci S, Samarzija I, Frömter E (1978) Determination of intracellular K+ activity in rat kidney proximal tubule cells. Pflügers Arch 378:37–45

    Google Scholar 

  10. Koefoed-Johnsen V, Ussing HH (1958) The nature of the frog skin potential. Acta Physiol Scand 42:298–308

    Google Scholar 

  11. Jehl B, Bauer R, Dörge A, Rick R (1981) The use of propane/isopentane mixtures for rapid freezing of biological specimens. J Microscop 123:307–309

    Google Scholar 

  12. Lewis SA, Diamond JM (1976) Na transport by rabbit urinary bladder, a tight epithelium. J Membr Biol 28:1–40

    Google Scholar 

  13. Lewis SA, Hanrahan JW (1985) Apical and basolateral membrane ionic channels in rabbit urinary bladder epithelium. Pflügers Arch 405:S83-S88

    Google Scholar 

  14. Lewis SA, Wills NK (1979) Intracellular ion activities and their relationship to membrane properties of tight epithelia. Fed Proc 38:2739–2742

    Google Scholar 

  15. Lewis SA, Wills NK (1983) Apical membrane permeability and kinetic properties of the sodium pump in rabbit urinary bladder. J Physiol 341:169–184

    Google Scholar 

  16. Lewis SA, Eaton DC, Diamond JM (1976) The mechanism of Na+ transport by rabbit urinary bladder. J Membr Biol 28:41–70

    Google Scholar 

  17. Lewis SA, Eaton DC, Clausen C, Diamond JM (1977) Nystatin as a probe for investigating the electrical properties of a tight epithelium. J Gen Physiol 70:427–440

    Google Scholar 

  18. Lewis SA, Wills NK, Eaton DC (1978) Basolateral membrane potential of a tight epithelium: ionic diffusion and electrogenic pumps. J Membr Biol 41:117–148

    Google Scholar 

  19. Reuss L, Reinach P, Weinman SA, Grady TP (1983) Intracellular ion activities and Cl-transport mechanisms in bullfrog corneal epithelium. Am J Physiol 244:C336-C347

    Google Scholar 

  20. Rick R, Dörge A, von Arnim E, Thurau K (1978a) Electron micropobe analysis of frog skin epithelium: evidence for a syncytial sodium transport compartment. J Membr Biol 39: 313–331

    Google Scholar 

  21. Rick R, Dörge A, Macknight ADC, Leaf A, Thurau K (1978b) Electron microprobe analysis of the different epithelial cells of toad urinary bladder. J Membr Biol 39:257–271

    Google Scholar 

  22. Rick R, Dörge A, Katz U, Bauer R, Thurau K (1980) The osmotic behavior of toad skin epithelium. Pflügers Arch 385:1–10

    Google Scholar 

  23. Rick R, Dörge A, Thurau K (1982) Quantitative analysis of electrolytes in frozen dried sections. J Microsc 125:239–247

    Google Scholar 

  24. Rick R, Beck FX, Dörge A, Thurau K (1985) Cl transport in the frog cornea: an electron microprobe analysis. J Membr Biol 83:235–250

    Google Scholar 

  25. Wills NK (1981) Antibiotics as tools for studying the electrical properties of tight epithelia. Fed Proc 40:2202–2205

    Google Scholar 

  26. Wills NK, Lewis SA (1980) Intracellular Na+ activity as a function of Na+ transport rate across a tight epithelium. Biophys J 30:181–186

    Google Scholar 

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Authors and Affiliations

  1. Physiologisches Institut der Universität München, Pettenkoferstrasse 12, D-8000, München 2, Federal Republic of Germany

    Adolf Dörge, Peter Wienecke, Franz Beck, Brigitte Wörndl & Klaus Thurau

  2. Medical School, Department of Physiology and Biophysics, University of Alabama in Birmingham, University Station, 35294, Birmingham, AL, USA

    Roger Rick

Authors
  1. Adolf Dörge
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  2. Peter Wienecke
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  3. Franz Beck
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  4. Brigitte Wörndl
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  5. Roger Rick
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  6. Klaus Thurau
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Dörge, A., Wienecke, P., Beck, F. et al. Na transport compartment in rabbit urinary bladder. Pflugers Arch. 411, 681–687 (1988). https://doi.org/10.1007/BF00580866

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  • DOI: https://doi.org/10.1007/BF00580866

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