The Na+, K+, and Cl- Content of Goose Salt Gland Slices and the Effects of Acetylcholine and Ouabain

In goose salt gland slices incubated in bicarbonate-buffered medium which contained 170 mEq of Na+/liter, net total tissue Na+, expressed as milliequivalents per kilogram, was, in the presence of either acetylcholine (plus eserine) or ouabain, significantly higher than that of the bathing fluid. Acetylcholine caused an increase in the tissue Na+ content as compared with untreated slices; there was an approximately equivalent decrease in K+ and a significant decrease in Cl-. The calculated net intracellular concentrations of Na+, expressed as milliequivalents per liter of intracellular water, in unstimulated, acetylcholine-stimulated, and ouabain-treated slices were 2.1, 3.1, and 2.7 times higher, respectively, than the concentration of Na+ in the bathing fluid. The net intracellular concentration of Na+, expressed as milliequivalents per liter of intracellular water, in slices incubated in the presence of acetylcholine was 531 mEq/liter; this is approximately the same as the concentration of Na+ in the secreted fluid of the goose salt gland (515 mEq/liter). The results indicate that the main concentration gradient for Na+ could be established across the basal membrane. The data do not indicate whether this involves active transport of Na+ per se. A second stage which might involve Na-K ATPase activity at the luminal membrane is discussed. The sum of the total tissue Na+ and K+ was approximately 250 mEq/kg, whereas the Cl- content was only approximately 130 mEq/kg.

[1]  L. Hokin,et al.  The Formation and Continuous Turnover of a Fraction of Phosphatidic Acid on Stimulation of NaCl Secretion by Acetylcholine in the Salt Gland , 1967, The Journal of general physiology.

[2]  M. R. Hokin Respiration and ATP and ADP levels during Na+ transport in salt gland slices. , 1966, Life sciences.

[3]  E. Schoffeniels,et al.  The ionic composition of rat aortic smooth muscle fibres. , 1965, Archives internationales de physiologie et de biochimie.

[4]  G. V. Rossum Measurements of respiratory pigments and sodium efflux in slices of avian salt-gland , 1964 .

[5]  N. M. Hawkins,et al.  STUDIES ON SODIUM-POTASSIUM-ACTIVATED ADENOSINETRIPHOSPHATASE. XI. THE SALT GLAND OF THE HERRING GULL. , 1964, Archives of biochemistry and biophysics.

[6]  K. Schmidt-Nielsen,et al.  Respiration of avian salt-secreting gland in tissue slice experiments. , 1963, The American journal of physiology.

[7]  M. R. Hokin STUDIES ON A NA+ + K+-DEPENDENT, OUABAIN-SENSITIVE ADENOSINE TRIPHOSPHATASE IN THE AVIAN SALT GLAND. , 1963, Biochimica et biophysica acta.

[8]  D. Fawcett Physiologically Significant Specializations of the Cell Surface , 1962, Circulation.

[9]  K. Schmidt-Nielsen,et al.  An electrophysiological study of the salt gland of the herring gull. , 1962, The American journal of physiology.

[10]  W. Doyle The principal cells of the salt-gland of marine birds. , 1960, Experimental cell research.

[11]  L. Hokin,et al.  Studies on the Carrier Function of Phosphatidic Acid in Sodium Transport , 1960, The Journal of general physiology.

[12]  K. Schmidt-Nielsen,et al.  Control of secretion from the avian salt gland. , 1958, The American journal of physiology.

[13]  Knut Schmidt-Nielsen,et al.  THE SALT GLAND OF THE HERRING GULL , 1958 .

[14]  K. Schmidt-Nielsen,et al.  Extrarenal salt excretion in birds. , 1958, The American journal of physiology.

[15]  J C SKOU,et al.  The influence of some cations on an adenosine triphosphatase from peripheral nerves. , 1957, Biochimica et biophysica acta.

[16]  O. Schales,et al.  A SIMPLE AND ACCURATE METHOD FOR THE DETERMINATION OF CHLORIDE IN BIOLOGICAL FLUIDS , 1941 .