Subcellular distribution of ouabain and changes in NaK ATPase activity in relation to the pharmacological effects of ouabain in dog : effects of DPH and KCl infusion /

Rhee, Hee Min

January 1973

No description available.

Health Sciences

Digitalis

Quabain

Subcellular distribution of ouabain and changes in NaK ATPase activity in relation to the pharmacological effects of ouabain in dog : effects of DPH and KCl infusion /

Rhee, Hee Min

January 1973

No description available.

Health Sciences

Digitalis

Quabain

Hepatocyte Water Volume and Potassium Activity During Hypotonic Stress

Wang, Kening, Wondergem, Robert

01 August 1993

Hepatocytes exhibit a regulatory volume decrease (RVD) during hypotonic shock, which comprises loss of intracellular K+ and Cl- accompanied by hyperpolarization of transmembrane potential (Vm) due to an increase in membrane K+ conductance, (GK). To examine hepatocyte K+ homeostasis during RVD, double-barrel, K+-selective microelectrodes were used to measure changes in steady-state intracellular K+ activity (aKi) and Vm during hyposmotic stress. Cell water volume change was evaluated by measuring changes in intracellular tetramethylammonium (TMA+). Liver slices were superfused with modified Krebs physiological salt solution. Hyposmolality (0.8×300 mosm) was created by a 50 m m step-decrease of external sucrose concentration. Hepatocyte Vm hyperpolarized by 19 mV from -27 ± 1 to -46 ± 1 mV and aKidecreased by 14% from 91 ± 4 to 78 ± 4 m m when slices were exposed to hyposmotic stress for 4-5 min. Both Vm and aKireturned to control level after restoring isosmotic solution. In paired measurements, hypotonic stress induced similar changes in Vm and aKiboth control and added ouabain (1 m m) conditions, and these values returned to their control level after the osmotic stress. In another paired measurement, hypotonic shock first induced an 18-mV increase in Vm and a 15% decrease in aKiin control condition. After loading hepatocytes with TMA+, the same hypotonic shock induced a 14-mV increase in Vm and a 14% decrease in aTMAi. This accounted for a 17% increase of intracellular water volume, which was identical to the cell water volume change obtained when aKiwas used as the marker. Nonetheless, hyposmotic stress-induced changes in Vm and aKiwere blocked partly by Ba2+ (2 m m). We conclude that (i) hepatocyte Vm increases and aKidecreases during hypotonic shock; (ii) the changes in hepatocyte Vm and aKiduring and after hypotonic shock are independent of the Na+-K+ pump; (iii) the decrease in aKiduring hypotonic stress results principally from hepatocyte swelling.

intracellular K +

ion-sensitive microelectrodes

membrane potential

osmotic stress

quabain