1. Osmotic properties of internally perfused barnacle muscle cells. I. Isosmotic conditions.
- Author
-
Bitner JB, Peña-Rasgado C, Ruiz J, Cardona J, and Rasgado-Flores H
- Subjects
- Animals, Osmosis physiology, Perfusion methods, Water metabolism, Cell Size physiology, Muscles metabolism, Osmolar Concentration, Thoracica physiology
- Abstract
Barnacle muscle cells regulate their volume when exposed to anisotonic conditions. Due to their large size, these cells can be internally perfused. Interestingly, perfused cells maintain their volume regulatory properties (17,21). Thus, the osmotic properties of barnacle muscle cells can be studied under conditions in which the intracellular and extracellular osmolalities, the membrane potential (V(M)), the cell volume and the intracellular pressure can all be measured simultaneously. In this manuscript we report the effect that various rates of isosmotic (1000 mOsm x kg H2O(-1)) intracellular perfusion have on cell volume, intracellular pressure, intracellular osmolality, V(M), and the apparent sarcolemmal hydraulic water permeability (L'p). Replacement of the cytosol with the perfusate at a perfusion rate of 0.83 microl x min(-1) took 120 min. During this transition period, the cell volume increased from 45.1+/-6.9 microl to 73.7+/-5.8 microl, the intracellular osmolality decreased from 1406+/-133 to 1188+/-64 mOsm x kg H2O(-1), and the intracellular pressure underwent a transient drop of 2.8 cm H2O. After 2.5 hr of continuous perfusion at 0.83 microl min(-1), the above mentioned parameters reached steady values: the L'p was 1.35 x 10(-5) cm x sec(-1) x Osm(-1) x kg H2O(-1); cell volume was 67.2+/-6 microl; the intracellular osmolality was 1052+/-10 mOsm x kg H2O(-1); the intracellular pressure was 5.6+/-0.4 cm H2O; V(M) depolarized slowly at a rate of 0.03 mV x min(-1). Stepwise increases in the rate of perfusion (from 0.83 to 3.18 microl min(-1)) produced reversible increases in the intracellular pressure, L'p and cell volume and decreases in intracellular osmolality. We conclude that intracellular perfusion: i/ produces a transient removal of intracellular osmotically active components; ii/ promotes sarcolemmal water filtration; iii/ induces a laminar flow of perfusate at the center of the cell, and iv/ enables calculations of sarcolemmal L'p values under isosmotic conditions.
- Published
- 2001