S. N. Ayrapetyan scite author profile

The dependence of electrogenic sodium pump activity on changes in the cell volume of Helix pomatia neurons with different levels of intracellular sodium ion concentration was studied. Hypertonic solutions caused hyperpolarization of the membrane and increased membrane resistance in cells with a low sodium content (low-sodium cells; LSC). The activity of the electrogenic sodium pump in hypertonic solutions was increased compared to the activity in hypotonic solutions in LSC and decreased in cells with a high sodium content (high-sodium cells; HSC). The concentration of ouabain which led to maximal inhibition of active 22Na efflux from the neurons was 10(-4) M. Lower concentrations of ouabain (10(-8) M and lower) did not inhibit the sodium pump but stimulated it. The swelling of neurons in hypotonic solutions was accompanied by an increase in the number of binding sites for ouabain, while shrinking in hypertonic solutions led to the opposite effect--a decrease in binding sites. An increase in the number of binding sites also took place in normal isotonic potassium-free solutions compared with normal Ringer's solution. Two saturable components of ouabain binding were detectable in all solutions examined. gamma-Aminobutyric acid (GABA) and acetylcholine (ACh) increased the number of ouabain binding sites on the membrane. The results suggest that there are two opposite mechanisms by which cell volume changes can modulate the pump activity. One of them depends on the intracellular sodium ion concentration and causes pump activation in hypertonic solutions in LSC and saturation in HSC, while a second mechanism mediates the activating effect of cell swelling on the sodium pump in HSC. In addition, there may be a negative feedback between the pump activity and the number of functioning pump units in the membrane.

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On the mechanism of the electrogenic sodium pump dependence of membrane chemosensitivity

Ayrapetyan¹,

Arvanov²

1979

Comparative Biochemistry and Physiology Part A: Physiology

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Changes of hydration of rats' tissues after in vivo exposure to 0.2 Tesla steady magnetic field

Danielyan

Ayrapetyan

1999

Bioelectromagnetics

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Hydration and [3H]ouabain uptake by different tissues of adult male rats were measured immediately after exposure to homogenous 0.2 T steady magnetic field. A time‐dependent decrease of hydration and adaptation, followed by disadaptation, was detected in brain and liver tissues in most of the rats after 3.5–5 h of exposure. The number of functional active ouabain binding receptors, which correlates with cell volume, was also decreased in brain, liver, and spleen and increased in kidney tissue after half an hour of exposure. It is suggested that cell hydration is a second messenger through which the SMF exerts its influence. Bioelectromagnetics 20:123–128, 1999. © 1999 Wiley‐Liss, Inc.

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The effects of cAMP, Ca2+, and phorbol esters on ouabain-induced depression of acetylcholine responses inHelix neurons

1992

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1. Using internal perfusion and concentration-clamp procedures applied to Helix neurons, the effects of cAMP, Ca2+, and phorbol esters on ouabain-induced depression of acetylcholine Cl-dependent responses were determined. 2. Intracellular cAMP (10(-4) M) depressed those acetylcholine responses which were blocked by ouabain but had no effect on ouabain-insensitive acetylcholine responses. In the presence of elevated intracellular cAMP, ouabain had no further depressant effect on these acetylcholine responses. Both elevated cAMP and ouabain reduced the acetylcholine response without altering the current-voltage curves. 3. An increase in intracellular Ca2+ concentration depressed the amplitude of current induced by application of acetylcholine in neurons with ouabain-sensitive responses and shifted the dose-response relationship to the right. However, elevated Ca2+ did not reduce the maximal response induced by acetylcholine, nor did it prevent the reduction of that response by ouabain. 4. 12-O-Tetradecanoylphorbol-13-acetate (TPA), a potent stimulator of protein kinase C activity, caused depression of both the ouabain-sensitive and the ouabain-insensitive acetylcholine responses. The inhibitory effect of TPA was markedly enhanced after addition of ATP to the intracellular medium and was greatly reduced by cooling to 5 degrees C. The blocking effect of ouabain, however, reexamined in the presence of TPA. 5. These observations are consistent with the hypothesis that the depression of acetylcholine induced Cl--responses in Helix neurons is a result of an increase in intracellular cAMP concentration but is unrelated to activation of protein kinase C or increases in intracellular Ca2+.

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S. N. Ayrapetyan

Autoregulation of the electrogenic sodium pump

On the mechanism of the electrogenic sodium pump dependence of membrane chemosensitivity

Changes of hydration of rats' tissues after in vivo exposure to 0.2 Tesla steady magnetic field

The effects of cAMP, Ca2+, and phorbol esters on ouabain-induced depression of acetylcholine responses inHelix neurons

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