Activity of cAMP-dependent protein kinases and cAMP-binding proteins from rat renal cytosol upon dehydration

The activity of cAMP-dependent protein kinases, cAMP binding and the spectrum of cAMP-binding proteins in renal papillary cytosol of intact rats and of rats kept on a water-deprived diet for 24 hours were investigated. It was found that the stimulation of protein kinases by 10(-6) M cAMP in the experimental group was significantly higher than in the control one. On DEAE-cellulose chromatography, the position of peaks of the specific cAMP binding corresponded to those of the regulatory cAMP-dependent protein kinases type I and II. Under these conditions, more than 80% of the binding activity in intact animals was localized in peak II, whereas in rats kept on a water-deprived diet over 60% of the binding activity was localized in peak I. The total binding activity of cytosol in experimental animals remained unchanged is compared to intact rats. It is suggested that in renal papilla dehydration is accompanied by the induction of synthesis of regulatory subunits of cAMP-dependent protein kinase type I.     

Effect of dehydration and dDAVP on water permeability of basolateral membranes of epithelial cells in the kidney collecting tubules

Water permeability of the outer medullary collecting duct's (OMCD) basolateral membrane was determined in vitro in the tubules isolated from hyperhydrated or dehydrated Wistar rats. Oil was injected into the lumen to block apical membrane water permeability. OMCD fragments underwent a hypoosmic shock (600/300 mOsm) and epithelial cells volume increased ad recorded with a digital camera. The latter's rate was used to calculate apparent water permeability of the membrane (Pf). Treatment of the tubules with Hg2Cl2 suppressed the water permeability. Water deprivation and dDAVP induced an increase in the basolateral water permeability. The data obtained suggest that the water permeability of the OMCD basolateral membrane may be stimulated by vasopressin and water deprivation.     

G(i) proteins in regulation of water permeability of the rat kidney collecting tube epithelium cell membrane

Principal mechanism of the transepithelial water permeability increase in the kidney collecting ducts in response to vasopressin involves insertion of aquaporin 2 (AQP2) into the apical membrane. Previously we have shown that water permeability of the basolateral membrane also may be increased with stimulation of V2-receptors. It is known that inhibition of G(i)-proteins with pertussis toxin blocks redistribution of AQP2 into the apical membrane following the application of vasopressin or forskolin. The aim of the present study was to investigate potential involvement of G(i)-proteins in regulation of basolateral membrane water permeability. Effect of pertussis toxin on the ability of desmopressin to increase the basolateral membrane osmotic water permeability was investigated, and the expression of Galpha(i)2 and Galpha(i)3 genes under normal conditions and after 2 days of water deprivation were evaluated. We demonstrated that dehydration leds to a 30% increase of Galpha(i)3 mRNA content while the Galpha(i)2 mRNA level remains unchanged. In control experiments, basolateral membrane water permeability increased in response to desmopressin from 59.2 +/- 6.61 to 70.6 +/- 9.2 microm/s (p < 0.05, paired t-test). Pertussis toxin completely blocked this reaction (53.5 +/- 5.18 vs 50.1 +/- 6.50 microm/s, respectively). We conclude that G(i)-proteins participate in the mechanism of the basolateral membrane water permeability increase in response to stimulation of V2-receptors. Clarification of the G(i)-proteins role in this process requires further investigation, but most likely they are involved in regulation of aquaporin transport and insertion into the cell membrane.     

Role of water channels in the regulation of the volume of principal cells of rat kidney collecting ducts in hypoosmotic medium

The effect of plasma membrane water permeability on the rate of changes in the volume of principal cells of collecting ducts of the outer substantia medullaris under conditions of hypoosmotic shock has been studied. Changes in cell volume were studied by the fluorescent method. It was shown that the hypotonic shock induced a rapid increase in the cell volume with the characteristic time that depended on plasma membrane water permeability. The decrease in volume occurred much more slowly, and the rate of volume decrease directly correlated with the rate of swelling. The inhibition of potassium transport by barium chloride decreased the rate of volume restoration, without affecting substantially the duration of the swelling phase. The inhibition of mercury-sensitive water channels by mercury caused a significant increase in the time of both cell swelling and volume restoration. It was concluded that the state of water channels largely determines the rate of the regulatory response of epithelial cells of collecting ducts to hypoosmotic shock and affects the exchange of cell osmolites.     

Morphometric analysis of the effects of vasopressin in the rat kidney collecting tubules]

A significant increase in the water permeability was found in the rat outer medullary collecting duct (OMCD) cells in presence of 10-7M of vasopressin. The latter caused a decrease in the OMCD cell volume in isoosmotic medium in adult rats. In pups, the water permeability of the OMCD cells was very high. Vasopressin seems to be unable to decrease the cell volume of the OMCD cells in pups which suggests an immaturity of the cell transduction mechanism.     

A mathematical model of the response of principal cells of collecting ducts to hypotonic shock

The regulatory decrease in the volume of principal cells of collecting ducts to hypoosmotic shock has been investigated experimentally and using the mathematical modeling. A mathematical model of the response of collecting duct principal cells to hypotonic shock has been constructed on the basis of the experimental time course of changes in cell volume measured by the fluorescent dye Calcein. It was shown that the regulatory decrease in volume under hypotonic conditions occurs via a marked release of osmolytes and is accompanied by a decrease in water permeability of the cell membrane. The mathematical modeling of transmembrane transport processes allowed us to quantitatively estimate the changes in membrane water permeability, which decreased tenfold, from 2 x 10(-1) cm/s to 2 x 10(-2) cm/s. It was also shown that the effective regulatory decrease in the volume of collecting duct principal cells in hypotonic medium results from a significant increase in membrane permeability for K+, Cl-, and organic anions.     

Study of the reaction of kidney collecting duct principal cells to hypotonic shock. Experiment and mathematical model

The reaction of rat kidney collecting duct principal cells to hypotonic shock was studied. The changes in cell relative volume were measured using fluorescent dye calcein, and a mathematical model based on our experimental results was developed. It was shown that regulatory volume decrease is mainly provided by significant release of osmolytes from the cell and decrease of the plasma membrane water permeability. Using our model, we calculated the membrane water permeability and found it to decrease from 2 · 10⁻¹ to 2 · 10⁻² cm/s. We conclude that for effective RVD to occur, a dramatic increase in the membrane permeability to K⁺, Cl⁻ and organic anions is necessary.