Role of renocortical cyclooxygenase-2 for renal vascular resistance and macula densa control of renin secretion.
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This study aimed to assess the role of cyclooxygenase-2 (COX-2)-derived prostanoids for the macula densa control of renal afferent arteriolar resistance and for renin secretion. For this purpose, studied were the effects of blocking macula densa salt transport by the loop diuretic bumetanide (100 microM) on renal perfusate flow and on renin secretion in isolated perfused rats, in which renocortical COX-2 expression was prestimulated in vivo by treatment with the angiotensin-converting enzyme inhibitor ramipril, with low-salt diet, or with a combination of both. These maneuvers stimulated COX-2 expression in an order of ramipril + low salt>> low salt > ramipril > controls. Flow rates through isolated kidneys at a constant pressure of 100 mmHg were dependent on the pretreatment regimen, in the way that they went in parallel with COX-2 expression. The COX-2 inhibitor NS-398 (10 microM) lowered flow rates depending on the COX-2 expression level and was most pronounced therefore after pretreatment with low salt + ramipril. NS-398 did not change the increase of flow in response to bumetanide but attenuated the stimulation of renin secretion in response to bumetanide in a manner depending on the expression level of COX-2. These findings suggest that in states of increased renocortical expression of COX-2, overall renal vascular resistance and the macula densa control of renin secretion become dependent on COX-2-derived prostanoids. (+info)
Endogenous and exogenous Na-K-Cl cotransporter expression in a low K-resistant mutant MDCK cell line.
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A low K-resistant mutant Madin-Darby canine kidney (MDCK) cell line, LK-C1, has been shown previously to lack functional Na-K-Cl cotransporter (NKCC) activity, indicating that it may be a useful NKCC "knockout" cell line for structure-function studies. Using immunological probes, we first characterized the defect in the endogenous NKCC protein of the LK-C1 cells and then fully restored NKCC activity in these cells by stably expressing the human secretory NKCC1 protein (hNKCC1). The endogenous NKCC protein of the LK-C1 cells was expressed at significantly lower levels than in wild-type MDCK cells and was not properly glycosylated. This latter finding indicated that the lack of functional NKCC activity in the LK-C1 cells may be due to the inability to process the protein to the plasma membrane. In contrast, exogenously expressed hNKCC1 protein was properly processed and fully functional at the plasma membrane. Significantly, the exogenous hNKCC1 protein was regulated in a manner similar to the protein in native secretory cells as it was robustly activated by cell shrinkage, calyculin A, and low-Cl incubation. Furthermore, when the LK-C1 cells formed an epithelium on permeable supports, the exogenous hNKCC1 protein was properly polarized and functional at the basolateral membrane. The low levels of endogenous NKCC protein expression, the absence of any endogenous NKCC transport activity, and the ability to form a polarized epithelium indicate that the LK-C1 cells offer an excellent expression system with which to study the molecular physiology of the cation Cl cotransporters. (+info)
K(+) transport in red blood cells from human umbilical cord.
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The current study was designed to characterise K(+) transport in human fetal red blood cells, containing mainly haemoglobin F (HbF, and termed HbF cells), isolated from umbilical cords following normal parturition. Na(+)/K(+) pump activity was comparable to that in normal adult human red cells (which contain HbA, and are termed HbA cells). Passive (ouabain-resistant) K(+) transport was dominated by a bumetanide (10 microM)-resistant component, inhibited by [(dihydroxyindenyl)oxy]alkanoic acid (100 microM), calyculin A (100 nM) and Cl(-) removal, and stimulated by N-ethylmaleimide (1 mM) and staurosporine (2 microM) - all consistent with mediation via the K(+)-Cl(-) cotransporter (KCC). KCC activity in HbF cells was also O(2)-dependent and stimulated by swelling and urea, and showed a biphasic response to changes in external pH. Peak activity of KCC in HbF cells was about 3-fold that in HbA cells. These characteristics are qualitatively similar to those observed in HbA cells, notwithstanding the different conditions experienced by HbF cells in vivo, and the presence of HbF rather than HbA. KCC in HbF cells has a higher total capacity, but when measured at the ambient PO(2) of fetal blood it would be similar in magnitude to that in fully oxygenated HbA cells, and about that required to balance K(+) accumulation via the Na(+)/K(+) pump. These findings are relevant to the mechanism by which O(2) regulates membrane transporters in red blood cells, and to the strategy of promoting HbF synthesis as a therapy for patients with sickle cell disease. (+info)
Epinephrine-induced increases in [Ca2+](in) and KCl-coupled fluid absorption in bovine RPE.
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PURPOSE: To define the ionic basis for the apical epinephrine-induced increase of fluid absorption (J(V)) across isolated bovine RPE-choroid. METHODS: Epinephrine-induced changes in RPE [Ca2+](in) levels were monitored with the ratioing dye fura-2. Transepithelial potential, resistance, and unidirectional fluxes of (36)Cl, (86)Rb (K substitute), and (22)Na were simultaneously determined in paired tissues from the same eye mounted in modified Ussing flux chambers. Radioisotopes (5-7 microCi) were added to the apical bath of one tissue and the basal bath of the other, and the appearance of label in the opposite bath was measured. RESULTS: Apical epinephrine (100 nM) transiently increased [Ca2+](in) by 153 +/- 78 nM. This increase was inhibited by the alpha(1)-adrenoreceptor antagonist prazosin (1 microM) and blocked by CPA(5 microM), an inhibitor of endoplasmic reticulum Ca2+-adenosine triphosphatases (ATPases). Apical epinephrine (100 nM) more than doubled the net Cl absorption rate, increased net K ((86)Rb) absorption by fivefold, and tripled net fluid absorption (J(V)), as predicted by isotonic coupling between ion and fluid transport. The epinephrine-induced increases in ion and fluid transport were completely inhibited by apical bumetanide (100 microM). CONCLUSIONS: Epinephrine increased fluid absorption across bovine RPE by activating apical membrane alpha(1)-adrenergic receptors, increasing [Ca2+](in), and stimulating bumetanide-sensitive Na,K,2Cl uptake at the apical membrane and KCl efflux at the basolateral membrane. (+info)
Optical method for quantifying rates of mucus secretion from single submucosal glands.
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We describe an optical method to quantify single- gland secretion. Isolated tracheal mucosa were mounted at the air-Krebs interface and coated with oil. Gland secretions formed spherical bubbles that were digitally imaged at intervals, allowing rates of secretion to be calculated. We monitored 340 glands in 54 experiments with 12 sheep. Glands secreted basally at low rates (0.57 +/- 0.04 nl x min(-1) x gland(-1), 123 glands) in tissues up to 9 h postharvest and at lower rates for up to 3 days. Carbachol (10 microM) stimulated secretion with an early transient and a sustained or oscillating phase. Peak secretion was 15.7 +/- 1.2 nl x min(-1) x gland(-1) (60 glands); sustained secretion was 4.5 +/- 0.5 nl x min(-1) x gland(-1) (10 glands). Isoproterenol and phenylephrine (10 microM each) stimulated only small, transient responses. We confirmed that cats have a large secretory response to phenylephrine (11.6 +/- 3.7 nl x min(-1) x gland(-1), 12 glands), but pigs, sheep, and humans all have small responses (<2 nl x min(-1)m x gland(-1)). Carbachol-stimulated peak secretion was inhibited 56% by bumetanide, 67% by HCO replacement with HEPES, and 92% by both. The distribution of secretion rates was nonnormal, suggesting the existence of subpopulations of glands. (+info)
Contractile regulation of the Na(+)-K(+)-2Cl(-) cotransporter in vascular smooth muscle.
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Vasoconstrictors activate the Na(+)-K(+)-2Cl(-) cotransporter NKCC1 in rat aortic smooth muscle, but the mechanism is unknown. Efflux of (86)Rb(+) from rat aorta in response to phenylephrine (PE) was measured in the absence and presence of bumetanide, a specific inhibitor of NKCC1. Removal of extracellular Ca(2+) completely abolished the activation of NKCC1 by PE. This was not due to inhibition of Ca(2+)-dependent K(+) channels since blocking these channels with Ba(2+) in Ca(2+)-replete solution did not prevent activation of NKCC1 by PE. Stimulation of NKCC1 by PE was inhibited 70% by 75 microM ML-9, 97% by 2 microM wortmannin, and 70% by 2 mM 2,3-butanedione monoxime, each of which inhibited isometric force generation in aortic rings. Bumetanide-insensitive Rb(+) efflux, an indication of Ca(2+)-dependent K(+) channel activity, was reduced by ML-9 but not by the other inhibitors. Stretching of aortic rings on tubing to increase lumen diameter to 120% of normal almost completely blocked the stimulation of NKCC1 by PE without inhibiting the stimulation by hypertonic shrinkage. We conclude that activation of the Na(+)-K(+)-2Cl(-) cotransporter by PE is the direct result of smooth muscle contraction through Ca(2+)-dependent activation of myosin light chain kinase. This indicates that the Na(+)-K(+)-2Cl(-) cotransporter is regulated by the contractile state of vascular smooth muscle. (+info)
Alterations in airway ion transport in NKCC1-deficient mice.
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Airways of Na(+)-K(+)-2Cl(-) (NKCC1)-deficient mice (-/-) were studied in Ussing chambers to determine the role of the basolateral NKCC1 in transepithelial anion secretion. The basal short-circuit current (I(sc)) of tracheae and bronchi from adult mice did not differ between NKCC1-/- and normal mice, whereas NKCC1-/- tracheae from neonatal mice exhibited a significantly reduced basal I(sc). In normal mouse tracheae, sensitivity to the NKCC1 inhibitor bumetanide correlated inversely with the age of the mouse. In contrast, tracheae from NKCC1-/- mice at all ages were insensitive to bumetanide. The anion secretory response to forskolin did not differ between normal and NKCC1-/- tissues. However, when larger anion secretory responses were induced with UTP, airways from the NKCC1-/- mice exhibited an attenuated response. Ion substitution and drug treatment protocols suggested that HCO secretion compensated for reduced Cl(-) secretion in NKCC1-/- airway epithelia. The absence of spontaneous airway disease or pathology in airways from the NKCC1-/- mice suggests that the NKCC1 mutant mice are able to compensate adequately for absence of the NKCC1 protein. (+info)
Effects of the potassium channel blocker barium on sodium and potassium transport in the rat loop of Henle in vivo.
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In vitro evidence suggests that the 'recycling' of K(+) ions through luminal K(+) channels in the thick ascending limb of the loop of Henle (TALH) is essential for the normal operation of the luminal Na(+)-K(+)-2Cl(-) co-transporter. In the present study these channels were investigated in vivo by perfusing superficial loops of Henle in anaesthetised rats with and without the K(+) channel blocker barium. Using a standard perfusate, intraluminal barium (5 mmol l(-1)) reduced sodium reabsorption (J(Na)) from 1887 +/- 50 to 1319 +/- 53 pmol min(-1) (P < 0.001). When the experiment was repeated using a low-Na(+) perfusate, designed to inhibit reabsorption in the pars recta (the initial segment of the loop of Henle), a similar reduction in J(Na) was observed (from 698 +/- 47 to 149 +/- 23 pmol min(-1), P < 0.001), strongly suggesting that the effect of barium is localised to the TALH. The magnitude of the reduction in J(Na) during blockade of K(+) channels confirms the importance of K(+) recycling in facilitating Na(+) reabsorption in the TALH in vivo. However, the reduction in J(Na) was not associated with a fall in the K(+) concentration of the fluid collected at the early distal tubule. When bumetanide, an inhibitor of the Na(+)-K(+)-2Cl(-) co-transporter, was included in the low-Na(+) perfusate, net K(+) secretion was observed. Addition of barium to this perfusate reduced, but did not abolish, the secretion, suggesting that bumetanide-induced K(+) secretion results partly from paracellular transport. Experimental Physiology (2001) 86.4, 469-474. (+info)