A numerical model of the renal distal tubule.
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A numerical model of the rat distal tubule was developed to simulate water and solute transport in this nephron segment. This model incorporates the following: 1) Na-Cl cotransporter, K-Cl cotransporter, Na channel, K channel, and Cl channel in the luminal membrane; 2) Na-K-ATPase, K channel, and Cl channel in the basolateral membrane; and 3) conductances for Na, K, and Cl in the paracellular pathway. Transport rates were calculated using kinetic equations. Axial heterogeneity was represented by partitioning the model into two subsegments with different sets of model parameters. Model equations derived from the principles of mass conservation and electrical neutrality were solved numerically. Values of the model parameters were adjusted to minimize a penalty function that was devised to quantify the difference between model predictions and experimental results. The developed model could simulate the water and solute transport of the distal tubule in the normal state, as well as in conditions including thiazide or amiloride application and various levels of sodium load and tubular flow rate. (+info)
A kinetic model of the thiazide-sensitive Na-Cl cotransporter.
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The aim of this study was to construct a numerical model of the thiazide-sensitive Na-Cl cotransporter (TSC) that can predict kinetics of thiazide binding and substrate transport of TSC. We hypothesized that the mechanisms underlying these kinetic properties can be approximated by a state diagram in which the transporter has two binding sites, one for sodium and another for chloride and thiazide. On the basis of the state diagram, a system of linear equations that should be satisfied in the steady state was postulated. Numerical solution of these equations yielded model prediction of kinetics of thiazide binding and substrate transport. Rate constants, which determine transitional rates between states, were systematically adjusted to minimize a penalty function that was devised to quantitatively estimate the difference between model predictions and experimental results. With the resultant rate constants, the model could simulate the following experimental results: 1) dissociation constant of thiazide in the absence of sodium and chloride; 2) inhibitory effect of chloride on thiazide binding; 3) stimulatory effect of sodium on thiazide binding; 4) combined effects of sodium and chloride on thiazide binding; 5) dependence of sodium influx on extracellular sodium and chloride; and 6) inhibition of sodium influx by extracellular thiazide. We conclude that known kinetic properties of TSC can be predicted by a model which is based on a state diagram. (+info)
A furosemide-sensitive K+-Cl- cotransporter counteracts intracellular Cl- accumulation and depletion in cultured rat midbrain neurons.
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Efficacy of postsynaptic inhibition through GABAA receptors in the mammalian brain depends on the maintenance of a Cl- gradient for hyperpolarizing Cl- currents. We have taken advantage of the reduced complexity under which Cl- regulation can be investigated in cultured neurons as opposed to neurons in other in vitro preparations of the mammalian brain. Tightseal whole-cell recording of spontaneous GABAA receptor-mediated postsynaptic currents suggested that an outward Cl- transport reduced dendritic [Cl-]i if the somata of cells were loaded with Cl- via the patch pipette. We determined dendritic and somatic reversal potentials of Cl- currents induced by focally applied GABA to calculate [Cl-]i during variation of [K+]o and [Cl-] in the patch pipette. [Cl-]i and [K+]o were tightly coupled by a furosemide-sensitive K+-Cl- cotransport. Thermodynamic considerations excluded the significant contribution of a Na+-K+-Cl- cotransporter to the net Cl- transport. We conclude that under conditions of normal [K+]o the K+-Cl- cotransporter helps to maintain [Cl-]i at low levels, whereas under pathological conditions, under which [K+]o remains elevated because of neuronal hyperactivity, the cotransporter accumulates Cl- in neurons, thereby further enhancing neuronal excitability. (+info)
Effect of furosemide on pulmonary blood flow distribution in resting and exercising horses.
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We determined the spatial distribution of pulmonary blood flow (PBF) with 15-micron fluorescent-labeled microspheres during rest and exercise in five Thoroughbred horses before and 4 h after furosemide administration (0.5 mg/kg iv). The primary finding of this study was that PBF redistribution occurred from rest to exercise, both with and without furosemide. However, there was less blood flow to the dorsal portion of the lung during exercise postfurosemide compared with prefurosemide. Furosemide did alter the resting perfusion distribution by increasing the flow to the ventral regions of the lung; however, that increase in flow was abated with exercise. Other findings included 1) unchanged gas exchange and cardiac output during rest and exercise after vs. before furosemide, 2) a decrease in pulmonary arterial pressure after furosemide, 3) an increase in the slope of the relationship of PBF vs. vertical height up the lung during exercise, both with and without furosemide, and 4) a decrease in blood flow to the dorsal region of the lung at rest after furosemide. Pulmonary perfusion variability within the lung may be a function of the anatomy of the pulmonary vessels that results in a predominantly fixed spatial pattern of flow distribution. (+info)
Evaluation of changes in intrarenal oxygenation in rats using multiple gradient-recalled echo (mGRE) sequence.
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Changes in intrarenal oxygenation in rats during pharmacological stimuli were evaluated with a multiple gradient-recalled echo (mGRE) sequence. With administration of the loop diuretic furosemide, oxygenation in the medulla improved; acetazolamide, a proximal tubular diuretic, produced no significant change. These results are consistent with our previous studies in humans and resemble earlier studies of medullary oxygenation using oxygen microelectrodes in anesthetized rats. The technique may be useful in the evaluation of therapeutic strategies in animal models of pathophysiological states such as acute renal failure. (+info)
Endothelial cell shrinkage increases permeability through a Ca2+-dependent pathway in single frog mesenteric microvessels.
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1. We tested whether calcium (Ca2+)-dependent mechanisms were essential for our previous observation that a change in the endothelial cell (EC)-extracellular matrix (ECM) attachment caused an increase in microvessel hydraulic permeability (Lp) after exposure to hypertonic solutions in single perfused mesenteric microvessels in pithed frogs (Rana pipiens). 2. In microvessels where integrin-dependent EC-ECM attachments were disrupted by pretreatment with the peptide Gly-Arg-Gly-Asp-Thr-Pro (GRGDTP; 0.3 mmol l-1), we measured microvessel Lp after exposure to hypertonic solutions under experimental conditions that reduced Ca2+ influx into endothelial cells. 3. High K+ solutions (59.7 and 100 mmol l-1 K+) were used to depolarize the endothelial membrane and therefore to reduce the electrochemical driving force for Ca2+ influx through conductive Ca2+ channels. These solutions abolished the increase in Lp caused by hypertonic solutions in the microvessels pretreated with GRGDTP. 4. We previously suggested that the removal of albumin from the perfusate may reduce EC-ECM attachment because hypertonic solutions increased the Lp of microvessels above that due to removal of albumin alone. This additional increase in Lp was attenuated by the 59.7 mmol l-1 K+ solution and was completely abolished by the 100 mmol l-1 K+ solution. 5. Bumetanide, an inhibitor of the Na+-K+-2Cl- co-transporter and one of the mechanisms of regulatory volume increase after exposure to hypertonic solutions in endothelial cells, did not change the response of microvessels to high K+ solutions. 6. Our findings indicate that Ca2+ entry into endothelial cells via passive conductance channels is necessary to increase microvessel Lp after exposure to hypertonic solutions in microvessels where EC-ECM attachments are disrupted. (+info)
Involvement of the n-terminus of Kir6.2 in coupling to the sulphonylurea receptor.
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1. ATP-sensitive potassium (KATP) channels are composed of pore-forming Kir6.2 and regulatory SUR subunits. ATP inhibits the channel by interacting with Kir6.2, while sulphonylureas block channel activity by interaction with a high-affinity site on SUR1 and a low-affinity site on Kir6.2. MgADP and diazoxide interact with SUR1 to promote channel activity. 2. We examined the effect of N-terminal deletions of Kir6.2 on the channel open probability, ATP sensitivity and sulphonylurea sensitivity by recording macroscopic currents in membrane patches excised from Xenopus oocytes expressing wild-type or mutant Kir6.2/SUR1. 3. A 14 amino acid N-terminal deletion (DeltaN14) did not affect the gating, ATP sensitivity or tolbutamide block of a truncated isoform of Kir6.2, Kir6.2DeltaC26, expressed in the absence of SUR1. Thus, the N-terminal deletion does not alter the intrinsic properties of Kir6.2. 4. When Kir6.2DeltaN14 was coexpressed with SUR1, the resulting KATP channels had a higher open probability (Po = 0.7) and a lower ATP sensitivity (Ki = 196 microM) than wild-type (Kir6.2/SUR1) channels (Po = 0.32, Ki = 28 microM). High-affinity tolbutamide block was also abolished. 5. Truncation of five or nine amino acids from the N-terminus of Kir6.2 also enhanced the open probability, and reduced both the ATP sensitivity and the fraction of high-affinity tolbutamide block, although to a lesser extent than for the DeltaN14 deletion. Site-directed mutagenesis suggests that hydrophobic residues in Kir6. 2 may be involved in this effect. 6. The reduced ATP sensitivity of Kir6.2DeltaN14 may be explained by the increased Po. However, when the Po was decreased (by ATP), tolbutamide was unable to block Kir6. 2DeltaN14/SUR1-K719A,K1385M currents, despite the fact that the drug inhibited Kir6.2-C166S/SUR1-K719A,K1385M currents (which in the absence of ATP have a Po of > 0.8 and are not blocked by tolbutamide). Thus the N-terminus of Kir6.2 may be involved in coupling sulphonylurea binding to SUR1 to closure of the Kir6.2 pore. (+info)
Activation of the Na+-K+ pump by hyposmolality through tyrosine kinase-dependent Cl- conductance in Xenopus renal epithelial A6 cells.
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1. We studied the regulatory mechanism of Na+ transport by hyposmolality in renal epithelial A6 cells. 2. Hyposmolality increased (1) Na+ absorption, which was detected as an amiloride-sensitive short-circuit current (INa), (2) Na+-K+ pump activity, (3) basolateral Cl- conductance (Gb,Cl), and (4) phosphorylation of tyrosine, suggesting an increase in activity of protein tyrosine kinase (PTK). 3. A Cl- channel blocker, 5-nitro-2-(3-phenylpropylamino)-benzoate (NPPB), which abolished Gb, Cl, blocked the INa by inhibiting the Na+-K+ pump without any direct effect on amiloride-sensitive Na+ channels. Diminution of Gb,Cl by Cl- replacement with a less permeable anion, gluconate, also decreased the hyposmolality-increased Na+-K+ pump activity. 4. The PTK inhibitors tyrphostin A23 and genistein induced diminution of the hyposmolality-stimulated Gb,Cl, which was associated with attenuation of the hyposmolality-increased Na+-K+ pump activity. 5. Taken together, these observations suggest that: (1) hyposmolality activates PTK; (2) the activated PTK increases Gb,Cl; and (3) the PTK-increased Gb,Cl stimulates the Na+-K+ pump. 6. This PTK-activated Gb,Cl-mediated signalling of hyposmolality is a novel pathway for stimulation of the Na+-K+ pump. (+info)