UNIPROT:P41181 - FACTA Search

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Query: UNIPROT:P41181 (collecting duct)
5,183 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

During antidiuresis, the medullary collecting duct (MCD) reabsorbs sodium in load-dependent fashion. However, attempts to characterize reabsorption when sodium delivery to the MCD is elevated have not led to clear results, largely due to interfering effects of the strategies employed to raise delivery. In the present study, microcatheterization was performed in rats undergoing water diuresis induced solely by infusion of 2.5% dextrose in water, and in rats where solute delivery to the MCD was markedly elevated by the combination of water diuresis with acute potassium chloride loading. The results show that delivery of sodium was elevated by the experimental maneuvers, averaging 7.01 +/- 0.83 mumol . min-1 . g kidney wt-1 compared with a normal antidiuretic value in the literature of 3.50 +/- 0.40 mumol . min-1 . g-1. Sodium and chloride reabsorptions were increased proportionally, indicating that the MCD has a large capacity to transport sodium chloride. Normalized sodium reabsorption remained high, varying in different series between 80 +/- 10 and 96 +/- 1% of the delivered load. Thus the MCD reabsorbed an average of 6.37 +/- 0.70 mumol . min-1 . g-1 of sodium while sodium excretion was 0.52 +/- 0.11 mumol . min-1 . g-1. The results emphasize the importance of MCD sodium chloride reabsorption for determination of final urinary salt excretion, and thus for regulation of body salt balance.
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PMID:Load dependency of sodium chloride reabsorption by medullary collecting duct in rat. 366 17

25 years have elapsed since the introduction of the first effective oral diuretic, chlorothiazide. Diuretics are now amongst the most widely prescribed drugs in clinical practice worldwide. Availability of these drugs has not only brought therapeutic benefit to countless numbers of patients but it has at the same time provided valuable research tools with which to investigate the functional behaviour of the kidney and other electrolyte-transporting tissues. Despite many remaining gaps in our knowledge of the biochemical processes involved in diuretic drug action, available compounds can be divided into 5 groups on the basis of their preferential effects on different segments of the nephron involved in tubular reabsorption of sodium chloride and water. Firstly, there is heterogeneous group of chemicals that share the common property of powerful, short-lived diuretic effects that are complete within 4 to 6 hours. These agents act on the thick ascending limb of Henle's loop and are known as 'high ceiling' or 'loop' diuretics. The second group are the benzothiadiazines and their many related heterocyclic variants, all of which localise their effects to the early portion of the distal tubule. The third group comprises the potassium-sparing diuretics which act exclusively on the Na+-K+/H+ exchange mechanisms in the late distal tubule and cortical collecting duct. The action of drugs in groups 2 and 3 is prolonged to between 12 and 24 hours. The fourth group consists of diuretics that are chemically related to ethacrynic acid but have the unusual property of combining within the same molecule the property of saluresis and uricosuria. These compounds have actions, to different individual extents, in the proximal tubule, thick ascending limb, and early distal tubule and are known as 'polyvalent' diuretics. Finally, there is a mixed group of weak or adjunctive diuretics which includes the vasodilator xanthines such as aminophylline, and the osmotically active compounds such as mannitol. Available evidence on the molecular mechanisms of action of diuretics in each group is reviewed. The haemodynamic, humoral and physical factors involved in control of electrolyte and fluid handling by the kidney in normal conditions and pathological states are discussed in relation to rational choices of different diuretics in the treatment of various oedematous and non-oedematous conditions.
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PMID:Diuretics. Clinical pharmacology and therapeutic use (Part I). 388 91

25 years have elapsed since the introduction of the first effective oral diuretic, chlorothiazide. Diuretics are now amongst the most widely prescribed drugs in clinical practice worldwide. Availability of these drugs has not only brought therapeutic benefit to countless numbers of patients but it has at the same time provided valuable research tools with which to investigate the functional behaviour of the kidney and other electrolyte-transporting tissues. Despite many remaining gaps in our knowledge of the biochemical processes involved in diuretic drug action, available compounds can be divided into 5 groups on the basis of their preferential effects on different segments of the nephron involved in tubular reabsorption of sodium chloride and water. Firstly, there is a heterogeneous group of chemicals that share the common property of powerful, short-lived diuretic effects that are complete within 4 to 6 hours. These agents act on the thick ascending limb of Henle's loop and are known as 'high ceiling' or 'loop' diuretics. The second group are the benzothiadiazines and their many related heterocyclic variants, all of which localise their effects to the early portion of the distal tubule. The third group comprises the potassium-sparing diuretics which act exclusively on the Na+-K+/H+ exchange mechanisms in the late distal tubule and cortical collecting duct. The action of drugs in groups 2 and 3 is prolonged to between 12 and 24 hours. The fourth group consists of diuretics that are chemically related to ethacrynic acid but have the unusual property of combining within the same molecule the property of saluresis and uricosuria. These compounds have actions, to different individual extents, in the proximal tubule, thick ascending limb, and early distal tubule and are known as 'polyvalent' diuretics. Finally, there is a mixed group of weak or adjunctive diuretics which includes the vasodilator xanthines such as aminophylline, and the osmotically active compounds such as mannitol. The metabolic consequences of continued diuretic usage are considered along with non-metabolic sequelae such as ototoxicity or interactions with other concurrent treatments. The relationships between the clinical benefits conferred and the potential harms generated by long term diuretic therapy are also discussed.
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PMID:Diuretics. Clinical pharmacology and therapeutic use (Part II). 388 20

A homogeneous population of single cells from the thick ascending limb of Henle's loop (TALH) has been isolated from the rabbit kidney medulla. A total medullary cell suspension was prepared by a series of collagenase, hyaluronidase, and trypsin digestions and separated on a Ficoll gradient (2.6-30.7% wt/wt). Morphologically, the cells isolated from the TALH were homogeneous and showed polarity within their plasma membrane structure, with a few blunt microvilli on their apical surface and deep infoldings of the basal-lateral membrane. Biochemically, the TALH cells were highly enriched in calcitonin-sensitive adenylate cyclase and Na, K-ATPase. Alkaline phosphatase and arginine vasopressin-sensitive adenylate cyclase, highly concentrated in proximal tubule and collecting duct, were present only in low concentrations in the TALH cells. Additionally, furosemide, a diuretic inhibiting sodium chloride transport in the TALH in vivo, inhibited oxygen consumption of the TALH cells in a dose-dependent manner. The TALH cells were viable, as judged by morphological appearance, trypan blue exclusion, the response of oxygen consumption to 2,4-dinitrophenol, succinate and ouabain, and the cellular Na, K and ATP levels.
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PMID:Separation of renal medullary cells: isolation of cells from the thick ascending limb of Henle's loop. 625 27

Diuretics have a central role in the treatment of edema and hypertension. This function is primarily an induction of a net negative balance of solute and water. Reviewed herein are the transport properties of each nephron segment that governs salt and water reabsorption with specific reference to the mechanisms by which the various diuretic agents affect those transport processes. Under normal circumstances, the proximal tubule reabsorbs about 50 to 66 percent of the filtered fluid by both active and passive mechanisms. However, diuretics that inhibit proximal reabsorption are "weak" diuretics since distal compensatory mechanisms can overcome their effect. The thin descending limb of Henle is highly permeable to water and relatively impermeable to solutes. Thus, its main physiologic function is to allow osmotic water abstraction. Although diuretics have no direct epithelial effect on this segment, many of the diuretics decrease fluid reabsorption from it by abolishing the papillary osmotic gradient. The decreased water absorption from the descending limb of Henle has a major role in over-all increased diuresis since nephron segments distal to the descending limb are impermeable to water in the absence of vasopressin. The thin ascending limb of Henle is impermeable to water while being highly permeable to sodium and chloride. Diuretics have no direct effect on the thin ascending limb of Henle. The medullary and cortical segments of the thick ascending limb of Henle absorb sodium chloride by active mechanisms as a result of a secondary active chloride transport mechanism that depends on the presence of sodium (co-transport mechanism). This transport mechanism is located on the luminal membrane. Most of the "loop" diuretics effect this process from the luminal side by having a direct inhibitory effect on this co-transport process. The diuretics that have a primary effect on the medullary segment (furosemide, bumetanide, ethacrynic acid) inhibit the concentrating mechanisms, whereas the diuretics that are effective primarily in the cortical segment (thiazides plus the diuretics affecting the medullary segment) inhibit the urinary diluting mechanism. The loop diuretics are physiologically the most potent family of diuretics. The cortical collecting duct segment reabsorbs sodium by active mechanisms. These processes are stimulated by aldosterone. The diuretics that affect these processes are considered weak diuretics, but they do have the metabolic effect of potassium sparing.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Site and mechanism of action of diuretics. 649 55

The element concentrations in various intra- and extracellular compartments of the tip of the rat renal papilla were determined during antidiuresis using electron microprobe analysis. Urinary concentrations (means +/- SEM) were: urea, 1509 +/- 116; potassium, 268 +/- 32; sodium, 62 +/- 19 mmoles X 1(-1); and osmolality, 2548 +/- 141 mOsm X kg-1. Electrolyte concentrations in the interstitial space were: sodium, 437 +/- 19; chloride, 438 +/- 20; and potassium, 35 +/- 2 mmoles X kg-1 wet wt. The vasa recta plasma exhibited almost identical element concentrations. The values in the papillary collecting duct cells were: sodium, 28 +/- 1; chloride, 76 +/- 3; potassium, 135 +/- 3; and phosphorus, 316 +/- 7 mmoles X kg-1 wet wt. Similar concentrations were observed in the papillary epithelial cells. In interstitial cells potassium and phosphorus concentrations were virtually identical to those of the collecting duct cells, whereas sodium and chloride concentrations were higher by about 30 mmoles X kg-1 wet wt. The element composition of the various papillary cells is, thus, not substantially different from that of proximal tubular cells. This finding demonstrates that cellular accumulation of electrolytes is not the regulatory mechanism by which papillary cells adapt osmotically to their high environmental osmolality and sodium chloride concentration.
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PMID:Intra- and extracellular element concentrations of rat renal papilla in antidiuresis. 672 35

The hypotheses of passive salt accumulation predict an enhancement of renal concentrating ability by urea. We tested this prediction in rabbits, a species whose nephons when studied in vitro show tansport properties that support these hypotheses. We used calm, unanesthetized, hydropenic, vasopressin-treated rabbits with intact kidneys fed a 16% protein diet, and we observed the effect of urea administration at two rates of solute excretion (60 and 190 microOsm/min . kg body wt; N = 10 and 5, respectively). After an i.v. mannitol infusion, when urea was infused, the i.v. solute excretion rate was unchanged, the changes in urine urea concentration were large (a change of 767 and 408 mumoles/ml), but only small and variable changes in urine osmolality occured (a change of 78 +/- 146, and 36 +/- 50 microOsm/g H20). In additional experiments, we removed the kidneys from antidiuretic, or urea- or mannitol-infused rabbits and measured the intrarenal distribution of sodium, potassium, urea, and chloride. When the urine urea level was greater than 400 mmoles, the urine-to-papilla ratios for urea were 1.6 to 3.6. This suggested that a low collecting duct permeability to urea could explain the absence of a marked enhancement of concentrating ability during urea administration. Further analysis, based on a model of inner medullary solute compartments, indicated that sodium chloride was the major (86%) osmotically active solute in the medullary central core of these rabbits and that it was not influenced by changes in urinary urea concentration. The results of tissue analysis were consonant with either active or passive sodium chloride reabsorption from the thin ascending limb of Henle's loop in these rabbits.
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PMID:Urea and renal concentrating ability in the rabbit. 677 Jan 67

Inability to attain Umax after overnight dehydration is the earliest functional abnormality in human and experimental pyelonephritis caused by diverse microorganisms. In order to characterize the defect in Umax in experimental enterococcal pyelonephritis, another index of renal concentrating ability. TcH2O, was determined during saline loading. Normal TcH2O depends on adequate sodium chloride delivery and reabsorption in the ascending limb of Henle's loop and water reabsorption from the collecting duct. Rats with early pyelonephritis, 3 days after intravenous injection of enterococci, were compared with normal rats in studies of Umax during hydropenia and TcH2O during 1.2% saline infusion. Mean Umax in infected rats was significantly lower than in uninfected rats (1120 vs. 2767 mOsm/kg H2O) (p less than 0.01), but CIn in infected rats was not significantly different from that in uninfected rats (0.96 vs. 0.89 ml/min per 100 gm) (p less than 0.05). During saline diuresis, maximal Cosm/CIn was more than 35% in both the normal and infected rats. The relationship between TcH2O/CIn and Cosm/CIn was linear in both groups, and the r, slope, any y intercept of the regression equation of TcH2O/CIn vs. Cosm/CIn in infected rats were not significantly different from those in normal rats. During saline diuresis the regression of sodium excretion UNaV/CIn) vs. Cosm in infected rats was not significantly different from that in control rats. The finding of normal TcH2O during saline loading suggests that reabsorption of increasing amounts of sodium chloride from the ascending limb of Henle's loop and reabsorption of water in the collecting duct are normal in early pyelonephritis.
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PMID:Free water reabsorption during saline diuresis in experimental enterococcal pyelonephritis in rats. 706 23

The aim of this study was to examine the possible role of renal prostaglandins in the response of the inner medullary collecting duct (IMCD) to acute volume expansion. Collecting duct microcatheterization and clearance studies were carried out in anesthetized rats, volume-expanded with isotonic Ringer's solution. In volume-expanded control animals, there was no significant sodium or chloride reabsorption between the beginning and end (papillary tip) of the IMCD. Administration of indomethacin or meclofenamate prior to and during volume expansion in two other groups of rats resulted in significant water, sodium, and chloride reabsorption along the IMCD and markedly blunted the diuretic, natriuretic and chloriuretic response to volume expansion. Because delivery to the beginning of the duct was not significantly decreased, enhanced reabsorption in the IMCD largely accounted for the decrease in natriuresis and chloriuresis. Inner medullary tissue fluid chloride concentration increased after inhibition of prostaglandin synthesis. The results indicate that renal prostaglandins, perhaps by directly decreasing sodium chloride reabsorption, have an important role in the decrease in collecting duct reabsorption of sodium and chloride observed with acute volume expansion.
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PMID:Prostaglandin synthesis inhibition during volume expansion: collecting duct function. 712 Jul 51

The present study examines the possibility that prostaglandins affect the renal tubular handling of urea. Meclofenamate (1 mg.kg-1.h-1), an inhibitor of prostaglandin synthesis, decreased fractional urea clearance from 86 to 67%, increased urine osmolality, and decreased the fractional excretion of water in rats undergoing a hypertonic sodium chloride diuresis. The percentage of [14C]urea microinjected into distal convoluted tubules that was recovered in urine fell from 75 to 64% (P less than 0.01) after meclofenamate. The fraction of injected urea excreted like inulin (direct recovery) was reduced from 20 to 8% (P less than 0.0001) by meclofenamate. Addition of PGE2 (1.2 or 89 pmol) or PGF2 alpha (1.4 pmol) to the microinjectate returned the urinary recovery of the microinjected [14C]urea to the control level, but PGA2 (3 pmol) did not. Direct urea recovery was doubled by PGE2 or PGF2 alpha. These results indicate that prostaglandin E2 and F2 alpha inhibit the reabsorption of urea in the collecting duct. Prostaglandins may participate in the renal concentrating mechanism by altering the inner medullary influx of urea.
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PMID:Prostaglandin E2 and F2 alpha reduces urea reabsorption from the rat collecting duct. 724 74

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