Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UNIPROT:P01185 (vasopressin)
 23,126 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Atrial natriuretic factor (ANF) is a peptide hormone that causes a large increase in urinary sodium chloride and water excretion when its plasma concentration rises above basal levels. As yet, there is no consensus regarding the chief site of action of ANF in the kidney. We microdissected and perfused rat cortical collecting ducts in vitro to determine whether ANF-(1-28) can directly inhibit net sodium and fluid absorption. ANF decreased both net sodium absorption and vasopressin-stimulated net fluid absorption by 50-90% when added to the peritubular bath solution. Approximately 50% inhibition of net fluid absorption occurred at 0.1 nM ANF, a level equivalent to plasma concentrations in volume-expanded rats. The action of ANF was mimicked by the addition of exogenous guanosine 3',5'-cyclic monophosphate. If ANF has a similar action on the cortical collecting duct in vivo, it could account for a substantial part of the ANF-mediated increase in urinary sodium and water excretion.
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PMID:ANF inhibits NaCl and fluid absorption in cortical collecting duct of rat kidney. 252 30

The non-osmotic stimulation of release of arginine vasopressin (AVP) seems to be the main determinant of the impaired water excretion and hyponatraemia in patients with cardiac failure. This non-osmotic stimulation of AVP release could be secondary to a decrease in stroke volume to which the ventricular receptors respond by decreasing the vagal afferent input to the hypothalamus via the mid-brain. Improvement of cardiac stroke volume would then decrease AVP release and improve water excretion. In cardiac failure, the non-osmotic stimulation of AVP release is not clearly modulated by the renin-angiotensin system or by the atrial natriuretic peptide plasma concentration. Nevertheless, physiological concentrations of atrial natriuretic peptide could inhibit the renal epithelial water transport at the collecting duct level. Water-loading and osmotic-loading experiments in patients with cardiac failure indicated that the release of AVP is still under osmotic control and favoured the concept that volume depletion in general and cardiac failure in particular may lower the osmotic threshold and increase the osmotic sensitivity to vasopressin release. Experiments using a specific vasopressin antagonist rarely indicated a vasoconstrictor role for endogenous AVP in either experimental or clinical cardiac failure. Intrarenal factors also contributed to the impaired water excretion observed in patients with cardiac failure: increased central sympathetic efferent discharge and stimulation of the renin-angiotensin-aldosterone system would be expected as a consequence of the decreased effective arterial blood volume. These effects could then decrease maximal reabsorption of solute further impairing the ability of the kidney to excrete free water. The impaired water excretion is correlated with the severity of the cardiac deterioration and thus has prognostic implications.
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PMID:Water disturbances in cardiac failure. 253 70

The plasma membrane composition of virtually all eucaryotic cells is established, maintained, and modified by the process of membrane recycling. Specific plasma membrane components are inserted by exocytosis of transport vesicles, and are removed by endocytosis of segments of the membrane in which particular proteins are concentrated. In the kidney collecting duct, vasopressin induces the cycling of vesicles that are thought to carry water channels to and from the apical plasma membrane of principal cells, thus modulating the water permeability of this membrane. In the intercalated cells of the collecting duct, hydrogen ion secretion is controlled by the recycling of vesicles carrying proton pumps to and from the plasma membrane. In both cell types, "coated" carrier vesicles are involved, but whereas clathrin-coated vesicles participate in water channel recycling, the vesicles in intercalated cells are coated with the cytoplasmic domains of proton pumps. Following a brief outline of membrane recycling in general, this review summarizes previous data on membrane recycling in the collecting duct and related transporting epithelia and discusses some selected points relating to the role of membrane recycling and cell-specific function in the collecting duct.
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PMID:Membrane recycling and epithelial cell function. 253 41

Recent micropuncture studies have demonstrated that administration of high doses of 1-deamino-8-D-arginine vasopressin (dDAVP), a synthetic analogue of vasopressin (AVP), causes desensitization of the thick ascending limb to AVP but may leave unaltered the effect of this hormone on the permeability to water of the collecting duct. In the present experiments, desensitization to AVP was studied by measuring adenosine 3',5'-cyclic monophosphate (cAMP) synthesis in microdissected cortical thick ascending limbs (CTAL) and cortical collecting ducts (CCD) incubated in vitro. Desensitization was induced by intramuscular injections of dDAVP (2 micrograms/day for 3 days). In a first series of experiments, performed on Brattleboro rats lacking circulating AVP, the effects of AVP on cAMP accumulation were reduced by 30% in CTAL of the rats given dDAVP, whereas in CCD no reduction was noted. Desensitization of CTAL was selective for AVP (i.e., homologous), the effects of glucagon being unaltered. In a second series of experiments, performed on Sprague-Dawley rats, a marked (up to 75% 2 h after dDAVP injection), homologous and reversible desensitization of CTAL to AVP was observed. However, here again no desensitization was obtained in CCD, indicating that in the normal rat, administration of 2 micrograms dDAVP also elicited preferential desensitization of CTAL.
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PMID:Independent desensitization of rat renal thick ascending limbs and collecting ducts to ADH. 253 47

Urine is an abundant source of epidermal growth factor (EGF) and prepro-EGF has been localized to the thick ascending limb and distal convoluted tubule of the kidney. However, the functional role of EGF in the kidney is poorly understood. Determination of EGF receptors and functional responses to EGF in intrarenal structures distal to the site of renal EGF production may prove critical to our understanding of the role of this peptide. These studies were designed to investigate the response to EGF of rat inner medullary collecting duct cells in culture and in freshly isolated suspensions. Primary cultures of inner medullary collecting duct cells demonstrated equilibrium binding of 125I-labeled EGF at 4 and 23 degrees C. At 23 degrees C, there was 89 +/- 1% specific binding (n = 30). Scatchard analysis of 125I-EGF binding suggested the presence of both high-affinity binding with a dissociation constant (Kd) of 5 X 10(-10) M and maximal binding sites (Ro) of 2.7 X 10(3) binding sites/cell and low-affinity binding, with Kd of 8.3 X 10(-9) M and Ro of 1.8 X 10(4) binding sites/cell. Bound EGF, 68 +/- 3%, was internalized by 45 min. EGF binding was not inhibited by antidiuretic hormone, atrial natriuretic peptide or bradykinin at 23 degrees C, but there was concentration-dependent inhibition of binding by transforming growth factor-alpha. Incubation with phorbol myristate acetate decreased 125I-EGF binding in a concentration-dependent manner. 125I-EGF binding was also demonstrated in freshly isolated suspensions of rat inner medullary collecting duct cells.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Response of rat inner medullary collecting duct to epidermal growth factor. 254 6

The present study quantitated the effects of extracellular volume expansion on sodium and water excretion in 118 anesthetized dogs. The animals received a priming injection of 10 ml kg-1 Ringer solution i.v. which was followed by a constant Ringer solution infusion at a rate of 0.25 ml.min-1.kg-1 until the end of the experiment. Fifteen minutes after the start of the constant infusion the renal parameters were examined in 11 subsequent 15 min periods (the total time was 3 hours). Volume expansion produced no significant change in arterial blood pressure, glomerular filtration rate (GFR), plasma sodium and potassium concentration or, haematocrit, but did reduce the CPAH from 284 ml.min-1 to 218 ml.min-1 (the data were calculated for 100 gram wet kidney weight). There were constant significant increases in the urinary excretion rate from 0.84 ml.min-1 to 4.06 ml.min-1 and the 39% of the infused water was excreted during the experiment. Volume expansion also caused a significant increase in sodium excretion during the three first periods from 120 mumol.min-1 to 329 mumol.min-1 followed by a small but significant decrease. The sodium excretion at the end of the experiment was 221 mumol.min-1 and the 23% of the infused sodium was excreted in the course of the experiment. The increase of the water excretion during the volume expansion was associated with fall of the urine osmolality and the urine because hypoosmotic as compared to the plasma. We have provided evidence that vasopressin was not involved in the control of water excretion in our experiments. It is concluded that neither filtered sodium nor decreased aldosterone secretion can account for the increase in sodium excretion that occurs after Ringer solution loading in the dog. It has been proposed that a decrease in plasma protein concentration may decrease passive sodium reabsorption due to oncotic forces in the proximal tubule. The Ringer solution diuresis elicits a rise in medullary blood flow, thereby causing a washout of medullary sodium. This might dissipate the osmotic force for the back-diffusion of water from the collecting duct. Our studies indicate that the response of the diluting segments of the distal nephron to increased delivery of sodium depends upon the presence or absence of volume expansion. However the increase of the distal tubular loading activates the tubuloglomerular feedback which increases the proximal tubular reabsorption. Based on these assumptions our studies provide further evidence that the tubuloglomerular feedback regulates the blood pressure in the peritubular capillaries in the cortex around the proximal tubules.
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PMID:The effect of Ringer solution induced extracellular volume expansion on kidney function. 260 31

This chapter shows how the mammalian kidney is able to regulate the excretion of water independently from that of solutes. For this function, which derives from several evolutionary steps among vertebrates, it takes advantage of the diluting ability of the thick ascending limb to produce osmotic energy which is then used to concentrate solutes in the urine. This concentration is permitted by a highly sophisticated architecture of nephrons and vessels in the renal medulla, combined with special permeability characteristics of the different nephron segments and specific hormonal regulation. Two different types of loops of Henle and several well-insulated vascular compartments contribute to this process. The major nitrogenous waste product, urea, is concentrated by an indirect process involving a transfer of osmotic energy from the outer to the inner medulla. As known for several decades, concentrating function is primarily regulated by the effect of antidiuretic hormone (ADH) on water permeability of the collecting duct. However, as discovered more recently, it is also largely dependent upon the effect of the same hormone on urea permeability in the terminal collecting duct. In addition, recent investigations have revealed a much more complex hormonal regulation of the concentrating process than previously thought. ADH itself acts on many other structures in the kidney, and many other hormones and mediators, the secretion of which is not thought to be influenced by the water status, do affect urine concentration either directly or by their interaction with ADH. Rodents display a wide spectrum of morphological and functional renal adaptations improving water conservation. Their study has brought a better understanding of the significant steps and anatomical structures that contribute to the concentrating process. Finally, it is also apparent that the capacity to concentrate urine is influenced in individual animals of a given species by the availability of water, by specific feeding patterns, and by the protein content of the diet.
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PMID:The role of the kidney in the maintenance of water balance. 269 39

The water permeability of collecting ducts is greatly increased by the antidiuretic hormone, vasopressin (VP). Freeze-fracture studies were carried out to test if this permeability increase is associated with the appearance of intramembrane particle (IMP) aggregates and whether increased doses of VP lead to an increase in the number and size of particle aggregates in the luminal membrane of principal cells in the isolated cortical collecting duct. Unstimulated cells expressed 17 +/- 6.5 particle aggregates per 100 microns 2. Stimulation with VP at concentrations of 20 or 200 microU/ml increased the number of particle aggregates significantly to 129 +/- 15.8 and 324 +/- 45.8, respectively. The size of the particle aggregates increased from 0.0012 microns 2 under control conditions to 0.025 microns 2 at 20 microU/ml VP and to 0.063 microns 2 at 200 microU/ml VP. In addition, the total area occupied by the IMP increased from 0.02 microns 2/100 microns 2 (controls) to 3.17% and 20.38% (after 20 and 200 microU ADH/ml, respectively). Particle aggregates were also observed in the luminal plasma membrane of isolated collecting ducts fixed immediately after dissection, resembling the in vivo status. These results demonstrate that a dose-dependent relationship exists between the concentration of the applied VP and the number of particle aggregates, as well as the size of the aggregates. Cytoplasmic tubular vesicles in fusion with the apical membrane were observed.
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PMID:Vasopressin-induced intramembrane particle aggregates. A dose-response relationship in the isolated cortical collecting duct of the rabbit kidney. 280 60

To test the possibility that adenosine may be involved in a urine concentrating mechanism, effects of 1-phenylisopropyladenosine (PIA) on cyclic AMP levels have been examined in medullary thick ascending limb (mTAL) and medullary collecting duct (MCD) isolated from the rat. Low and high doses of PIA did not alter basal cyclic AMP levels in both segments. However, PIA depressed vasopressin-dependent cyclic AMP production in MCD in a dose-dependent manner: this effect of PIA was maximum at 10(-6) M. 8-Phenyltheophylline, a competitive inhibitor for adenosine receptor, completely abolished this inhibitory effect of PIA. This finding may suggest an existence of adenosine receptor on the MCD. In mTAL, PIA also suppressed vasopressin-mediated cyclic AMP generation. The present study shows an interaction between PIA and vasopressin in both MCD and mTAL. This interaction may contribute in part to urinary-concentrating disturbance in renal ischemia.
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PMID:Effect of phenylisopropyladenosine on vasopressin-dependent cyclic AMP generation in defined nephron segments from rat. 282 7

This review focuses on events at the apical plasma membrane of toad urinary bladder and mammalian collecting duct as their permeability to water changes in response to antidiuretic hormone (ADH) and to its withdrawal. The major marker of the permeability change is observed in freeze-fracture electron microscopy of the apical plasma membrane and consists of a dramatic increase in membrane particle aggregates and, in toad bladder but not in collecting duct, in fused vesicles (aggrephores) that contain particle aggregates in their limiting membranes. Withdrawal of ADH is accompanied by endocytosis at the apical membrane, reflecting retrieval of water-permeable, particle aggregate-containing membrane. Covalent labeling of the external surface of the apical membrane of toad bladder identifies specific proteins that are present in the apical membrane only during the response to ADH. Proteins of the same molecular weights are also present in the retrieved membrane when ADH is withdrawn. Several controversial areas are considered, including the extent of cell swelling as water flows across the epithelium from dilute apical solution to isotonic basal solution, whether only principal cells or principal cells and intercalated cells participate in the water permeability response of the collecting duct, the role of the cytoskeleton in the water permeability response, and the proposed second water permeability barrier that is affected by ADH, but not by adenosine 3',5'-cyclic monophosphate.
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PMID:Antidiuretic hormone moves membranes. 284 50


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