Renal brush border membrane adaptation to phosphorus deprivation: Effects of fasting versus low-phosphorus diet

Renal brush border membrane adaptation to phosphorus deprivation: Effects of fasting versus low-phosphorus diet. limentary phosphorus deprivation due to a low-phosphorus diet (LPD) elicits a profound antiphosphaturia and an increase in sodium-dependent inorganic phosphate (Pi) uptake by renal cortic...

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Veröffentlicht in:	Kidney international 1980-07, Vol.18 (1), p.36-47
Hauptverfasser:	Kempson, Stephen A., Shah, Sudhir V., Werness, Peter G., Berndt, Theresa, Lee, Peter H., Smith, Lynwood H., Knox, Franklyn G., Dousa, Thomas P.
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Sprache:	eng
Schlagworte:	Animals Biological Transport Calcium - urine Cell Membrane - metabolism Cells, Cultured Diet Fasting Kidney - metabolism Kidney - ultrastructure Kidney Cortex - metabolism Kidney Tubules, Proximal - metabolism Magnesium - urine Male Microvilli - metabolism Phosphates - metabolism Phosphates - urine Phosphorus - administration & dosage Phosphorus - deficiency Rats Sodium - metabolism Thyroidectomy
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creator	Kempson, Stephen A. Shah, Sudhir V. Werness, Peter G. Berndt, Theresa Lee, Peter H. Smith, Lynwood H. Knox, Franklyn G. Dousa, Thomas P.
description	Renal brush border membrane adaptation to phosphorus deprivation: Effects of fasting versus low-phosphorus diet. limentary phosphorus deprivation due to a low-phosphorus diet (LPD) elicits a profound antiphosphaturia and an increase in sodium-dependent inorganic phosphate (Pi) uptake by renal cortical brush border membrane (BBM) vesicles. But, in alimentary phosphorus deprivation due to total fasting, high urinary excretion of Pi persists. In the present study, we determined whether low tubular reabsorption of Pi in fasting is due to a diminished capacity of the specific Pi transport system with the renal cortical luminal BBM or whether it is due to a reduced transepithelial reabsorption of Pi because of metabolic conditions occurring in proximal tubule cells during fasting. Sodium-dependent Pi transport in BBM vesicles isolated from LPD rats was markedly increased compared with fasted rats or rats fed a normal phosphorus diet. Sodium-dependent uptake of D-glucose was significantly lower in LPD rats, compared with fasted animals or animals fed a normal diet. Thus, in contrast to LPD, fasting does not elicit an increase in Pi transport and a decrease in D-glucose transport across the isolated renal BBM. The same differences in BBM transport of Pi were present also in thyroparathyroidectomized rats. Further experiments demonstrated that the adaptation of renal function and the renal BBM transport to LPD are overridden by a subsequent period of total fasting. Results of the present study show that fasting both prevents and reverses the renal response of rats to alimentary phosphorus deprivation. The differences in Pi excretion between fasted rats, LPD rats, and LPD rats subsequently fasted are attributed, at least in part, to specific adaptive changes in sodium-dependent Pi transport across the luminal BBM, rather than to alterations in other cellular (metabolic) components of transepithelial Pi reabsorption in the proximal tubule. Adaptation de la bordure en brosse rénale à la privation de phosphore: Effets du jeûne comparé à une alimentation pauvre en phosphore. La privation de phosphore alimentaire, obtenue au moyen d'une alimentation pauvre en phosphore (LPD), détermine une chute importante de la phosphaturie et une augmentation de la captation sodium-dépendante de phosphore (Pi) par les vésicules de la membrane de bordure en brosse (BBM). Dans la privation alimentaire de phosphore due au jeûne total, cependant, une excrétion urinaire élevée de phosphore
doi_str_mv	10.1038/ki.1980.108
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But, in alimentary phosphorus deprivation due to total fasting, high urinary excretion of Pi persists. In the present study, we determined whether low tubular reabsorption of Pi in fasting is due to a diminished capacity of the specific Pi transport system with the renal cortical luminal BBM or whether it is due to a reduced transepithelial reabsorption of Pi because of metabolic conditions occurring in proximal tubule cells during fasting. Sodium-dependent Pi transport in BBM vesicles isolated from LPD rats was markedly increased compared with fasted rats or rats fed a normal phosphorus diet. Sodium-dependent uptake of D-glucose was significantly lower in LPD rats, compared with fasted animals or animals fed a normal diet. Thus, in contrast to LPD, fasting does not elicit an increase in Pi transport and a decrease in D-glucose transport across the isolated renal BBM. The same differences in BBM transport of Pi were present also in thyroparathyroidectomized rats. Further experiments demonstrated that the adaptation of renal function and the renal BBM transport to LPD are overridden by a subsequent period of total fasting. Results of the present study show that fasting both prevents and reverses the renal response of rats to alimentary phosphorus deprivation. The differences in Pi excretion between fasted rats, LPD rats, and LPD rats subsequently fasted are attributed, at least in part, to specific adaptive changes in sodium-dependent Pi transport across the luminal BBM, rather than to alterations in other cellular (metabolic) components of transepithelial Pi reabsorption in the proximal tubule. Adaptation de la bordure en brosse rénale à la privation de phosphore: Effets du jeûne comparé à une alimentation pauvre en phosphore. La privation de phosphore alimentaire, obtenue au moyen d'une alimentation pauvre en phosphore (LPD), détermine une chute importante de la phosphaturie et une augmentation de la captation sodium-dépendante de phosphore (Pi) par les vésicules de la membrane de bordure en brosse (BBM). Dans la privation alimentaire de phosphore due au jeûne total, cependant, une excrétion urinaire élevée de phosphore persiste. Dans ce travail nous avons cherché à établir si la faible réabsorption tubulaire de Pi au cours du jeûne est due à une diminution de la capacité du transport spécifique de Pi par BBM ou si elle est liée aux conditions métaboliques prévalant dans les cellules tubulaires proximales du fait du jeûne. Le transport sodium-dépendant de Pi par BBM obtenues de rats LPD est fortement augmenté par comparaison avec les résultats que donnent des rats à jeun ou des rats recevant une alimentation normale en Pi. La captation de D-glucose est significativement plus faible chez les rats LPD par comparaison avec les animaux à jeun ou les animaux recevant une alimentation normale. Ainsi, à l'opposé de LPD, le jeûne ne détermine pas une augmentation du transport de Pi et une diminution du transport du glucose à travers BBM isolées. Les mêmes différences sont observées chez des rats thyroparathyroïdectomisés. D'autres expériences démontrent que l'adaptation de la fonction rénale et du transport par BBM à LPD est effacée par une période ultérieure de jeûne total. Ces résultats montrent que la jeûne empêche et inverse la réponse rénale de rats LPD. La différence d'excrétion de Pi entre les rats à jeun, LPD, LPD ultérieurement à jeun est attribuée, au moins en partie, à des modifications adaptatives spécifiques du transport de Pi sodium-dépendant à travers BBM, plutôt qu'à des modifications d'autres composants cellulaires de la réabsorption transépithéliale de Pi dans le tube proximal.</description><identifier>ISSN: 0085-2538</identifier><identifier>EISSN: 1523-1755</identifier><identifier>DOI: 10.1038/ki.1980.108</identifier><identifier>PMID: 7218659</identifier><language>eng</language><publisher>United States: Elsevier Inc</publisher><subject>Animals ; Biological Transport ; Calcium - urine ; Cell Membrane - metabolism ; Cells, Cultured ; Diet ; Fasting ; Kidney - metabolism ; Kidney - ultrastructure ; Kidney Cortex - metabolism ; Kidney Tubules, Proximal - metabolism ; Magnesium - urine ; Male ; Microvilli - metabolism ; Phosphates - metabolism ; Phosphates - urine ; Phosphorus - administration & dosage ; Phosphorus - deficiency ; Rats ; Sodium - metabolism ; Thyroidectomy</subject><ispartof>Kidney international, 1980-07, Vol.18 (1), p.36-47</ispartof><rights>1980 International Society of Nephrology</rights><lds50>peer_reviewed</lds50><oa>free_for_read</oa><woscitedreferencessubscribed>false</woscitedreferencessubscribed><citedby>FETCH-LOGICAL-c457t-6da24e8b07ac8114888638f93f9f8b49fc8c0fa210386a80df7b06c16d90b9363</citedby><cites>FETCH-LOGICAL-c457t-6da24e8b07ac8114888638f93f9f8b49fc8c0fa210386a80df7b06c16d90b9363</cites></display><links><openurl>$$Topenurl_article</openurl><openurlfulltext>$$Topenurlfull_article</openurlfulltext><thumbnail>$$Tsyndetics_thumb_exl</thumbnail><link.rule.ids>314,780,784,27924,27925</link.rule.ids><backlink>$$Uhttps://www.ncbi.nlm.nih.gov/pubmed/7218659$$D View this record in MEDLINE/PubMed$$Hfree_for_read</backlink></links><search><creatorcontrib>Kempson, Stephen A.</creatorcontrib><creatorcontrib>Shah, Sudhir V.</creatorcontrib><creatorcontrib>Werness, Peter G.</creatorcontrib><creatorcontrib>Berndt, Theresa</creatorcontrib><creatorcontrib>Lee, Peter H.</creatorcontrib><creatorcontrib>Smith, Lynwood H.</creatorcontrib><creatorcontrib>Knox, Franklyn G.</creatorcontrib><creatorcontrib>Dousa, Thomas P.</creatorcontrib><title>Renal brush border membrane adaptation to phosphorus deprivation: Effects of fasting versus low-phosphorus diet</title><title>Kidney international</title><addtitle>Kidney Int</addtitle><description>Renal brush border membrane adaptation to phosphorus deprivation: Effects of fasting versus low-phosphorus diet. limentary phosphorus deprivation due to a low-phosphorus diet (LPD) elicits a profound antiphosphaturia and an increase in sodium-dependent inorganic phosphate (Pi) uptake by renal cortical brush border membrane (BBM) vesicles. But, in alimentary phosphorus deprivation due to total fasting, high urinary excretion of Pi persists. In the present study, we determined whether low tubular reabsorption of Pi in fasting is due to a diminished capacity of the specific Pi transport system with the renal cortical luminal BBM or whether it is due to a reduced transepithelial reabsorption of Pi because of metabolic conditions occurring in proximal tubule cells during fasting. Sodium-dependent Pi transport in BBM vesicles isolated from LPD rats was markedly increased compared with fasted rats or rats fed a normal phosphorus diet. Sodium-dependent uptake of D-glucose was significantly lower in LPD rats, compared with fasted animals or animals fed a normal diet. Thus, in contrast to LPD, fasting does not elicit an increase in Pi transport and a decrease in D-glucose transport across the isolated renal BBM. The same differences in BBM transport of Pi were present also in thyroparathyroidectomized rats. Further experiments demonstrated that the adaptation of renal function and the renal BBM transport to LPD are overridden by a subsequent period of total fasting. Results of the present study show that fasting both prevents and reverses the renal response of rats to alimentary phosphorus deprivation. The differences in Pi excretion between fasted rats, LPD rats, and LPD rats subsequently fasted are attributed, at least in part, to specific adaptive changes in sodium-dependent Pi transport across the luminal BBM, rather than to alterations in other cellular (metabolic) components of transepithelial Pi reabsorption in the proximal tubule. Adaptation de la bordure en brosse rénale à la privation de phosphore: Effets du jeûne comparé à une alimentation pauvre en phosphore. La privation de phosphore alimentaire, obtenue au moyen d'une alimentation pauvre en phosphore (LPD), détermine une chute importante de la phosphaturie et une augmentation de la captation sodium-dépendante de phosphore (Pi) par les vésicules de la membrane de bordure en brosse (BBM). Dans la privation alimentaire de phosphore due au jeûne total, cependant, une excrétion urinaire élevée de phosphore persiste. Dans ce travail nous avons cherché à établir si la faible réabsorption tubulaire de Pi au cours du jeûne est due à une diminution de la capacité du transport spécifique de Pi par BBM ou si elle est liée aux conditions métaboliques prévalant dans les cellules tubulaires proximales du fait du jeûne. Le transport sodium-dépendant de Pi par BBM obtenues de rats LPD est fortement augmenté par comparaison avec les résultats que donnent des rats à jeun ou des rats recevant une alimentation normale en Pi. La captation de D-glucose est significativement plus faible chez les rats LPD par comparaison avec les animaux à jeun ou les animaux recevant une alimentation normale. Ainsi, à l'opposé de LPD, le jeûne ne détermine pas une augmentation du transport de Pi et une diminution du transport du glucose à travers BBM isolées. Les mêmes différences sont observées chez des rats thyroparathyroïdectomisés. D'autres expériences démontrent que l'adaptation de la fonction rénale et du transport par BBM à LPD est effacée par une période ultérieure de jeûne total. Ces résultats montrent que la jeûne empêche et inverse la réponse rénale de rats LPD. 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But, in alimentary phosphorus deprivation due to total fasting, high urinary excretion of Pi persists. In the present study, we determined whether low tubular reabsorption of Pi in fasting is due to a diminished capacity of the specific Pi transport system with the renal cortical luminal BBM or whether it is due to a reduced transepithelial reabsorption of Pi because of metabolic conditions occurring in proximal tubule cells during fasting. Sodium-dependent Pi transport in BBM vesicles isolated from LPD rats was markedly increased compared with fasted rats or rats fed a normal phosphorus diet. Sodium-dependent uptake of D-glucose was significantly lower in LPD rats, compared with fasted animals or animals fed a normal diet. Thus, in contrast to LPD, fasting does not elicit an increase in Pi transport and a decrease in D-glucose transport across the isolated renal BBM. The same differences in BBM transport of Pi were present also in thyroparathyroidectomized rats. Further experiments demonstrated that the adaptation of renal function and the renal BBM transport to LPD are overridden by a subsequent period of total fasting. Results of the present study show that fasting both prevents and reverses the renal response of rats to alimentary phosphorus deprivation. The differences in Pi excretion between fasted rats, LPD rats, and LPD rats subsequently fasted are attributed, at least in part, to specific adaptive changes in sodium-dependent Pi transport across the luminal BBM, rather than to alterations in other cellular (metabolic) components of transepithelial Pi reabsorption in the proximal tubule. Adaptation de la bordure en brosse rénale à la privation de phosphore: Effets du jeûne comparé à une alimentation pauvre en phosphore. La privation de phosphore alimentaire, obtenue au moyen d'une alimentation pauvre en phosphore (LPD), détermine une chute importante de la phosphaturie et une augmentation de la captation sodium-dépendante de phosphore (Pi) par les vésicules de la membrane de bordure en brosse (BBM). Dans la privation alimentaire de phosphore due au jeûne total, cependant, une excrétion urinaire élevée de phosphore persiste. Dans ce travail nous avons cherché à établir si la faible réabsorption tubulaire de Pi au cours du jeûne est due à une diminution de la capacité du transport spécifique de Pi par BBM ou si elle est liée aux conditions métaboliques prévalant dans les cellules tubulaires proximales du fait du jeûne. Le transport sodium-dépendant de Pi par BBM obtenues de rats LPD est fortement augmenté par comparaison avec les résultats que donnent des rats à jeun ou des rats recevant une alimentation normale en Pi. La captation de D-glucose est significativement plus faible chez les rats LPD par comparaison avec les animaux à jeun ou les animaux recevant une alimentation normale. Ainsi, à l'opposé de LPD, le jeûne ne détermine pas une augmentation du transport de Pi et une diminution du transport du glucose à travers BBM isolées. Les mêmes différences sont observées chez des rats thyroparathyroïdectomisés. D'autres expériences démontrent que l'adaptation de la fonction rénale et du transport par BBM à LPD est effacée par une période ultérieure de jeûne total. Ces résultats montrent que la jeûne empêche et inverse la réponse rénale de rats LPD. La différence d'excrétion de Pi entre les rats à jeun, LPD, LPD ultérieurement à jeun est attribuée, au moins en partie, à des modifications adaptatives spécifiques du transport de Pi sodium-dépendant à travers BBM, plutôt qu'à des modifications d'autres composants cellulaires de la réabsorption transépithéliale de Pi dans le tube proximal.</abstract><cop>United States</cop><pub>Elsevier Inc</pub><pmid>7218659</pmid><doi>10.1038/ki.1980.108</doi><tpages>12</tpages><oa>free_for_read</oa></addata></record>
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subjects	Animals Biological Transport Calcium - urine Cell Membrane - metabolism Cells, Cultured Diet Fasting Kidney - metabolism Kidney - ultrastructure Kidney Cortex - metabolism Kidney Tubules, Proximal - metabolism Magnesium - urine Male Microvilli - metabolism Phosphates - metabolism Phosphates - urine Phosphorus - administration & dosage Phosphorus - deficiency Rats Sodium - metabolism Thyroidectomy
title	Renal brush border membrane adaptation to phosphorus deprivation: Effects of fasting versus low-phosphorus diet
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