I S Jensen1, C K Larsen1, J Leipziger1, M V Sørensen1,2. 1. Physiology, Institute of Biomedicine, Aarhus University, Aarhus, Denmark. 2. Aarhus Institute of Advanced Studies (AIAS), Aarhus University, Aarhus, Denmark.
Abstract
AIM: High dietary K(+) intake is associated with protection against hypertension. In mammals, acute K(+) intake induces natriuresis and kaliuresis, associated with a marked dephosphorylation of the renal Na(+) /Cl(-) cotransporter (NCC). It has been suggested that reduced activity of NCC increases the driving force for more distal tubular epithelial Na(+) channel (ENaC)-dependent K(+) secretion. This study investigated the ENaC dependence of urinary K(+) and Na(+) excretion following acute K(+) loading. METHODS: Mice were fed low (0.03%), control (0.2%) or high (2%) Na(+) diets for 25 days to preserve or promote Na(+) loss and thus ENaC activity. Once a week, the mice received either K(+) -containing gavage or a control gavage. Following the gavage treatment, the mice were placed in metabolic cages and urine was collected in real time. ENaC dependence of kaliuresis was assessed by benzamil injections prior to gavage. RESULTS: We confirmed that dietary Na(+) content is inversely related to plasma aldosterone, NCC phosphorylation and ENaC cleavage products. The novel findings were as follows: (i) acute K(+) feeding caused NCC dephosphorylation in all dietary groups; (ii) under all dietary conditions, K(+) loading induced natriuresis; (iii) high Na(+) diet markedly reduced the K(+) excretion following K(+) gavage; (iv) benzamil injection prior to K(+) loading increased natriuresis, decreased kaliuresis and eliminated the differences between the dietary groups. CONCLUSION: These data indicate that acute K(+) -induced kaliuresis is ENaC dependent. Maximal K(+) excretion rates are attenuated when ENaC is physiologically down-regulated or pharmacologically blocked. NCC is dephosphorylated following acute K(+) loading under all dietary Na(+) regimens. This leads to natriuresis, even in severely Na(+) -restricted animals.
AIM: High dietary K(+) intake is associated with protection against hypertension. In mammals, acute K(+) intake induces natriuresis and kaliuresis, associated with a marked dephosphorylation of the renal Na(+) /Cl(-) cotransporter (NCC). It has been suggested that reduced activity of NCC increases the driving force for more distal tubular epithelial Na(+) channel (ENaC)-dependent K(+) secretion. This study investigated the ENaC dependence of urinary K(+) and Na(+) excretion following acute K(+) loading. METHODS:Mice were fed low (0.03%), control (0.2%) or high (2%) Na(+) diets for 25 days to preserve or promote Na(+) loss and thus ENaC activity. Once a week, the mice received either K(+) -containing gavage or a control gavage. Following the gavage treatment, the mice were placed in metabolic cages and urine was collected in real time. ENaC dependence of kaliuresis was assessed by benzamil injections prior to gavage. RESULTS: We confirmed that dietary Na(+) content is inversely related to plasma aldosterone, NCC phosphorylation and ENaC cleavage products. The novel findings were as follows: (i) acute K(+) feeding caused NCC dephosphorylation in all dietary groups; (ii) under all dietary conditions, K(+) loading induced natriuresis; (iii) high Na(+) diet markedly reduced the K(+) excretion following K(+) gavage; (iv) benzamil injection prior to K(+) loading increased natriuresis, decreased kaliuresis and eliminated the differences between the dietary groups. CONCLUSION: These data indicate that acute K(+) -induced kaliuresis is ENaC dependent. Maximal K(+) excretion rates are attenuated when ENaC is physiologically down-regulated or pharmacologically blocked. NCC is dephosphorylated following acute K(+) loading under all dietary Na(+) regimens. This leads to natriuresis, even in severely Na(+) -restricted animals.
Authors: G Ryan Crislip; Lauren G Douma; Sarah H Masten; Kit-Yan Cheng; I Jeanette Lynch; Jermaine G Johnston; Dominique Barral; Krystal B Glasford; Meaghan R Holzworth; Jill W Verlander; Charles S Wingo; Michelle L Gumz Journal: Am J Physiol Renal Physiol Date: 2020-04-27
Authors: María Florencia Albertoni Borghese; María Del Carmen Ortiz; Rocío C Marinoni; Lucas H Oronel; Milena Palamidessi; Carolina A Yarza; Nicolás Di Siervi; Carlos Davio; Mónica P Majowicz Journal: PLoS One Date: 2020-03-03 Impact factor: 3.240
Authors: Gene Ryan Crislip; Stephanie E Wohlgemuth; Christopher A Wolff; Miguel A Gutierrez-Monreal; Collin M Douglas; Elnaz Ebrahimi; Kit-Yan Cheng; Sarah H Masten; Dominique Barral; Andrew J Bryant; Karyn A Esser; Michelle L Gumz Journal: Biomolecules Date: 2022-02-05