Impairment in renal medulla development underlies salt wasting in Clc-k2 channel deficiency
Meng-Hsuan Lin, … , Bi-Chang Chen, Chih-Jen Cheng
Meng-Hsuan Lin, … , Bi-Chang Chen, Chih-Jen Cheng
Published September 9, 2021
Citation Information: JCI Insight. 2021;6(20):e151039. https://doi.org/10.1172/jci.insight.151039.
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Research Article Nephrology

Impairment in renal medulla development underlies salt wasting in Clc-k2 channel deficiency

Abstract

The prevailing view is that the ClC-Ka chloride channel (mouse Clc-k1) functions in the thin ascending limb to control urine concentration, whereas the ClC-Kb channel (mouse Clc-k2) functions in the thick ascending limb (TAL) to control salt reabsorption. Mutations of ClC-Kb cause classic Bartter syndrome, characterized by renal salt wasting, with perinatal to adolescent onset. We studied the roles of Clc-k channels in perinatal mouse kidneys using constitutive or inducible kidney-specific gene ablation and 2D and advanced 3D imaging of optically cleared kidneys. We show that Clc-k1 and Clc-k2 were broadly expressed and colocalized in perinatal kidneys. Deletion of Clc-k1 and Clc-k2 revealed that both participated in NKCC2- and NCC-mediated NaCl reabsorption in neonatal kidneys. Embryonic deletion of Clc-k2 caused tubular injury and impaired renal medulla and TAL development. Inducible deletion of Clc-k2 beginning after medulla maturation produced mild salt wasting resulting from reduced NCC activity. Thus, both Clc-k1 and Clc-k2 contributed to salt reabsorption in TAL and distal convoluted tubule (DCT) in neonates, potentially explaining the less-severe phenotypes in classic Bartter syndrome. As opposed to the current understanding that salt wasting in adult patients with Bartter syndrome is due to Clc-k2 deficiency in adult TAL, our results suggest that it originates mainly from defects occurring in the medulla and TAL during development.

Authors

Meng-Hsuan Lin, Jen-Chi Chen, Xuejiao Tian, Chia-Ming Lee, I-Shing Yu, Yi-Fen Lo, Shinichi Uchida, Chou-Long Huang, Bi-Chang Chen, Chih-Jen Cheng

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Figure 8

Effects of Clc-k deficiency on renal histology.

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Effects of Clc-k deficiency on renal histology. (A) Top row: H&E-sta...
(A) Top row: H&E-stained kidney longitudinal sections of 2-week-old WT, Clc-k1–/–, Clc-k2–/–, and DKO kidneys (scale bar: 1 mm). Bottom row: Approximate renal areas (scale bars: 500 μm). C, cortex, OS, outer stripe of the outer medulla; IS, inner stripe of the outer medulla; OM, outer medulla; IM, inner medulla. (B) H&E-stained renal cortex of WT, Clc-k1–/–, Clc-k2–/–, and DKO kidneys. In DKO kidneys, the dilated tubules are marked by asterisks, and yellow arrowheads label tubules with desquamation and brush border loss. Both Clc-k2–/– and DKO kidneys are characterized by marked mononuclear cell infiltration in the interstitium and tubular cells with prominent nucleoli, especially those in medullary rays. Scale bars: 50 mm. (C) Quantitation of the degree of tubular injury (32). **P < 0.001 between the designated group and WT mice; #P < 0.05 between Clc-k2–/– and DKO mice using 1-way ANOVA with Šidák’s test for multiple comparisons.