Integrated compensatory network is activated in the absence of NCC phosphorylation
P. Richard Grimm, … , James B. Wade, Paul A. Welling
P. Richard Grimm, … , James B. Wade, Paul A. Welling
Published April 20, 2015
Citation Information: J Clin Invest. 2015;125(5):2136-2150. https://doi.org/10.1172/JCI78558.
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Research Article Nephrology

Integrated compensatory network is activated in the absence of NCC phosphorylation

Abstract

Thiazide diuretics are used to treat hypertension; however, compensatory processes in the kidney can limit antihypertensive responses to this class of drugs. Here, we evaluated compensatory pathways in SPAK kinase–deficient mice, which are unable to activate the thiazide-sensitive sodium chloride cotransporter NCC (encoded by Slc12a3). Global transcriptional profiling, combined with biochemical, cell biological, and physiological phenotyping, identified the gene expression signature of the response and revealed how it establishes an adaptive physiology. Salt reabsorption pathways were created by the coordinate induction of a multigene transport system, involving solute carriers (encoded by Slc26a4, Slc4a8, and Slc4a9), carbonic anhydrase isoforms, and V-type H+-ATPase subunits in pendrin-positive intercalated cells (PP-ICs) and ENaC subunits in principal cells (PCs). A distal nephron remodeling process and induction of jagged 1/NOTCH signaling, which expands the cortical connecting tubule with PCs and replaces acid-secreting α-ICs with PP-ICs, were partly responsible for the compensation. Salt reabsorption was also activated by induction of an α-ketoglutarate (α-KG) paracrine signaling system. Coordinate regulation of a multigene α-KG synthesis and transport pathway resulted in α-KG secretion into pro-urine, as the α-KG–activated GPCR (Oxgr1) increased on the PP-IC apical surface, allowing paracrine delivery of α-KG to stimulate salt transport. Identification of the integrated compensatory NaCl reabsorption mechanisms provides insight into thiazide diuretic efficacy.

Authors

P. Richard Grimm, Yoskaly Lazo-Fernandez, Eric Delpire, Susan M. Wall, Susan G. Dorsey, Edward J. Weinman, Richard Coleman, James B. Wade, Paul A. Welling

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Figure 1

SPAK KO transcript profile.

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SPAK KO transcript profile. (A) Heatmap rendering of the transcript exp...
(A) Heatmap rendering of the transcript expression profile of SPAK KO and WT mice (n = 4 mice per group). Differentially expressed genes in kidney cortex are shown. Each individual block represents the relative transcript level of an individual gene. Genes are arranged by row according to the FDR (from high [top] to low [bottom], with a lower-limit FDR <0.05). Each column represents the profile of an individual mouse. (B) GO classification of genes by biological function revealed that the SPAK KO profile was significantly enriched in 5 major functional classes. Level of significance (–log of the P value) is plotted for each significant GO term. Individual GO terms are arranged according to major functional class. (C) Number of SPAK-upregulated (red) and -downregulated (green) profile genes that were exclusively expressed in individual nephron segments. Glom, glomerulus; cTAL, cortical TAL.