Disruption of mitochondrial electron transport impairs urinary concentration via AMPK-dependent suppression of aquaporin 2
Joshua S. Carty, Ryoichi Bessho, Yvonne Zuchowski, Jonathan B. Trapani, Olena Davidoff, Hanako Kobayashi, Joseph T. Roland, Jason A. Watts, Andrew S. Terker, Fabian Bock, Juan Pablo Arroyo, Volker H. Haase
Joshua S. Carty, Ryoichi Bessho, Yvonne Zuchowski, Jonathan B. Trapani, Olena Davidoff, Hanako Kobayashi, Joseph T. Roland, Jason A. Watts, Andrew S. Terker, Fabian Bock, Juan Pablo Arroyo, Volker H. Haase
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Research Article Cell biology Nephrology

Disruption of mitochondrial electron transport impairs urinary concentration via AMPK-dependent suppression of aquaporin 2

Abstract

Urinary concentration is an energy-dependent process that minimizes body water loss by increasing aquaporin 2 (AQP2) expression in collecting duct (CD) principal cells. To investigate the role of mitochondrial (mt) ATP production in renal water clearance, we disrupted mt electron transport in CD cells by targeting ubiquinone (Q) binding protein QPC (UQCRQ), a subunit of mt complex III essential for oxidative phosphorylation. QPC-deficient mice produced less concentrated urine than controls, both at baseline and after type 2 vasopressin receptor stimulation with desmopressin. Impaired urinary concentration in QPC-deficient mice was associated with reduced total AQP2 protein levels in CD tubules, while AQP2 phosphorylation and membrane trafficking remained unaffected. In cultured inner medullary CD cells treated with mt complex III inhibitor antimycin A, the reduction in AQP2 abundance was associated with activation of 5′ adenosine monophosphate–activated protein kinase (AMPK) and was reversed by treatment with AMPK inhibitor SBI-0206965. In summary, our studies demonstrated that the physiological regulation of AQP2 abundance in principal CD cells was dependent on mt electron transport. Furthermore, our data suggested that oxidative phosphorylation in CD cells was dispensable for maintaining water homeostasis under baseline conditions, but necessary for maximal stimulation of AQP2 expression and urinary concentration.

Authors

Joshua S. Carty, Ryoichi Bessho, Yvonne Zuchowski, Jonathan B. Trapani, Olena Davidoff, Hanako Kobayashi, Joseph T. Roland, Jason A. Watts, Andrew S. Terker, Fabian Bock, Juan Pablo Arroyo, Volker H. Haase

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Figure 1

Efficient recombination of Qpc in HoxB7-Qpc–/– kidneys.

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Efficient recombination of Qpc in HoxB7-Qpc–/– kidneys. (A) Schematic il...
(A) Schematic illustrating the location of targeted DNA sequences within the conditional Qpc allele; loxP sites are depicted by red arrows. The sizes of the Qpc exons (ex) 1 and 2 are shown in base pairs (bp). PCR analysis of total genomic DNA isolated from kidney cortex and medulla of 12-week-old wild-type (wt), HoxB7-Qpc−/− mutants, and Cre littermate control mice. The genotype of mice is indicated by 2, representing the nonrecombined 2-lox allele and by 1, representing the recombined 1-lox allele; + or – indicates the presence or absence of the Cre transgene. (B) Representative images of immunofluorescent (IF) staining for aquaporin 2 (AQP2) and enhanced green fluorescent protein (eGFP) in formalin-fixed, paraffin-embedded kidney sections. Kidney tissues were obtained from 6-week- and 6-month-old HoxB7-mT/mG-Qpc−/− mice. (C) Quantification of eGFP+ and eGFP+AQP2 tubules in kidney cortex and medulla expressed as percentage of (eGFPAQP2+ + eGFP+) or total number of eGFP+ tubules, respectively; n =3, each. Percentages are represented as average mean values ± SD. *P < 0.05 by 2-tailed Student’s t test. NS, not significant. Scale bars: 100 μm. HoxB7, homeobox B7; Qpc, gene encoding ubiquinone-binding protein QPC.