4 research outputs found

    Salt and acid-base metabolism in claudin-16 knockdown mice: impact for the pathophysiology of FHHNC patients

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    Claudin-16 is defective in familial hypomagnesemia with hypercalciuria and nephrocalcinosis (FHHNC). Claudin-16 knockdown (CLDN16 KD) mice show reduced cation selectivity in the thick ascending limb. The defect leads to a collapse of the lumen-positive diffusion voltage, which drives Ca2+ and Mg2+ absorption. Because of the reduced tight junction permeability ratio for Na+ over Cl−, we proposed a backleak of NaCl into the lumen. Systemic analysis had revealed lower blood pressure and a moderately increased plasma aldosterone concentration. In this study, we measured the amiloride-sensitive equivalent short-circuit current in isolated, perfused collecting ducts and found it increased by fivefold in CLDN16 KD mice compared with wild-type (WT) mice. Amiloride treatment unmasked renal Na+ loss in the thick ascending limb of the nephron. Under amiloride treatment, CLDN16 KD mice developed hyponatremia and the renal fractional excretion of Na+ was twofold higher in CLDN16 KD compared with WT mice. The loss of claudin-16 also resulted in increased urinary flow, reduced HCO3− excretion, and lower urine pH. We conclude that perturbation in salt and acid-base metabolism in CLDN16 KD mice has its origin in the defective cation permselectivity of the thick ascending limb of the nephron. This study has contributed to the still incomplete understanding of the symptoms of FHHNC patients

    Stat3 Programs Th17-Specific Regulatory T Cells to Control GN

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    A pathogenic role for Th17 cells in inflammatory renal disease is well established. The mechanisms underlying their counter-regulation are, however, largely unknown. Recently, Th17 lineage-specific regulatory T cells (Treg17) that depend on activation of the transcription factor Stat3 were identified. We studied the function of Treg17 in the nephrotoxic nephritis (NTN) model of crescentic GN. The absence of Treg17 cells in Foxp3(Cre)×Stat3(fl/fl) mice resulted in the aggravation of NTN and skewing of renal and systemic immune responses toward Th17. Detailed analysis of Stat3-deficient Tregs revealed that the survival, activation, proliferation, and suppressive function of these cells remained intact. However, Tregs from Foxp3(Cre)×Stat3(fl/fl) mice lacked surface expression of the chemokine receptor CCR6, which resulted in impaired renal trafficking. Furthermore, aggravation of NTN was reversible in the absence of Th17 responses, as shown in CD4(Cre)×Stat3(fl/fl) mice lacking both Treg17 and Th17 cells, suggesting that Th17 cells are indeed the major target of Treg17 cells. Notably, immunohistochemistry revealed CCR6-bearing Treg17 cells in kidney biopsy specimens of patients with GN. CCR6 expression on human Treg17 cells also appears dependent on STAT3, as shown by analysis of Tregs from patients with dominant-negative STAT3 mutations. Our data indicate the presence and involvement of Stat3/STAT3-dependent Treg17 cells that specifically target Th17 cells in murine and human crescentic GN, and suggest the kidney-specific action of these Treg17 cells is regulated by CCR6-directed migration into areas of Th17 inflammation
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