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Disease
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Target Concepts:
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Query: UNIPROT:P41181 (
collecting duct
)
5,183
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Intercalated cells are highly specialized cells within the renal
collecting duct
epithelium and play an important role in systemic acid-base homoeostasis. Whereas type A intercalated cells secrete protons via an apically localized H+-ATPase, type B intercalated cells secrete HCO3-. Type B intercalated cells specifically express the HCO3-/Cl- exchanger AE4 (anion exchanger 4), encoded by Slc4a9. Mice with a targeted disruption of the gene for the
forkhead transcription factor
Foxi1 display renal tubular acidosis due to an intercalated cell-differentiation defect. Collecting duct cells in these mice are characterized by the absence of inter-calated cell markers including AE4. To test whether Slc4a9 is a direct target gene of Foxi1, an AE4 promoter construct was generated for a cell-based reporter gene assay. Co-transfection with the Foxi1 cDNA resulted in an approx. 100-fold activation of the AE4 promoter construct. By truncating the AE4 promoter at the 5'-end, we demonstrate that a fragment of approx. 462 bp upstream of the transcription start point is sufficient to mediate activation by Foxi1. Sequence analysis of this region revealed at least eight potential binding sites for Foxi1 in both sense and antisense orientation. Only one element was bound by recombinant Foxi1 protein in bandshift assays. Mutation of this site abolished both binding in bandshift assays and transcriptional activation by co-transfection of Foxi1 in the reporter gene assay. We thus identify the AE4 promoter as a direct target of Foxi1.
...
PMID:The forkhead transcription factor Foxi1 directly activates the AE4 promoter. 1615 12
Maintenance of the composition of inner ear fluid and regulation of electrolytes and acid-base homeostasis in the
collecting duct
system of the kidney require an overlapping set of membrane transport proteins regulated by the
forkhead transcription factor
FOXI1. In two unrelated consanguineous families, we identified three patients with novel homozygous missense mutations in
FOXI1
(p.L146F and p.R213P) predicted to affect the highly conserved DNA binding domain. Patients presented with early-onset sensorineural deafness and distal renal tubular acidosis. In cultured cells, the mutations reduced the DNA binding affinity of FOXI1, which hence, failed to adequately activate genes crucial for normal inner ear function and acid-base regulation in the kidney. A substantial proportion of patients with a clinical diagnosis of inherited distal renal tubular acidosis has no identified causative mutations in currently known disease genes. Our data suggest that recessive mutations in FOXI1 can explain the disease in a subset of these patients.
...
PMID:Acidosis and Deafness in Patients with Recessive Mutations in FOXI1. 2924 49
Acid-base balance is critical for normal life. Acute and chronic disturbances impact cellular energy metabolism, endocrine signaling, ion channel activity, neuronal activity, and cardiovascular functions such as cardiac contractility and vascular blood flow. Maintenance and adaptation of acid-base homeostasis are mostly controlled by respiration and kidney. The kidney contributes to acid-base balance by reabsorbing filtered bicarbonate, regenerating bicarbonate through ammoniagenesis and generation of protons, and by excreting acid. This review focuses on acid-base disorders caused by renal processes, both inherited and acquired. Distinct rare inherited monogenic diseases affecting acid-base handling in the proximal tubule and
collecting duct
have been identified. In the proximal tubule, mutations of solute carrier 4A4 (SLC4A4) (electrogenic Na
+
/HCO
3
-
-cotransporter Na
+
/bicarbonate cotransporter e1 [NBCe1]) and other genes such as CLCN5 (Cl
-
/H
+
-antiporter), SLC2A2 (GLUT2 glucose transporter), or EHHADH (enoyl-CoA, hydratase/3-hydroxyacyl CoA dehydrogenase) causing more generalized proximal tubule dysfunction can cause proximal renal tubular acidosis resulting from bicarbonate wasting and reduced ammoniagenesis. Mutations in adenosine triphosphate ATP6V1 (B1 H
+
-ATPase subunit), ATPV0A4 (a4 H
+
-ATPase subunit), SLC4A1 (anion exchanger 1), and FOXI1 (
forkhead transcription factor
) cause distal renal tubular acidosis type I. Carbonic anhydrase II mutations affect several nephron segments and give rise to a mixed proximal and distal phenotype. Finally, mutations in genes affecting aldosterone synthesis, signaling, or downstream targets can lead to hyperkalemic variants of renal tubular acidosis (type IV). More common forms of renal acidosis are found in patients with advanced stages of chronic kidney disease and are owing, at least in part, to a reduced capacity for ammoniagenesis.
...
PMID:Molecular Pathophysiology of Acid-Base Disorders. 3130 90
