BaseSpace
Correlation Engine 2.0
Import Your Data
Literature

FAQ

More FAQs

Back to top
Clear Search sequence regions
(e.g. rs2230926, MDM2, Angiogenesis, Leukemia, Hypothalamus, Anticancer prodrugs, Lovastatin)
Bookmark Forward

Integrated physiology of proximal tubular organic anion transport.

Naohiko Anzai, Promsuk Jutabha, Yoshikatsu Kanai, Hitoshi Endou

Department of Pharmacology and Toxicology, Kyorin University School of Medicine, 6-20-2 Shinkawa, Tokyo 181-8611, Japan.

Current opinion in nephrology and hypertension 2005 Sep


filter terms:
  • animals (1)
  • anions (2)
  • cell membrane (1)
  • cells (1)
  • diazepam binding inhibitor receptor (1)
  • diazepam- receptor (1)
  • dicarboxylate receptors (2)
  • dicarboxylic acids (2)
  • domain proteins (1)
  • humans (1)
  • ion transport (1)
  • kidney tubules (1)
  • membrane (2)
  • models biological (1)
  • monocarboxylate transporter (1)
  • multidrug resistance- associated protein (1)
  • multiprotein complexes (2)
  • organic anion transport (2)
  • organic anion transport proteins (2)
  • organic anion transporter (4)
  • organic cation transport proteins (2)
  • physiology (2)
  • polypeptide (1)
  • proteins membrane (1)
  • proteins nuclear (2)
  • proteins plasma (1)
  • proteomics (1)
  • PSD 95 (1)
  • receptors cytoplasmic (2)
  • renal diseases (1)
  • renal proximal tubules (2)
  • renovascular hypertension (1)
  • secretion (1)
  • Signal Transduction (1)
  • signaling (3)
  • slc22a12 protein, human (1)
  • sodium (1)
  • sodium phosphate cotransporter proteins (2)
  • transport (3)
  • transport proteins (3)
  • ZO 1 (1)
    • Sizes of these terms reflect their relevance to your search.

    Renal organic anion transport proteins play important roles in the reabsorption and the secretion of endogenous and exogenous compounds. This review focuses on the interpretation of the physiological integration of identified transport molecules in the renal proximal tubules. To date, molecular identification of organic anion transport proteins is still continuing: rodent organic anion transporter 5, organic anion-transporting polypeptide 4C1, voltage-driven organic anion transporter 1, multidrug resistance-associated protein 4, and sodium-coupled monocarboxylate transporter have yielded additional information in this field. In addition, particularly at the apical membrane of the proximal tubules, the importance of the PDZ (PSD-95, DglA, and ZO-1) binding domain proteins has emerged in the formation of the multimolecular complex as a functional unit of membrane transport. Finally, discovery of dicarboxylate receptors in the renal tubular cells raises the possibility that dicarboxylate anions function as intrarenal signaling molecules. This novel aspect of renal organic anion transport, the potential modulation of signaling via dicarboxylate receptors, may be of significant relevance to renovascular hypertension and other renal diseases. Comprehensive understanding of the multimolecular complex, which is composed of transporters and their related signaling elements and is supported by the scaffold proteins underneath the plasma membrane, may be useful in clarifying complex transport phenomena such as renal apical organic anion handling. In addition to the recent proteomics approaches and conventional molecular physiology, it is necessary to develop novel methods to analyze the overall function of the multimolecular complex for the post-genomic era.

    Citation

    Naohiko Anzai, Promsuk Jutabha, Yoshikatsu Kanai, Hitoshi Endou. Integrated physiology of proximal tubular organic anion transport. Current opinion in nephrology and hypertension. 2005 Sep;14(5):472-9

    Expand section icon Mesh Tags

    Expand section icon Substances


    PMID: 16046907

    View Full Text
    • Copyright © 2024 Illumina Inc. All rights reserved.