Water channels and barriers formed by claudins

Physiological studies in leaky epithelia, like kidney proximal tubules and the small intestine, have documented water transport via both transcellular and paracellular pathways. The discovery of aquaporin water channels provided a molecular basis for transcellular water movement. In contrast, the co...

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Bibliographic Details
Published in:Annals of the New York Academy of Sciences 2017-06, Vol.1397 (1), p.100-109
Main Authors: Rosenthal, Rita, Günzel, Dorothee, Theune, Dian, Czichos, Carolina, Schulzke, Jörg‐Dieter, Fromm, Michael
Format: Article
Language:English
Subjects:
Animals
Aquaporins
Aquaporins - metabolism
Biological Transport
Channels
Claudin-2 - metabolism
claudins
Claudins - metabolism
Computer applications
Forming
Groundwater flow
Humans
Ion channels
Ions
Kidney Tubules, Proximal - metabolism
Kidneys
paracellular water transport
Permeability
Permeation
Physiology
Pore size
Porosity
Proximal tubules
Sealing
Small intestine
Solutes
tight junction
Tight Junctions - metabolism
Transport
Water - metabolism
Water chemistry
Water transport
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Summary:Physiological studies in leaky epithelia, like kidney proximal tubules and the small intestine, have documented water transport via both transcellular and paracellular pathways. The discovery of aquaporin water channels provided a molecular basis for transcellular water movement. In contrast, the contribution, or even existence, of a specific paracellular water pathway has been disputed for a long time, until the cation channel–forming tight junction protein claudin‐2 was shown to also permit the paracellular passage of water through its pore. In proximal kidney tubules, claudin‐2–based water transport contributes 23–30% of the total water transport. Other paracellular ion channels (claudin‐10a, ‐10b, and ‐17) proved to be impermeable to water, although their pore size would be sufficient for water molecules to pass. Studies of barrier‐forming claudins, like claudin‐1 and claudin‐3, which tighten the paracellular pathway against ions and larger solutes, indicate that changes in the expression of these sealing claudins do not influence transepithelial water permeability. The present genetic, molecular, computational, and physiological studies are just now beginning to probe the mechanisms and regulation of paracellular permeation.
ISSN:0077-8923
1749-6632
DOI:10.1111/nyas.13383