The Aquaporins, Blueprints for Cellular Plumbing Systems*

Membrane Water Permeability Plasma membranes provide an effective barrier to the extracellular environment. Water was long believed to move through lipid bilayers by simple diffusion; however, membranes from different tissues vary in their permeability to water. The variability is particularly evident in mammalian kidney where proximal tubules and descending thin limbs of Henle’s loop have constitutively high water permeability and are responsible for reabsorption of more than 150 liters per day in adult humans. In contrast, ascending thin limbs have very low water permeability. Renal distal tubules empty into collecting ducts where stimulation with vasopressin causes an increase in water permeability (see Ref. 1 for review). These observations led to the suggestion that specialized water transport molecules must exist in membranes with intrinsically high water permeability. Nevertheless, despite extensive studies, the molecular identity of water transport proteins remained elusive until recently. The well defined features of membrane water permeability permitted serendipitous identification of the first known water channel. While purifying the 32-kDa subunit of the red cell Rh blood group antigen, a new 28-kDa polypeptide was discovered (2). Detailed biochemical studies of this newly identified tetrameric membrane protein were made easy by its low solubility in N-lauroylsarcosine, which permitted simple purification (3). The abundance of the protein in rat renal proximal tubules and descending thin limbs (2) sparked the idea that the 28-kDa polypeptide may be the long sought water channel, and its unique N-terminal amino acid sequence permitted cloning from an erythroid cDNA library (4).

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