Structural Determinants of Oligomerization of the Aquaporin-4 Channel*

Aquaporin (AQP) 4 is the predominant water channel in the mammalian brain, abundantly expressed in the blood-brain and brain-cerebrospinal fluid interfaces of glial cells. Its function in cerebral water balance has implications in neuropathological disorders, including brain edema, stroke, and head injuries. The 1.8-A crystal structure reveals the molecular basis for the water selectivity of the channel. Unlike the case in the structures of water-selective AQPs AqpZ and AQP1, the asparagines of the 2 Asn-Pro-Ala motifs do not hydrogen bond to the same water molecule; instead, they bond to 2 different water molecules in the center of the channel. Molecular dynamics simulations were performed to ask how this observation bears on the proposed mechanisms for how AQPs remain totally insulating to any proton conductance while maintaining a single file of hydrogen bonded water molecules throughout the channel.

Brownian motion (diffusion) of particles in membranes occurs in a highly anisotropic environment. For such particles a translational mobility (independent of velocity) can be defined if the viscosity of the liquid embedding the membrane is taken into account. The results of a model calculation are presented. They suggest that for a realistic situation translational diffusion should be about four times faster in relation to rotational diffusion than in the isotropic case.

Aquaporin channel-forming integral protein (CHIP) is the first characterized water channel protein (genome symbol AQP1), but the molecular structure of the aqueous pathway through CHIP remains undefined. The two halves of CHIP are sequence-related, and each has three bilayer-spanning domains with the motif asparagine-proline-alanine (NPA) at residues 76-78 (in cytoplasmic loop B) and 192-194 (in extracellular loop E). The NPA motifs are oriented 180 degrees to each other, and the second NPA is near cysteine 189, the known site where mercurials inhibit osmotic water permeability (Pf). When expressed in Xenopus oocytes, the double mutant A73C/C189S exhibited high, mercurial-sensitive Pf similar to wild-type CHIP. Conservative substitutions of slightly greater mass in or near NPA motifs in loop B or loop E in CHIP caused reduced Pf and failure of the protein to localize at the plasma membrane. Certain nonfunctional loop E mutants complemented the truncation mutant D237Z. Formation of mixed oligomers was demonstrated by velocity sedimentation, immunoprecipitation, and analysis of dimeric-CHIP polypeptides. Cellular distributions of individual mutants or complementing pairs of mutants were verified by plasma membrane isolation and confocal microscopy. An hourglass structural model is proposed in which a cytoplasmic chamber (loop B) connects within the membrane to an extracellular chamber (loop E) forming a single, narrow aqueous pathway through each of the CHIP subunits; subunit oligomerization may provide the vertical symmetry necessary for residence within the lipid bilayer.