Ultrastructure of human erythrocyte GLUT1.

This study was undertaken to examine GLUT1 quaternary structure. Independent but complementary methodologies were used to investigate the influence of membrane-solubilizing detergents on GLUT1/lipid/detergent micelle hydrodynamic radii. Hydrodynamic size analysis and electron microscopy of GLUT1/lipid/detergent micelles and freeze-fracture electron microscopy of GLUT1 proteoliposomes support the hypothesis that the glucose transporter is a multimeric (probably tetrameric) complex of GLUT1 proteins. GLUT1 forms a multimeric complex in octyl glucoside that dissociates upon addition of reductant. Some detergents (e.g., CHAPS and dodecyl maltoside) promote the dissociation of GLUT1 oligomers into smaller aggregation states (dimers or monomers). These complexes do not reassemble as larger oligomers when dissociating detergents are subsequently replaced with nondissociating detergents such as octyl glucoside or cholic acid. When dissociating detergents are replaced with lipids, the resulting proteoliposomes catalyze protein-mediated sugar transport, and the subsequent addition of solubilizing, nondissociating detergents generates higher (tetrameric) GLUT1 aggregation states. These findings suggest that some detergents stabilize while others destabilize GLUT1 quaternary structure. GLUT1 does not appear to exchange rapidly between protein/lipid/detergent micelles but is able to self-associate in the plane of the lipid bilayer.

Absence of aquaporin-4 water channels from kidneys of the desert rodent Dipodomys merriami merriami.

Recently, we found that aquaporin-4 (AQP4) is expressed in the S3 segment of renal proximal tubules of mice but not in rat proximal tubules. Because mice have relatively larger papillae than rats, it was proposed that the renal distribution of AQP4 in various species could be related to their maximum urinary concentrating ability. Therefore, kidneys and other tissues of Merriam's desert kangaroo rat, Dipodomys merriami merriami, which produce extremely concentrated urine (up to 5,000 mosmol/kgH(2)O), were examined for AQP4 expression and localization. Contrary to our expectation, AQP4 immunostaining was undetectable in any region of the kidney, and the absence of AQP4 protein was confirmed by Western blotting. By freeze fracture electron microscopy, orthogonal arrays of intramembraneous particles (OAPs) were not detectable in plasma membranes of principal cells and proximal tubules. However, AQP4 protein was readily detectable in gastric parietal and brain astroglial cells. Northern blotting failed to detect AQP4 mRNA in kangaroo rat kidneys, whereas both in situ hybridization and RT-PCR experiments did reveal AQP4 mRNA in collecting ducts and proximal tubules of the S3 segment. These results suggest that renal expression of AQP4 in the kangaroo rat kidney is regulated at the transcriptional or translational level, and the absence of AQP4 may be critical for the extreme urinary concentration that occurs in this species.

Mesoscopic surfactant organization and membrane protein crystallization.

The paucity of detailed X-ray crystallographic structures of integral membrane proteins arises from substantive technical obstacles in the overexpression of multimilligram quantities of protein, and in the crystallization of purified protein-detergent complexes (PDCs). With rare exception, crystal contacts within the lattice are mediated by protein-protein interaction, and the detergent surrounding the protein behaves as a disordered solvent. The addition and use of surfactants that display mesoscopic self-assembly behavior in membrane protein crystallization experiments presents a novel alternative strategy. Well-ordered crystals of the water channel human aquaporin-1 (hAQP1) that diffract to 4 A resolution have been obtained with this approach.

Aquaporin-4 is expressed in basolateral membranes of proximal tubule S3 segments in mouse kidney.

Because of the availability of knockout mouse models to examine renal transport mechanisms, it has become increasingly important to describe the cellular distribution of major renal transporters in mice. We have used immunocytochemistry and freeze-fracture electron microscopy to compare the renal distribution of aquaporin-4 (AQP4) with that previously described in rat. In rat kidney AQP4 is present exclusively in basolateral membranes of collecting duct principal cells. In mice, however, AQP4 was also detected by immunocytochemistry in basolateral membranes of proximal tubule S3 segments, and not detected in S1 and S2 segments of proximal tubule. Freeze-fracture electron microscopy revealed orthogonal arrays of intramembrane particles (OAPs) on the basolateral membranes of the S3 segment. In AQP4-knockout mice, immunostaining was absent and OAPs were found neither in collecting ducts nor in the S3 segment of the proximal tubule. The urinary concentrating capacity after deletion of both AQP1 and AQP4 was further reduced compared with that of AQP1 or AQP4 null mice, suggesting an additive effect of AQP1 and AQP4 in the concentrating mechanism. The functional significance of the apparent species-dependent expression of AQP4 in proximal tubules is unknown, but may relate to physiological differences between rats and mice.

Freeze-fracture analysis of plasma membranes of CHO cells stably expressing aquaporins 1-5.

Several studies suggest that aquaporin water channels can be identified in membranes by freeze-fracture electron microscopy. For this report, Chinese Hamster ovary cells were stably transfected with cDNAs encoding aquaporins 1-5. Measurement of the osmotic water permeability of the cells confirmed that functional protein was expressed and delivered to the plasma membrane. By freeze-fracture electron microscopy, a 20% increase in intramembrane particle (IMP) density was found in plasma membranes of cells expressing AQP2, 3 and 5, and a 100% increase was measured in AQP1-expressing cells, when compared to mock-transfected cells. On membranes of cells expressing AQP4, large aggregates of IMPs were organized into orthogonal arrays, which occupied 10-20% of the membrane surface. IMP aggregates were never seen in AQP2-transfected cells. Hexagonally packed IMP clusters were detected in approximately 5% of the membranes from AQP3-expressing cells. Particle size-distribution analysis of rotary shadowed IMPs showed a significant shift from 13. 5 (control cells) to 8.5 nm or less in AQP-expressing cells; size distribution analysis of unidirectionally shadowed IMPs also showed a significant change when compared to control. Some IMPs in AQP expressing cells had features consistent with the idea that aquaporins are assembled as tetramers. The results demonstrate that in transfected CHO cells, AQP transfection modifies the general appearance and number of IMPs on the plasma membrane, and show that only AQP4 assembles into well-defined IMP arrays.

Molecular characterization of a broad selectivity neutral solute channel.

In all living cells, coordination of solute and water movement across cell membranes is of critical importance for osmotic balance. The current concept is that these processes are of distinct biophysical nature. Here we report the expression cloning of a liver cDNA encoding a unique promiscuous solute channel (AQP9) that confers high permeability for both solutes and water. AQP9 mediates passage of a wide variety of non-charged solutes including carbamides, polyols, purines, and pyrimidines in a phloretin- and mercury-sensitive manner, whereas amino acids, cyclic sugars, Na+, K+, Cl-, and deprotonated monocarboxylates are excluded. The properties of AQP9 define a new evolutionary branch of the major intrinsic protein family of aquaporin proteins and describe a previously unknown mechanism by which a large variety of solutes and water can pass through a single pore, enabling rapid cellular uptake or exit of metabolites with minimal osmotic perturbation.

Three-dimensional organization of a human water channel.

Aquaporins (AQP) are members of the major intrinsic protein (MIP) superfamily of integral membrane proteins and facilitate water transport in various eukaryotes and prokaryotes. The archetypal aquaporin AQP1 is a partly glycosylated water-selective channel that is widely expressed in the plasma membranes of several water-permeable epithelial and endothelial cells. Here we report the three-dimensional structure of deglycosylated, human erythrocyte AQP1, determined at 7 A resolution in the membrane plane by electron crystallography of frozen-hydrated two-dimensional crystals. The structure has an inplane, intramolecular 2-fold axis of symmetry located in the hydrophobic core of the bilayer. The AQP1 monomer is composed of six membrane-spanning, tilted alpha-helices. These helices form a barrel that encloses a vestibular region leading to the water-selective channel, which is outlined by densities attributed to the functionally important NPA boxes and their bridges to the surrounding helices. The intramolecular symmetry within the AQP1 molecule represents a new motif for the topology and design of membrane protein channels, and is a simple and elegant solution to the problem of bidirectional transport across the bilayer.

Very high single channel water permeability of aquaporin-4 in baculovirus-infected insect cells and liposomes reconstituted with purified aquaporin-4.

The insect cell/baculovirus system was used to express the mercurial-insensitive water channel aquaporin-4 (AQP4) for purification and reconstitution. Immunoblot analysis of Sf9 cells infected with recombinant baculovirus showed greatest AQP4 expression at 72 h after infection at a multiplicity-of-infection of 5. Immunostaining and cell membrane fractionation indicated AQP4 plasma membrane expression. Quantitative immunoblot analysis showed approximately 60 microg of AQP4 per milligram of plasma membrane protein (approximately 2 mg of AQP4 protein per liter of Sf9 cell culture). Functional analysis by stopped-flow light scattering indicated that AQP4 functioned as a mercurial-insensitive water-selective transporter. Osmotic water permeability (Pf) in plasma membrane vesicles from AQP4-expressing Sf9 cells was very high (0.053 cm/s at 10 degrees C), weakly temperature dependent (activation energy, 4.5 kcal/mol), and not inhibited by HgCl2. The AQP4 single channel water permeability (p(f)), estimated from Pf and protein amount, was 19 x 10(-14) cm3/s. Purification of AQP4 to a single Coomassie blue-stained protein on SDS-PAGE (1300-fold over homogenate) was achieved by membrane fractionation, carbonate stripping of nonintegral proteins, solubilization in octyl-beta-glucoside, and anion exchange chromatography. AQP4 protein identity was confirmed by mass spectrometry. Reconstitution of purified AQP4 into proteoliposomes increased osmotic water permeability by >40-fold, giving a p(f) of 15 x 10(-14) cm3/s, remarkably greater than that of 4.9 x 10(-14) cm3/s measured in parallel for AQP1. These results establish the first purification of an aquaporin from a heterologous expression system. The high AQP4 p(f) suggests (a) significant functional differences among the aquaporins, (b) inadequacy of existing pore models to account for high water flow and water permselectivity, and (c) possible enhancement of water flow by AQP4 assembly in orthogonal arrays.

Functional analysis and association state of water channel (AQP-1) isoforms purified from six mammals.

Aquaporin-1 (AQP-1) or CHIP28 occurs in glycosylated (glyCHIP) and non-glycosylated (CHIP) forms and solubilization in octyl-beta-D-glucoside (OG) results in a tight association of glyCHIP and CHIP to form a heterodimer. The tight association did not permit separation of the two forms by affinity chromatography. We examined the mechanism of the tight association by enzymatic removal of sugar moieties, utilized organic solvents for preferential solubilization and purified CHIP28 from six mammals for inspection of glycosylation and association state in OG. Removal of terminal saccharides sustained the dimeric state of human CHIP28, while endo-glycosidases induced the transition into monomers, without leaving an affinity tag for separation purposes. Separation was achieved by preferential solubilization of non-glycosylated CHIP28 in CHCl3/MeOH/H2O mixtures. The two CHIP28 forms were solubilized in SDS, chromatographed in OG, and reconstituted into proteoliposomes; pf values were 1.5 and 1.6 x 10(-14) cm3/s (10 degrees C). Among erythrocytes from cow, pig, sheep, rabbit, dog, and horse CHIP28, one out of two molecules was glycosylated and High Performance Size Exclusion Chromatography (HPSEC) analysis also indicated heterodimers in OG; functional analysis of reconstituted proteoliposomes gave single channel water permeabilities, pf's, ranging from 2.0-3.4 x 10(-14) cm3/s (10 degrees C). The results indicate that CHIP28 structure, function, and association in OG are conserved among mammals and establish procedures to obtain glycosylated and non-glycosylated CHIP28 in functional form.

Water transport across mammalian cell membranes.

This review summarizes recent progress in water-transporting mechanisms across cell membranes. Modern biophysical concepts of water transport and new measurement strategies are evaluated. A family of water-transporting proteins (water channels, aquaporins) has been identified, consisting of small hydrophobic proteins expressed widely in epithelial and nonepithelial tissues. The functional properties, genetics, and cellular distributions of these proteins are summarized. The majority of molecular-level information about water-transporting mechanisms comes from studies on CHIP28, a 28-kDa glycoprotein that forms tetramers in membranes; each monomer contains six putative helical domains surrounding a central aqueous pathway and functions independently as a water-selective channel. Only mutations in the vasopressin-sensitive water channel have been shown to cause human disease (non-X-linked congenital nephrogenic diabetes insipidus); the physiological significance of other water channels remains unproven. One mercurial-insensitive water channel has been identified, which has the unique feature of multiple overlapping transcriptional units. Systems for expression of water channel proteins are described, including Xenopus oocytes, mammalian and insect cells, and bacteria. Further work should be directed at elucidation of the role of water channels in normal physiology and disease, molecular analysis of regulatory mechanisms, and water channel structure determination at atomic resolution.

Permeation of protons, potassium ions, and small polar molecules through phospholipid bilayers as a function of membrane thickness.

Two mechanisms have been proposed to account for solute permeation of lipid bilayers. Partitioning into the hydrophobic phase of the bilayer, followed by diffusion, is accepted by many for the permeation of water and other small neutral solutes, but transient pores have also been proposed to account for both water and ionic solute permeation. These two mechanisms make distinctively different predictions about the permeability coefficient as a function of bilayer thickness. Whereas the solubility-diffusion mechanism predicts only a modest variation related to bilayer thickness, the pore model predicts an exponential relationship. To test these models, we measured the permeability of phospholipid bilayers to protons, potassium ions, water, urea, and glycerol. Bilayers were prepared as liposomes, and thickness was varied systematically by using unsaturated lipids with chain lengths ranging from 14 to 24 carbon atoms. The permeability coefficient of water and neutral polar solutes displayed a modest dependence on bilayer thickness, with an approximately linear fivefold decrease as the carbon number varied from 14 to 24 atoms. In contrast, the permeability to protons and potassium ions decreased sharply by two orders of magnitude between 14 and 18 carbon atoms, and leveled off, when the chain length was further extended to 24 carbon atoms. The results for water and the neutral permeating solutes are best explained by the solubility-diffusion mechanism. The results for protons and potassium ions in shorter-chain lipids are consistent with the transient pore model, but better fit the theoretical line predicted by the solubility-diffusion model at longer chain lengths.

Structure and function of kidney water channels.

There is now firm evidence that water transporting proteins are expressed in renal and extrarenal tissues. In the kidney, proximal-type (CHIP28) and collecting duct (WCH-CD) water channels have been identified. We have cloned three kidney cDNAs with homology to the water channel (aquaporin) family, including a mercurial-insensitive water channel (MIWC), and a glycerol-transporting protein (GLIP) in collecting duct basolateral membrane. To elucidate water transporting mechanisms, a series of molecular and spectroscopic studies were carried out on purified CHIP28 protein and expressed chimeric and mutated CHIP28 cDNAs. The results indicate that CHIP28 transports water selectively, that CHIP28 monomers are assembled in membranes as tetramers, but that individual monomers function independently. Monomers contain multiple membrane-spanning helical domains. Based on these data and recent electron crystallography results, a model for water transport is proposed in which water moves through narrow pores located within individual CHIP28 monomers.

The CHIP28 water channel visualized in ice by electron crystallography.

Electron crystallography of frozen-hydrated two-dimensional crystals of deglycosylated human erythrocyte CHIP28 reveals an aqueous vestibule in each monomer leading to the water-selective channel that is enclosed by multiple transmembrane alpha-helices.

Detection of water proximity to tryptophan residues in proteins by single photon radioluminescence.

We recently developed a single photon radioluminescence (SPR) technique to measure submicroscopic distances in biological samples [Bicknese et al., and Shahrokh et al., Biophys. J., 63 (1992) 1256-1279]. SPR arises from the excitation of a fluorophore by the energy deposited from a slowing beta decay electron. The purpose of this study was to detect 3H2O molecules near tryptophan residues in proteins by tryptophan SPR. To detect small SPR signals, a sample compartment with reflective ellipsoidal optics was constructed, and amplified signals from a cooled photomultiplier were resolved by pulse-height analysis. A Monte Carlo calculation was carried out to quantify the relationship between SPR signal and 3H2O-tryptophan proximity. Measurements of tryptophan SPR were made on aqueous tryptophan; dissolved melittin (containing a single tryptophan); native and denatured aldolase; dissolved aldolase, monellin, and human serum albumin; and the integral membrane proteins CHIP28 (containing a putative aqueous pore) and MIP26 using 3H2O or the aqueous-phase probe 3H-3-O-methylglucose (OMG). After subtraction of a Bremsstrahlung background signal, the SPR signal from aqueous tryptophan (cps.microCi-1 mumol-1 +/- SE) was 8.6 +/- 0.2 with 3H2O and 7.8 +/- 0.3 with 3HOMG (n = 8). With 3H2O as donor, the SPR signal (cps.microCi-1 mumol-1) was 9.0 +/- 0.3 for monomeric melittin in low salt (trytophan exposed) and 4.6 +/- 0.8 (n = 9) for tetrameric melittin in high salt (tryptophans buried away from aqueous solution). The ratio of SPR signal obtained for aldolase under denaturing conditions of 8 M urea (fluorophores exposed) versus non-denaturing buffer (fluorophores buried) was 1.53 +/- 0.07 (n = 6). Ratios of SPR signals normalized to fluorescence intensities for monellin, aldolase, and human serum albumin, relative to that for d-tryptophan, were 1.42, 1.09, and 1.04, indicating that the cross-section for excitation of fluorophores in proteins is greater than that for tryptophan in solution. For the CHIP28 and MIP26 proteins in membranes, the ratio of SPR signal obtained with 3H2O versus 3HOMG was 1.35 +/- 0.13 (CHIP28, n = 5) and 0.99 +/- 0.02 (MIP26). These data are consistent with the existence of an aqueous channel through CHIP28 that excludes small solutes. We conclude that tryptophan radioluminescence in proteins is measurable and provides unique information about the presence of local aqueous compartments.

Purification and structure-function analysis of native, PNGase F-treated, and endo-beta-galactosidase-treated CHIP28 water channels.

CHIP28 occurs naturally in glycosylated and nonglycosylated forms. The purpose of this study was to determine the role of glycosylation in CHIP28 structure and function. A new purification procedure based on phenylboronic acid-agarose (PBA) affinity chromatography was developed to isolate CHIP28. In purified native CHIP28 from erythrocytes, approximately 50% of CHIP28 molecules were glycosylated; each mole of glycosylated CHIP28 contained 5.4 kDa of monosaccharides consisting of 2 mol of Fuc, 8 mol of Gal, 1 mol of GalN, 13 mol of GlcN, 3 mol of Man, and 1 mol of Neu5Ac. The proportions of each monosaccharide and the sensitivity to endo-beta-galactosidase indicated that CHIP28 contained polylactosaminyl oligosaccharides. Glycosylated and nonglycosylated CHIP28 remained tightly associated when solubilized in octyl beta-D-glucoside (OG) and could not be separated by conventional chromatographic procedures. To remove the sugar moiety, CHIP28 was enzymatically deglycosylated by PNGase F and purified by Q-Sepharose anion-exchange and Erythrina cristagalli lectin chromatography. High-performance size-exclusion chromatography revealed that native CHIP28 eluted as an apparent dimer, whereas deglycosylated CHIP28 eluted as an apparent monomer. In reconstituted proteoliposomes, deglycosylated CHIP28 had a single channel water permeability (pf) of 3.1 x 10(-14) cm3/s (10 degrees C), not different from that of 3.2 x 10(-14) cm3/s for native CHIP28. Circular dichroism of native and deglycosylated CHIP28 in OG revealed 45% and 48% alpha-helix, respectively; intrinsic tryptophan fluorescence showed no effects of glycosylation on tryptophan environment. Freeze-fracture electron microscopy with rotary shadowing indicated that native and deglycosylated CHIP28 assembled as tetramers in reconstituted proteoliposomes.(ABSTRACT TRUNCATED AT 250 WORDS)

Projection structure of the CHIP28 water channel in lipid bilayer membranes at 12-A resolution.

Osmotic water transport across plasma membranes in erythrocytes and several epithelial cell types is facilitated by CHIP28, a water-selective membrane channel protein. In order to examine the structure of CHIP28 in membranes, large (1.5-2.5-microns diameter), highly ordered, two-dimensional (2-D) crystals of purified and deglycosylated erythrocyte CHIP28 were generated by reconstitution of detergent-solubilized protein into synthetic lipid bilayers via detergent dialysis. Fourier transforms computed from low-dose electron micrographs of such crystals preserved in negative stain display order to 12-A resolution. The crystal lattice is tetragonal (a = b = 99.2 +/- 1.4 A) with plane group symmetry p4g. A projection density map at 12-A resolution defines the molecular boundary and organization of the CHIP28 monomers in the membrane plane. The unit cell contains four CHIP28 dimers, each composed of two oblong-shaped (37 x 25 A ) monomers with opposite orientations. The CHIP28 monomers associate to form tetrameric structures around the 4-fold axes normal to the membrane plane where stain is excluded. The 2-D crystals of CHIP28 display order extending beyond the limit typically achieved by negative staining and therefore may be amenable to high-resolution structure analysis by cryo-electron microscopy.

A 28 kDa sarcolemmal antigen in kidney principal cell basolateral membranes: relationship to orthogonal arrays and MIP26.

Two recently cloned water channels, CHIP28 and WCH-CD, are homologous to MIP26, an integral membrane channel-forming protein found in lens fiber plasma membranes. CHIP28 is found in basolateral and apical plasma membranes of kidney proximal tubules and thin descending limbs of Henle, whereas WCH-CD is apically located in collecting duct principal cells. So far, the putative water channel that may be responsible for the high constitutive permeability of principal cell basolateral membranes has not been identified. Interestingly, freeze-fracture electron microscopy has shown that characteristic orthogonal arrays of intramembrane particles (OAPs) are found on the basolateral plasma membranes of collecting duct principal cells, and that morphologically identical OAPs present in lens fiber cell plasma membranes contain the protein MIP26. Similar OAPs have also been detected on plasma membranes of other cell types including gastric parietal cells, astroglial cells and skeletal muscle fibers. By indirect immunofluorescence, western blotting and northern blotting, MIP26 was found only in lens fibers. In addition, functional studies on reconstituted and oocyte-expressed MIP26 excluded the possibility that MIP26 might be a basolateral water channel in the kidney. However, a polyclonal antibody raised against skeletal muscle sarcolemmal vesicles, which are enriched in OAPs, produced an intense staining of principal cell basolateral plasma membranes in kidney collecting duct and immunoprecipitated a 28 kDa protein from kidney papilla. The immunoprecipitated protein from papilla was not recognized by anti-CHIP28 or anti-MIP26 antibodies, indicating that principal cell basolateral membranes contain a novel member of the CHIP/MIP family. Because this antibody also stained brain astrocyte end feet, which are enriched in OAPs, it is possible that the 28 kDa protein is related to these structures. We conclude that OAPs probably contain related but distinct proteins that may have different membrane channel functions in different cell types.

Tetrameric assembly of CHIP28 water channels in liposomes and cell membranes: a freeze-fracture study.

Channel forming integral protein of 28 kD (CHIP28) functions as a water channel in erythrocytes, kidney proximal tubule and thin descending limb of Henle. CHIP28 morphology was examined by freeze-fracture EM in proteoliposomes reconstituted with purified CHIP28, CHO cells stably transfected with CHIP28k cDNA, and rat kidney tubules. Liposomes reconstituted with HPLC-purified CHIP28 from human erythrocytes had a high osmotic water permeability (Pf0.04 cm/s) that was inhibited by HgCl2. Freeze-fracture replicas showed a fairly uniform set of intramembrane particles (IMPs); no IMPs were observed in liposomes without incorporated protein. By rotary shadowing, the IMPs had a diameter of 8.5 +/- 1.3 nm (mean +/- SD); many IMPs consisted of a distinct arrangement of four smaller subunits surrounding a central depression. IMPs of similar size and appearance were seen on the P-face of plasma membranes from CHIP28k-transfected (but not mock-transfected) CHO cells, rat thin descending limb (TDL) of Henle, and S3 segment of proximal straight tubules. A distinctive network of complementary IMP imprints was observed on the E-face of CHIP28-containing plasma membranes. The densities of IMPs in the size range of CHIP28 IMPs, determined by non-linear regression, were (in IMPs/microns 2): 2,494 in CHO cells, 5,785 in TDL, and 1,928 in proximal straight tubules; predicted Pf, based on the CHIP28 single channel water permeability of 3.6 x 10(-14) cm3/S (10 degrees C), was in good agreement with measured Pf of 0.027 cm/S, 0.075 cm/S, and 0.031 cm/S, respectively, in these cell types. Assuming that each CHIP28 monomer is a right cylindrical pore of length 5 nm and density 1.3 g/cm3, the monomer diameter would be 3.2 nm; a symmetrical arrangement of four cylinders would have a greatest diameter of 7.2 nm, which after correction for the thickness of platinum deposit, is similar to the measured IMP diameter of approximately 8.5 nm. These results provide a morphological signature for CHIP28 water channels and evidence for a tetrameric assembly of CHIP28 monomers in reconstituted proteoliposomes and cell membranes.

Nonpolar environment of tryptophans in erythrocyte water channel CHIP28 determined by fluorescence quenching.

CHIP28 is an abundant water-transporting protein in erythrocytes, kidney proximal tubule, and other fluid-transporting tissues. To determine the environment of the four tryptophans in CHIP28, fluorescence spectra and quenching by polar and nonpolar compounds were measured in stripped human erythrocyte membranes containing CHIP28 and in proteoliposomes reconstituted with purified CHIP28; comparative studies were performed in membranes containing MIP26. Functional analysis showed that CHIP28 water permeability was not affected by the polar quenchers iodide and acrylamide nor the nonpolar n-anthroyloxy fatty acids (n-AF). The emission maximum of CHIP28 tryptophan fluorescence was at 324 +/- 2 nm and did not change with the addition of quenchers; the maximum for MIP26 was at 335 +/- 5 nm. There was weak quenching of CHIP28 tryptophan fluorescence by the polar compounds iodide and acrylamide, with Stern-Volmer constants of 0.13 and 0.71 M-1, respectively. HgCl2 inhibited water permeability by > 95% at 50 microM and quenched CHIP28 fluorescence reversibly by up to 70% with a biphasic concentration dependence; quenching by HgCl2 and acrylamide was not additive. The membrane-associated n-AF probes quenched CHIP28 fluorescence by up to 80% with the greatest quenching for n = 2 and 12; addition of HgCl2 or acrylamide after n-AF caused a small, anthroyloxy-position-dependent increase in quenching which was greatest at n = 6. These studies indicate that the tryptophans in CHIP28 are in a nonpolar, membrane-associated environment. Mathematical modeling of the n-AF results suggests that the tryptophans are clustered near the surface and center of the bilayer.(ABSTRACT TRUNCATED AT 250 WORDS)