Structural organization of (Na+ + K+)-ATPase in purified membranes

Reconstitution of detergent-solubilized Na,K-ATPase and formation of two-dimensional crystals

Very pure, detergent-solubilized Na,K-ATPase from dog or lamb kidneys has been successfully reconstituted at high protein-to-lipid weight ratios. Studies have been conducted to establish the orientation of the Na,K-ATPase molecules in the reconstituted membranes and to assess the functional activity and the conformational state of the reconstituted enzyme. Results indicate that reincorporation of the Na,K-ATPase molecules in the lipid bilayer is unidirectional and that the reconstituted enzyme retains its functional and structural integrity. Two-dimensional crystals have been induced in these preparations by vanadate ions. The arrays, with a dimeric structure in the unit cell, have a morphology similar to that of the crystals that had previously formed in the native membranes. Filtered images show that in projection, the molecule had an asymmetrical mass distribution, which at the resolution of 2.5 nm is identical to that of the earlier crystals. These sheets, although small, represent the first crystals of Na, K-ATPase to be formed by reconstitution. We expect that optimization of the reconstitution and crystallization parameters will lead to larger and better-ordered sheets, suitable for electron crystallography.

Molecular imaging of Na+,K(+)-ATPase in purified kidney membranes

Ion channels and pumps in cell membranes consist of multiple transmembrane segments that are thought to be critical for transport of ions. Channel structures constituted by these transmembrane segments are characteristic of ion channels, whereas such structures have not been identified in ion pumps until now. By applying atomic force microscopy on Na+,K(+)-ATPase molecules in canine kidney membranes under tapping mode, we identified a hollow in the protein with a characteristic internal diameter of 6-20 A and an external diameter of 20-55 A depending upon treatment conditions. This hollow may be interpreted as a channel-like conformation of Na+,K(+)-ATPase. In the regions where the proteins were absent, lipid head structures with 2 A width and 6 A length were imaged in an orthorhombic lattice.

Na,K-ATPase and carboxyfluorescein distinctly alter vesicle formation in vitro

The mechanism of vesicle formation as well as the precise reasons for their stability are not known. Thus, it is necessary to simulate the process in vitro for studying its mechanism. If phospholipids are suspended in physiological solution by means of cholate and the detergent is then removed by dialysis, the phospholipids self-assemble to form unilamellar vesicles. We report here that the addition of Na,K-ATPase (an integral membrane protein) to the phospholipids changes the vesicle structure, they become larger and a multilamellar population appears. By contrast, carboxyfluorescein, a compound commonly used for labelling the aqueous vesicle compartment, produces an unexpected effect on vesicle structure by inducing complex, tore-like intravesicular multilayer formations associated with a 5-fold increase in diameter. Thus, the presence of a protein in the membrane phase or of a compound in the water phase can influence and direct vesicle formation in vitro; these model systems might give some clues to possible physicochemical or biological factors governing the formation of natural membrane structures.

A pH induced two-dimensional crystal of membrane-bound Na+,K(+)-ATPase of dog kidney

Two-dimensional crystals of membrane-bound Na+,K(+)-ATPase were formed in acidic media and their qualities were investigated by electron cryo-microscopy as well as by conventional electron microscopy. At pH 4.8 in sodium citrate buffer, the best crystallization condition, more than 80% of membranes formed crystals. The high ratio allowed high-resolution images to be taken by electron cryo-microscopy. Image processing revealed that they had unique lattice constants (a = 108.7 A, b = 66.2 A, gamma = 104.2 degrees) and had few defects in the crystalline arrays. The reconstituted Fourier map of the ice-embedded crystal showed that there are two high contrast parts in one unit cell.

Quantitative immunogold localization of Na, K-ATPase along rat nephron

Ultrastructural localization of Na, K-ATPase alpha-subunit along rat nephron segments was investigated quantitatively by immunogold electron microscopy on LR-White ultrathin sections using affinity-purified antibody against alpha-subunit of the enzyme. Ultrathin sections were incubated with the antibody at a saturation level and the number of gold particles bound per micron of the plasma membrane (particle density) of the tubular epithelial cells from the proximal tubule to the collecting duct was determined. In all the tubular epithelial cells, gold particles were located exclusively on the basolateral surface, and no significant binding of gold particles to the apical surface was observed. Distribution of gold particles on the basolateral membranes was quite heterogeneous; lateral membranes and infolded basal membranes were highly labeled, whereas the basal membranes which are in direct contact with the basal lamina were scarcely labeled. The average particle density on the basal surface was highest in the distal straight tubule cells (11.4 units), very high in the distal convoluted tubule cells (9.8 units), intermediate in the proximal tubule cells (3.3 units), in the connecting tubule cells (4.3 units), and in the principal cells of the collecting duct (5.6-3.8 units), low in the thin limb of Henle's loop (1.0 unit), and at the control level in the intercalated cells in the connecting and collecting duct. The relative number of gold particles/mm nephron segment and the relative number of gold particles in the various nephron segments were calculated using quantitative morphological data. The estimated distribution profile of the former was in good agreement with the Na, K-ATPase activity profile in rat nephron, which was determined biochemically with a microenzymatic method.

Structural dynamics and oligomeric interactions of Na+,K(+)-ATPase as monitored using fluorescence energy transfer

The oligomeric nature of the purified lamb kidney Na+,K(+)-ATPase was investigated by measuring the fluorescence energy transfer between catalytic (alpha) subunits following sequential labeling with fluorescein 5'-isothiocyanate (FITC) and erythrosin 5'-isothiocyanate (ErITC). Although these two probes had different spectral responses upon reaction with the enzyme, our studies suggest that a sizeable proportion of their binding occurs at the same ATP protectable, active site domain of alpha. Fluorescence energy transfer (FET) from donor (FITC) to acceptor (ErITC) revealed an apparent 56 A distance between the putative ATP binding sites of alpha subunits, which is consistent with (alpha beta)2 dimers rather than randomly spaced alpha beta heteromonomers. In this work, methods were introduced to eliminate the contribution of nonspecific probe labeling to FET values and to determine the most probable orientation factor (K2) for these rigidly bound fluorophores. FET measurements between anthroylouabain/ErITC, 5'-iodoacetamide fluorescein (5'IAF)/ErITC, and TNP-ATP/FITC, donor/acceptor pairs were also made. Interestingly, none of these distances were affected by ligand-dependent changes in enzyme conformation. These results and those from electron microscopy imaging (Ting-Beall et al. 1990. FEBS Lett. 265:121) suggest a model in which ATP binding sites of (alpha beta)2 dimers are 56 A apart, and reside 30 A from the intracellular surface of the membrane contiguous with the phosphorylation domain.

Two-dimensional crystallization of membrane proteins

In spite of several great breakthroughs, the overall rate of progress in determining high-resolution structures of membrane proteins has been slow. This is entirely due to the scarcity of suitable, well-ordered crystals. Most membrane proteins are multimeric complexes with a composite molecular mass in excess of 50000 Da which puts them outside the range of current solution NMR techniques. For the foreseeable future, detailed information about the structure of large membrane proteins will therefore depend on crystallographic methods.

Ouabain inhibition of kidney ATPase is altered by 9.14 GHz radiation

At each of several stabilized temperatures between 7.0 and 43.8 degrees C, increases in dog-kidney, Na(+)-, K(+)-ATPase catalytic activity were usually observed in association with exposure for 5 min to 9.14 GHz CW microwave radiation in a thin tubular reactor. However, at 24.9 degrees C, a 23% decrease occurred. Comparisons of activity of ouabain-inhibited reactions revealed that the efficacy of the cardiac glycoside as an inhibitor of ATPase activity was severely diminished by the microwave field. The ouabain-site control mechanism may be a specific microwave target at this exposure frequency. Experimental results can be interpreted in terms of molecular structural changes or direct energy input. The estimated SAR of energy that was incident on preparations is 20 W/kg.

Configuration of subunits within crystals of Na, K-ATPase maintained in the frozen-hydrated state

Two-dimensional crystalline sheets of Na, K-ATPase were studied in the vitrified, frozen-hydrated state by electron microscopy and image processing. The technique of correlation averaging was used to determine the projected structure. The projection map shows asymmetry between the pair of "alpha beta" protomers comprising a dimer of Na, K-ATPase molecules. The two protomers differ in overall density as well as in shape. One protomer has an oblong shape, whereas the other with higher density has a head and a hook region. Such an asymmetry has not been reported by other laboratories. This asymmetry may either be due to the coexistence of two different conformations of the enzyme in the dimeric form or due to the simultaneous existence of two molecular species of Na, K-ATPase.

Identification of monoclonal antibody binding domains of Na+,K(+)-ATPase by immunoelectron microscopy

Treatment of purified preparations of porcine Na+,K(+)-ATPase with phospholipase A2, MgCl2 and NaVO3 leads to the formation of two-dimensional crystals exclusively in a dimeric configuration. Two-dimensional computer-averaged projections of the electron microscopy images of the crystalline enzyme with bound Fab fragments of monoclonal antibody M10-P5-C11 were accomplished using image enhancement software and showed that the antibody fragments caused only a modest increase in the unit cell size, while reducing the extent of asymmetry of the two promoters in each unit cell. The digital imaging also showed that the antibody's epitope on the alpha subunit resides on the 'lobe' or 'hook' region of the intracellular portion of the enzyme. Since functional studies indicate that M10-P5-C11 binds near or between the ATP binding site and the phosphorylation site, this visualized 'lobe' region of alpha may comprise the catalytic site. In addition, the binding of another inhibitory antibody, 9-A5, has been found to prevent crystal formation and the presence of the carbohydrate sugars on the enzyme's beta subunit shown to be required for crystal formation.

N-terminal amino acid sequence, immunohistochemical localization and tissue distribution of a plasma membrane protein (Prot17) of rat enterocytes

Prot17, a protein of the basolateral membrane of rat small intestine with a mol.wt. of 17 kDa, can be isolated using a previously described method (Schiechl 1988). It occurs in the membrane as an oligomer with a mol.wt. of 90 kDa. In the present study a polyclonal antibody specific for Prot17 was used to explore by immunohistochemical techniques the tissue distribution of Prot17 and its ultrastructural localization within the cells. Furthermore the amino acid sequence of the N-terminal part of this molecule up to position 17 could be analyzed. The results are summarized as follows: Prot17 is a membrane anchored protein. Its partial amino acid sequence suggests that it is neither identical nor related to other known proteins. Immunofluorescence studies revealed, that it occurs only in epithelial cells. It is mainly found in the absorptive and goblet cells of the intestine and the acinar cells of the pancreas. Smaller quantities are found also in the bile duct epithelium of the liver, in the proximal tubule cells of the kidney and in the cells of the respiratory epithelium. Ultrastructural localization of Prot17 was possible in the intestinal epithelium and pancreas acinar cells. In both cell types it was found in the basolateral and microvillous membrane. In pancreas, Prot17 was also detected in the membrane of the zymogen granules. In the absorptive cells of the intestine Prot17 was found in both the membrane and the contents of subluminal vesicles. Furthermore, in apical granules of secretory cells of the respiratory epithelium binding of Prot17 specific antibody was found in the granular content, the membrane being negative.

Polarized infrared absorption of Na+/K+-ATPase studied by attenuated total reflection spectroscopy

Na+/K+-ATPase can be isolated from the outer medulla of mammalian kidney in the form of flat membrane fragments containing the enzyme in a density of 10(3)-10(4) protein molecules per microm2 (Deguchi et al. (1977) J. Cell. Biol. 75, 619-634). In this paper we show that these membrane fragments can be bound to a germanium plate coated with a phospholipid bilayer. With this system infrared spectroscopic studies of the enzyme have been carried out using the technique of attenuated total reflection (ATR). At a coverage of the lipid surface corresponding to 30-40% of a monolayer of membrane fragments, characteristic infrared bands of the protein such as the amide I and II bands can be resolved. About 24% of the NH-groups of the peptide backbone are found to be resistant to proton/deuterium exchange within a time period of several days. Evidence for orientation of the protein with respect to the supporting lipid layer is obtained from experiments with polarized light, the largest polarization effects being associated with the -COO- band at 1400 cm-1. Experiments with aqueous media of different ionic composition indicate that the average orientation of transition moments changes when K+ in the medium is replaced by Tris+ or Na+.

Digital image analysis of two-dimensional Na,K-ATPase crystals: dissimilarity between pump units

Two-dimensional crystals of purified Na,K-ATPase were induced by treatment with phospholipase-A2 and vanadate. The negatively stained crystals were imaged by electron microscopy and analysed by digital image processing. Two-dimensional averaged projections of the crystals were calculated by the technique of correlation analysis, utilizing SPIDER (System for Processing of Image Data in Electron microscopy and Related fields) image processing software. The calculated dimensions of the unit cell were found to be 13.3 X 4.59 nm with included angle of 98 degrees, comparable to those reported by others. However, the two protomers of the unit cell were found always to be dissimilar in shape and in orientation. All protomers of one side of the dimer ribbon had a triangular outline, and all protomers of the opposing side had a comma shape. This dissimilarity could be explained by two orientations of identical protomers: one orientation for one side of the dimer ribbon, and another orientation for the protomers of the opposing side of the ribbon. An alternative explanation is that the protomers of one side of the dimer ribbon are actually in a conformation different from that of the protomers of the opposing of the ribbon.

Three-dimensional structure of renal Na,K-ATPase determined from two-dimensional membrane crystals of the p1 form

Electron microscopy and image processing were used to reconstruct a three-dimensional model of membrane-bound monomeric renal Na,K-ATPase from negatively stained two-dimensional crystals of the p1 type. Correlation methods were applied to obtain projection averages which were aligned by a phase difference minimization procedure. The self-consistency of the reconstruction process was high as determined by correlation between experimental projections and projections of the calculated model. The three-dimensional model of the Na,K-ATPase promoter in the p1 crystal form contains three characteristic domains, a protein dense ellipsoid, a small globular stain deficient domain, and a connecting low-contrast region. The latter is thought to correspond to the lipid-penetrating part of the Na,K-ATPase promoter. The location of this domain gives the protein an asymmetric distribution in the bilayer so that it is exposed primarily on one side proposed to correspond to the intracellular face.

Assembly of two-dimensional membrane crystals of Na,K-ATPase

The assembly of vanadate-induced two-dimensional membrane crystals of Na,K-ATPase was analyzed by electron microscopy and image processing. Electron micrographs of negatively stained linear arrays of protein molecules were recorded and processed by correlation averaging methods. The arrays were compared with fully developed p21 crystals of the enzyme. On the basis of similarity in protein form, symmetry, and packing arrangement it was concluded that the fully developed crystals are built of tightly packed ribbons. Assembly pathways for two-dimensional membrane crystals of Na,K-ATPase are proposed.

Precipitation of solubilized Na+/K+-ATPase by divalent cations

A method for preparation of membranous fragments of pure and highly active shark rectal gland Na+/K+-ATPase by Mn2+ precipitation of C12E8-solubilized enzyme is described. The method is rapid and inexpensive, and yields enzyme with a specific Na+/K+-ATPase activity of up to 1800 mumol/mg per h at 37 degrees C. The influence of the detergent/protein and lipid/protein ratios on the yield of membrane bound enzyme is described.

Identification of polypeptides associated with sarcolemmal vesicles enriched in orthogonal arrays

Electron microscopy of freeze-fracture replicas from the sarcolemmas of fast-twitch muscle fibers reveals orthogonal arrays of particles. The biochemical nature of macromolecules associated with the sarcolemmal orthogonal array was investigated using muscle fragments and isolated sarcolemmal vesicles. Muscle fragments incubated in vitro with the lectin concanavalin A exhibited a clustering of orthogonal arrays into local patches. Treatment with other lectins did not result in the clustering of arrays. Clustering was inhibited by the addition of alpha-methyl-D-mannoside, a ligand which also binds concanavalin A. These results suggest that the orthogonal arrays (or associated components) specifically bind concanavalin A. Sarcolemmal vesicles from rabbit sacrospinalis (SAC) and rat extensor digitorum longus (EDL) (both primarily fast-twitch) and rat soleus (SOL) (primarily slow-twitch) were obtained by a combination of low-salt fractionation and sucrose density gradient centrifugation. SDS-polyacrylamide gel electrophoresis (SDS-PAGE) of proteins and glycoproteins solubilized from these vesicles revealed several bands. Four of these bands were present in gels from both the rabbit and rat fast-twitch muscle sarcolemmal preparations (that contained arrays), yet were absent in gels from rat slow-twitch muscle sarcolemmal preparations (not bearing arrays). An enrichment in vesicles containing arrays was achieved by binding SAC sarcolemmal vesicles to Con A-Sepharose 4B beads. SDS-PAGE analysis of array-enriched vesicles from the concanavalin A beads revealed enrichment of three major bands at Mr 93,000, 54,000 and 49,000. These enriched bands correlate with three of the four bands common to fast-twitch EDL and SAC, yet absent in slow-twitch SOL sarcolemmal preparations. We conclude that at least one macromolecular component associated with the sarcolemmal orthogonal array is a concanavalin A binding glycoprotein. We further conclude that three candidates for this component co-purify with the morphological array, and have approximate molecular weights of 93,000, 54,000 and 49,000.

The three-dimensional structure of the Na,K-ATPase from electron microscopy

The structure of Na,K-ATPase has been studied by electron microscopy and image reconstruction. A three-dimensional structure of this enzyme has been obtained to an overall resolution of 2.5 nm using data from specimens of negatively stained dimer sheets tilted through a range of angles +/- 60 degrees. The reconstruction shows a complex mass distribution consisting of ribbons of paired molecules extending approximately 6.0 nm from the cytoplasmic side of the membrane. The molecular envelope consists of a massive "body" with "lobe" and "arm" structures projecting from it. The body has a columnar shape and is tilted with respect to the plane of the membrane. The region of interaction responsible for dimer formation is located between two bodies and is clearly visible in the reconstruction. It has been identified as a segment in the amino-terminal portion of the alpha subunit. The arms that interconnect the ribbons are located close to the membrane and are most probably formed by the beta subunits.

Early alterations at the plasma membrane of breast cancer cell lines in response to estradiol and hydroxytamoxifen

The time course of the early stage of estradiol-17 beta (E2) and hydroxytamoxifen (OHTAM) action at the plasma membrane of hormone-responsive MCF-7 and non-responsive MDA-MB-231 (MDA) breast cancer cell lines was investigated using scanning electron microscopy (SEM), electron probe X-ray microanalysis and microelectrophysiology analysis. SEM showed a marked increase in the density and the length of microvilli (MV) on MCF-7 cells treated with 1 nM estradiol for 1 min. This membrane response disappeared at 5 min. No early effect was obtained with OHTAM, but both compounds produced a similar surge of heterogeneous MV at 15 min of treatment. The morphological change induced by E2 subsided at 60 min, whereas that of OHTAM persisted. X-ray microanalysis and computer determination of peak/background ratios permitted the demonstration that these morphological alterations were concomitant with a rise in the intracellular level of potassium. Microelectrophysiology analysis showed a sharp transitory decrease in the membrane potential of MCF-7 cells in response to estradiol. In the estrogen-insensitive MDA cells, the hormone did not modify the membrane potential and K levels decreased at 1 and 5 min before rising again to control levels at minute 15 when MV appeared. With OHTAM, potassium decreased significantly at 60 min of treatment. These initial and transitory changes in surface morphology paralleled by alterations in potassium level may be consistent with the occurrence of estrogen membrane receptors on target cells, a new aspect of steroid hormone action.

Rat hepatic (Na+, K+)-ATPase: alpha-subunit isolation by immunoaffinity chromatography and structural analysis by peptide mapping

The catalytic alpha-subunit of rat hepatic (Na+, K+)-ATPase (EC 3.6.1.3) has been isolated by immunoaffinity chromatography from microsomes solubilized in n-dodecyl octaethylene glycol monoether. The procedure employs an anticatalytic mouse monoclonal antibody ("9-A5") covalently linked to Sepharose 4B that specifically blocks phosphorylation of the sodium pump's alpha-subunit from [gamma-32P]ATP [Schenk, D. B., Hubert, J.J., & Leffert, H.L. (1984) J. Biol. Chem. 259, 14941-14951]. The hepatic subunit is virtually identical with purified rat, dog, and human renal alpha-subunits as judged by its apparent molecular weight after polyacrylamide gel electrophoresis in sodium dodecyl sulfate (Mr 92K) and its two-dimensional tryptic and chymotryptic peptide maps on cellulose-coated thin-layer plates. In contrast, the structures of authentic renal beta-subunits from the three species differ significantly from each other as judged by their peptide maps; no detectable homologies are seen between their chymotryptic maps and those of putative hepatic "beta"-subunits (Mr 50K and 55K) eluted from 9-A5-Sepharose. Additional studies of ouabain-sensitive 86Rb+ uptake in primary cultures of adult rat hepatocytes reveal inhibition curves with single inflection points (ID50 = 0.1 mM ouabain) in the absence or presence of pump-stimulating peptides like insulin, glucagon, and epidermal growth factor. These findings indicate that rat hepatocytes express only one of two known structurally conserved forms of catalytic subunit (the renallike alpha form) and, if at all, structurally divergent forms of the sodium pump's beta-subunit. In addition, immunoaffinity chromatography with 9-A5-Sepharose facilitates the isolation of (Na+, K+)-ATPases from nonrenal tissues with low levels of sodium pumps.

Particles and pits matched in native membranes

We have obtained high resolution electron microscopic images of complementary membrane surface replicas of purified microsomal vesicles from pig kidney outer medulla containing Na+,K+-ATPase. Ultra-rapid freezing of a membrane suspension was followed by fracturing and replicating of the liquid helium cooled specimen under ultra-high vacuum conditions free of hydrocarbon contaminants. The protoplasmic fracture faces are populated with intramembrane particles while the external fracture faces reveal complementary pits. This is the first demonstration of extended precise matching of individual intramembrane particles and their corresponding pits in biological membranes containing transmembrane proteins. The data are also consistent with the theory that the majority of Na+,K+-ATPase mass is located at the protoplasmic half of the membrane.

The lateral mobility of the (Na+,K+)-dependent ATPase in Madin-Darby canine kidney cells

Fluorescence microphotolysis (recovery after photobleaching) was used to determine the lateral mobility of the (Na+,K+)ATPase and a fluorescent lipid analogue in the plasma membrane of Madin-Darby canine kidney (MDCK) cells at different stages of development. Fluorescein-conjugated Fab' fragments prepared from rabbit anti-dog (Na+,K+)ATPase antibodies (IgG) and 5-(N-hexadecanoyl)aminofluorescein (HEDAF) were used to label the plasma membrane of confluent and subconfluent cultures of MDCK cells. Fractional fluorescence recovery was 50% and 80-90% for the protein and lipid probes, respectively, and was independent of developmental stage. The estimated diffusion constants of the mobile fraction were approximately 5 X 10(-10) cm2/s for the (Na+,K+)ATPase and approximately 2 X 10(-9) cm2/s for HEDAF. Only HEDAF diffusion showed dependency on developmental stage in that D for confluent cells was approximately twice that for subconfluent cells. These results indicate that (Na+,K+)ATPase is 50% immobilized in all developmental stages, whereas lipids in confluent MDCK cells are more mobile than in subconfluent cells. They suggest, furthermore, that the degree of immobilization of the (Na+,K+)ATPase is insufficient to explain its polar distribution, and they support restricted mobility of the ATPase through the tight junctions as the likely mechanism for preventing the diffusion of this protein into the apical domain of the plasma membrane in confluent cell cultures.

One-dimensional crystals of (Na+ + K+)-ATPase dimers

Preparations of purified (Na+ + K+)-ATPase contain both fragments of membranes and long and undulating cylindrical structures. These structures have been described as edgeways of membrane fragments. We have analyzed these structures using negative staining, thin sectioning and freeze-fracture-etch electron microscopy and describe their structure for the first time. Each cylinder is 12-19 nm in width and is comprised of an unstained core from which rows of distinct particles spaced 5-6 nm apart project on both sides. Each cylindrical structure was interpreted as a linear polymer of (alpha beta)2 dimers of (Na+ + K+)-ATPase molecules. Therefore, the particles that project from both sides are the cytoplasmic domains of the molecules of the enzyme, whereas the membrane-spanning domains form the unstained core of the cylinder. From considerations of the packing of the dimers in the cylinder we conclude that the cross-sectional area of the cytoplasmic domain should be larger than that of the membrane-spanning domain. Our results are consistent with the hypothesis that the (alpha beta) protomer is the native state of the enzyme. The (alpha beta)2 dimers observed in the fractions are the result of a secondary aggregation process occurring during the purification procedure.

Novel crystalline sheets of Na,K-ATPase induced by phospholipase A2

Treatment of purified preparations of Na,K-ATPase by phospholipase A2 has led to the formation of two-dimensional crystals of the protein. Control tests with another phospholipase and two detergents have shown that crystallization occurs as the result of hydrolysis and/or solubilization of the phospholipids in the enzyme vesicles. Experimentation with various buffer systems has indicated that reduction in the amount of phospholipids alone is sufficient for inducing the formation of crystalline sheets. Inclusion of crystal inducing ions in the buffer facilitates the crystallization process, resulting in more extensive arrays. The new crystalline sheets are exclusively dimeric with average unit cell dimensions: a = 15.8 +/- 0.4 nm, b = 4.9 +/- 0.2 nm, and gamma = 64 +/- 3 degrees. Examination of the micrographs shows that the initial intermolecular interaction leading to the formation of sheets is between the alpha subunits. Results from this study suggest that removal and/or modification of phospholipids by phospholipases could prove successful in crystallizing those membrane proteins in which excess lipid is the main barrier to the formation of two-dimensional arrays.

Density and disposition of Ca2+-ATPase in sarcoplasmic reticulum membrane as determined by shadowing techniques

We have studied the disposition of calcium ATPase in the native sarcoplasmic reticulum (SR) membrane of vertebrate muscles by rotary shadowing of freeze-dried isolated vesicles and of freeze-fractured in situ membranes. The predominant disposition of the ATPase molecules is disorderly, but small oligomers (dimers, tetramers, and occasionally larger aggregates) are seen. In vesicles from white hind legs of rabbits, the density of ATPase over nonjunctional SR is 31-34,000/microns2. ATPase density is always quite high, but small protein-free lipid patches may be interspersed with it.

Ordered arrays of Ca2+-ATPase on the cytoplasmic surface of isolated sarcoplasmic reticulum

Isolated sarcoplasmic reticulum (SR) vesicles with polymerized calcium pump protein were freeze-dried and rotary shadowed following uranyl acetate stabilization. This technique allows direct observation of a single side of the vesicle without requiring optical filtering. The heads of individual ATPase molecules, projecting above the cytoplasmic surface, are clearly resolved in the replicas. Ca ATPase molecules form extensive arrays in vanadate-treated, rabbit SR vesicles and in gently isolated, native SR vesicles from scallop. Gentle isolation results in limited areas of orderly structure in native SR isolated from vertebrate muscles. Special attention is given to the effect of various shadow thicknesses on the appearance of the heads. This information is essential to the interpretation of images in the accompanying paper (Franzini-Armstrong, C., and D.J. Ferguson, 1985, Biophys. J., 48:607-615).

Three-dimensional structure of renal Na,K-ATPase determined by electron microscopy of membrane crystals

The three-dimensional structure of Na,K-ATPase was determined by electron microscopy and image processing. Tilt series of negatively stained membrane crystals were recorded. The projections were analyzed by Fourier methods and the data combined to a 3-D model. The unit cell contains two rod-shaped stain-deficient regions interpreted as alpha beta-promoters of Na,K-ATPase. The rods are related by dyad axes oriented perpendicular to the membrane. Outside the lipid bilayer the rods contact different protein units on the two sides of the membrane.

Structure of two-dimensional crystals of membrane-bound Na,K-ATPase as analyzed by correlation averaging

The structure of two-dimensional crystals of membrane-bound Na,K-ATPase from rabbit kidney has been analyzed with a correlation averaging procedure. Two principally different crystal forms are observed with p1 and p21 symmetry, respectively. In the p1 form the averaged projection structure shows a triangular shaped protein domain interpreted as a protomer (alpha beta-unit) of Na,K-ATPase. In the p21-form the stain-deficient area is extended toward a twofold symmetry axis. The results are in good agreement with a previous analysis where Fourier methods were applied to well ordered crystals of pig kidney Na,K-ATPase and illustrate that the correlation averaging procedure can be used for the analysis of membrane crystals of Na,K-ATPase showing curved lattice lines.

Intercellular fibrillar skeleton in the basal interdigitations of kidney tubular cells

The tubular cells from the thick ascending limb of the loop of Henle in rabbit kidney medulla contain in their basal-lateral surfaces a complex system of interdigitations. Within these interdigitations, the plasma membranes are separated by extracellular spaces of relatively constant width that contain a previously undescribed fibrillar system. The structural organization and distribution of this intercellular fibrillar skeleton was studied using freeze-fracture etch and then section electron microscopy. The skeleton is comprised of discrete strands with a density of 300 to 400 per micron 2 evenly distributed along the entire basal-lateral region. Each strand has the shape of a brace and it is constructed from up to eight finer filaments each having a width of about 2 nm. The filaments are tightly joined together along their shafts for about 30 nm but they separate at both ends for about 10 nm before contacting the external surface of the plasma membrane. We propose that this intercellular fibrillar skeleton is responsible for maintaining the wide (about 50 nm) and uniform plasma membrane separation along the entire length of the basal-lateral region of the tubular cells of the thick ascending limb.

Asymmetric mass distribution of (Na+ + K+)-ATPase in membranes studied by freeze-fracture-etch electron microscopy

SDS-purified porcine kidney (Na+ + K+)-ATPase was studied by thin-section and freeze-etch electron microscopy. Freeze-fracturing of resealed membrane fragments shows no difference in the distribution of intramembranous particles of approx. 9.0 nm in diameter between convex and concave fracture faces. However, two types of convex face are found: FA, which shows a rather smooth background with many intramembranous particles, and FB, which shows a textured background with very few or no intramembranous particles. Etching the fractured samples further reveals that FA faces are covered with many intramembranous particles, while the etched external faces (EA) are either irregularly granulated or reveal many particles half the size of intramembranous particles. FB faces are covered with distinct pits of 9 nm or larger. The etched external surfaces (EB) are covered with many particles of intramembranous particle size. These results suggest that there are two vesicle orientations in our resealed purified membrane preparation: right-side-out, as in vivo, and inside-out. The majority of the protein mass is distributed only on one side of the membranes. Right-side-out resealed membrane vesicles after fracturing and etching show particulated FA convex fracture faces and irregularly granulated or smooth etched EA surfaces, indicating that the FA face is the protoplasmic fracture face and that the majority of the protein mass of the (Na+ + K+)-ATPase is located on the cytoplasmic half of the membrane.