Recombination of human erythrocyte apoprotein and lipid. I. Interaction of apoprotein and lipid at the air-water interface

The formation and stabilization of a complex between total erythrocyte apoprotein and monolayers of total erythrocyte lipid as measured by changes of surface pressure (Δπ) and rate of change of surface pressure (dπ/dt) was studied as a function of pH, ionic strength, and lipid surface pressure. Penetration of apoprotein into lipid monolayers was favored by conditions in which lipid and apoprotein were oppositely charged. Once the interaction was completed, the resultant surface complex was resistant to large changes in subphase pH and ionic strength as shown by the insensitivity of Δπ to these parameters. The dπ/dt, however, showed strong dependence on pH and ionic strength, but not on lipid surface pressure. A sharp decrease in dπ/dt around pH 3.5–4.5 is associated with the change in apoprotein charge from (+) to (?). Comparison of complex formation between apoprotein and bovine serum albumin, cytochrome c, and human hemoglobin suggests that erythrocyte apoprotein was specialized in its interaction with erythrocyte lipids. The data show that formation of an apoprotein-lipid complex at the air-water interface has both electrostatic and hydrophobic components. This contradicts results from other laboratories studying erythrocyte membrane recombination by bulk methods.     

Assembly of Plasmid DNA into Liposomes After Condensation by Cationic Lipid in Anionic Detergent Solution

A novel strategy to prepare negatively charged and small DNA-containing liposomes after condensation of plasmid DNA by a cationic lipid in deoxycholate micelle environment is described. The average diameter of resulting complexes was 62±8 nm. DNA-containing liposomes were then prepared by dialysis. The shape of the resulting liposomes was spherical. The average diameter and the surface charge of the liposomes were 86±6 nm and −24±3 mV, respectively. The plasmid DNA inside liposomes remained in a supercoiled form after incubation with DNase.     

Sizes of two amino acyl-tRNA synthetase complexes from E. coli with their cognate tRNAs.

The complexes of valyl-tRNA synthetase with tRNA_I^Val and arginyl-tRNA synthetase with tRNA_II^Arg from $\text{E. coli}$ were studied by light scattering measurements and analytical ultracentrifugation of concentrations as low as 40 μg/ml. The molecular weights determined from these studies were 260,000 ± 2,000 for the valyl-tRNA synthetase·tRNA complex, and 310,000 ± 1,500 for the arginyl-tRNA synthetase·tRNA complex at pH 7.1. The stoichiometry for the complexes are apparently 2:1 for valyl-tRNA synthetase and tRNA and 4:1 in the case of the arginyl-tRNA synthetase and tRNA. From the angular dependence of the scattered intensity a radius of gyration of 54.5 Å for the complex between valyl-tRNA synthetase and tRNA was found, whereas for the other complex a value of 59.1 Å was found.     

Structural analysis of the isolated chloroplast coupling factor and the N,N'-dicyclohexylcarbodiimide binding proteolipid

Negative staining of purified spinach dicyclohexylcarbodiimide (DCCD) sensitive ATPase revealed a population of 110 Å subunits attached by stalks to short string-like aggregates. The interpretation of these data is that 110 Å CF₁ are attached by stalks to an aggregate of CF₀.The CF₁-CF₀ complex was incorporated into phospholipid vesicles; freezefracture analysis of this preparation revealed a homogeneous population of particles spanning the lipid bilayer; these averaged 96 Å in diameter. The DCCD binding proteolipid (apparent molecular weight 7500), an integral component of CF₀, was isolated from membranes by butanol extraction and was incorporated rated into phospholipid vesicles. Freeze-fracture analysis of the DCCD-binding proteolipid/vesicle preparation revealed a population of particles averaging 83 Å in diameter suggesting that the DCCD-binding proteolipid self-associates in lipid to form a stable complex. This complex may be required for proton transport across chloroplast membranes in vivo. The size difference between CF₀ and DCCD-proteolipid freeze-fracture particles may be related to differences in polypeptide composition of the two complexes.     

Elongation of duplex DNA by recA protein

recA protein, which is essential for the recombination process in Escherichia coli, was incubated in the presence of 5′-γ-thiotriphosphate with circular plasmid pBR_βG containing small single-stranded gaps. Stable complexes were formed which appear in the electron microscope as fibres with a diameter about five times that of naked DNA. Complex formation appears to be a co-operative process whereby the average rise per base-pair with respect to the fibre axis increases from 3·39 ± 0·08 Å to 5·20 ± 0·18 Å. The elongation of DNA by about 50% is compatible with an unwinding of the double helix and an intercalating mode of binding of recA and/or 5′-γ-thiotriphosphate to DNA.     

Enhanced Hoechst 33258 fluorescence in plants.

The topological features of isolated Chinese hamster ovary metaphase chromosomes were studied with high resolution scanning electron microscopy (SEM) using the techniques of direct current sputtering for the deposition of metal on the specimens. Metaphase chromosome surfaces consist of numerous compact microconvules of an average diameter of 520 ± 78 Å when corrected for the thickness of the gold-palladium coating (80 ± 2 Å). These microconvules contain several orders of supercoiling. The superhelical structures were detected also in water-spread preparations. Most of the isolated chromosomes had membrane-like structures attached at the distal portions of the chromatids forming a terminal “plate”. Limited tryptic digests of such isolated chromosomes resulted in considerable stretching of the chromatids and revealed a series of interchromatidal fibers with diameters of 203 ± 38 Å (corrected for gold coating). Treatment of these chromosomes with EDTA revealed a longitudinal array of fibers within the chromatids. The diameters of these fibers decreased as the concentration of EDTA was increased. The technique of direct current sputtering for the preparation of chromosomes for scanning microscopy is satisfactory for detailed topological ultrastructural studies in the 70 Å range.     

Fluorescence polarization studies of human and rhesus A-I apolipoproteins and their complexes with phosphatidylcholine.

Human and rhesus A-I apolipoproteins, covalently labelled with dansyl chloride, were used in fluorescence polarization studies of: 1) the monomeric structure of the free proteins in solution; 2) the interaction of the apolipoproteins with sonicated egg phosphatidylcholine; and 3) the size of the saturated complexes of protein with phospholipid. The results indicate that both monomeric apolipoproteins have relatively rigid, yet asymmetrical structures, with Stokes radii of 24.2 ± 0.5 Å, in neutral aqueous solutions. Axial ratios are of the order of $\text{6}\text{1}$ or $\text{4}\text{1}$ for hydrated, prolate or oblate ellipsoids, respectively. A molar excess of about 200 phosphatidylcholine molecules are required to saturate each apolipoprotein. At saturation, the complexes with both proteins have Stokes radii of 40.6 ± 1.7 Å. Since the radius of phosphatidylcholine vesicles is around 125 Å, we conclude that the complexes are relatively small structures derived from disruption of the lipid vesicles, rather than from adsorption of the proteins on intact vesicles.     

Plasma and erythrocyte lipid peroxidation levels in patients with testis tumor after orchiectomy

Plasma and erythrocyte lipid peroxidation levels of 20 patients with histopathologically confirmed testis cancer and 20 healthy control individuals were studied between November 1995 and June 1997. The group with testis cancer had a mean age of 24.8±8.2 yr and the control group’s mean age was 28.3±6.9 yr. Stage distribution of the testis cancer cases were 4 of stage A, 10 of stage B, and 6 of stage C. Blood samples of the patients were drawn after orchiectomy and after 12 h fasting before chemotherapy. Mean plasma and erythrocyte lipid peroxidation levels were detected to be 14.51±5.30 nmol malondialdehide (MDA)/mL and 9.30±2.06 nmol MDA/g hemoglobin (Hb), respectively, in the testis cancer group, whereas the healthy control group had mean plasma and erythrocyte lipid peroxidation levels of 10.7±1.82 nmol MDA/mL and 6.18±1.68 nmol MDA/g Hb, respectively. Plasma and erythrocyte lipid peroxidation values of the testis cancer patients were determined to be statistically significantly higher than that of the health control group (p<0.001, p<0.001). No significant correlation was determined between plasma, erythrocyte lipid peroxidation levels and tumor markers. In conclusion, it can be said that an increase in the lipid peroxidation may play a role in the pathogenesis of testis carcinomas in addition to the other causes.     

Formation and characterisitcs of hepatic dexamethasone-receptor complexes of different molecular weight

The dexamethasone-binding receptor protein in rat liver cytosol has a Stokes radius of 61 Å and a sedimentation coefficient of 4.0 S. In contrast, cell nuclei labelled with [³H]dexamethasone in vivo or in vitro (reconstitution experiments with [³H]dexamethasone-labelled cytosol and isolated unlabelled nuclei) contain a high-salt-extractable dexamethasone-receptor complex with a Stokes radius of 30–36 Å and a sedimentation coefficient of 3.2 S. Exposure of liver homogenate or 1000 × g homogenate supernatant to low ionic strenght during preparation of cytosol resulted in conversion of the 61 Å to a 36 Å complex very similar to the intranuclear form of dexamethasone receptor. 61 → 36 Å complex-verting activity was present in both the 100 × g ?10 000 × g sediment of liver homogenate, from which it could be extracted by hypotonic media, and in the liver cell nuclei, from which it could be extracted by hypertonic media. Mild digestion of the 61 Å dexamethasone-receptor complex with trypsin also gave rise to a complex with a Stokes radius of 36 Å. Reconstitution experiments with isolated liver cell nuclei indicated that both the 61 Å and 36 Å dexamethasone-receptor complexes were taken up by the nuclei; reextraction of the nuclei incubated with the 61 Å complex revealed that this form had been converted to the 30–36 Å complex.Further digestion of teh 61 and 36 Å [³H]dexamethasone-receptor complexes with hypotonic extract of the 1000 × g ?10 000 × g sediment of liver homogenate or with trypsin resulted in formation of a third complex with a Stokes radius of 19 Å and a sedimentation coefficient of 2.5 S. The approximate molecular weights of the 61, 36 and 19 Å dexamethasone-receptor complexes were calculated as 102 000, 46 00 and 19 000, respectively, and the frictional ratios of the molecules as 1. 84, 1. 38 amd 1.00, respectively.It is concluded that the nuclear 30–36 Å dexamethasone-receptor complex is formed from the cytosol 61 Å complex by proteolytic digestion and that this latter protein contains at least two sites with a relatively high sensitivity to protelytic cleavage.     

Calculation of mobility and entropy of the binding of molecules by crystals

A simple method for evaluating a range of molecular movements in crystals has been developed. This estimate is needed to calculate the entropy of binding, in particular in protein–ligand complexes. The estimate is based on experimental data concerning the enthalpy of sublimation and saturated vapor pressure obtained for 15 organic crystals with melting temperatures of 25–80°С. For this set, we calculated the values of the average range and the corresponding average amplitude of molecular movements in crystals that constituted 0.75 ± 0.14 Å and 0.18 ± 0.03 Å, respectively. The entropy of sublimation calculated based on the average range of molecular movements in crystals was well consistent with the experimental data.     

Intracellular receptors for 5alpha-dihydrostestosterone in the epididymis of adult rats. Comparison with the androgenic receptors in the ventral prostate and the androgen binding protein (ABP) in the testicular and epididymal fluid

Epididymal cytosol fractions of adult short-time castrated rats contained at least two different androgen protein complexes by experiments $\text{in vivo}$ (Complex I and II).Complex I is probably located intracellularly in the epididymal cells. It was specific for 5α-dihydrotestosterone (DHT) and appeared to be very similar to the cytoplasmic DHT-receptor complexes in rat ventral prostate. By ultracentrifugation on sucrose gradients, it sedimented as heavy aggregates 8–10 S complexes and 3–4 S complexes, which dissociated into 3–4 S complexes at high ionic strength. Complex I was eluted in the void volume from columns of Sephadex G-200.Complex II was also specific for DHT and showed physical properties similar to those of the androgen binding protein (ABP) in the testicular fluid. It was eluted between immunoglobulin G (IgG) (53 Å) and albumin (36 Å) by gel filtration on Sephadex G-200. The sedimentation coefficient was 4.5–5 S (mean 4.6 S_W, 20) at both high and low ionic strength.Complex I and the cytosol receptors for DHT in the rat ventral prostate were both destroyed by heating at 50° C for 30 min, addition of 1 mM p-chloro-mercuri-phenyl-sulphonate (PCMPS) and charcoal absorption (1 mg/mg protein) overnight, whereas complex II was not influenced by similar treatment.Hemi-castration for 4 weeks caused complex II to disappear completely from the castrated side, confirming the intraluminal localization of this complex. Complex I was not influenced by such treatment, indicating that this protein is located within the epididymal cells. The similarity between complex I and the cytoplasmic DHT-receptor complexes in the ventral prostate also suggests that complex I represents the cytoplasmic receptors for DHT in the epididymis.     

Eight-coordination. Synthesis and structure of the schiff-base chelate bis(N,N′-disalicylidene-1,2-phenylenediamino)cerium(IV)

In an effort to elucidate the factors that determine the geometry of eight-coordinate complexes we synthesized and structurally characterizes the complex bis(N,N′-disalicylidene-1,2-phenylenediamino)Cerium(IV), Ce(salophen)₂. It is a square antiprismatic species with each chelating ligand spanning sss edges. The CeO bonds average 2.214 Å, appreciably shorter than CeN distance of 2.606 Å. The tow ligands have the sandwich orientation and the trapezoidal planes intersect at 88.2°. The δ angles are 7.0°, 2.6°, 56.5° and 55.9° and the ? angles are 30.0° and 28.6°. The complex crystallized in space group P2₁/C with Z = 4, a = 11.090(2) Å, b = 16.332(3) Å, c = 18.916(3) Å, β = 70.10(2)° and d_calc = 1.585 g/cm₃.     

Structural and Compositional Changes in Erythrocyte Membrane of Obese Compared to Normal-Weight Adolescents

Unhealthy dietary habits are key determinants of obesity in adolescents. Assuming that dietary fat profile influences membrane lipid composition, the aim of this study was to analyze structural changes in the erythrocyte membrane of obese compared to normal-weight adolescents. The study was conducted in a group of 11 obese and 11 normal-weight adolescent subjects. The lipid profile, lipid peroxidation and acetylcholinesterase enzyme (AChE) activity were analyzed by conventional methods. The structural properties of reconstituted erythrocyte membrane were characterized by X-ray diffraction. Erythrocyte membrane from obese adolescents had a lipid profile characterized by a higher cholesterol/phospholipid ratio, an increase in saturated fatty acid and a decrease in monounsaturated and n-6 polyunsaturated fatty acid concentrations. Differences in lipid content were associated with changes in the structural properties of reconstituted membranes and the oxidative damage of erythrocyte membrane. The lower oxidative level shown in the obese group (0.15 ± 0.04 vs. 0.20 ± 0.06 nmol/mg for conjugated diene concentrations and 2.43 ± 0.25 vs. 2.83 ± 0.31 nmol/mg protein for malondialdehyde levels) was related to a lower unsaturation index. These changes in membrane structural properties were accompanied by a lower AChE activity (1.64 ± 0.13 vs. 1.91 ± 0.24 nmol AChE/[min mg protein]) in the obese group. The consequences of unhealthy dietary habits in adolescents are reflected in the membrane structural properties and may influence membrane-associated protein activities and functions.     

The periodicity and architecture of lipid retained and extracted lung surfactant and its origin from multilamellar bodies.

Lipid and carbohydrate retaining procedures were utilized to retain these components of surfactant in thin section. The origin of tubular myelin surfactant from multilamellar bodies was postulated on morphological evidence to be : an expansion of lamellae in pairs caused by the absorption of a homogeneous, probably carbohydratebased, material of undetermined origin; immediately after the pairs expanded to 438 Å, the lamella (lipid bilayer) that was most peripheral in the multilamellar body underwent a molecular rearrangement to form the two cross lipid bilayers; the four lipid bilayers formed a square tubule 413 Å of side and 0.16–1.8 μ long. The homogeneous material included within each tubule (the surfactant matrix) did not completely fill the intratubular space, but a centrally located, spherical, 57 Å diameter, electron transparent, area was observed. The 413 Å square tubules were separated on all sides by a 25 Å fatty acid tail area. The phospholipid head areas were 46 Å and the surfactant matrix was 132 Å between the electron transparent, center area and the phospholipid heads layer.Extraction with several organic solvents was also studied: slight ethanol extraction—alteration of surfactant matrix and loss of transparent, central area. Moderate ethanol extraction—alteration of surfactant matrix to form artifactual tubules and filaments, disruption of lipid bilayers. Severe extraction—ethanol produced loss of integrity of both matrix and lipid bilayers; vinylcyclohexane dioxide or methacrylate produced complete loss of all lipid bilayers, but surfactant matrix retained tubular configuration ; DMP-30 produced complete loss of lipid bilayers, and although most of the matrix material was retained, all areas appeared fractured and randomly oriented.     

Lamellar dispersion and phase separation of chloroplast membrane lipids by negative staining electron microscopy

Aqueous dispersions of lipids isolated from spinach chloroplast membranes were studied by electron microscopy after negative staining with phosphotungstic acid. Influence of low temperature (5°C for 24 h) was also investigated. It was observed that when contacted with water, these lipids, as such, formed multilamellar structures. Upon sonication, these multilamellar structures gave rise to a clear suspension of unilamellar vesicles varying in size (diameter) between 250 and 750 Å. When samples of sonicated unilamellar vesicles were stored at 5°C for 24 h or more, they revealed a variety of lipid aggregates including liposomes, cylindrical rods (about 100 Å wide and up to 3600 Å long), and spherical micellar structures (100–200 Å in diameter)—thus indicating phase separation of lipids.     

Preparation and crystallization of a cross-linked complex of bovine adrenodoxin and adrenodoxin reductase

Bovine adrenodoxin was cross-linked to adrenodoxin reductase with 1-ethyl-3-(3-dimethyl-aminopropyl) carbodiimide. Mass spectrometry showed the reaction product to be a 1:1 complex of the two proteins with M_r = 64,790 ± 50. The cross-linked complex showed cytochrome c reductase activity and could be crystallized by hanging-drop vapor diffusion. Crystals of the adrenodoxin-adrenodoxin reductase complex are hexagonal, space group P6₁22 or P6₅22, with a = 93.26 Å and c= 612.20 Å and diffract to 2.9 Å resolution at 100 K. Assuming two cross-linked complexes per asymmetric unit yields a reasonable V_M of 2.97 ų/Da. Proteins 28:289–292, 1997. © 1997 Wiley-Liss Inc.     

Condensation of DNA by basic protiens does not depend on protien composition

We have studied by electron microscopy the size and morphology of the complexes obtained with different DNAs (between 500 and 5243 base pairs long) and four different proteins: sea urchin histone H1; sea cucumber histone ?₀, chicken erythrocyte histone H5, and clupeine. Surprisingly, the type of protein used has only a marginal influence on the complexes formed. The molecular weight and topology of DNA do not show any influence. The size of the complexes depends strongly on the ratio of positive to negative charges and also on the ionic conditions. Our studies have been mainly carried out at a ratio of 0.4. Under these conditions the average thickness of rods and toroids observed varies between 165 Å at 1.5 mM salt to 290 Å at 100 mM salt, with minor variations around these values depending on the type of DNA and protein used. We conclude that the formation of DNA condensates is mainly determined by a balance of electrostatic and intermolecular forces, the influence of specific interactions is only marginal. This conclusion seems to apply not only to the complexes described here, but also to chromatin fibers and to DNA condensed by low molecular weight counterions and other compounds (polyamines, inorganic ions, ethanol, etc.). © 1994 John Wiley & Sons, Inc.     

Membranous cytochrome c oxidase. A freeze-fracture electron microscopic analysis

Suspensions of membranous cytochrome c oxidase prepared from beef heart mitochondria by Triton extraction were ultra-rapidly cooled (in excess of 10,000 deg.C/s) and analyzed using freeze-fracture and freeze-fracture-etch techniques. The preparations contained non-crystalline and crystalline vesicles as isolated vesicles, vesicles inside other vesicles and stacks of vesicles. In non-crystalline vesicles the particles (about 100 Å diameter) are probably formed by the deviation of hydrophobic fracture planes of the membranes around the large transmembrane enzymes. The intramembrane particles thus formed are compared to particles (about 80 Å diameter) in a vesicle reconstituted from purified enzyme and lipid. Crystalline membranous cytochrome c oxidase vesicles display an unusual fracture pattern in which adjacent crystalline surfaces are separated from each other and from the surrounding ice by fracture steps that are approximately the thickness of a single membrane (100 to 120 Å). In addition adjacent crystalline fracture surfaces have similar low-relief textures, both of which differ significantly from the hydrophobic surfaces normally exposed in membrane fractures. This fracture morphology is interpreted in terms of fractures along hydrophilic surfaces of the membranes. Images of etched crystalline vesicles provide support for this interpretation because etching exposes no new surfaces. It is concluded that the crystalline lattices are derived from the portions of enzymes that protrude from the membrane bilayers and that the interdigitation of the enzymes on the inside surfaces of the vesicles or between vesicles determines the appearance of the crystalline surfaces. The arrangement of the tails of the y-shaped molecules on the cytoplasmic sides of the crystalline membranes can be visualized in micrographs directly and in reconstructions of filtered images. The more complex pattern of arms protruding on the matrix side is obscured by the unidirectional shadowing. Fragmentation of the crystalline membranes during fracturing is indicated by particles sometimes present at the edges of fractured membranes and by deep, irregular pits observed in crystalline surfaces. Particles resting on some crystalline surfaces may be fragments of crystalline membranes removed during fracturing. In other crystalline membranes non-protein is removed during fracturing, leaving globular particles embedded in the lattice, which measure about 118 Å diameter. Comparing these particles to the 3-dimensional arrangement of protein described in the accompanying paper (Frey et al., 1982) suggests that such particles are composed of 2 dimers paired along the a-axis. Intramembrane and fragmentation particles of similar size may also have this protein composition.     

Triton shells of intact erythrocytes

About 40% of human erythrocyte membrane protein is resistant to solubilization in 0.5% Triton X-114. These components comprise a structure called a Triton shell roughly similar in size and shape to the original erythrocyte and thus constitute a cytoskeleton. With increasing concentrations of Triton the lipid content of the Triton shell decreases dramatically, whereas the majority of the protein components remain constant. Exceptions to this rule include proteins contained in band 3, the presumed anion channel, and in band 4 which decrease with increasing Triton concentration. The Triton-insoluble complex includes spectrin (bands 1 and 2), actin (band 5), and bands 3′ and 7. Component 3′ has an apparent molecular weight of 88,000 daltons as does 3; but unlike 3, it is insensitive to protease treatment of the intact cell, has a low extinction coefficient at 280 nm, and is solubilized from the shells in alkaline water solutions. Component 7 also has a low extinction coefficient at 280 nm. Spectrin alone is solubilized from the Triton shells in isotonic media. The solubilized spectrin contains no bound Triton and coelectrophoreses with spectrin eluted in hypotonic solutions from ghosts. Electron micrographs of fixed Triton shells stained with uranyl acetate show the presence of numerous filaments which appear beaded and are 80–120 Å in diameter. The filaments cannot be composed mainly of actin, but enough spectrin is present to form the filaments. Triton shells may provide an excellent source of material useful in the investigation of the erythrocyte cytoskeleton.