First images of a glutamate receptor ion channel: oligomeric state and molecular dimensions of GluRB homomers.

We have expressed, purified, and characterized glutamate receptor ion channels (GluR) assembled as homomers of the subunit GluRB. For the first time, single-milligram quantities of biochemically homogeneous GluR have been obtained. The protein exhibits the expected pharmacological profile and a high specific activity for ligand binding. Density-gradient centrifugation reveals a uniform oligomeric assembly and a molecular mass suggesting that the channel is a tetramer. On the basis of electron microscopic images, the receptor appears to form an elongated structure that is visualized in several orientations. The molecular dimensions of the molecule are approximately 11 x 14 x 17 nm, and solvent-accessible features can be seen; these may contribute to formation of the ion-conducting pathway of the channel. The channel dimensions are consistent with an overall 2-fold symmetric assembly, suggesting that the tetrameric receptor may be a dimer of dimers.

Effect of the ionic environment on the molecular structure of bacteriophage SPP1 portal protein.

Bacteriophage SPP1 portal protein is a large cyclical homo-oligomer composed of 13 subunits. The solution structure and assembly behavior of this protein with high-point rotational symmetry was characterized. The purified protein was present as a monodisperse population of 13-mers, named gp6H, at univalent salt concentrations in the hundred millimolar range (>/= 250 mM NaCl) or in the presence of bivalent cations in the millimolar range (>/= 5 mM MgCl2). Gp6H had a slightly higher sedimentation coefficient, a smaller shape-dependent frictional ratio, and a higher rate of intersubunit cross-linking in the presence of magnesium than in its absence. In the absence of bivalent cations and at univalent salt concentrations below 250 mM, the 13-mer molecules dissociated partially into stable monomers, named gp6L. The monomer had a somewhat different shape from the subunit present in the 13-mer, but maintained a defined tertiary structure. The association-dissociation equilibrium was mainly between the monomer and the 13-mer with a minor population of intermediate oligomers. Their interconversion was strongly influenced by the ionic environment. Under physiological conditions, the concentration of Mg2+ found in the Bacillus subtilis cytoplasm (10-50 mM) probably promotes complete association of gp6 into 13-mer rings with a compact conformation.

Ultrastructural characterization of peptide-induced membrane fusion and peptide self-assembly in the lipid bilayer.

The peptide sequence B18, derived from the membrane-associated sea urchin sperm protein bindin, triggers fusion between lipid vesicles. It exhibits many similarities to viral fusion peptides and may have a corresponding function in fertilization. The lipid-peptide and peptide-peptide interactions of B18 are investigated here at the ultrastructural level by electron microscopy and x-ray diffraction. The histidine-rich peptide is shown to self-associate into two distinctly different supramolecular structures, depending on the presence of Zn(2+), which controls its fusogenic activity. In aqueous buffer the peptide per se assembles into beta-sheet amyloid fibrils, whereas in the presence of Zn(2+) it forms smooth globular clusters. When B18 per se is added to uncharged large unilamellar vesicles, they become visibly disrupted by the fibrils, but no genuine fusion is observed. Only in the presence of Zn(2+) does the peptide induce extensive fusion of vesicles, which is evident from their dramatic increase in size. Besides these morphological changes, we observed distinct fibrillar and particulate structures in the bilayer, which are attributed to B18 in either of its two self-assembled forms. We conclude that membrane fusion involves an alpha-helical peptide conformation, which can oligomerize further in the membrane. The role of Zn(2+) is to promote this local helical structure in B18 and to prevent its inactivation as beta-sheet fibrils.

Cryo-electron microscopy structure of yeast Ty retrotransposon virus-like particles.

The virus-like particles (VLPs) produced by the yeast retrotransposon Ty1 are functionally related to retroviral cores. These particles are unusual in that they have variable radif. A paired mass-radius analysis of VLPs by scanning transmission electron microscopy showed that many of these particles form an icosahedral T-number series. Three-dimensional reconstruction to 38-A resolution from cryo-electron micrographs of T = 3 and T = 4 shells revealed that the single structural protein encoded by the TYA gene assembles into spiky shells from trimeric units.

Bacteriophage PRD1 proteins: cross-linking and scanning transmission electron microscopy analysis.

Bacteriophage PRD1, a double-stranded DNA virus infecting Escherichia coli, has a membrane inside the protein capsid. Chemical cross-linking and scanning transmission electron microscopy showed that the multimeric major coat protein (P3) exists in a trimeric form. Cross-linking revealed, in addition, that protein P11, located between the protein coat and the membrane, exists also as a homotrimer. Minor protein P7 was associated with the major coat protein P3. Under nonreducing conditions the infectivity proteins P16 and P18 formed homomultimeric complexes which were dissociated upon addition of 2-mercaptoethanol.

Radial mass density functions of vitrified helical specimens determined by scanning transmission electron microscopy: their potential use as substitutes for equatorial data.

Using STEM dark field images, we have determined linear mass densities and radial density profiles of vitrified helical particles. The samples studied are: TMV, RNA-free helical polymers of TMV coat protein (TMV-P), Salmonella typhimurium bacterial flagellar filaments and Escherichia coli pili. The difference between the profiles obtained for TMV and TMV-P shows a maximum at a radius of about 4 nm, corresponding to the RNA in TMV. Of the peaks that are resolved in X-ray diffraction analysis we can resolve the ones for TMV at radii of approximately 4.2 and approximately 6.7 nm and a shoulder at approximately 7.8 nm. Density peaks in bacterial flagellar filaments appear at radii of approximately 4.2, approximately 6.5, approximately 8.5, and approximately 10.5 nm. Accurate mass data can be obtained if the filaments are embedded in ice layers of uniform thickness; their diameters need to be similar to that of the mass standard (TMV) when these data are measured in a comparative manner. Ice layers are often not uniform, and thickness variations are well revealed in STEM dark field. The signal-to-noise ratio and contrast for the transverse projections are lower than those measured for freeze-dried specimens: half an order and one order of magnitude, respectively. The thinnest uniformly thick ice layer still containing a single layer of particles is approximately 10-15 nm thicker than the particles. Radial mass density functions that are directly determined in STEM may have a potential use as substitutes for the unreliable equatorial data in helical reconstructions of TEM bright field images of vitrified specimens.

The aerolysin membrane channel is formed by heptamerization of the monomer.

The cytolytic toxin aerolysin has been found to form heptameric oligomers by SDS-PAGE electrophoresis, STEM mass measurements of single oligomers and image analysis of two-dimensional membrane crystals. Two types of crystal, flat sheets and long regular tubes, have been obtained by reconstitution of purified protein and Escherichia coli phospholipids. A noise-filtered image of the best crystalline sheets reveals a structure with 7-fold symmetry containing a central strongly stain-excluding ring that encircles a dark stain-filled channel 17 A in diameter. The ring is surrounded by seven arms each made up of two unequal sized domains. By combining projected views and side-views, a simplified model of the aerolysin channel complex has been constructed. The relevance of this structure to the mode of action of aerolysin is discussed.

Characteristic views of Escherichia coli RNA polymerase core enzyme in the scanning transmission electron microscope.

Eight characteristic views of Escherichia coli RNA polymerase core enzyme are presented which were found using multivariate statistical image processing of about 1000 individual molecular images. The data set was obtained from negatively stained specimens with a scanning transmission electron microscope (STEM) operated in dark field mode. The molecular projections were found to a resolution of around 30 A, thus visualizing new structural details of the core enzyme. An approximate twofold axis seems to relate the beta to the beta' subunit as well as both alpha units to each other.

Electron microscopic characterization of helical filaments formed by subunits I and II (core proteins) of ubiquinol: cytochrome c reductase from Neurospora mitochondria.

The isolated and water-soluble complex of subunits I and II (core proteins) of ubiquinone:cytochrome c reductase from Neurospora mitochondria forms filaments below pH 6.0. Three independent helical reconstructions of single filaments were compared with the 3-D reconstruction of the native enzyme. A model for the helix is proposed in which the core complex dimers are arranged radially with the face which is proximal to the membrane in the native enzyme on the outside of the helix. The dimension of the core complex dimer perpendicular to the helix axis (70 A) provides an independent estimate of the height of the core complex to that obtained previously from cytochrome reductase crystals. The results of STEM mass measurement and the helical model give a mass per repeating unit of 90 kDa, which would indicate that the monomeric core complex consists of one 45-kDa and one 50-kDa subunit.

Identification and electron microscopic analysis of a chaperonin oligomer from Neurospora crassa mitochondria.

A 7-fold symmetric particle has been identified in Neurospora crassa which is most probably the mitochondrial chaperonin. The particle, about 12 nm in diameter, appears in preparations of cytochrome reductase, and is shown to contain a 60 kd protein which cross-reacts with anti-GroEL antibodies. Results of STEM mass measurement suggest that the particle is composed of 14 subunits. A preliminary interpretation of the structure of the particle based on electron microscopy is given. Its quaternary structure and molecular weight are similar to those of the recently discovered family of particles called chaperonins, found in bacteria, chloroplasts and mitochondria.

Structural characterization of the core of the paired helical filament of Alzheimer disease.

The paired helical filament, the principal constituent of the neurofibrillary tangles characteristic of Alzheimer disease, is shown to consist of two structurally distinct parts. An external fuzzy region can be removed by Pronase treatment to leave a Pronase-resistant morphologically recognizable core. Scanning transmission electron microscopy gives an estimate for the mass per unit length as 79 kDa.nm-1 before Pronase treatment and 65 kDa.nm-1 after treatment. The fuzzy region carries all the epitopes recognized by two different antisera against microtubule-associated protein tau. By contrast, a monoclonal antibody (mAb) we have raised to paired helical filament cores (mAb 423) decorates Pronase-treated filaments much more strongly than it does untreated ones. We have shown in previous papers that the epitope recognized by mAb 423 is carried by a central 9.5-kDa fragment of tau protein, which therefore forms part of the Pronase-resistant core structure. The remainder of the tau protein incorporated into the filaments must contribute part, if not all, of the fuzzy region. The mass per unit length measurements imply that the three-domain structural subunit of the core that we visualized previously by image reconstruction has a molecular mass of approximately equal to 100 kDa.

Three-dimensional reconstruction of maltoporin from electron microscopy and image processing.

Two dimensional crystals of maltoporin (or phage lambda receptor) were obtained by reconstitution of purified maltoporin trimers and Escherichia coli phospholipids by detergent dialysis. Two different trimer packing forms were observed. One was hexagonal (a = 7.8 nm) and one rectangular (a = 7.8 nm, b = 13.6 nm). In this paper we describe the three-dimensional structure of maltoporin, deduced from the study of the rectangular form by electron microscopy and image processing. At a resolution of approximately 2.5 nm, maltoporin trimers form aqueous channel triplets which appear to merge into a single outlet at the periplasmic surface of the outer membrane. The pore defined by maltoporin has a similar structure to that outlined by the matrix protein. From the results of functional studies by conductance measurement, it is concluded that the three channels defined by maltoporin act, contrary to those formed by the porin (OmpF protein), as a single conducting unit. A tentative outline of the maltoporin promoter is given. Maltoporin appears to be constituted by three different domains: a major rod-like domain spanning the membrane, a minor domain located near the periplasmic surface of the membrane and finally a central domain responsible for the splitting of the channel.

The quaternary structure of Escherichia coli RNA polymerase studied with (scanning) transmission (immuno)electron microscopy.

A model for the quaternary structure of Escherichia coli RNA polymerase (nucleosidetriphosphate:RNA nucleotidyltransferase, EC 2.7.7.6) is presented. It is based on results from classification of profiles of enzyme molecules, and from application of immuno electron microscopy. Classification of molecules, prepared with the single carbon layer technique, was first achieved for images recorded in dark field with the scanning transmission electron microscope and later on for images recorded in bright-field transmission electron microscopy. It results in five approximately equally sized groups, containing about 80% of the core enzyme profiles. Holoenzyme profiles can be grouped into the same classes, and have approximately the same dimensions (9 nm X 16 nm). Based on the shapes and sizes of the classified profiles, a tentative model for core enzyme has been constructed. Correlation of shadow projections of this model, with the distributions of attachment sites of antibodies against alpha, beta, beta' and sigma over the profiles, has led to models for core and holoenzyme in which the subunits are localized. The model is compared with literature data on the quaternary structure of RNA polymerase.

Scanning transmission electron microscopy of biological macromolecules.

The practical usefulness of a STEM (Scanning Transmission Electron Microscope) for the study of the structure of biological macromolecules has been investigated using a STEM attachment connected to a TEM (Transmission Electron Microscope), which in one case was equipped with a tungsten hairpin cathode, and in the other case with a field emission gun. The point to point resolution has been determined. Results obtained in STEM dark field from light negatively stained specimens are compared with results obtained in TEM bright field from normal negatively stained specimens. In addition unstained molecules have been visualized. Some remarks are made about preparation methods suitable for STEM.

Estradiol-induced synthesis of vitellogenin. I. The isolation of large polysomes from estrogenized rooster liver.

Conventional procedures for the isolation of polysomes, applied to estrogenized rooster liver, fail to yield polysomes containing 30 or more ribosomes, the size expected for polysomes synthesizing the estradiol-induced protein vitellogenin. A new procedure characterized by early and selective removal of cell components ribonucleases allowed the isolation of polysomes with up to 55 ribosomes. Electron microscopy was used for the determination of polysome size and showed that the large polysomes were not aggregates.