Wheat germ cytoplasmic ribosomes. Localization of 7-methylguanosine and 6-methyladenosine by electron microscopy of immune complexes

Nucleoside analysis of the RNA from the small subunit of wheat germ cytoplasmic ribosomes shows 1 mol each of N7-methylguanosine and N6-methyladenosine/mol of RNA. Antibodies directed against each methylated nucleoside were used to localize these residues within the subunit by electron microscopy of immune complexes. Antibodies to 7-methylguanosine bound 40 S subunits at a single site, at or slightly above the division between the upper and lower segments of the particle and on the surface furthest from the platform (or large lobe) of the subunit. This site is essentially equivalent to that previously seen with Escherichia coli and chloroplast 30 S subunits (Trempe, M. R., Ohgi, K., and Glitz, D. G. (1982) J. Biol. Chem. 257, 9822-9829). Antibodies to N6-monomethyladenosine were induced in rabbits with a nucleoside-albumin conjugate and shown to be specific for the modified nucleoside. Electron microscopy of antibody-subunit complexes placed the methyladenosine residue in a position that is essentially indistinguishable from that of 7-methylguanosine.     

Structure of ribosomes and ribosomal subunits of Drosophila

Summary The ultrastructure of Drosophila melanogaster cytoplasmic ribosomal subunits and monomers have been examined by electron microscopy. The Drosophila ribosomal structures are compared to those determined for other eucaryotes and E. coli. Negatively contrasted images of 60S subunits are seen in the most frequent view to be approximately round particles about 280 Å in diameter. About 35% of the particles present a single prominent projection which we call the 60S peak. The peak emanates from a flattened region of the 60S subunit. The maximum observed length of the 60S peak is approximately 90Å. The Drosophila 60S peak is highly reminiscent of the E. coli L7/L12 stalk. The Drosophila 40S subunit is an elongated, slightly bent particle which measures 280×170×160 Å. It bears a strong resemblance to small ribosomal subunits of other eucaryotes and is strikingly similar to the E. coli 30S subunit. Micrographs of 80S monomeric ribosomes show the long axis of the 40S to be parallel and in apparent contact with the flattened region of 60S subunit. The 60S peak appears to bisect the long axis of the 40S subunit. The 40S subunit seems to be oriented in the monomeric ribosome so that the 40S projection is toward the body of the large subunit. Comparison of our data with similar studies in different organisms indicates that the eucaryotic large ribosomal subunits exhibit morphological heterogeneity while the small subunits remain remarkably similar.     

Localization of yeast RNA polymerase I core subunits by immunoelectron microscopy.

Immunoelectron microscopy was used to determine the spatial organization of the yeast RNA polymerase I core subunits on a three-dimensional model of the enzyme. Images of antibody-labeled enzymes were compared with the native enzyme to determine the localization of the antibody binding site on the surface of the model. Monoclonal antibodies were used as probes to identify the two largest subunits homologous to the bacterial beta and beta' subunits. The epitopes for the two monoclonal antibodies were mapped using subunit-specific phage display libraries, thus allowing a direct correlation of the structural data with functional information on conserved sequence elements. An epitope close to conserved region C of the beta-like subunit is located at the base of the finger-like domain, whereas a sequence between conserved regions C and D of the beta'-like subunit is located in the apical region of the enzyme. Polyclonal antibodies outlined the alpha-like subunit AC40 and subunit AC19 which were found co-localized also in the apical region of the enzyme. The spatial location of the subunits is correlated with their biological activity and the inhibitory effect of the antibodies.     

Localization of subunits in proteasomes from Thermoplasma acidophilum by immunoelectron microscopy

The subunit topography of the Thermoplasma acidophilum proteasome was determined by iminunoelectron microscopy using monospecific antibodies directed against the two constituent subunits (,β). Anti--subunit IgG was found to bind to the outer disks of the cylinder- or barrel-shaped molecule, while the binding sites of the anti-β-subunit IgG were mapped on the two inner rings. Probably the homologues of the two subunits in the compositionally more complex but isomorphous eukaryotic proteasomes occupy equivalent positions.     

Subcellular localization of DNA-binding protein BA by immunofluorescence and immunoelectron microscopy

Nonhistone protein BA has been shown to decrease in amount in the chromatin of growth- stimulated normal rat liver (Yeoman et al. 1975. Cancer Res. 35:1249-1255) and in mitogen-stimulated normal human lymphocytes (Yeoman et al. 1976. Exp. Cell Res. 100:47- 55.). Subsequently, protein BA was purified and was shown to prefer to bind to double- stranded A-T-rich DNAs (Catino et al. 1978. Biochemistry. 17:983-987.). Immunization of rabbits with highly purified protein BA has resulted in the production of a specific antibody. A specific immunoreactivity for chromosomal protein BA has been demonstrated by immunoelectrophoresis and double antibody immunoprecipitation analysis with rabbit anti-BA immunoglobulin and IgG fractions. Light microscope examination of normal rat liver crysections by the indirect immunofluorescence procedure has demonstrated a cytoplasmic as well as a nuclear localization for protein BA with a pronounced perinucleolar fluorescence. Immunoelectron microscopy employing the peroxidase antiperoxidase method of antigen localization has confirmed the immunofluorescence data and has show a heterochromatin localization for protein BA. The relationship of the localization of protein BA to gene control in quiescent cells or to configurations of heterochromatin as well as the marked reduction in the amounts of protein BA which occur in stimulated growth states remains to be defined.     

Ribosome structure determined by electron microscopy of Escherichia coli small subunits,large subunits and monomeric ribosomes

Unique, three-dimensional structures have been determined for Escherichia coli small subunits, large Subunits and monomeric ribosomes by electron microscopy of ribosomes and subunits and of antibody-labeled ribosomes and subunits.Small subunits orient on the carbon substrate with their long axes parallel to the plane of the carbon. In these projections the subunit is divided into a onethird and a two-thirds portion by a region of accumulated negative stain similar to that observed in eukaryotic small subunits. Four characteristic views, or projections, are readily recognized and correspond to orientations of approximately ?40 °, 0 °, +50 ° and +110 ° about the long axis of the subunit. Three of these have been described (Lake et al., 1974a; Lake & Kahan, 1975). The two most distinctive views are a quasi-symmetric view (0 °) that is characterized by an approximate line of mirror symmetry that coincides with the long axis of the subunit, and an asymmetric view (110 °) that is characterized by a concave and a convex subunit boundary. In the asymmetric projection, a platform or ledge is viewed “face-on”. The platform is attached to the lower two-thirds of the subunit just below the one-third/two-thirds partition. It is separated from the upper one-third of the subunit at the level of the partition and above the partition it forms a cleft approximately 30 to 40 Å wide, which has been suggested as the site of the codon-anticodon interaction (Lake & Kahan, 1975).Four characteristic views are presented for the large subunit. The most prominent of these, the quasi-symmetric view (θ = 90 °, φ = 0 °), is distinguished by a central protuberance located on a line of approximate mirror symmetry. The central protuberance is surrounded by projecting features inclined at about 50 ° on both sides of it. The smaller of these projections is rod-like, about 40 Å wide and approximately 100 Å long. The feature projecting from the other side of the central protuberance is shorter, more blunt and wider than the rod-like appendage. In another view approximately orthogonal to the quasi-symmetric projection, the asymmetric projection (θ = 10 °, φ = 90 °), the subunit profile is distinguished by a convex lower edge and an upper boundary which is indented by a notch. The subunit is separated, in projection, by the notch into two unequal regions. The smaller region comprises about 20% of the total projected density and consists of the central protuberance and the rod-like appendage.The profiles observed in fields of monomeric 70 S ribosomes result from superpositions of the 30 S and 50 S profiles. Two major views are observed, an overlap and a non-overlap view, corresponding to whether or not the profile of the small subunit overlaps that of the large subunit in the 70 S profile. The small subunit is oriented in the monomeric ribosome so that the platform is in contact with the large subunit. The central protuberance of the large subunit overlaps part of the upper one-third of the small subunit in the overlap view of 70 S ribosomes, although in three dimensions they are probably separated by 30 to 50 Å. A region of the small subunit comprising the platform, the cleft and part of the upper one-third, suggested to be the approximate binding site of IF3 and IF2 (Lake & Kalian, 1975), is located at the interface between the large and small subunits, in a region of the small subunit that is close to, but probably not in physical contact with, the large subunit.     

Nuclear export and cytoplasmic maturation of ribosomal subunits

Based on the characterization of ribosome precursor particles and associated trans-acting factors, a biogenesis pathway for the 40S and 60S subunits has emerged. After nuclear synthesis and assembly steps, pre-ribosomal subunits are exported through the nuclear pore complex in a Crm1- and RanGTP-dependent manner. Subsequent cytoplasmic biogenesis steps of pre-60S particles include the facilitated release of several non-ribosomal proteins, yielding fully functional 60S subunits. Cytoplasmic maturation of 40S subunit precursors includes rRNA dimethylation and pre-rRNA cleavage, allowing 40S subunits to achieve translation competence. We review current knowledge of nuclear export and cytoplasmic maturation of ribosomal subunits.     

Structure of LiCl core particles of 50 S ribosomal subunits from Escherichia coli by electron microscopy.

The structure of 50 S E. coli ribosomal subunits was studied by electron microscopy as these particles were gradually depleted of proteins by incubation with 0.5 to 6.0 m LiCl. Changes observed in the structure of the depleted subunits were correlated with the location of the deleted ribosomal proteins on the control 50 S particle. These changes were particularly striking in the "crown" region, the site of a considerable number of the proteins necessary for the biological activity of the 50 S subunit. Protein L 16, the first to be removed by the LiCl treatment, was found to be essential for the structural integrity of the large subunit through interactions with ribosomal proteins residing in the left-hand side crest and the interface. Based on electron microscopic evidence, a scheme was proposed for the structural changes accompanying the stepwise unfolding of the 50 S E. coli subunit by LiCl.     

The extraction of proteins from eukaryotic ribosomes and ribosomal subunits

Proteins were extracted from rat liver ribosomes and ribosomal subunits: with 67% acetic acid (in the presence of 3.3 mM, 33 mM, or 67 mM Mg) with 2 M LiCL in 4 M urea; with 0.25 N HCI; with 1% SDS; and after RNase digestion. The most efficient extraction and the best recovery were either with acetic acid in the presence of 33 mM or 67 mM Mg, or with LiCI-urea. Protein extracted with acetic acid, LiCi-urea, or with HCI had little or no contamination with RNA. The ribosomal proteins were analyzed by two-dimensional polyacrylamide gel electrophoresis: the proteins extracted with acetic acid were the most soluble in the sample gel solution; their electrophoretograms displayed the maximum number of spots and the smallest number of derivatives or altered proteins. Preparations of protein extracted with SDS or RNase were relatively insoluble in the sample gel solution, and proteins extracted with HCI showed a large number of derivatives. All things considered, the most satisfactory method for the extraction of protein from eukaryotic ribosomes is with 67% acetic acid in the presence of 33 mM MgCl2.     

Visualization of the cytoplasmic surface of Torpedo postsynaptic membranes by freeze-etch and immunoelectron microscopy

The synapse-specific Mr 43,000 protein (43K protein) and the acetylcholine receptor were visualized by freeze-etch immunoelectron microscopy in preparations of purified Torpedo postsynaptic membranes. Vesicles were immobilized on glass and then sheared open by sonication to expose the cytoplasmic surface. Membranes were labeled with monoclonal antibodies to the 43K protein or the acetylcholine receptor. The cytoplasmic surface was devoid of filamentous structure, and the 43K protein and the cytoplasmic projection of the acetylcholine receptor were associated with prominent surface particles. Acetylcholine receptor and 43K protein, in membrane surfaces in direct contact with glass coated with polyornithine, segregated into dense particle aggregates separated by smooth membrane patches, whereas those in contact with glass coated with Alcian Blue underwent little or no detectable rearrangement. After treatment of vesicles at alkaline pH to remove the 43K protein, the cytoplasmic surfaces were still covered by a dense array of particles that were more uniform in shape and appeared slightly shorter than those seen on unextracted membranes, but similar in height to the extracellular projection. Monoclonal antibodies to the acetylcholine receptor labeled these particles, while antibodies to 43K protein did not. We conclude that the 43K protein is in direct association with the receptor and that complexes of the receptor and 43K protein can undergo surface-induced lateral redistribution. In addition, the cytoplasmic projection of the acetylcholine receptor is sufficiently large to be readily detected by freeze-etch electron microscopy and is similar in height to the extracellular projection.     

Characterization of N6, O2-dimethyladenosine from nuclear RNA of Novikoff hepatoma.

A modified nucleoside was isolated from low molecular weight nuclear RNA of Novikoff hepatoma, the nucleotide sequence of which was reported earlier. The structure of this novel nucleoside was shown to be N6, O2'-dimethyladenosine (m6Am) by mass spectrometry of its trimethylsilyl derivative and by comparison with the mass spectra of N6- and O-2' monmethyl model compounds. The complete characterization was carried out using 0.04 A260 units (2 microgram) of m6Am.