Heterogeneity of Escherichia coli ribosomes established by scanning transmission electron microscopy.

Quantitative mass image analysis of Escherichia coli ribosomal particles by scanning transmission electron microscopy (STEM) provided direct evidence that presumably homogeneous preparations of ribosomes are, in reality, populations of heterogeneous particles. Variations in composition, relative molecular mass (Mr) and shape were observed both in the monosomes and in the ribosomal subunits. None of these changes can be resolved visually; they can be evaluated only by computer processing. The variations in relative mass and shape monitored by values of radius of gyration (RG) were attributed to the loss of ribosomal proteins and/or factors and correlated with the changes in ribosome composition and biological activity. The highest activity was found in monosomes prepared from the standard 0.5 M NH4Cl wash. With increasing concentrations (up to 1.5 M) of NH4Cl in the wash buffer the activity decreased slowly, then dropped rapidly to about half in 2 M NH4Cl. The most striking effects were observed in ribosomal particles washed with 0.1 M NH4Cl. The 70S monosomes and the 30S subunits attained maximum Mr and RG values (2660 kDa and 76 A, and 990 kDa and 75 A, respectively), which were greater than the theoretical values, while the activity was minimal (approximately 12%). The Mr and RG parameters of the 50S subunits remained uneffected by the NH4Cl washes (approximately 1600 kDa and 68 A).     

Mitochondrial structure revealed by high-resolution scanning electron microscopy

Mitochondrial structure has been examined in three dimensions using high-resolution scanning electron microscopy in cells from rat liver, retina (photoreceptors and retinal pigment epithelium), and kidney (proximal convoluted tubular cells and podocytes). Tissues were prepared by aldehyde-osmium fixation and freeze cleavage using a cryoprotectant, followed by removal of the cytosol by immersion in a dilute osmium tetroxide solution. The microscope used (Hitachi S-570) was equipped with a secondary electron detector located in the column above the specimen, situated within the objective lens. Mitochondria in all tissues examined were found to have only tubular cristae, which in some instances could be seen to span the entire diameter of the organelle. The walls of the tubular cristae, when unfractured, were in contact with the inner mitochondrial membrane; and their lumens were open to the intermembranous space. We hypothesize that in cells of many, perhaps most tissues, mitochondrial cristae are not shelf-like but are, in fact, tubes which span the mitochondrial matrix and are continuous with the inner mitochondrial membrane at both ends.     

Subunit arrangement of Escherichia coli F1-ATPase studied by scanning transmission electron microscopy

The shape and the arrangement of subunits in Escherichia coli F1-ATPase (ECF1) lacking the delta subunit have been explored with a high performance scanning transmission electron microscope. In tilting experiments, the ECF1 molecule appeared as a flat cylinder whose width (approx. 120 A) was about twice its height. The symmetry of front view projections of ECF1 has been investigated by computer analysis. In a population taken at random from the data bank, one third of the particles showed five-fold radial symmetry components, one third six-fold radial symmetry components and the last third no typical symmetry. The six-fold radial symmetry was consistent with a hexagonal arrangement of six large peripheric masses, which probably correspond to the three alpha and the three beta subunits of ECF1. The five-fold radial symmetry was tentatively explained by a fusion of two juxtaposed peripheric subunits. Lateral projections showed a zig-zag organization of the large masses, suggesting that the large alpha and beta subunits are located on two levels, with some degree of intercalation between the subunits of the two levels.     

Escherichia coli pyruvate dehydrogenase complex: particle masses of the complex and component enzymes measured by scanning transmission electron microscopy

Particle masses of the Escherichia coli pyruvate dehydrogenase (PDH) complex and its component enzymes have been measured by scanning transmission electron microscopy (STEM). The particle mass of PDH complex measured by STEM is 5.28 X 10(6) with a standard deviation of 0.40 X 10(6). The masses of the component enzymes together with their standard deviations are (2.06 +/- 0.26) X 10(5) for the dimeric pyruvate dehydrogenase (E1), (1.15 +/- 0.17) X 10(5) for dimeric dihydrolipoyl dehydrogenase (E3), and (2.20 +/- 0.17) X 10(6) for dihydrolipoyl transacetylase (E2), the 24-subunit core enzyme. The latter value corresponds to a subunit molecular weight of (9.17 +/- 0.71) X 10(4) for E2. The subunit molecular weight measured by polyacrylamide gel electrophoresis in sodium dodecyl sulfate is 8.6 X 10(4). STEM measurements on PDH complex incubated with excess E3 or E1 failed to detect any additional binding of E3 but showed that the complex would bind additional E1 under forcing conditions (high concentrations with glutaraldehyde). The additional E1 subunits were bound too weakly to represent binding sites in an isolated or isolable complex. The mass measurements by STEM are consistent with the subunit composition 24:24:12 when interpreted in the light of the flavin content of the complex and assuming 24 subunits in the core enzyme (E2).     

Conformational analysis of 16 S ribosomal RNA from Escherichia coli by scanning transmission electron microscopy

Digitized images of molecules of 16 S rRNA from Escherichia coli, obtained by scanning transmission electron microscopy (STEM), provide quantitative structural information that is lacking in conventional electron micrographs. We have determined the morphology, total molecular mass, mass distribution within individual rRNA molecules and apparent radii of gyration. From the linear density (M/L) we have assessed the number of strands in the structural backbone of rRNA and studied the pattern of branching and folding related to the secondary and tertiary structure of rRNAs under various buffer conditions. Even in reconstitution buffer 16 S RNA did not show any resemblance to the native 30 S subunit.     

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.     

Visualization of ion-dependent conformational changes in Escherichia coli 23 S rRNA by scanning transmission electron microscopy

Electron micrographs of Escherichia coli 23 S rRNA molecules obtained by scanning transmission electron microscopy, unstained and under nondenaturing conditions, reveal previously unresolved structural patterns. The complexity of the pattern is dependent upon the ambient ionic strength conditions. In water and in very low ionic strength buffer, the conformation of 23 S rRNA is characterized by an extended framework, with short side branches related to the secondary and tertiary structure of the molecule. The total length of this filamentous complex is approximately 2500 A, only about one-fourth of the length of 23 S rRNA when fully stretched under the denaturing conditions used for imaging by conventional electron microscopy. These data, supplemented by the determination of the linear density (M/L), suggest that in low ionic strength the backbone of 23 S rRNA is formed by a structure corresponding, on the average, to the mass of four nucleotide strands (M/L approximately equal to 480 Da/A). With increasing ionic strength, 23 S rRNA coils into more compact forms. Molecules in these states can be characterized by apparent radii of gyration (RG), which can be calculated from the mass distribution within the digitized images of individual RNA molecules. The 23 S rRNA is in its most condensed form (RG = 115 A) in ribosomal reconstitution buffer; however, it still does not attain the compactness of the large subunit (RG = 69 A), nor does it show any resemblance to the native 50 S subunit. The net content of ordered secondary structure, as determined by circular dichroism spectroscopy, is not visibly affected by the changes of ionic strength conditions. These results imply that the observed conformational changes in 23 S rRNA are caused by intramolecular folding of the 23 S rRNA strands induced by the shielding effect of ambient charges.     

Organization of developing Escherichia coli colonies viewed by scanning electron microscopy.

Colony growth was initiated by inoculating minimal glucose agar with 1-microliter. spots of a plasmid-free Escherichia coli culture and incubating at 32 degrees C. Inoculations took place over a 3-day period, at the end of which the plates were fixed and dried for scanning electron microscopy. In this way, it was possible to examine the surfaces of colonies ranging in age from 0 to 68 h. Macroscopically, the colonies were organized into different concentric zones, and several morphological features could be seen to develop over this period. These included a shallow depression ring marking the site of inoculation, a deeper indentation ring whose position moved outward as the colony grew, an expanding plateau region between the two rings, a mound outside the indentation ring, and a flat brim extending onto the substrate which was either present or absent at different times. Microscopically, a variety of cell morphologies and cell arrangements were detected. Upon inoculation, the bacteria accumulated at the periphery of the inoculation spot but showed no other kind of order. For the first 7.5 h, all bacteria were rod shaped; at the end of this initial phase, a high degree of alignment was seen in the cells at the colony edge. By 24.5 h, both shorter more ovoid cells and longer filaments had begun to appear, and large multicellular arrays had formed. At later stages of colony development, morphologically distinguishable zones involving cells of different shapes and sizes had formed, and these zones often marked the boundaries of macroscopic features. The edges were particularly interesting and at 68 h displayed very sharp saw-toothed boundaries between concentrically organized groups of bacteria. There were some transient irregularities in the concentric organizations of growing colonies, and one colony had entered upon a distinct developmental pathway.     

Secretion of LamB-LacZ by the signal recognition particle pathway of Escherichia coli

LamB-LacZ fusion proteins have classically been used in studies of the general secretion pathway of Escherichia coli. Here we describe how increasing signal sequence hydrophobicity routes LamB-LacZ Hyb42-1 to the signal recognition particle (SRP) pathway. Secretion of this hydrophobic fusion variant (H*LamB-LacZ) was reduced in the absence of fully functional Ffh and Ffs, and the translocator jamming caused by Hyb42-1 was prevented by efficient delivery of the fusion to the periplasm. Finally, we found that in the absence of the ribosome-associated chaperone, trigger factor (Tig), LamB-LacZ localized to the periplasm in a SecA-dependent, SRP-independent fashion. Collectively, our results provide compelling in vivo evidence that there is an SRP-dependent cotranslational targeting mechanism in E. coli and argue against a role for trigger factor in pathway discrimination.     

Helical structure of P pili from Escherichia coli. Evidence from X-ray fiber diffraction and scanning transmission electron microscopy.

The structure of the P pili from Escherichia coli has been studied using X-ray fiber diffraction and scanning transmission electron microscopy (STEM). Analysis of the fiber diffraction data indicates that the pili are constituted largely of structural subunits arranged helically with approximately 33 subunits in 10 turns in an axial repeat of 244.5 +/- 1.8 A. Radial electron density distributions calculated from equatorial diffraction data and STEM data indicate that the pili are about 65 A in diameter with a small central cavity roughly 15 A across. The principal protein component of the pili is PapA, which has a molecular weight of 16.5 kDa. Assuming that each subunit consists of a single PapA molecule, the mass-per-unit-length of the pili predicted from the X-ray data is 2.23 kDa/A. Measurements of mass-per-unit-length were also made through the analysis of STEM images. These measurements indicate a value of 2.13 +/- 0.14 kDa/A. STEM images demonstrated the presence of thin, thread-like structures emerging from the ends of pili and spanning breaks in the pili structure. These structures, which have been observed under other conditions, have been termed fibrillae. In the STEM images the fibrillae appear about 20 A in diameter. The mass-per-unit-length of the fibrillae was estimated using the STEM data to be 0.4 kDa/A. These data are consistent with the fibrillae representing an unwound or unraveled form of the pili proteins overstretched to about five times the length they would have in the intact pili.     

The maxillae of Drosophila melanogaster as revealed by scanning electron microscopy

The scanning electron micrographs show the external morphology of the maxillae of Drosophila melanogaster. Specifically, they illustrate the patterning of the different types of chemo-receptive sensilla on the maxillary palpi making possible a clearer understanding of the structure of the tiny maxillary lobes. It appears that the maxillary lobes act as “cleaning brushes” during the feeding process.     

Shell structure in Difflugia Lobostoma observed by scanning and transmission electron microscopy

Observations by scanning and transmission electron microscopy provide information about shells of Difflugia lobostoma which suggests a complex activity in shell construction. As observed by scanning microscopy, the shell consists of a single layer of sand grains which are organized into rosettes. The sand grains of the rosettes are different in size from those of flat areas between rosettes suggesting that the organism sorts these stones and places them according to size. Hydrofluoric acid treatment dissolves the sand but leaves a web of cement material intact. Examination of such acid treated specimens by transmission microscopy shows structure in the cement material of the shell, and granules of similar structure in the cell body. The rosette pattern observed differs from shell patterns in other species of Difflugia, and this suggests that shell structure may be species specific.     

Consequences of depletion of the signal recognition particle in Escherichia coli

Thus far, the role of the Escherichia coli signal recognition particle (SRP) has only been studied using targeted approaches. It has been shown for a handful of cytoplasmic membrane proteins that their insertion into the cytoplasmic membrane is at least partially SRP-dependent. Furthermore, it has been proposed that the SRP plays a role in preventing toxic accumulation of mistargeted cytoplasmic membrane proteins in the cytoplasm. To complement the targeted studies on SRP, we have studied the consequences of the depletion of the SRP component Fifty-four homologue (Ffh) in E. coli using a global approach. The steady-state proteomes and the proteome dynamics were evaluated using one- and two-dimensional gel analysis, followed by mass spectrometry-based protein identification and immunoblotting. Our analysis showed that depletion of Ffh led to the following: (i) impaired kinetics of the biogenesis of the cytoplasmic membrane proteome; (ii) lowered steady-state levels of the respiratory complexes NADH dehydrogenase, succinate dehydrogenase, and cytochrome bo(3) oxidase and lowered oxygen consumption rates; (iii) increased levels of the chaperones DnaK and GroEL at the cytoplasmic membrane; (iv) a σ(32) stress response and protein aggregation in the cytoplasm; and (v) impaired protein synthesis. Our study shows that in E. coli SRP-mediated protein targeting is directly linked to maintaining protein homeostasis and the general fitness of the cell.     

The fine structure of nuclei as revealed by electron microscopy

Summary The process of nucleolus formation has been studied by electron microscopy in spermatogonia of new-born, 15-day-old mice. One of two heteropycnotic sex chromosomes is concerned with nucleolus formation in the type A spermatogonia. The evidence for such formation has been presented with regard to behaviour and fine structure of both sex chromosome and nucleolus, Nucleolar material appears at one of two heteropycnotic sex chromosomes which are closely attached to the nuclear envelope. The two sex chromosomes approach each other, and subsequently one of them migrates into the central part of the nucleoplasm, being related to the nucleolar material which develops to show a nucleolar configuration. The sex chromosomes are homogeneously electron dense during the nucleolus formation, but assume a vesicular form at the middle stage of its development. The nucleolus is mostly of fibrillar and amorphous components at early stages of its development, but the granular components increases in amount as development proceeds. The final, mature nucleolus is composed of irregularly twisted nucleolonemata consisting of granular components, separated from fibrillar and amorphous areas. The compactly dense sex chromosome remains closely connected with the mature nucleolus.     

Structure of trichomonads as revealed by scanning electron microscopy.

A scanning electron microscope (SEM) study of Hypotrichomonas acosta (Moskowitz), Trichomonas vaginalis Donné, Pentatrichomonas hominis (Davaine), and Tritrichomonas foetus (Riedmüller) provided new information about the structure of the periflagellar canal; emergence of the flagella from the cell body; structure of the undulating membrane; and position, shape, and size of the pelta. Of special interest were the spatial relationships of the attached part of the recurrent flagellum and the accessory filament in Hypotrichomonas and in the members of Trichomonadinae, i.e. Trichomonas and Pentatrichomonas.