Removing Contamination-Induced Reconstruction Artifacts from Cryo-electron Tomograms

Imaging of fully hydrated, vitrified biological samples by electron tomography yields structural information about cellular protein complexes in situ. Here we present a computational procedure that removes artifacts of three-dimensional reconstruction caused by contamination present in samples during imaging by electron microscopy. Applying the procedure to phantom data and electron tomograms of cellular samples significantly improved the resolution and the interpretability of tomograms. Artifacts caused by surface contamination associated with thinning by focused ion beam, as well as those arising from gold fiducial markers and from common, lower contrast contamination, could be removed. Our procedure is widely applicable and is especially suited for applications that strive to reach a higher resolution and involve the use of recently developed, state-of-the-art instrumentation.     

High-resolution electron microscopy and electron tomography: resolution versus precision

The performance of high-resolution electron microscopy and electron tomography is usually discussed in terms of two-point resolution, expressing the possibility of perceiving separately two image points of an object. However, the concept resolution obtains another meaning if one uses prior knowledge about the object and the imaging procedure in the form of a parametric model describing the expectations of the observations. The unknown parameters, such as the positions of the components in an object, can be measured quantitatively by fitting this model to the observations. Due to the statistical nature of the experiment, the resulting solutions for the positions of the components and therefore for the distance between the components will never be exact. An alternative to resolution is then the precision with which the distance can be measured. In the present paper, it is shown that the precision depends on the size of the components, the distance between the components, the resolution of the instrument, and the number of electron counts. For electron tomography, it also depends on the orientation of the object with respect to the rotation axis.     

Structure of porcine heart cytoplasmic malate dehydrogenase: combining X-ray diffraction and chemical sequence data in structural studies

The amino acid sequence of cytoplasmic malate dehydrogenase (sMDH) has been determined by a combination of X-ray crystallographic and chemical sequencing methods. The initial molecular model incorporated an "X-ray amino acid sequence" that was derived primarily from an evaluation of a multiple isomorphous replacement phased electron density map calculated at 2.5-A resolution. Following restrained least-squares crystallographic refinement, difference electron density maps were calculated from model phases, and attempts were made to upgrade the X-ray amino acid sequence. The method used to find the positions of peptides in the X-ray structure was similar to those used for studying protein homology and was shown to be successful for large fragments. For sMDH, X-ray methods by themselves were insufficient to derive a complete amino acid sequence, even with partial chemical sequence data. However, for this relatively large molecule at medium resolution, the electron density maps were of considerable help in determining the linear position of peptide fragments. The N-acetylated polypeptide chain of sMDH has 331 amino acids and has been crystallographically refined to an R factor of 19% for 2.5-A resolution diffraction data.     

Amino acid sequence of Paracoccus denitrificans cytochrome c550.

The amino acid sequence of Paracoccus (formerly Micrococcus) denitrificans cytochrome c550 has been established by a combination of standard chemical techniques and interpretation of a 2.5 A resolution x-ray electron density map. Peptides derived from a trypsin digest were chemically sequenced, and then ordered by fitting them to the density map. The amino acid compositions of chymotryptic peptides confirmed the x-ray map ordering the tryptic peptides. The amino acid sequence of this respiratory, prokaryotic cytochrome with 134 residues is discussed in relation to those of eukaryotic respiratory cytochrome c (103 to 113 amino acids), and prokaryotic, photosynthetic c2 (103 to 124 amino acids). At the primary structure level, c and c550 differ no more from cytochromes c2 than the various cytochromes c2 do from one another. It is suggested that the respiratory electron transport chain in prokaryotes and eukaryotes is a relatively late evolutionary offshoot of the photosynthetic electron transport chain in purple non-sulfur bacteria.     

Ultrathin cryosections: an important tool for immunofluorescence and correlative microscopy.

Here we show that ultrathin cryosections of placental tissue can be used as a substrate in immunofluorescence experiments. A high degree of spatial resolution can be achieved in these preparations because there is essentially no out-of-focus fluorescence. Therefore, immunofluorescence microscopy using ultrathin cryosections provides a very useful method for determining the precise subcellular localization of antigens in tissues. In addition, ultrathin cryosections of placenta also serve as a substrate for correlative immunofluorescence and immunoelectron microscopy using FluoroNanogold as the detection system. In correlative microscopy, the exact same structures in the same ultrathin section were observed by both fluorescence and electron microscopy. Using a particle counting procedure and electron microscopy, we compared the labeling obtained with colloidal gold and FluoroNanogold and found a higher number of particles with silver-enhanced FluoroNanogold than with colloidal gold.     

Towards native-state imaging in biological context in the electron microscope

Modern cell biology is reliant on light and fluorescence microscopy for analysis of cells, tissues and protein localisation. However, these powerful techniques are ultimately limited in resolution by the wavelength of light. Electron microscopes offer much greater resolution due to the shorter effective wavelength of electrons, allowing direct imaging of sub-cellular architecture. The harsh environment of the electron microscope chamber and the properties of the electron beam have led to complex chemical and mechanical preparation techniques, which distance biological samples from their native state and complicate data interpretation. Here we describe recent advances in sample preparation and instrumentation, which push the boundaries of high-resolution imaging. Cryopreparation, cryoelectron microscopy and environmental scanning electron microscopy strive to image samples in near native state. Advances in correlative microscopy and markers enable high-resolution localisation of proteins. Innovation in microscope design has pushed the boundaries of resolution to atomic scale, whilst automatic acquisition of high-resolution electron microscopy data through large volumes is finally able to place ultrastructure in biological context.     

Chemical ionization mass spectrometry of trimethylsilylated carbohydrates and organic acids retained in uremic serum

After appropriate sample pretreatment and derivatization, uremic serum was investigated by combined high resolution gas chromatography and mass spectrometry, using both electron impact and chemical ionization methods. Electron impact and chemical ionization spectra of a number of identified (trimethylsilylated) carbohydrates and organic acids are compared. The utilization of chemical ionization mass spectrometry, with isobutane as the reagent gas, is discussed in detail. The influence of the reagent gas pressure on the total ion current and on the spectral appearance was studied. The identification of compounds, based on electron impact mass spectral data, was confirmed and often aided appreciably by using this technique. The chemical ionization spectra of trimethylsilyated alditols and aldonic acids, as well as of other organic acids showed protonated molecular ions, whereas aldoses did not. Differences with electron impact spectra are found mainly in the high mass region. The loss of one or more trimethylsilanol groups becomes the predominating fragmentation route at higher reagent gas pressures.     

An innovative coating technique for light and electron microscopic autoradiography.

We describe a modified nuclear emulsion coating technique for both electron and light microscopic autoradiography. We propose that by reversing the application of formvar film so that it adheres to and covers thin sections placed on grids, we have developed a technically accessible methodology that produces optimal conditions for the tracing of specific nuclear activity. A smooth, continuous base is formed over the sections on which a monolayer of evenly packed silver halide crystals can be applied by dip-coating. The same principle is applied to pre-stained 1-micron plastic sections of glass slides. We suggest that the application of formvar film over thin sections does not impede or interfere with the exposure of the emulsion by the labeled tissue. On the contrary, it virtually eliminates contamination and background radiation, enhancing the specificity and quality of resolution at even low magnifications. This technical modification, which facilitates the application of the emulsion, could render electron microscopic autoradiography a routine laboratory procedure, allowing for easily reproducible results and quantitative evaluation. At the light microscopic level, this technique prevents chemical fogging caused by certain stains, and thus allows routine pre-staining before coating with emulsion.     

Methods for reconstructing density maps of "single" particles from cryoelectron micrographs to subnanometer resolution

Recently the resolution attainable in density maps calculated from cryo-electron micrographs of free-standing virus capsids has advanced to resolutions below 1 nm. This represents a significant milestone in that resolutions of this order potentially allow direct visualization of individual elements of protein secondary structure (i.e., alpha-helices), in addition to the shapes and connectivity of subdomains. We describe here a computational strategy for structural analyses at this level of detail: its principal innovation is a procedure for correcting the contrast transfer function of the electron microscope. Also important is the practice of combining data from pairs of differently defocused micrographs to improve the signal-to-noise ratio of the images, thereby allowing more precise determinations of the particles' orientations and origins and contributing to higher resolution reconstructions. These procedures proved instrumental in our analysis of the capsid of hepatitis B virus at 9-A resolution (Conway et al., 1997, Nature 386, 91-94). Finally, we discuss the prospects for achieving comparable resolutions for isolated macromolecular complexes with lower symmetry or no symmetry and for further extension of the resolution.     

N-acylkansosamine. A novel N-acylamino sugar from the trehalose-containing lipooligosaccharide antigens of Mycobacterium kansasii

A novel N-acylamino sugar was isolated from the antigenic trehalose-containing lipooligosaccharides IV-VII of Mycobacterium kansasii. The native reducing sugar, its O-acetyl derivative, the methylglycoside, the O-acetylated alditol, and the de-N-acylated N-, O-acetylated alditol were all examined by high resolution 1H NMR, 13C NMR, direct probe and gas-liquid chromatography-mass spectrometry in both the chemical ionization and electron impact modes, and by high resolution mass spectrometry. The dideoxy sugar had a formula weight of 277, an empirical formula of C12H23NO6, C- and O-methyl substituents, and a N-methoxypropionyl branch. Upon alkaline hydrolysis, methoxypropionic acid was released and shown to correspond to the synthetic compound by gas chromatography and chemical ionization and electron impact mass spectrometry. The structure 4,6-dideoxy-2-O-methyl-3-C-methyl-4-(2'-methoxypropionamido)-alpha and beta-L-manno-hexopyranose, with the trivial name N-acylkansosamine, is proposed. The sugar is present in the more polar, highly antigenic lipooligosaccharides and is regarded as exclusive to M. kansasii and as its primary cell wall immunodeterminant.     

A cryosectioning procedure for the ultrastructural analysis and the immunogold labelling of yeast Saccharomyces cerevisiae

Yeast Saccharomyces cerevisiae has been a crucial model system for the study of a multitude of cellular processes because of its amenability to genetics, molecular biology and biochemical procedures. By contrast, the morphological analysis of this organism by immunoelectron microscopy (IEM) has remained in a primordial phase preventing researchers to routinely incorporate this technique into their investigations. Here, in addition to simple but detailed protocols to perform conventional electron microscopy (EM) on plastic embedded sections, we present a new IEM procedure adapted from the Tokuyasu method to prepare cryosections from mildly fixed cells. This novel approach allows an excellent cell preservation and the negatively stained membranes create superb contrast that leads to a unique resolution of the yeast morphology. This, plus the optimal preservation of the epitopes, permits combined localization studies with a fine resolution of protein complexes, vesicular carriers and organelles at an ultrastructural level. Importantly, we also show that this cryo-immunogold protocol can be combined with high-pressure freezing and therefore cryofixation can be employed if difficulties are encountered to immobilize a particular structure with chemical fixation. This new IEM technique will be a valuable tool for the large community of scientists using yeast as a model system, in particular for those studying membrane transport and dynamics.     

Structure and composition of ferritin cores isolated from human spleen, limpet (Patella vulgata) hemolymph and bacterial (Pseudomonas aeruginosa) cells

Ferritin cores isolated from human spleen, limpet (Patella vulgata) hemolymph and bacterial (Pseudomonas aeruginosa) cells have been investigated by high resolution transmission electron microscopy, electron diffraction and chemical analysis. Hemosiderin particles isolated from thalassemic spleens also have been studied. The results show that there is a marked difference in structure and composition of the biomineral phases. Human ferritin and hemosiderin particles are single domain crystals of hydrated iron (III) oxide (ferrihydrite). Lattice fringes were low in contrast and often discontinuous within the central regions of the core. Heat treatment of human ferritins results in a 5 A shrinkage in particle size and an increase in the single crystalline nature of the core. In contrast, lattice images and electron diffraction of limpet and bacterial cores show no evidence of long-range crystallographic order. Chemical analysis indicates a high inorganic phosphate (Pi) (Fe/Pi = 1.71) content in bacterial ferritin compared with human ferritin (thalassemic) (Fe/Pi = 21.0). The high Pi content of bacterial ferritin suggests a hydrated amorphous iron (III) phosphate mineral core. Structural disorder within the limpet and bacterial cores may be associated with increased Pi content and increased oxidation in Fe(II), resulting in rapid mineral deposition. Growth of the iron (III) oxide cores in human ferritin is discussed on the basis of high resolution electron microscopy results.     

角质层的离析及显微观察方法

植物角质层的离析方法很多,获取化石植物的角质层可以同时用几种化学处理方法。舒氏液浸解是最常用的方法,也是几种方法共用时最关键的步骤。浸解液浓度过大或处理时间过长有可能破坏角质层的结构。对于已经获取到的角质层,利用相差光学显微技术可以增加反差。利用微分干涉光学显微技术不仅反差增加,而且有立体感,背景颜色也可以调节。荧光显微分析技术在不破坏标本的前提下,可以获取到表皮的特征。扫描电子显微镜具有观察不透明物体,放大范围广以及高的分辨力等优越性,可作为光学显微镜的必要补充。     

Scanning electron microscopy preparation methods: their influence on the morphology and fibril formation in Pseudomonas fragi (ATCC 4973)

The use of cryo-scanning electron microscopy (cryo-SEM) in the study of the morphology of Pseudomonas fragi (ATCC 4973) revealed gross differences when compared to material prepared using conventional chemical methods. Changes associated with each step of the chemical preparatory procedure were monitored by cryo-SEM. It appeared that fibril formation was associated with the ethanol dehydration stage of the chemical preparation method and was not an attachment feature of these cells.     

Protein crystallography at sub-zero temperatures: cryo-protective mother liquors for protein crystals.

A procedure has been developed for maintaining the integrity of protein crystals at sub-zero temperatures. It involves the replacement of the normal crystal mother liquor with salt-free aqueous/organic liquids of low freezing point. Detailed knowledge of the physical chemical properties of these mixed solvents permits conditions to be chosen that maximize the similarity between their microenvironments and that provided by the normal mother liquor. Since the mixed solvents remain fluid at very low temperatures, it is possible to diffuse substrates into the crystals in the cold. Results have been obtained for a dozen different crystalline proteins, demonstrating that the crystals diffract to high resolution after repeated cooling to below − 70 °C. At low temperatures radiation damage to all the crystals is negligible, and for two proteins there is an improvement in the intensities of high resolution reflections. The technique requires no special equipment, does not change unit cell dimensions, and does not demand cross-linking the crystals.     

BAmSA: Visualising transmembrane regions in protein complexes using biotinylated amphipols and electron microscopy

Membrane protein (MP) complexes play key roles in all living cells. Their structural characterisation is hampered by difficulties in purifying and crystallising them. Recent progress in electron microscopy (EM) have revolutionised the field, not only by providing higher-resolution structures for previously characterised MPs but also by yielding first glimpses into the structure of larger and more challenging complexes, such as bacterial secretion systems. However, the resolution of pioneering EM structures may be difficult and their interpretation requires clues regarding the overall organisation of the complexes. In this context, we present BAmSA, a new method for localising transmembrane (TM) regions in MP complexes, using a general procedure that allows tagging them without resorting to neither genetic nor chemical modification. Labels bound to TM regions can be visualised directly on raw negative-stain EM images, on class averages, or on three-dimensional reconstructions, providing a novel strategy to explore the organisation of MP complexes.     

The isolation and characterization of alpha-keratin microfibrils.

A method of isolating alpha-keratin microfibrils which avoids the degradation previously associated with the use of chemical, physical or enzymic procedures has been developed. Electron microscope studies of the isolation procedure establish that the microfibrils originate from the presumptive cortical cells. A purification procedure, monitored by electron microscopy, has enabled microfibrils to be isolated on a scale sufficient for chemical characterization. The amino acid composition of the microfibrils is very similar to that of low-sulphur protein fractions extracted from a range of hard mammalian keratins and thus provides direct experimental evidence for the assumption that the low-sulphur proteins comprise the microfibril in alpha-keratin.     

Sequence of rubredoxin by x-ray diffraction

A tentative amino acid sequence has been determined for rubredoxin from Clostridium pasteurianum by examining the shapes of the side chains in an electron density map at 2 Å resolution. Superpositions of the appropiate portions of this map and “ball and stick” representations of the amino acids assigned are presented as evidence in support of our identifications. Discrepancies exist between the sequence shown here and that determined by chemical methods. The sequence deduced from the 2Å resolution map, however, represents our best estimate in the absence of chemical data and before refinement of the structure. We emphasize the results at 2 Å resolution because, until recently, the 2 Å resolution map was usually the final result of an X-ray structure determination. It is instructive to show the level of reliability that can be expected at that stage and to illustrate the kinds of mistakes that are likely to occur when making identifications from electrondensity maps.     

A protocol for isolating Xenopus oocyte nuclear envelope for visualization and characterization by scanning electron microscopy (SEM) or transmission electron microscopy (TEM)

This protocol details methods for the isolation of oocyte nuclear envelopes (NEs) from the African clawed toad Xenopus laevis, immunogold labeling of component proteins and subsequent visualization by field-emission scanning electron microscopy (FESEM) and transmission electron microscopy (TEM). This procedure involves the initial removal of the ovaries from mature female X. laevis, the dissection of individual oocytes, then the manual isolation of the giant nucleus and subsequent preparation for high-resolution visualization. Unlike light microscopy, and its derivative technologies, electron microscopy enables 3-5 nm resolution of nuclear structures, thereby giving unrivalled opportunities for investigation and immunological characterization in situ of nuclear structures and their structural associations. There are a number of stages where samples can be stored, although we recommend that this protocol take no longer than 2 d. Samples processed for FESEM can be stored for weeks under vacuum, allowing considerable time for image acquisition.