Cell Biology


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0 Q&A 667 Views Oct 20, 2023

For the analysis of cellular architecture during mitosis, nanometer resolution is needed to visualize the organization of microtubules in spindles. Here, we present a detailed protocol that can be used to produce 3D reconstructions of whole mitotic spindles in cells grown in culture. For this, we attach mammalian cells enriched in mitotic stages to sapphire discs. Our protocol further involves cryo-immobilization by high-pressure freezing, freeze-substitution, and resin embedding. We then use fluorescence light microscopy to stage select mitotic cells in the resin-embedded samples. This is followed by large-scale electron tomography to reconstruct the selected and staged mitotic spindles in 3D. The generated and stitched electron tomograms are then used to semi-automatically segment the microtubules for subsequent quantitative analysis of spindle organization. Thus, by providing a detailed correlative light and electron microscopy (CLEM) approach, we give cell biologists a toolset to streamline the 3D visualization and analysis of spindle microtubules (http://kiewisz.shinyapps.io/asga). In addition, we refer to a recently launched platform that allows for an interactive display of the 3D-reconstructed mitotic spindles (https://cfci.shinyapps.io/ASGA_3DViewer/).


Key features

• High-throughput screening of mitotic cells by correlative light and electron microscopy (CLEM).

• Serial-section electron tomography of selected cells.

• Visualization of mitotic spindles in 3D and quantitative analysis of microtubule organization.


Graphical overview


0 Q&A 925 Views Jan 20, 2023

Combining two different plants together through grafting is one of the oldest horticultural techniques. In order to survive, both partners must communicate via the formation of de novo connections between the scion and the rootstock. Despite the importance of grafting, the ultrastructural processes occurring at the graft interface remain elusive due to the difficulty of locating the exact interface at the ultrastructural level. To date, only studies with interfamily grafts showing enough ultrastructural differences were able to reliably localize the grafting interface at the ultrastructural level under electron microscopy. Thanks to the implementation of correlative light electron microscopy (CLEM) approaches where the grafted partners were tagged with fluorescent proteins of different colors, the graft interface was successfully and reliably targeted. Here, we describe a protocol for CLEM for the model plant Arabidopsis thaliana, which unambiguously targets the graft interface at the ultrastructural level. Moreover, this protocol is compatible with immunolocalization and electron tomography acquisition to achieve a three-dimensional view of the ultrastructural events of interest in plant tissues.


Graphical abstract



0 Q&A 834 Views Dec 5, 2022

Cryo-electron tomography (cryo-ET) is a formidable technique to observe the inner workings of vitrified cells at a nanometric resolution in near-native conditions and in three-dimensions. One consequent drawback of this technique is the sample thickness, for two reasons: i) achieving proper vitrification of the sample gets increasingly difficult with sample thickness, and ii) cryo-ET relies on transmission electron microscopy (TEM), requiring thin samples for proper electron transmittance (<500 nm). For samples exceeding this thickness limit, thinning methods can be used to render the sample amenable for cryo-ET. Cryo-focused ion beam (cryo-FIB) milling is one of them and despite having hugely benefitted the fields of animal cell biology, virology, microbiology, and even crystallography, plant cells are still virtually unexplored by cryo-ET, in particular because they are generally orders of magnitude bigger than bacteria, viruses, or animal cells (at least 10 μm thick) and difficult to process by cryo-FIB milling. Here, we detail a preparation method where abaxial epidermal onion cell wall peels are separated from the epidermal cells and subsequently plunge frozen, cryo-FIB milled, and screened by cryo-ET in order to acquire high resolution tomographic data for analyzing the organization of the cell wall.

0 Q&A 5054 Views Sep 20, 2019
A protocol was developed to visualize and analyze the structure of membrane vesicles (MVs) from Gram-negative bacteria. It is now accepted that these micrometric spherical vesicles are commonly produced by cells from all three domains of life, so the protocol could be useful in the study of vesicles produced by eukaryotes and archaea as well as bacteria. The multiplicity of functions performed by MVs, related to cell communication, interaction with the immune system, pathogenesis, and nutrient acquisition, among others, has made MVs a hot topic of research.

Due to their small size (25-300 nm), the observation of MVs requires electron microscopy and is usually performed by transmission electron microscopy (TEM) of negatively stained MVs. Other protocols applied for their visualization include scanning electron microscopy, TEM after fixation and embedding of vesicles, or even atomic force microscopy. In some of these techniques, vesicle structure is altered by drying, while others are time-consuming and most of them can generate artifacts. Cryo-TEM after plunge freezing allows the visualization of samples embedded in a thin film of vitreous ice, which preserves their native cellular structures and provides the highest available resolution for the imaging. This is achieved by very high cooling rates that turn the intrinsic water of cells into vitreous ice, avoiding crystal formation and phase segregation between water and solutes. In addition to other types of characterization, an accurate knowledge of MV structure, which can be obtained by this protocol, is essential for MV application in different fields.
0 Q&A 6256 Views Jul 20, 2019
Multibeam scanning electron microscopy (multiSEM) provides a technical platform for seamless nano-to-mesoscale mapping of cells in human tissues and organs, which is a major new initiative of the U.S. National Institutes of Health. Such cross-length-scale imaging is expected to provide unprecedented understanding of relationships between cellular health and tissue-organ as well as organismal-scale health outcomes. For example, understanding relationships between loss in cell viability and cell network connectivity enables identification of emergent behaviors and prediction of degenerative disease onset, in organs as diverse as bone and brain, at early timepoints, providing a basis for future treatments and prevention. Developed for rapid throughput imaging of minute defects on semiconductor wafers, multiSEM has recently been adapted for imaging of human organs, their constituent tissues, and their respective cellular inhabitants. Through integration of geospatial approaches, statistical and network modelling, advances in computing and the management of immense datasets, as well as recent developments in machine learning that enable the automation of big data analyses, multiSEM and other cross- cutting imaging technologies have the potential to exert a profound impact on elucidation of disease mechanisms, translating to improvements in human health. Here we provide a protocol for acquisition and preparation of sample specimen sizes of diagnostic relevance for human anatomy and physiology. We discuss challenges and opportunities to integrate this approach with multibeam scanning electron microscopy workflows as well as multiple imaging modalities for mapping of organ and tissue structure and function.
0 Q&A 4327 Views Apr 20, 2019
In this paper, we describe a protocol allowing measurement of the mechanical tension of individual axons grown ex vivo from neural tissue explants. This protocol was developed with primary cultures of olfactory epithelium explants from embryonic (E13.5) mice. It includes a detailed description of explant dissection and culture, as well as the main steps of the procedure for axon tension measurement using the previously established Biomembrane Force Probe.
0 Q&A 5625 Views Apr 5, 2019
Plant cell walls consist of different polysaccharides and structural proteins, which form a rigid layer located outside of the plasma membrane. The wall is also a very dynamic cell composite, which is characterized by complex polysaccharide interactions and various modifications during cell development. The visualization of cell wall components in situ is very challenging due to the small size of cell wall composites (nanometer scale), large diversity of the wall polysaccharides and their complex interactions. This protocol describes immunogold labeling of different cell wall epitopes for high-resolution transmission electron microscopy (TEM). It provides a detailed procedure for collection and preparation of plant material, ultra-thin sectioning, specimen labeling and contrasting. An immunolabeling procedure workflow was optimized to obtain high efficiency of carbohydrates labeling for high-resolution TEM. This method was applied to study plant cell wall characteristics in various plant tissues but could also be applied for other cell components in plant and animal tissues.
0 Q&A 5042 Views Nov 20, 2018
The recent development of 3D electron microscopic techniques for cells and tissues has necessitated the development of new methods for the detection of proteins and protein-complexes in situ. The development of new genetic tags, such as the ascorbate peroxidase, APEX, for electron microscopic detection of tagged proteins has expanded the available toolbox and ushered in a new era in biological electron microscopy. Here, we describe methods for combining conditionally-stable nanobodies to fluorescent protein tags with APEX-based detection. These methods are compatible with detection of low levels of expression of fluorescently-tagged proteins and with detection of protein complexes using split GFP-based complementation methods. We describe a simple protocol for applying these methods to the electron microscopic detection of proteins and protein complexes in cultured cells.
0 Q&A 5909 Views Oct 20, 2018
In plants, macroautophagy, here referred as autophagy, is a degradation pathway during which the double-membrane structure named autophagosome engulfs the cargo and then fuses with vacuole for material recycling.

To investigate the process of autophagy, transmission electron microscopy (TEM) was used to monitor the ultrastructure of autophagic structures and identify the cargo during this process due to its high resolution. Compared to other autophagy examination methods including biochemical assays and confocal microscopy, TEM is the only method that indicates the morphology of autophagic structures in nanoscale, which is considered to be one of the best ways to illustrate the morphology of autophagic intermediates and the substrate of autophagy. Here, we describe the autophagy examination assay using TEM in Nicotiana benthamiana leaf cells.
0 Q&A 5939 Views Apr 20, 2018
Positive-stranded (+) RNA viruses are intracellular pathogens in humans, animals and plants. To build viral replicase complexes (VRCs) viruses manipulate lipid flows and reorganize subcellular membranes. Redesigned membranes concentrate viral and host factors and create an environment that facilitates the formation of VRCs within replication organelles. Therefore, efficient virus replication depends on the assembly of specialized membranes where viral macromolecular complexes are turned on and hold a variety of functions. Detailed characterization of viral replication platforms in cells requires sophisticated imaging approaches. Here we present a protocol to visualize the three-dimensional organization of the tombusvirus replicase complex in yeast with MEtal-Tagging Transmission Electron Microscopy (METTEM). This protocol allowed us to image the intracellular distribution of the viral replicase molecules in three-dimensions with METTEM and electron tomography. Our study showed how viral replicase molecules build replication complexes within specialized cell membranes.



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