What we have learned and will learn from cell ultrastructure in embedment-free section electron microscopy

Electron-translucency and partial defects of synaptic basal lamina in the electrocyte synapse of an electric ray (Narke japonica) in 3D embedment-free section electron microscopy

The synaptic basal lamina of the electrocytes was disclosed to be electron-translucent to some extent when viewed in an en-face direction in embedment-free section transmission electron microscopy (EFS-TEM), and synaptic vesicles located close to the presynaptic membrane were seen through the synaptic basal lamina together with the presynaptic and postsynaptic membranes. This feature of translucency has the potential to analyze possible spatial interrelations in situ between bioactive molecules in the synaptic basal lamina and the synaptic vesicles in further studies. The synaptic basal lamina, appearing as an electron-dense line sandwiched by two parallel lines representing the presynaptic and postsynaptic membranes in ultrathin sections cut right to the synaptic junctional plane in conventional TEM, was not fully continuous but randomly intermittent along its trajectory. Compatible with the intermittent line appearance, the en-face 3D view in embedment-free section TEM revealed for the first time partial irregular defects of the synaptic basal lamina. Considering the known functional significance of several molecules contained in the synaptic basal lamina in the maintenance and exertion of the synapse, its partial defects may not represent its rigid structural features, but its immature structure under remodeling or its dynamic changes in consistency such as the sol/gel transition, whose validity needs further examination. RESEARCH HIGHLIGHTS: In embedment-free section TEM, a 3D en-face view of synaptic basal lamina in situ is reliably possible. The basal lamina en-face is electron-translucent, which makes it possible to analyze spatial interrelation between pre- and post-synaptic components. Partial irregular defects in the basal lamina are revealed in Torpedo electrocytes, suggesting its remodeling or dynamic changes in consistency.

Occurrence of fenestral diaphragms and knots in renal glomerular endothelia of diabetic mutant MafA-/-MafK+ mice as revealed in embedment-free transmission electron microscopy

Using the advantages (high contrast and transparency and efficient 3D viewing) of embedment-free section transmission electron microscopy (TEM), the occurrence of numerous fenestral diaphragms was clearly shown in 3D en-face viewing of the renal glomerular capillary endothelium of severe overt diabetes mellitus mice, which were generally MafA-deficient and simultaneously MafK-overexpressed specifically in pancreatic β-cells. This presents another example of nephritis-induced diaphragmed fenestrae in the renal glomerular endothelium. In addition, knot-/umbilicus-like structures discrete from and larger than the central knots of regular diaphragms of fenestrated endothelium were clearly demonstrated to occur randomly in the renal glomerular endothelial fenestrae of mutant mice and wild ones. The knot-structures were revealed to be protrusions of underlining basement lamina in conventional TEM by section-tilting observation.

Advantages of embedment-free section transmission electron microscopy

The usefulness of embedment-free section transmission electron microscopy (TEM) is stressed for present and future morphological analyses, and several examples are demonstrated which are revealed in sections for the first time by this method: en-face views of slit diaphragm of renal glomerulus and fenestrated diaphragm of capillary endothelium, transparency of neural myelin, attenuated endothelium and some basement laminae, labyrinth architecture of vacuoles within lipid droplets, and enhanced 3D effect of ultrastructures, the latter of which is the case in electron tomography. In addition, the biological significance of structured appearance (microtrabecular lattices) of the cytoplasmic matrix, which is disclosed by this method, are briefly reviewed in relation to the sol-gel transition of cytoplasmic heterogenous proteins. Since the ultrastructures of various cells and tissues in this method are confirmed to be well correspondent to those in conventional epoxy section TEM except for isotropic dimensional changes, and because there is no necessity for any special expensive equipments other than those for the conventional TEM, the embedment-free section TEM method with these advantages, deserves much more wide application to the morphological research including electron tomography.

Disclosure in 3D of slit-membrane as well as -strands, and en-face basal lamina in situ of renal glomerulus of normal rats in embedment-free section transmission electron microscopy

With higher contrast and transparency due to the absence of epon and stereo-viewing effect due to thicker sections than conventional electron microscopy as methodological advantages, the renal glomerular slits were re-examined in embedment-free section electron microscopy. In addition to clear demonstration of strands bridging the slits in forms of ladders with highly irregular intervals and various extension-directions and length, this study disclosed clearly for the first time in the "section" TEM thin sheets which partially spanned the slit together with the strand-ladders. No strands were found to align in forms of typical zippers in normal kidney. Furthermore, en-face ultrastructure of the basal lamina in situ was clearly demonstrated in superimposed sites of the endothelial fenestrae with the slits.

A cytoplasmic gel network capable of mediating the conversion of chemical energy to mechanical work in diverse cell processes: a speculation

Enigmatic morphological features of the formation and fate of "dark" (hyper-basophilic, hyper-argyrophilic and hyper-electrondense) neurons suggest that the mechanical work causing their dramatic shrinkage (whole-cell ultrastructural compaction) is done by a previously "unknown" ultrastructural component residing in the spaces between their "known" (i.e. visible in the conventional transmission electron microscopy) ultrastructural constituents. Embedment-free section electron microscopy revealed in these spaces the existence of a continuous network of gel microdomains, which is embedded in a continuous network of fluid-filled lacunae. We gathered experimental facts suggesting that this gel network is capable of a volume-reducing phase-transition (an established physico-chemical phenomenon), which could be the motor of the whole-cell ultrastructural compaction. The present paper revisits our relevant observations and speculates how such a continuous whole-cell gel network can do both whole-cell and compartmentalized mechanical work.

Ultrastructural consideration on the nature, sol and gel, of the aqueous cytoplasm in embedment-free section electron microscopy

TEM of any in situ cells in embedment-free sections--regardless of specimen-fixation methods--clearly shows strand-lattices occupying the cytoplasmic matrix. The cytoplasmic matrix is assumed to be a site of soluble proteins; however, it appears indistinct as conventional TEM cannot target it. Strand-lattices similar to the cytoplasmic ones are duplicated in bovine serum albumin as well as solated gelatin fixed at warm temperatures and at appropriate concentrations, while lattices from gelatin gelated by cooling before fixation are much more compact than those from solated gelatin at a given concentration. Based on the finding of the in vitro proteins, a new interpretation of cell ultrastructures in embedment-free section TEM is proposed: first, differences in the compactness of cytoplasmic lattices represent those in the protein concentration in the cytoplasmic matrix; second, when loose and compact lattices are contiguous within a cell, the cytoplasmic matrix domain occupied by the compact lattice is in a gel state while the remaining domain of the same cell is in a sol state. The explanation for the states of the gel and sol based on the lattice-compactness is applicable to changes in the lattice-compactness of the cytoplasmic matrix of neurohypophyseal axons under intense secretion.

First disclosure of lipid droplet substructure and myelin translucency in embedment-free section electron microscopy

In conventional transmission electron microscopy (EM), thinly sectioned specimens embedded in epoxy resin are observed. However, because of a substantial level of electron density of epoxy resin, the possibility cannot be ruled out that bio-structures having electron density similar to that of epoxy resin are not clearly recognized and thus are neglected or misinterpreted in conventional EM. This was the reason to require for embedment-free EM. Embedment-free sections have already been made available reliably by transient embedding in polyethylene glycol (PEG) and subsequent de-embedding through immersion in water, and further by critical-point drying, and this embedment-free EM is thus termed PEG-EM. However, this PEG-EM has not been successful to attract reasonable attention from electron microscopists and instead been misunderstood as a non-reliable method. In this paper, the remarkably enhanced contrast and electron translucency of any observation targets in PEG-EM are clearly demonstrated by comparing with images in conventional EM of adipocytes and neural myelin as examples. These features of PEG-EM, together with faithful correspondence in EM images of any individual substructures between the two methods, confirm the reliability of PEG-EM. Furthermore, the much higher thickness of embedment-free sections together with these features makes the PEG-EM more advantageous than the conventional EM for three-dimensional appreciation of structural elements, which is made by stereo-viewing of sections or by EM tomography. Therefore, the PEG-EM is regarded as an important adjunct to the conventional EM for histological studies and wide application of this method may unravel a new level of histology.