CYTOPLASMIC MICROTUBULES IN DIFFERENT ANIMAL CELLS

In avian, murine, and human cells fixed with glutaraldehyde, cytoplasmic microtubules 180 to 250 A in diameter and of undetermined length were found. These cytoplasmic microtubules are similar to those described by Ledbetter and Porter in plant cells after the same glutaraldehyde fixation. The cytoplasmic microtubules in animal cells are connected with the satellites of the centrioles and are similar to the mitotic spindle fibers. Their protein nature and their possible role in maintaining the shape of the cells are discussed. Their presence in all examined animal cells as well as in plant cells favors the hypothesis that they are a permanent component of the cytoplasm.     

Microtubule heterogeneity of Ornithogalum umbellatum ovary epidermal cells: non-stable cortical microtubules and stable lipotubuloid microtubules

Lipotubuloids, structures containing lipid bodies and microtubules, are described in ovary epidermal cells of Ornithogalum umbellatum. Microtubules of lipotubuloids can be fixed in electron microscope fixative containing only buffered OsO(4) or in glutaraldehyde with OsO(4) post-fixation, or in a mixture of OsO(4) and glutaraldehyde. None of these substances fixes cortical microtubules of ovary epidermis of this plant which is characterized by dynamic longitudinal growth. However, cortical microtubules can be fixed with cold methanol according immunocytological methods with the use of β-tubulin antibodies and fluorescein. The existence of cortical microtubules has also been evidenced by EM observations solely after the use of taxol, microtubule stabilizer, and fixation in a glutaraldehyde/OsO(4) mixture. These microtubules mostly lie transversely, sometimes obliquely, and rarely parallel to the cell axis. Staining, using Ruthenium Red and silver hexamine, has revealed that lipotubuloid microtubules surface is covered with polysaccharides. The presumption has been made that the presence of a polysaccharide layer enhances the stability of lipotubuloid microtubules.     

Control of autofluorescence of archival formaldehyde-fixed, paraffin-embedded tissue in confocal laser scanning microscopy (CLSM).

Confocal laser scanning microscopy (CLSM) offers the advantage of quasi-theoretical resolution due to absence of interference with out-of-focus light. Prerequisites include minimal tissue autofluorescence, either intrinsic or induced by fixation and tissue processing, and minimal background fluorescence due to nonspecific binding of the fluorescent label. To eliminate or reduce autofluorescence, three different reagents, ammonia-ethanol, sodium borohydride, and Sudan Black B were tested on paraffin sections of archival formaldehyde-fixed tissue. Paraffin sections of biopsy specimens of human bone marrow, myocardium, and of bovine cartilage were compared by CLSM at 488-nm, 568-nm and 647-nm wavelengths with bone marrow frozen sections fixed either with formaldehyde or with glutaraldehyde. Autofluorescence of untreated sections related to both the specific type of tissue and to the tissue processing technique, including fixation. The reagents' effects also depended on the type of tissue and technique of tissue processing, including fixation, and so did the efficiency of the reagents tested. Therefore, no general recipe for the control of autofluorescence could be delineated. Ammonia-ethanol proved most efficient in archival bone marrow sections. Sudan Black B performed best on myocardium, and the combination of all three reagents proved most efficient on paraffin sections of cartilage and on frozen sections fixed in formaldehyde or glutaraldehyde. Sodium borohydride was required for the reduction of unwanted fluorescence in glutaraldehyde-fixed tissue. In formaldehyde-fixed tissue, however, sodium borohydride induced brilliant autofluorescence in erythrocytes that otherwise remained inconspicuous. Ammonia-ethanol is believed to reduce autofluorescence by improving the extraction of fluorescent molecules and by inactivating pH-sensitive fluorochromes. The efficiency of borohydride is related to its capacity of reducing aldehyde and keto-groups, thus changing the fluorescence of tissue constituents and especially of glutaraldehyde-derived condensates. Sudan Black B is suggested to mask fluorescent tissue components.     

Immunofluorescence technique for 100-nm-thick semithin sections of Epon-embedded tissues

An immunofluorescence staining method for Epon-embedded materials is described. Rat kidney and liver were fixed by perfusion with 1% glutaraldehyde for 10 min. Tissue slices were embedded in Epon. Semithin sections with thicknesses ranging from 1,000 to 100 nm were cut and mounted on clean glass slides. Epoxy resin was removed by treatment with 10% sodium ethoxide. Sections were digested with 0.05% trypsin and then treated with sodium borohydride. Sections were immunostained for leucine aminopeptidase (plasma membrane), catalase (peroxisomes), 3-ketoacyl-CoA thiolase (mitochondria), cathepsin D (lysosomes), and LGP107 (lysosomal membrane) using Cy(2)- or Alexa 546-labeled secondary antibodies. In 1,000-nm-thick sections, non-specific fluorescence remained and such fluorescence decreased as the sections became thinner. Clear specific fluorescence was obtained in the sections with thicknesses ranging from 250 to 100 nm with Alexa 546-labeled antibody (red fluorescence) but was not specific enough with Cy(2)- or Alexa 430-labeled antibody (green fluorescence). Sodium borohydride greatly abolished autofluorescence of glutaraldehyde. The present method made it possible to obtain signals in cross-sections of biological materials with a thickness of 250-100 nm, which are difficult to obtain in optical section using a confocal laser microscope.     

Demonstration of Pulmonary Surfactant by Tracheal Injection of Tricomplex Salt Mixture: Electron Microscopy

Laboratory animals were perfused with glutaraldehyde through the right ventricle before filling the whole lung intratracheally with a solution of 0.05 N Pb(NO₃)₂ and K₃Fe(CN)₆ and incubating it at 37 C for 30 min. An electron-dense reaction product on the surface of epithelial cells and in certain well-localized regions of the alveolar septa results. Nonspecific, intracellular, precipitates do not occur. Lungs which are sliced before glutaraldehyde fixation and immersed in the tricomplex salt mixture show patchy localization of reaction product. Diffuse, electron-dense deposits measuring 100-2000 mμ in diameter are seen in the cytoplasm of epithelial, endothelial and interstitial cells although occasionally there is localization on the surface of the epithelial cells and in specific sites within cells. Injection of the whole lung with tricomplex salt mixture after fixation with glutaraldehyde by vascular perfusion is a better method for the ultrastructural demonstration of pulmonary surfactant than immersion fixation and staining.     

Immunoelectron Microscopy of Giardia lamblia Cytoskeleton Using Antibody to Acetylated α-Tubulin

Giardia lamblia trophozoites contain acetylated α-tubulin but lack detectable levels of tyrosinolated α-tubulin, as demonstrated in immunoblots with monoclonal antibodies specific for these tubulin forms. By immunofluorescence microscopy, acetylated α-tubulin is localized in axonemes, median bodies and in the adhesive disk. Post-embeddment immunogold labeling of thin sections of cells was used to evaluate acetylation at the level of individual microtubules by electron microscopy. Cells were fixed with glutaraldehyde and embedded in the acrylic resin LR Gold. Results indicate all microtubules in adhesive disk, axonemes, basal bodies, funis and the median bodies contain acetylated α-tubulin. Unlike immunofluorescence labeling, all microtubules of the adhesive disk and the funis could be gold labeled. No nonspecific labeling of the cytoplasm or of structures other than microtubules was observed. Acetylated microtubules in G. lamblia do not appear to be a subset of microtubules and acetylation appears uniform along the entire length of individual microtubules. Acetylation and the tyrosinolation state of microtubules in Giardia are discussed in the context of microtubule stability and crosslinked features of the cytoskeleton.     

Cellular localization of water soluble, allergenic proteins in rye-grass (Lolium perenne) pollen using monoclonal and specific IgE antibodies with immunogold probes

Summary A postembedding method has been developed for localizing water soluble allergens in rye-grass pollen. This uses dry fixation in glutaraldehyde vapour, followed by 2,2-dimethoxypropane, prior to a 100% ethanol series leading into embedment in LR Gold. This has allowed the attachment of specific monoclonal antibodies to the allergen, which are themselves probed with specific immunogold labels to the antibodies. Wall and cytoplasmic sites have been identified, representing an improvement of fixation and localization of allergens over previous studies employing polyclonal, broad spectrum antibodies.Rye-grass allergens are labelled in mature pollen grains in the exine (tectum, nexine and central chamber), and in the electron opaque areas of the cytoplasm, especially mitochondria. The allergens are absent from the intine, polysaccharide (P) particles, amyloplasts, Golgi bodies and endoplasmic reticulum. IgE antibodies derived from humans allergic to rye-grass pollen, bind to similar sites in the cytoplasm but only to the outer surface of the pollen grain wall. This method now provides a valuable tool for further developmental studies on the pollen grains, in order to establish the site/s of synthesis of the allergens.     

Visualisation of microtubules and actin filaments in fixed BY-2 suspension cells using an optimised whole mount immunolabelling protocol

Excellent visualisation of microtubules and actin filaments was obtained in fixed tobacco BY-2 suspension cells after optimising a protocol for whole mount immunolabelling. The procedure is based on modification of fixation, cell wall digestion, dimethyl sulfoxide (DMSO) treatment, post fixation, and blocking. The most critical aspects of successful preservation and visualization of cytoskeletal elements appeared to be: a two-step fixation with paraformaldehyde and glutaraldehyde before enzymatic cell wall digestion and a post fixation with aldehydes thereafter. The method allows the improved visualization of the organisation of the microtubular and actin filament arrays during the successive stages of cell division and at interphase. Although we present the application of our protocols for cytoskeleton labelling, the excellent results show the potential of using this method for the analysis of various proteins and molecules in plant cells.Electronic Supplementary Material Supplementary material is available for this article at     

The structure of cytoplasm in directly frozen cultured cells. I. Filamentous meshworks and the cytoplasmic ground substance

Cultured fibroblasts or epithelial cells derived from Xenopus laevis embryos were directly frozen, freeze-substituted by an improved method, and then either critical-point-dried and viewed as whole mounts, or embedded and thin sectioned. In thin regions of these cells, where ice crystal artifacts are absent, the cytoplasm consisted of a dense, highly interconnected meshwork of filaments, embedded in a finely granular ground substance. The meshwork in directly frozen, intact cells was compared with that in cells that were lysed (physically, with detergents, or with filipin), or fixed with glutaraldehyde before freezing. Although filaments tended to be less numerous in lysed cells, their overall organization was the same as that in intact cells. However, fixation with glutaraldehyde before freezing distorted the meshwork to variable degrees depending on the osmolarity of the fixation buffer, and also obscured the granular ground substance which is obvious in directly frozen cells. With optimal preparative methods, the cytoplasm of these directly frozen cells is shown to consist of a cytoskeleton composed of discrete interwoven filaments interconnected by numerous finer filaments and a readily extractable granular matrix which presumably represents aggregations of cytoplasmic proteins.     

Actin-endoplasmic reticulum complexes inDrosera

In epidermal cells ofDrosera tentacles that have been preserved for ultrastructural analysis through high pressure freeze fixation and freeze substitution we describe the frequent occurrence of microfilament (MF)-endoplasmic reticulum (ER) complexes. These are found throughout the cytoplasm where they are observed in close association with the plasmalemma (PL), the tonoplast, nuclei, mitochondria, chloroplasts, and microbodies. The MF component of the complexes is identified as actin based on immunogold labelling with actin antibodies. The actin-ER complexes are prominent in the cortical cytoplasm. In this region a network of predominantly tubular ER occupies an intermediary position in which it associates closely with both the PL and the actin MFs. We suggest that the ER, especially those elements adjacent to the PL in the cortical cytoplasm, stabilizes the actin MFs and provides the necessary anchor against which the forces for cytoplasmic streaming are generated.Abbreviations CF chemical fixation - ER endoplasmic reticulum - FS freeze substitution - HPF high pressure freezing - MF microfilaments - MT microtubules - PL plasmalemma     

Exposure of lumenal microtubule sites after mild fixation

High-resolution analysis of tubulin structure and docking the structure of tubulin dimer into a map of microtubules led to a prediction that sites for tubulin acetylation are in the interior of microtubules. This is somehow difficult to reconcile with their susceptibility to proteases and acetylation in assembled microtubules. To assess the availability of acetylated alpha-tubulin for antibodies, immunofluorescence on detergent-extracted cells, on cells fixed under various conditions and in microinjected cells was performed with monoclonal antibodies of known epitope locations. The presented data indicate that acetylated alpha:Lys40 is not exposed on unfixed microtubules but that this region of lumenal microtubule surface becomes easily exposed under mild fixation conditions.     

A hot aldehyde-peroxide fixation method for electron microscopy of the free-living nematode Caenorhabditis elegans

An improved method for the fixation of the third and fourth larval stages and adults of Caenorhabditis elegans has been developed. Worms are placed in a mixture of 1.5% paraformaldehyde and 1.0% glutaraldehyde at pH 7.0 and 70 C and the suspension promptly cooled in a water bath at 20 C for 1 hr. The fixed worms are then immersed in a mixture of 5% glutaraldehyde and hydrogen peroxide at 4 C for 1 hr, stained en bloc in uranyl acetate, and embedded in resin for electron microscopy. The procedure results in superior fixation, particularly of microfilaments and microtubules. The high temperature of the initial fixation straightens the worms and thus facilitates serial sectioning.     

Crosslinked fibrous collagen for use as a dermal implant: control of the cytotoxic effects of glutaraldehyde and dimethylsuberimidate

Collagen intended for use as a dermal implant may be crosslinked to increase its strength and persistence in vivo. Sheets of rat fibrous dermal collagen were crosslinked with either glutaraldehyde or dimethylsuberimidate and the cytotoxicity to human dermal fibroblasts resulting from these treatments was measured by following the inhibition of [3H]leucine incorporation into protein. Both agents were cytotoxic at the concentrations required to effect adequate crosslinking (0.005% and 25 mM, respectively). This cytotoxicity could be limited by extensive washing and by incubation with 5 mM L-lysine, with 66 mM (0.25% w/v) sodium borohydride, or with 71.3 mM (1% w/v) dimedone. However, cytotoxicity was most efficiently controlled by treatment with a combination of 66 mM sodium borohydride and 5 mM L-lysine or 66 mM sodium borohydride and 71.3 mM dimedone. [3H]Leucine incorporation by cells exposed to crosslinked collagen treated with these combinations approached 100% of the values recorded with cells exposed to uncrosslinked collagen.     

Monoclonal antibodies to kinesin heavy and light chains stain vesicle- like structures, but not microtubules, in cultured cells

Kinesin, a microtubule-activated ATPase and putative motor protein for the transport of membrane-bounded organelles along microtubules, was purified from bovine brain and used as an immunogen for the production of murine monoclonal antibodies. Hybridoma lines that secreted five distinct antikinesin IgGs were cloned. Three of the antibodies reacted on immunoblots with the 124-kD heavy chain of kinesin, while the other two antibodies recognized the 64-kD light chain. When used for immunofluorescence microscopy, the antibodies stained punctate, cytoplasmic structures in a variety of cultured mammalian cell types. Consistent with the identification of these structures as membrane-bounded organelles was the observation that cells which had been extracted with Triton X-100 before fixation contained little or no immunoreactive material. Staining of microtubules in the interphase cytoplasm or mitotic spindle was never observed, nor were associated structures, such as centrosomes and primary cilia, labeled by any of the antibodies. Nevertheless, in double-labeling experiments using antibodies to kinesin and tubulin, kinesin-containing particles were most abundant in regions where microtubules were most highly concentrated and the particles often appeared to be aligned on microtubules. These results constitute the first direct evidence for the association of kinesin with membrane-bounded organelles, and suggest a molecular mechanism for organelle motility based on transient interactions of organelle-bound kinesin with the microtubule surface.     

Identification of a novel nucleotide-sensitive microtubule-binding protein in HeLa cells

A protein of Mr 170,000 (170K protein) has been identified in HeLa cells, using an antiserum raised against HeLa nucleotide-sensitive microtubule-binding proteins. Affinity-purified antibodies specific for this 170K polypeptide were used for its characterization. In vitro sedimentation of the 170K protein with taxol microtubules polymerized from HeLa high-speed supernatant is enhanced in the presence of an ATP depleting system, but unaffected by the non-hydrolyzable ATP analogue AMP-PNP. In addition, it can be eluted from taxol microtubules by ATP or GTP, as well as NaCl. Thus it shows microtubule-binding characteristics distinct from those of the previously described classes of nucleotide-sensitive microtubule-binding proteins, the motor proteins kinesin and cytoplasmic dynein, homologues of which are also present in HeLa cells. The 170K protein sediments on sucrose gradients at approximately 6S, separate from kinesin (9.5S) and cytoplasmic dynein (20S), further indicating that it is not associated with these motor proteins. Immunofluorescence localization of the 170K protein shows a patchy distribution in interphase HeLa cells, often organized into linear arrays that correlate with microtubules. However, not all microtubules are labeled, and there is a significant accumulation of antigen at the peripheral ends of microtubules. In mitotic cells, 170K labeling is found in the spindle, but there is also dotty labeling in the cytoplasm. After depolymerization of microtubules by nocodazole, the staining pattern is also patchy but not organized in linear arrays, suggesting that the protein may be able to associate with other intracellular structures as well as microtubules. In vinblastine-treated cells, there is strong labeling of tubulin paracrystals, and random microtubules induced in vivo by taxol are also labeled by the antibodies. These immunofluorescence labeling patterns are stable to extraction of cells with Triton X-100 before fixation, further suggesting an association of the protein with cytoplasmic structures. In vivo, therefore, the 170K protein appears to be associated with a subset of microtubules at discrete sites. Its in vitro behavior suggests that it belongs to a novel class of nucleotide-sensitive microtubule-binding proteins.     

Effects of dimethylsulfoxide on the ultrastructure of fixed cells

It has been reported that the use of dimethylsulfoxide (DMSO) as a solvent for fixatives enhances preservation of cellular ultrastructure. By contrast, we have shown that DMSO alters the ultrastructural integrity of glutaraldehyde fixed cells. The cell membrane, nuclear envelope, endoplasmic reticulum, ribosomes, microtubules and intracytoplasmic organelles are most susceptible to the action of DMSO. We hypothesize that DMSO exerts intracellular alterations via its interaction with remnant interfacial water in fixed cells. DMSO-induced alterations of these and related cellular components may result in the formation of artefactual structures and networks. Thus, it appears that DMSO containing glutaraldehyde neither accelerates fixation nor enhances stabilization of cellular ultrastructure. For these reasons, addition of DMSO to fixatives is not recommended.     

Effects of dimethylsulfoxide on the ultrastructure of fixed cells

It has been reported that the use of dimethylsulfoxide (DMSO) as a solvent for fixatives enhances preservation of cellular ultrastructure. By contrast, we have shown that DMSO alters the ultrastructural integrity of glutaraldehyde fixed cells. The cell membrane, nuclear envelope, endoplasmic reticulum, ribosomes, microtubules and intracytoplasmic organelles are most susceptible to the action of DMSO. We hypothesize that DMSO exerts intracellular alterations via its interaction with remnant interfacial water in fixed cells. DMSO-induced alterations of these and related cellular components may result in the formation of artefactual structures and networks. Thus, it appears that DMSO containing glutaraldehyde neither accelerates fixation nor enhances stabilization of cellular ultrastructure. For these reasons, addition of DMSO to fixatives is not recommended.     

Nucleoid structure in freeze fractures of Streptococcus faecalis: effects of filtration and chilling.

With the techniques used in this study, the nucleoid of Streptococcus faecalis could not be seen in freeze-etch preparations unless glutaraldehyde had been added to cultures of cells before they were frozen. With time, the nucleoid became visible as a network of fibers, apparently as a result of the aggregation of individual chromosomal elements in the presence of glutaraldehyde. When glutaraldehyde was added to undisturbed cultures, the fibers that became visible were observed in small patches that were seemingly scattered throughout the cytoplasm. However, if cells were chilled or placed on filters before glutaraldehyde was added, the fibers which then developed were seen in large central areas. The appearance of centralized nucleoids in freeze fractures of cells that had been chilled or filtered could be correlated with a decrease in the central density of the cytoplasm, as seen by light microscopy, in cells embedded in gelatin or bovine serum albumin. These observations are discussed in relation to a model for the normal structure of the nucleoid which suggests that the treatments routinely used to study the morphology-physiology of cells (chilling, filtration, and fixation) result in a reorganization of the cytoplasm, leading to an increase in the centralization of nuclear material.     

Possibility of the long-term fixation of the cells of a HeLa culture without disturbing their ultrastructure

It is shown that the composition of fixatives (2.5% glutaraldehyde in 0.1 M phosphate buffer with pH 7.2-7.4, and the mixture of 2.5% glutaraldehyde with 2% paraformaldehyde in 0.1 M phosphate buffer with pH 7.2-74) and duration of fixation (30 minutes, 24 hours, 7 days, and 30 days) under the room temperature exerts no influence on preservation of HeLa cultured cells. The ultrastructure of all the organelles of these cells is similar in any cases examined. All the membrane structures are well preserved; no condensation of chromatin is observed; the widths of the canals of endoplasmic reticulum, and of the intracristal and lateral spaces of mitochondria are invariable. Polysomes are present in the cytoplasm throughout the period of fixation.     

Tannic Acid Supplemented Fixation Improves Ultrastructural Evaluation of Respiratory Epithelium in Children with Recurrent Respiratory Tract Infections

Samples of the respiratory mucosa of children with recurrent respiratory infections suspected of having primary ciliary dyskinesia are routinely fixed with glutaraldehyde before ultrastructural examination. This standard technique, however, may not be optimal for visualizing ciliary components or for preserving several cellular and extracellular structures during dehydration and embedding procedures. In this study, brushes of nasal (28 samples) and/or tracheal (9 samples) mucosa from 32 children with recurrent respiratory tract infections were examined. Twenty-nine samples were fixed with glutaraldehyde supplemented with tannic acid to determine if the ultrastructural analysis of respiratory epithelium and bronchial secretions could be improved. Eight samples were conventionally fixed with glutaraldehyde alone. Lesions of the cellular membrane and damaged cells were easily visualized using tannic acid supplemented fixation. Internal ciliary structures including individual microtubules and dynein arms were also more clearly observed. In addition, the internal structure of microvilli of the respiratory epithelium could be studied and the presence of phospholipid-rich surfactant-like material within nasal and tracheal secretions were visualized after tannic acid supplemented fixation. We suggest that addition of tannic acid during fixation is useful for accurate ultrastructural evaluation of respiratory mucosa in both clinical and experimental situations.