Immunostructural evidence for the template mechanism of microtubule nucleation.

Two opposing models have been proposed to explain how the gamma-tubulin ring complex (gammaTuRC) induces microtubule nucleation. In the 'protofilament' model, the gammaTuRC induces nucleation as a partially or completely straightened protofilament that is incorporated longitudinally into the wall of the nascent microtubule, whereas the 'template' model proposes that the gammaTuRC acts as a helical template that constitutes the base of the newly-formed polymer. Here we appraise these two models, using high-resolution structural and immunolocalization methods. We show that components of the gammaTuRC localize to a narrow zone at the extreme minus end of the microtubule and that these ends terminate in a pointed cap. Together, these results strongly favour the template model of microtubule nucleation.

Structure of the gamma-tubulin ring complex: a template for microtubule nucleation.

The gamma-tubulin ring complex (gammaTuRC) is a protein complex of relative molecular mass approximately 2.2 x 10(6) that nucleates microtubules at the centrosome. Here we use electron-microscopic tomography and metal shadowing to examine the structure of isolated Drosophila gammaTuRCs and the ends of microtubules nucleated by gammaTuRCs and by centrosomes. We show that the gammaTuRC is a lockwasher-like structure made up of repeating subunits, topped asymmetrically with a cap. A similar capped ring is also visible at one end of microtubules grown from isolated gammaTuRCs and from centrosomes. Antibodies against gamma-tubulin label microtubule ends, but not walls, in centrosomes. These data are consistent with a template-mediated mechanism for microtubule nucleation by the gammaTuRC.

Individual microtubules viewed by immunofluorescence and electron microscopy in the same PtK2 cell.

PtK2 cells were grown on gold grids and treated with Triton X-100 in a microtubule stabilizing buffer. The resulting cytoskeletons were fixed with glutaraldehyde and subjected to the indirect immunofluorescence procedure using monospecific tubulin antibodies. Grids were examined first by fluorescence microscopy, and the display of fluorescent cytoplasmic microtubules was recorded. The grids were then stained with uranyl acetate and the display of fibrous structures recorded by electron microscopy. Thus the display of cytoplasmic microtubular structures in the light microscope and the electron microscope can be compared within the same cytoskeleton. The results show a direct correspondence of the fluorescent fibers in the light microscope with uninterrupted fibers of diameter approximately 550 A in the electron microscope. This is the diameter reported for a single microtubule decorated around its circumference by two layers of antibody molecules. Thus under optimal conditions immunofluorescence microscopy can visualize individual microtubules.

A rat monoclonal antibody reacting specifically with the tyrosylated form of alpha-tubulin. I. Biochemical characterization, effects on microtubule polymerization in vitro, and microtubule polymerization and organization in vivo.

The antigenic site recognized by a rat monoclonal antibody (clone YL 1/2) reacting with alpha-tubulin (Kilmartin, J.V., B. Wright, and C. Milstein, 1982, J. Cell Biol., 93:576-582) has been determined and partially characterized. YL 1/2 reacts specifically with the tyrosylated form of brain alpha-tubulin from different mammalian species. YL 1/2 reacts with the synthetic peptide Gly-(Glu)3-Gly-(Glu)2-Tyr, corresponding to the carboxyterminal amino acid sequence of tyrosylated alpha-tubulin, but does not react with Gly-(Glu)3-Gly-(Glu)2, the constituent peptide of detyrosylated alpha-tubulin. Electron microscopy as well as direct and indirect immunofluorescence microscopy shows that YL 1/2 binds to the surface of microtubules polymerized in vitro and in vivo. Further in vitro studies show that the antibody has no effect on the rate and extent of microtubule polymerization, the stability of microtubules, and the incorporation of the microtubule-associated proteins (MAP2) and tau into microtubules. In vivo studies using Swiss 3T3 fibroblasts injected with YL 1/2 show that; when injected at low concentration (2 mg IgG/ml in the injection solution), the antibody binds to microtubules without changing their distribution in the cytoplasm. Injection of larger concentration of YL 1/2 (6 mg IgG/ml) induces the formation of microtubule bundles, and still higher concentrations cause the aggregation of microtubule bundles around the nucleus (greater than 12 mg IgG/ml).

Role of microtubules in the organization and localization of the Golgi apparatus.

Normal interphase PtK2 and A549 cells display long microtubules radiating from the microtubule-organizing center (MTOC) to the plasma membrane. Both MTOC and Golgi apparatus are contained in the same perinuclear area. Treatment of cells with 1 microM colcemid for 2 h results in microtubule depolymerization and fragmentation of the Golgi apparatus into elements scattered throughout the cytoplasm. Both normal microtubules and the Golgi apparatus assemble again following removal of colcemid. Injection of the alpha, beta-nonhydrolyzable GTP analog, guanosine 5'(alpha, beta-methylene)diphosphate [pp(CH2)pG], into interphase cells growing in normal medium results in the formation of microtubule bundles resistant to colcemid and prevents the fragmentation of the Golgi apparatus. Injection of pp(CH2)pG into cells incubated with colcemid results in substitution of tubulin ribbons for microtubules and has no effect on the Golgi-derived elements scattered throughout the cytoplasm. Removal of colcemid 1 h after the injection of pp(CH2)pG results in polymerization of large numbers of short, single randomly oriented microtubules, whereas the Golgi apparatus remains fragmented. Treatment of cells with 10 microM taxol for 3 h results both in polymerization of microtubule bundles without relation to the MTOC in the cell periphery and fragmentation of the Golgi apparatus. The Golgi-derived fragments are present exclusively in regions of the peripheral cytoplasm enriched in microtubules. The codistribution of microtubules and Golgi elements can be reversed in taxol-treated cells by injection of a monoclonal (YL 1/2) antibody reacting specifically with the tyrosylated form of alpha-tubulin. Cells incubated with colcemid after treatment with taxol have large numbers of Golgi-derived elements in close association with colcemid-resistant microtubule bundles. Incubation of cells with 50 microM vinblastine for 90 min results in microtubule dissembly, formation of tubulin paracrystals, and fragmentation of the Golgi apparatus into elements without relation to the tubulin paracrystals.

Antibody microarray for correlating cell phenotype with surface marker.

To correlate cell surface markers with the cell phenotype, an antibody microarray prepared by covalently immobilizing antibodies onto a cellulose membrane and subsequent immunocytochemical staining were employed. The direct binding assay of a lymphoblastic leukemia cell line on the microarray showed that the immobilized antibody served to capture cells expressing the specific antigen. The density of bound cells increased linearly with an increasing content of antigen-expressing cells in suspension. The method was further applied to the analysis of surface antigens expressed on neural stem cells. A binding assay was performed with neural cells obtained from the neurosphere culture of the rat fetal striatum on a microarray spotted with eight kinds of antibodies and four different proteins, followed by immunocytochemical staining of cells bound to the microarray using antibodies to the intracellular markers of immature (nestin and vimentin) and mature (beta-tubulin III and glial fibrillary acidic protein) neural cells. As a result, the phenotype of bound cells could be correlated to surface antigen expression, which illustrated the potential of the solid-phase cytometry developed here for the identification of surface markers.

Differential distribution of tubulin epitopes in human spermatozoa.

Two monoclonal antibodies (16 D3 and 24 E3) were used to map tubulin domains in human spermatozoa by indirect immunofluorescence. Their specificity to tubulin in these cells was established by Western blotting. Whereas 16 D3 uniformly stained the principal piece of the flagellum, the staining provided by 24 E3 decreased along the tail to become very weak 30 micron further away from the midpiece. This latter antibody also reacted with the proximal centriole as well as the midpiece, but not all spermatozoa stained identically at this level indicating heterogeneity within the population of sperm cells from a given donor. 16 D3 reacted weakly with the head, and the staining was interrupted after a bright spot in the neck. The study of a pathological case (the short tail spermatozoon) with an abnormal arrangement of dense fibers was consistent with a correlation between the distribution of the epitope defined by 24 E3 and that of peri-axenomal structures. The existence of tubulin domains interacting with these structures is postulated.

Hydrogen peroxide induces endothelial cell atypia and cytoskeleton depolymerization.

Reactive oxygen intermediates induce cell injury in a variety of pathophysiological conditions. Human umbilical cord vein endothelial cell (HUVEC) cultures were exposed to 1 or 200 microM H2O2 for 15 min, and observed after 15 min, or 1, 4, 24, or 120 h. Factor VIII and the cytoskeletal proteins vimentin and tubulin were visualized immunocytochemically. Release of lactate dehydrogenase (indices of cell membrane injury) did not increase after H2O2 exposure; nor was cellular expression of factor VIII affected. 200 microM H2O2 induced cell contraction after 15 min which disappeared after 1 and 4 h, but was evident again after 24 h. Immediately after exposure, the filamentous structure of vimentin and tubulin disappeared, but normalized after 1 h. After 120 h, the cytoskeleton filaments were coarsened and disorganized, and an abundance of multinucleated giant cells were observed. Catalase (150 U/ml) abolished all effects of H2O2. One microM H2O2 did not induce any changes in HUVEC. Thus, the present concentrations of H2O2 did not induce cell necrosis or altered expression of factor VIII. Early, reversible cell contraction and depolymerization of cytoskeletal proteins were observed, followed by a delayed contraction and cell atypia after 200 microM H2O2.

Dehydration and embedding temperatures affect the antigenic specificity of tubulin and immunolabeling by the protein A-colloidal gold technique.

Qualitative and quantitative tests were performed to determine whether the temperature at which dehydration and embedding occur affects the antigenic specificity of tubulin and the protein A-gold (pAg) immunolabeling technique. The analysis indicates that low temperature (-35 degrees C) treatment increased the specificity and density of pAg labeled anti-tubulin antibodies to Leishmania tropica subpellicular microtubules as compared to samples prepared at 0 degrees C or 20 degrees C.

A method for co-localization of tubular lysosomes and microtubules in macrophages: fluorescence microscopy of individual cells.

Routinely used procedures for chemical fixation often fail to preserve delicate membrane-bounded tubular structures in a variety of cell types. Fixation procedures commonly employed in immunocytochemical studies for localization of structural proteins, such as those found in cytoskeletal elements, may also degrade these tubular structures. Here we describe a procedure that preserves the elaborate tubular lysosome system found in stimulated macrophages and allows the subsequent immunofluorescence localization of microtubules in the same cells. Use of this methodology permits the assessment of the spatial relationship between tubular lysosomes and microtubules in macrophages.

In situ appearance of the cold-stable microtubules in the growing axons of the tectal plate of mouse investigated immunocytochemically after polyethyleneglycol (PEG) embedding.

Tubulin immunostaining of semi-thin sections after polyethylene glycol embedding was used in the tectal plate of the embryonic mouse at 10 days postmating to analyze the effects of cold treatment on the microtubules of the different cell types seen at this stage. Three sets of microtubules are observed. In the radially oriented bipolar columnar cells, dense bundles of microtubules are present in the ventricular processes between the cell nucleus and the ventricular surface. In the mitotic cells, located just at the surface of the ventricle, microtubules are among condensed chromosomal figures. In the apical region, the intermediate zone, tangentially oriented axonal profiles contain dense bundles of microtubules among tangentially oriented young neurons. Cold treatment does not modify the organization of the cells. However, it depolymerizes whole cytoplasmic and mitotic microtubules of the bipolar cells and a large number of microtubules in the growing axons. In the axonal profiles, the cold-stable fraction of microtubules displays the appearance of short fragments. Some of these are regularly organized, suggesting that they could be the remnants of the same individual microtubule. These fragments are approximately 1 micron long and seem to represent nearly 10% of the total microtubules in the axons. These cold-stable fragments might fulfill a function in the axon analogous to the microtubule organizing centers in the perikaryon and their presence can explain some properties of the growing axons suggested by previous studies on the guidance of neurites and growth cones as well as on the growth of isolated axons.

New immunological approaches to studying the odontoblast.

The use of specific polyclonal and monoclonal antibodies as probes to study odontoblast morphology, function, and differentiation has received relatively little attention. The extent of the odontoblast processes in human and rat teeth is one question that we have approached recently by utilizing antibodies specific for intracellular elements, i.e., the cytoskeleton. Indirect immunofluorescence on both paraffin-embedded thin sections and surface-demineralized collagenase-digested whole mounts has indicated that the odontoblast process does extend to the dentino-enamel junction. By using other antibodies which recognize intra- and extracellular components, or antibodies which recognize unique antigens expressed at the cell surface of the odontoblast or its precursor cells, many more precise molecular details of odontoblast form and function would become accessible for analysis.

An immunocytochemical study of the human odontoblast process using antibodies against tubulin, actin, and vimentin.

An immunofluorescence technique was applied at the light microscope level to human third molar coronal dentin in order to localize the intracellular components tubulin, vimentin, and actin. Third molars were split immediately upon extraction, and immersed in periodate-lysine-paraformaldehyde fixative. The crowns were demineralized, dehydrated, and wax-embedded, and 6-micron sections were prepared. The sections were post-fixed in -20 degrees C acetone, and then incubated with monoclonal mouse anti-tubulin, anti-vimentin, or anti-actin antibodies, followed by fluorescein-conjugated sheep anti-mouse immunoglobulins. Intratubular immunofluorescence labeling for tubulin and vimentin was very similar in pattern and intensity and extended to the dentino-enamel junction. In contrast, the actin labeling appeared less intense and more punctate, and was located primarily in the pulpal half of the crown, although some labeling was detectable up to the dentino-enamel junction. The presence of tubulin-, vimentin-, and actin-containing structures extending to the dentino-enamel junction supports the hypothesis that the odontoblast process does extend to the dentino-enamel junction in the human, and is in agreement with earlier studies of rat molars.

Immunohistochemical and morphological studies on the human fetal cochlea: a comparative view on methods.

The preservation of morphology and antigenicity can vary uncontrollably with human fetuses since these rely heavily on immediate fixation of the temporal bone following spontaneous abortion. Once good fixation is established, there is the question of the approach taken for morphologic and immunohistochemical studies. To achieve maximal preservation for the purpose of studying normal and pathologic fetal cochleae, commonly used preparation methods for analyzing the cochlea were reviewed and compared for both immunohistochemical and morphologic studies. Cochleae obtained after spontaneous abortion ranged from the 9th gestational week to birth. Four different methods were compared for morphologic study: the block surface method; a microslicing technique; paraffin; and celloidin sectioning. For immunohistochemical study, three methods were compared: pre-embedding; paraffin; and frozen sectioning. For morphologic preservation, the block surface method gave best overall results, showing good representation of the fetal cochlea for surface preparation, light, and electron microscopy. Celloidin sectioning was also found to show good light microscopic results for both the middle and inner ear. To achieve optimal results, preservation quality, fixation procedures, and antibody all contribute to the efficacy of a methods choice.

[Morphology of the microtubule system during the sphering, layering and polarization of normal and transformed fibroblasts]. / Morfologiia sistemy mikrotrubochek pri okruglenii, rasplastyvanii i poliarizatsii normal'nykh i transformirovannykh fibrolbastov.

The ultrastructure of the genital system (ductus seminalis, vestibulum, ductus tortuosus and canaliculus fecundans) has been studied during mating and oviposition. All these organs have a common organization and contain three parts: muscular and epithelial layer and chitin intima lining the interior surface of the female genital system. Ultrastructures of the muscular tissue and of the basal part of epidermis are similar. The luminal surface and microvilli are different in various organs of the female genital system. The ultrastructural pattern and the thickness of chitin intima may also vary, and can be used as a character for identificating different organs of the female system in ultrathin sections.

The formation of the nervous system during larval development in Triops cancriformis (Bosc) (crustacea, Branchiopoda): An immunohistochemical survey.

We provide data of the development of thenervous system during the first five larval stages of Triops cancriformis. We use immunohistochemical labeling (against acetylated α-tubulin, serotonin, histamine, and FMRFamide), confocal laser scanning microscopy analysis, and 3D-reconstruction. The development of the nervous system corresponds with the general anamorphic development in T. cancriformis. In larval stage I (L I), all brain parts (proto-, deuto-, and tritocerebrum), the circumoral connectives, and the mandibular neuromere are already present. Also, the frontal filaments and the developing nauplius eye are already present. However, until stage L III, the nauplius eye only consists of three cups. Throughout larval development, the protocerebral network differentiates into distinct subdivisions. In the postnaupliar region, additional neuromeres and their commissures emerge in an anteroposterior gradient. The larval nervous system in L V consists of a differentiated protocerebrum including a central body, a nauplius eye comprising four cups, a circumoral nerve ring, mandibular- and postnaupliar neuromeres up to the seventh thoracic segment, each featuring an anterior and a posterior commissure, and two parallel connectives. The presence of a protocerebral bridge is questionable. The distribution of neurotransmitters in L I is restricted to the naupliar nervous system. Over the course of the five stages of development, neurotransmitter distribution also follows an anteroposterior gradient. Each neuromere is equipped with two ganglia innervating the locomotional appendages and possesses a specific neurotransmitter distribution pattern. We suggest a correlation between neurotransmitter expression and locomotion.

Immunoproteomics reveals that cancer of the tongue and the gingivobuccal complex exhibit differential autoantibody response.

Autoantibody response to tumor antigens has been widely used to identify novel tumor markers for different cancers, including that of the head and neck. The oral cavity, which is in the head and neck region, comprises of many sub sites with distinct biologies and incidence of cancer of each sub site of the oral cavity is different. It is anticipated therefore that each sub site of the oral cavity may elicit a differential autoantibody response. This report evaluates the autoantibody response in 15 patients with cancer of gingivo-buccal complex and in 15 patients with cancer of tongue using Immunoproteomics, and shows that the autoantibody response to alpha-enolase, HSP 70, peroxiredoxin-VI, annexin II, pyruvate kinase, alpha-tubulin, beta-tubulin, ATP synthase, triose phosphate isomerase and aldose reductase seen in patients with cancer of gingivo-buccal complex is absent in patients with cancer of tongue. This suggests that cancer of these sub sites should be studied separately because of their different biology and emerging site specific molecular signatures including autoantibody responses to ensure unambiguous clinical interpretations.

Antibodies introduced into living cells with liposomes localize specifically and inhibit specific intracellular processes.

We have developed a system for efficiently packaging antibodies and other macromolecules into liposomes and then delivering the encapsulated molecules into living cells through liposome-cell fusion. Fusion is very efficient, and all cells can be demonstrated to contain liposome-delivered antibodies by staining with a fluorescent second antibody. Using lupus antibodies directed against small nuclear ribonucleoprotein components of the cell, we were able to demonstrate strong nuclear localization, while control antibodies showed a general diffuse distribution throughout the cell. Lupus antibodies directed against ribosomes, on the other hand, strongly localized in the nucleolus and the cytoplasm with very little nucleoplasmic localization. Antitubulin antibodies predominantly localized in the cytoplasm. These results show that antibodies can survive liposome packaging and can retain their ability to recognize and bind to their specific antigens in the living cell. It also indicates that the nuclear envelope does not present a barrier to the liposome-introduced antibodies in Drosophila tissue culture cells. To determine if the antibodies were capable of interfering with cellular processes in vivo, we measured the effects of liposome-introduced antiribosome antibodies on translation and antitubulin antibodies on mitosis. In both cases, there was a significant inhibition suggesting that the antibodies can be used to interfere with specific functions at specific times in vivo.

Immunoelectron microscopy of Giardia lamblia cytoskeleton using antibody to acetylated alpha-tubulin.

Giardia lamblia trophozoites contain acetylated alpha-tubulin but lack detectable levels of tyrosinolated alpha-tubulin, as demonstrated in immunoblots with monoclonal antibodies specific for these tubulin forms. By immunofluorescence microscopy, acetylated alpha-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 alpha-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.