Ultrastructural modifications of the follicular epithelium accompanying the onset of vitellogenesis in the whirligig beetle,Gyrinus natator

Summary The ultrastructure of the follicle cells during previtellogenesis and early vitellogenesis have been studied. In previtellogenesis follicle cells are columnar with numerous bundles of microtubules located along the lateral plasma membranes. Oocyte-follicle cell gap junctions are not found in this stage. At the onset of vitellogenesis, the bundles of microtubules disappear and are replaced by an apically located ring of microtubules. The modification of microtubular cytoskeleton is not followed by the development of intercellular spaces between the follicle cells. Concurrently, numerous gap junctions are formed between specialized follicle cell processes and oocyte microvilli, which are arranged in characteristic cone-shaped aggregations. It is suggested that cytoskeletal changes and formation of heterologous gap junctions, occurring at the onset of vitellogenesis, are induced by juvenile hormone.     

Embryogenesis in <Emphasis Type="Italic">Sedum acre</Emphasis> L.: structural and immunocytochemical aspects of suspensor development

The changes in the formation of both the actin and the microtubular cytoskeleton during the differentiation of the embryo-suspensor in Sedum acre were studied in comparison with the development of the embryo-proper. The presence and distribution of the cytoskeletal elements were examined ultrastructurally and with the light microscope using immunolabelling and rhodamine-phalloidin staining. At the globular stage of embryo development extensive array of actin filaments is present in the cytoplasm of basal cell, the microfilament bundles generally run parallel to the long axis of basal cell and pass in close to the nucleus. Microtubules form irregular bundles in the cytoplasm of the basal cell. A strongly fluorescent densely packed microtubules are present in the cytoplasmic layer adjacent to the wall separating the basal cell from the first layer of the chalazal suspensor cells. At the heart-stage of embryo development, in the basal cell, extremely dense arrays of actin materials are located near the micropylar and chalazal end of the cell. At this stage of basal cell formation, numerous actin filaments congregate around the nucleus. In the fully differentiated basal cell and micropylar haustorium, the tubulin cytoskeleton forms a dense prominent network composed of numerous cross-linked filaments. In the distal region of the basal cell, a distinct microtubular cytoskeleton with numerous microtubules is observed in the cytoplasmic layer adjacent to the wall, separating the basal cell from the first layer of the chalazal suspensor cells. The role of cytoskeleton during the development of the suspensor in S. acre is discussed.     

Tubulin-specific antibody and the expression of microtubules in 3T3 cells after attachment to a substratum : Further evidence for the polar growth of cytoplasmic microtubules in vivo

Mouse 3T3 cells were allowed to attach to and spread on glass. The expression of cytoplasmic microtubules during the respreading process was monitored by immunofluorescence microscopy using monospecific antibody against tubulin. During radial attachment of the cells a ring of flattened cytoplasm is seen around the nucleus. Cytoplasmic microtubules then enter this spreading ring from the perinuclear region and elongate toward the plasma membrane. At later times microtubules appear perpendicular to the plasma membrane and seem to be in intimate contact with it giving the impression that they “stretch” the cytoplasm. When the cells assume their typical fibroblastic shape numerous microtubules are seen. They traverse the cytoplasm. Some come close to the plasma membrane and some bend to conform to the shape of the cell. Changes in microtubular organization correlate well with changes in cell shape. These results together with our previous observations on the assembly of cytoplasmic microtubules upon recovery from colcemid treatment suggest that microtubules may grow as polar structures from a microtubular organizing center towards the plasma membrane. The hypothesis that cytoplasmic microtubules might confer polarity on the cell is discussed.     

Comparison of flagellated and nonflagellated sperm in plants

Differences among flagellated and nonflagellated sperm in land plants are striking, but close examination reveals similarities in pattern of cytoskeleton and in nuclear structure. The microtubular cytoskeleton of flowering plant sperm consists of microtubule bundles arranged obliquely around the nucleus, terminating in cellular extensions. Microtubules are linked into bundles that branch and rejoin along the axis of the sperm cell, forming a cytoskeleton that determines cell shape but does not actively participate in cell movement. Generative cells and sperm share a pattern of microtubules not found in somatic cells. This pattern is initiated in the generative cell, one division before sperm formation, a situation parallel to spermatogenous cell development in vascular plants with flagellated sperm. Chromatin in flagellated and nonflagellated sperm is condensed by specialized histones.     

Alterations to the microtubular cytoskeleton and increased disorder of chromosome alignment in spontaneously ovulated mouse oocytes aged in vivo: an immunofluorescence study

Alterations in the organization of the microtubular cytoskeleton and chromosome alignment were examined by tubulin immunofluorescence and DAPI staining during in vivo ageing of naturally ovulated, metaphase-arrested oocytes of CBA/Ca mice in the fallopian tubes. In oocytes isolated from young mice on the day of oestrus, a few hours after ovulation, when they are still tightly surrounded by cumulus, the anti-tubulin fluorescence is almost exclusively restricted to the metaphase spindle. Only some faintly staining foci are observed in the cytoplasm, which presumably represent cytoplasmic MTOC not involved in spindle formation. The spindle is usually barrel-shaped or slightly pointed at its poles and does not possess astral fibres. In oocytes aged for more than 12 h in the fallopian tubes cytoplasmic asters develop, while microtubules seem to become gradually lost from the spindle, preferentially in its central area near the chromosomes. Astral fibres are observed radiating out from the polar centrosomes into the cytoplasm. In oocytes free of cumulus, and consequently more than 24 h post-ovulation, a pronounced shrinking of the spindle is observed. The mean pole-to-pole distance becomes significantly reduced in postovulatory aged cells. At the same time astral microtubules in the cytoplasm appear to become gradually depolymerized. Age-dependent alterations in the microtubular cytoskeleton do not seem to result from a changed pattern of the post-translational detyrosylation of -tubulin in certain sets of microtubules. In freshly ovulated oocytes chromosomes in most spindles are well ordered and precisely arranged at the equatorial plane. In 11% of the cells only, there was dislocation of one or several of the chromosomes from the spindle equator. By contrast, 61.4% of bipolar spindles of postovulatory aged oocytes have chromosomes displaced from the centre of the spindle towards one of the spindle poles. The implications of the observed alterations in the microtubular cytoskeleton, shrinking of the spindle and increased disorder of chromosome alignment are discussed with regard to predisposition to aneuploidy and reduction of developmental potential of postovulatory aged oocytes.     

Structure and function of the microtubular cytoskeleton during pollen development in Gasteria verrucosa (Mill.) H. Duval

In a study of pollen development in Gasteria verrucosa, the changes in the spatial organization of microtubules were related to the processes of cell division, nuclear movement and cytomorphogenesis. Sections of polyethylene-glycol-embedded anthers of G. verrucosa were processed immunocytochemically to record the structure and succession of fluorescently labeled microtubular configurations. Using microspectrophotometric measurements the relative quantity of tubulin in microtubules per unit of cytoplasm was determined. Cell dimensions and nuclear positions were measured to relate changes in cell shape and nuclear movements to microtubular configurations. Microtubules were detected in the different cells during microsporogenesis and microgametogenesis. In microspore mother cells which are approximately isodiametric at interphase, microtubules were predominantly arranged in a criss-cross pattern. The microtubules probably function as a flexible cytoskeleton which sustains the integrity of the cytoplasm. Bundles of microtubules were observed in the microspores, in the generative cells and during nuclear division, where they functioned in establishing and maintaining cell and spindle shapes. Microtubules radiating from nuclear membranes appeared to fix the nucleus in position. In prophase of meiosis and after microspore mitosis, periods a high fluorescence intensity were distinguished indicating a variation in the quantity of microtubules.Abbreviation MT microtubule     

Confocal laser scanning microscopy of microtubule organizational changes in isolated generative cells of Allemanda neriifolia during mitosis

Summary Organizational changes in the microtubules of isolated generative cells of Allemanda neriifolia during mitosis were examined using anti--tubulin and confocal laser scanning microscopy. Due to an improved resolution and a lack of out-of-focus interference, the images of the mitotic cytoskeleton obtained using the confocal microscope are much clearer than those obtained using the non-confocal fluorescence systems. In the confocal microscope one can see clearly that the spindle-shaped interphase cells contain a cage-like cytoskeleton consisting of numerous longitudinally oriented microtubule bundles and some associated smaller bundles. At prophase, the shape of the cells invariably becomes spherical. The microtubule cytoskeleton inside the cells concomitantly changes into a less organized form — consisting of thick bundles, patches, and dots. This structural form is not very stable, and soon afterwards the cytoskeleton changes into a reticulate network. Then the nuclear envelope breaks down, and the microtubules become randomly dispersed throughout the cell. Afterwards, the microtubules reorganize themselves into a number of half-spindle-like structures, each possessing a microtubule-nucleating center. The locations of these centres mark out the positions of the presumptive spindle poles. Numerous microtubules radiate from these centres toward the opposite pole. At metaphase, the microtubules form a number of bipolar spindles. Each spindle has two half-spindles, and each half-spindle has a sharply focused microtubule centre at the pole region. From the centres, kinetochore and non-kinetochore microtubules radiate toward the opposite half-spindle. At anaphase A, sister chromatids separate, the cells elongate, and the kinetochore microtubules disappear; the non-kinetochore microtubules, however, remain, and a new array of microtubules, in the form of a cage, appears. The peripheral cage bundles and the non-kinetochore bundles coverge into a sharp point at the pole region. Later, at anaphase B the microtubule cytoskeleton undergoes reorganization giving rise to a new array of longitudinally oriented microtubule bundles in the cell centre and a cage-like cytoskeleton in the periphery. At telophase, some of the cells elongate further, but some become spherical. The microtubules in the central region of the elongated cell become partially disrupted due to the formation of a phragmoplast-junction-like structure in the mid-interzone region. The microtubule bundles at the periphery are spirally organized, and they appear not to be disrupted by the phragmoplast-like junction. The microtubules in the spherical telophase cells (unlike those seen in the elongated telophase cells) are arranged differently, and no phragmoplast-junction-like structure forms in the spherical cells. The structural and functional significances of some of these new features of the organization of the microtubule cytoskeleton as revealed by the confocal microscope are discussed.     

The microtubular cytoskeleton of three dinoflagellates: an immunofluorescence study

Summary The sub-thecal microtubular cytoskeleton of the dinoflagellatesAmphidinium rhynchocephalum, Gymnodinium sanguineum, andGymnodinium. sp has been investigated by indirect immunofluorescence microscopy. In these cells, the majority of cytoskeletal microtubules lie in the anterior-posterior plane. These longitudinal microtubules clearly originate from one of two radially arranged microtubular bands that correspond in location with the anterior and posterior edge of the cingolar depression. Despite the morphological variability of these gymnodinioid dinoflagellates, our data indicate that the microtubular cytoskeleton perfectly reflects the spatial patterning of the epicone and hypocone in each cell.Abbreviations ALB Anterior longitudinal microtubular bundles - ATB Anterior transverse microtubular bands - C cingulum - CLB Cingular longitudinal microtubular bundles - E Epicone - H Hypocone - PLB Posterior longitudinal microtubular bundles - PTB Posterior transverse microtubular bands - S Sulcus     

The structure of symplasmic early oocytes and their enveloping sheath cells in the polychaete,Platynereis dumerilii

1. Early oocytes of Platynereis dumerilii are found in clusters floating in the coelom. The oocytes of a cluster form a syncytium which is enveloped by several sheath cells. 2. At stage 2, only a single sheath cell per cluster remains, and it penetrates the group of rounded oocytes, enveloping each one of them. At stage 4, this cell contains a reticular basket made up of bundles of filaments and is inferred to be degenerating, from the presence of vacuoles, clumps of pigment-like material, and atypical mitochondria. 3. Synaptonemal complexes are typical of the nuclei of stage 2 oocytes. Oocytes of stage 4 (early vitellogenesis) contain stacks of endoplasmic reticulum in a distinctive arrangement, with interspersed electron-dense masses. Similar masses accumulate in the cytoplasm close to the nucleus and adjacent to the nuclear pores. 4. From the present observations, a physical supporting rather than a nutritive function is attributed to the sheath cell, which ensures cohesion among the oocytes connected with each other throughout the cluster phase by cytoplasmic bridges. This finding is discussed with respect to conclusions drawn from oocyte transplantation experiments.     

Microtubules and actin cytoskeleton in Cryptococcus neoformans compared with ascomycetous budding and fission yeasts

Actin cytoskeleton and microtubules were studied in a human fungal pathogen, the basidiomycetous yeast Cryptococcus neoformans (haploid phase of Filobasidiella neoformans), during its asexual reproduction by budding using fluorescence and electron microscopy. Staining with rhodamine-conjugated phalloidin revealed an F-actin cytoskeleton consisting of cortical patches, cables and cytokinetic ring. F-actin patches accumulated at the regions of cell wall growth, i. e. in sterigma, bud and septum. In mother cells evenly distributed F-actin patches were joined to F-actin cables, which were directed to the growing sterigma and bud. Some F-actin cables were associated with the cell nucleus. The F-actin cytokinetic ring was located in the bud neck, where the septum originated. Antitubulin TAT1 antibody revealed a microtubular cytoskeleton consisting of cytoplasmic and spindle microtubules. In interphase cells cytoplasmic microtubules pointed to the growing sterigma and bud. As the nucleus was translocated to the bud for mitosis, the cytoplasmic microtubules disassembled and were replaced by a short intranuclear spindle. Astral microtubules then emanated from the spindle poles. Elongation of the mitotic spindle from bud to mother cell preceded nuclear division, followed by cytokinesis (septum formation in the bud neck). Electron microscopy of ultrathin sections of chemically fixed and freeze-substituted cells revealed filamentous bundles directed to the cell cortex. The bundles corresponded in width to the actin microfilament cables. At the bud neck numerous ribosomes accumulated before septum synthesis. We conclude: (i) the topology of F-actin patches, cables and rings in C. neoformans resembles ascomycetous budding yeast Saccharomyces, while the arrangement of interphase and mitotic microtubules resembles ascomycetous fission yeast Schizosaccharomyces. The organization of the cytoskeleton of the mitotic nucleus, however, is characteristic of basidiomycetous yeasts. (ii) A specific feature of C. neoformans was the formation of a cylindrical sterigma, characterized by invasion of F-actin cables and microtubules, followed by accumulation of F-actin patches around its terminal region resulting in development of an isodiametrical bud.     

Actin and tubulin in teratocarcinoma cells. Amount and intracellular organization upon cytodifferentiation.

Embryonal carcinoma (EC) cells and differentiated derivatives grown in tissue culture have rather similar amounts of actin and tubulin. Indirect immunofluorescent microscopy with antibodies to actin shows striking differences in the actin organization in the different teratocarcinoma derivatives. In the EC cells, actin is found predominantly in ruffles and in surface protrusions, as well as in the cytoplasm, but microfilament bundles are not seen. Some of the differentiated clones contain strongly stained microfilament bundles; others contain actin arrangements which appear to be characteristic of the particular cell type. Indirect immunofluorescence microscopy with antibody to tubulin suggests that cytoplasmic microtubules are present both in the EC cells and in the various differentiated states studied. However, the ease with which microtubules can be documented is dependent on how cells are spread on the substratum. During in vitro differentiation of EC cells, changing patterns of actin distribution appear. Cells at the edge of the colony show the characteristic changes in microfilament and microtubular organization before those in the center.     

Organization, nucleation, and acetylation of microtubules in Xenopus laevis oocytes: a study by confocal immunofluorescence microscopy

Anti-tubulin immunofluorescence and laser-scanning confocal microscopy were used to examine microtubule organization during Xenopus oogenesis (Dumont stages I-VI). Stage I oocytes contained a poorly ordered microtubule array, characterized by concentrations of microtubule in the cortex, surrounding the germinal vesicle, and associated with the mitochondrial mass. No focus of microtubule organization was detectable by optical sectioning or in microtubule regrowth experiments, suggesting that stage I oocytes lack a functional MTOC. The microtubule array becomes progressively more complex and polarized during oogenesis; an extensive array of microtubules and microtubule bundles was apparent in the animal hemisphere of stage VI oocytes, and a less ordered array was observed in the vegetal hemisphere. A dense network of microtubules surrounded the germinal vesicle, apparently extending from a tubulin- and microtubule-rich region of cytoplasm adjacent to the vegetal surface of the GV. The organization of microtubules in normal oocytes, in oocytes recovering from cold-induced microtubule depolymerization, and in enucleated oocytes, suggested that the germinal vesicle serves as an MTOC in stage VI oocytes. Antibodies to acetylated alpha-tubulin revealed numerous acetylated, presumably stable, microtubules in stage I and stage VI oocytes. The array of oocyte microtubules thus might function as a stable framework for the localization of developmentally important molecules and organelles during oogenesis.     

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The microtubule organizational changes in the isolated generative cells of Allemanda schottii were followed using immunofluorescence and confocal laser scanning microscopy. Due to the improved resolution and the lack of out-of-focus flares, the microtubule cytoskeleton of the generative cells could be visualized more clearly than using conventional epifluorescence systems. Immediately after isolation the microtubule cytoskeleton of the generative cells was cage-like composed of longitudinally oriented microtubule bundles. Later, some bundles began to depolymerize and at the same time some smaller bundles appearred. The smaller bundles unlike the longitudinal bundles crisscrossed throughout the cell. Later still, the cells became spherical. Both the longitudinal and the smaller bundles disappearred. At the same time some of the microtubules began to aggregate around the nucleus. These perinuclear microtubules were apparently not very stable, because soon afterwards,they started to disintegrate. By the time the cells became completely spherical,the cytoplasm became filled with diffuse fluorescence indicating that the tubulin was no longer existing in a polymerized form but in a monomeric form inside the cell. After the fuberlin had completely depolymerized the microtubules started to reform. The sequence of events leading to the reformation of the microtubule cytoskeleton in the spherical cells was as follow: A few nucleating centres began to form first. Then the nucleating centres gave rise to microtubule bundles. The bundles extended and aggregated to form a reticulate network. This cytoskeletal network appearred stable and well organized. It also had a lot of microtubule-bundle junctions. The network persisted after Triton X-l00 extraction.     

Cytoskeletal organization of human mesenchymal stem cells (MSC) changes during their osteogenic differentiation

Human MSCs have been studied to define the mechanisms involved in normal bone remodeling and the regulation of osteogenesis. During osteogenic differentiation, MSCs change from their characteristic fibroblast-like phenotype to near spherical shape. In this study, we analyzed the correlation between the organization of cytoskeleton of MSCs, changes in cell morphology, and the expression of specific markers (alkaline phosphatase activity and calcium deposition) of osteogenic differentiation. For osteoblastic differentiation, cells were cultured in a culture medium supplemented with 100 nM dexamethasone, 10 mM beta- glycerophosphate, and 50 microg/ml ascorbic acid. The organization of microfilaments and microtubules was examined by inmunofluorescence using Alexa fluor 594 phalloidin and anti alpha-tubulin monoclonal antibody. Cytochalasin D and nocodazole were used to alter reversibly the cytoskeleton dynamic. A remarkable change in cytoskeleton organization was observed in human MSCs during osteogenic differentiation. Actin cytoskeleton changed from a large number of thin, parallel microfilament bundles extending across the entire cytoplasm in undifferentiated MSCs to a few thick actin filament bundles located at the outermost periphery in differentiated cells. Under osteogenic culture conditions, a reversible reorganization of microfilaments induced by an initial treatment with cytochalasin D but not with nocodazole reduced the expression of differentiation markers, without affecting the final morphology of the cells. The results indicate that changes in the assembly and disassembly kinetics of microfilaments dynamic of actin network formation may be critical in supporting the osteogenic differentiation of human MSCs; also indicated that the organization of microtubules appears to have a regulatory role on the kinetic of this process.     

Microtubular organization in flat epitheloid and stellate process-bearing astrocytes in culture

Microtubules and microfilament patterns in cultured astrocytes were revealed by using indirect immunofluorescent microscopy in conjunction with anti-tubulin immune serum and anti-actin immunoglobulins respectively. In flat epitheloid astroglial cells (either polygonal or elongated) colchicine-sensitive immunofluorescent fibres, which correspond to bundles of microtubules, extend from the perinuclear cytoplasm into the cell periphery by running for long distances through the different focal planes. These patterns of organization differ markedly from the patterns of organization of microfilaments which are arranged in fibres parallel to each other and often oriented along the cell boundary. In response to the combined treatments of serum withdrawal and administration of dBcAMP, flat epitheloid astrocytes adopt a morphology similar to that of the mature astrocytes in situ in the CNS, that is of stellate process-bearing cells. This is prevented or is reverted by the administration of colchicine at the appropriate times. There are strong suggestions indicating that during cell processes formation the microtubular network is reorganized and microtubules assembled into dense bundles which are oriented along the axis of the cell processes. In view of these results, we suggest that, in contrast to microfilaments, microtubules are not determinant for the maintenance of cellular shape in elongated or polygonal flat epitheloid astroglial cells but they are required for both the formation and maintenance of processes in stellate astrocytes.     

Distribution of microtubules during the breakdown of the nuclear envelope of the Xenopus oocyte: an immunocytochemical study

Xenopus oocytes were stained by anti-tubulin and anti-MAP1 antibodies during the first meiotic cell division. In the prophase-blocked oocytes, only few microtubules are present around the upper part of the nuclear envelope. These microtubules are resistant to cold, calcium and antimitotic drug treatments. At this stage, monoclonal anti-MAP1 antibody and polyclonal anti-centrosome antibody reveal punctate staining of the nucleus and nucleoli. During the progesterone-induced maturation, a microtubular network appears at the basal part of the disrupting nucleus. Anti-MAP1 and anti-centrosome antibodies stain a dense layer at the basal part of this microtubular array. Microtubules present in this array are cold, calcium- and antimitotic drug sensitive. Anti-MAP1 and anti-tubulin antibodies stain the whole metaphase II spindle, whereas only the poles of the metaphase II spindle are stained by the anti-centrosome antibody.     

Dynamics of the oocyte cortical cytoskeleton during oogenesis in Rhodnius prolixus

The oocyte cortex undergoes dramatic changes during oogenesis in Rhodnius prolixus. Despite numerous studies examining oogenesis in the telotrophic ovariole, none has investigated the ultrastructural details of the oocyte cortex, in particular, the lateral cortical cytoskeleton. Indirect immunofluorescent staining of sections, rhodamine phalloidin staining of whole mounts and scanning and transmission EM of permeabilized and unpermeabilized preparations revealed the dynamic changes of the oocyte cortex from early previtellogenesis through to late vitellogenesis. During early previtellogenesis, oocytes 50-150 mum in length have a smooth oolemma, with no discernible cortical cytoskeleton. During mid to late previtellogenesis (oocytes 150-350 mum in length) a tightly woven network of microfilaments and microtubules forms, excluding mitochondria and Golgi complexes from the lateral cortex. At the onset of vitellogenesis, the follicuiar epithelium becomes patent, and there is an increase in microvilli covering the lateral oocyte surface. The microfilament cores form a discrete pattern that corresponds to the imprint of the follicle cells on the oocyte surface. While the lateral microfilament cytoskeleton becomes more elaborate, the lateral microtubule cytoskeleton diminishes, remaining sparse throughout vitellogenesis. The oocyte cortical cytoskeleton undergoes dramatic changes during oogenesis. These cortical dynamics are intricately related to the cellular and molecular processes that occur during oogenesis.     

Microtubule configurations and post-translational alpha-tubulin modifications during mammalian spermatogenesis

The mechanisms underlying cell cycle progression and differentiation are tightly entwined with changes associated in the structure and composition of the cytoskeleton. Mammalian spermatogenesis is a highly intricate process that involves differentiation and polarization of the round spermatid. We found that pachytene spermatocytes and round spermatids have most of the microtubules randomly distributed in a cortical network without any apparent centrosome. The Golgi apparatus faces the acrosomal vesicle and some microtubules contact its surface. In round spermatids, at step 7, there is an increase in short microtubules around and over the nucleus. These microtubules are located between the rims of the acrosome and may be the very first sign in the formation of the manchette. This new microtubular configuration is correlated with the beginning of the migration of the Golgi apparatus from the acrosomal region towards the opposite pole of the cell. Next, the cortical microtubules form a bundle running around the nucleus perpendicular to the main axis of the cell. At later stages, the nuclear microtubules increase in size and a fully formed manchette appears at stage 9. On the other hand, acetylated tubulin is present in a few microtubules in pachytene spermatocytes and in the axial filament (precursor of the sperm tail) in round spermatids. Our results suggest that at step 7, the spermatid undergoes a major microtubular reordering that induces or allows organelle movement and prepares the cell for the formation of the manchette and further nuclear shaping. This new microtubular configuration is associated with an increase in short microtubules over the nucleus that may correspond to the initial step of the manchette formation. The new structure of the cytoskeleton may be associated with major migratory events occurring at this step of differentiation.     

Microtubule dynamics in root hairs of Medicago truncatula

The microtubular cytoskeleton plays an important role in the development of tip-growing plant cells, but knowledge about its dynamics is incomplete. In this study, root hairs of the legume Medicago truncatula have been chosen for a detailed analysis of microtubular cytoskeleton dynamics using GFP-MBD and EB1-YFP as markers and 4D imaging. The microtubular cytoskeleton appears mainly to be composed of bundles which form tracks along which new microtubules polymerise. Polymerisation rates of microtubules are highest in the tip of growing root hairs. Treatment of root hairs with Nod factor and latrunculin B result in a twofold decrease in polymerisation rate. Nonetheless, no direct, physical interaction between the actin filament cytoskeleton and microtubules could be observed. A new picture of how the plant cytoskeleton is organised in apically growing root hairs emerges from these observations, revealing similarities with the organisation in other, non-plant, tip-growing cells.     

Identification of multiple microtubule initiating sites in mouse neuroblastoma cells.

Mouse neuroblastoma N-18 cells can be induced by serum deprivation to sprout multiple neurite-like processes which contain many microtubules. Mitotic drugs such as colcemid and colchicine depolymerize these microtubules and the cells lose their processes. Reappearance of microtubules after removal of the drugs was followed by immunofluorescence microscopy using tubulin specific antibodies. At early recovery times multiple star-like structures which contained tubulin were detected in the perinuclear are and in the cytoplasm of individual cells. The mean number seen per cell as approximately 5. Their formation preceeded the organization of the complex microtubular networks typical of N-18 cells. The probable action of these structures as microtubular organization centers (MTOCs) is discussed. Multiple structures were detected during recovery from the influence of mitotic drugs both in previously induced and non-induced N-18 cells, suggesting that N-18 cells harbour the potential of formation of multiple organization centers even without previous induction. We discuss the possibility that differentiation of neuroblastoma N-18 cells may require microtubular organization centers.