Centrosome Behavior under the Action of a Mitochondrial Uncoupler and the Effect of Disruption of Cytoskeleton Elements on the Uncoupler-Induced Alterations

Carbonyl cyanide p-(trifluoromethoxy)phenylhydrazone (FCCP) induced in pig kidney embryo cells a loss of rhodamine 123 staining of mitochondria in 2-3 min. Within 5 min after FCCP inoculation of cells prestained with rhodamine 123, the diffuse staining of the cytoplasm was absent. FCCP did not induce changes in the cytoplasmic microtubule complex, but induced nonrandom (preferentially perpendicular to the substrate surface) orientation of maternal centrioles. Nonrandom orientation of maternal centrioles occurred 10 min after treatment and remained for 2 hr. At 30 min after introduction of the drug, FCCP treatment increased the mean number of pericentriolar satellites on maternal centrioles and the frequency of primary cilia. The percentage of centrioles perpendicular to the substrate induced by FCCP treatment was slightly increased by disruption of microtubules and slightly diminished by disruption of microfilaments. In both cases centrioles were oriented significantly differently from random (P < 0.01). These results suggest that microtubules are neither involved in the signaling pathway from plasma membrane to the centriole, nor do they anchor the centrioles perpendicular to the substrate, as proposed by Albrecht-Buehler and Bushnell (Experimental Cell Research 120, 1979).     

The ultrastructure of the centrosome in cytoplasts and its alteration under the action of ouabain]

It has been shown that after enucleation of the PE cells with cytochalasin D the centrioles remain in approximately 80% of cytoplasts. Some cytoplasts contain only single centriole, either a mother (active) of a daughter (inactive) one. 20% cytoplasts have no centrioles. 2h after enucleation the centrosome structure in the cytoplasts did not differ from that in normal cells. 14-16 h after enucleation in many cytoplasts large secondary lysosomes and lipid droplets appeared around the centrosome. At this time in some cytoplasts in the centrosome we observed free microtubule convergence foci. 14-16 h after the enucleation, some cytoplasts have doubling centrioles. Under the influence of ouabain (30 min), the number of active centrioles oriented perpendicularly to the substrate plane in the cytoplasts increased. We suggest that the preferentially perpendicular orientation of centrioles to the substrate plane does not depend on the nuclear activity.     

Structural change in the cell center during fibroblast polarization and movement

In polarizing and migrating 3T3/Balb mouse fibroblasts, the centrioles are located between the nucleus and the leading edge of the cell. In cells within the monolayer and in migrating cells, the centrioles have a random orientation towards the substrate. In polarized cells, that still remain in the monolayer, one centriole may be perpendicular to the substrate plane in 70% of cases. Upon polarization and migration of fibroblasts, the number of microtubules, which radiate from the centriolar region, increases. These data support a hypothesis that the number of microtubules in the cell centre characterizes the rate of their renovation in the cytoplasm. It is concluded that the cell centre is strongly involved in polarization and migration of fibroblasts.     

Chromosome attachment to the spindle in crane-fly spermatocytes requires actin and is necessary to initiate the anaphase-onset checkpoint

Summary We investigated the possible involvement of actin in the attachment of chromosomes to spindles in crane-fly primary spermatocytes. In a previous study, cytochalasin D, an inhibitor of actin polymerisation, prevented bivalent attachment to microtubules when applied at prophase, but did not cause the detachment of already attached bivalents. We were able to detach the already attached bivalents by first treating prometaphase cells with an antitubulin drug, nocodazole, to disrupt spindle microtubules. 2 min after nocodazole addition, we added cytochalasin D, to disrupt actin filaments; then 2 min later nocodazole was removed, and the cells were kept in cytochalasin D until the time of normal anaphase. Double treatment with nocodazole and cytochalasin D blocked reattachment of bivalents to the spindle. Single treatment with nocodazole alone caused chromosome detachment but did not prevent reattachment when nocodazole was washed out. Extended treatment with cytochalasin D alone starting in prometaphase did not cause bivalents to detach from the spindle. These data suggest that actin is needed for attachment of bivalents to spindle microtubules. This protocol is relevant to the anaphase-onset checkpoint. From previous experiments it was argued that the anaphase-onset checkpoint recognises unattached chromosomes only after those chromosomes first interact with (become attached to) the spindle. Our experiments showed that anaphase disjunction occurred at normal times when bivalents were prevented from attaching to the spindle (by adding cytochalasin D in prophase), while anaphase disjunction was greatly delayed when previously attached bivalents were detached (with nocodazole) and then prevented from re-attaching (with cytochalasin D) in the double treated cells. Thus the anaphaseonset checkpoint recognises only those unattached bivalents that previously were attached to the spindle. Other results provided further indication that actin-microtubule interactions are important in spindle organisation. Nocodazole treatment for 4 min caused most microtubules to disappear: bivalents aggregated around remnant microtubules. When cytochalasin D treatment followed nocodazole treatment, remnant spindle microtubules were not seen, suggesting that actin interactions help stabilise those microtubules.Abbreviations CD cytochalasin D - NMBD nuclear-membrane breakdown - NOC nocodazole     

Stimulation of plasminogen activator expression and induction of DNA synthesis by microtubule-disruptive drugs

Treatment of confluent Swiss 3T3 cells in serum-free medium with colchicine, a drug known to depolymerize microtubules, results in a dose-dependent increase in both released and cell-associated plasminogen activator levels. Other anti-microtubule drugs (vinblastine and nocodazole) are also active in stimulating plasminogen activator expression. In contrast, cytochalasin B, a microfilament-disruptive drug, has no effect. In addition, treatment with colchicine, vinblastine or nocodazole, but not cytochalasin B, also results in a dose-dependent induction of DNA synthesis in both confluent and quiescent sparse 3T3 cells in the absence of serum. Furthermore, colchicine treatment also mediates a marked morphologic change. Thus, disruption of microtubules may be sufficient to render 3T3 cells in an “activated” state characterized by morphologic alteration, enhanced plasminogen activator expression and induction of DNA synthesis.     

Ultrastructural disorders of the mitotic apparatus during cytochalasin B action

A correlation between the number of chromosome sets and the number of centrioles (8n--8 centrioles) was observed in polyploid metaphase cells, during cytochalasin B treatment on the cultured Chinese hamster cells. There is no correlation between the number of chromosome sets and the centriole number after stopping the action of the drug in many cells, but a great variation is observed in maintenance of chromosomes and centrioles (up 6 to 25 n and up 4 to 22 centrioles). In multipolar mitosis, either during the drug action or after its stopping, different numbers of chromosomes are directed towards the poles not depending on the number of centrioles in the poles. During the cytochalasin B treatment, either in bipolar or multipolar metaphases, there are destructions in the ultrastructure of the mitotic apparatus: there are no astral microtubules; in the poles there are diplosomes and duplex of centrioles with fibrillar material around both centrioles; kinetochores are of prometaphase type. After stopping the drug action the astral microtubules appear, but no other patterns of normalization in the mitotic apparatus occur. Desynchronization of three cycles (chromosomal, centriolar and centrosomal) is discussed as a factor of abnormal development of the mitotic apparatus and as a factor of stabilization of aneuploidy in the cell culture.     

Induction of multipolar mitoses in cultured cells: Decay and restructuring of the mitotic apparatus and distribution of centrioles

During recovery after a long (up to 12 h) treatment of pig embryo culture cells (PK) with nocodazole at concentrations of 0.02 g/ml and 0.2 g/ml all c-metaphase cells divide normally into two daughter cells. During recovery after a short (1–4 h) treatment with 0.6 g/ml nocodazole only multipolar mitoses (as a rule tripolar) arise. At the ultrastructural level, the increasing nocodazole concentration leads to progressive disruption of the mitotic spindle. At a nocodazole concentration of 0.2 g/ml kinetochores are not associated with microtubules. At a nocodazole concentration of 0.6 g/ml there are no microtubules around the centrosomes, and in every cell one of the two diplosomes disintegrates. In tripolar telophase centrioles are distributed among the spindle poles generally in a 2:2:0 pattern. Mother and daughter centrioles are always disoriented but not separated. The centriole-free pole contains a cloud of electron-dense material. During tripolar division two of the three daughter cells mainly fuse shortly after telophase forming one binucleate cell. Thus a multipolar mitosis arises as a result of the uncoupling of mother centrioles and spindle microtubules, but not of the duration of the c-mitotic arrest. Centriole-free poles account for the divergence of chromosomes, but mainly they are unable to ensure the normal cytokinesis of daughter cells.by M. Trendelenburg     

Centrosome behavior in the exposure of tissue culture cells to energy metabolism inhibitors

The organization of the centrosome in PK cells has been analysed according to several parameters: the presence of primary cilium, the number of pericentriolar satellites, the presence of striated rootlets, the distance between two centrioles and their orientation as regards the substrate plane. 2,4-Dinitrophenol (DNP), DNP with deoxyglucose (DOG), sodium azide cause the increase of frequency of occurrence of primary cilia and the growth of mean number of satellites per active centriole. The distribution of active and inactive centrioles in control cells is described by a histogram corresponding to a histogram of accidental distribution. Under the action of DNP or DNP with DOG, but not of sodium azide a part of active centrioles settled down perpendicularly to the substrate plane increases. The orientation of inactive centrioles under all the treatments used doesn't practically change.     

Migration Behavior of Granule Cell Neurons in Cerebellar Cultures. II. An Electron Microscopic Study

We examined the fine structure of migrating granule cell neurons in cerebellar microexplant cultures. Radially migrating bipolar cells extended microspikes or small filopodia from their soma and processes and frequently made contact with neighboring cells. These microspikes contained microfilaments but no microtubules. At the later phase of the migration, in which they had symmetrical bipolar long processes, filopodia extending from perikarial region of cells contained microtubules, suggesting that they are precursors of the future thick perpendicular processes. When cell bodies changed orientation from radial to perpendicular, microtubules that were nucleated from perinuclear centrioles frequently extended into both thick radial and perpendicular processes from the perikarial region. Bundles of 10nm intermediate filaments also appeared in these processes. During migration by the perpendicular contact guidance, many filopodia extending from both the thick leading processes and thin trailing processes made close contacts with the radial parallel neurite. These findings suggest that; 1) The direct contact of the filopodia from both the growth cones and their processes of the granule cells to the neurite bundle plays roles in both the parallel and perpendicular contact guidances. 2) The spacial and temporal changes of cytoskeletons and the association of microtubules with perinuclear centrioles are important for the formation of perpendicular processes and initiation of the perpendicular contact guidance.     

Role of cytoskeletal elements in the recruitment of Cx43-GFP and Cx26-YFP into gap junctions

Cytoskeletal elements may be important in connexin transport to the cell surface, cell surface gap junction plaque formation and/or gap junction internalization. In this study, fluorescence recovery after photobleaching was used to examine the role of microfilaments and microtubules in the recruitment and coalescence of green fluorescent protein-tagged Cx43 (Cx43-GFP) or yellow fluorescent tagged-Cx26 (Cx26-YFP) into gap junctions in NRK cells. In untreated cells, both Cx26-YFP and Cx43-GFP were recruited into gap junctions within photobleached areas of cell-cell contact within 2 hrs. However, disruption of microfilaments with cytochalasin B inhibited the recruitment and assembly of both Cx26-YFP and Cx43-GFP into gap junctions within photobleached areas. Surprisingly, disruption of microtubules with nocodazole inhibited the recruitment of Cx43-GFP into gap junctions but had limited effect on the transport and clustering of Cx26-YFP into gap junctions within the photobleached regions of cell-cell contact. These results suggest that the recruitment of Cx43-GFP and Cx26-YFP to the cell surface or their lateral clustering into gap junctions plaques is dependent in part on the presence of intact actin microfilaments while Cx43-GFP was more dependent on intact microtubules than Cx26-YFP.     

Role of Cytoskeletal Elements in the Recruitment of Cx43-GFP and Cx26-YFP into Gap Junctions

Cytoskeletal elements may be important in connexin transport to the cell surface, cell surface gap junction plaque formation and/or gap junction internalization. In this study, fluorescence recovery after photobleaching was used to examine the role of microfilaments and microtubules in the recruitment and coalescence of green fluorescent protein-tagged Cx43 (Cx43-GFP) or yellow fluorescent tagged-Cx26 (Cx26-YFP) into gap junctions in NRK cells. In untreated cells, both Cx26-YFP and Cx43-GFP were recruited into gap junctions within photobleached areas of cell-cell contact within 2 hrs. However, disruption of microfilaments with cytochalasin B inhibited the recruitment and assembly of both Cx26-YFP and Cx43-GFP into gap junctions within photobleached areas. Surprisingly, disruption of microtubules with nocodazole inhibited the recruitment of Cx43-GFP into gap junctions but had limited effect on the transport and clustering of Cx26-YFP into gapjunctions within the photobleached regions of cell-cell contact. These results suggest that the recruitment of Cx43-GFP and Cx26-YFP to the cell surface or their lateral clustering into gap junctions plaques is dependent in part on the presence of intact actin microfilaments while Cx43-GFP was more dependent on intact microtubules than Cx26-YFP.     

Role of Cytoskeletal Elements in the Recruitment of Cx43-GFP and Cx26-YFP into Gap Junctions

Cytoskeletal elements may be important in connexin transport to the cell surface, cell surface gap junction plaque formation and/or gap junction internalization. In this study, fluorescence recovery after photobleaching was used to examine the role of microfilaments and microtubules in the recruitment and coalescence of green fluorescent protein-tagged Cx43 (Cx43-GFP) or yellow fluorescent tagged-Cx26 (Cx26-YFP) into gap junctions in NRK cells. In untreated cells, both Cx26-YFP and Cx43-GFP were recruited into gap junctions within photobleached areas of cell-cell contact within 2 hrs. However, disruption of microfilaments with cytochalasin B inhibited the recruitment and assembly of both Cx26-YFP and Cx43-GFP into gap junctions within photobleached areas. Surprisingly, disruption of microtubules with nocodazole inhibited the recruitment of Cx43-GFP into gap junctions but had limited effect on the transport and clustering of Cx26-YFP into gapjunctions within the photobleached regions of cell-cell contact. These results suggest that the recruitment of Cx43-GFP and Cx26-YFP to the cell surface or their lateral clustering into gap junctions plaques is dependent in part on the presence of intact actin microfilaments while Cx43-GFP was more dependent on intact microtubules than Cx26-YFP.     

Microtubules, microfilaments and the transport of acetylcholine receptors in embryonic myotubes

Both microtubules and microfilaments have been implicated in the exocytotic and endocytotic transport of coated and smooth surfaced membrane vesicles. We have reexamined this question by using specific pharmacological agents to disrupt these filaments and assess the effect on the movement of acetylcholine receptor (AChR) containing membrane vesicles in embryonic chick myotubes. Myotube cultures treated with nocodazole (0.6 microgram/ml) or colcemid (0.5 microgram/ml) (to disrupt microtubules) show only a 20-25% decrease in the number of cell surface AChRs after 48 h. Addition of chick brain extract (CBE) to cultured myotubes causes a significant increase in the total number of cell surface AChRs (measured by [125I]alpha-bungarotoxin (alpha-BGT) binding), thus providing us with a way to manipulate receptor and transport vesicle populations. Cultures treated with CBE plus nocodazole or colcemid show a 1.7-fold increase in AChR number over drug treatment alone, the same increase seen in cultures treated with CBE alone, although the total number remains about 20-25% less than that seen in control cultures. In cultures treated with cytochalasin D (0.2 microgram/ml) or dihydrocytochalasin B (5.0 micrograms/ml) (to disrupt microfilaments), 35 and 65% decreases in cell surface AChR number were seen after 48 h. However, in cultures treated with CBE and cytochalasin D, the same total number of AChRs was found as in cultures treated with CBE alone. No significant effects were seen with any of these drugs on the receptor incorporation rate (the appearance of new alpha-BGT-binding sites) after 6 h. The half-life for AChRs in control cultures was 23.0 h. In cytochalasin D and dihydrocytochalasin B it was 21.9 and 19.0 h, respectively; with colcemid and nocodazole, it increased to 37.1 and 28.1 h. These results suggest that non-myofibrillar microfilament bundles are not involved in the movement of AChR-containing membrane vesicles; further, the small effects seen with microtubule inhibitors tend to rule out a major role for microtubules in this transport.     

Characterization of novel F-actin envelopes surrounding nuclei during cleavage of a polychaete worm

F-actin accumulations and their possible functions were investigated during cleavage of the polychaete Ophryotrocha puerilis. Unusual cytoplasmic accumulations of F-actin were detected which have never been described before in animal embryos. As shown by TRITC-phalloidin labeling, envelopes of F-actin surrounded late prophase nuclei for a short period of time. DTAF-immunofluorescence of beta-tubulin showed that the F-actin envelope was closely associated with microtubules of the developing spindle apparatus. However, experimental disassembly of microtubules by nocodazole did not prevent the assembly of the F-actin envelope. Disturbance of F-actin envelope formation by cytochalasin B did not alter the course of mitotic events, i.e. position of the nuclei and orientation of the spindle apparatus were not affected, although the respective blastomeres remained uncleaved. However, disassembly of the F-actin envelope correlated temporally with breakdown of the nuclear envelope. Therefore, it is suggested that this new structure plays a role in fragmentation of the nuclear envelope during cleavage of Ophryotrocha puerilis.     

Microtubules regulate local Ca2+ spiking in secretory epithelial cells

The role of the cytoskeleton in regulating Ca(2+) release has been explored in epithelial cells. Trains of local Ca(2+) spikes were elicited in pancreatic acinar cells by infusion of inositol trisphosphate through a whole cell patch pipette, and the Ca(2+)-dependent Cl(-) current spikes were recorded. The spikes were only transiently inhibited by cytochalasin B, an agent that acts on microfilaments. In contrast, nocodazole (5-100 micrometer), an agent that disrupts the microtubular network, dose-dependently reduced spike frequency and decreased spike amplitude leading to total blockade of the response. Consistent with an effect of microtubular disruption, colchicine also inhibited spiking but neither Me(2)SO nor beta-lumicolchicine, an inactive analogue of colchicine, had any effect. The microtubule-stabilizing agent, taxol, also inhibited spiking. The nocodazole effects were not due to complete loss of function of the Ca(2+) signaling apparatus, because supramaximal carbachol concentrations were still able to mobilize a Ca(2+) response. Finally, as visualized by 2-photon excitation microscopy of ER-Tracker, nocodazole promoted a loss of the endoplasmic reticulum in the secretory pole region. We conclude that microtubules specifically maintain localized Ca(2+) spikes at least in part because of the local positioning of the endoplasmic reticulum.     

The effects of microtubule and microfilament disrupting agents on cytoskeletal arrays and wall deposition in developing cotton fibers

Summary The effects of various cytoskeletal disrupting agents (cholchicine, oryzalin, trifluralin, taxol, cytochalasins B and D) on microtubules, microfilaments and wall microfibril deposition were monitored in developing cotton fibers, using immunocytochemical and fluorescence techniques. Treatment with 10^–4 M colchicine, 10^–6 M trifluralin or 10^–6 M oryzalin resulted in a reduction in the number of microtubules, however, the drug-stable microtubules still appear to influence wall deposition. Treatment with 10^–5 M taxol increased the numbers of microtubules present within 15 minutes of application. New microtubules were aligned parallel to the existing ones, however, some evidence of random arrays was observed. Microtubules stabilized with taxol appeared to function in wall organization but do not undergo normal re-orientations during development. Microtubule disrupting agent had no detectable affect on the microfilament population. Exposure to either 4×10^–5 M cytochalasin B or 2×10^–6M cytochalasin D resulted in a disruption of microfilaments and a re-organization of microtubule arrays. Treatment with either cytochalasin caused a premature shift in the orientation of microtubules in young fibers, whereas in older fibers the microtubule arrays became randomly organized. These observations indicate that microtubule populations during interphase are heterogeneous, differing at least in their susceptibility to disruption by depolymerizing agents. Changes in microtubule orientation (induced by cytochalasin) indicate that microfilaments may be involved in regulating microtubule orientation during development.     

Structural analysis of human neutrophil migration: Centriole, microtubule, and microfilament orientation and function during chemotaxis

Orientation of nucleus, centriole, microtubules, and microfilaments within human neutrophils in a gradient of chemoattractant (5 percent Escherichia coli endotoxin-activated serum) was evaluated by electron microscopy. Purified neutropils (hypaque-Ficoll) were placed in the upper compartment of chemotactic chambers. Use of small pore (0.45 μm) micropore filters permitted pseudopod penetration, but impeded migration. Under conditions of chemotaxis with activated serum beneath the filter, the neutrophil population oriented at the filter surface with nuclei located away from the stimulus, centrioles and associated radial array of microtubules beneath the nuclei, and microfilament-rich pseudopods penetrating the filter pores. Reversal of the direction of the gradient of the stimulus (activated serum above cells) resulted in a reorientation of internal structure which preceded pseudopod formation toward the activated serum and migration off the filter. Coordinated orientation of the entire neutrophil population did not occur in buffer (random migration) or in a uniform concentration of activated serum (activated random migration). Conditions of activated random migration resulted in increased numbers of cells with locomotory morphology, i.e. cellular asymmetry with linear alignment of nucleus, centriole, microtubule array, and pseudopods. Thus, activated serum increased the number of neutrophils exhibiting locomotory morphology, and a gradient of activated serum induced the alignment of neutrophils such that this locomotory morphology was uniform in the observed neutrophil populayion. In related studies, cytochalasin B and colchicines were used to explore the role of microfilaments and microtubules in the neutrophil orientation and migration response to activated serum. Cytochalasin B (3.0 μg/ml) prevented migration and decreased the microfilaments seen, but allowed normal orientation of neutrophil structures. In an activated serum gradient, colchicines, but not lumicolchicine, decreased the orientation of nuclei and centrioles, and caused a decrease in centriole-associated microtubules in concentrations as low as 10(-8) to 10(-7) M. These colchicines effects were associated with the rounding of cells and impairment of pseudopod formation. The impaired pseudopod formation was characterized by an inability to form pseudopods in the absence of a solid substrate, a formation of narrow pseudopods within a substrate, and a defect in pseudopod orientation in an activated serum gradient. Functional studies of migration showed that colchicines, but not lumicolchicine, minimally decreased activated random migration and markedly inhibited directed migration, but had not effect on random migration. These studies show that, although functioning microfilaments are probably necessary for neutrophil migration, intact microtubules are essential for normal pseudopod formation and orientation, and maximal unidirectional migration during chemotaxis.     

Centrioles in the cell cycle. I. Epithelial cells

A study was made of the structure of the centrosome in the cell cycle in a nonsynchronous culture of pig kidney embryo (PE) cells. In the spindle pole of the metaphase cell there are two mutually perpendicular centrioles (mother and daughter) which differ in their ultrastructure. An electron-dense halo, which surrounds only the mother centriole and is the site where spindle microtubules converge, disappears at the end of telophase. In metaphase and anaphase, the mother centriole is situated perpendicular to the spindle axis. At the beginning of the G1 period, pericentriolar satellites are formed on the mother centriole with microtubules attached to them; the two centrioles diverge. The structures of the two centrioles differ throughout interphase; the mother centriole has appendages, the daughter does not. Replication of the centrioles occurs approximately in the middle of the S period. The structure of the procentrioles differs sharply from that of the mature centriole. Elongation of procentrioles is completed in prometaphase, and their structure undergoes a number of successive changes. In the G2 period, pericentriolar satellites disappear and some time later a fibrillar halo is formed on both mother centrioles, i.e., spindle poles begin to form. In the cells that have left the mitotic cycle (G0 period), replication of centrioles does not take place; in many cells, a cilium is formed on the mother centriole. In a small number of cells a cilium is formed in the S and G2 periods, but unlike the cilium in the G0 period it does not reach the surface of the cell. In all cases, it locates on the centriole with appendages. At the beginning of the G1 period, during the G2 period, and in nonciliated cells in the G0 period, one of the centrioles is situated perpendicular to the substrate. On the whole, it takes a mature centriole a cycle and a half to form in PE cells.