Assessing the Cytoskeletal System and its Elements in C6 Glioma Cells and Astrocytes by Atomic Force Microscopy

Object To investigate how the characteristic structure of the cytoskeleton in glioma cells is associated with invasiveness. Methods The whole cytoskeletal system was characterized by atomic force microscopy (AFM), while single cytoskeletal elements were exhibited by AFM and using cytoskeletal protein inhibitors to inhibit microfilaments or/and microtubules and displayed by immunofluorescence microscopy. The fluorescence intensity of F-actin was measured by flow cytometry and the structural difference between C6 glioma cells and astrocytes was studied. Results Cytoskeletons in both cells presented network structures, however, the C6 glioma cells showed an irregular edge root and their microfilaments were creber and dense. Intermediate filaments were extensive network structure with non-polarized multipoint connections. The microtubules were relatively big and long and formed tight bundles with close connections between bundles. Astrocytes had a regular and smooth edge, with sparse microfilaments, while the intermediate filaments were dense and interwoven and the microtubules were dense bundled, but only loosely connected each other. Besides, the fluorescence intensity of F-actin was significantly higher in C6 glioma cells (202.54 ± 11.06) than in the astrocytes (62.64 ± 10.23), P < 0.01. Conclusion Whole cytoskeleton and its elements of C6 cells were disclosed of characteristic structures associated with invasiveness. Meanwhile, the content of F-actin could be used as a parameter for measuring cell invasiveness.     

Organization of the actin cytoskeleton during pollen development inGasteria verrucosa (Mill.) H. Duval visualized with rhodamine-phalloidin

The three-dimensional organization of the microfilamental cytoskeleton of developingGasteria pollen was investigated by light microscopy using whole cells and fluorescently labelled phalloidin. Cells were not fixed chemically but their walls were permeabilized with dimethylsulphoxide and Nonidet P-40 at premicrospore stages or with dimethylsulphoxide, Nonidet P-40 and 4-methylmorpholinoxide-monohydrate at free-microspore and pollen stages to dissolve the intine.Four strikingly different microfilamentous configurations were distinguished. (i) Actin filaments were observed in the central cytoplasm throughout the successive stages of pollen development. The network was commonly composed of thin bundles ramifying throughout the cytoplasm at interphase stages but as thick bundles encaging the nucleus prior to the first and second meiotic division. (ii) In released microspores and pollen, F-actin filaments formed remarkably parallel arrays in the peripheral cytoplasm. (iii) In the first and second meiotic spindles there was an apparent localization of massive arrays of phalloidin-reactive material. Fluorescently labelled F-actin was present in kinetochore fibers and pole-to-pole fibers during metaphase and anaphase. (iv) At telophase, microfilaments radiated from the nuclear envelopes and after karyokinesis in the second meiotic division, F-actin was observed in phragmoplasts.We did not observe rhodamine-phalloidin-labelled filaments in the cytoplasm after cytochalasin-B treatment whereas F-actin persisted in the spindle. Incubation at 4° C did not influence the existence of cytoplasmic microfilaments whereas spindle filaments disappeared. This points to a close interdependence of spindle microfilaments and spindle tubules.Based on present data and earlier observations on the configuration of microtubules during pollen development in the same species (Van Lammeren et al., 1985, Planta165, 1-11) there appear to be apparent codistributions of F-actin and microtubules during various stages of male meiosis inGasteria verrucosa.Abbreviation DMSO dimethylsulfoxide     

Rotavirus Infection of Cells in Culture Induces Activation of RhoA and Changes in the Actin and Tubulin Cytoskeleton

Rotavirus infection induces an increase in [Ca²⁺]_cyto, which in turn may affect the distribution of the cytoskeleton proteins in the infected cell. Changes in microfilaments, including the formation of stress fibers, were observed starting at 0.5 h.p.i. using fluorescent phalloidin. Western blot analysis indicated that RhoA is activated between 0.5 and 1 h.p.i. Neither the phosphorylation of RhoA nor the formation of stress fibers were observed in cells infected with virions pre-treated with an anti-VP5* non-neutralizing mAb, suggesting that RhoA activation is stimulated by the interaction of the virus with integrins forming the cell receptor complex. In addition, the structure of the tubulin cytoskeleton was also studied. Alterations of the microtubules were evident starting at 3 h.p.i. and by 7 h.p.i. when microtubules were markedly displaced toward the periphery of the cell cytoplasm. Loading of rotavirus-infected cells with either a Ca²⁺ chelator (BAPTA) or transfection with siRNAs to silence NSP4, reversed the changes observed in both the microfilaments and microtubules distribution, but not the appearance of stress fibers. These results indicate that alterations in the distribution of actin microfilaments are initiated early during infection by the activation of RhoA, and that latter changes in the Ca²⁺ homeostasis promoted by NSP4 during infection may be responsible for other alterations in the actin and tubulin cytoskeleton.     

Microtubule stability affects the unique motility of F-actin in Marchantia polymorpha

Actin microfilaments play crucial roles in diverse plant functions. Some specific cellular processes require interaction between F-actin and microtubules, and it is believed that there are direct or indirect connections between F-actin and microtubules. We previously reported that actin microfilaments exhibit unique dynamic motility in cells of the liverwort, Marchantia polymorpha; the relevance of this activity to microtubules has not been explored. To examine whether the dynamics of F-actin in M. polymorpha were somehow regulated by microtubules, we investigated the effects of stabilization or destabilization of microtubules on dynamics of actin bundles, which were visualized by Lifeact-Venus. To our surprise, both stabilization and destabilization of microtubules exerted similar effects on F-actin motility; apparent sliding movement of F-actin in M. polymorpha cells was accelerated by both oryzalin and paclitaxel, with the effect of paclitaxel more evident than that of oryzalin. Immunofluorescence staining revealed that some F-actin bundles were arrayed along with microtubules in M. polymorpha thallus cells. These results suggest that microtubules play regulatory roles in the unique F-actin dynamics in M. polymorpha.     

The involvement of F-actin inUromyces cell differentiation: The effects of cytochalasin E and phalloidin

Summary The role of F-actin in cell differentiation ofUromyces appendiculatus (bean rust fungus) germlings was examined by treating differentiating and nondifferentiating germlings with the actin-binding drugs cytochalasin E (CE) and phalloidin. Prolonged exposure of urediospores to 5×10^–3–5 × 10^–5 M CE induced nuclear division in up to 28–45% of the resulting germlings, whereas the rate of mitosis in established germlings exposed to these concentrations of CE was significantly lower (4–11%). Germlings treated with CE shifted from polarized apical growth to spherical expansion, cytoplasmic microfilaments were depolymerized, and nuclear inclusions became enlarged. Differentiating germlings exposed to a 10 minute pulse of 5×10^–6M CE before the initiation of septum formation prevented the establishment of the F-actin septal ring and growth of the crosswall delimiting the appressorium. Although these CE treatments resulted in morphological and nuclear events similar to those occurring during normal appressorium formation, transient microfilament depolymerization was not sufficient to induce differentiation. Phalloidin stabilized cytoplasmic microfilaments, especially posteriorly-located microfilaments, but did not affect differentiation, nor did it significantly inhibit the effects of CE.Abbrevations CE cytochalasin E - DAPI 4,6-diamidino-2-phenylindole - DMSO dimethyl sulfoxide - F-actin filamentous actin     

Selective extraction of cotton fiber cytoplasts to identify cytoskeletal-associated proteins

Cytoplasts from cotton (Gossypium hirsutum L.) fiber cells retain microtubule and microfilament cytoskeletons through extraction with non-ionic detergent and ethylene glycol bis-(β-aminoethyl ether) N,N,N',N'-tetraacetic acid. Tubulin and actin are the most abundant proteins in extracted cytoplasts; however, many other less abundant proteins are also present. To determine if minor proteins were associated with the cytoskeleton, microtubules and microfilaments were selectively removed from extracted cytoplasts by detergent extraction in an alkaline Ca²⁺ solution. Under these extraction conditions, microtubules and microfilaments were fragmented and depolymerized unless previously stabilized by taxol and phalloidin. Associated proteins were identified by their loss in conjunction with either microtubules or microfilaments. As judged by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, one protein, of roughly 115 kDa, appeared to be associated with microfilaments since it was present in Ca²⁺-extracted preparations only when microfilaments were stabilized with phalloidin. The failure of most minor proteins to associate with microtubules and microfilaments suggests that caution must be used when interpreting co-isolation as evidence for an association of low abundance proteins with cytoskeletons.     

Cortical microtubules and cortical microfilaments in the green alga,Micrasterias pinnatifida

Summary Cortical microtubules and cortical microfilaments were visualized in cells ofMicrasterias pinnatifida treated by freeze-substitution, and the pattern of their distribution was reconstructed from serial sections. Most cortical microtubules accompanied the long microfilaments that ran parallel to the microtubules. Cortical microfilaments not accompanied by the microtubules were also found. They were short and slightly curved. Both types of cortical microfilament were not grouped into bundles, and were 6–7 nm in diameter, a value that corresponds to the diameter of filaments of F-actin.     

FLUORESCENT LABELLING OF THE CYTOSKELETON IN CERAMIUM STRICTUM (RHODOPHYTA)1,2

Using rhodamine-phalloidin to detect F-actin/microfilaments and indirect immunofluorescence to detect tubulin/microtubules, we studied the cytoskeleton in axial cells of Ceramium strictum Harv., especially microfilaments and microtubules associated with cytoplasmic strands (trabeculae) that extend longitudinally through the central vacuole. As axial cells attained mature size, trabeculae became progressively thinner, branched, and then broke down. An extensive microfilament array was present in peripheral parts of axial cells as well as in trabeculae. Microfilament arrays were highly disrupted by cytochalasin-B; this resulted in small irregular actin structures in axial cell peripheries and occasional dense aggregations at the base of cells. No actin-fluorescence was detected in intact trabeculae after cytochalasin-B treatment. Microtubules formed a primary structural component in trabeculae, which were disrupted by griseofulvin (5 to 0.005 μM) but reformed after two days in griseofulvin-free medium.     

F-actin network may regulate a Cl− channel in renal proximal tubule cells

A variety of mechanisms have been proposed for the regulation of ion channel molecules. As integral membrane proteins, ion channels may interact with the cytoskeleton. Regulation of channels by the actin network may therefore be important. In the present study we used cytochalasin D and exogenous actin to test this possibility. The Cl^– channel of the apical membrane of renal proximal epithelium was detected in its active state after prolonged depolarization. Within 6 sec after its addition, cytochalasin D (0.05 g/ml) significantly decreased the number of open channels and mean open probability (NPo) of the Cl^– channel. Colchicine (1 mm), which affects microtubules, did not influence channel activation. Cytochalasin D is known to not only disrupt the F-actin network but to inhibit polymerization of F-actin as well. The latter effect is also produced by DNaseI. Cytochalasin D, but not DNaseI, inactivated Cl^– channels in cell-free membrane patches, suggesting that cytochalasin D inactivated the channel by disrupting the actin network. Cytochalasin D appeared to specifically affect the channel, as opposed to membrane permeability, since only the activated whole-cell Cl^– currents were altered by cytochalasin D. Addition of actin polymer, but not actin monomer, reactivated the cytochalasin-D-depressed channel. Thus, repair of the disrupted F-actin network with actin polymer apparently restored the activity and number of open Cl^– channels. We therefore conclude that the F-actin network interacts with and possibly regulates the Cl^– channel of renal proximal tubule epithelia.We would like to thank T. Tamatsukuri for technical support. This study was presented to the American Society of Nephrology, Baltimore, 1991.     

Physiological oxygen tension modulates the chemically induced mitogenic response of cultured rat hepatocytes

Freshly isolated rat hepatocytes were cultured at periportal- (13% O₂) or perivenous-like (4% O₂) oxygen tension and exposed to subtoxic exposure levels of cyproterone acetate (CPA: 10–330 μM), phenobarbital (PB: 0.75-6 mM), and dimethylsulfoxide (DMSO: 0.1–3.3%) from 24–72 h after seeding. Induced alterations in ploidy, in the number of S-phase cells, the degree of binuclearity, and cellular protein content were determined by twin parameter protein/DNA flow cytometry analysis of intact cells and isolated nuclei. CPA and PB increased whereas DMSO decreased dose dependently the total number of S-phase cells. The changes differed within individual ploidy classes and were modulated by the oxygen tension. CPA increased and DMSO decreased the number of S-phase cells preferentially among the diploid hepatocytes at periportal-like oxygen tension. In contrast, PB increased binuclearity and S-phase cells mainly among the tetraploid hepatocytes at perivenous-like oxygen tension. Cellular protein content increased dose dependently after exposure to the hepatomitogens (CPA, PB) and decreased after exposure to DMSO at both oxygen tensions. Comparison with in vitro data proves that chemicals which interact with cells from the progenitor liver compartment (CPA, DMSO) exert their mitogenic activity best in cultures at periportal-like oxygen tension preferentially in diploid hepatocytes, whereas chemicals which affect cells from the functional compartment show a higher activity at perivenous-like oxygen tension. Physiological oxygen tension seems to be an effective modulator of the proliferative response of cultured rat hepatocytes similar to that expected for periportally or perivenously derived hepatocytes. © 1993 Wiley-Liss, Inc.     

Morphological evidence for the existence of a more complex cytoskeleton in Amoeba proteus

Summary Various stabilization and extraction procedures were tested to demonstrate the ultrastructural organization of the cytoskeleton in normal, locomoting Amoeba proteus. Most reliable results were obtained after careful fixation in glutaraldehyde/lysine followed by prolonged extraction in a polyethylene glycol/Triton X-100 solution. Before dehydration in a graded series of ethanol and critical-point drying, the amoebae were split by the sandwich-technique, i.e., by mechanical cleavage of cells mounted between two poly-L-lysine-coated glass slides. Platinum-carbon replicas as well as thin sections prepared from such cell fragments revealed a cytoskeleton composed of at least four different types of filaments: (1) 5–7-nm filaments organized as a more or less ordered cortical network at the internal face of the plasma membrane and probably representing F-actin; (2) 10–12-nm filaments running separately or slightly aggregated through the cytoplasm and probably representing intermediate filaments; (3) 24–26-nm filaments forming a loose network and probably representing microtubules; and (4) 2–4-nm filaments as connecting elements between the other cytoskeleton constituents. Whereas microfilaments are responsible for protoplasmic streaming and other motile phenomena, the function of intermediate filaments and cytoplasmic microtubules in amoebae is still obscure.     

The cytoskeleton of the fiber cells of Trichoplax adhaerens (Placozoa)

Summary The cytoskeleton of Trichoplax adhaerens fiber cells was studied after chemical fixation, freeze-substitution, lysis of attached cells with nonionic detergents and by immunofluorescence. Cytoskeletal elements present in the cell bodies and reaching into the extensions include microtubules, intermediate filaments, 6–7 nm and 2–3 nm microfilaments. The latter seem to interconnect other cytoskeletal elements. Actin-like microfilaments are found both as networks and parallel strands. Immunofluorescence with antiactin shows the presence of actin in the cell body, underneath the plasmalemma and within the extensions. Both the results of immunofluorescence and the identification of 6–7 nm actin-like microfilaments support the concept of contractility of the fiber cells as the cause of the rapid shape changes of Trichoplax. Anti-tubulin fluorescence corresponds to the location of microtubules in the extensions as well as the cell bodies of the fiber cells. The extensions are withdrawn upon depolymerization of the microtubules by colchicine.     

Differential Responses of Cultured MC3T3-E1 Cells to Dynamic and Static Stimulated Effect of Microgravity in Cell Morphology,Cytoskeleton Structure and Ca²⁺ Signaling

Random positioning machine (RPM) and diamagnetic levitation are two essential ground-based methods used to stimulate the effect of microgravity in space life science research. However, the force fields generated by these two methods are fundamentally different, as RPM generates a dynamic force field acting on the surface in contact with supporting substrate, whereas diamagnetic levitation generates a static force field acting on the whole body volume of the object (e.g. cell). Surprisingly, it is hardly studied whether these two fundamentally different force fields would cause different responses in mammalian cells. Thus we exposed cultured MC3T3-E1 osteoblasts to either dynamically stimulated effect of microgravity (d-µg) with RPM or statically stimulated effect of microgravity (s-µg) with diamagnetic levitation, respectively, for 3 h. Subsequently, the cells were examined for changes in cell morphology, cytoskeleton (CSK) structure and Ca²⁺ signaling. The results show that compared to the condition of normal gravity (1g), both d-µg and s-µg resulted in decrease of cell area and disruption of the microfilaments and microtubules in MC3T3-E1 cells, but cells under d-µg were more smooth and round while those under s-µg exhibited more protrusions. The decrease of cell area and disruption of microfilaments and microtubules induced by d-µg but not s-µg were rescued by inhibition of the stretch-activated channel by gadolinium chloride (Gd). Inhibition of calmodulin (CaM) by inhibitor, W-7, promoted the effects of s-µg on cell area and CSK filaments, but inhibition of calmodulin-dependent protein kinase (CaMK) by inhibitor, KN-93, weakened d-µg-induced effects on cell area and cytoskeleton. In addition, both d-µg and s-µg decreased the CaM expression and CaMKⅡ activity in MC3T3-E1 cells. Furthermore, s-µg resulted in decrease of the intracellular free Ca²⁺ concentration ([Ca²⁺]_i) in MC3T3-E1 cells, which was reversed by disrupting microfilaments with cytochalasin B (CytB). Instead, d-µg induced increase of [Ca²⁺]_i, which was inhibited by Gd. Taken together these data suggest that dynamic and static stimulated microgravity cause different responses in MC3T3-E1 cells. The dynamic force field acts on stretch-activated channels to induce microfilaments disruption and Ca²⁺ influx in MC3T3-E1 cells whereas the static force field directly induces microfilament disruption, which in turn decreases the [Ca²⁺]_i in MC3T3-E1 cells. Such findings may have important implications to better understanding microgravity related cellular events and their applications.     

The Type II Arabidopsis Formin14 Interacts with Microtubules and Microfilaments to Regulate Cell Division

Formins have long been known to regulate microfilaments but have also recently been shown to associate with microtubules. In this study, Arabidopsis thaliana FORMIN14 (AFH14), a type II formin, was found to regulate both microtubule and microfilament arrays. AFH14 expressed in BY-2 cells was shown to decorate preprophase bands, spindles, and phragmoplasts and to induce coalignment of microtubules with microfilaments. These effects perturbed the process of cell division. Localization of AFH14 to microtubule-based structures was confirmed in Arabidopsis suspension cells. Knockdown of AFH14 in mitotic cells altered interactions between microtubules and microfilaments, resulting in the formation of an abnormal mitotic apparatus. In Arabidopsis afh14 T-DNA insertion mutants, microtubule arrays displayed abnormalities during the meiosis-associated process of microspore formation, which corresponded to altered phenotypes during tetrad formation. In vitro biochemical experiments showed that AFH14 bound directly to either microtubules or microfilaments and that the FH2 domain was essential for cytoskeleton binding and bundling. However, in the presence of both microtubules and microfilaments, AFH14 promoted interactions between microtubules and microfilaments. These results demonstrate that AFH14 is a unique plant formin that functions as a linking protein between microtubules and microfilaments and thus plays important roles in the process of plant cell division.     

Effects of four agents that modify microtubules and microfilaments (vinblastine,colchicine, lidocaine,and cytochalasin B) on macrophage-mediated cytotoxicity to tumor cells

Summary The effects of vinblastine, colchicine, lidocaine, and cytochalasin B on tumor cell killing by BCG-activated macrophages were examined. These four drugs were selected for their action on membrane-associated cytoskeletal components, microtubules, and microfilaments. Colchicine and vinblastine, which block microtubular synthesis, inhibit macrophage-mediated tumor-cell cytotoxicity at a concentration of 10^–6 M. Cytochalasin B, which disrupts microfilaments, enhances tumor cell lysis and stasis due to activated macrophages at a concentration of 10^–7 M. Lidocaine, which may induce the disappearance of both microtubules and microfilaments, has the same inhibiting effect as vinblastine at a concentration of 5×10^–7 M. Whereas vinblastine and lidocaine seem to act on the macrophage itself, cytochalasin B exerts its effect predominantly on the tumor cell. These results suggest that microtubules and microfilaments play a role in the destruction of tumor cells by activated macrophages.     

The dynamics of the actin cytoskeleton during sporogenesis in Psilotum nudum L.

The actin cytoskeleton (microfilaments, MFs) accompanies the tubulin cytoskeleton (microtubules) during the meiotic division of the cell, but knowledge about the scope of their physiological competence and cooperation is insufficient. To cast more light on this issue, we analysed the F-actin distribution during the meiotic division of the Psilotum nudum sporocytes. Unfixed sporangia of P. nudum were stained with rhodamine-phalloidin and 4′,6-diamidino-2-phenylindole dihydrochloride, and we monitored the changes in the actin cytoskeleton and nuclear chromatin throughout sporogenesis. We observed that the actin cytoskeleton in meiotically dividing cells is not only part of the kariokinetic spindle and phragmoplast but it also forms a well-developed network in the cytoplasm present in all phases of meiosis. Moreover, in telophase I F-actin filaments formed short-lived phragmoplast, which was adjacent to the plasma membrane, exactly at the site of future cell wall formation. Additionally, the meiocytes were pre-treated with cytochalasin-B at a concentration that causes damage to the MFs. This facilitated observation of the effect of selective MFs damage on the course of meiosis and sporogenesis of P. nudum. Changes were observed that occurred in the cytochalasin-treated cells: the daughter nuclei were located abnormally close to each other, there was no formation of the equatorial plate of organelles and, consequently, meiosis did not occur normally. It seems possible that, if the actin cytoskeleton only is damaged, regular cytokinesis will not occur and, hence, no viable spores will be produced.     

Requirement for specific protein kinase activities during the rapid redistribution of F-actin that precedes the outgrowth of neurites in PC12D cells.

Rapid changes in morphology of PC12D cells, a subline of PC12 cells, in response to various agents were studied in relation to the subsequent outgrowth of neurites. A few minutes after addition of NGF or of dbcAMP, staining of F-actin with rhodamine phalloidin revealed the formation of ruffles around the periphery of cells. Simultaneous relocalization of F-actin to the area of ruffles occurred in response to NGF. A moderate relocalization of F-actin occurred in dbcAMP-treated cells. Other neurite-promoting agents on PC12D cells, such as bFGF, EGF and PMA, also caused ruffling and an identical redistribution of F-actin. The actin bundles then condensed into several dot-like aggregates that subsequently became the growth cones of neurites. When an inhibitor of protein kinase, K-252a, was added, only the NGF-induced morphological change was selectively decreased. By contrast, an inhibitor of protein kinase A, H-89, selectively blocked the dbcAMP-induced change. These are analogous to the effects of those inhibitors on the outgrowth of neurites. These observations indicate that the formation of ruffles with the redistribution of F-actin might be one of the earliest steps in the neurite outgrowth and that the morphological changes might be triggered by the activation of specific protein kinases. Neither cytochalasin B nor colchicine prevented the series of morphological changes. However, processes formed in the presence of cytochalasin B had no filopodium and protrusions formed in the presence of colchicine were shaped like large filopodia. It appears that microtubules and microfilaments may not be absolutely required for the initiation of the rapid morphological changes, but that complete neurites might be formed with contribution by microtubules and by microfilaments.     

Fluid Shear Stress Upregulates E-Tmod41 via miR-23b-3p and Contributes to F-Actin Cytoskeleton Remodeling during Erythropoiesis

The membrane skeleton of mature erythrocyte is formed during erythroid differentiation. Fluid shear stress is one of the main factors that promote embryonic hematopoiesis, however, its effects on erythroid differentiation and cytoskeleton remodeling are unclear. Erythrocyte tropomodulin of 41 kDa (E-Tmod41) caps the pointed end of actin filament (F-actin) and is critical for the formation of hexagonal topology of erythrocyte membrane skeleton. Our study focused on the regulation of E-Tmod41 and its role in F-actin cytoskeleton remodeling during erythroid differentiation induced by fluid shear stress. Mouse erythroleukemia (MEL) cells and embryonic erythroblasts were subjected to fluid shear stress (5 dyn/cm²) and erythroid differentiation was induced in both cells. F-actin content and E-Tmod41 expression were significantly increased in MEL cells after shearing. E-Tmod41 overexpression resulted in a significant increase in F-actin content, while the knockdown of E-Tmod41 generated the opposite result. An E-Tmod 3’UTR targeting miRNA, miR-23b-3p, was found suppressed by shear stress. When miR-23b-3p level was overexpressed / inhibited, both E-Tmod41 protein level and F-actin content were reduced / augmented. Furthermore, among the two alternative promoters of E-Tmod, P_E0 (upstream of exon 0), which mainly drives the expression of E-Tmod41, was found activated by shear stress. In conclusion, our results suggest that fluid shear stress could induce erythroid differentiation and F-actin cytoskeleton remodeling. It upregulates E-Tmod41 expression through miR-23b-3p suppression and P_E0 promoter activation, which, in turn, contributes to F-actin cytoskeleton remodeling.     

Nuclear centering in Spirogyra: force integration by microfilaments along microtubules

The contribution of microtubules and microfilaments to the cytomechanics of transverse nuclear centering were investigated in the charophycean green alga Spirogyracrassa (Zygnematales). Cytoplasmic strands of enhanced rigidity and fasciate appearance radiate from the rim of the lenticular nucleus through the vacuole, frequently split once or twice and are attached to the helical chloroplast bands in the peripheral cytoplasm. The nucleus is encased in tubulin and a web of F-actin. Bundles of microtubules, emerging from the nuclear rim, are organized into dividing fascicles within the strands and reach to the inner surface of the chloroplast envelope. Organelles are translocated in both directions along similarly arranged fascicles of microfilament bundles which extend from the nucleus to the peripheral actin cytoskeleton. Application of microtubule- and/or microfilament-depolymerizing drugs affected the position of the nucleus only slowly, but in distinct ways. The differential effects suggest that nuclear centering depends on the tensional integrity of the perinuclear scaffold, with microfilaments conveying tension along stabilized microtubules and the actin cytoskeleton integrating the translocation forces generated within the scaffold. Received: 9 December 1996 / Accepted: 29 April 1997