Plant nuclei can contain extensive grooves and invaginations

Plant cells can exhibit highly complex nuclear organization. Through dye-labeling experiments in untransformed onion epidermal and tobacco culture cells and through the expression of green fluorescent protein targeted to either the nucleus or the lumen of the endoplasmic reticulum/nuclear envelope in these cells, we have visualized deep grooves and invaginations into the large nuclei of these cells. In onion, these structures, which are similar to invaginations seen in some animal cells, form tubular or planelike infoldings of the nuclear envelope. Both grooves and invaginations are stable structures, and both have cytoplasmic cores containing actin bundles that can support cytoplasmic streaming. In dividing tobacco cells, invaginations seem to form during cell division, possibly from strands of the endoplasmic reticulum trapped in the reforming nucleus. The substantial increase in nuclear surface area resulting from these grooves and invaginations, their apparent preference for association with nucleoli, and the presence in them of actin bundles that support vesicle motility suggest that the structures might function both in mRNA export from the nucleus and in protein import from the cytoplasm to the nucleus.     

Overexpression of cofilin stimulates bundling of actin filaments, membrane ruffling, and cell movement in Dictyostelium

Cofilin is a low molecular weight actin-modulating protein whose structure and function are conserved among eucaryotes. Cofilin exhibits in vitro both a monomeric actin-sequestering activity and a filamentous actin-severing activity. To investigate in vivo functions of cofilin, cofilin was overexpressed in Dictyostelium discoideum cells. An increase in the content of D. discoideum cofilin (d-cofilin) by sevenfold induced a co-overproduction of actin by threefold. In cells over-expressing d-cofilin, the amount of filamentous actin but not that of monomeric actin was increased. Overexpressed d-cofilin co-sedimented with actin filaments, suggesting that the sequestering activity of d- cofilin is weak in vivo. The overexpression of d-cofilin increased actin bundles just beneath ruffling membranes where d-cofilin was co- localized. The overexpression of d-cofilin also stimulated cell movement as well as membrane ruffling. We have demonstrated in vitro that d-cofilin transformed latticework of actin filaments cross-linked by alpha-actinin into bundles probably by severing the filaments. D. discoideum cofilin may sever actin filaments in vivo and induce bundling of the filaments in the presence of cross-linking proteins so as to generate contractile systems involved in membrane ruffling and cell movement.     

The central role of septa in the basidiomycete Schizophyllum commune hyphal morphogenesis

The purpose of the present research was to observe in the filamentous basidiomycete Schizophyllum commune, the connection between the nuclear division and polymerization of the contractile actin ring with subsequent formation of septa in living hyphae. The filamentous actin was visualized using Lifeact-mCherry and the nuclei with EGFP tagged histone 2B (H2B). Time-lapse fluorescence microscopy confirmed that in monokaryotic and dikaryotic hyphae, the first signs of the contractile actin ring occur at the site of the nuclear division, in one to two minutes after division. At this stage, the telophase nuclei have moved tens of micrometers from the division site. The actin ring is replaced by the septum in six minutes. The apical cells treated with filamentous actin disrupting drug latrunculin A, had swollen tips but the cells were longer than in control samples due to the absence of the actin rings. The nuclear pairing and association with clamp cell development as well as the clamp cell fusion with the subapical cell was disrupted in latrunculin-treated dikaryotic hyphae, indicating that actin filaments are involved in these processes, also regulated by the A and B mating-type genes. This suggests that the actin cytoskeleton may indirectly be a target for mating-type genes.     

Characterization of filaments within the subacrosomal space of rat spermatids during spermiogenesis

Two types of filaments were observed within the subacrosomal space of rat spermatids. The first of these types was characterized as actin by demonstration of actin filament affinity for myosin S-1 subfragments. Actin filaments were noted in the subacrosomal space shortly after the acrosomal sac made contact with the nucleus. As the acrosome increased its surface area contact with the spermatid nucleus, the number of layers of subacrosomal filaments increased. Pre-treatment with detergent, which in addition to permeablizing cells to allow entry of S-1, also caused the acrosome to vesiculate and the subacrosomal space to widen. In such preparations filaments were more easily visualized and appeared to extend between the nuclear and acrosomal membranes, indicating, but not proving, attachment to these membranes. During spermatid clongation, the number of actin filaments in the subacrosomal space increased greatly, especially over the dorsal convex region of the spermatid head. The polarity of the majority of filaments was not ascertainable since filaments were tightly packed within the narrow subacrosomal space. In late spermiogenesis (steps 18 and 19), actin filaments were no longer detected within the subacrosomal space. A second and much thicker type of filamentous structure was observed in the subacrosomal space of spermatids at steps 14-17 of spermiogenesis. About 14 nm in diameter (10-15 nm measurement range depending on fixation protocol utilized), these filaments did not decorate with myosin S-1 subfragments and were found in subacrosomal regions not containing actin. Fourteen nanometer filaments were seen in parallel array along the ventral folded portion of the nuclear membrane and extended partially around the nucleus. Like actin filaments. 14 nm filaments were not seen in the subacrosomal space during late spermiogenesis.     

The 3' terminal sequence of chicken ovalbumin messenger RNA and its comparison with other messenger RNA molecules.

The subcellular distribution of actin in embryonic chick fibroblasts and brain was examined biochemically. Several gentle extraction procedures, which did not cause the breakdown of muscle filamentous actin, caused the release of large amounts of “cytoplasmic actin” in a monomeric form. This did not behave as a precursor or degradation product of filamentous actin in pulse label experiments and failed to form filaments under the same conditions as muscle actin. However, when it was purified and concentrated it was able to form aggregates which were very similar to paracrystals of muscle filamentous actin. These results suggest that cytoplasmic actin is at a higher concentration than muscle actin before it will polymerize, and that in the cell much of it is either monomeric or in a labile state.     

3T3 cells have nuclear invaginations containing F-actin

Nuclear envelope invaginations occur in many kinds of cell. Double-labeling of 3T3 cells with Hoechst 33342 strain for DNA and phalloidin-rhodamine for F-actin, show that some nuclei appear to contain tangled knots of F-actin. Concanavalin A-fluorescein staining for membranes shows that the knots are continuations of the nuclear envelope. Although they contain F-actin, the knots appear by electron microscopy to be cytoplasmic invaginations lacking microfilaments. Since we have shown previously that nuclear-membrane associated actin forms perinuclear shells in 3T3 cells, we propose that nuclear knots also are composed of actin associated with the nuclear membrane. 3T3 nuclei also contain nuclear invaginations of a second kind. These invaginations lie perpendicular to the first type and lack F-actin.     

pH Change in Culture Medium Induces Reorganization of Intranuclear Actin in Two-Cell Mouse Embryos

Actin is a permanent component of the cell nucleus involved in many nuclear processes. However, some nuclear functions of actin remain insufficiently explored. The role played by various extracellular stimuli in regulation of nuclear actin still remains enigmatic. Deviation of basic parameters of culture medium from optimal values is a member of the group of extracellular stimuli that are very important for mammalian embryos cultured in vitro. Change in culture medium pH from the level optimal for embryo homeostasis is one such signals. The purpose of this study was to investigate the intranuclear actin distribution in nuclei of two-cell mouse embryos under stress conditions induced by changes in extracellular pH. The pattern of actin localization has been tracked after short-term culturing of the embryos at optimal (pH 7.2), increased (pH 7.8), or decreased (pH 6.5) pH conditions. Analysis was carried out with confocal microscopy using methods of direct fluorescent and indirect immunofluorescent identification of actin. It has been shown that the change of culture medium pH from the optimum value is the signal that alters intranuclear actin distribution in nuclei of the embryonic cells. Culture of two-cell mouse embryos in suboptimal pH conditions (pH 6.5 and pH 7.8) induced alterations in the intranuclear actin localization, which, in particular, were expressed in accumulation of monomeric actin and the appearance of phalloidin-stainable actin in the nuclei. These changes, in our opinion, show some signs of similarity with stress-induced changes in nuclear-actin distribution, which, as has been reported earlier by a number of researchers, have been observed in the nuclei of somatic cells.     

Autoregulation of actin synthesis responds to monomeric actin levels

Regulation of the assembly and expression of actin is of major importance in diverse cellular functions such as motility and adhesion and in defining cellular and tissue architecture. These biological processes are controlled by changing the balance between polymerized (F) and soluble (G) actin. Previous studies have indicated the existence of an autoregulatory pathway that links the state of assembly and expression of actin, resulting in the reduction of actin synthesis after actin filaments are depolymerized. We have employed the marine toxins swinholide A and latrunculin A, both disrupting the organization of the actin-cytoskeleton, to determine whether this autoregulatory response is activated by a decrease in the level of polymerized actin or by an increase in monomeric actin concentrations in the cell. We showed that in cells treated with swinholide A the level of filamentous actin is decreased, and using a reversible cross-linking reagent, we found that actin dimers are formed. Latrunculin A also disassembled actin filaments, but produced monomeric actin, followed by a reduction in actin and vinculin expression, while swinholide A treatment elevated the synthesis of these proteins. In cells treated with both latrunculin A and swinholide A, dimeric actin was formed, and actin and vinculin synthesis were higher than in control cells. These results suggest that the substrate that confers an autoregulated reduction in actin expression is monomeric actin, and when its level is decreased by dimeric actin formation, actin synthesis is increased. J. Cell. Biochem. 65:469–478. © 1997 Wiley-Liss Inc.     

Tracking down the different forms of nuclear actin

Actin is a rather uncommitted protein with a high degree of structural plasticity: it can adopt a variety of structural states, depending on the specific ionic conditions or the interaction with ligand proteins. These interactions lock actin into a distinct conformation, which specifies the oligomeric or polymeric form it can assume. The interplay between monomeric, oligomeric and polymeric forms is used by the cell to execute an enormous variety of motility processes, such as lamellipodium formation during locomotion or intracellular transport of vesicles. In these cytoplasmic events, monomeric G-actin and filamentous F-actin are the prevalent forms. However, there might be other structural states of actin in cells that have so far not received the attention they deserve. Here, we propose that specific, "unconventional" actin conformations might contribute especially to the multitude of functions executed by actin in the nucleus. We present evidence for the existence of different forms of nuclear actin, taken from studies with selected antibodies.     

Actin filaments line up acrossTradescantia epidermal cells,anticipating wound-induced divison planes

Summary This paper describes the role of actin filaments in setting up the phragmosome — the transvacuolar device that anticipates the division plane — and in forming a supracellular system that seems to override cell boundaries. Tradescantia leaf epidermal cells were induced to divide by wounding the leaf. New division planes formed parallel to slits, and encircled puncture wounds — the new division planes lining up across cells, instead of the joints being off-set as in normal, unwounded tissue. Within 30 min after wounding, rhodamine phalloidin staining showed that a belt of fine, cortical actin filaments formed parallel to the wound. In the next stage, migration of nuclei to a wall adjacent to the wound, involved pronounced association of actin filaments with the nucleus. Migration could be inhibited with cytochalasin D, confirming the role of actin in traumatotaxis. Later still, actin strands were seen to line up from cell to cell, parallel to the wound, anticipating the future division plane. Next, actin filaments accumulated in this anticlinal plane, throughout the depth of the cell, thereby contributing to the formation of the phragmosome. The phragmosome has been shown in previous work (Flanders et al. 1990) to contain microtubules that bridge nucleus to cortex, and is now found to contain actin filaments. Actin filaments are therefore involved in the key stages of nuclear migration and division plane alignment. The supracellular basis of actin alignment is discussed.Dedicated to the memory of Professor Oswald Kiermayer     

Actin filaments responsible for the location of the nucleus in the lentil statocyte are sensitive to gravity

The location of the nucleus in statocytes or lentil roots grown: 1), at 1 g on the ground, 2), on a 1 g centrifuge in space, 3), in simulated microgravity on a slowly rotating clinostat (0.9 rmp) 4), in microgravity in space was investigated and statistically evaluated. In cells differentiated at 1 g on the ground, the nuclear membrane was almost in contact with the plasmalemma lining the proximal cell wall, whereas in statocytes of roots crown on the clinostat there was a distance of 0.47 micrometers (horizontal clinorotation) and or 0.76 micrometers (vertical clinorotation) between these membranes. However, in microgravity the nucleus was the most displaced, 0.87 micrometers from the proximal cell wall. Centrifugation of vertically grown roots in the root-tip direction showed that the threshold of centrifugal force to detach all nuclei from the proximal cell wall was about 40 g. In statocytes developed in the presence of cytochalasin B at 1 g the nuclei were sedimented on the amyloplasts at the distal cell pole, demonstrating that the location of the nucleus depends on actin filaments. The results obtained are in agreement with the hypothesis that gravity causes a tension of actin filaments and that this part of the cytoskeleton undergoes a relaxation in microgravity.     

Formation of long and winding nuclear F-actin bundles by nuclear c-Abl tyrosine kinase

The non-receptor-type tyrosine kinase c-Abl is involved in actin dynamics in the cytoplasm. Having three nuclear localization signals (NLSs) and one nuclear export signal, c-Abl shuttles between the nucleus and the cytoplasm. Although monomeric actin and filamentous actin (F-actin) are present in the nucleus, little is known about the relationship between c-Abl and nuclear actin dynamics. Here, we show that nuclear-localized c-Abl induces nuclear F-actin formation. Adriamycin-induced DNA damage together with leptomycin B treatment accumulates c-Abl into the nucleus and increases the levels of nuclear F-actin. Treatment of c-Abl-knockdown cells with Adriamycin and leptomycin B barely increases the nuclear F-actin levels. Expression of nuclear-targeted c-Abl (NLS-c-Abl) increases the levels of nuclear F-actin even without Adriamycin, and the increased levels of nuclear F-actin are not inhibited by inactivation of Abl kinase activity. Intriguingly, expression of NLS-c-Abl induces the formation of long and winding bundles of F-actin within the nucleus in a c-Abl kinase activity-dependent manner. Furthermore, NLS-c-AblΔC, which lacks the actin-binding domain but has the full tyrosine kinase activity, is incapable of forming nuclear F-actin and in particular long and winding nuclear F-actin bundles. These results suggest that nuclear c-Abl plays critical roles in actin dynamics within the nucleus.     

Actin in B16 melanoma cells of differing metastatic potential : Effects of trypsin and serum

Actin is present in cells in monomeric and polymeric (filamentous) forms. Filamentous actin is distributed in Triton-soluble (cytosolic) and Triton-insoluble (cytoskeletal core) fractions. We have used the DNase 1 inhibition assay and immunofluorescence to investigate the distribution of actin in monomeric and polymeric forms in cloned B16 murine melanoma cell lines of low and high metastatic capacity. The protease trypsin caused rounding up and detachment of both cell lines within 5 min. This was associated with almost complete depolymerization of cytosolic actin filaments but the Triton-insoluble cytoskeleton was not quantitatively affected by trypsin treatment. There were quantitative differences between the clones in their response to incubation in the presence or absence of 10% serum. The highly metastatic cell line contained 35% more actin when incubated in the presence of 10% serum, almost completely distributed to the Triton-insoluble cytoskeleton, an effect not seen in the low metastatic cells.     

Intermediate filament systems are collapsed onto the nuclear surface after isolation of nuclei from tissue culture cells

Standard procedures for the biochemical isolation and purification of tissue culture cell nuclei are very similar to recently described methods for the preparation of detergent-resistant cytoskeletons. But the latter in addition to extracted nuclei contain cytoplasmic filament systems. We, therefore, investigated the distribution of these filamentous systems during nuclear isolation both by immunofluorescence microscopy and by SDS-gel electrophoresis. The intermediate filaments copurify with each single isolated nucleus. The majority of the filaments is collapsed onto isolated nuclei and still constitutes a filamentous system. This can be shown by partially unfolding the collapsed filament systems.     

Involvement of microtubules and 10-nm filaments in the movement and positioning of nuclei in syncytia

Previous studies (Holmes, K.V., and P.W. Choppin. J. Exp. Med. 124:501- 520; J. Cell Biol. 39:526-543) showed that infection of baby hamster kidney (BHK21-F) cells with the parainfluenza virus SV5 causes extensive cell fusion, that nuclei migrate in the syncytial cytoplasm and align in tightly-packed rows, and that microtubules are involved in nuclear movement and alignment. The role of microtubules, 10-nm filaments, and actin-containing microfilaments in this process has been investigated by immunofluorescence microscopy using specific antisera, time-lapse cinematography, and electron microscopy. During cell fusion, micro tubules and 10-nm filaments from many cells form large bundles which are localized between rows of nuclei. No organized bundles of actin fibers were detected in these areas, although actin fibers were observed in regions away from the aligned nuclei. Although colchicine disrupts microtubules and inhibits nuclear movement, cytochalasin B (CB; 20-50 microgram/ml) does not inhibit cell fusion or nuclear movement. However, CB alters the shape of the syncytium, resulting in long filamentous processes extending from a central region. When these processes from neighboring cells make contact, fusion occurs, and nuclei migrate through the channels which are formed. Electron and immunofluorescence microscopy reveal bundles of microtubules and 10-nm filaments in parallel arrays within these processes, but no bundles of microfilaments were detected. The effect of CB on the structural integrity of microfilaments at this high concentration (20 microgram/ml) was demonstrated by the disappearance of filaments interacting with heavy meromyosin. Cycloheximide (20 microgram/ml) inhibits protein synthesis but does not affect cell fusion, the formation of microtubules and 10-nm filament bundles, or nuclear migration and alignment; thus, continued protein synthesis is not required. The association of microtubules and 10-nm filaments with nuclear migration and alignment suggests that microtubules and 10-nm filaments are two components in a system which serves both cytoskeletal and force-generating functions in intracellular movement and position of nuclei.     

Cytoskeletal asymmetry in Zea mays subsidiary cell mother cells: a monopolar prophase microtubule half-spindle anchors the nucleus to its polar position

Double labeling of microtubules and actin filaments revealed that in prophase subsidiary mother cells of Zea mays a monopolar prophase microtubule "half-spindle" is formed, which lines the nuclear hemisphere distal to the inducing guard mother cell. The nuclear hemisphere proximal to the guard mother cell is lined by an F-actin cap, consisting of a cortical F-actin patch and actin filaments originating from it. The microtubules of the "half-spindle" decline from the nuclear surface and terminate to the preprophase microtubule band. After disintegration of the latter, a bipolar metaphase spindle is organized. The polar F-actin cap persists during mitosis and early cytokinesis, extending to the chromosomes and the subsidiary cell daughter nucleus. In oryzalin treated subsidiary mother cells the prophase nuclei move away from the polar site. Cytochalasin B and latrunculin-B block the polar migration of subsidiary mother cell nuclei, but do not affect those already settled to the polar position. The prophase nuclei of latrunculin-B treated subsidiary mother cells are globally surrounded by microtubules, while the division plane of latrunculin-B treated subsidiary mother cells is misaligned. The prophase nuclei of brick 1 mutant Zea mays subsidiary mother cells without F-actin patch are also globally surrounded by microtubules. The presented data show that the prophase microtubule "half-spindle"-preprophase band complex anchors the subsidiary mother cell nucleus to the polar cell site, while the polar F-actin cap stabilizes the one metaphase spindle pole proximal to the inducing guard mother cell.     

Latrunculin B or ATP depletion induces cofilin-dependent translocation of actin into nuclei of mast cells

Increasing cellular G-actin, using latrunculin B, in either intact or permeabilized rat peritoneal mast cells, caused translocation of both actin and an actin regulatory protein, cofilin, into the nuclei. The effect was not associated with an increase in the proportion of apoptotic cells. The major part of the nuclear actin was not stained by rhodamine-phalloidin but could be visualized with an actin antibody, indicating its monomeric or a conformationally distinct state, e.g. cofilin-decorated filaments. Introduction of anti-cofilin into permeabilized cells inhibited nuclear actin accumulation, implying that an active, cofilin-dependent, import exists in this system. Nuclear actin was localized outside the ethidium bromide-stained region, in the extrachromosomal nuclear domain. In permeabilized cells, the appearance of nuclear actin and cofilin was not significantly affected by increasing [Ca(2+)] and/or adding guanosine 5'-O-(3-thiotriphosphate), but was greatly promoted when ATP was withdrawn. Similarly, ATP depletion in intact cells also induced nuclear actin accumulation. In contrast to the effects of latrunculin B, ATP depletion was associated with an increase in cortical F-actin. Our results suggest that the presence of actin in the nucleus may be required for certain stress-induced responses and that cofilin is essential for the nuclear import of actin.     

Actin filaments responsible for the location of the nucleus in the lentil statocyte are sensitive to gravity

The location of the nucleus in statocytes of lentil roots grown: I), at 1 g on the ground, 2), on a 1 g centrifuge in space, 3), in simulated microgravity on a slowly rotating clinostat (0.9 rmp) 4), in microgravity in space was investigated and statistically evaluated. In cells differentiated at 1 g on the ground, the nuclear membrane was almost in contact with the plasmalemma lining the proximal cell wall, whereas in statocytes of roots grown on the clinostat there was a distance of 0.47 μm horizontal clinorotation) and of 0.76 μm vertical clinorotation) between these membranes. However, in microgravity the nucleus was the most displaced, 0.87 μm from the proximal cell wall. Centrifugation of vertically grown roots in the root-tip direction showed that the threshold of centrifugal force to detach all nuclei from the proximal cell wall was about 40 g. In statocytes developed in the presence of cytochalasin B at 1 g the nuclei were sedimented on the amyloplasts at the distal cell pole, demonstrating that the location of the nucleus depends on actin filaments. The results obtained are in agreement with the hypothesis that gravity causes a tension of actin filaments and that this part of the cytoskeleton undergoes a relaxation in microgravity.     

Distribution of microfilament bundles during rotation of the nucleus in 3T3 cells treated with monensin

Cytoskeletal aspects of monensin-treated 3T3 cells with rotating nuclei were studied by immunofluorescence. The pattern of intermediate filaments and microtubules appeared unchanged when compared with control cells having a stationary nucleus. In contrast, the actin microfilament bundles appeared to have a consistent distribution in cells with rotating nuclei. Typically, we did not find long microfilament bundles that traverse the length of the cytoplasm of cells that were fixed at the time of nuclear rotation. Instead, there was a local distribution of short microfilament bundles situated ventrally to the nucleus and oriented at various angles to one another and to the predominant distribution of microfilament bundles in the cell. The observations suggest that the actin cytoskeleton is reorganized locally before or during rotation of the nucleus.