Confocal Microscopy Observations on Actin Cytoskeleton in the Pollen and Pollen Protoplast of Narcissus

Actin cytoskeleton was localized in the pollen and pollen protoplast of Narcissus cyclamineus using fluorescence labelled phalloidin andconfocal microscopy. In the hydrated pollen (before germination) actin filamem bundles were arranged in a parallel array and at right angles to the long axis of the pollen grain in the cortex. But at the germination pore region(or fur row) the actin filament bundles formed a reticulate network. In the centre of the grain there was also an actin filament network which was more open and had less bundles associated with it than the network underneath the furrow. When the pollen grain started to produce pollen tube, most(if not all) of the actin filament bundles in the pollen grain rearranged into a parallel array pointing towards the tube. The bundles in the array later elongated and extended into the pollen tube. In the pollen protoplast a very tightly-packed actin bundle network was present. Numerous branches and jonts of actin filament bundles could be seen in the network. If the protoplasts were fixed before staining, the bundles aggregated and the branches and joints became less obvious indicating that fixation had affected the nature and arrangement of the actin filament bundles. If the pollen protoplasts were bursted (using the osmotic shock technique) or extracted (using Triton X-100), fragments of actin filament bundles could still be found associated with the membrane ghost indicating that some of the actin filament bundles in the cortex were tightly attached to the membrane. Using a double staining technique, actin filaments and microtubules were co-localized in the pollen protoplast. The co-alignment of some of the actin filament bundles with the microtubule bundles suggested that the actin cytoskeleton and the microtubule cytoskeleton were not distributed at random but in a well organized and orchestrated manner [possibly under the control of a yet undiscovered structure(s). The actin filament cytoskeleton in the generative cells failed to stain either in pollen or pollen tube, but they became stained in the pollen protoplast. The actin cytoskeleton in the generative cell appeared as a loosely organized network made up of short and long actin filament bundles.     

Actin Distribution in Mitotic Apparatus of Somatic Embryo Cells of Norway Spruce

F-actin distribution was studied in mitotic cells of embryogenic suspension culture of Norway spruce [Picea abies (L.) Karst.]. Actin was present in dividing cells of embryo head during whole mitosis. Transient co-localization of actin microfilaments with preprophase band of microtubules was observed. Weak actin staining occurred with non-kinetochor microtubular fibers in metaphase spindle. F-actin was not localized with kinetochore microtubular fibres in metaphase as well as with shortening kinetochore fibres in late anaphase. On the other hand, abundant actin microfilaments array was formed in the area of late anaphase spindle in equatorial level of the cell between separating chromatids. F-actin was also present in phragmoplast area in telophase. This revised version was published online in July 2006 with corrections to the Cover Date.     

Actin in the preprophase band of Allium cepa

F-actin has been identified in the preprophase band of Allium cepa. Cells attached to subbed slides were obtained from formaldehyde-fixed root tips digested in EGTA and Cellulysin. The air-dried cells were extracted in Triton X-100, treated with rhodamine-phalloidin, rinsed briefly in PBS, and viewed in the fluorescence microscope. Interphase cells contain a network of actin fibers that extends into all areas of the cytoplasm. During preprophase, the network is replaced by a band of fibers aligned in the position of the preprophase band. Colocalization of F-actin with rhodamine-phalloidin and microtubules with tubulin immunocytochemistry confirms that the two bands are coincident. The actin appears to comprise a thin layer of fibers next to the plasmalemma. Like the microtubule preprophase band, the actin band narrows as preprophase progresses and disappears by midprophase. Fluorescent actin bands are not seen in fixed cells pretreated with excess unlabeled phalloidin before staining. They are also absent in roots exposed to cytochalasins B and D before fixation, but preprophase band microtubules at all stages of aggregation are still present. Colchicine treatment leads to the loss of both preprophase band microtubules and actin. The possible function of preprophase band actin is discussed.     

Characterization and dynamics of cytoplasmic F-actin in higher plant endosperm cells during interphase, mitosis, and cytokinesis

We have identified an F-actin cytoskeletal network that remains throughout interphase, mitosis, and cytokinesis of higher plant endosperm cells. Fluorescent labeling was obtained using actin monoclonal antibodies and/or rhodamine-phalloidin. Video-enhanced microscopy and ultrastructural observations of immunogold-labeled preparations illustrated microfilament-microtubule co-distribution and interactions. Actin was also identified in cell crude extract with Western blotting. During interphase, microfilament and microtubule arrays formed two distinct networks that intermingled. At the onset of mitosis, when microtubules rearranged into the mitotic spindle, microfilaments were redistributed to the cell cortex, while few microfilaments remained in the spindle. During mitosis, the cortical actin network remained as an elastic cage around the mitotic apparatus and was stretched parallel to the spindle axis during poleward movement of chromosomes. This suggested the presence of dynamic cross-links that rearrange when they are submitted to slow and regular mitotic forces. At the poles, the regular network is maintained. After midanaphase, new, short microfilaments invaded the equator when interzonal vesicles were transported along the phragmoplast microtubules. Colchicine did not affect actin distribution, and cytochalasin B or D did not inhibit chromosome transport. Our data on endosperm cells suggested that plant cytoplasmic actin has an important role in the cell cortex integrity and in the structural dynamics of the poorly understood cytoplasm-mitotic spindle interface. F-actin may contribute to the regulatory mechanisms of microtubule-dependent or guided transport of vesicles during mitosis and cytokinesis in higher plant cells.     

Colocalization of cortical microtubules and F-actin in<Emphasis Type="Italic">Dipodascus magnusii</Emphasis> using confocal laser scanning microscopy

Distribution of microtubules and F-actin in aerobically growing cells of Dipodascus magnusii, belonging to the class Saccharomycetes was analyzed using immunofluorescence microscopy and labeling with rhodamine-tagged phalloidin. A conspicuous system of permanent cytoplasmic microtubules was observed in association with multiple nuclei. In elongating cells, helices of cytoplasmic microtubules appeared at the cell cortex. In cells approaching cytokinesis transversely oriented microtubules were revealed at incipient division sites. Confocal laser scanning microscopy showed a continuity of these transverse microtubules with the remaining microtubule network. The actin system of D. magnusii consisted of patches and filaments. Patches were found to accumulate at the tips of growing cells. Bands of fine actin filaments were usually observed before F-actin rings were established. A close cortical association of microtubules with the F-actin ring was documented on individual optical sections of labeled cells. Cells with developing septa showed medial F-actin discs associated at both sides with microtubules. Colocalization of cytoplasmic microtubules with actin filaments at the cortex of dividing cells supports a role of both cytoskeletal components in controlling cell wall growth and septum formation in D. magnusii.     

Accumulation of F-actin during cytokinesis inAllium. Correlation with microtubule distribution and the effects of drugs

Summary The distribution of F-actin in the phragmoplast/cell plate complex of formaldehyde-fixedAllium root cells was visualized with rhodaminephalloidin (RP). Increased RP fluorescence appears in late anaphase in a broad zone between separating chromosomes. The fluorescence is mostly amorphous in appearance and does not resemble the distinct actin fibers seen in interphase cells. The actin becomes more concentrated near the midplane by telophase and takes the form of a relatively bright layer of fluorescence adjacent to the forming cell plate. This distribution differs markedly from that of phragmoplast microtubules (MTs) which extend back from the plate toward the daughter nuclei. F-actin continues to accumulate in new parts of the expanding phragmoplast, while RP fluorescence gradually decreases near older portions of the plate. It disappears completely near the new wall in most interphase cells. Treatment of root tips with cytochalasin B or D before fixation markedly reduces RP fluorescence, but phragmoplast MTs remain. Colchicine or oryzalin treatment leads to the disappearance of both phragmoplast actin and MTs. The possible function of actin in the phragmoplast/cell plate complex is discussed.Abbreviations CB cytochalasin B - CD cytochalasin D - CIPC isopropyl N-(3-chlorophenyl-)carbamate - DIC differential interference contrast - MT microtubule - PBS phosphate buffered saline - PM plasmalemma - RP rhodamine-phalloidin     

Microtubules remodel actomyosin networks in Xenopus egg extracts via two mechanisms of F-actin transport

Interactions between microtubules and filamentous actin (F-actin) are crucial for many cellular processes, including cell locomotion and cytokinesis, but are poorly understood. To define the basic principles governing microtubule/F-actin interactions, we used dual-wavelength digital fluorescence and fluorescent speckle microscopy to analyze microtubules and F-actin labeled with spectrally distinct fluorophores in interphase Xenopus egg extracts. In the absence of microtubules, networks of F-actin bundles zippered together or exhibited serpentine gliding along the coverslip. When microtubules were nucleated from Xenopus sperm centrosomes, they were released and translocated away from the aster center. In the presence of microtubules, F-actin exhibited two distinct, microtubule-dependent motilities: rapid ( approximately 250-300 nm/s) jerking and slow ( approximately 50 nm/s), straight gliding. Microtubules remodeled the F-actin network, as F-actin jerking caused centrifugal clearing of F-actin from around aster centers. F-actin jerking occurred when F-actin bound to motile microtubules powered by cytoplasmic dynein. F-actin straight gliding occurred when F-actin bundles translocated along the microtubule lattice. These interactions required Xenopus cytosolic factors. Localization of myosin-II to F-actin suggested it may power F-actin zippering, while localization of myosin-V on microtubules suggested it could mediate interactions between microtubules and F-actin. We examine current models for cytokinesis and cell motility in light of these findings.     

The role of actin, actomyosin and microtubules in defining cell shape during the differentiation of Naegleria amebae into flagellates

Differentiation of Naegleria amebae into flagellates was used to examine the interaction between actin, actomyosin and microtubules in defining cell shape. Amebae, which lack microtubules except during mitosis, differentiate into flagellates with a fixed shape and a complex microtubule cytoskeleton in 120 min. Based on earlier models of ameboid motility it has been suggested that actomyosin is quiescent in flagellates. This hypothesis was tested by following changes in the cytoskeleton using three-dimensional reconstructions prepared by confocal microscopy of individual cells stained with antibodies against actin and tubulin as well as with phalloidin and DNase I. F-actin as defined by phalloidin staining was concentrated in expanding pseudopods. Most phalloidin staining was lost as cells rounded up before the onset of flagellum formation. Actin staining with a Naegleria-specific antibody that recognizes both F- and G-actin was confined to the cell cortex of both amebae and flagellates. DNase I demonstrated G-actin throughout all stages. Most of the actin in the cortex was not bound by phalloidin yet was resistant to detergent extraction suggesting that it was polymerized. The microtubule cytoskeleton of flagellates was intimately associated with this actin cortex. Treatment of flagellates with cytochalasin D produced a rapid loss of flagellate shape and the appearance of phalloidin staining while latrunculin A stabilized the flagellate shape. These results suggest that tension produced by an actomyosin network is required to maintain the flagellate shape. The rapid loss of the flagellate shape induced by drugs, which specifically block myosin light chain kinase, supports this hypothesis.     

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.     

Phragmoplasts in the Absence of Nuclear Division

All land plants (embryophytes) use a phragmoplast for cytokinesis. Phragmoplasts are distinctive cytoskeletal structures that are instrumental in the deposition of new walls in both vegetative and reproductive phases of the life cycle. In meristems, the phragmoplast is initiated among remaining non-kinetochore spindle fibers between sister nuclei and expands to join parental walls at the site previously marked by the preprophase band of microtubules (PPB). The microtubule cycle and cell cycle are closely coordinated: the hoop-like cortical microtubules of interphase are replaced by the PPB just prior to prophase, the PPB disappears as the spindle forms, and the phragmoplast mediates cell plate deposition after nuclear division. In the reproductive phase, however, cortical microtubules and PPBs are absent and cytokinesis may be uncoupled from the cell cycle resulting in multinucleate cells (syncytia). Minisyncytia of 4 nuclei occur in microsporocytes and several (typically 8) nuclei occur in the developing megagametophyte. Macrosyncytia with thousands of nuclei may occur in the nuclear type endosperm. Cellularization of syncytia involves formation of adventitious phragmoplasts at boundaries of nuclear-cytoplasmic domains (NCDs) defined by radial microtubule systems (RMSs) emanating from non-sister nuclei. Once initiated in the region of microtubule overlap at interfaces of opposing RMSs, the adventitious phragmoplasts appear structurally identical to interzonal phragmoplasts. Phragmoplasts are constructed of multiple opposing arrays similar to what have been termed microtubule converging centers. The individual phragmoplast units are distinctive fusiform bundles of anti-parallel microtubules bisected by a dark mid-zone where vesicles accumulate and fuse into a cell plate.     

The organization of F-actin in root tip cells ofAdiantum capillus veneris throughout the cell cycle

Summary The patterns of F-actin in relation to microtubule (Mt) organization in dividing root tip cells ofAdiantum capillus veneris were studied with rhodamine-phalloidin (RP) labelling and tubulin immunofluorescence. Interphase cells display a well organized network of cortical/subcortical, endoplasmic and perinuclear actin filaments (AFs), not particularly related to the interphase Mt arrays. The cortical AFs seem to persist during the cell cycle while the large subcortical AF bundles disappear by preprophase/prophase and reappear after cytokinesis is completed. In some but not all of the preprophase cells the cortical AFs tend to form a band (AF-PPB) coincident with the preprophase band of Mts (Mt-PPB). In metaphase and anaphase cells AFs are localized in the cell cortex, around the spindle and inside it coincidently with kinetochore Mt bundles. During cytokinesis AFs are consistently found in the phragmoplast. In oryzalin treated cells neither Mt-PPBs, spindles and phragmoplasts exist, nor such F-actin structures can be observed. In cells recovering from oryzalin, AF-PPBs, AF kinetochore bundles and AF phragmoplasts reform. They show the same pattern with the reinstating respective Mt arrays. In contrast, in cells treated with cytochalasin B (CB), AFs disappear but all categories of Mt arrays form normally.These observations show that F-actin organization in root tip cells ofA. capillus veneris differs from that of root tip cells of flowering plants examined so far. In addition, Mts seem to be crucial for F-actin organization as far as it concerns the PPB, the mitotic spindle, and the phragmoplast.Abbreviations AF actin filament - CB cytochalasin B - MBS m-male-imidobenzoyl-N-hydroxysuccinimide ester - MSB microtubule stabilizing buffer - Mt microtubule - PBS phosphate buffered saline - PPB preprophase band - RP rhodamine phalloidin     

Plant actin filament and microtubule interactions during anaphase--telophase transition: effects of antagonist drugs

F-actin and microtubule co-distribution and interaction were studied during anaphase-telophase. Rapid and drastic changes in the cytoskeleton during these particular stages were studied in isolated plant endosperm cells of the blood lily. These wall-free cells can be considered as natural dividing protoplasts. As identified previously, an F-actin cytoskeletal network characterized the plant cortex and formed an elastic cage around the spindle, remaining throughout interphase, mitosis and cytokinesis. Actin was specifically labeled by fluorescent phalloidin and/or monoclonal antibodies. Gold-labelled secondary antibodies were used for ultrastructural observations and silver-enhancement was applied for video-enhanced microscopy. Microtubule and microfilament dynamics and interaction were studied using drug antagonists to actin (cytochalasins B, D) and to tubulin (colchicine). This permitted precise correlations to be made between chromosome movement inhibition and alteration in the actin/tubulin cytoskeleton. During anaphase chromosome migration, the cortical actin network was stretched along the microtubular spindle, while it remained homogeneous when anaphase was inhibited by colchicine. Cytochalasins did not inhibit chromosome movement but altered actin distribution. A new population of actin filaments appeared at the equator in late anaphase before the microtubular phragmoplast was formed and contributed to cell plate formation. Our conclusion is that F-actin-microtubule interaction may contribute to the regulatory mechanism of plant cytokinesis.     

The cytoskeleton of hydatid cyst cultured cells and its sensitivity to inhibitors

Cell cultures obtained from the germinal layer of hydatid cysts of the parasitic tapeworm Echinococcus granulosus were characterized with respect to their microtubule and microfilament systems. These were stained using monospecific antibodies against tubulin from sea urchin spermatozoa or sheep brain and against Dictyostelium discoideum actin as well as rhodamine conjugated phalloidin. The results show that the distribution of microtubules nad actin containing fibres of these cells is remarkably similar to that of mammalian cells both during interphase and mitosis. Hydatid cells, however, could not be stained with a specific antivimentin antibody. Indirect immunofluorescence with antitubulin antibodies of inhibitor treated cells shows that hydatid cell microtubules are sensitive to several antimicrotubular drugs including benzimidazole derivatives, colchicine, vinblastine, and griseofulvin.     

Three-dimensional localization and redistribution of F-actin in higher plant mitosis and cell plate formation

The distribution of F-actin cables in dividing endosperm cells of a higher plant, Haemanthus, was visualized with the immunogold-silver-enhanced method and compared with the arrangement of immunogold-stained microtubules in the same cells. The three-dimensional distribution of F-actin cables and microtubules during mitosis and cell plate formation was analyzed using ultrathin optical sectioning of whole mounts in polarized light video microscopy. F-actin cables form a loose irregular network in the interphase cytoplasm. Much of this network remains outside of the spindle during mitosis. A few F-actin cables were detected within the spindle. Their pronounced rearrangement during mitosis appears to be related to the presence and growth of microtubule arrays. During prometaphase, actin cables located on the spindle surface and those present within the spindle tend to arrange parallel to the long axis of the spindle. Cables outside the spindle do not reorient, except those at the polar region, where they appear to be compressed by the elongating spindle. Beginning with mid-anaphase, shorter actin cables oriented in various directions accumulate at the equator. Some of them are incorporated into the phragmoplast and cell plate and are gradually fragmented as the cell plate is formed and ages. Actin cables adjacent to microtubule arrays often show a regular punctate staining pattern. Such a pattern is seldom observed in the peripheral cytoplasm, which contains few microtubules. The rearrangement of F-actin cables mimicks the behavior of spindle inclusions, such as starch grains, mitochondria, etc., implying that F-actin is redistributed passively by microtubule growth or microtubule-related transport. Thus F-actin or actomyosin-based motility does not appear to be directly involved in mitosis and cytokinesis in higher plants.     

Microfilament Distribution in Maize Meiotic Mutants Correlates with Microtubule Organization

Microtubules and microfilaments often codistribute in plants; their presumed interaction can be tested with drugs although it is not always clear that these are without side effects. In this study, we exploited mutants defective in meiotic cell division to investigate in a noninvasive way the relationship between the two cytoskeletal elements. By staining unfixed, permeabilized cells with rhodamine-phalloidin, spatial and temporal changes in microfilament distribution during maize meiosis were examined. In wild-type microsporocytes, a microtubule array that radiates from the nucleus disappeared during spindle formation and returned at late telophase. This result differed from the complex cytoplasmic microfilament array that is present at all stages, including karyokinesis and cytokinesis. During division, a second class of microfilaments also was observed in the spindle and phragmoplast. To analyze this apparent association of microtubules and microfilaments, we examined several meiotic mutants known to have stage-specific disruptions in their microtubule arrays. Two mutations that altered the number or form of meiotic spindles also led to a dramatic reorganization of F-actin. In contrast, rearrangement of nonspindle, cytoplasmic microtubules did not lead to concomitant changes in F-actin distribution. These results suggested that microtubules and microfilaments interact in a cell cycle-specific and site-specific fashion during higher plant meiosis.     

Two Arabidopsis phragmoplast-associated kinesins play a critical role in cytokinesis during male gametogenesis

In plant cells, cytokinesis is brought about by the phragmoplast. The phragmoplast has a dynamic microtubule array of two mirrored sets of microtubules, which are aligned perpendicularly to the division plane with their plus ends located at the division site. It is not well understood how the phragmoplast microtubule array is organized. In Arabidopsis thaliana, two homologous microtubule motor kinesins, PAKRP1/Kinesin-12A and PAKRP1L/Kinesin-12B, localize exclusively at the juxtaposing plus ends of the antiparallel microtubules in the middle region of the phragmoplast. When either kinesin was knocked out by T-DNA insertions, mutant plants did not show a noticeable defect. However, in the absence of both kinesins, postmeiotic development of the male gametophyte was severely inhibited. In dividing microspores of the double mutant, microtubules often became disorganized following chromatid segregation and failed to form an antiparallel microtubule array between reforming nuclei. Consequently, the first postmeiotic cytokinesis was abolished without the formation of a cell plate, which led to failures in the birth of the generative cell and, subsequently, the sperm. Thus, our results indicate that Kinesin-12A and Kinesin-12B jointly play a critical role in the organization of phragmoplast microtubules during cytokinesis in the microspore that is essential for cell plate formation. Furthermore, we conclude that Kinesin-12 members serve as dynamic linkers of the plus ends of antiparallel microtubules in the phragmoplast.     

Structural rearrangements of tubulin and actin during the cell cycle of the yeast Saccharomyces

The distribution of actin and tubulin during the cell cycle of the budding yeast Saccharomyces was mapped by immunofluorescence using fixed cells from which the walls had been removed by digestion. The intranuclear mitotic spindle was shown clearly by staining with a monoclonal antitubulin; the presence of extensive bundles of cytoplasmic microtubules is reported. In cells containing short spindles still entirely within the mother cells, one of the bundles of cytoplasmic microtubules nearly always extended to (or into) the bud. Two independent reagents (anti-yeast actin and fluorescent phalloidin) revealed an unusual distribution of actin: it was present as a set of cortical dots or patches and also as distinct fibers that were presumably bundles of actin filaments. Double labeling showed that at no stage in the cell cycle do the distributions of actin and tubulin coincide for any significant length, and, in particular, that the mitotic spindle did not stain detectably for actin. However, both microtubule and actin staining patterns change in a characteristic way during the cell cycle. In particular, the actin dots clustered in rings about the bases of very small buds and at the sites on unbudded cells at which bud emergence was apparently imminent. Later in the budding cycle, the actin dots were present largely in the buds and, in many strains, primarily at the tips of these buds. At about the time of cytokinesis the actin dots clustered in the neck region between the separating cells. These aspects of actin distribution suggest that it may have a role in the localized deposition of new cell wall material.     

Actomyosin is Involved in the Organization of the Microtubule Preprophase Band in Arabidopsis Suspension Cultured Cells

The microtubule preprophase bands （PPBs） participate in the sequence of events to position cell plates in most plants. However, the mechanism of PPB formation remains to be clarified. In the present study, the organization of PPBs in Arabidopsis suspension cultured cells was investigated by confocal laser scanning microscopy combined with pharmacological treatments of reagents specific for the cytoskeleton elements. Double staining of F-actin and microtubules （MTs） showed that actin filaments were arranged randomly and no colocalization with cortical MTs was observed in the interphase cells. However, cortical actin filaments showed colocalization with MTs during the formation of PPBs. A broad actin band formed with the broad MT band in the initiation of PPB and narrowed down together with the MT band to form the PPB. Nevertheless, broad MT bands were formed but failed to narrow down in cells treated with the F-actin disruptor latrunculin A. In contrast, in the presence of the F-actin stabilizer phalloidin, PPB formation did not exhibit any abnormality. Therefore, the integrity, but not the dynamics, of the actin cytoskeleton is necessary for the formation of normal PPBs. Treatment with 2, 3-butanedine monoxime, a myosin inhibitor, also resulted in the formation of broad MT bands, indicating that actomyosin may be involved in the rearrangement of MTs to form the PPBs. Double staining of MTs and myosin revealed that myosin concentrated on the PPB region during PPB formation. It is suggested that the actin cytoskeleton at the PPB site may serve as a rack to transport cortical MTs by using myosin when the broad MT band narrows down to form the PPB.     

Expression of the mitotic kinesin Kif15 in postmitotic neurons: Implications for neuronal migration and development

Kif15 is a kinesin-related protein whose mitotic homologues are believed to crosslink and immobilize spindle microtubules. We have obtained rodent sequences of Kif15, and have studied their expression and distribution in the developing nervous system. Kif15 is indeed expressed in actively dividing fibroblasts, but is also expressed in terminally postmitotic neurons. In mitotic cells, Kif15 localizes to spindle poles and microtubules during prometaphase to early anaphase, but then to the actin-based cleavage furrow during cytokinesis. In interphase fibroblasts, Kif15 localizes to actin bundles but not to microtubules. In cultured neurons, Kif15 localizes to microtubules but shows no apparent co-localization with actin. Localization of Kif15 to microtubules is particularly good when the microtubules are bundled, and there is a notable enrichment of Kif15 in the microtubule bundles that occupy stalled growth cones and dendrites. Studies on developing rodent brain show a pronounced enrichment of Kif15 in migratory neurons compared to other neurons. Notably, migratory neurons have a cage-like configuration of microtubules around their nucleus that is linked to the microtubule array within the leading process, such that the entire array moves in unison as the cell migrates. Since the capacity of microtubules to move independently of one another is restricted in all of these cases, we propose that Kif15 opposes the capacity of other motors to generate independent microtubule movements within key regions of developing neurons.     

黄蝉花生殖细胞有丝分裂期间微管的动态

用微管免疫荧光方法观察了黄蝉花生殖细胞在花粉管中进行有丝分裂时的微管动态。微管在不同分裂期的分布情形很不一样。当生殖细胞由花粉进入花粉管后,细胞便立刻开始分裂进入早前期,在这阶段微管以一个紧密微管网笼子形式存在生殖细胞内。之后,细胞进入中前期,在此阶段细胞核扩大,染色体变粗,而存在细胞内的微管网逐渐变为疏松散漫状,跟着细胞进入晚前期,而微管笼子则由网状变为纵向排列状。分裂进入早中期微管变细并呈波浪状,微管由笼子结构过渡到纺锤体结构。进入中期,纺锤体全部形成,在纺锤体内可以清楚地看到两种不同类型的微管束,一种附着在染色体上,而另一种则从一极延伸至另一极。跟着细胞进入早后期,在这一阶段姊妹染色体分开并分别移向两极,在赤道板位置微管明显减少。之后,细胞进入晚后期,姊妹染色体集中在两极,极端有新微管出现。在两个染色体团之间又汇集了许多类似成膜体微管的微管。细胞进入分裂末期,存在赤道板位置的微管又再次减少,而在中央部位则新形成一“成膜体联接区”,把两个新形成的精子连接着。