Bundling of microtubules by motor and tail domains of a kinesin-like calmodulin-binding protein from Arabidopsis: regulation by Ca(2+)/Calmodulin

Kinesin-like calmodulin-binding protein (KCBP), a novel kinesin-like protein from plants, is unique among kinesins and kinesin-like proteins in having a calmodulin-binding domain adjacent to its motor domain. KCBP localizes to mitotic microtubule (MT) arrays including the preprophase band, the spindle apparatus, and the phragmoplast, suggesting a role for KCBP in establishing these MT arrays by bundling MTs. To determine if KCBP bundles MTs, we expressed C-terminal motor and N-terminal tail domains of KCBP, and used the purified proteins in MT bundling assays. The 1.5 C protein with the motor and calmodulin-binding domains induced MT bundling. The 1.5 C-induced bundles were dissociated in the presence of Ca(2+)/calmodulin. Similar results were obtained with a 1.4 C protein, which lacks much of the coiled-coil region present in 1.5 C protein and does not form dimers. The N-terminal tail of KCBP, which contains an ATP-independent MT binding site, is also capable of bundling MTs. These results, together with the KCBP localization data, suggest the involvement of KCBP in establishing mitotic MT arrays during different stages of cell division and that Ca(2+)/calmodulin regulates the formation of these MT arrays.     

Disruption of actin microfilaments causes cortical microtubule disorganization and extra-phragmoplast formation at M/G1 interface in synchronized tobacco cells

The roles of actin microfilaments (MFs) in the organization of microtubules (MTs) at the M/G1 interface were investigated in transgenic tobacco BY-2 cells stably expressing a GFP-tubulin fusion protein, using the MF-disrupting agent, Bistheonellide A (BA). When MFs were disrupted by BA treatment, cortical MTs (CMTs) did not become reorganized even 3 h after phragmoplast collapse, whereas non-treated cells completed CMT reorganization within 1 h. Furthermore, in the absence of MFs, the tubulin proteins did not show appropriate recruitment but remained at the site where the phragmoplast had existed, or extra-phragmoplasts were organized. These extra-phragmoplasts could functionally form extra-cell plates. This is the first observation of the formation of multiple cell plates during one nuclear division, and of phragmoplast generation irrespective of the position of the mitotic spindle or nuclei. The significance of these observations on the role of MFs at the M/G1 interface is discussed.     

Quantitative analysis of changes in actin microfilament contribution to cell plate development in plant cytokinesis

Background  

Plant cells divide by the formation of new cross walls, known as cell plates, from the center to periphery of each dividing cell. Formation of the cell plate occurs in the phragmoplast, a complex structure composed of membranes, microtubules (MTs) and actin microfilaments (MFs). Disruption of phragmoplast MTs was previously found to completely inhibit cell plate formation and expansion, indicative of their crucial role in the transport of cell plate membranes and materials. In contrast, disruption of MFs only delays cell plate expansion but does not completely inhibit cell plate formation. Despite such findings, the significance and molecular mechanisms of MTs and MFs remain largely unknown.     

Reorganization of the actin and microtubule cytoskeleton throughout blue-light-induced differentiation of characean protonemata into multicellular thalli

Summary The reorganization of the actin and microtubule (MT) cytoskeleton was immunocytochemically visualized by confocal laser scanning microscopy throughout the photomorphogenetic differentiation of tip-growing characean protonemata into multicellular green thalli. After irradiating dark-grown protonemata with blue or white light, decreasing rates of gravitropic tip-growth were accompanied by a series of events leading to the first cell division: the nucleus migrated towards the tip; MTs and plastids invaded the apical cytoplasm; the polar zonation of cytoplasmic organelles and the prominent actin patch at the cell tip disappeared and the tip-focused actin microfilaments (MFs) were reorganized into a homogeneous network. During prometaphase and metaphase, extranuclear spindle microtubules formed between the two spindle poles. Cytoplasmic MTs associated with the apical spindle pole decreased in number but did not disappear completely during mitosis. The basal cortical MTs represent a discrete MT population that is independent from the basal spindle poles and did not redistribute during mitosis and cytokinesis. Preprophase MT bands were never detected but cytokinesis was characterized by higher-plant-like phragmoplast MT arrays. Cytoplasmic actin MFs persisted as a dense network in the apical cytoplasm throughout the first cell division. They were not found in close contact with spindle MTs, but actin MFs were clearly coaligned along the MTs of the early phragmoplast. The later belt-like phragmoplast was completely depleted of MFs close to the time of cell plate fusion except for a few actin MF bundles that extended to the margin of the growing cell plate. The cell plate itself and young anticlinal cell walls showed strong actin immunofluorescence. After several anticlinal cell divisions, basal cells of the multicellular protonema produced nodal cell complexes by multiple periclinal divisions. The apical-dome cell of the new shoot which originated from a nodal cell becomes the meristem initial that regularly divides to produce a segment cell. The segment cell subsequently divides to produce a single file of alternating internodal cells and multicellular nodes which together form the complexly organized characean thallus. The actin and MT distribution of nodal cells resembles that of higherplant meristem cells, whereas the internodal cells exhibit a highly specialized cortical system of MTs and streaming-generating actin bundles, typical of highly vacuolated plant cells. The transformation from the asymmetric mitotic spindle of the polarized tip-growing protonema cell to the symmetric, higher-plant-like spindle of nodal thallus cells recapitulates the evolutionary steps from the more primitive organisms to higher plants.Abbreviations FITC fluorescein isothiocyanate - MF microfilament - MT microtubule - MSB microtubule-stabilizing buffer - PBS phosphate-buffered saline     

Interaction of antiparallel microtubules in the phragmoplast is mediated by the microtubule-associated protein MAP65-3 in Arabidopsis

In plant cells, microtubules (MTs) in the cytokinetic apparatus phragmoplast exhibit an antiparallel array and transport Golgi-derived vesicles toward MT plus ends located at or near the division site. By transmission electron microscopy, we observed that certain antiparallel phragmoplast MTs overlapped and were bridged by electron-dense materials in Arabidopsis thaliana. Robust MT polymerization, reported by fluorescently tagged End Binding1c (EB1c), took place in the phragmoplast midline. The engagement of antiparallel MTs in the central spindle and phragmoplast was largely abolished in mutant cells lacking the MT-associated protein, MAP65-3. We found that endogenous MAP65-3 was selectively detected on the middle segments of the central spindle MTs at late anaphase. When MTs exhibited a bipolar appearance with their plus ends placed in the middle, MAP65-3 exclusively decorated the phragmoplast midline. A bacterially expressed MAP65-3 protein was able to establish the interdigitation of MTs in vitro. MAP65-3 interacted with antiparallel microtubules before motor Kinesin-12 did during the establishment of the phragmoplast MT array. Thus, MAP65-3 selectively cross-linked interdigitating MTs (IMTs) to allow antiparallel MTs to be closely engaged in the phragmoplast. Although the presence of IMTs was not essential for vesicle trafficking, they were required for the phragmoplast-specific motors Kinesin-12 and Phragmoplast-Associated Kinesin-Related Protein2 to interact with MT plus ends. In conclusion, we suggest that the phragmoplast contains IMTs and highly dynamic noninterdigitating MTs, which work in concert to bring about cytokinesis in plant cells.     

Localization of a kinesin-like calmodulin-binding protein in dividing cells of Arabidopsis and tobacco

The cloning and characterization of a novel kinesin-like protein ( k inesin-like c almodulin- b inding p rotein, KCBP) from Arabidopsis and other plants has recently been described. Unlike all other known kinesin-like proteins, KCBP interacts with calmodulin in the presence of micromolar calcium. An antibody specific to KCBP was raised using a calmodulin-binding synthetic peptide that is unique to KCBP. The KCBP antibody detected a single protein of about 140 kDa in Arabidopsis and tobacco, the size predicted from cDNA sequences. In synchronized cell cultures, the amount of KCBP was abundant during M-phase and very low in interphase. To get some insight into the function of this novel motor protein, KCBP in Arabidopsis and tobacco cells was localized by indirect immunofluorescence microscopy using affinity-purified anti-KCBP antibody. The KCBP was localized to the pre-prophase band, the mitotic spindle and the phragmoplast. The association of KCBP with microtubule arrays in dividing cells suggests that this minus-end-directed microtubule motor protein is likely to be involved in the formation of these microtubule arrays and/or functions associated with these structures.     

A Novel Plant Kinesin-Related Protein Specifically Associates with the Phragmoplast Organelles

In higher plants, the formation of the cell plate during cytokinesis requires coordinated microtubule (MT) reorganization and vesicle transport in the phragmoplast. MT-based kinesin motors are important players in both processes. To understand the mechanisms underlying plant cytokinesis, we have identified AtPAKRP2 (for Arabidopsis thaliana phragmoplast-associated kinesin-related protein 2). AtPAKRP2 is an ungrouped N-terminal motor kinesin. It first appeared in a punctate pattern among interzonal MTs during late anaphase. When the phragmoplast MT array appeared in a mirror pair, AtPAKRP2 became more concentrated near the division site, and additional signal could be detected elsewhere in the phragmoplast. In contrast, the previously identified AtPAKRP1 protein is associated specifically with bundles of MTs in the phragmoplast at or near their plus ends. Localization of the tobacco homolog(s) of AtPAKRP2 was altered by treatment of brefeldin A in BY-2 cells. We discuss the possibility that AtPAKRP1 plays a role in establishing and/or maintaining the phragmoplast MT array, and AtPAKRP2 may contribute to the transport of Golgi-derived vesicles in the phragmoplast.     

Electron tomographic analysis of somatic cell plate formation in meristematic cells of Arabidopsis preserved by high-pressure freezing

We have investigated the process of somatic-type cytokinesis in Arabidopsis (Arabidopsis thaliana) meristem cells with a three-dimensional resolution of approximately 7 nm by electron tomography of high-pressure frozen/freeze-substituted samples. Our data demonstrate that this process can be divided into four phases: phragmoplast initials, solid phragmoplast, transitional phragmoplast, and ring-shaped phragmoplast. Phragmoplast initials arise from clusters of polar microtubules (MTs) during late anaphase. At their equatorial planes, cell plate assembly sites are formed, consisting of a filamentous ribosome-excluding cell plate assembly matrix (CPAM) and Golgi-derived vesicles. The CPAM, which is found only around growing cell plate regions, is suggested to be responsible for regulating cell plate growth. Virtually all phragmoplast MTs terminate inside the CPAM. This association directs vesicles to the CPAM and thereby to the growing cell plate. Cell plate formation within the CPAM appears to be initiated by the tethering of vesicles by exocyst-like complexes. After vesicle fusion, hourglass-shaped vesicle intermediates are stretched to dumbbells by a mechanism that appears to involve the expansion of dynamin-like springs. This stretching process reduces vesicle volume by approximately 50%. At the same time, the lateral expansion of the phragmoplast initials and their CPAMs gives rise to the solid phragmoplast. Later arriving vesicles begin to fuse to the bulbous ends of the dumbbells, giving rise to the tubulo-vesicular membrane network (TVN). During the transitional phragmoplast stage, the CPAM and MTs disassemble and then reform in a peripheral ring phragmoplast configuration. This creates the centrifugally expanding peripheral cell plate growth zone, which leads to cell plate fusion with the cell wall. Simultaneously, the central TVN begins to mature into a tubular network, and ultimately into a planar fenestrated sheet (PFS), through the removal of membrane via clathrin-coated vesicles and by callose synthesis. Small secondary CPAMs with attached MTs arise de novo over remaining large fenestrae to focus local growth to these regions. When all of the fenestrae are closed, the new cell wall is complete. Few endoplasmic reticulum (ER) membranes are seen associated with the phragmoplast initials and with the TVN cell plate that is formed within the solid phragmoplast. ER progressively accumulates thereafter, reaching a maximum during the late PFS stage, when most cell plate growth is completed.     

Cytoskeleton and morphogenesis in brown algae

BACKGROUND: Morphogenesis on a cellular level includes processes in which cytoskeleton and cell wall expansion are strongly involved. In brown algal zygotes, microtubules (MTs) and actin filaments (AFs) participate in polarity axis fixation, cell division and tip growth. Brown algal vegetative cells lack a cortical MT cytoskeleton, and are characterized by centriole-bearing centrosomes, which function as microtubule organizing centres. SCOPE: Extensive electron microscope and immunofluorescence studies of MT organization in different types of brown algal cells have shown that MTs constitute a major cytoskeletal component, indispensable for cell morphogenesis. Apart from participating in mitosis and cytokinesis, they are also involved in the expression and maintenance of polarity of particular cell types. Disruption of MTs after Nocodazole treatment inhibits cell growth, causing bulging and/or bending of apical cells, thickening of the tip cell wall, and affecting the nuclear positioning. Staining of F-actin using Rhodamine-Phalloidin, revealed a rich network consisting of perinuclear, endoplasmic and cortical AFs. AFs participate in mitosis by the organization of an F-actin spindle and in cytokinesis by an F-actin disc. They are also involved in the maintenance of polarity of apical cells, as well as in lateral branch initiation. The cortical system of AFs was found related to the orientation of cellulose microfibrils (MFs), and therefore to cell wall morphogenesis. This is expressed by the coincidence in the orientation between cortical AFs and the depositing MFs. Treatment with cytochalasin B inhibits mitosis and cytokinesis, as well as tip growth of apical cells, and causes abnormal deposition of MFs. CONCLUSIONS: Both the cytoskeletal elements studied so far, i.e. MTs and AFs are implicated in brown algal cell morphogenesis, expressed in their relationship with cell wall morphogenesis, polarization, spindle organization and cytokinetic mechanism. The novelty is the role of AFs and their possible co-operation with MTs.     

The kinesin-like calmodulin binding protein is differentially involved in cell division

The kinesin-like calmodulin (CaM) binding protein (KCBP), a minus end-directed microtubule motor protein unique to plants, has been implicated in cell division. KCBP is negatively regulated by Ca(2)+ and CaM, and antibodies raised against the CaM binding region inhibit CaM binding to KCBP in vitro; therefore, these antibodies can be used to activate KCBP constitutively. Injection of these antibodies into Tradescantia virginiana stamen hair cells during late prophase induces breakdown of the nuclear envelope within 2 to 10 min and leads the cell into prometaphase. However, mitosis is arrested, and the cell does not progress into anaphase. Injection of antibodies later during cell division has no effect on anaphase transition but causes aberrant phragmoplast formation and delays the completion of cytokinesis by approximately 15 min. These effects are achieved without any apparent degradation of the microtubule cytoskeleton. We propose that during nuclear envelope breakdown and anaphase, activated KCBP promotes the formation of a converging bipolar spindle by sliding and bundling microtubules. During metaphase and telophase, we suggest that its activity is downregulated.     

Distribution and function of actin in the developing stomatal complex of winter rye (Secale cereale cv. Puma)

Summary The dynamics of actin distribution during stomatal complex formation in leaves of winter rye was examined by means of immunofluorescence microscopy of epidermal sheets. This method results in actin localization patterns that are the same as those seen with rhodamine-phalloidin staining, but are more stable. During stomatal development MFs are extensively rearranged, and most of the time the orientation or placement of MFs is distinctly different from that of MTs, the exception being co-localization of MTs and MFs in phragmoplasts. Although MFs show an orientation similar to that of MTs in interphase guard mother cells, no banding of MFs into anything resembling the interphase MT band is observed. From prophase to telophase, a distinct, dense concentration of MFs is found in subsidiary cell mother cells (SMCs) between the nucleus and the region of the cell cortex facing the guard mother cell. Cytochalasin B treatment causes incorrect positioning of the SMC nucleus/daughter nuclei and abarrent placement and orientation of the new cell wall that forms the boundary of the subsidiary cell at cytokinesis. These results suggest that MFs are involved in maintaining the SMC nucleus in its correct position and the SMC spindle in the correct orientation relative to the division site previously delineated by the preprophase band. Because these MFs thus appear to assure that the SMC phragmoplast begins to form in the correct orientation near the division site to which it needs to grow, we suggest that MFs are involved in control of correct placement and orientation of the new cell wall of the subsidiary cell.Abbreviations CB cytochalasin B - DIC differential interference contrast - DMSO dimethylsulfoxide - MBS m-maleimidobenzoyl-N-hydroxylsuccinimide ester - MF microfilament - MT microtubule - PBS phosphate buffered saline - SMC subsidiary cell mother cell Dedicated to the memory of Professor Oswald Kiermayer     

The molecular mechanism of targeted vesicle transport in cytokinesis

Recent studies have demonstrated that vesicle transport to cleavage furrow is indispensable for cytokinesis. Some animal and plant cells form distinct structures during cell division known as central spindle and phragmoplast, respectively. Several essential factors involved in the vesicle transport have been isolated so far. SNARE proteins and molecular motors play a central role in this process. For future research of cytokinesis, it is important to investigate these factors as well as cytoskeletal components of the contractile ring in detail. This review focuses on the molecular mechanism of targeted vesicle transport in cytokinesis.     

Microtubule organization during successive microsporogenesis in Allium cepa and simultaneous cytokinesis in Nicotiana tabacum

Microtubule cytoskeleton organization during microspore mother cell (MMC) meiosis in Allium cepa L. and microsporogenesis in Nicotiana tabacum L. was examined. The MMC microtubules (MTs) were short and well dispersed in the cytoplasm of both taxa. As the MMCs of both species entered metaphase of meiosis I, the MTs constructed a spindle that facilitated the chromosomes to orient in the meridian plane. At anaphase of meiosis I, the spindle MTs differentiated into two types: one MT type became short, pulled the chromosomes toward the two poles, and was designated as centromere MTs; the second type of MT connected the two poles, and was designated as pole MTs. In A. cepa, where successive cytokinesis was observed, pole MTs assumed a tubbish shape. Some new short MTs aggregated in the meridian plane and constricted to form a phragmoplast, which developed into a cell plate, divided the cytoplasm into two parts and produced a dyad. However, in tobacco, a phragmoplast was not generated in anaphase of meiosis I and II and cytokinesis did not occur. The spindle MTs depolymerized and reorganized the radial arrangement of MTs from the nucleate surface to the periplasm during anaphase. Following telophase of meiosis II, the cytoplasm produced centripetal furrows, which met in the center of the cell and divided it into four parts, serving as a form of cytokinesis. In this process, MTs appeared to bear no relationship to cytokinesis.     

Ultrastructural Changes of the Microtubule in the Generative Cell of Amaryllis vittata Ait. During Mitosis

Structural changes of microtubules (MTs) in the generative cell (GC) of Amaryllis vittara Alt. during mitosis in pollen tube have been investigated with electron microscopy. The division cycle was completed approximately within 12 h. During prophase, the MTs bundles distributed in the cortex of the GC, they were less and shorter than that before mitosis, some of which beginning to be near the nucleus. When the chromatin condensed and the GC entered metaphase, the MTs increased in number and distributed among the chromosomes (CHs) in the original nuclear zone, but they were not arranged in distinct bundlesed. Some of them connected with the CHs to form kinetochore MTs (KMTs), where as the cortical MTs in prophase still remained there. During metaphase, the CHs were arranged on the equartor forming a metaphase plate, and all the MTs formed a diffuse spindle. When the GC entered anaphase, the KMTs were shortened and they were involved in the segregation of the CHs into two groups. The MTs were much more and focused in the two polar regions. In late anaphase, while the MTs still existed at the poles, rich phragmoplast MTs appeared in the equator zone and the precusors of cell plate (CP) aggregated in the middle of the phragmoplast. When the GC entered telophase, the CHs diffused as chromatin, and phragmoplast MTs extended between the two newly formed nuclear envelops and even through the CP While the polar MTs and KMTs disappeared, the MTs in the newly formed sperm cells were different from that of the GC.     

朱顶红生殖细胞分裂过程中微管超微结构的变化

用透射电镜的方法,对朱顶红（Ａｍ ａｒｙｌｌｉｓｖｉｔｔａｔａ Ａｉｔ．）花粉管中生殖细胞的分裂过程中微管分布和结构形态变化进行了观察,获得如下主要的结果：有丝分裂前期,微管的数量较分裂前减少并变短,靠近细胞核分布。分裂前中期,微管出现于原来的核区并与染色体发生联系,形成着丝点微管。分裂中期,染色体排列于赤道面上形成赤道板,微管构成纺锤体。分裂后期,染色体分成两群,被缩短的着丝点微管拉向两极。在纺锤体两极的微管汇聚。后期的晚期,当极的微管尚未消失时,在赤道区域出现丰富的成膜体微管,在成膜体中央,细胞板前体物聚集。分裂末期,极微管和着丝点微管消失,成膜体微管在新形成的核膜和细胞板间扩展并穿过细胞板     

Identification of a phragmoplast-associated kinesin-related protein in higher plants

The phragmoplast executes cytokinesis in higher plants. The major components of the phragmoplast are microtubules, which are arranged in two mirror-image arrays perpendicular to the division plane [1]. The plus ends of these microtubules are located near the site of the future cell plate. Golgi-derived vesicles are transported along microtubules towards the plus ends to deliver materials bound for the cell plate [2] [3]. During cell division, rapid microtubule reorganization in the phragmoplast requires the orchestrated activities of microtubule motor proteins such as kinesins. We isolated an Arabidopsis cDNA clone of a gene encoding an amino-terminal motor kinesin, AtPAKRP1, and have determined the partial sequence of its rice homolog. Immunofluorescence experiments with two sets of specific antibodies revealed consistent localization of AtPAKRP1 and its homolog in Arabidopsis and rice cells undergoing anaphase, telophase and cytokinesis. AtPAKRP1 started to accumulate along microtubules towards the spindle midzone during late anaphase. Once the phragmoplast microtubule array was established, AtPAKRP1 conspicuously localized to microtubules near the future cell plate. Our results provide evidence that AtPAKRP1 is a hitherto unknown motor that may take part in the establishment and/or maintenance of the phragmoplast microtubule array.     

The cotton kinesin-like calmodulin-binding protein associates with cortical microtubules in cotton fibers

Microtubules in interphase plant cells form a cortical array, which is critical for plant cell morphogenesis. Genetic studies imply that the minus end-directed microtubule motor kinesin-like calmodulin-binding protein (KCBP) plays a role in trichome morphogenesis in Arabidopsis. However, it was not clear whether this motor interacted with interphase microtubules. In cotton (Gossypium hirsutum) fibers, cortical microtubules undergo dramatic reorganization during fiber development. In this study, cDNA clones of the cotton KCBP homolog GhKCBP were isolated from a cotton fiber-specific cDNA library. During cotton fiber development from 10 to 21 DPA, the GhKCBP protein level gradually decreases. By immunofluorescence, GhKCBP was detected as puncta along cortical microtubules in fiber cells of different developmental stages. Thus our results provide evidence that GhKCBP plays a role in interphase cell growth likely by interacting with cortical microtubules. In contrast to fibers, in dividing cells of cotton, GhKCBP localized to the nucleus, the microtubule preprophase band, mitotic spindle, and the phragmoplast. Therefore KCBP likely exerts multiple roles in cell division and cell growth in flowering plants.     

The cytoplast concept in dividing plant cells: cytoplasmic domains and the evolution of spatially organized cell

The unique cytokinetic apparatus of higher plant cells comprises two cytoskeletal systems: a predictive preprophase band of microtubules (MTs), which defines the future division site, and the phragmoplast, which mediates crosswall formation after mitosis. We review features of plant cell division in an evolutionary context and from the viewpoint that the cell is a domain of cytoplasm (cytoplast) organized around the nucleus by a cytoskeleton consisting of a single "tensegral" unit. The term "tensegrity" is a contraction of "tensional integrity" and the concept proposes that the whole cell is organized by an integrated cytoskeleton of tension elements (e.g., actin fibers) extended over compression-resistant elements (e.g., MTs).During cell division, a primary role of the spindle is seen as generating two cytoplasts from one with separation of chromosomes a later, derived function. The telophase spindle separates the newly forming cytoplasts and the overlap between half spindles (the shared edge of two new domains) dictates the position at which cytokinesis occurs. Wall MTs of higher plant cells, like the MT cytoskeleton in animal and protistan cells, spatially define the interphase cytoplast. Redeployment of actin and MTs into the preprophase band (PPB) is the overt signal that the boundary between two nascent cytoplasts has been delineated. The "actin-depleted zone" that marks the site of the PPB throughout mitosis may be a more persistent manifestation of this delineation of two domains of cortical actin. The growth of the phragmoplast is controlled by these domains, not just by the spindle. These domains play a major role in controlling the path of phragmoplast expansion. Primitive land plants show different morphological changes that reveal that the plane of division, with or without the PPB, has been determined well in advance of mitosis.The green alga Spirogyra suggests how the phragmoplast system might have evolved: cytokinesis starts with cleavage and then actin-related determinants stimulate and positionally control cell-plate formation in a phragmoplast arising from interzonal MTs from the spindle. Actin in the PPB of higher plants may be assembling into a potential furrow, imprinting a cleavage site whose persistent determinants (perhaps actin) align the outgrowing edge of the phragmoplast, as in Spirogyra. Cytochalasin spatially disrupts polarized mitosis and positioning of the phragmoplast. Thus, the tensegral interaction of actin with MTs (at the spindle pole and in the phragmoplast) is critical to morphogenesis, just as they seem to be during division of animal cells. In advanced green plants, intercalary expansion driven by turgor is controlled by MTs, which in conjunction with actin, may act as stress detectors, thereby affecting the plane of division (a response clearly evident after wounding of tissue). The PPB might be one manifestation of this strain detection apparatus.     

Cell Cycle-Dependent Microtubule-Based Dynamic Transport of Cytoplasmic Dynein in Mammalian Cells

Background

Cytoplasmic dynein complex is a large multi-subunit microtubule (MT)-associated molecular motor involved in various cellular functions including organelle positioning, vesicle transport and cell division. However, regulatory mechanism of the cell-cycle dependent distribution of dynein has not fully been understood.

Methodology/Principal Findings

Here we report live-cell imaging of cytoplasmic dynein in HeLa cells, by expressing multifunctional green fluorescent protein (mfGFP)-tagged 74-kDa intermediate chain (IC74). IC74-mfGFP was successfully incorporated into functional dynein complex. In interphase, dynein moved bi-directionally along with MTs, which might carry cargos such as transport vesicles. A substantial fraction of dynein moved toward cell periphery together with EB1, a member of MT plus end-tracking proteins (+TIPs), suggesting +TIPs-mediated transport of dynein. In late-interphase and prophase, dynein was localized at the centrosomes and the radial MT array. In prometaphase and metaphase, dynein was localized at spindle MTs where it frequently moved from spindle poles toward chromosomes or cell cortex. +TIPs may be involved in the transport of spindle dyneins. Possible kinetochore and cortical dyneins were also observed.

Conclusions and Significance

These findings suggest that cytoplasmic dynein is transported to the site of action in preparation for the following cellular events, primarily by the MT-based transport. The MT-based transport may have greater advantage than simple diffusion of soluble dynein in rapid and efficient transport of the limited concentration of the protein.     

The Arabidopsis HINKEL gene encodes a kinesin-related protein involved in cytokinesis and is expressed in a cell cycle-dependent manner

Plant cytokinesis starts in the center of the division plane, with vesicle fusion generating a new membrane compartment, the cell plate, that subsequently expands laterally by continuous fusion of newly arriving vesicles to its margin. Targeted delivery of vesicles is assisted by the dynamic reorganization of a plant-specific cytoskeletal array, the phragmoplast, from a solid cylinder into an expanding ring-shaped structure. This lateral translocation is brought about by depolymerization of microtubules in the center, giving way to the expanding cell plate, and polymerization of microtubules along the edge. Whereas several components are known to mediate cytokinetic vesicle fusion [8-10], no gene function involved in phragmoplast dynamics has been identified by mutation. Mutations in the Arabidopsis HINKEL gene cause cytokinesis defects, such as enlarged cells with incomplete cell walls and multiple nuclei. Proper targeting of the cytokinesis-specific syntaxin KNOLLE [8] and lateral expansion of the phragmoplast are not affected. However, the phragmoplast microtubules appear to persist in the center, where vesicle fusion should result in cell plate formation. Molecular analysis reveals that the HINKEL gene encodes a plant-specific kinesin-related protein with a putative N-terminal motor domain and is expressed in a cell cycle-dependent manner similar to the KNOLLE gene. Our results suggest that HINKEL plays a role in the reorganization of phragmoplast microtubules during cell plate formation.