Recovery of microtubules on the blepharoplast of Ceratopteris spermatogenous cells after oryzalin treatment

Most land plants have ill-defined microtubule-organizing centers (MTOCs), consisting of sites on the nuclear envelope or even along microtubules (MTs). In contrast, the spermatogenous cells of the pteridophyte Ceratopteris richardii have a well-defined MTOC, the blepharoplast, which organizes MTs through the last two division cycles. This allows a rare opportunity to study the organization and workings of a structurally well-defined plant MTOC. In this study, antheridial plants were treated with levels of oryzalin that cause complete MT loss from the cells containing blepharoplasts. The oryzalin was then washed out and plants were allowed to recover for varying amounts of time. If the spermatogenous cells were fixed prior to washing out, the blepharoplasts had an unusual appearance. In the matrix (pericentriolar) material where MT ends are normally found, clear areas of about the diameter of MTs were seen embedded in a much deeper matrix, made more obvious in stereo pairs. Occasionally, the matrix material was highly distended, although the basal body template cylinder morphology appeared to be unaltered. The blepharoplasts often occurred as clusters of 2 or 4, indicating that blepharoplast reproduction is not affected by the lack of MTs, but that their movement to the poles is. Gamma (gamma) tubulin antibodies labeled the edge of the blepharoplast in areas where the pits are located, indicating that these might be sites for MT nucleation. After wash out, the new MTs always re-appeared on the blepharoplast and the recovery occurred within an hour of washout. MT lengths increased with increasing washout time and were indistinguishable from untreated blepharoplasts after 24 h of recovery. After washout, arrays formed in new sperm cells such as the spline and basal bodies were often malformed or present in multiple copies, as were the blepharoplasts in these cells prior to wash out. These data indicate that the blepharoplast serves as the site of MT nucleation and organization even after complete MT de-polymerization.     

The Pleiomorphic Plant MTOC： An Evolutionary Perspective

γ-Tubulin is an essential component of the microtubule organizing center （MTOC） responsible for nucleating microtubules in both plants and animals. Whereas γ-tubulin is tightly associated with centrosomes that are inheritable organelles in cells of animals and most algae, it appears at different times and places to organize the myriad specialized microtubule systems that characterize plant cells. We have traced the distribution of γ-tubulin through the cell cycle in representative land plants （embryophytes） and herein present data that have led to a concept of the pleiomorphic and migratory MTOC. The many forms of the plant MTOC at spindle organization constitute pleiomorphism, and stage-specific “migration” is suggested by the consistent pattern of redistribution of γ-tubulin during mitosis. Mitotic spindles may be organized at centriolar centrosomes （only in final divisions of spermatogenesis）, polar organizers （POs）, plastid MTOCs, or nuclear envelope MTOCs （NE-MTOCs）. In all cases, with the possible exception of centrosomes in spermatogenesis, the γ-tubulin migrates to broad polar regions and along the spindle fibers, even when it is initially a discrete polar entity. At anaphase it moves poleward, and subsequently migrates from polar regions （distal nuclear surfaces） into the interzone （proximal nuclear surfaces） where interzonal microtubule arrays and phragmoplasts are organized. Following cytokinesis, γ-tubulin becomes associated with nuclear envelopes and organizes radial microtubule systems （RMSs）. These may exist only briefly, before establishment of hoop-like cortical arrays in vegetative tissues, or they may be characteristic of interphase in syncytial systems where they serve to organize the common cytoplasm into nuclear cytoplasmic domains （NCDs）.     

Post-translational tubulin modifications in spermatogeneous cells of the pteridophyteCeratopteris richardii

Summary Acetylation and tyrosinization are post-translational modifications of tubulin generally associated, respectively, with highly stable or dynamic microtubule arrays in animals and protists. Little is known of these modifications in land plants, however. We examined the presence and distribution of post-translational tubulin modifications in developing spermatogenous cells of the pteridophyteCeratopteris richardii by immunofluorescence and immunogold, utilizing antibodies specific for acetylated and tyrosinated tubulin. Acetylated tubulin is found in mid to late stage spermatogenous cells in stable microtubule configurations: the spline, flagella, and basal bodies. Tyrosinated tubulin, a modification associated with dynamic microtubule arrays, is also present in these structures as well as all other microtubules in the cell. The lamellar strip of the multilayered structure, a body previously described as tubulin-containing, was not labelled by any of the tubulin antibodies or antiserum. Treatment of cultures with the microtubule stabilizer taxol results in the appearance of new arrays of microtubules, including bundles in the cytoplasm. Only those new taxol-induced microtubule arrays present in mid to late stage cells (i.e., those with other normally acetylated tubulin arrays) have acetylated domains. Younger spermatogenous cells had similar microtubule bundles but no acetylated tubulin. Tyrosinated tubulin was found in all these taxol-stabilized arrays. These data indicate that, although these pteridophyte cells have the ability to acetylate tubulin, that this ability is limited to stages after the final spermatogenous cell mitosis and is limited to the highly stable spline and flagella microtubules.Abbreviations LS lamellar strip of multilayered structure - MTOC microtubule organizing center     

Probing microtubule organizing centres with MPM-2 in dividing cells of higher plants using immunofluorescence and immunogold techniques

Summary The localization in higher plant cells of phosphorylated proteins recognized by the monoclonal antibody MPM-2 was investigated, with particular attention to putative microtubule organizing centres (MTOCs). Immunofluorescence and immunogold electron microscopy showed that MPM-2 did not localize with most putative MTOCs in cells and protoplasts of the gymnospermPicea glauca and in cells of the angiospermVicia faba. The distribution of phosphoproteins detected by MPM-2 was similar during mitosis in both species. At late interphase and early prophase MPM-2 preferentially labelled nucleoli and the region around the condensing chromosomes but not the cytoplasm. General labelling of the cytoplasm followed dissolution of the nuclear envelope and by prometaphase centromeres stained strongly. At metaphase and very early anaphase kinetochores stained strongly by immunofluorescence but only weakly using immunogold; spindle microtubules (MTs) showed little staining. Kinetochore staining disappeared during anaphase and by telophase centromeres and loose regions of chromatin in reforming nuclei were labelled. Treatment with the anti-microtubular drug amiprophosmethyl (APM) showed that the phosphorylation/dephosphorylation cycle detected by MPM-2 proceeded independently of the mitotic spindle. Staining of centromeres/kinetochores with MPM-2 suggests that phosphorylation and dephosphorylation of this region of mitotic chromosomes may be involved in chromosome organization, chromatid separation and MT nucleation and/or attachment.Abbreviations APM amiprophos-methyl - DAPI 4,6-diamidino-2-phenylindole - EGTA ethylene glycol-bis(-aminoethyl ether) - FITC fluorescein isothiocyanate - MT microtubule - MTOC microtubule organizing centre - MtSB microtubule stabilizing buffer - PBS phosphate buffered saline - PBSB phosphate buffered saline with bovine serum albumin - PIPES piperazine-N,N-bis (2-ethanesulfonic acid) - PPB preprophase band - SPB spindle pole body - TRITC tetramethylrhodamine isothiocyanate     

Spline and flagellar microtubules are resistant to mitotic disrupter herbicides

Summary Microtubule arrays in developing spermatogenous cells of pteridophytes have unique microtubule organizing centers and post-translation modifications of tubulin. Sensitivity of these arrays to the microtubule-destabilizing effects of the mitotic disrupter herbicides was examined by immunofluorescence, transmission and immunogold electron microscopy. Acetylated, stabilized arrays, such as the spline, and microtubules of the basal bodies and flagella are formed after the final mitotic division and are resistant to these herbicides. Non-acetylated, dynamic arrays that exist prior to the final mitosis, such as interphase and mitotic arrays, are eliminated by all of these herbicides, with symptomology (arrested prometaphase, lobed nuclei, irregular cell plate formation) similar to that observed in other land plants. The only exception to the instability of these mitotic microtubule arrays are the few microtubules that are collected by kinetochores into short tufts. The presence of structurally-distinguishable MTOCs, such as the blepharoplast, did not confer resistance, despite the anchoring of the minus ends of the microtubules. Simultaneous treatment with herbicide and 5-bromodeoxyuridine (BrdU), with subsequent detection with anti-BrdU of cells that had gone through S-phase during the BrdU incubation, reveals that only acetylated arrays formed prior to herbicide treatment are resistant. These data indicate that only actively polymerizing, dynamic microtubule arrays are sensitive to the destabilizing effects of the mitotic disrupter herbicides.Abbreviations MTOC microtubule organizing center - BrdU 5-bromodeoxyuridine     

Microtubule patterns during meiosis in two higher plant species

Summary A monoclonal antibody to higher plant tubulin was used to trace microtubule (MT) structures by immunofluorescence throughout mitosis and meiosis in two angiosperms,Lycopersicon esculentum andOrnithogalum virens. Root tip cells showed stage specific MT patterns typical of higher plant cells. These included parallel cortical interphase arrays oriented perpendicular to the long axis of the cell, preprophase band MTs in late interphase through prophase, barrelshaped spindles, and finally phragmoplasts. Pollen mother cell divisions exhibited randomly oriented cortical MT arrays in prophase I, pointed spindles during karyokinesis, and elongate phragmoplasts. A preprophase band was not observed in either meiotic division. MT initiation sites were seen as broad zones associated with the nuclear envelope.     

Effects of {gamma}-tubulin complex proteins on microtubule nucleation and catastrophe in fission yeast

Although gamma-tubulin complexes (gamma-TuCs) are known as microtubule (MT) nucleators, their function in vivo is still poorly defined. Mto1p (also known as mbo1p or mod20p) is a gamma-TuC-associated protein that recruits gamma-TuCs specifically to cytoplasmic MT organizing centers (MTOCs) and interphase MTs. Here, we investigated gamma-TuC function by analyzing MT behavior in mto1Delta and alp4 (GCP2 homologue) mutants. These cells have free, extra-long interphase MTs that exhibit abnormal behaviors such as cycles of growth and breakage, MT sliding, treadmilling, and hyperstability. The plus ends of interphase and spindle MTs grow continuously, exhibiting catastrophe defects that are dependent on the CLIP170 tip1p. The minus ends of interphase MTs exhibit shrinkage and pauses. As mto1Delta mutants lack cytoplasmic MTOCs, cytoplasmic MTs arise from spindle or other intranuclear MTs that exit the nucleus. Our findings show that mto1p and gamma-TuCs affect multiple properties of MTs including nucleation, nuclear attachment, plus-end catastrophe, and minus-end shrinkage.     

The microtubular cytoskeleton during development of the zygote,proembryo and free-nuclear endosperm inArabidopsis thaliana (L.) Heynh

The microtubular cytoskeleton has been studied during development of the zygote, proembryo and free-nuclear endosperm inA. thaliana using immunofluorescence localization of tubulin in enzymatically isolated material. Abundant micro tubules (MTs) are found throughout proembryogenesis. Microtubules in the coenocytic endosperm are mainly internal. By contrast, there is a re-orientation of MTs to a transverse cortical distribution during zygote development, predominantly in a subapical band which accompanies a phase of apical extension. The presence of these cortical arrays coincides with the elongation of the zygote. Cortical arrays also accompany elongation of the cylindrical suspensor. Extensive networks of MTs ramify throughout the cytoplasm of cells in the proembryo proper. Perinuclear arrays are detected in a number of cell types and MTs contribute to typical mitotic configurations during nuclear divisions. Preprophase bands of MTs are absent throughout megasporogenesis and embryo-sac development and do not occur in endosperm cell divisions. We have observed MTs throughout the first division cycle of the zygote. By placing the observed stages in a most probable sequence, we have identified this cell cycle as the point during embryogenesis at which a preprophase band is reinstated as a regular feature of cell division. Preprophase bands were observed to predict planes of cytokinesis in cell divisions up to the octant stage.Abbreviations DIC differential interference contrast optics - MT microtubule - PPB preprophase band of microtubule We thank Ms. Margaret Travers for her helpful English translation of Yakovlev and Alimova (1976) and Mr. James Whitehead for preparation of Fig. 11. M.C.W. was supported by an Australian Postgraduate Research Award.     

Induction of random microtubule polymerization in cold and drug-treated PtK1 cells following hyperosmotic shock treatment

The effects of hypertonic sucrose on spindle and interphase microtubule (MT) arrays of PtK1 cells were investigated by incubating cells in complete culture medium at 4 degrees or 37 degrees C, with or without hypertonic sucrose, nocodazole or vinblastine (VLB). Results from anti-tubulin immunofluorescence showed that sucrose-induced alterations of spindle morphology seen at 37 degrees C did not occur at cold temperatures, but cold-induced MT loss was diminished. Application of warm hypertonic sucrose following depolymerization of MTs by nocodazole or cold resulted in the formation of a "feltwork" of randomly oriented, short MTs throughout the cytoplasm. These results, and those obtained substituting VLB for nocodazole, suggest that the effects of sucrose depend on the cytoplasmic concentration of soluble tubulin and support the hypothesis that osmotic factors are involved in effects of hypertonic sucrose on MT organization.     

Microtubule organization requires cell cycle-dependent nucleation at dispersed cytoplasmic sites: polar and perinuclear microtubule organizing centers in the plant pathogen Ustilago maydis

Growth of most eukaryotic cells requires directed transport along microtubules (MTs) that are nucleated at nuclear-associated microtubule organizing centers (MTOCs), such as the centrosome and the fungal spindle pole body (SPB). Herein, we show that the pathogenic fungus Ustilago maydis uses different MT nucleation sites to rearrange MTs during the cell cycle. In vivo observation of green fluorescent protein-MTs and MT plus-ends, tagged by a fluorescent EB1 homologue, provided evidence for antipolar MT orientation and dispersed cytoplasmic MT nucleating centers in unbudded cells. On budding gamma-tubulin containing MTOCs formed at the bud neck, and MTs reorganized with >85% of all minus-ends being focused toward the growth region. Experimentally induced lateral budding resulted in MTs that curved out of the bud, again supporting the notion that polar growth requires polar MT nucleation. Depletion or overexpression of Tub2, the gamma-tubulin from U. maydis, affected MT number in interphase cells. The SPB was inactive in G2 phase but continuously recruited gamma-tubulin until it started to nucleate mitotic MTs. Taken together, our data suggest that MT reorganization in U. maydis depends on cell cycle-specific nucleation at dispersed cytoplasmic sites, at a polar MTOC and the SPB.     

Structural and immunocytochemical characterization of the Ginkgo biloba L. sperm motility apparatus

Summary. Ginkgo biloba and the cycads are the only extant seed plants with motile sperm cells. However, there has been no immunocytochemical characterization of these gametes to determine if they share characteristics with the flagellated sperm found in bryophytes and pteridophytes or might give clues as to the relationships to nonflagellated sperm in all other seed plants. To determine characteristics of proteins associated with the motility apparatus in these motile sperm, we probed thin sections of developing spermatogenous cells of Ginkgo biloba with antibodies to acetylated and tyrosinated tubulin and monoclonal antibodies that recognize mammalian centrosomes and centrin. The blepharoplast that occurs as a precursor to the motility apparatus consists of an amorphous core, pitted with cavities containing microtubules and a surface studded with probasal bodies. The probasal bodies and microtubules within the blepharoplast cavities are labeled with antibodies specific to acetylated tubulin. Positive but weak reactions of the blepharoplast core occur with the centrosomereactive antibodies MPM-2 and C-9. Reactions to centrin antibodies are negative at this developmental stage. From this pre-motility apparatus structure, an assemblage of about 1000 flagella and associated structures arises as the precursor to the motility apparatus for the sperm. The flagellar apparatus consists of a three-layered multilayered structure that subtends a layer of spline microtubules, a zone of amorphous material similar to that in the blepharoplast, and the flagellar band. Centrin antibodies react strongly with the multilayered structure, the transition zone of the flagella, and fibrillar material near the flagellar base at the surface of the amorphous material. Both the spline microtubules and all of the tubules in the flagella react strongly with the antibodies to acetylated tubulin. These localizations are consistent with the localizations of these components in pteridophyte and bryophyte spermatogenous cells, although the blepharoplast material surrounding and connecting flagellar bases does not occur in the seedless (nonseed) land plants. These data indicate that despite the large size of ginkgo gametes and the taxonomic separation between pteridophytes and Ginkgo biloba, similar proteins in gametes of both groups perform similar functions and are therefore homologous among these plants. Moreover, the presence of acetylated tubulin in bands of microtubules may be a characteristic shared with more derived non-flagellated sperm of other conifers and angiosperms. Correspondence and reprints: Southern Weed Science Research Unit, USDA Agricultural Research Service, P.O. Box 350, Stoneville, MS 38776, U.S.A.     

Non-centrosomal microtubule-organising centres in cold-treated cultured Drosophila cells

In this paper we describe a new type of non-centrosomal microtubule-organising centre (MTOC), which is induced by cold treatment of certain cultured Drosophila cells and allows rapid reassembly of microtubule (MT) arrays. Prolonged cooling of two types of cultured Drosophila cells, muscle cells in primary culture and a wing imaginal disc cell line Cl.8+ results in disassembly of MT arrays and induces the formation of clusters of short MTs that have not been described before. Upon rewarming, the clusters are lost and the MT array is re-established within 1 h. In Cl.8+ cells, gamma-tubulin-containing centrosomes are detected, both in cell extensions and in the expected juxtanuclear position, and gamma-tubulin co-localises with the cold-induced MT clusters. The MT plus-end-binding protein, Drosophila EB1, decorates growing tips of MTs extending from clusters. We conclude that the cold-induced MT clusters represent acentrosomal MTOCs, allowing rapid reassembly of MT arrays following exposure to cold.     

Microtubule orientation and dynamics in elongating characean internodal cells following cytosolic acidification, induction of pH bands, or premature growth arrest

Summary Cortical microtubules (MTs) at indifferent zones in immatureNitella internodes were investigated by injection of fluorescently tagged sheep brain tubulin into living cells and by immunofluorescence on fixed material. Nearly identical MT patterns and numbers were detected with the two techniques, indicating that sheep brain tubulin incorporated into all cortical MTs. MTs were aligned transversely to the long axis of the cell and approximately one MT was present every micrometer of longitudinal cell distance. Treatment of internodes with propionic acid to acidify cytosolic pH caused depolymerization of MTs and an increase in the unpolymerized tubulin pool. Transfer of young, vigorously elongating cells to media inducing premature growth cessation resulted in a slight decrease in microtubule numbers but did not significantly alter microtubule orientation patterns or microtubule lifespans. MTs remained transverse for days following growth cessation before finally assuming a more random alignment characteristic of mature, non-growing internodes. No differences in MT numbers, orientation, or dynamics were detected between acid and alkaline bands in internodes incubated in a band-inducing medium. Thus, properties of cortical MT arrays were not closely coupled to growth status or to regional differences in cellular physiology associated with pH banding.Abbrevations BIM band-inducing medium - CCM Chara culture medium - CF carboxyfluorescein - FRAP fluorescence redistribution after photobleaching - MT microtubule     

Dynamics of microtubule reassembly and reorganization in the coenocytic green alga Ernodesmis verticillata (Kützing) Børgesen

The dynamics of microtubule (MT) disassembly and reassembly were studied in the green alga Ernodesmis verticillata, using indirect immunofluorescent localization of tubulin. This alga possesses two distinct MT arrays: highly-ordered, longitudinally-oriented cortical MTs, and shorter perinuclear MTs radiating from nuclear surfaces. Perinuclear MTs are very labile, completely disassembling in the cold (cells on ice) within 5–10 min or in 25 μM amiprophos-methyl (APM) within 15–30 min. Although cortical MTs are generally absent after 3 h in APM, it takes 45–60 min before any cold-induced depolymerization is apparent, and some cortical MTs persist after 6 h of cold treatment. The extent of immunofluorescence of cytoplasmic (depolymerized?) tubulin is inversely proportional to the abundance of cortical MTs. Recovery of MT arrays upon warming or upon removal of APM occurs within 30–60 min for the perinuclear MTs, but the cortical arrays take much longer to regain their normal patterns. The cortical MTs initially reappear in a random distribution with respect to the cell axis, but within 3–4 d of warming (or 24–36 h of removing APM) they are nearly parallel to each other and to the cell's longitudinal axis. Thus, although the timing differs, the actual patterns of depolymerization and recovery are similar, irrespective of whether physical or chemical agents are used. Longer-term treatments in 1 μM APM indicate that despite the rapid disappearance of perinuclear MTs, a loss of the uniform nuclear spacing occurs gradually over 1–6 d. Similar disorganization of nuclei is obtained with long-term treatment with 1 μM taxol, where a gradual loss of perinuclear MTs is accompanied by an increased abundance of mitotic spindles. This implies that perinuclear MTs can disassemble in vivo in the presence of taxol, and that they are not the sole components involved in maintaining nuclear spacing in these coenocytes. The results indicate that both nuclear and cortical sites of MT nucleation may exist in this organism, and that MT reassembly and re-organization are temporally distinct events in cells that have highly-ordered arrays of long MTs.     

Microtubule Cytoskeleton Remodeling by Acentriolar Microtubule-organizing Centers at the Entry and Exit from Mitosis in Drosophila Somatic Cells

Cytoskeleton microtubules undergo a reversible metamorphosis as cells enter and exit mitosis to build a transient mitotic spindle required for chromosome segregation. Centrosomes play a dominant but dispensable role in microtubule (MT) organization throughout the animal cell cycle, supporting the existence of concurrent mechanisms that remain unclear. Here we investigated MT organization at the entry and exit from mitosis, after perturbation of centriole function in Drosophila S2 cells. We found that several MTs originate from acentriolar microtubule-organizing centers (aMTOCs) that contain γ-tubulin and require Centrosomin (Cnn) for normal architecture and function. During spindle assembly, aMTOCs associated with peripheral MTs are recruited to acentriolar spindle poles by an Ncd/dynein-dependent clustering mechanism to form rudimentary aster-like structures. At anaphase onset, down-regulation of CDK1 triggers massive formation of cytoplasmic MTs de novo, many of which nucleated directly from aMTOCs. CDK1 down-regulation at anaphase coordinates the activity of Msps/XMAP215 and the kinesin-13 KLP10A to favor net MT growth and stability from aMTOCs. Finally, we show that microtubule nucleation from aMTOCs also occurs in cells containing centrosomes. Our data reveal a new form of cell cycle–regulated MTOCs that contribute for MT cytoskeleton remodeling during mitotic spindle assembly/disassembly in animal somatic cells, independently of centrioles.     

A highly divergent gamma-tubulin gene is essential for cell growth and proper microtubule organization in Saccharomyces cerevisiae

A Saccharomyces cerevisiae gamma-tubulin-related gene, TUB4, has been characterized. The predicted amino acid sequence of the Tub4 protein (Tub4p) is 29-38% identical to members of the gamma-tubulin family. Indirect immunofluorescence experiments using a strain containing an epitope-tagged Tub4p indicate that Tub4p resides at the spindle pole body throughout the yeast cell cycle. Deletion of the TUB4 gene indicates that Tub4p is essential for yeast cell growth. Tub4p-depleted cells arrest during nuclear division; most arrested cells contain a large bud, replicated DNA, and a single nucleus. Immunofluorescence and nuclear staining experiments indicate that cells depleted of Tub4p contain defects in the organization of both cytoplasmic and nuclear microtubule arrays; such cells exhibit nuclear migration failure, defects in spindle formation, and/or aberrantly long cytoplasmic microtubule arrays. These data indicate that the S. cerevisiae gamma- tubulin protein is an important SPB component that organizes both cytoplasmic and nuclear microtubule arrays.     

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     

How do Plants Organize Microtubules Without a Centrosome？

A microtubule nucleates from a γ-tubuUn complex, which consists of γ-tubulin, proteins from the SPC971SPC98 family, and the WD40 motif protein GCP-WD. We analyzed the phylogenetic relationships of the genes encoding these proteins and found that the components of this complex are widely conserved among land plants and other eukaryotes. By contrast, the interphase and mitotic arrays of microtubules in land plants differ from those in other eukaryotes. In the interphase cortical array, the majority of microtubules nucleate on existing microtubules in the absence of conspicuous microtubule organizing centers （MTOCs）, such as a centrosome. During mitosis, the spindle also forms in the absence of conspicuous MTOCs. Both poles of the spindle are broad, and branched structures of microtubules called microtubule converging centers form at the poles. In this review, we hypothesize that the microtubule converging centers form via microtubule-dependent microtubule nucleation, as in the case of the interphase arrays. The evolutionary insights arising from the molecular basis of the diversity in microtubule organization are discussed.     

蕨类植物精细胞运动器和细胞骨架的研究

介绍了近年来蕨类植物游动精子运动器和细胞骨架的研究进展。游动精子由配子体精子器中的非运动细胞发育形成,其分化过程包括了运动器官和细胞骨架的合成和组装。精子发生过程中形成的运动器的各部分结构包括鞭毛、基体、多层结构及附属结构;基体是细胞中新形成的结构,在不同类群的蕨类植物中分别由双中心粒、分支生毛体和生毛体产生。鞭毛、基体和多层结构中的微管带形成了游动精子三个独特的微管列阵,由于微管蛋白的后修饰作用这些微管列阵十分稳定;centrin是运动器中的重要成分, 但功能尚不清楚,可能和细胞骨架及运动器的构建有关。     

Microtubule arrays in differentiated cells contain elevated levels of a post-translationally modified form of tubulin

Tyrosinated (Tyr) and detyrosinated (Glu) alpha-tubulins are post-translationally modified species that differ by a single amino acid at their respective C-termini. We have examined the distribution of these two species by immunofluorescence in proliferating and differentiated cells using antisera specifically reactive with each of the forms. In proliferating PtK1 cells, Tyr tubulin was the predominant form in almost every cytoplasmic microtubule (MT); only a few MTs contained detectable Glu tubulin. In contrast, staining of centrioles and primary cilia of PtK1 cells suggested that Glu tubulin was the predominant form in these stable assemblies of MTs. An examination of the distribution (by immunofluorescence) and relative amount (by immunoblot analysis) of the two forms of tubulin in the stable assemblies of MTs present in cultured neuronal cells (neurites), sperm and tracheal cells (axonemes and basal bodies), and platelets and erythrocytes (marginal bands) revealed that, in general, the MTs in these arrays contained substantially elevated levels of Glu tubulin in comparison with the levels in MTs of cultured cells. The one exception, the marginal band of toad erythrocytes, which contained only Tyr tubulin, demonstrates that an elevated level of Glu tubulin is not an obligate feature of a stable array of MTs. Nonetheless, an elevated level of Glu tubulin may be a useful indicator of stable MTs in differentiated cells. It is important to note that commonly used sources of tubulin (e.g., brain or flagella) necessarily yield tubulin that differs strikingly from tubulin of proliferating cells in its content of Glu tubulin.(ABSTRACT TRUNCATED AT 250 WORDS)