Arrangement of cortical microtubules in the shoot apex of Vinca major L.

The arrangements of cortical microtubules (MTs) and of cellulose microfibrils in the median longitudinal cryosections of the vegetative shoot apex of Vinca major L., were examined by immunofluorescence microscopy and polarizing microscopy, respectively. The arrangement of MTs was different in the various regions of the apex: the MTs tended to be arranged anticlinally in tunica cells, randomly in corpus cells, and transversely in cells of the rib meristem. However, in the inner layers of the tunica in the flank region of the apex, cells with periclinal, oblique or random arrangements of MTs were also observed. In leaf primordia, MTs were arranged anticlinally in cells of the superficial layers and almost randomly in the inner cells. Polarizing microscopy of cell walls showed that the arrangement of cellulose microfibrils was anticlinal in tunica cells, random in corpus cells, and transverse in cells of the rib meristem; thus, the patterns of arrangement of microfibrils were the same as those of MTs in the respective regions. These results indicate that the different patterns of arrangement of MTs and microfibrils result in specific patterns of expansion in the three regions. These differences may be necessary to maintain the organization of the tissues in the shoot apex.Abbreviations MT(s) microtubule(s) - lp length of the youngest leaf primordium     

微管解聚对生长因子在DNA合成中的作用

本实验探讨了生长因子和胞质微管在刺激G_0期C3H/10 T1/2细胞进入S期合成DNA中的作用及其相互关系。结果表明,PPP(pla- telet-poor plasma)不具有刺激DNA合成的能力,浓度在30ng/ml以上的EGF仅能刺激部分G_0期细胞进入S期,而50ng/ml EGF与5%PPP共同作用时,则表现出它们间具有较强的协同剌激作用,其刺激DNA合成的效果基本上达到与10%血清相同。Taxol可抑制微管的解聚,G_0期细胞经其处理后,使微管处于稳定状态时能明显抑制血清或EGF+PPP对细胞合成DNA的刺激作用。这种抑制作用在G_0期细胞进入S期的早期阶段即表现出来,说明只有生长因子的刺激作用而无微管的解聚,细胞便不能从G_0期进入S期。G_0期细胞经秋水仙酰胺处理使微管解聚后,则能提高血清或EGF+PPP对DNA合成的刺激作用。同样地,这种刺激作用也在G_0期细胞进入S期的早期阶段即表现出来。但秋水仙酰胺单独处理G_0期细胞,虽使微管处于解聚状态,若无生长因子存在,则无刺激作用,G_0期细胞便不能进入S期。因此,生长因子之间的协同刺激作用和微管的解聚是G_0期C3H/10 T1/2细胞进入S期进行DNA合成的两个必要条件。     

Morphogenetic processes inAttheya decora (Bacillariophyceae,Biddulphiineae)

The valva of the diatomAttheya decora is formed within a silica deposition vesicle which enlarges centrifugally by the fusion of small vesicles. The silica deposition vesicle can already be seen when the spindle has not yet disappeared completely. Valva formation seems to begin with the shaping of an organic matrix within a silica deposition vesicle. Later, this material silicifies. The complicated shape of the labiate process is preformed by the silica deposition vesicle, the inner membrane of which is associated with electron dense material on both faces. The horns are formed when the expanding silica deposition vesicle has reached the cell corners. They are elaborated without participation of microtubules. Swelling of local depositions of polysaccharides seems to provide the forces that spread the silicified horns during daughter cell separation and to cause the local spontaneous plasmolyses under the valva and along the cell flanks in the region of the intercalary bands. The inner organic wall layers and the organic continuations of the intercalary bands are formed on the surface of the plasmalemma; each of the continuations is produced simultaneously with the intercalary band belonging to it and becomes attached to the latter when the silica deposition vesicle opens.     

African swine fever virus interaction with microtubules

The role of microtubules in intracellular transport of African swine fever virus (ASFV) and virus-induced inclusions was studied by immunofluorescence using anti-ASFV and anti-tubulin antibodies, by electron microscopy of infected Vero cells and by in vitro binding of virions to purified microtubules. MTC, a reversible colchicine analogue, was used to depolymerize microtubules. In cells treated with MTC multiple large inclusions containing ASFV antigens and particles were observed in the cytoplasm. Removal of the drug lead to migration and fusion of the inclusions at a perinuclear location. To study the effect of microtubule repolymerization on virus particle distribution, the particles were counted in thin sections of MTC treated cells and at different times after removal of the drug. In cells treated with MTC 6.8% and 3.6% of the virus particles were found respectively in the cytoplasm and at the cell membrane while 38% of the particles were located around the virosome. With reversal of the drug effect the number of virus particles around the virosomes progressively decreased to 10% at 2 h while the number of particles in the cytoplasm and at the cell membrane increased. At 2 h after removal of the drug 33.5% of the particles were found budding from the cell membrane. Virus particles were found closely associated with microtubules in cytoskeletons obtained by Triton X-100 extraction of taxol treated cells. The association of virus particles with microtubules was also observed in vitro using purified microtubules and virus particles. The results show that microtubules are involved in the transport of African swine fever virus particles from the assembly site to the cell surface and in the movement and fusion of the virus inclusions.     

STRUCTURE AND PHYSIOLOGY OF THE HAPTONEMA IN CHRYSOCHROMULINA (PRYMNESIOPHYCEAE). I. FINE STRUCTURE OF THE FLAGELLAR/HAPTONEMATAL ROOT SYSTEM IN C. ACANTHA AND C. SIMPLEX1

The intracellular structural relationships between the flagella and haptonema in Chrysochromulina acantha Leadbeater & Manton (Prymnesiophyceae) were studied in detail and a reconstruction is presented. Three micro-tubular roots are associated with the flagellar apparatus. The largest, consisting of a sheet of approximately 20 microtubules, has its origins at the base of the left basal body. The main body of microtubules passes over the surface of a mitochondrion toward the left chloroplast and apparently terminates at a pair of microtubules oriented perpendicularly to it. Four microtubules diverge from the sheet and pass behind the left basal body. Two other roots–one consisting of a 2 + 2 + 1 arrangement of microtubules, the other of a single microtubule only—are associated with the right basal body. The two basal bodies are connected by distal and proximal fibers, and they are linked also to the base of the haptonema, three fibers extending from the haptonemal base to the right basal body, one only to the left. An additional fiber extending from the right basal body passes between the left basal body and the base of the haptonema, terminating at the largest microtubular root. Lateral extensions link this fiber to both the left basal body and the haptonematal base. Negative staining of isolated root systems of C. simplex Estep et al. shows that the arrangement of microtubules and fibrous connections is similar to that in C. acantha. The root system of C. acantha is compared to those of other members of the Prymnesiophyceae.     

Impact of taxol-mediated stabilization of microtubules on nuclear morphology,ploidy levels and cell growth in maize roots

Direct contact of the radiating perinuclear microtubules (MTs) with the nuclear envelope was visualized with an immunogold technique using specific monoclonal tubulin antibody. The possibility that these perinuclear MT arrays are involved in establishing and maintaining nuclear organization during the interphase of cycling cells in maize root meristems was tested using taxol, a MT-stabilizing agent. Taxol not only stabilized all MTs against the action of the MT-disrupters colchicine and oryzalin but also prevented these agents from their usual induction of nuclear enlargement and decondensation of nuclear chromatin. On the contrary, nuclear size decreased and the chromatin became more compact in mitotically cycling cells of the taxol-treated root apices. Moreover, taxol prevented the stimulation, by colchicine and oryzalin, of the onset of the S phase in cells of the quiescent centre and proximal root meristem. Exposure of maize roots to taxol strongly decreased final cell volumes, suggesting that the more condensed nuclear chromatin is less efficient in genome expression and that this accounts for the restriction of cellular growth. All these findings support the hypothesis that MT arrays, radiating from the nuclear surface, are an essential part of an integrated plant ‘cell body’ consisting of nucleus and the MT cytoskeleton, and that they regulate, perhaps via their impact on chromatin condensation and activity, progress through the plant cell cycle.     

Trypanosoma cruzi Infection of BSC-1 Fibroblast Cells Causes Cytoskeletal Disruption and Changes in Intracellular Calcium Levels

ABSTRACT The disruption of vimentin and actin filaments of host BSC-1 fibroblast cells by Trypanosoma cruzi was investigated using a mouse monoclonal anti-vimentin antibody and rhodamine phalloidin, respectively. Indirect immunofluorescence microscopy demonstrated that infection of BSC-1 cells by T. cruzi caused disruption of both cytoskeletal components. The disruption was greater as infection progressed. Mechanisms other than mechanical ones may play a role in the disruption since disrupted cytoskelelal elements were well removed from the parasites. In the determination of intracellular calcium concentrations using Fura-2 AM, infected and uninfected cells both showed an initial increase in intracellular calcium levels. At later times of infection (3 to 5 days), intracellular calcium levels of infected cells were significantly lower than those of control cells. There was no specific localization of intracellular calcium in the infected host cells as determined by image analysis.     

Morphological aspects of chromosome spindle fibres inMesostoma: “microtubular fir-tree” structures and microtubule association with kinetochores and chromatin

Summary Bipolarly oriented bivalents in spermatocytes of the turbellarianMesostoma ehrenbergii, displaying fast oscillatory movements in metaphase, were studied with the electron microscope. Kinetochores and chromosome fibres were reconstructed using serial sections cut perpendicular to the spindle axis. Only a small proportion of kinetochore microtubules (kMT) is continuous between the kinetochore and the centrosome. kMTs intermingle with non-kinetochore microtubules (non-kMTs), partly inclined with regard to the kMTs, thus forming a chromosome fibre MT lattice. This resembles the microtubular fir-tree structures (MTFT) described by Bajer and Molè-Bajer inHaemanthus endosperm mitosis. A minimal function of the MTFT may be the anchorage of kMTs in the polar region. Regarding the association of MTs with the chromosome, three types of attachment can be discriminated: (1) normal insertion of kMT plus ends in the kinetochore, (2) penetration of kinetochores and deep insertion in the chromatin, and (3) lateral attachment with kinetochore and chromatin. Lateral association of MTs seems to be mediated by filamentous crossbridges. The observations are discussed in connection with possible behaviour of kMTs during kinetochore movement.Abbreviations kMT kinetochore microtubules - MAP microtubule-associated protein - non-kMT non-kinetochore microtubules - MTFT microtubular fir-tree - PCM pericentriolar material     

Presence and absence of the preprophase band of microtubules in moss protonemata: a clue to understanding its function?

Summary InFunaria protonemata, preprophase bands (PPBs) of microtubules do not develop when the tip cell divides, when side branches are initiated or in intercalary regeneration divisions. We report here that PPBs do, however, develop when a tmema cell is formed. In the former cases, cell division is not coupled with an expansion of the mother cell wall at the site where the cell plate will attach. In the latter case, the mother cell wall ruptures at that site and the tmema cell elongates. This observation and the findings on presence and absence of the PPB in other cell types indicate a connection between PPB occurrence and mother cell wall expansion. They support the idea that the PPB might be involved in the local secretion of cell wall material. We extend this notion, suggesting that the microtubules of the PPB control the oriented deposition of a thin layer of cellulose microfibrils at the mother cell wall which supports the firm attachment of the cell plate when the mother cell wall expands.Abbreviations FITC fluorescein isothiocyanate - IgG immunoglobulin G - MT microtubule - PPB preprophase band of microtubules - TC tmema cell     

Cytochalasin induces spindle fusion in the syncytial blastoderm of the early Drosophila embryo.

Microfilament integrity is needed to maintain the regular arrangement of the spindle microtubules and to guarantee the normal progression of the last syncytial mitoses in Drosophila embryo. To investigate when and how microfilaments participate in this process, we incubated permeabilized embryos with the inhibitor of actin polymerization, cytochalasin B, at different times during the nuclear cycle. Our results suggest that the correct microfilament distribution is only required for the appropriate segregation of nuclei during the 11th, 12th and 13th syncytial mitoses rather than during the 10th mitosis when the spindles are too far apart to interact. When cytochalasin B treatment was performed during the last syncytial mitoses many spindles fuse among them and the regular mitotic progression is perturbed.