Cell division in caffeine-induced binucleate protonemal cells ofAdiantum. II. Formation of the preprophase band and cell division in centrifuged and non-centrifuged cells

Organization of microtubules (MTs) in relation to the behavior of nuclei was examined in dividing binucleate cells ofAdiantum capillus-veneris L. To induce binucleate cells, caffeine, an inhibitor of formation of the cell plate, was applied at 4 mM to synchronously dividing protonemal cells during cytokinesis (Murata and Wada 1993). Formation of the preprophase band (PPB) during the next cell cycle was examined in non-centrifuged and centrifuged cells. The two nuclei were separated or associated with one another in both non-centrifuged and centrifuged cells, although the location of the nuclei in the cylindrical protonemal cells was different (Murata and Wada 1993). Irrespective of centrifugation, a single PPB was formed around the nuclei in cells with associated nuclei. Two PPBs were formed in cells with separated nuclei in centrifuged cells. Patterns of mitosis and cytokinesis varied, depending on the location of the PPB and the distribution of the nuclei. The role of the nucleus in formation of the PPB is discussed.     

The effect of taxol onTriticum preprophase root cells: preprophase microtubule band organization seems to depend on new microtubule assembly

Summary To examine whether preprophase microtubule band (PPB) organization occurs by rearrangement of pre-existing, or by assembly of new microtubules (Mts), we treated root cells ofTriticum turgidum with taxol, which stabilizes pre-existing Mts by slowing their depolymerization. With taxol early preprophase cells failed to form a normal PPB and PPB narrowing was prevented in cells that had already formed a wide one. The PPB became persistent in prometaphase cells and the formation of multipolar prophase-prometaphase spindles was induced. These data favour the suggestion that PPB formation and narrowing, as well as prophase spindle development, are dynamic processes depending on continuous Mt assembly at the PPB site and in the perinuclear cytoplasm.Abbreviations Mt microtubule - MTOC microtubule organizing centre - PPB preprophase microtubule band - DMSO dimethyl sulfoxide     

Effects of microtubule-disruptive and membrane-stabilizing agents on low density lipoprotein metabolism by cultured human fibroblasts

The cellular mechanisms involved in the uptake and metabolism of low density lipoprotein (LDL) by cultured normal human fibroblasts have been investigated with the aid of drugs known to disrupt cytoplasmic microtubules or to inhibit membrane fusion.Two drugs which disrupt microtubules by differing mechanisms, colchicine and vinblastine, each reduced the high affinity surface binding of ¹²⁵I-labelled LDL by fibroblasts. Associated reductions of the endocytosis and degradation of the lipoprotein could be attributed almost entirely to this effect. In contrast, lumicolchicine, an analogue of colchicine without microtubule-disruptive activity, had little or no effect on ¹²⁵I-labelled LDL metabolism.Each of two groups of membrane-stabilizing agents, the phenothiazines and the tertiary amine local anaesthetics, directly inhibited both the internalization of ¹²⁵I-labelled LDL following high affinity binding to cell surface receptors and the catabolism of the lipoprotein subsequent to endocytosis, supporting previous morphological evidence for the importance of membrane fusion in these processes.     

The 72-kDa Microtubule-Associated Protein from Porcine Brain

A microtubule-associated protein (MAP) with a molecular mass of 72-kDa that was purified from porcine brain by using its property of heat stability in a low pH buffer was characterized. Low-angle rotary shadowing revealed that the 72-kDa protein was a rodlike protein approximately 55-75 nm long. The 72-kDa protein bound to microtubules polymerized from phosphocellulose column-purified tubulin (PC-tubulin) with taxol and promoted the polymerization of PC-tubulin in the absence of taxol. Microtubules polymerized by the 72-kDa protein showed a tendency to form bundles of several microtubules. Quick-freeze, deep-etch electron microscopy revealed that the 72-kDa protein formed short crossbridges between microtubules. We performed peptide mapping to analyze the relationship of the 72-kDa protein to other heat-stable MAPs, and the results showed some resemblance of the 72-kDa protein to MAP2. Cross-reactivity with a monoclonal anti-MAP2 antibody further suggested that the 72-kDa protein and MAP2 are immunologically related. To study the relationship between the 72-kDa protein and MAP2C, a smaller molecular form of MAP2 identified in juvenile rat brain, we prepared the 72-kDa protein from rat brain by the same method as that used for porcine brain. The fact that the 72-kDa protein from juvenile rat brain was also stained with our monoclonal anti-MAP2 antibody also suggested that the 72-kDa protein is an MAP2C homologue of the porcine brain.     

Microtubule associated proteins of goat brain

The microtubule associated proteins of goat brain were separated from tubulin on the basis of their thermostability and then fractionated by chromatography on Sepharose 4B column. Analysis of the fractions by SDS-Polyacrylamide gel electrophoresis and assay of their tubulin-assembly-promoting activity indicate that this activity resides primarily in the tauproteins (mol. wt. 55,000–70,000) and a class of even lower molecular weight (25,000–35,000) proteins. Electrophoresis of the microtubule associated protein fractions separated from tubulin by phosphocellulose chromatography are in agreement with the results obtained from fractionation on Sepharose 4B columns.     

An electron microscopic study on the mating tube formation in the heterobasidiomycete Tremella mesenterica

Ultrastructure of the mating tube formed in yeast haplont of the heterobasidiomycete Tremella mesenterica was studied by electron microscopy. Cell wall of the mating tube emerged as evagination of the inner layers, rupturing outer layers of the mother cell wall. Comparison with budding cells suggested that the tube emergence place at bud scar and the process of tube emergence was the same as that of bud emergence. Electron transparent vesicles of 0.1 m diameter were scattered in the cytoplasm of the mating tube. Nucleus-associated organelle was located at one side of the nuclear envelope which extended towards the mating tube. A few microtubules were detected in the mating tube, but their association with a nucleus was not clear. The cytoplasmic structure of the mating tube was discussed in comparison with that of hyphae of the filamentous fungi.     

The changes of nuclear position and distribution of circumferentially aligned cortical microtubules during the progression of cell cycle inAdiantum protonemata

The intracellular positions of the nucleus and of cortical, circumferentially aligned microtubules (CCAM) in filamentous, single-celled protonemata ofAdiantum capillus-veneris were determined throughout the cell cycle in the dark. When apical growth continued at G₁ phase, the nucleus migrated keeping a constant distance from the tip. When the apical growth stopped at late S or G₂ phase, the nucleus stopped moving forward and then slightly moved backward to the site of cytokinesis. The CCAM were found only in the dome of protonemal tip when growing under continuous red light; they increased in number after dark incubation for 12 hr and then decreased after 20th hr in the dark. The CCAM were usually observed in the region between the nucleus and the tip at 28 hr in the dark. They were located around the nuclear region at pre-prophase and prophase, but then totally disappeared at metaphase and thereafter.     

Association of centrioles with clusters of apical vesicles in mitotic thyroid epithelial cells. Are centrioles involved in directing secretion?

Summary The ultrastructure of thyroid epithelial cells in mitosis has been investigated. A spatial association is described between clusters of apical vesicles (believed to contain thyroglobulin destined for secretion into the follicular lumen) and centrioles, in late prophase and late telophase cells. Quantitative techniques demonstrate the statistical significance of this association and suggest that it is not related to proximity of the Golgi apparatus or to the location of the centriole in the cell, which changes considerably during these phases of mitosis. The physical basis for this association remains uncertain, but microtubules emanating from the pericentriolar area may be involved.In interphase cells, centrioles are located very close to the follicular lumen, where the majority of apical vesicles are also found. The association of centrioles with clusters of apical vesicles also in mitotic cells suggests that in interphase cells the apically located centrioles may serve as a focus for apical vesicles, helping to direct these secretory vesicles toward the follicular lumen and to maintain cellular polarization. Previous studies demonstrating that centrioles can act as microtubule organizing centers in interphase cells and studies linking microtubules and secretion also tend to support this hypothesis.The author is grateful to Drs. Jan Wolff, Lars E. Ericson, and Seymour H. Wollman for useful discussions and to Mr. Franklin E. Reed for expert technical assistance.     

In vivo comparison of N-11CH3 vs O-11CH3 radiolabeled microtubule targeted PET ligands

Altered dynamics of microtubules (MT) are implicated in the pathophysiology of a number of brain diseases. Therefore, radiolabeled MT targeted ligands that can penetrate the blood brain barrier (BBB) may offer a direct and sensitive approach for diagnosis, and assessing the clinical potential of MT targeted therapeutics using PET imaging. We recently reported two BBB penetrating radioligands, [¹¹C]MPC-6827 and [¹¹C]HD-800 as specific PET ligands for imaging MTs in brain. The major metabolic pathway of the above molecules is anticipated to be via the initial labeling site, O-methyl, compared to the N-methyl group. Herein, we report the radiosynthesis of N-¹¹CH₃-MPC-6827 and N-¹¹CH₃-HD-800 and a comparison of their in vivo binding with the corresponding O-¹¹CH₃ analogues using microPET imaging and biodistribution methods. Both O-¹¹CH₃ and N-¹¹CH₃ labeled MT tracers exhibit high specific binding and brain. The N-¹¹CH₃ labeled PET ligands demonstrated similar in vivo binding characteristics compared with the corresponding O-¹¹CH₃ labeled tracers, [¹¹C]MPC-6827 and [¹¹C]HD-800 respectively.     

ELECTROMAGNETIC ACTIVITY OF YEAST CELLS IN THE M PHASE

Electromagnetic activity around yeast mitotic cells (Saccharomyces cerevisiae) was measured in the frequency range 8–9 MHz and special care was taken to extract reliable information from the raw signals. The characteristic of cold-sensitive tubulin mutants tub2-401 and tub2-406, which come to arrest before mitosis at a restrictive temperature (14°C) and which re-enter mitosis upon a shift back to a permissive temperature (28°C), was used to prepare synchronized mitotic cells. Immunofluorescence microscopy using an antitubulin antibody was used to analyze microtubular structures. The arrested tub2-401 mutant that had back-shifted to permissive temperature displayed no microtubules and no electromagnetic activity around the cells. In contrast, the arrested cells of the mutant tub2-406 displayed developed, but aberrant, nonfunctional microtubules and a high electromagnetic activity around the cells. The electromagnetic activity around the arrested mutant tub2-401 back-shifted to permissive temperature peaks at four time points which may coincide with (i) formation of the mitotic spindle, (ii) binding of chromatids to kinetochore microtubules, (iii) elongation of the spindle in anaphase A, and (iv) elongation of the spindle in anaphase B. The profile of the electromagnetic activity around the synchronized mutant tub2-406 at permissive temperature seems to be delayed by the time required for aberrant nonfunctional microtubules to be depolymerized. Experimental results presented in this paper support Pohl's idea of existence of the electromagnetic field around yeast cells.