Vinblastine-induced paracrystals and unusually large microtubules (macrotubules) in rat renal cells

Summary Vinblastine sulfate was administered to adult rats by intravenous injections. Kidney cortex was fixed after 1, 2, or 5 hours of treatment and studied by routine transmission electron microscopy.In control animals, cells of distal convoluted tubules possessed numerous microtubules with an average diameter of 280 Å. In treated animals, the microtubules of these cells were reduced in number, and paracrystalline inclusions characteristic of vinblastine treatment were common. Macrotubules (570 Å average diameter) were also present and often were seen close to, or in apparent continuity with, paracrystals. Since the work of others indicates that vinblastine-induced paracrystals contain microtubular protein (tubulin), observation of continuities between paracrystals and macrotubules is interpreted as evidence that macrotubules are also composed of tubulin and that macrotubules may become incorporated into paracrystals.Unlike the ordinary microtubules of cells of the distal tubules, vinblastine-induced macrotubules exhibited cross-striations in longitudinal view and subunit structure in cross section.Macrotubules and paracrystals were also observed in cells of the proximal convoluted tubule, mesangium, glomerular endothelium, parietal epithelium of Bowman's capsule, and visceral epithelium of Bowman's capsule. Continuities between macrotubules and paracrystals, although relatively common in occurrence in distal tubule cells, were only rarely seen in the other kinds of cells examined. Acknowledgements. The authors gratefully acknowledge the technical help of Mrs. Dawn Bockus, Miss Judy Groombridge, Mrs. Jeri Hunter, Mrs. Jolan Pinter, Miss Franque Remington, Miss Mary Stewart, Miss Louise Young, Mr. Reginald Pickering, and Mr. W. J. Masten. This research was supported by N.I.H. grants AM 16 236, GM 00 100, and HE 03 174, by Institutional Cancer Grant IN-26L from the American Cancer Society, and by the Graduate School Research Fund of the University of Washington.     

Phospholipase C signaling involvement in macrotubule assembly and activation of the mechanism regulating protoplast volume in plasmolyzed root cells of Triticum turgidum

The role of phosphoinositide-specific phospholipase C (PI-PLC) signaling in the macrotubule-dependent protoplast volume regulation in plasmolyzed root cells of Triticum turgidum was investigated. At the onset of hyperosmotic stress, PI-PLC activation was documented. Inhibition of PI-PLC activity by U73122 blocked tubulin macrotubule formation in plasmolyzed cells and their protoplast volume regulatory mechanism. In neomycin-treated plasmolyzed cells, macrotubule formation and protoplast volume regulation were not affected. In these cells the PI-PLC pathway is down-regulated as neomycin sequesters the PI-PLC substrate, 4,5-diphosphate-phosphatidyl inositol (PtdInsP(2)). These phenomena were unaffected by R59022, an inhibitor of phosphatidic acic (PA) production via the PLC pathway. Taxol, a microtubule (MT) stabilizer, inhibited the hyperosmotic activation of PI-PLC, but oryzalin, which disorganized MTs, triggered PI-PLC activity. Taxol prevented macrotubule formation and inhibited the mechanism regulating the volume of the plasmolyzed protoplast. Neomycin partly relieved some of the taxol effects. These data suggest that PtdInspP(2) turnover via PI-PLC assists macrotubule formation and activation of the mechanism regulating the plasmolyzed protoplast volume; and the massive disorganization of MTs that is carried out at the onset of hyperosmotic treatment triggers the activation of this mechanism.     

Actomyosin is involved in the plasmolytic cycle: gliding movement of the deplasmolyzing protoplast

Summary.  The leaf cells of Chlorophytum comosum seem to have the ability to regulate their protoplast volume and shape during the plasmolytic cycle. This phenomenon was morphologically expressed by the stabilization of the plasmolyzed protoplast volume and shape within 1–5 min after the immersion of the leaf segments in the plasmolytic fluid and temporarily at the onset of deplasmolysis. During the latter stage the plasmolyzed protoplast rounded up and assumed a perfectly convex shape and glided into the cell lumen along the cell axis. This gliding movement was active, nonsaltatory, and conducted with a constant velocity and lasted for a short time. During this movement the protoplast volume did not change appreciably. As far as we know, this movement has not been described so far. Deplasmolysis proceeded and was rapidly completed when the protoplast stopped moving. Leaf cells which have been affected by an antiactin filament drug or myosin inhibitors lost their ability to regulate the volume and shape of the plasmolyzing protoplast. In addition, the gliding protoplast movement was also inhibited in the treated cells. These data show for the first time that the actomyosin system is involved in the mechanism of volume regulation during the plasmolytic cycle and that it underlies the gliding movement of the deplasmolyzing protoplast. Received June 3, 2002; accepted September 26, 2002; published online April 2, 2003 RID="*" ID="*" Correspondence and reprints: Department of Botany, Faculty of Biology, University of Athens, Athens 15784, Greece. E-mail: bgalatis@biol.uoa.gr     

Effects of anti-microtubule drugs onin vitro polymerization of tubulin from mung bean

Effects of anti-microbule drugs on tubulin polymerizationin vitro were investigated using purified mung bean (Vigna radiata) tubuli. Colchicine induced the formation of macrotubules at the relatively low concentration of 10 μM. and the appearance of corkscrew-like filaments from the ends of the macrotubules at concentrations of more than 100 μM. Vinblastine substantially inhibited polymerization at 1 μM and caused the formation of paracrystals at concentrations greater than 10 μM. Oryzalin inhibited polymerization at 1 μM partially and at 10 μM completely. Paracrystal formation was also induced by cremart at 10 μM, but these paracrystals appeared to be more rigid than those induced by vinblastine. Amiprophos methyl (APM), with a chemical configuration similar to cremart, substantially inhibited polymerization at 1 μM, but the formation of paracrystals was weak. Griseofulvin at 10 μMalso inhibited the polymerization of tubulin while at higher concentrations aggregates of helices were formed. Inhibition of polymerization by phenylcarbamate herbicides was more effective than that caused by benzimidazoylcarbamate fungicides. The effects of drugs onin vitro preformed (MTs) were also investigated. Colchicine and vinblastine showed identical effects to those on the polymerization process. Griseofulvin, cremart and APM induced only macrotubule formation while the other drugs tested had no major effects     

Influence of vincristine on the Golgi complex of leukaemic lymphoblasts

In vitro and in vivo effects of vincristine on the Golgi complex of leukaemic lymphoblasts were studied. The cells incubated in vitro for 4 hours with vincristine of 1.25 x 10(-5) M concentration lacked microtubules, but regularly contained paracrystals and parallel arrays of macrotubules associated with ribosomes. The Golgi complex in control lymphoblasts was represented by 1-3 dictyosomes (stacks of cisternae) grouped in one area. After exposure to vincristine the dictyosomes lay at a considerable distance from each other. In many of them the cisternae were shorter than in controls and distended or transformed into large vacuoles. In cells incubated in vitro with lower concentrations of vincristine (1.25 x 10(-6) and 1.25 x 10(-7) M) and in cells obtained after the second therapeutic dose of vincristine (in the course of normal clinical treatment) neither changes in the Golgi complex nor formation of paracrystals and macrotubules were observed.     

Effects of acidic pH on the formation of vinblastine-induced paracrystals in Chinese hamster ovary cells

Summary— The pH-related change in morphology of vinblastine (VLB)-induced paracrystals formed in Chinese hamster ovary (CHO) cells was examined immunohistochemically in order to determine both the mechanism of tubulin crystallization and the influence of acidic pHs on cytoskeletal microtubules. Lowering the extracellular pH (pHe) rapidly reduced the intracellular pH (pHi) in CHO cells. Lowering the pHi to near the neutral range significantly accelerated the growth of VLB-induced paracrystals, compared to that of paracrystals formed at a physiological pHe. However, further cytoplasmic acidification caused by the addition of sodium azide into the culture medium induced the disappearance of typical paracrystals and the appearance of a highly organized meshwork of tubulin appearing as short, thick filaments at the light microscopic level. Treatments using different concentrations of VLB at different pHe's showed that low pHi's (6.7 and 6.3) suppressed paracrystal-formation at lower concentrations of VLB (5×10^?6 M and 10^?5 M). At higher concentrations of VLB (5×10^?5 M and 10^?4 M), only short filaments were formed at pHi 6. 3. Electron microscopy revealed that the filaments had a ladder-like structure probably consisting of a stacked series of fused rings. This indicates that paracrystals may be modified by extremely low pH. These results show that paracrystals are unstable in living cells and that their formation is regulated by environmental pH.     

Plasmolysis during the division cycle of Escherichia coli

Cells of Escherichia coli were plasmolyzed with sucrose. They were classified according to length by way of electron micrographs taken from samples prepared by agar filtration. The percentage of plasmolyzed cells increased about two- and threefold between mean cell sizes of newborn and separating cells. However, dividing cells were less frequently plasmolyzed than nondividing cells of the same length class. Analysis of cell halves (prospective daughters) in dividing cells showed that they behaved as independent cellular units with respect to plasmolysis. The results indicate that compressibility of the protoplast (given a certain plasmolysis space) is inversely related to cell size. That a dividing cell does not react as one osmotic compartment to osmotic stress may suggest that cell size-dependent strength of the cell membrane-cell wall association, rather than variation in turgor, plays a role during the cell division cycle.     

Colchicine-induced Paracrystals in Root Cells of Wheat (Triticum aestivum L.)

Tubulin conformations other than microtubules in the meristematiccells of wheat roots grown in the presence of 2 mM colchicinesolution were investigated by immunofluorescence and electronmicroscopy. In the affected cells microtubules disappeared andwere replaced by tubulin fluorescent strands that occurred inthe cortical cytoplasm. With increasing time of exposure tocolchicine the tubulin strands became better organized and occurredalso in the subcortical cytoplasm and finally they were restrictedto the area around the nucleus. In prophase and preprophasecells thick strands occupied the cortical cytoplasmic zone wherein normal cells a preprophase microtubule band (PMB) was expectedto be assembled. In the colchicine-treated cells electron microscopy revealedan accumulation of paracrystalline aggregates, which initiallyoccurred along the cell wall and later deeper in the cytoplasm,in the perinuclear regions and the cytoplasmic invaginationsof the nucleus. In transverse planes the paracrystalline strandsappear to consist of hexagonal subunits in a 'honeycomb' arrangement,while in longitudinal and oblique sections they exhibit variableimages. Since their distribution coincides with that of thetubulin strands visualized by immunofluorescence, they are consideredto be the same structure. Therefore, the paracrystals consistof, or at least contain, tubulin. They are most likely to bepolymers of tubulin-colchicine complexes.Copyright 1995, 1999Academic Press Wheat roots, colchicine, immunofluorescence, electron microscopy, tubulin paracrystals, Triticum aestivum L     

Instability of pleomorphic tubulin paracrystals artificially induced by Vinca alkaloids in tissue-cultured cells

The processes of tubulin paracrystal induction in Chinese hamster ovary cells treated with a Vinca alkaloid, ie, vinblastine or vincristine, and treated simultaneously with one of the Vinca alkaloids and colcemid or colchicine were followed by four different microscopic techniques, in particular by tubulin-immunofluorescence. Vinca alkaloid alone, in lower concentrations, induced basically tactoid or needle-shaped (N-shaped) paracrystals. However, the formation of crystalloid was greatly enhanced by increasing the concentration of Vinca alkaloid. Square or barrel-shaped (S-shaped) and hexagonal paracrystals were also commonly induced by simultaneous treatment with a Vinca alkaloid and colcemid or colchicine. Large rectangular paracrystals often displayed fibrillar or lamellar fine structures which ran perpendicular to the long axis but tended to cleave into fragments by spontaneous splitting. Electron micrographs revealed the fine structure of crystalloids to be aggregates of numerous filaments. The growth of paracrystals, particularly N-shaped crystals, was markedly inhibited when cells were exposed to drug(s) at a low temperature (4 degrees C). We confirmed that both N- and S-shaped paracrystals dissociated rapidly after the culture medium was replaced with fresh, drug-free medium. Glutaraldehyde-fixed paracrystals treated with RNase solution were stained with acridine orange, showing a weak orange color. Possible factors involved in the assembly and disassembly of tubulin paracrystals are discussed.     

The relationship between cell injury and osmotic volume reduction: III. Freezing injury and frost resistance in winter wheat

In order to distinguish between several possible mechanisms of frost hardening in winter wheat (Triticum aestivum L.) cells from two hardy and two tender cultivars were plasmolyzed in CaCl₂ solution at room temperature and cell volumes estimated by microscopic examination. Analyses of Boyle-van't Hoff plots of these data reveal that all cells from cultivars progressively increase their intracellular solute concentration up to 20 days hardening. This increase, which we had predicted from published calorimetric data to be the sole mechanism of hardening explained less than half of the increase in hardening seen in the most hardy cultivar, Kharkov. Hardening also increased the osmotically inactive volume.At CaCl₂ concentrations greater than 5%, plasmolyzed protoplasts departed further from the Boyle-van't Hoff prediction, remaining larger than expected until some higher concentration of CaCl₂, where protoplast volume again sharply decreased. In all cultivars except hardened Kharkov, the concentration of CaCl₂ producing this abrupt volume decrease had a freezing point corresponding to the killing temperature. If this concentration was exceeded during plasmolysis, then the protoplasts burst during deplasmolysis at some volume less than their original volume.We interpret these data to mean that, in addition to the often described hardening mechanism of increased cell solute and water binding, winter wheat shows a third mechanism, a mechanical resistance to protoplast shrinkage which produces volumes larger than those predicted during osmotic stress. The resisting element appears to be the plasma membrane itself. Shrinkage brings the membrane under compressive stress, developing tangential pressure within it. Cell injury occurs when the cell membrane area has been reduced to the point at which irreversible loss of membrane material is inevitable. Cell death occurs during deplasmolysis when the protoplast bursts because its membrane contains insufficient material to subtend the area of the cell wall.Of the cultivars tested, hardened Kharkov was unique in avoiding injury. Hardened Kharkov was injured only after the volume inflection had been greatly exceeded. Refractile droplets of lipid appeared in the cytoplasm of hardened Kharkov protoplasts during plasmolysis but disappeared during deplasmolysis suggesting that hardy Kharkov was able reversibly to store membrane lipids in cytoplasmic vesicles and return them to the membrane on deplasmolysis.     

Location of glycoproteins that contain glucosamine in plant tissues

When radioactive d-glucosamine is provided to Acer pseudoplatanus cells in liquid culture in order to label those glycoproteins that contain amino sugars, it is incorporated predominantly into a crude cell wall fraction. This observation was confirmed histologically by preparing autoradiographs of thin tissue sections from plasmolyzed cells. Highly purified cell wall material from unlabeled cells has also been shown to contain small amounts of glucosamine. Similarly, about one-half of the amino sugar recovered from cultured cells of Nicotiana tabacum is present in their cell walls. In corn roots, however, the labeled glycoproteins that are formed after glucosamine incorporation are predominantly cytoplasmic and not deposited outside the protoplast.     

Antimicrobial Actions of Hexachlorophene: Lysis and Fixation of Bacterial Protoplasts

Hexachlorophene was found to be both a lytic and a fixative agent for protoplasts isolated from Bacillus megaterium. Concentrations of 50 to 100 mug of drug per mg of original cell dry weight were required to lyse 4.4 x 10(9) protoplasts (2 mg of original cell dry weight). At higher drug concentrations, protoplasts became fixed against osmotic stress and reduced in sensitivity to disruption by n-butanol. Lower drug concentrations caused proportionate lysis in the protoplast population. Intact cells lost the ability to become plasmolyzed at these same hexachlorophene concentrations. Nonplasmolyzed, drug-treated cells were resistant to the action of lysozyme, whereas plasmolyzed, drug-treated cells were sensitive. But the sensitivity of isolated cell walls to lysozyme digestion was not markedly altered by hexachlorophene treatment. These effects appeared to be secondary in the killing of cells by hexachlorophene because they occurred at concentrations higher than the minimum lethal concentration.     

Macrotubule-dependent protoplast volume regulation in plasmolysed root-tip cells of Triticum turgidum: involvement of phospholipase D

The probable involvement of phospholipase D (PLD)/phosphatidic acid (PA) signalling in the hyperosmotic stress response of Triticum turgidum root cells was investigated by examining the effects of butanol-1, butanol-2, phosphatidylbutanol (PtdBut), N-acylethanolamine (NAE) and PA on the hyperosmotic response, the organization of the tubulin cytoskeleton and the accumulation of a phosphorylated p38-like mitogen-activated protein (MAP) kinase (phospho-p46) in plasmolysed root cells. The effects of all the treatments were assessed by differential interference contrast (DIC) microscopy of living cells, tubulin immunofluorescence, conventional transmission electron microscopy (TEM), tubulin immunogold localization, protoplast volume measurements and western blot analysis. Butanol-1 and NAE compromised the viability of plasmolysed cells, induced a marked reduction in the plasmolysed protoplast volume, and inhibited hyperosmotically induced tubulin macrotubule formation and the accumulation of phospho-p46. Exogenous PA reinforced the hyperosmotic response of T. turgidum root cells and positively affected tubulin macrotubule formation. Additionally, PA reduced the effects of butanol-1 in plasmolysed cells. Taken together, the data suggest that PLD-mediated PA synthesis occurs upstream of the accumulation of phospho-p46 to regulate hyperosmotically induced macrotubule formation in plasmolysed T. turgidum root cells.     

A plasmolytic cycle: The fate of cytoskeletal elements

Summary In most plant cells, transfer to hypertonic solutions causes osmotic loss of water from the vacuole and detachment of the living protoplast from the cell wall (plasmolysis). This process is reversible and after removal of the plasmolytic solution, protoplasts can re-expand to their original size (deplasmolysis). We have investigated this phenomenon with special reference to cytoskeletal elements in onion inner epidermal cells. The main processes of plasmolysis seem to be membrane dependent because destabilization of cytoskeletal elements had only minor effects on plasmolysis speed and form. In most cells, the array of cortical microtubules is similar to that found in nonplasmolyzed states except that longitudinal patterns seen in some control cells were never observed in plasmolyzed protoplasts of onion inner epidermis. As soon as deplasmolysis starts, cortical microtubules become disrupted and only slowly regenerate to form an oblique array, similar to most nontreated cells. Actin microfilaments responded rapidly to the plasmolysis-induced deformation of the protoplast and adapted to its new form without marked changes in organization and structure. Both actin microfilaments and microtubules can be present in Hechtian strands, which, in plasmolyzed cells, connect the cell wall to the protoplast. Anticytoskeletal drugs did not affect the formation of Hechtian strands.Abbreviations DIC differential interference contrast - DiOC₆(3) 3,3-dihexyloxacarbocyanine iodide Dedicated to Professor Walter Gustav Url on the occasion of his 70th birthday     

Actin paracrystal induction by forskolin and by db-cAMP in CHO cells

Forskolin, a hypotensive diterpine, is assumed to be a potent activator of adenylate cyclase leading to increased levels of cAMP. When this drug is used at 10(-5) M on CHO-C14 cells in culture, it induces within 15 min actin paracrystals in all cells. At this time the paracrystals are mostly situated close to the cell periphery. Electron microscopy (EM) shows structures typical of actin paracrystals. Scanning electron microscopy (SEM) reveals a reduction in surface microvilli and blebs. Identical results can be obtained by adding 1 mM db-cAMP to the culture medium directly. The paracrystals are observed within 15 min and thus represent one of the earliest ultrastructural changes so far described for reverse transformation of CHO cells by db-cAMP. The microtubular and vimentin profiles appear unchanged by forskolin treatment of CHO-K1 cells. Out of currently unknown reasons forskolin does not induce the actin transformation in several other commonly used cell lines.     

Tubulin paracrystals in intermitotic nuclei of the foraminifer Allogromia laticollaris Arnold after treatment with vinblastine

Electron microscopic investigations on the foraminifer Allogromia laticollaris showed that after treatment with 10(-3) M vinblastine tubulin paracrystals can be demonstrated in intermitotic nuclei. As these paracrystals are either membrane coated or lie free in the karyoplasm, and as in the perinuclear cytoplasm, membrane coated paracrystals can be demonstrated as well, it is assumed that the cytoplasmic tubulin which is composing the intranuclear division spindle can transverse the intact nuclear envelope via vesicle transport.     

Immunocytochemical localization of glucocorticoid receptor in human gingival fibroblasts and evidence for a colocalization of glucocorticoid receptor with cytoplasmic microtubules

The cellular distribution of the glucocorticoid receptor (GR) in relation to various intracellular and plasma membrane structures in human fibroblasts was studied using indirect immunofluorescence techniques with monoclonal and polyclonal antibodies. During interphase, GR was located predominantly in the cytoplasm, showing a similar pattern as tubulin. In mitotic cells, GR and tubulin were localized in mitotic spindles and in telophase midbodies. Colchicine and vinblastine induced a similar redistribution of GR and tubulin to the cell periphery. This redistribution was reversible for colchicine but not for vinblastine. Vinblastine also induced paracrystals containing GR and tubulin. These results support the hypothesis that GR interacts in vivo with cytoplasmic microtubules.     

Plasmolysis as a Tool to Reveal Lead Localization in the Apoplast of Root Cells

In order to analyze the distribution of lead between cell walls and plasmalemma, two-day-old maize seedlings (Zea mays L.) were incubated for 24 h on a solution of lead nitrate at a concentration causing 50% inhibition of root growth (10^–5 M). Using the histochemical technique (precipitation of lead dithizonate), the distribution of lead in plasmolyzed and nonplasmolyzed cells of the root cortex was compared. This allowed us to separate the lead bound by cell walls from the lead located on the protoplast surface and in the periplasmic space. The plasmolysis was conducted prior to histochemical reaction by the incubation of seedling roots in 0.6 M sucrose solution for 30 min. The lead precipitates were located in cell walls and on the surface of protoplast. A small amount of lead was found in periplasmic space of some cells in root cortex. It is suggested that the lead is bound not only to the cell wall matrix but also to the plasmalemma.     

Nucleation of macrotubules on double-walled microtubule seeds

It is known that histone H1 is able to cause the formation of double-walled microtubules from microtubule protein. Now, we demonstrate that in dependence on the mass ratio H1/microtubule protein upon addition of tubulin to short pieces of double-walled microtubules either their inner or their outer wall elongates resulting in normal microtubules or in macrotubules, respectively. Because of their genesis we suggest that macrotubules like double-walled microtubules (see Unger et al., Eur. J. Cell Biol. 46, 98-104 (1988)) expose those sides of tubulin dimers at their surface which usually form the lumen face of microtubules.     

Mechanisms of regulating tubulin synthesis in cultured mammalian cells.

Colchicine and nocadazole both depolymerize microtubules in cultured fibroblasts and lead to a rapid inhibition of tubulin synthesis. The level of translatable tubulin mRNA is greatly reduced in drug-treated cells as demonstrated by translation in a reticulocyte-derived in vitro protein synthesizing system. A model of tubulin synthesis regulation is proposed in which the elevated level of unpolymerized tubulin in drug-treated cells inhibits the formation of new tubulin mRNA and the preexisting message decays rapidly. In agreement with this model, tubulin message is found to be short-lived and has an approximately 2 hr half-life in cells treated with actinomycin D. Another prediction of the proposed model is that destabilization of microtubules without a concomitant increase in free tubulin will not inhibit tubulin synthesis. Vinblastine also disrupts microtubules but leads to the aggregation of tubulin into large paracrystals with an apparent decrease in the concentration of free tubulin. This drug does not inhibit tubulin production but rather leads to a measurable enhancement of tubulin synthesis.