STABILITY AND COLCHICINE EFFECT OF WALL MICROFIBRILLAR ALIGNMENT IN THE NITELLA RHIZOID

The cell wall of the Nitella rhizoid was stripped to make wedges of various thicknesses. Polarizing and interference microscopes were used to examine the post-deposition orientation of wall microfibrils. The fibrils appeared to maintain alignment after they were deposited. Since during growth the rhizoid wall elements are static in the cylindrical part or extend isotropically in the dome (Chen, 1973), these observations provide indirect evidence that the fibrillar reorientation observed in the Nitella internode is due to a passive reorientation during the predominant longitudinal cell elongation (Gertel and Green, 1977). The static microfibrils of the secondary wall of rhizoid, however, reoriented under the influence of colchicine, the alignment becoming almost random after 48 hrs. The disturbance of alignment started in the region adjacent to the plasma membrane, increasing in thickness with prolonged treatment.     

Microtubules do not control orientation of secondary cell wall microfibril deposition inMicrasterias

Summary The influence of the microtubule disorganizing substances amiprophos-methyl (APM) and colchicine on secondary wall formation inMicrasterias denticulata was investigated by the freezeetch technique. The results reveal that neither microtubule inhibitor changes the pattern of microfibril deposition. The application of APM or colchicine also does not cause any structural alterations of the microfibrils or of the protoplasmic (Pf) and the exoplasmic (Ef) fracture face of the plasma membrane, thus indicating that microtubules are not involved in secondary wall formation inM. denticulata. However, since areas of the plasma membrane which collapsed upon freeze-etching are restricted to the Pf-face of cells treated with microtubule inhibitors, cortical microtubules may function as mechanical support during secondary wall formation. In the cortical cytoplasm filamentous structures are found in close spatial relationship and an almost parallel alignment to rosettes of the plasma membrane.     

SUPERNUMERARY CHROMOSOMES IN TRADESCANTIA II. EFFECT OF COLCHICINE ON MEIOTIC ISOCHROMOSOME CONFIGURATIONS

The effect of colchicine on meiotic pairing and configuration frequencies of three homologous isosupernumerary chromosomes was investigated. In the absence of colchicine, the three isochromosomes displayed a high degree of interchromosomal pairing and chiasma formation. As a consequence, a high frequency of bivalents and trivalents were observed at diakinesis-metaphase I. The unique structure of isochromosomes enables them to pair intrachromosomally (i.e., foldback pairing) yet the preferential occurrence of interchromosomal pairing suggests that all six arms of the three isosupernumerary chromosomes were in close association prior to or upon initiation of synapsis. Supernumerary chromosomes in microsporocytes treated during presynapsis or early synapsis with colchicine exhibited a significant reduction (P < 0.001) in the number of bivalents and trivalents at diakinesis. However, there was no reduction in overall chiasma frequency among supernumeraries due to the induction of increased intrachromosomal pairing and chiasma formation. A colchicine-sensitive association or alignment of homologues preceding effective pairing has been demonstrated in standard chromosomes of a number of plant species. This study provides the first evidence to indicate that at least certain supernumerary chromosomes may display presynaptic association as well. The results also support the strongly held contention that colchicine is not directly preventing or inhibiting the actual formation of chiasmata, since no reduction in chiasma frequency was observed in the isochromosomes.     

Manipulation of ploidy for kiwifruit breeding: in vitro chromosome doubling in diploid <Emphasis Type="Italic">Actinidia chinensis</Emphasis> Planch.

Tetraploid plants were induced by colchicine treatment of in vitro leaf petiole segment cultures of five diploid Actinidia chinensis Planch. genotypes, including the commercially important, yellow-fleshed cultivar ‘Hort16A’, three female selections with red-fleshed fruit and one male pollinizer. Petiole segments were incubated on a shoot regeneration medium for a period of 4 weeks, and subsequently microshoots were treated with 0.05 or 0.1% colchicine. About one-third of the regenerated shoots were tetraploid following 0.05% colchicine treatment, more than with 0.1% colchicine treatment. Similar rates of tetraploid induction were achieved with all the genotypes tested. The efficiency of induction of polyploidy depended on the interaction between the types of in vitro culture chosen and the concentration of colchicine used. There are no previous reports of colchicine being used so successfully to induce polyploidy in Actinidia.     

Colchicine and the mitotic spindle of the aquatic phycomycete Allomyces

Summary Exposure of germlings of Allomyces neo-moniliformis to colchicine for 0 to 5 min after zoospore encystment was found to block 30% of germlings derived from flagellated zoospores and 55% of germlings derived from deflagellated zoospores in C-metaphase configurations at the first mitotic division. The zoospore lacks a pool of colchicine binding protein, and protein synthesis is absent during the time when colchicine first becomes effective in inducing C-metaphase. From these observations it is concluded that the microtubule subunit protein of the spindle apparatus of the first mitotic division to a large extent is derived from the depolymerization of the cytoplasmic microtubules of the zoospore. GTP, Mg²⁺, and ATP were observed to be antagonistic to the action of colchicine in vivo. It is suggested that these compounds may compete with colchicine for binding to the subunit protein in vivo. Germlings derived from flagellated zoospores are appreciably less subject to the action of colchicine in the presence of the antagonistic compounds than are germlings derived from deflagellated zoospores. This differential sensitivity to colchicine is interpreted as reflecting a difference in the quantity of microtubule subunit protein present at the time of exposure to colchicine.     

THE ROLE OF MICROTUBULES IN THE MOVEMENT OF PIGMENT GRANULES IN TELEOST MELANOPHORES

When microtubules in teleost melanophores are disrupted with antimitotic agents, colchicine, high hydrostatic pressure, low temperature, and vinblastine, the alignment and movement of the pigment granules in these cells disappear; during recovery, the return of alignment and movement corresponds in both time and space with the repolymerization of microtubules. Furthermore, analysis of nearest neighbor distances in untreated melanophores reveals that pigment granules are closely associated with microtubules. Other structures such as microfilaments, the endoplasmic reticulum, and the cytoplasmic matrix do not appear to be involved. Thus we conclude that microtubules determine the alignment and are essential for the selective movements of the pigment granules in these cells. Investigations of the mechanism of movement show that microtubules are required for both centrifugal and centripetal migrations and that they do not change in number or location during redistribution of pigment. Our results further indicate that microtubules in melanophores behave as semistable organelles as determined by investigation with colchicine and hydrostatic pressure. These observations and others rule out a push-pull mechanism based on the polymerization and depolymerization of microtubules or one which distinguishes two operationally different sets of microtubules. We propose instead that particles move by sliding along a fixed array of microtubules.     

Colchicine induced changes in the rate of entry of cells into prophase in roots ofVicia faba andHyacinthus orientalis

Summary Colchicine treatments change the rate of entry of cells into prophase in roots of bothVicia faba andHyacinthus orientalis. These changes have been discussed with respect to the effects of colchicine on cell progression through interphase. Since colchicine treatments alter the normal kinetics of cell entry into mitosis, the rate of accumulation of cells in metaphase following colchicine treatments cannot be used to determine cycle time in the species investigated in this study. Evidence is also presented showing that hyacinth roots are less sensitive to colchicine treatments than those of the broad bean.     

Upstream biomanufacturing of pharmaceutical colchicine

The plant-based colchicine potentially affects major diseases such as cardiovascular events, cancers and gout. Gloriosa superba seeds are a conventional pharmaceutical source of colchicine. The demand for pharmaceutical-grade colchicine has increased due to the shortage of feasible upstream manufacturing, encompassing all stages in the processes of biosynthesis and biomanufacturing before the raw material is ready for purification. Consequently, developing sustainable upstream industrial colchicine biofactories is imperative, especially in curtailing drug costs. A new upstream bioprocess has been established, using specialized biorhizomes with comprehensive specific-enzymes that catalyze the construction of biogenic functionalized intermediates that are converted into colchicine. This review emphasizes a novel biorhizome approach for biomanufacturing pharmaceutical-grade natural colchicine, a biosynthetic pathway elucidation and its challenges to synthetic biotechnology.     

The effect of agents influencing cytoskeletal elements upon the dielectrophoretic behavior of cultured epidermal cells

The degree of alignment of epidermal cells when subjected to an ac electrical field of different frequencies was studied. In untreated cells the alignment increased with field frequency between 20 and 600 kHz. Microtubular inhibitors, colchicine and vinblastine sulfate, decreased the response at 600 kHz and increased the response at 200 kHz. Dimethyl sulfoxide decreased the alignment at all frequencies studied and a microfilament inhibitor, cytochalasin B, was found to abolish this decrease. Possible reasons for these observations are given and the relevance to cell-cell communication discussed.     

Cucurbitacine als stathmokinetische Wirkstoffe

Summary A synergism of colchicine and different cucurbitacins has been shown, to be a cause in the formation of ball-metaphases in Bryonia species. The bitter principles cucurbitacin L and I, dihydrocucurbitacin B, and tetrahydrocucurbitacin I, which were examined more closely with respect to their karyological effects, were shown to give rise to C-metaphases in Hordeum and Vicia at concentrations of about 0.016 per cent. On the one hand the number of mitotic stages is reduced, and on the other hand there is an increase of metaphase stages. Higher concentrations lead to pycnotic degenerations of nuclei and are toxic. When colchicine is applied together with cucurbitacins, ball-metaphases result. This could be demonstrated in plants lacking colchicine and cucurbitacins (Hordeum) when both substances were applied at the same time. Ball-metaphases also appear in plants containing cucurbitacins (Bryonia alba, B. dioica, Citrullus colocythis, Iberis amara) when they are treated with colchicine.     

Mechanisms of cellular adhesion : II. The interplay between adhesion, the cytoskeleton and morphology in substrate-attached cells

cAMP/theophylline exaggerates cell shape—whether the fibroblastic morphology of controls or the epithelioid shape of colchicine-treated cells. The ultrastructural basis is that cAMP/theophylline increases the number and linearity of microtubules and microfilament bundles, although where also treated with colchicine, the cells adopt a well-spread shape maintained by microfilament bundles alone. Since interference reflection microscopy shows that colchicine promotes the marked alignment of focal contacts (which terminate microfilament bundles) it is concluded that microtubules encourage angular cell form and modify the pattern of adhesions by influencing the directionality of microfilament bundle formation although they are inessential for the maintenance of the spread form or adhesion per se.     

A low molecular weight colchicine binding protein from the aquatic Phycomycete Allomyces neo-moniliformis

Summary A colchicine binding protein of the zoospore, flagellum, and pre- and post-mitotic germlings of the aquatic Phycomycete, Allomyces neo-moniliformis, was found to have a sedimentation coefficient of 2.3 S, and a molecular weight of approximately 30 000. The characteristics of this colchicine binding protein from Allomyces are compared to those of the 6 S colchicine binding proteins obtained from a variety of other organisms.     

EFFECTS OF MICROTUBULE INHIBITORS ON PRONUCLEAR MIGRATION AND EMBRYOGENESIS IN FUCUS DISTICHUS(PHAEOPHYTA)1

Pronuclear migration in Fucus distichus spp. edentatus (de la Pyl.) Powell is blocked by incubation of fertilized eggs in colchicine (1 mg/ml) and Nocodazole (2 μg/ ml). Rhizoids form prior to decondensation of the sperm chromatin in eggs in which pronuclear fusion is blocked. This occurs during continuous colchicine incubation as well as in eggs recovering from a short treatment with either drug following fertilization. During recovery of the cells, the sperm and egg chromosomes condense, and the sperm chromosomes migrate toward the egg pronucleus. The delay in migration following removal of colchicine is as much as 24 h and is even slower following removal of Nocodazole. The egg chromosomes form a metaphase plate in treated cells while the sperm chromosomes are still distant in the cytoplasm. This suggests that egg centrioles are important in the mitotic division of the zygote, not sperm centrioles. The effect of colchicine treatment on the mitotic plane and cytokinesis is also discussed.     

The effect of colchicine on pyrin and pyrin interacting proteins

MEFV which encodes pyrin, cause familial Mediterranean fever (FMF), the most common auto‐inflammatory disease. Pyrin is believed to be a regulator of inflammation, though the nature of this regulatory activity remains to be identified. Prophylactic treatment with colchicine, a microtubule toxin, has had a remarkable effect on disease progression and outcome. It has been thought that, inhibition of microtubule polymerization is the main mechanism of action of colchicine. But, the exact cellular mechanism explaining the efficacy of colchicine in suppressing FMF attacks is still unclear. Given the ability of colchicine treatment to be considered as a differential diagnosis criteria of FMF, we hypothesized that colchicine may have a specific effect on pyrin and pyrin interacting proteins. This study showed that colchicine prevents reticulated fibrils formed by PSTPIP1 filaments and reduces ASC speck rates in transfected cells. We further noted that, colchicine down‐regulates MEFV expression in THP‐1 cells. We also observed that colchicine causes re‐organization of actin cytoskeleton in THP‐1 cells. Pyrin is an actin‐binding protein that specifically localizes with polymerizing actin filaments. Thus, MEFV expression might be affected by re‐organization of actin cytoskeleton. The data presented here reveal an important connection between colchicine and pyrin which might explain the remarkable efficacy of colchicine in preventing FMF attacks. J. Cell. Biochem. 113: 3536–3546, 2012. © 2012 Wiley Periodicals, Inc.     

Colchicine-induced microspore embryogenesis in coffee

A protocol for the induction of androgenesis and plant regeneration from C. arabica cv. Caturra isolated microspores in vitro using colchicine pretreatment has been developed. Microspores were mechanically isolated and then carefully purified. Before colchicine pretreatment, microspores were cultured in a semi-solid medium for further develop and regeneration. Different times of colchicine exposure as well as different concentrations were tested. The best androgenic response was found when microspores were precultured in 100 mg l^–1 colchicine for 48 h. The microspore developmental stages responsive to colchicine were late-uninucleated and early binucleated pollen. Flow cytometry and morphological analyses revealed that 95% of regenerated plants were dihaploids (2n=2x=22). However, some doubled dihaploid plants (2n=4x=44) were also obtained, suggesting that not only androgenic induction but also chromosome duplication could be expected as result of colchicine exposure of coffee microspores. This report represents a new approach in the coffee pollen culture, as well as a major step forward to the utilization of haploid technology in coffee breeding.     

Induction of tetraploidy in Buddleia globosa

The aim was to produce a tetraploid form of Buddleia globosa to facilitate introgression of yellow flower colour into B. davidii, which is naturally tetraploid. Protocols were established for the micropropagation of B. globosa and tetraploid plants were obtained by application in vitro of colchicine to pre-cultured excised nodal sections. Three concentrations of colchicine were applied (0.01%, 0.05% and 0.1% w/v) for 1, 2 or 3 days. At 0.01% tetraploids were produced only after 2 days of application. All other treatments produced at least one tetraploid. The colchicine technique was extremely effective: of 29 lines tested, 19 were tetraploid and 5 were mixoploid. The vegetative characteristics of these tetraploids are described and the flowering characteristics of the three that flowered. This revised version was published online in August 2006 with corrections to the Cover Date.     

Impact of colchicine application during callus induction and shoot regeneration on micropropagation and polyploidisation rates in two <Emphasis Type="Italic">Miscanthus</Emphasis> species

Grasses from the genus Miscanthus have several characteristics that make them very favourable crops for efficient, low input, multifunctional and environmentally friendly biomass production. This study is aimed to improve a polyploidisation method to effectively induce polyploids in Miscanthus sinensis and Miscanthus x giganteus. Colchicine was applied for 2, 4 or 7 d in micropropagation systems using inflorescence segments at two different points: during callus induction (313 and 626 μM colchicine) and during shoot regeneration from callus (313 μM colchicine). Among the tested combinations, the most effective (up to 40%) was the 4-d colchicine treatment of a shoot-forming callus cultured 4 d before the experiment on regeneration medium under light conditions. In vitro colchicine treatment during callus induction and during shoot regeneration from callus resulted in no chimeric polyploids as well as a very low number of albinos (2.5%). Additionally, some combinations using colchicine did not significantly reduce the rates of micropropagation effectiveness. The obtained material is promising for the creation of new high-biomass-yielding forms in the Miscanthus genus. In all genotypes tested, chromosome doubling significantly increased pollen stainability. According to preliminary results, induced tetraploids are fertile and useful in hybrid production. Leaves of polyploid forms of two genotypes demonstrated significantly greater width in comparison to the controls.     

Structural and metabolic correlation for <Emphasis Type="Italic">Bacillus megaterium</Emphasis> ACBT03 in response to colchicine biotransformation

This study aims to evaluate the effects of colchicine on metabolic and structural changes in Bacillus megaterium ACBT03, enduring colchicine bioconversion. Electron microscopy examination of cells adapted to different concentrations of colchicine for its bioconversion to pharmacologically active 3-demethylated colchicine, endowed changes in cell shape, decreased cell wall and plasma membrane thickness. In line with microscopic studies, lipid and membrane protein contents were drastically reduced in bacterial cells adapted to higher concentrations of colchicine and resulting into decrease in cell membrane thickness. More numbers of polyhydroxybutyrate (PHB) rich inclusion bodies were found inside the colchicine adapted cells and presence of higher amount of PHB, a carbon source for generation of redox potential, indicates that it might be responsible for activation of P450 BM-3 enzyme and plays significant role in colchicine demethylation. The presence of dense ribosome like bodies in colchicine adapted cells showed higher biosynthesis of P450 BM-3. Reduction in cell wall and cell membrane thickness, presence of more inclusion bodies and ribosome like masses in colchicine adapted cells were some of the key interlinked phenomena responsible for colchicine bioconversion. This is the first study which reports that colchicine demethylation process severely affects the structural and metabolic functions of the bacteria.     

Resistance of Rosa microtubule polymerization to colchicine results from a low-affinity interaction of colchicine and tubulin

The inhibition of the polymerization of tubulin from cultured cells of rose (Rosa. sp. cv. Paul's scarlet) by colchicine and the binding of colchicine to tubulin were examined in vitro and compared with data obtained in parallel experiments with bovine brain tubulin. Turbidimetric measurements of taxol-induced polymerization of rose microtubules were found to be sensitive and semiquantitative at low tubulin concentrations, and to conform to some of the characteristics of a nucleation and condensation-polymerization mechanism for assembly of filamentous helical polymers. Colchicine inhibited the rapid phase of polymerization at 24°C with an apparent inhibition constant (K _i) of 1.4·10^-4 M for rose tubulin and an apparent K _i=8.8·10^-7 M for brain tubulin. The binding of [³H]colchicine to rose tubulin to form tubulin-colchicine complex was mildly temperature-dependent and slow, taking 2–3 h to reach equilibrium at 24°C, and was not affected by vinblastine sulfate. The binding of [³H]colchicine to rose tubulin was saturable and Scatchard analysis indicated a single class of low-affinity binding sites having an apparent affinity constant (K) of 9.7·10² M^-1 and an estimated molar binding stoichiometry (r) of 0.47 at 24°C. The values for brain tubulin were K=2.46·10⁶ M^-1 and r=0.45 at 37°C. The binding of [³H]colchicine to rose tubulin was inhibited by excess unlabeled colchicine, but not by podophyllotoxin or tropolone. The data demonstrate divergence of the colchicine-binding sites on plant and animal tubulins and indicate that the relative resistance of plant microtubule polymerization to colchicine results from a low-affinity interaction of colchicine and tubulin.Abbreviations MT microtubule - TC tubulin-colchicine complex     

Doubled haploid plants following colchicine treatment of microspore-derived embryos of oilseed rape (<Emphasis Type="Italic">Brassica napus L.</Emphasis>)

An efficient method for producing doubled haploid plants of oilseed rape (Brassica napus L.) was established using in vitro colchicine treatment of haploid embryos. Haploid embryos in the cotyledonary stage were treated with one of four colchicine concentrations (125, 250, 500 and 1,000 mg/L); for one of three treatment durations (12, 24 and 36 h) at one of the two temperatures (8 and 25°C) and were compared to control embryos (without colchicine treatment). The number of chromosomes, seed recovery, size and density of leaf stomata, and pollen grain size from regenerated plants were determined. No doubled haploid plants were regenerated from control embryos; however, the doubled haploid plants were regenerated from colchicine-treated embryos. A high doubling efficiency, 64.29 and 66.66% of regenerated plants, was obtained from 250 mg/L colchicine treatment for 24 h and 500 mg/L colchicine treatment for 36 h, respectively, at 8°C. Following 500 mg/L colchicine treatment for 36 h, a few plants regenerated (9 plants). At the higher colchicine concentration (1,000 mg/L), no plant regenerated. These results indicate that the colchicine treatment of embryos derived from microspores can induce efficient chromosome doubling for the production of doubled haploid lines of oilseed rape.