Phomopsin A production by Phomopsis leptostromiformis in liquid media.

Phomopsis leptostromiformis WA1515 produced 75 to 150 mg of phomopsin A per liter in stationary cultures in a Czapek-Dox medium supplemented with 5 to 10 g of yeast extract per liter. pH and temperature optima were approximately 6.0 and 25 degrees C, respectively. A commercial tryptic digest of casein was a satisfactory alternative to the yeast extract, but poor growth and very little phomopsin were obtained when the yeast was replaced by vitamin-free Casamino Acids or a mixture of 18 amino acids. Approximately 95% of the phomopsin A produced was found in the cutlure liquid. No phomopsin was detected in shaken cultures. No phomopsin B was found in any culture. Methods are described for recovery and estimation of phomopsin A from culture liquids.     

Phomopsin A production by Phomopsis leptostromiformis in liquid media.

Phomopsis leptostromiformis WA1515 produced 75 to 150 mg of phomopsin A per liter in stationary cultures in a Czapek-Dox medium supplemented with 5 to 10 g of yeast extract per liter. pH and temperature optima were approximately 6.0 and 25 degrees C, respectively. A commercial tryptic digest of casein was a satisfactory alternative to the yeast extract, but poor growth and very little phomopsin were obtained when the yeast was replaced by vitamin-free Casamino Acids or a mixture of 18 amino acids. Approximately 95% of the phomopsin A produced was found in the cutlure liquid. No phomopsin was detected in shaken cultures. No phomopsin B was found in any culture. Methods are described for recovery and estimation of phomopsin A from culture liquids.     

The synthesis of the brain specific S100 protein in colcemid resistant mutants of rat glial cells

We have isolated two colcemid-resistant mutant sublines, CMR (7A) and CMR (7B), from rat glial cells, C6, using multiple consecutive selections with increasing concentrations of colcemid. The mutant sublines show a decreased uptake of [3H]colchicine but have no apparent defect in the cytoplasmic binding of the drug. The synthesis of the brain-specific S100 protein is less sensitive to colcemid inhibition in the mutant cell lines than in parental C6 cells, suggesting that colcemid must enter the cell to inhibit S100 protein synthesis.     

Colcemid inhibits the rejoining of the nucleotide excision repair of UVC-induced DNA damages in Chinese hamster ovary cells

In our previous study, we found that colcemid, an inhibitor of mitotic spindle, promotes UVC-induced apoptosis in Chinese hamster ovary cells (CHO.K1). In this study, a brief treatment of colcemid on cells after but not before UV irradiation could synergistically reduce the cell viability. Although colcemid did not affect the excision of UV-induced DNA damages such as [6-4] photoproducts or cyclobutane pyrimidine dimers, colcemid accumulated the DNA breaks when it was added to cells following UV-irradiation. This colcemid effect required nucleotide excision repair (NER) since the same accumulation of DNA breaks was barely or not detected in two NER defective strains of CHO cells, UV5 or UV24. Furthermore, the colcemid effect was not due to semi-conservative DNA replication or mitosis since the colcemid-caused accumulation of DNA breaks was also seen in non-replicating cells. Moreover, colcemid inhibited rejoining of DNA breaks accumulated by hydroxyurea/cytosine arabinoside following UV irradiation. Nevertheless, colcemid did not affect the unscheduled DNA synthesis as assayed by the incorporation of bromodeoxyuridine. Taken together, our results suggest that colcemid might inhibit the step of ligation of NER pathways.     

Delayed disruption of the telomeric links between chromosomes in experimentally induced cells with micronuclei exposed to 5-bromodeoxyuridine in the 1st S period after colcemid administration

Under a long-term administration of colcemid in the Chinese hamster cell culture some cells with micronuclei are seen to form. In the case of co-treatment with colcemid and 5-bromodeoxyuridine (5-BrdU) at metaphases of the first division of cells with micronuclei polycentric chromosomes were observed. These polycentric chromosomes occur due to delayed disruption of telomeric links, previously existing in the interphase. During colcemid treatment the cells pass through two S-periods: one in mononuclear cells, the other in cells with micronuclei. This phenomenon was tested according to the frequency of metaphases with dicentrics after 5-BrdU-treatment of cells at the first or second S-period or during the two cycles of chromosome replication. The 5-BrdU treatment during the first cycle or two cycles of replication resulted in the same frequency of cells with dicentrics--about 50%. The treatment with colcemid alone during two cycles of replication and administration 5-BrdU at the second S-period results in a considerably lower amount (%) of cells with dicentrics--about 10%. Thus, the delayed disruption of telomeric links between chromosomes may occur under the treatment with 5-BrdU at the first S-period after colcemid administration. It is also concluded that this phenomenon can be reproduced in cell with micronuclei when 5-BrdU is incorporated differentially in the sister chromatids.     

Colcemid inhibits the rejoining of the nucleotide excision repair of UVC-induced DNA damages in Chinese hamster ovary cells

In our previous study, we found that colcemid, an inhibitor of mitotic spindle, promotes UVC-induced apoptosis in Chinese hamster ovary cells (CHO.K1). In this study, a brief treatment of colcemid on cells after but not before UV irradiation could synergistically reduce the cell viability. Although colcemid did not affect the excision of UV-induced DNA damages such as [6–4] photoproducts or cyclobutane pyrimidine dimers, colcemid accumulated the DNA breaks when it was added to cells following UV-irradiation. This colcemid effect required nucleotide excision repair (NER) since the same accumulation of DNA breaks was barely or not detected in two NER defective strains of CHO cells, UV5 or UV24. Furthermore, the colcemid effect was not due to semi-conservative DNA replication or mitosis since the colcemid-caused accumulation of DNA breaks was also seen in non-replicating cells. Moreover, colcemid inhibited rejoining of DNA breaks accumulated by hydroxyurea/cytosine arabinoside following UV irradiation. Nevertheless, colcemid did not affect the unscheduled DNA synthesis as assayed by the incorporation of bromodeoxyuridine. Taken together, our results suggest that colcemid might inhibit the step of ligation of NER pathways.     

Commitment to ploidy conversion of 3Y1 cells during metaphase arrest by colcemid

Diploid rat 3Y1 fibroblasts proliferate to a saturation density, where they are arrested with a 2N DNA content. After treatment to induce ploidy conversion, the conversion rate can be estimated by determining the fraction of cells with a 4N DNA content in the confluent culture using flow cytometry. Using this method it was found that during mitotic inhibition with colcemid, 3Y1 cells were converted to tetraploids with a high efficiency (above 80%); the optimum colcemid concentration and exposure period were 40 ng/ml and 8 hr, respectively. When metaphase cells were reseeded with 40 ng/ml of colcemid, they delayed anchorage to a dish; 6 hr was required for complete adhesion (in the absence of colcemid only 1 hr was required). When reseeded metaphase cells were exposed to 40 ng/ml of colcemid for 5 hr followed by its removal, a greater fraction of the cells anchored to the substratum were converted to tetraploids, whereas most of the floating cells were not. A greater fraction of the anchored cells had formed nuclei, whereas most of the floating cells preserved condensed metaphase chromosomes. These results indicate that the cells which have formed nuclear structure without chromosome separation during mitotic inhibition are irreversibly committed to ploidy conversion, with restoration of anchorage.     

Effect of colcemid on the centrosome and microtubules in dermal melanophores of Xenopus laevis larvae in vivo.

An electron microscopy study showed that in melanophores with dispersed and aggregated pigment the sensitivity of the centrosome and the stability of microtubules were different and depended on the colcemid concentration. The structure of the centrosome didn't change upon exposure to colcemid in dispersed melanophores. In aggregated melanophores, on exposure to 10(-6) M colcemid, the centrosome retained its structure; colcemid at 10(-5)-10(-3) M caused a dramatic collapse of the centrosome. Treatment of aggregated melanophores with colcemid resulted in the complete disassembly of the microtubules; though microtubules in dispersed melanophores appear to be colcemid resistant. Light microscopy studies indicated that in Xenopus melanophores with aggregated or dispersed pigment melanosomes didn't change their location after exposure to 10(-3)-10(-6) M colcemid. Subsequent incubation in colcemid-free medium revealed that the cells retained their ability to translocate melanosomes in response to hormone stimulation. Electron microscopy data revealed the inactivation of the centrosome as MTOC (microtubule-organizing center) in dispersed melanophores with melatonin substituted for MSH in the presence of colcemid. In contrast, with melanocyte-stimulating hormone (MSH) substituted for melatonin, we observed the activation of the centrosome in aggregated cells. We showed that in aggregated melanophores pigment movement proceeded in the complete absence of microtubules, suggesting the involvement of a microtubule-independent component in the hormone-induced melanosome dispersion. However, we observed abnormal aggregation along colcemid-resistent microtubules in dispersed melanophores, suggesting the involvement of not only stable but also labile microtubules in the centripetal movement of melanosomes. The results raise the intriguing questions about the mechanism of the hormone and colcemid action on the centrosome structure and microtubule network in melanophores with dispersed and aggregated pigment.     

Commitment to Ploidy Conversion of 3y1 Cells During Metaphase Arrest By Colcemid

Abstract. Diploid rat 3Y1 fibroblasts proliferate to a saturation density, where they are arrested with a 2N DNA content. After treatment to induce ploidy conversion, the conversion rate can be estimated by determining the fraction of cells with a 4N DNA content in the confluent culture using flow cytometry. Using this method it was found that during mitotic inhibition with colcemid, 3Y1 cells were converted to tetraploids with a high efficiency (above 80%); the optimum colcemid concentration and exposure period were 40 ng/ml and 8 hr, respectively. When metaphase cells were reseeded with 40 ng/ml of colcemid, they delayed anchorage to a dish; 6 hr was required for complete adhesion (in the absence of colcemid only 1 hr was required). When reseeded metaphase cells were exposed to 40 ng/ml of colcemid for 5 hr followed by its removal, a greater fraction of the cells anchored to the substratum were converted to tetraploids, whereas most of the floating cells were not. A greater fraction of the anchored cells had formed nuclei, whereas most of the floating cells preserved condensed metaphase chromosomes. These results indicate that the cells which have formed nuclear structure without chromosome separation during mitotic inhibition are irreversibly committed to ploidy conversion, with restoration of anchorage.     

Biosynthesis of radiolabeled phomopsin by Phomopsis leptostromiformis.

[14C]phomopsin and [36Cl]phomopsin were synthesized by Phomopsis leptostromiformis in liquid cultures containing various labeled compounds. [U-14C]isoleucine, [U-14C]phenylalanine, and [U-14C]proline were the best precursors in terms of labeling efficiency, whereas [36Cl]hydrochloride was much less efficient. When each of the four precursors was used, a large proportion of recovered label was associated with phomopsin. The specific activities of phomopsin produced with labeled isoleucine, phenylalanine, proline, and hydrochloride were 150, 120, 90, and 17 muCi/mmol, respectively. 14C label from acetate, malate, propionate, sucrose, or tryptophan was neither specifically nor efficiently incorporated into phomopsin.     

Intra-allelic suppression of a mutation that stabilizes microtubules and confers resistance to colcemid

Cmd 4 is a colcemid resistant beta-tubulin mutant of Chinese hamster ovary cells that exhibits hypersensitivity to paclitaxel and temperature sensitivity for growth. The mutant beta-tubulin allele in this cell line encodes a D45Y amino acid substitution that produces colcemid resistance by making microtubules more stable. By selecting revertants of the temperature sensitive and paclitaxel hypersensitive phenotypes, we have identified three cis-acting suppressors of D45Y. One suppressor, V60A, maps to the same region as the D45Y alteration, and a second suppressor, Q292H, maps to a distant location. Both appear to produce compensatory changes in microtubule assembly that counteract the effects of the original D45Y substitution. Consistent with this view, expression of the V60A mutation in transfected wild-type cells produced paclitaxel resistance and greatly decreased microtubule assembly. Additionally, it produced a paclitaxel-dependent phenotype in which cells grew normally in the presence, but not the absence, of the drug. The Q292H mutation caused even greater disassembly of microtubules such that cells were unable to proliferate when the transgene was expressed; but, unlike the V60A mutation, cell growth could not be rescued by paclitaxel. A third suppressor, A254V, maps to a region near the interface between alpha- and beta-tubulin that contains the colchicine binding site. Although it made transfected wild-type cells hypersensitive to colcemid, it did not affect paclitaxel or vinblastine sensitivity, nor did it reduce microtubule assembly. We suggest that this mutation acts by increasing tubulin's affinity for colcemid.     

Effect of colcemid on the spreading of fibroblasts in culture

The effect of colcemid upon the spreading of mouse embryo fibroblast-like cells on substrates was studied with the aid of time-lapse microcinematography and scanning electron microscopy. Two types of substrates were used: flat glass and narrow strips of glass surrounded by non-adhesive lipid film; on the latter, spreading and polarization of cells proceeded simultaneously. On glass, colcemid did not prevent transition of cells into a well-attached state; however, the time required for this transition increased considerably as compared with control cultures. Similar effects were caused by two other drugs inhibiting the formation of microtubules: colchicine and vinblastine. The intermediate stages of spreading on flat glass had several abnormal features in the colcemid-containing medium: (a) the shape of cytoplasmatic outgrowths formed by the cell was altered and their distribution became less regular; (b) partial detachment of the attached parts of the cells was very frequent; (c) the spreading of various parts of the cell was not well correlated: the central part of the cell could remain unspread long after the spreading of the peripheral part. Similar effects of colcemid were observed in experiments with cells spreading on the narrow strips of the glass. In addition, colcemid prevented stabilization of the cell surface, i.e., differentiation of the cellular edge into active and stable parts. About two-thirds of the cells attached to the narrow strips of glass were completely detached from the substrate in the course of spreading in colcemid-containing medium. The possible mechanisms of the action of colcemid on spreading are discussed and it is suggested that intracellular structures sensitive to colcemid are essential for the coordination of the reactions in various parts of the cell in the course of spreading.     

Microtubular system in cultured mouse epithelial cells

Previous observations had shown that colcemid does not affect locomotion of epithelial cells. Nevertheless, cultured mouse kidney cells forming epithelial sheets were found to contain a well-developed microtubular system sensitive to colcemid. The orientation of microtubules in the epithelial cells was not correlated with the stable or active state of the cell edges. It is suggested that microtubular system of the epithelial cells forming coherent sheets, in contrast to that of individually moving fibroblasts, is not essential for stabilization of the lateral cell edges.     

The interaction of phomopsin A with bovine brain tubulin

Phomopsin A is an anti-mitotic compound from the fungus Phomopsis leptostroniformis which is a potent inhibitor of microtubule assembly in vitro; like maytansine, it is known to compete with vinblastine for binding to tubulin (E. Lacey, J. A. Edgar, and C. C. J. Culvenor (1987) Biochem. Pharmacol. 36, 2133-2138). A major difference between the effects of maytansine and vinblastine is that vinblastine is a potent inhibitor of tubulin decay, whereas maytansine has little or no effect on decay. Since phomopsin A is structurally distinct from either maytansine or vinblastine, tubulin decay may be measured by either the time-dependent loss of the ability to bind to [3H]colchicine or the time-dependent increase in the binding of bis(8-anilinonaphthalene 1-sulfonate) (BisANS) to tubulin. By either method, phomopsin A was found to be a much stronger inhibitor of tubulin decay than is vinblastine or any other drug yet tested, and in fact, when decay is measured by the increase of BisANS binding, phomopsin A appears to stop the process entirely. This may prove to be useful in the determination of the higher-order structure of the tubulin molecule.     

HYPODIPLOID METAPHASE FIGURES IN HUMAN LYMPHOCYTE CULTURES TREATED WITH COLCEMID

A small proportion of dividing human lymphocytes exposed to colcemid continued cytokinesis in spite of partial or complete destruction of the mitotic spindle which made normal chromosome distribution impossible. At low concentrations of colcemid the cells divided into two, three, or more parts about chromosome aggregates, to form separate, apparently intact units, often with very low chromosome numbers. Greater concentrations of colcemid caused a more even dispersal of the chromosomes, and the cells tended to divide into two parts, between which the chromosomes were more or less equally distributed on a random basis. This abnormal nuclear division is viewed in relation to the many known effects of colchicine and colcemid on mitosis and other stages of the cell proliferation cycle.     

Cytotoxic effects of colcemid or high specific activity tritiated thymidine on clonogenic cell survival in B6CF1 mice

High specific activity tritiated thymidine (HSA-[3H]TdR) and colcemid were given in cytotoxic doses and regimens to B6CF1/Anl mice. The number of cells per intestinal crypt was reduced by the S-phase-specific (HSA-[3H]TdR and the metaphase blocking and cytotoxic effect of multiple injections of colcemid. In 50-day-old mice, the cytotoxic effect of multiple injections of colcemid reduced both the number of cells per crypt and the clonogenic cell survival. However, the number of surviving intestinal clonogenic or stem cells, assayed by the microcolony technique, did not change in 110--130-day old mice. These data suggest that most of the cells at risk from these cytotoxic agents are not clonogenic in adult 110--130-day old mice but are the cells in amplification division. However, since the stem cells of young mice are more susceptible to colcemid, they are apparently in a more rapid cell cycle than those of older mice. The clonogenic cell survival measured in 110--130-day old mice after a single radiation dose of 14 Gy (1400 rad) responded in a non-linear way to increasing time of continuous colcemid cytotoxicity. These data suggest that the intestinal stem cells can respond to amplification compartment cell death by a shortening of their cell cycle and thus, over time, the number of stem cells at risk to colcemid cytotoxicity increases.     

Dual effect of protein kinase C on the induction of DNA synthesis by colcemid in G0-arrested human diploid fibroblasts

G0-arrested human diploid fibroblasts, TIG-1, was stimulated to induce DNA synthesis by serum, epidermal growth factor (EGF), colchicine, colcemid, or 12-O-tetradecanoylphorbol-13-acetate (TPA). The induction of DNA synthesis was mediated by protein kinase C (PKC) when stimulated with TPA but not when stimulated with other agents. When TPA-stimulated cells were immediately treated with colcemid, induction of DNA synthesis was reduced. This reduction diminished when colcemid was added more than 6 h after TPA treatment. Conversely, when colcemid-stimulated cells were treated with TPA, induction of DNA synthesis was also reduced. This reduction was enhanced when the interval between the addition of two stimulants was extended. PKC-deprivation abolished both stimulatory and inhibitory effects of TPA on DNA synthesis. Staurosporine blocked an induction of DNA synthesis by TPA but appeared to be ineffective on the inhibitory action of TPA on DNA synthesis by colcemid. These results suggest that the inhibitory effect of TPA on the induction of DNA synthesis by colcemid is mediated by down regulation-sensitive and staurosporine-insensitive PKC.     

Cytoplasmic microtubule assembly-disassembly from endogenous tubulin in a Brij-lysed cell model

We studied the characteristics of cytoplasmic microtubule reassembly from endogenous tubulin pools in situ using a Brij 58-lysed 3T3 cell system. Cells that were pretreated in vivo with colcemid retain endogenous tubulin in the depolymerized state after lysis. When lysed cells were removed from colcemid block and incubated in GTP-PIPES reassembly buffer at pH 6.9, microtubules repolymerized randomly throughout the cytoplasm, appeared to be free-ended and were generally not associated with the centrosomes. However, tubulin could be induced to polymerize in an organized manner from the centrosomes by increasing the pH to 7.6 in the presence of ATP and cAMP. Microtubules polymerized in ATP had significantly longer lengths than those assembled in GTP or UTP. When cells not treated with colcemid were lysed, the integrity of the cytoplasmic microtubule complex (CMTC) was maintained during subsequent incubation in reassembly buffer. However, in contrast to unlysed, living cells, microtubules of lysed cells were stable to colchicine. A significant fraction of the CMTC was stable to cold- induced disassembly whereas microtubules reassembled after lysis were extremely cold-sensitive. When cells not treated with colcemid were lysed and incubated in millimolar Ca++, microtubules depolymerized from their distal ends and a much reduced CMTC was observed. Ca++ reversal with EGTA rapidly resulted in a reformation of the CMTC apparently by elongation of Ca++ resistant microtubules.     

Morphology of the microtubule system in mouse kidney epithelial cells]

The cultured mouse kidney cells forming epithelial sheets were studied using an indirect immunofluorescence microscopy with antibodies against tubulin. These cells, as well as fibroblasts, were found to contain a well developed microtubular system sensitive to colcemid. The assembly of microtubules after washing out of colcemid began from one or two perinuclear centers, associated with the cilium-like structure. There were certain differences between the microtubular systems in epithelial cells and fibroblasts: 1) Microtubules in the fibroblasts penetrated the whole cytoplasm including the peripheral lamella whereas in the epithelial cells the lamellar cytoplasm was often free from microtubules. 2) The orientation of microtubules in the epithelial cells, unlike in the fibroblasts, was not correlated with the stable or active state of the cell margin. A possible role of microtubular system in the epithelial cells and fibroblasts is compared and discussed.     

Paclitaxel resistance in cells with reduced beta-tubulin

We previously described the isolation of colcemid resistant Chinese hamster ovary cell lines containing alpha- and beta-tubulin mutations that increase microtubule assembly and stability. By analyzing colcemid sensitive revertants from one of the beta-tubulin mutants, we now find that loss or inactivation of the mutant allele represents the most common mechanism of reversion. Consistent with this loss, the revertants have 35% less tubulin at steady state, no evidence for the presence of a mutant polypeptide, and a normal extent of tubulin polymerization. In addition to the loss of colcemid resistance, the revertant cells exhibit increased resistance to paclitaxel relative to wild-type cells. This paclitaxel resistance can be suppressed by transfecting the revertant cells with a cDNA for wild-type beta-tubulin, indicating that the reduction in tubulin in the revertant cells is responsible for the resistance phenotype. We propose that reducing tubulin levels may represent a novel mechanism of paclitaxel resistance.