Nordihydroguaiaretic acid,of a new family of microtubule-stabilizing agents,shows effects differentiated from paclitaxel

Nordihydroguaiaretic acid (NDGA) protected microtubules in NRK cells from depolymerization caused by structurally and functionally diverse drugs such as nocodazole, colchicine, vinblastine, and ilimaquinone. Hitherto reported drugs, although structurally unrelated to paclitaxel, stabilize microtubules in a way similar to that of paclitaxel and compete for paclitaxel binding to tubulin. However, NDGA had activity toward microtubules different from the effects of paclitaxel. In NRK cells, paclitaxel caused microtubule bundle formation in the presence and absence of microtubule-depolymerizing drugs. However, microtubule bundle did not form, and microtubules radiated from the microtubule-organizing center, in cells treated with NDGA. Acceleration of tubulin polymerization in vitro by paclitaxel was strong but that by NDGA was weak. Microtubules polymerized in vitro in the presence of paclitaxel, but not those polymerized in the presence of NDGA, resisted the effects of cold. NDGA seemed to bind to tubulin, but did not compete for [3H]paclitaxel binding to tubulin. These observations indicate that NDGA belongs to a novel family of microtubule-stabilizing drugs.     

Tubulin and benzimidazole-resistance in Trichostrongylus colubriformis (Nematoda)

Benzimidazole treatment produced greater effects on microtubule-dependent acetylcholinesterase secretion, the presence of microtubules in intestinal cells, and colchicine binding in susceptible compared with benzimidazole-resistant Trichostrongylus colubriformis. In addition, the binding of benzimidazoles was markedly reduced in preparations from the latter strain, indicating that the mechanism of resistance to benzimidazoles in this nematode involves a reduced affinity of tubulin for benzimidazoles.     

Effects of local anesthetics on membrane properties. II. Enhancement of the susceptibility of mammalian cells to agglutination by plant lectins.

Treatment of untransformed mouse and hamster cells with the tertiary amine local anesthetics dibucaine, tetracaine and procaine increases their susceptibility to agglutination by low doses of the plant lectin concanavalin A. Agglutination of anesthetic-treated untransformed cells by low doses of concanavalin A is accompanied by redistribution of concanavalin A receptors on the cell surface to form patches, similar to that occurring in spontaneous agglutination of virus-transformed cells by concanavalin A. Immunofluorescence and freeze-fracture electronmicroscopic observations indicate that local anesthetics per se do not induce this redistribution of concanavalin A receptors but modify the plasma membrane so that receptor redistribution is facilitated on binding of concanavalin A to the cell surface. Fluorescence polarization measurements on the rotational freedom of the membrane-associated probe, diphenylhexatriene, indicate that local anesthetics produce a small increase in the fluidity of membrane lipids. Spontaneous agglutination of transformed cells by low doses of concanavalin A is inhibited by colchicine and vinblastine but these alkaloids have no effect on concanavalin A agglutination of anesthetic-treated cells. Evidence is presented which suggests that local anesthetics may impair membrane peripheral proteins sensitive to colchicine (microtubules) and cytochalasin-B (microfilaments). Combined treatment of untransformed 3T3 cells with colchicine and cytochalasin B mimics the effect of local anesthetics in enhancing susceptibility to agglutination by low doses of concanavalin A. A hypothesis is presented on the respective roles of colchicine-sensitive and cytochalasin B-sensitive peripheral membrane proteins in controlling the topographical distribution of lectin receptors on the cell surface.     

Effects of local anesthetics on membrane properties II. Enhancement of the susceptibility of mammalian cells to agglutination by plant lectins

Treatment of untransformed mouse and hamster cells with the tertiary amine local anesthetics dibucaine, tetracaine and procaine increases their susceptibility to agglutination by low doses of the plant lectin concanavalin A. Agglutination of anesthetic-treated untransformed cells by low doses of concanavalin A is accompanied by redistribution of concanavalin A receptors on the cell surface to form patches, similar to that occurring in spontaneous agglutination of virus-transformed cells by concanavalin A. Immunofluorescence and freeze-fracture electronmicroscopic observations indicate that local anesthetics per se do not induce this redistribution of concanavalin A receptors but modify the plasma membrane so that receptor redistribution is facilitated on binding of concanavalin A to the cell surface. Fluorescence polarization measurements on the rotational freedom of the membrane-associated probe, diphenylhexatriene, indicate that local anesthetics produce a small increase in the fluidity of membrane lipids. Spontaneous agglutination of transformed cells by low doses of concanavalin A is inhibited by colchicine and vinblastine but these alkaloids have no effect on concanavalin A agglutination of anesthetic-treated cells. Evidence is presented which suggests that local anesthetics may impair membrane peripheral proteins sensitive to colchicine (microtubules) and cytochalasin-B (microfilaments). Combined treatment of untransformed 3T3 cells with colchicine and cytochalasin B mimics the effect of local anesthetics in enhancing susceptibility to agglutination by low doses of concanavalin A. A hypothesis is presented on the respective roles of colchicine-sensitive and cytochalasin B-sensitive peripheral membrane proteins in controlling the topographical distribution of lectin receptors on the cell surface.     

Effect of local anesthetics on plasma protein secretion by rat hepatocytes

The effects of some local anesthetics on plasma protein secretion by rat liver slices have been studied and have been compared with those of colchicine. Rat liver slices were pulse-labelled with l-[¹⁴C]leucine for 9 min at 37°C, collected on filter paper, washed with non-radioactive leucine and reincubated in the presence or absence of the drug to be tested. The radioactive plasma proteins produced were obtained by immunoprecipitation from either the chase medium or from the washed slices. Chlorpomazine, (3 · 10^?5 M), dibucaine (10^?5 M), lidocaine (10^?3 M) and procaine (5 · 10^?5 M) inhibited both the synthesis and secretion of plasma protein but did not affect the uptake of l-leucine into the slices nor the incorporation of phosphate into intracellular nucleotide phosphates or into phopholipids. The inhibition of secretion elicited by these drugs is probably not due to the inhibition of protein synthesis since cycloheximide, when added to the chase medium at a concentration which completely inhibits protein synthesis, did not inhibit plasma protein secretion, while cycloheximide plus procaine did inhibit secretion and also caused a retention of non-secreted plasma proteins within the slices. Unlike colchicine, howover, procaine did not cause the retained plasma proteins to accumulate in Goli-derived secretory vesicles, but showed a more general effect causing a distribution among several cell fractions.     

Microtubules and protein secretion in rat lacrimal glands. Inhibitory effect of the tubulin . colchicine complex isolated from lacrimal glands upon brain tubulin polymerization. Identification of the complex by gel electrophoresis.

The specific inhibitory effect of colchicine upon protein secretion by lacrimal glands could be related to the formation of a complex between colchicine and tubulin from the soluble fraction of the gland. By gel electrophoresis under nondissociating conditions, it is shown that this complex is similar to the colchicine . tubulin complex from brain. The complex isolated from lacrimal glands is highly inhibitory upon brain tubulin assembly since as low as 0.07 microM complex impedes the polymerization of 8 microM tubulin by 50%, compared to 3 microM for free colchicine. Therefore, a small percentage of complexed tubulin (0.9%) is enough for polymerization to be blocked. In lacrimal glands the complex might prevent the polymerization of tubulin, and colchicine shift the tubulin in equilibrium microtubules equilibrium to microtubules disassembly. The disorganization of the labile microtubular system could lead to a modification of the transport of the secretory granules and to a perturbation of secretion.     

Effect of drugs affecting microtubular assembly on microtubules, phospholipid synthesis and physiological indices (signalling, growth, motility and phagocytosis) in Tetrahymena pyriformis

Structural changes of microtubules, incorporation of radioactively labelled components into phospholipids, cell motility, growth and phagocytosis were studied under the effect of four drugs affecting microtubular assembly: colchicine, nocodazole, vinblastine and taxol. Although the first three agents influence microtubules in the direction of depolymerization and the fourth stabilizes them, their effects on the structure of microtubules cannot be explained by this. Using confocal microscopy after an acetylated anti-tubulin label, in nocodazole- and colchicine-treated cells, the basal body cages disappear and longitudinal microtubules (LM) became thinner without changing transversal microtubules (TM). After taxol treatment LM also became thinner, however TM disappeared. Under the effect of vinblastine TM became thinner, without influencing LM. These drugs influence the incorporation of components ([(3)H]-serine, [(3)H]-palmitic acid and (32)P) into phospholipids, however their effect is equivocal and cannot be consequently coupled with the effect on the microtubules. Nocodazole, vinblastine and taxol significantly reduced the cell's motility, however colchicine did so to a lesser degree. Vinblastine and nocodazole totally inhibited, and taxol significantly decreased cell growth, while colchicine in a lower concentration increased the multiplication of cells. Phagocytosis was not significantly influenced after 1 min, but after 5 min all the agents studied (except colchicine) significantly inhibited phagocytosis. After 15 and 30 min each molecule caused highly significant inhibition. The experiments demonstrate that drugs affecting microtubular assembly dynamics influence differently the diverse (longitudinal, transversal etc.) microtubular systems of Tetrahymena and also differently influence microtubule-dependent physiological processes. The latter are more dependent on microtubular dynamics than are changes in phospholipid signalling.     

4-Hydroxynonenal interacts with tubulin by reacting with its functional -SH groups

4-Hydroxynonenal, which is one of the most important products of lipid peroxidation, alters microtubular organization and structure in 3T3 fibroblasts. Changes in cell shape and the disappearance of microtubules are observed by immunofluorescence after incubation with the aldehyde, and the colchicine binding activity of tubulin from 3T3 cells is modified. Moreover, the aldehyde determines a decrease in the ability of purified tubulin to polymerize and to bind colchicine. These effects may be related to the interaction of the aldehyde with functional -SH groups of tubulin which are necessary for protein integrity and functions. Indeed, the addition of cysteine protects against the damaging effects of the aldehyde.     

Microtubules and beta cell function: effect of colchicine on microtubules and insulin secretion in vitro by mouse beta cells

A monolayer culture system was developed to study the role of microtubules in insulin secretion. Cultured cells were obtained to study the role of microtubules in insulin secretion. Cultured cells were obtained by enzymatic digestion of pancreases from C57BL-KsJ mice 6-12 wk of age. On day 4 of culture, the medium was changed, control or treatment medium added, and frequent samples were removed for insulin assay. Microtubules and beta cells were identified by indirect immunofluorescence with monospecific antibodies to tubulin and insulin. An extensive microtubule network radiates from the perinuclear region of the beta cell to the plasma membrane. Although alterations in the calcium concentration of the medium did not affect the microtubule pattern, the absence of calcium or glucose in the medium inhibited insulin secretion (P less than 0.001). Optimum insulin release occurred at a calcium concentration of 2.5 mM. Colchicine, in concentrations of 10(-10) M, did not affect the microtubule immunofluorescent pattern, whereas concentrations of 1 and 5 x 10(-7) M decreased the number of microtubules, and microtubules could not be identified in cultures treated with 10(-6) M colchicine for 2 h. After a 2-h preincubation, the prolonged release of insulin at either 2.0 or 4.5 mg/ml of glucose was decreased by 10(-6) M colchicine (P less than 0.02). The immediate release of insulin was similar to that in control plates and occurred in cultures with no identifiable microtubules. Microtubules and insulin secretion were not altered by 10(-6) M lumicolchicine and prolonged insulin secretion recovered 24 h after removal of colchicine. These studies show that the microtubules facilitate sustained secretion of insulin but are not required for the immediate release of the hormone. Alterations in the extracellular calcium concentration which play an essential role in insulin secretion do not alter the microtubule pattern in the beta cell.     

Cell shape changes and transmembrane receptor uncoupling induced by tertiary amine local anesthetics

Tertiary amine local anesthetics (dibucaine, Tetracaine, procaine, etc.) modify cell morphology, concanavalin A (Con A)-mediated agglutinability and redistribution of Con A receptors. Con A agglutination of untransformed mouse 3T3 cells was enhanced at low concentrations of local anesthetics, and the dynamics of fluorescent-Con A indicated that ligand-induced clustering was increased in the presence of the drugs. In contast, these drugs inhibited Con A-induced receptor capping on mouse spleen cells. These effects can be duplicated by combinations of vinblastine (or colchicine) and cytochalasin B suggesting that local anesthetics act on microtubule cell surface receptor mobility and distribution. It is proposed that tertiary amine local anesthetics displace plasma membrane-bond Ca²⁺, resulting in disengagement of microfilament systems from the plasma membrane and increased cellular Ca²⁺ concentration to levels which disrupt microtubular organization. The possible involvement of cellular Ca²⁺ in cytoskeletal destruction by local anesthetics was investigated utilizing Ca²⁺-specific ionophores A23187 and X537A. In media containing Ca²⁺ and cytochalasin B these ionophores caused effects similar to tertiary amine local anesthetics.     

A radioligand binding assay for antitubulin activity in tumor cells

The benzamide RH-5854 is shown to be highly potent toward tumor cells and to arrest nuclear division by a highly specific covalent binding to the beta-subunit of tubulin in the colchicine binding region. Binding of 3H-RH-5854 to beta-tubulin in HCT-116 colon cancer cells is saturable and has been exploited in the development of a cell-based competitive binding assay, which allows antitubulin effects to be detected in whole cells. 3H-RH-5854 binding is strongly inhibited by preincubating the cells with compounds that bind to the colchicine site and with paclitaxel. Binding of 3H-RH-5854 is enhanced by preincubating the cells with vinblastine but not by other agents that bind at or near the vinblastine site (ansamitocin P-3 and phomopsin A). Various cytotoxic agents that do not act on tubulin do not affect binding of 3H-RH-5854 in HCT-116 cells, demonstrating specificity of the assay for detection of antitubulin activity. As an alternative to traditional assays that employ isolated brain tubulin, the 3HRH-5854 binding assay enables screening for antitubulin effects directly in tumor cells, providing an assay that accounts for cell-specific criteria that influence sensitivity such as different tubulin isotypes, tubulin mutations, drug metabolism, and efflux mechanisms.     

EFFECTS OF PSYCHOTROPIC DRUGS ON NEUROTUBULE ASSEMBLY

Abstract— The interaction of psychotropic drugs with brain microtubules was assessed by viscometry, [³H]colchicine binding studies and neurite growth in neuroblastoma cells in tissue culture. Of the thirteen drug- tested, only d-amphetamine, chlorpromazine and reserpine inhibited the in vitro repoly-merization of microtubules. However, the maximal drug effects observed in these studies occurred at concentrations in excess of the pharmacologically theraputic range. These results suggest: (1) the affinity of these drugs for tubulin appears to be similar to, but clearly less than, that observed for colchicine; (2) the toxic side effects of these drugs may be mediated, in part, by the microtubule system; (3) these drugs may inhibit microtubule assembly by disrupting secondary processes rather than by a direct interaction with tubulin.     

Role of membrane colchicine binding proteins in the transmission of prolactin message to casein genes in the rabbit mammary gland

Previous work demonstrated that tubulin binding drugs specifically inhibit the capacity of prolactin to initiate casein and DNA synthesis in the mammary cell. It was concluded that microtubules or other tubulin containing cellular structures were involved in the transmission of the prolactin message to genes. In the present work, it is shown that griseofulvin, an antimitotic drug which alters microtubule structure and function, does not prevent prolactin actions. Autoradiographic studies showed that [3H]colchicine binds preferentially to plasma and Golgi membranes in the mammary cell. Short term cultures of mammary explants with [3H]colchicine demonstrated that the labelled drug binds to membranous cellular structures which were isolated from explants at the end of the culture. Fractions containing plasma and Golgi membranes contained the highest amount of radioactivity. Solubilisation of the membranes by Triton X-100 dissociated the [3H]colchicine from the prolactin receptors as judged by a chromatography of the soluble fraction on a Sepharose 6 B column. On the column, the labelled colchicine remains associated with a molecular entity which may be free tubulin. In all cases, the binding of [3H]colchicine was greatly attenuated by an excess of unlabelled colchicine but was only slightly affected by the competition with lumicolchicine. These results suggest that mammary membranes contain tubulin and that binding of drugs to this molecule inhibits the generation of the prolactin second messengers eliciting the hormonal actions in the mammary cell. This also suggests that microtubules are probably not involved in the mechanism of prolactin action.     

Effects of local anesthetics on cell morphology and membrane-associated cytoskeletal organization in BALB/3T3 cells

Tertiary amine local anesthetics (dibucaine, tetracaine, procaine) reversibly affect the morphology of untransformed BALB/3T3 cells and the organization of membrane-associated cytoskeletal elements. In the presence of these drugs cells contract and become rounded in shape with the appearance of numerous surface "blebs." Electron microscope examination of anesthetic-treated cells revealed significant reductions in plasma membrane-associated microtubules and microfilaments and/or their plasma membrane attachment. The relationship of the findings on local anesthetic-induced changes in cellular cytoskeletal systems is discussed in relation to previous proposals on plasma membrane organization and control of cell surface receptor topography and mobility.     

Fluorescent deacetylcolchicine: New aspects of its activity and localization in PtK-1 cells

PtK-1 cells have been used to localize structures which are decorated by deacetylcolchicine conjugated with fluorescein isothiocyanate (FDC). This colchicine derivative competitively inhibits [³H]colchicine binding to soluble tubulin, is able to depolymerize microtubules (MTs) assembled in vitro, and inhibits cell growth by arresting colchicine-sensitive cells in mitosis. Fixed cells were incubated with FDC (10^?5 M), and/or with tetramethyl rhodamine-labelled anti-tubulin antibodies using the indirect immunofluorescence technique. In double label microscopy the cells show corresponding fluorescence of MTs after incubation with anti-tubulin antibodies and FDC. This can be demonstrated most clearly with cells in mitosis which are preincubated with the microtubule-stabilizing agent taxol. FDC binding is decreased, but not completely blocked, by preincubation of fixed cells with unlabelled colchicine (10^?4 M). Trimethyl colchicinic acid (TMCA) conjugated with FITC, a colchicine derivative which does not bind to soluble tubulin, and FITC alone, inactivated by methylamine, do not bind to MTs. These results demonstrate that FDC is able to decorate and to depolymerize sensitive MTs, indicating a direct action of the drug on these structures. Furthermore, the labelling of other cellular structures by FDC, possibly membrane systems as well as chromatin, is compared with recent data.     

Cold-stable microtubules in the cytoplasm of mouse embryo fibroblasts.

Treatment of cultured mouse embryo fibroblasts with Triton X-100 after prolonged incubation at 0 degrees C reveals a network of microtubules in the cytoplasm of cooled cells. This network of cold-stable microtubules was demonstrated by immunofluorescence microscopy, using a monospecific antibody against tubulin and by electron microscopy. The cold-stable microtubules, as well as the ordinary cytoplasmic microtubules, were sensitive to Ca ions and were not observed in the cells pre-treated with colchicine or vinblastine. The cold-stable microtubules do not seem to be in equilibrium with the pool of depolymerized tubulin at 0 degrees C.     

Microtubule-associated proteins-dependent colchicine stability of acetylated cold-labile brain microtubules from the Atlantic cod, Gadus morhua

Assembly of brain microtubule proteins isolated from the Atlantic cod, Gadus morhua, was found to be much less sensitive to colchicine than assembly of bovine brain microtubules, which was completely inhibited by low colchicine concentrations (10 microM). The degree of disassembly by colchicine was also less for cod microtubules. The lack of colchicine effect was not caused by a lower affinity of colchicine to cod tubulin, as colchicine bound to cod tubulin with a dissociation constant, Kd, and a binding ratio close to that of bovine tubulin. Cod brain tubulin was highly acetylated and mainly detyrosinated, as opposed to bovine tubulin. When cod tubulin, purified by means of phosphocellulose chromatography, was assembled by addition of DMSO in the absence of microtubule-associated proteins (MAPs), the microtubules became sensitive to low concentrations of colchicine. They were, however, slightly more stable to disassembly, indicating that posttranslational modifications induce a somewhat increased stability to colchicine. The stability was mainly MAPs dependent, as it increased markedly in the presence of MAPs. The stability was not caused by an extremely large amount of cod MAPs, since there were slightly less MAPs in cod than in bovine microtubules. When "hybrid" microtubules were assembled from cod tubulin and bovine MAPs, these microtubules became less sensitive to colchicine. This was not a general effect of MAPs, since bovine MAPs did not induce a colchicine stability of microtubules assembled from bovine tubulin. We can therefore conclude that MAPs can induce colchicine stability of colchicine labile acetylated tubulin.     

Ionophore-induced disassembly of blood platelet microtubules: effect of cyclic AMP and indomethacin

Cytoplasmic calcium levels are believed to be important in blood platelet activation. Upon activation, the discrete marginal microtubule band, which maintains the discoid shape of non-activated platelets, becomes disrupted. Present studies demonstrate that the extent of assembly of the marginal microtubule band is related to cytoplasmic calcium levels. The divalent cationophore, A23187, causes platelet aggregation, secretion, and contraction by promoting calcium transport from intraplatelet storage sites into the cytoplasm. A23187 caused disassembly of platelet microtubules. Quantitation of electron micrographs revealed that numbers of microtubules were reduced by approximately 80% after A23187 treatment. Secondly, assembled microtubules in homogenates of platelets, in which microtubules were stabilized prior to homogenization, were decreased in favor of free tubulin in A23187-treated platelets. Thirdly, A23187 increased 14C-colchicine binding by intact platelets; this also indicated a shift in the microtubule subunit equilibrium to favor free, colchicine-binding tubulin subunits. In control experiments, A23187 did not affect the stability of platelet tubulin, the colchicine binding reaction, or the total tubulin content of platelets. Stimulation of colchicine binding depended on A23187 concentration (0.05-0.5 microM) and did not require extracellular calcium. A23187-stimulation of colchicine binding was blocked by dibutyryl cyclic AMP (0.80 mM) and/or 3-isobutyl-1-methylxanthine (50 microM) and by indomethacin (10 microM). Cyclic AMP or indomethacin also interferes with A23187-induced platelet activation, but indomethacin is not likely to completely inhibit the perturbation of intraplatelet calcium gradients by A23187. It is suggested that A23187-induced microtubule disassembly may be an indirect effect of calcium on microtubules.     

IV. Neurotoxicity of colchicine and other tubulin-binding agents: A selective vulnerability of certain neurons to the disruption of microtubules

Colchicine and certain other agents which disrupt microtubules and interfere with axonal and dendritic transport are highly toxic to certain CNS neurons. The present chapter summarizes our knowledge about this selective neurotoxicity. Injections of colchicine into several brain regions lead to the death of selected populations of neurons within those regions. Intra-hippocampal injections selectively destroy granule cells of the dentate gyrus; hippocampal pyramidal cells are essentially unaffected. Injections into the cerebellum, olfactory bulb, and caudate nucleus also destroy resident neurons. In these areas several cell types are vulnerable. Neurons of the cerebral cortex appear to be much less affected by colchicine, although some neurons of paleocortical regions are vulnerable. Colchicine does not appear to be an excitotoxin like kainic acid.The neurotoxicity of colchicine appears to be related to the destruction of microtubules, since other agents which disrupt microtubules have similar toxic effects, and since analogs of colchicine which do not disrupt microtubules are non-toxic. Colchicine may induce an autotoxic response which leads to neuronal death in certain populations due to the accumulation of some toxic cellular product which is normally transported by a microtubule-dependent process. The selective vulnerability of neurons to the neurotoxic effects of colchicine may be a model for system degenerations of the central nervous system in which certain subpopulations of neurons are selectively vulnerable to abnormal accumulations of metabolic products.     

Effects of local anesthetics on cytokinesis and polar lobe formation in fertilized eggs of Ilyanassa obsoleta

Summary

We have examined the ability of fertilized eggs of Ilyanassa obsoleta to form polar lobe constrictions and undergo cytokinesis in the presence of several local anesthetics and compared these effects with those of drugs known to affect microtubules. Procaine, lidocaine (Xylocaine), mepivacaine, tetracaine, and dibucaine all delay the beginning of polar lobe constrictions at low concentrations and in the order of their lipid solubilities. All of the anesthetics are effective at lower concentrations in the absence of extracellular Ca²⁺. Procaine and tetracaine ‘lock’ cells for several hours halfway through the constriction of the polar lobe neck and prevent subsequent cytokinesis, effects similar to those of the microtubule agents, colchicine and nocodazole. Procaine has no effect on membrane potential, ψ_m, or on intracellular chloride activity, (Cl)_c, as determined with ion-selective microelectrodes. This suggests that procaine does not inhibit cellular shape changes by affecting the ionic activities of the predominant intracellular cation (K⁺) or anion (Cl^?).