Gliding motility of algae in unaffected by cytochalasin B

The effect of the antibiotic cytochalasin B on gliding motility of Oscillatoria and Navicula was studied using time lapse microcinematography. Contrary to its effects on many other non-muscle motile systems, cytochalasin B did not significantly inhibit motility.     

GLIDING MOTILITY OF OSCILLATORIA: ULTRASTRUCTURAL AND CHEMICAL CHARACTERIZATION OF THE FIBRILLAR LAYER1,2

Ultrastructural examination of platinum-carbon replicated trichomes or wall fragments of 3 Oscilatoria species readily displayed the fibrillar components of the presumed motility system. These fibrils had a lateral organization as well as longitudinal continuity and wavelike distortions, which are consistent with the hypothesized movement mechanism. The fibrils were sensitive to proteolytic enzymes but resistant to hydrolytic agents, suggesting a protein composition. The fibrils and motility were unaffected by cytochalasin B.     

Effect of Colchicine,Vinblastine, and Cytochalasin B on Cell Surface Anionic Sites of Tritrichomonas foetus1

ABSTRACT. Drugs that interact with microtubules (colchicine and vinblastine) and microfilaments (cytochalasin B) partially inhibited cell growth and motility of Tritrichomonas foetus. Parasites incubated with these substances became rounded and cell division was blocked. Neither colchicine nor vinblastine disrupted the microtubules that form the peltar-axostylar system. Any one of these drugs interfered with the net negative surface charge of T. foetus as evaluated by determination of the cellular electrophoretic mobility (EPM). The decrease in the EPM of cytochalasin B-treated cells was caused by dimethylsulfoxide, which was used as solvent. Untreated cells as well as cytochalasin B-treated cells showed a uniform distribution of anionic sites on the plasma membrane as seen with cationized ferritin particles. In cells treated with colchicine or vinblastine the anionic sites were distributed in patches. These results are discussed in terms of participation of labile cytoplasmic microtubules and microfilaments in the control of the distribution of anionic sitecontaining macromolecules located on the cell surface of T. foetus.     

INHIBITION OF PHAGOCYTOSIS AND PLASMA MEMBRANE MOBILITY OF THE CULTIVATED MACROPHAGE BY CYTOCHALASIN B : Role of Subplasmalemmal Microfilaments

Functional and morphologic effects of cytochalasin B on the cultivated macrophage were examined to determine the basis for plasma membrane movements of the type required for endocytosis and/or spreading on a substratum. Inhibition of phagocytosis and changes in cell shape by cytochalasin B exhibited nearly identical dose-response curves requiring 2–5 x 10^-6 M and 1–2 x 10^-5 M cytochalasin B to inhibit these functions by 50% and 100%, respectively. In contrast, hexose transport was ten times more sensitive to the drug requiring 2–3 x 10^-7 M cytochalasin B to achieve 50% inhibition of 2-deoxyglucose uptake. Inhibition of phagocytosis and changes in cell shape could not be explained solely by drug effects on hexose transport. Analysis of serial thin sections showed that cytochalasin B doses inhibitory for hexose transport had no effect on distribution or organization of either of the two subplasmalemmal microfilament types. However, cytochalasin B concentrations (2.0 x 10^-5 M) that inhibited phagocytosis and altered cell shape disorganized and/or disrupted oriented bundles of 40–50-Å subplasmalemmal microfilaments, but had no effect on the microfilamentous network. Comparative dose-response studies showing positive correlations among cytochalasin B effects on phagocytosis, changes in cell shape, and alterations in oriented subplasmalemmal microfilament bundles provide additional support for the hypothesis that microfilamentous structures play a role in translocation of plasma membrane required for endocytosis and cell motility.     

Cytochalasin B inhibition of brain glucose transport and the influence of blood components on inhibitor concentration

The effect of cytochalasin B on cerebral glucose transport and metabolism was investigated in 19 isolated perfused dog brain preparations. Cytochalasin B is a potent, non-competitive inhibitor of glucose transport at the blood-brain interface. Both glucose transport into (K_i = 6.6 ± 1.9 μM) and out of the capillary endothelial cell are inhibited. The inhibition is readily reversible by perfusion with blood containing no cytochalasin B. After 2 min of exposure to 30 μM cytochalasin B, the cerebral oxygen consumption decreased by 31% probably due to decreased availability of glucose for oxidative metabolism. About one-half of the cytochalasin B that is dissolved in blood is bound to erythrocytes and other blood components while the remainder is free.     

Effects of hyaluronic acid in culture and cytochalasin B treatment before freezing on survival of cryopreserved bovine embryos produced in vitro

Summary One limitation to the widespread use of in vitro-produced embryos in cattle is their poor survival following cryopreservation. Two approaches for enhancing survival of in vitro-produced bovine embryos following cryopreservation were evaluated: culture in the presence of hyaluronic acid and alterations in the cytoskeleton through cytochalasin B treatment. The experiment was a 2×2 factorial design to test main effects of hyaluronic acid added to culture at day 5 after insemination (+or−) and cryopreservation treatment (control or cytochalasin B). Embryos used for cryopreservation were blastocysts and expanded blastocysts harvested on day 7 after insemination. Cytochalasin B increased the percent of embryos that re-expanded (P<0.0001) and that hatched following thawing (P<0.05). The hatching percent was 29.6% for embryos treated with cytochalasin B versus 9.1% for control embryos. There was no significant effect of hyaluronic acid on survival although there was a tendency for embryos cultured with hyaluronic acid to have higher percent hatching if not treated with cytochalasin B (12.7% for hyaluronic acid versus 4.5% for control; hyaluronic acid x cytochalasin B interaction; P=0.09). In conclusion, cytochalasin B treatment before freezing improved cryosurvival of bovine embryos produced in vitro. Such a treatment could be incorporated into methods for cryopreservation of bovine embryos provided post-transfer survival is adequate. In contrast, culture with hyaluronic acid was of minimal benefit—the increased cryosurvival in the absence of cytochalasin B was not sufficient to allow an adequate number of embryos to survive.     

Effect of strain and cultural conditions on the production of cytochalasin B by the potential mycoherbicide Pyrenophora semeniperda (Pleosporaceae,Pleosporales)

The seed pathogen Pyrenophora semeniperda has demonstrated potential as a mycoherbicidal biocontrol for eliminating persistent seed banks of annual bromes on western North American rangelands. This pathogen exhibits variation in virulence that is related to mycelial growth rate, but direct laboratory tests of virulence on seeds often have low repeatability. We developed a rapid and sensitive high pressure liquid chromatography method for quantification of the phytotoxin cytochalasin B in complex mixtures in order to evaluate its use in virulence screening. All 10 strains tested produced large quantities of this metabolite in solid wheat seed culture, with production varying over a fourfold range (535–2256 mg kg^?1). No cytochalasin B was produced in liquid potato dextrose broth culture, showing that its synthesis is strongly dependent on cultural conditions. In a Bromus tectorum coleoptile bioassay, solid culture extracts showed mild toxicity similar to the cytochalasin B standard at a concentration equivalent to 10^?4 M cytochalasin B (72–95% of control), whereas at 10^?3 M equivalent, the extracts exhibited significantly higher toxicity (8–18% of control) than the cytochalasin B standard (34% of control). This suggests the possible presence of other phytotoxic metabolites. Cytochalasin B production in solid wheat seed culture exhibited the predicted significant negative correlation with mycelial growth rate on potato dextrose agar, but the correlation was not very strong, possibly because cytochalasin B production and growth rate were measured under different cultural conditions.     

Preparation,In Vivo Administration,Dose-Limiting Toxicities,and Antineoplastic Activity of Cytochalasin B

An effective and inexpensive protocol for producing cytochalasins A and B is being disclosed to propose a viable method by which to examine the in vivo antineoplastic activity of these congeners in preclinical tumor-bearing mammalian models. In addition, we determine the maximum tolerated doses of cytochalasin B using multiple routes and formulations, characterize the tissue distribution of intravenous bolus cytochalasin B, and assess the in vivo antineoplastic activity of cytochalasin B in comparison in doxorubicin in Balb/c mice challenged intradermally with M109 murine lung carcinoma. We also examine the effects of cytochalasin B against several other murine neoplastic cell lines (Lewis lung, LA4, B16F10, and M5076). Finally, we examine a potential mechanism of the antimetastatic activity of cytochalasin B by observing the effects of the agent on the secretion of N-acetylglucosaminidase (GlcNACase) by B16BL6 and B16F10 murine melanomas in vitro. The results of the study can be summarized as follows: 1) Cytochalasin B can be safely administered intravenously, intraperitoneally, and subcutaneously in murine models, with the maximum tolerated dose of all routes of administration being increased by liposome encapsulation. 2) Cytochalasin B can significantly inhibit the growth of tumors in mice challenged with M109, Lewis lung, LA4, B16F10, or M5076, producing long-term survival against lung carcinomas and adenocarcinomas (M109, Lewis lung, and LA4) and B16F10 melanoma, but not M5076 sarcoma. These effects were comparable to intraperitoneally administered doxorubicin. 4) Low concentrations of cytochalasin B inhibit the secretion of GlcNACase, indicating that cytochalasin B may inhibit metastatic progression by mechanisms not directly associated with its influence on cell adhesion and motility.     

Continuous observations of bacterial gliding motility in a dialysis microchamber: The effects of inhibitors

Use of a dialysis microchamber has allowed continuous observations on the same set of gliding bacteria during changes in the composition of the perfused medium. This procedure has revealed the presence of an adaptive, cyanide-insensitive metabolic pathway, which allows cyanide-treated Flexibacter BH3 to begin gliding again at a reduced rate when glucose is the substrate. In addition, it has revealed that individual flexibacter cells can maintain their gliding motility for up to 20 h in the absence of exogenous substrate.Gliding in Flexibacter BH3 was prevented by those inhibitors blocking the electron transport process. Inhibitors of glucose metabolism did not prevent motility, since the flexibacters obviously metabolize endogenous substrate under such circumstances. Proton ionophores, which induce membrane depolarization, rapidly inhibited gliding in Flexibacter BH3. This inhibition was irreversible in the case of gramicidin S. Gliding was not inhibited by cytochalasin B or antiactin antibody. High concentrations of Ca²⁺ were particularly inhibitory to the gliding process. The significance of these results is discussed in relation to a possible mechanism of gliding involving the generation of rhythmical contractions in the outer cell membrane of Flexibacter BH3.Abbreviations used CCCP carbonyl cyanide m-chlorophenyl hydrazone - DNP p-dinitrophenol - GMCS gramicidin S - HQNO 2-heptyl-4-hydroxyquinoline N-oxide - PCMB p-chloromercuribenzoate - CM complete Lewin's medium - BS Lewin's basal salts     

Intracellular location of the Ah receptor

The subcellular distribution of the Ah receptor from the mouse hepatoma line, Hepa-1, was investigated following cytochalasin B treatment and cell enucleation. Probing the resultant cytoplast and nucleoplast fractions with radiolabelled tetrachlorodibenzo-p-dioxin (TCDD) revealed the presence of a specifically bound peak of receptor only in the cytoplast fraction. However, the quantity of receptor recovered in these experiments was only 10–12% of the expected value. We therefore undertook an investigation to determine the fate of the Ah receptor in the presence of cytochalasin B. Incubation of Hepa-1 cells with this compound resulted in a rapid loss or inactivation of cytosolic binding activity with a concomitant decrease in the amount of receptor partitioned into the nucleus at all time periods examined. Control experiments indicated that cytochalasin B did not compete with TCDD for binding to the Ah receptor and furthermore, that its mechanism of action could not be attributed to a non-specific effect on all cytosolic proteins. The results obtained are discussed in relation to the proposed models for induction by the estrogen and glucocorticoid binding receptors.     

Electrical Conductance of Cell-to-Cell Junctions and the Cytoskeleton of Plant Cells

In the submerged trichomes of floating-moss (Salvinia auriculataAubl.) and the roots of the higher water plant Trianea bogotensisKarst., the dependence of the electrical resistance of intercellular junctions on the presence of the agents that destroy microfilaments (cytochalasin B) and microtubules (colchicine) was investigated using the microelectrode technique. The resistance of the junctions (R _c) was estimated taking into account the input resistance and the coefficient of intercellular electrical communication. Should the cells be connected via symplast, R _cwill describe the resistance of plasmodesmata. Cytochalasin B (3–30 g/ml) reversibly changed R _cduring the first minutes after application. The extent of the change depended on the concentration of the inhibitor; its character of action depended on the initial strength of intercellular communication. When the initial conductance of the contact was high, cytochalasin B elevated the resistance; when it was low, the inhibitor decreased it. In all the experiments, cytochalasin B reduced the input resistance (R _i) that suggests the dependence of plasma membrane resistance on actin cytoskeleton. The effect of colchicine (0.1–1.0 mM) on R _iand R _cwas observed only when the cellular membrane was hyperpolarized or after a prolonged action of the inhibitor (for about 0.5 h). It was concluded that the electrical conductance of plasmodesmata and plasma membrane depended on the state of actin cytoskeleton. A complex and probably mediated interaction of microtubules with the processes affecting these characteristics of the cells was suggested.     

Roles of actin filaments in cytoplasmic streaming and organization of transvacuolar strands in root hair cells ofHydrocharis

Summary Effects of cytochalasin B and mycalolide-B on cytoplasmic streaming, organizations of actin filaments and the transvacuolar strand were studied in root hair cells ofHydrocharis, which shows reverse fountain streaming. Both toxins inhibited cytoplasmic streaming and destroyed the organizations of actin filaments and transvacuolar strands. However, we found a great difference between these toxins with respect to reversibility. The effects of cytochalasin B were reversible but not those of mycalolide B. The present results suggest that actin filaments work as a track of cytoplasmic streaming and as a cytoskeleton to maintain the transvacuolar strand. The usefulness of root hair cells ofHydrocharis in studying the dynamic organization of actin filaments of plant is discussed.Abbreviations CB cytochalasin B - DMSO dimethylsulfoxide - ML-B mycalolide B     

Amoeboid Locomotion of Naegleria gruberi: the Effects of Cytochalasin B on Cell-Substratum Interactions and Motile Behaviour

The major manifestations of amoeboid locomotion in Naegleria—cytoplasmic streaming, pseudopod production, cell polarity and focal contact production—require that the actin-based cytoskeleton be extremely dynamic. Whether these features are causally linked is unclear. In an attempt to answer this question we have used the fungal product cytochalasin B (cyt B) to dissect the motility process. This drug can perturb the organisation of actin filaments both in vivo and in vitro. Essentially cyt B acts as a molecule which can cap the barbed ends of actin filaments. Not surprisingly therefore cyt B has an effect on rates of actin polymerization and the dynamic state of actin in the cytoplasm. We have found that cyt B has a profound effect on focal contact production and breakdown. Within minutes of addition of cyt B focal contact production ceases, existing focal contacts are stabilised but cytoplasmic streaming and pseudopod production are not blocked. In conclusion it is now clear that the state of actin required for focal contact production is different from that required for pseudopod extension and cytoplasmic streaming.     

Immunochemical identification of mung bean actin like protein and its cellular involvement during germination

Actin like protein, extracted and purified fromVigna radiata (mung bean) seedling, has been found to give positive enzyme-linked immunosorbent assay with mouse monoclonal antiactin antibody. In vivo studies show that cytochalasin B at sublethal dose inhibits the chromosomal movement at metaphase stage during germination. Fromin vitro studies it is found that the actin like protein isolated from mung bean seedling has a cytochalasin B binding property with a Kd value 1.2 × 10⁻⁵ M. From these two specific observations it appears probable that the biological function of mung bean actin like protein is to take part in cell division process directly or indirectly during the time of seedling development.     

Motility comparisons of two shape-distinctiveEntamoeba variants

Summary The motility ofEntamoeba sp. (Laredo isolate, LA) is compared to a colchicine-resistant variant (LACR) derived from it and known to exhibit physiological and morphological differences. Both variants possess contractile elements which in glycerinated cell models were activated by Mg²⁺-ATP. Short-term experiments indicated that whereas both variants are insensitive to colchicine, treatment with cytochalasin B induces a change in cell shape and loss of adhesiveness in LA cells leaving LACR relatively unaffected. Quantitative analysis of time-lapse cinematographic recordings revealed that the mean relative surface area change of LA cells was 411% per minute with a mean pseudopod extension rate of 103 m per minute. In contrast, the respective values for LACR cells were 112% per minute und 32 m per minute. Cytochalasin B treatment reduced the relative surface area change of LA cells by approximately 18-fold with a corresponding reduction in LACR cells of only 1.6-fold. Similarly, cytochalasin B inhibited pseudopod extension by 34 and 1.8-fold in LA and LACR cells respectively. Thus, we have demonstrated a clear difference in both pattern and rate of locomotion of the two variants and have shown that the colchicine resistant variant has also become relatively insensitive to treatment with CB.     

Asymmetrical binding of phloretin to the glucose transport system of human erythrocytes

Summary The sidedness of phloretin binding to the glucose carrier has been determined by comparing the type of inhibition produced in zerotrans entry and zerotrans exit experiments. Initial rates of zerotrans entry were measured by the method of R.D. Taverna and R.G. Langdon (Biochim. Biophys. Acta 298:412–421, 1973), which involves pink ghosts loaded with glucose oxidase; this obviates the problem of rapid substrate accumulation inside the cells. With phloretin equilibrated across the membrane, the inhibition of entry was competitive, and the inhibition of exit noncompetitive. The experimental procedures were validated by showing that the inhibition by cytochalasin B, known to bind inside but not outside, was noncompetitive in entry and competitive in exit, as predicted. It was also demonstrated that even after pre-incubation of the cells with a relatively high concentration of phloretin, the phloretin adsorbed in the membrane did not significantly alter the rate of carrier reorientation. The results show that the outward-facing form of the glucose carrier, but not the inward-facing form, bears a phloretin binding site; thus phloretin, as well as cytochalasin B, is bound asymmetrically, phloretin outside and cytochalasin B inside.     

A variant form of beta-actin in a mutant of KB cells resistant to cytochalasin B

Lines of KB cells resistant to cytochalasin B have been isolated and characterized. The mutant Cyt 1 exhibits increased cross-resistance to cytochalasin E. Cyt 1 cells bind less cytochalasin B than parental KB cells. Two-dimensional gel analysis shows that Cyt 1 cells carry an alteration in beta-actin. This is further confirmed by one-dimensional peptide analysis. The altered beta-actin (beta'-actin) is synthesized when poly(A)+ RNA from Cyt 1 cells is translated in a reticulocyte-cell-free translation system. These results suggest that the primary site of action of cytochalasin B on cellular motility processes is beta-actin.     

Contractile Proteins in Chemical Signal Transduction in Plant Microspores

Involvement of contractile components in chemical signal transduction from the cell surface to the organelles was studied using unicellular systems. Neurotransmitters dopamine and serotonin as well as active oxygen species hydrogen peroxide and tert-butyl peroxide were used as chemical signals. Experiments were carried out on vegetative microspores of field horsetail Equisetum arvense and generative microspores (pollen) of knight’s star Hippeastrum hybridum treated with cytochalasin B (an inhibitor of actin polymerization in microfilaments), colchicine, and vinblastine (inhibitors of tubulin polymerization in microtubules). Both types of the treated microspores demonstrated suppressed development, particularly, after cytochalasin B treatment. At the same time, increased blue fluorescence was observed in certain cell regions (along the cell wall and around nuclei and chloroplasts) where the corresponding contractile proteins could be localized. In contrast to anticontractile agents, dopamine, serotonin B, and peroxides stimulated microspore germination. Microspore pretreatment with cytochalasin B and colchicine followed by the treatment with serotonin, dopamine, or peroxides decreased the germination rate. The involvement of actin and tubulin in chemical signal transduction from the cell surface to the nucleus is proposed.__________Translated from Izvestiya Akademii Nauk, Seriya Biologicheskaya, No. 3, 2005, pp. 281–286.Original Russian Text Copyright © 2005 by Roshchina.     

Actin-microtubule interactions in the algaNitella: analysis of the mechanism by which microtubule depolymerization potentiates cytochalasin's effects on streaming

Summary In the characean algaNitella, depolymerization of microtubules potentiates the inhibitory effects of cytochalasins on cytoplasmic streaming. Microtubule depolymerization lowers the cytochalasin B and D concentrations required to inhibit streaming, accelerates inhibition and delays streaming recovery. Because microtubule depolymerization does not significantly alter³H-cytochalasin B uptake and release, elevated intracellular cytochalasin concentrations are not the basis for potentiation. Instead, microtubule depolymerization causes actin to become more sensitive to cytochalasin. This increased sensitivity of actin is unlikely to be due to direct stabilization of actin by microtubules, however, because very few microtubules colocalize with the subcortical actin bundles that generate streaming. Furthermore, microtubule reassembly, but not recovery of former transverse alignment, is sufficient for restoring the normal cellular responses to cytochalasin D. We hypothesize that either tubulin or microtubule-associated proteins, released when microtubules depolymerize, interact with the actin cytoskeleton and sensitize it to cytochalasin.Abbreviations APW artificial pond water - Ca_c cytoplasraic free calcium concentration - DMSO dimethyl sulfoxide - MT microtubule-minus - MT+ microtubule-plus.     

Multiplication of Legionella pneumophila in HeLa Cells in the Presence of Cytoskeleton and Metabolic Inhibitors

A study has been carried out on the action of cytoskeleton and metabolic inhibitors on intracellular multiplication in HeLa cells of a virulent strain of Legionella pneumophila serogroup 6. The effects of the substances were separately tested on both penetration and intracellular multiplication of L. pneumophila. Only cytochalasin A and 2-deoxy-d -glucose (2dG) affected bacterial internalisation, whereas intracellular multiplication was inhibited by cytochalasins A, B, C, D and J (D being the most active) and by 2dG with a dose-response effect. The action of 2dG was counteracted by 50 mM glucose. Experiments carried out with cytochalasin D and a rhodamine-phalloidin conjugate showed the involvement of cytoskeletal elements in intracellular multiplication of Legionella; compounds acting on microtubules had no effect.