Ultraviolet light inhibits grey crescent formation on the frog egg

Summary Work by others has shown that ultraviolet (UV) irradiation of the vegetal half of the uncleaved frog egg causes defects in neural development. We find that the earliest effect of irradiation ofRana pipiens eggs is to prevent grey crescent formation, the first indication of dorso-ventral polarization of the egg. The UV effect on the grey crescent and on neural development shows similarities in timing, dose-responses, and reversal by cold. We suggest that the UV effect on neural morphogenesis may be caused by the inhibition of cortical-cytoplasmic movement involved in grey crescent formation.     

Involvement of the cytoskeleton in early grey crescent formation in axolotl oocytes

Summary Maturing axolotl oocytes which are treated with protein synthesis inhibitors or which are heat-shocked can be induced to reorganize their cytoplasm and to form an early grey crescent. The maturing axolotl oocyte has been used as a model system to study the role of the cytoskeleton in dorsoventral polarization as visualized by grey crescent formation. Results presented here provide evidence for the involvement of microtubules in the formation of the early grey crescent. Whereas inhibitors of microtubule polymerization and antibodies against tubulin both elicit early grey crescent formation, the effect of taxol shows that microtubule polymerization is required at a late stage in this event. The nucleus furnishes important factors required for early grey crescent formation and might play a role in microtubule polymerization.     

Inhibition of protein synthesis elicits early grey crescent formation in the axolotl oocyte

Summary In the axolotl (Ambystoma mexicanum Shaw), it was recently shown that cycloheximide (CH) could induce early grey crescent formation (EGC) in non-activated oocytes, maturing in vitro (Grinfeld and Beetschen 1982). Since it was not proved that EGC was a consequence of protein synthesis inhibition rather than a side-effect of the drug, experiments were performed using microinjections of a quite different inhibitor, diphtheria toxin (DT). This toxin also appeared to elicit EGC. Incorporation of (³H) leucine into oocyte proteins in the presence of increasing DT concentrations (10^–11 to 10^–6 M) was then investigated. The frequency of EGC closely parallels the level of protein synthesis inhibition, which is higher in symmetrized oocytes. The lowest CH concentration which can still elicit EGC also exerts a fairly strong inhibition of (³H) leucine incorporation into proteins. It is concluded that protein synthesis inhibition in the late maturing oocyte actually creates specific conditions which allow cytoplasmic rearrangements to occur, leading to grey crescent formation. These results support the interpretation that (a) proteinic inhibitor (s) of symmetrization could be synthesized in the normal maturing oocyte.     

Early grey crescent formation experimentally induced by cycloheximide in the axolotl oocyte

Summary The effects of cycloheximide (CH) on grey crescent formation in artificially maturedAmbystoma mexicanum oocytes were determined. CH induced grey crescent formation after a few hours, especially after a 45° to 90° rotation from the vertical animal-vegetal axis. With low concentrations of CH (about 0.5 ng/oocyte), meiosis was still able to proceed normally to the stable second metaphase stage, but higher concentrations blocked it after 1st polar body extrusion and an interphasic nucleus appeared. Such effects were compared to those of inactone, an analogue of cycloheximide, which as a pure substance does not inhibit protein synthesis, but still contained a small amount of CH in the available samples. It is concluded that grey crescent formation can occur in non-activated oocytes. The effects of cycloheximide might be due to partial inhibition of protein synthesis and the presence of a proteinic inhibitor of the symmetry reaction in the normal oocyte is suggested.     

Inducing effects of the grey crescent region of early developmental stages of ambystoma mexicanum

Summary Parts of the grey crescent region of 1–2 cell, 8 cell and morula stages ofAmbystoma mexicanum were combined with presumptive gastrula ectoderm of the same species (sandwich method).Grey crescent material of the early cleavage stages induced neural tissues at a very low rate (6%–7%).From the morula stage onwards, the inducing ability of the grey crescent area increased and led to the formation of mesodermal as well as neural organs. The implanted area did not participate in the organ formations.

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Zusammenfassung Von Axolotl-Keimen wurden im 1–2 Zell-Stadium, im 8 Zell-Stadium und im Morula-Stadium Implantate aus der Region des grauen Halbmondes entnommen und mit präsumptivem Ektoderm aus frühen Gastrulen der gleichen Spezies kombiniert (Sandwich-Methode).Material aus dem grauen Halbmond früher Furchungsstadien induzierte nur wenig neurales Gewebe (6%–7% der Fälle).Vom Morula-Stadium an war die Induktionsrate höher. Neben neuralen wurden auch mesodermale Organe induziert. — Das implantierte Gewebe war nicht an den Organbildungen beteiligt.

     

Effects of cytochalasin B and colchicine on dental cytodifferentiation in vitro]

The effects of various concentrations of cytochalasin B and colchicine on the polarization of odontoblasts and ameloblasts of mouse tooth buds cultivated in vitro, were studies. It was shown that cytochalasin B, deside its action on the microfilaments, had important cytotoxic effects; dilatation of the odontoblast's processus, accumulation of secretory granules in the Golgi apparatus, dilatation of mitochondria, inhibition of polarization or depolarization of odontoblasts and ameloblasts. These modifications resulted chiefly from the lesion of microtubules which seem to play an important role in the polarization of the cells studies.     

Effects of cytochalasin B, colchicine and vincristine on the metabolism of isolated fat-cells

1. Colchicine and vincristine only slightly inhibit the metabolism of glucose to CO(2) and lipids by isolated fat-cells. 2. Prolonged incubation with these agents causes no further inhibition. 3. Cytochalasin B, however, inhibits glucose metabolism to both CO(2) and lipids in fat-cells. 4. However, at a concentration that causes a strong inhibition of glucose metabolism cytochalasin B is without effect on the metabolism of pyruvate, lactate or arginine to these end products. The uptake of labelled alpha-aminoisobutyrate is likewise not modified. Similarly it does not affect release of glycerol or free fatty acid, or the actions of adrenaline, insulin or caffeine on these parameters. At 10mug/ml it slightly lowers ATP concentrations, an effect that does not occur at 2mug/ml. 5. The transport of fructose into adipocytes by a specific fructose-transport system is also not affected by the agent, but the uptake of 2-deoxyglucose is strongly inhibited. It is concluded that cytochalasin B may specifically inhibit the glucose-transport system of isolated fat-cells. 6. Cytochalasin A has a much weaker action than cytochalasin B on glucose metabolism.     

Effects of colchicine and cytochalasin B on hypertonicity-induced changes in toad urinary bladder

Summary Coincident with an increase in the water permeability of toad urinary bladder induced by serosal hypertonicity, a transformation of the ridge-like surface structures of the granular cells into individual microvillous structures occurs. This study was initiated to establish whether the transformation is mediated by the cytoskeletal network and, thus, can be prevented by disruption of microtubulemicrofilament function with colchicine or cytochalasin B (CB). Scanning electron microscopy revealed the characteristic branching ridges on granular cells of control bladder incubated with colchicine or CB. In contrast, transformation of ridges to discrete microvilli was observed in experimental bladders exposed to serosal hypertonicity alone or in combination with either colchicine or CB. These results suggest that the mechanism underlying hypertonicity-induced surface changes which are associated with increased water permeability does not involve either microtubules or microfilaments.     

Effects of cytochalasin B and colchicine on attachment of a major surface protein of fibroblasts

We have investigated the effects of the drugs cytochalasin B and colchicine on the surface levels of the large, external, transformation-sensitive (LETS) glycoprotein. Colchicine neither removed LETS protein from the surface, nor inhibited its regeneration after removal by mild trypsinization. Cells treated with cytochalasin B, however, showed both a 2–3-fold increase in the turnover rate of their surface LETS protein and a marked inhibition in its regeneration. Inhibition of regeneration was not due to inhibition of synthesis or transport to the surface. In fact, in the presence of cytochalasin B, increased quantities of LETS protein were released into the medium. The results are consistent with the idea of an association of LETS protein with the actin-containing microfilaments. However, other possible explanations, such as effects on cellular morphology or on transport of sugar precursors cannot yet be excluded.     

Effects of colchicine on the ultrastructure of mouse taste buds

Summary Effect of colchicine on the ultrastructure of taste bud cells was studied in the mouse. In untreated mice microtubules were abundant throughout the entire cytoplasm of type-III cells, but only in the apical cytoplasm of type-I cells. After 2 h of colchicine treatment, no microtubules were observed in any taste bud cells; dense secretory granules in the apical cytoplasm of type-I cells mostly disappeared, and instead, numerous phagosomes appeared. It is suggested that colchicine causes an interruption of the transport of the secretory granules in type-I cells from the Golgi apparatus to the membrane of the apical surface, from which release occurs. In type-III cells, after 4 or 5 h of treatment, dense-cored vesicles scattered throughout the cytoplasm tended to increase in number; they were often observed to accumulate in the vicinity of the Golgi apparatus. Five hours after treatment with 5-hydroxy-l-tryptophan (5-HTP) following colchicine pretreatment, monoamine specific fluorescent cells and vesicles with highly electron-dense cores of type-III cells were still present. On the other hand, 5 h after 5-HTP treatment alone both fluorescent cells and vesicles with highly electron-dense cores had already disappeared. These observations suggest that the treatment with colchicine interrupts the transport of densecored vesicles of type-III cells to synaptic areas, in which those vesicles are presumed to discharge the neurotransmitter substance.     

Organelle distribution in chick neuroepithelial cells: effects of colchicine and cytochalasin B

The intracellular distribution of mitochondria, cytoplasmic inclusions and rough endoplasmic reticulum cisternae of chick neuroepithelial cells was investigated at neurulation stages 6, 8, 10 and 12. These neuroepithelial cells were subdivided into three zones: apical, median and basal and the distribution percentages of distribution of these organelles were obtained. Mitochondrial distribution was related to the energy supply that mitochondria provide for apical microfilament contraction. Cytoplasmic inclusions were distributed preferentially in the apical zone of the neuroepithelial cells during the four stages. Rough endoplasmic reticulum cisternae were homogeneously distributed in the three zones at stages 10 and 12, but at stages 6 and 8 there are more elevated percentages of rough endoplasmic reticulum in the apical zones than in the other zones. Experimental treatments with colchicine and cytochalasin B does not modify the patterns of mitochondria and rough endoplasmic reticulum cisternae but alters the distribution of cytoplasmic inclusions. Finally, there is a correlation in the normal neurulating neuroepithelial cells between the distributions of mitochondria and rough endoplasmic reticulum distribution and between the distributions of mitochondria and cytoplasmic inclusions distribution. This relationship is retained in the treated neuroepithelial cells.     

Effects of colchicine on ultrastructure of the lactating mammary cell: Membrane involvement and stress on the Golgi apparatus

Summary The effects of colchicine on ultrastructure of the lactating mammary cell in the rat and goat were studied by electron microscopy. Changes in tissue of the rat were examined over time (1, 2 and 4 h). The goat gland was evaluated by comparing ultrastructure of tissue at the time of maximum milk flow suppression induced by the drug with that of untreated tissue. Colchicine produced notable changes in the tissue of both species: 1) the secretion of lipid droplets and Golgi vesicle contents (exocytosis) was inhibited and the droplets and vesicles became randomly distributed throughout the cell, 2) the Golgi apparatus was significantly reduced in size, 3) casein and lipid continued to be synthesized as evidenced by greater numbers of secretory vesicles and increased sizes of casein micelles and lipid droplets, 4) secretory vesicles showed a propensity to cluster around lipid droplets, 5) isolated microtubules were found occasionally in the control tissue, ordinarily in the vicinity of the Golgi apparatus, but rarely in the colchicine-treated tissue. These observations indicate that colchicine has two effects leading to suppression of exocytosis in the mammary cell: one involves early interference with capacity of secretory vesicle membranes to fuse and a further effect, related to higher concentrations of colchicine, causes intracellular disorganization and loss of polarity. Microtubules were not seen as directly involved in the mechanisms of exocytosis. The secretion of milk fat globules is coupled to exocytosis and thereby is also inhibited by colchicine.Supported in part by grant HL 03622 of the U.S. Public Health Service     

Effects of colchicine on axonal transport and ultrastructure of the hypothalamo-neurohypophyseal system of the rat

Summary The effect of colchicine on the transport of proteins in the hypothalamo-neurohypophyseal tract of the rat was studied after injection of (³⁵S) cysteine into the supraoptic nucleus (SON) region. Colchicine, dissolved in distilled water and administered subarachnoidally, inhibited the axonal transport of labelled proteins into the neurohypophysis: the radioactivity that was recovered in neurohypophyseal TCA precipitable material was markedly decreased and hardly any radioactivity was found in the neurohypophyseal proteins which were separated by polyacrylamide gel disc electrophoresis.As revealed by electron microscopy the SON cell bodies showed marked changes after treatment with colchicine: a deeply folded nucleolemma; a pronounced, granular nucleolus; a dispersed chromatin; a zonal distribution of cell organelles with mitochondria and lysosomes accumulated at the periphery, crowded ribosomes, often arranged as polyribosomes and richly branching short profiles of endoplasmic reticulum filled with filamentous material forming an inner perinuclear zone separated by enlarged Golgi complexes.The profiles of elongated Herring bodies in the infundibulum were increased. The axon terminals were filled with heavily osmiophilic neurosecretory granules. The neurofilaments were slightly or moderately increased in number. No apparent changes were observed with regard to the neurotubuli in the SON neurons. The glial cells of the supraopticoneurohypophyseal tract showed reactive changes with a proliferation of filamentous elements. The biochemical and ultrastructural findings are discussed especially with respect to the mechanisms of transport and release of neurosecretory granules.     

The effect of cytochalasin B,colchicine and vinblastine on the adhesion of Trichomonas vaginalis to glass surfaces

The attachment of Trichomonas vaginalis to glass surfaces was studied in the presence of cytochalasin B, colchicine and vinblastine. Marked inhibition of adhesion was noted with high concentrations of cytochalasin B. Colchicine and vinblastine were without effect. These findings suggest that Trichomonas vaginalis adhesion is at least partially mediated by the extension of cellular probes, due to the action of cytochalasin-sensitive microfilaments.     

Remnant motility of macrophages treated with cytochalasin B in the presence of colchicine

We have previously observed that mouse peritoneal macrophages cultured for 48 h and treated with colchicine to depolymerize cytoplasmic microtubules become ameboid and cease to migrate by gliding on the substratum. We have now found that when such cells were further exposed to both colchicine and cytochalasin B, the induced ameboid movements were reversibly inhibited. Cells treated concomitantly with both drugs did not become motionless, but exhibited a remnant motility that took the form of zeiosis (blebbing). The zeiotic blebs contained ribosomes and fibrous material, but lacked organized microfilament arrays and rarely included other cytoplasmic organelles. Zeiosis appears to be a form of surface movement independent both of cytoplasmic microtubules and of the cytochalasin-sensitive contractile system. These observations imply an additional mechanism that can reversibly alter the form of the cell.     

Binding of cytochalasin B to platelets

The binding of cytochalasin B (CB) to human platelets and to isolated platelet cytosol and membranes has been analyzed with [3H]CB. High- and low affinity classes of saturable binding sites were associated with intact platelets. Binding at very low concentrations of CB (i.e., high-affinity binding) was partially prevented by 100 mM D-galactose or D-glucose and to a much lesser extent by L-glucose. Binding to platelet cytosol also involved two classes of sites with affinities and capacities similar to those observed with the whole cells. None of this binding, however, was affected by 100 mM D-galactose. Saturable binding to platelet membranes occurred at sites with a uniform binding affinity. Approximately 52% of this binding was prevented by 1 M D-galactose and another 15% by cytochalasin E (CE). We hypothesize that binding in the cytosol is to monomeric (low-affinity) and polymerized (high-affinity) actin, whereas membrane binding (high-affinity only) occurs primarily at sites involved with galactose transport.     

Cloning and characterization of the first amphibian bradykinin gene

More than ten bradykinin-related peptides and their cDNAs have been identified from amphibians, but their genes are unknown. In present study, four cDNAs encoding one, two, four and six copies of bradykinin-related peptides were cloned from the frog (Odorrana grahami) skin cDNA library, respectively. Three bradykinin-related peptides (bradykinin, Thr6-bradykinin, Leu5Thr6-bradykinin) were deduced from these four cDNA sequences. Based on the cDNA sequence, the gene sequence encoding an amphibian bradykinin-related peptide from O. grahami was determined. It is composed of 7481 base pairs including two exons and two introns. The first exon codes signal peptide and the second exon codes acidic spacer peptide and Thr6-bradykinin. The promoter region of the bradykinin gene contains several putative recognition sites for nuclear factors, such as SRY, GATA-1, LYF-1, DeltaE, CDXA, NKX-2.5, MIF1 and S8. The current work may facilitate to understand the regulation and possible functions of amphibian skin bradykinin-related peptides.