Is the microtubule disruption-induced alteration of peroxide concentration a factor inhibiting the assembly of ribonucleoprotein stress granules?

It has been examined whether the destruction of cell microtubules affects the increase in the intracellular hydrogen peroxide concentration caused by sodium arsenite, which induces the formation of stress ribonucleoprotein granules. As expected, sodium arsenite caused a 50% increase in hydrogen peroxide concentration in HeLa cells; on the other hand, another stress granule inducer tert-butylhydroquinone did not affect the peroxide concentration. The disruption of microtubules by nocodazole or vinblastine also resulted in some increase in the intracellular peroxide concentration, and the microtubule stabilization by taxol did not affect it. The combined treatment of cells with arsenite and antimicrotubule drugs caused an additive effect, and the peroxide concentration increased twice or more. Thus, the inhibition of stress granule formation after microtubule disruption cannot be explained by a decrease in peroxide concentration as compared with the affect of arsenite.     

Effects of four agents that modify microtubules and microfilaments (vinblastine,colchicine, lidocaine,and cytochalasin B) on macrophage-mediated cytotoxicity to tumor cells

Summary The effects of vinblastine, colchicine, lidocaine, and cytochalasin B on tumor cell killing by BCG-activated macrophages were examined. These four drugs were selected for their action on membrane-associated cytoskeletal components, microtubules, and microfilaments. Colchicine and vinblastine, which block microtubular synthesis, inhibit macrophage-mediated tumor-cell cytotoxicity at a concentration of 10^–6 M. Cytochalasin B, which disrupts microfilaments, enhances tumor cell lysis and stasis due to activated macrophages at a concentration of 10^–7 M. Lidocaine, which may induce the disappearance of both microtubules and microfilaments, has the same inhibiting effect as vinblastine at a concentration of 5×10^–7 M. Whereas vinblastine and lidocaine seem to act on the macrophage itself, cytochalasin B exerts its effect predominantly on the tumor cell. These results suggest that microtubules and microfilaments play a role in the destruction of tumor cells by activated macrophages.     

THE MECHANISM OF ACTION OF COLCHICINE : Colchicine Binding Properties of Sea Urchin Sperm Tail Outer Doublet Tubulin

The thermal depolymerization procedure of Stephens (1970. J. Mol. Biol. 47:353) has been employed for solubilization of Strongylocentrotus purpuratus sperm tail outer doublet microtubules with the use of a buffer during solubilization which is of optimal pH and ionic strength for the preservation of colchicine binding activity of chick embryo brain tubulin. Colchicine binding values were corrected for first-order decay during heat solubilization at 50°C (t_½ = 5.4 min) and incubation with colchicine at 37°C in the presence of vinblastine sulfate (t_½ = 485 min). The colchicine binding properties of heat-solubilized outer doublet tubulin were qualitatively identical with those of other soluble forms of tubulin. The solubilized tubulin (mol wt, 115,000) bound 0.9 ± 0.2 mol of colchicine per mol of tubulin, with a binding constant of 6.3 x 10⁵ liters/mol at 37°C. The colchicine binding reaction was both time and temperature dependent, and the binding of colchicine was prevented in a competitive manner by podophyllotoxin (K_i = 1.3 x 10^-6 M). The first-order decay of colchicine binding activity was substantially decreased by the addition of the vinca alkaloids, vinblastine sulfate or vincristine sulfate, thus demonstrating the presence of a vinca alkaloid binding site(s) on the outer doublet tubulin. Tubulin contained within the assembled microtubules did not decay. Intact outer doublet microtubules bound less than 0.001 mol of colchicine per mol of tubulin contained in the microtubules, under conditions where soluble tubulin would have bound 1 mol of colchicine per mol of tubulin (saturating concentration of colchicine, no decay of colchicine binding activity). The presence of colchicine had no effect on the rate of solubilization of outer doublet microtubules during incubation at 37°C. Therefore, the colchicine binding site on tubulin is blocked (not available to bind colchicine) when the tubulin is in the assembled outer doublet microtubules.     

The effects of microtubule and microfilament disrupting agents on cytoskeletal arrays and wall deposition in developing cotton fibers

Summary The effects of various cytoskeletal disrupting agents (cholchicine, oryzalin, trifluralin, taxol, cytochalasins B and D) on microtubules, microfilaments and wall microfibril deposition were monitored in developing cotton fibers, using immunocytochemical and fluorescence techniques. Treatment with 10^–4 M colchicine, 10^–6 M trifluralin or 10^–6 M oryzalin resulted in a reduction in the number of microtubules, however, the drug-stable microtubules still appear to influence wall deposition. Treatment with 10^–5 M taxol increased the numbers of microtubules present within 15 minutes of application. New microtubules were aligned parallel to the existing ones, however, some evidence of random arrays was observed. Microtubules stabilized with taxol appeared to function in wall organization but do not undergo normal re-orientations during development. Microtubule disrupting agent had no detectable affect on the microfilament population. Exposure to either 4×10^–5 M cytochalasin B or 2×10^–6M cytochalasin D resulted in a disruption of microfilaments and a re-organization of microtubule arrays. Treatment with either cytochalasin caused a premature shift in the orientation of microtubules in young fibers, whereas in older fibers the microtubule arrays became randomly organized. These observations indicate that microtubule populations during interphase are heterogeneous, differing at least in their susceptibility to disruption by depolymerizing agents. Changes in microtubule orientation (induced by cytochalasin) indicate that microfilaments may be involved in regulating microtubule orientation during development.     

Anti-tubulin immunofluorescence studies of recovery from vinblastine cytotoxicity in Chinese hamster cells

Antitubulin immunofluorescent staining was used to examine the relationship among crystal formation, mitotic arrest, and recovery potential in vinblastine-treated Chinese hamster cells. Although vinblastine caused a mitotic block at concentrations as low as 5 x 10(-9) M, it induced tubulin crystal formation only at concentrations higher than 10(-6) M. At these higher concentrations, cells took 48-72 h to recover after return to normal medium. This extended period of time was apparently needed for breakdown of the crystals and regeneration of normal cytoplasmic microtubules. At concentrations less than 10(-6) M, although the mitotic block was still effective, no crystals were present. Possibly because of this lack of crystal formation, the cells recovered rapidly, generating cytoplasmic microtubules within 30 min, and beginning to undergo mitosis within 60 min. These findings tend to support biochemical evidence that tubulin binds to vinblastine at two types of binding site: a high affinity, low capacity site, responsible for tubulin disaggregation; and a low affinity site, responsible for protofilament splaying.     

Inhibition of functional activity of the adenylyl cyclase signaling system of the ciliate Dileptus anser by colchicine and vinblastine

Cytoskeleton plays a key role in the functioning of hormonal signaling systems in vertebrate animals. However, data on the effect of cytoskeletal components, in particular microtubules, on the functional activity of chemosignaling systems of unicellular organisms are currently lacking. The goal of this work consisted of studying the effects of microtubule-disrupting agents, colchicine and vinblastine, on the adenylyl cyclase system of free living infusoria Dileptus anser. The incubation of D. anser with colchicine and vinblastine (10^?5–10^?6 M) weakly affected the basal activity of adenylyl cyclase (AC), but led to a significant decrease in or complete block of AC stimulation with nonhormonal (GppNHp, sodium fluoride) and hormonal agents (adrenaline, serotonin, glucagon). The basal level of GTP binding in heterotrimeric G proteins decreased and there was observed inhibition of stimulation of G proteins by hormones. Colchicine and vinblastine have been shown to interrupt adrenalin-produced AC stimulation achieved through G_s-protein, but weakly affect its inhibiting AC effect caused by the G_i-protein. Thus, it has been established for the first time that, in unicellular organisms, i.e., infusoria D. anser, microtubules are involved in the regulation of the functional activity of the AC system and their action is realized at the level of G proteins, which is similar to Gs-proteins in vertebrate animals.     

Effects of Propyzamide on Tobacco Cell Microtubules In Vivo and In Vitro

Treatment with propyzamide at 2 ? 10^-6 M or at higher concentrationsarrested the cell cycleat metaphase in tobacco BY-2 cells. Metaphasecells having disorganized spindle microtubulesand scatteredchromosomes began to appear within several minutes of the additionof propyzamide. Within 30 min, disrupted spindle microtubulesand dispersed chromosomes were seenin all metaphase cells. Propyzamideat 2 ? 10^-6 M or at higher concentrations also disrupted corticalmicrotubules, but disruption of cortical microtubules requiredmore time than disruption of spindle microtubules. The effectof propyzamide on microtubules was found to be readily reversible.The cells arrested at metaphase by 2 ? 10^-6 M propyzamide resumedmitosis within 2 h from the termination of treatment with propyzamide.Spindle microtubules reappeared within 15 min from the terminationof treatment with propyzamide, and the cortical microtubuleswithin 1 h. Tubulin was isolated from tobacco BY-2 cells bycolumn chromatography on ethyl Nphenylcarbamate-Sepharose 4B.On incubation with EGTA, Mg²⁺ and DMSO, the purified tobaccotubulin polymerized into microtubules. Propyzamide at 1 ? 10^-4M completely inhibitedthe polymerization of tobacco tubulin,but did not inhibit polymerization of bovine braintubulin. Tobaccotubulin was adsorbed onto a column of propyzamide-analogue-linkedSepharose 4B and then purified by chromatography on this column. (Received February 15, 1988; Accepted June 29, 1988)     

Micronuclear division and microtubular stability in the ciliate Colpoda steinii

The first microtubules which appear in the prophase micronucleus of Colpoda steinii are located beneath the nuclear envelope and not connected to the chromosomes. Most microtubules of the metaphase spindle are connected to the tapered tips of the micronucleus and terminate singly at the chromosomes surrounded by a conical, RNA-containing kinetochore which disappears upon cold treatment. During anaphase, an interzonal stembody is formed which is maximally stretched at telophase before the daughter micronuclei are pinched off from its ends. The macronucleus, which also stretches parallel to the micronuclear stembody, has fewer microtubules which insert at the inner nuclear envelope but are not attached to the chromatin. Based upon the effects of depolymerizing factors different classes of microtubules can be distinguished. Kinetochore microtubules are sensitive to cold and vinblastine (VLB). In 2.5×10^–5 M VLB their number is drastically reduced and the interzonal microtubules of early anaphase, which are also highly sensitive to nocodazole, become completely disassembled. The cross-bridged microtubules of the fully formed stembody of late anaphase display the highest resistance to depolymerization. They show signs of partial disassembly only after prolonged cold exposure and withstand higher concentrations of VLB or nocodazole than other micronuclear microtubules. Microtubules in the elongating macronucleus are fairly insensitive to cold but are depolymerized by 5×10^–5 M VLB while 1.66×10^–5 M nocodazole, which leaves only traces of stembody microtubules, merely reduces their number and length. All microtubules are fairly resistant to colchicine since high concentrations (5×10^–2 M) are required to prevent assembly while fully formed stembodies are unaffected. Macronuclear microtubules are depolymerized at this concentration. Nocodazole, which depolymerizes all premetaphase microtubules at 6.6×10^–6 M, leads to multipolar metaphase spindles with numerous microtubules, even at 1.66×10^–5 M, an effect ascribed to the activity of the nuclear envelope as a microtubule organizing centre. At twice this concentration multipolar spindles are no longer found and the remaining microtubules show no apparent order. A stabilizing influence of the micronuclear envelope is indicated by the fact that whenever remnants of microtubules are found after depolymerizing treatments, they are located in its vicinity.     

Evidence for three “classes” of microtubules in the interpolar space of the mitotic micronucleus of a ciliate and the participation of the nuclear envelope in conferring stability to microtubules

Exposure of Nyctotherus ovalis to low temperatures or vinblastine caused similar reactions of classes of microtubules (mt) present in the mitotic micronucleus of this ciliate towards both treatments. However, differences of sensitivity between certain classes of mt at individual mitotic stages exist. Unlike the kinetochore mt (kmt) of most other eukaryotic cells, kmt in Nyctotherus completely disassemble after incubation at 6–8 ° C (60 min) and most disappear after prolonged exposure to vinblastine (10^–5 M, 16 h). The depolymerization of kmt causes the collapse of the spindle and a dislocation of chromosomes at metaphase, yet the reduced number of kmt after vinblastine-treatment still allows an alignment of composite complexes at the spindle equator. The data suggest that three individual sets of mt exist in the interpolar spindle region during ana- and telophase: 1) interpolar mt (int mt), which are assembled during anaphase, are cold- and vinblastine sensitive; 2) manchette mt (ma mt), which are first observed underneath the nuclear envelope during mid-anaphase, are cold-stable and insensitive to vinblastine treatment (10^–5 M); after prolonged treatment (16 h) they form spiral structures; 3) stembody mt (st mt), comprising the interpolar region of the nucleus during telophase, are cold- and vinblastine insensitive. Paracrystalline structures resembling a stembody are formed in telophase-like division stages after prolonged vinblastine exposure (16 h, 10^–5 M). Since kmt and int mt possess the same sensitivity under depolymerizing conditions, they probably have a similar composition. Thus the idea that the int mt in this organism arise by elongation of kmt is supported. However, st mt apparently do not originate from an extension of preexistent int mt, but appear to represent a new set of stable mt. This is emphasized not only by their greater stability compared to the int mt but also by the distribution of cold-stable mt in late anaphase micronuclei. The ma mt may be an intermediary step in formation of st mt since their stability resembles that of the st mt. A comparison of the substructure of vinblastine-induced paracrystals in Nyctotherus with those observed in in vitro systems with known composition suggests that a turnover of MAPs may be responsible for the different stability of mt and thus could specify and regulate mt sensitivity and function. Another organelle, possibly involved in conferring stability to mt, is the nuclear membrane. The assumption that the nuclear envelope possesses an intrinsic property to nucleate mt and thus aid in the alignment of mt is supported.     

Abrogation by prostaglandin F2alpha of LH-stimulated cyclic AMP accumulation in isolated rat corpora lutea of pregnancy.

Corpora lutea explanted from rats on the sixth day of pregnancy responded to luteinizing hormone (LH; 5 μg/ml) in vitro with a two- to five-fold increase in cellular cyclic AMP (cAMP) concentration. The maximal cAMP level was reached within 60 min and maintained to the end of the 2 hr-incubation. On incubation with prostaglandin F_2α (PGF_2α) in addition to LH, this rise in cAMP accumulation was prevented. For significant suppression, 1.4 × 10^?5M PGF_2α was required. In the absence of LH, PGF_2α (4.2 × 10^?5M) caused no change in cellular cAMP. Addition of PGF_2α (4.2 × 10^?5M) to the incubation medium after the maximal response to LH was attained, caused the cAMP concentration to return to its basal level within 15 min. This abrogation of LH-stimulated cAMP accumulation represents the earliest and hence possibly the triggering event in PGF_2α-induced luteolysis.     

The insensitivity of Vinca rosea to vinblastine

Root tip mitosis in both Vinca rosea and the chosen control Lepidium sativum is susceptible to the effects of colchicine at and above 5×10^–4 M. — Root tip mitosis in L. sativum is susceptible to the effects of vinblastine at concentrations equal to and greater than 10^–4 M, while root tip mitosis in V. rosea, the plant which is the source of vinblastine, is unaffected by exogenously-applied VBL at concentrations up to and including 10^–2 M. — The possible mechanisms by which this resistance of V. rosea to vinblastine might be conferred are discussed.     

INFLUENCES OF COLCHICINE, VINBLASTINE AND CYTOCHALASIN ON THE RELEASE OF 5-HYDROXYTRYPTAMINE FROM RAT BRAIN SYNAPTOSOMES

Rat brain synaptosomes preincubated with [³H]5-HT. were further incubated and the release of [³H]5-HT from the preparation was studied. The spontaneous release consisted of an initial rapid phase followed by slower release. Incubation with 60 mM-KCl increased the release while 60 mw-NaCl did not affect it. The effect of KG was abolished when NaCl was omitted from the medium. The potassium-induced release was Ca²⁺ -dependent while that induced by tyramine (10^?5-10^?4M) and the spontaneous release did not depend on Ca²⁺. Vinblastine (10^?5–2.5 X 10^?4 M) caused an increase in the spontaneous release and an decrease in the potassium-induced release, while it completely inhibited the release by tyramine at 2.5 X 10^?4 M. Colchicine (5 X 10^?5–10^?3M) and cytochalasin D (10^?5, 10^?4 M) failed to produce any change in the release. Cytochalasin B (10^?5, 10^?4M) increased the spontaneous release and decreased the potassium-induced release but it did not affect the release by tyramine. Colchicine (10^?3 M). vinblastine (10^?4 M) and cytochalasin B (10^?4 M) did not affect significantly Na⁺.K⁺-. Mg²- and Ca²⁺ -ATPase activities. These results suggest that none of microtubules. microfilaments and contractile protein participates in the mechanism of [³H]5-HT release from synaptosomes, in vitro.     

Modification of the enamel maturation pattern by vinblastine as revealed by glyoxal bis(2-hydroxyanil) staining and 45calcium radioautography

Summary Patterns characteristic of enamel maturation can be visualized at the surface of the rat incisor by staining with glyoxal bis(2-hydroxyanil) (GBHA) and radioautography following ⁴⁵calcium injection. In this study, the effects of vinblastine on enamel maturation were monitored by these two methods. At 4 h after injection of vinblastine, the darkly-stained GBHA bands had widened incisally into the interband regions when compared to normal, control teeth. Radioautography at 5 min after calcium injection in vinblastine-treated animals (4 h) showed a modified maturation pattern of weaker labeling and less distinct banding. At 8 h after vinblastine injection, most of the enamel stained uniformly with GBHA, and bands and interband regions could not be resolved. Radioautography at 5 min after calcium injection showed that the 8 h vinblastine treatment removed the banding pattern, leaving only a weakly-labeled area. Vinblastine is known to destroy and prevent the formation and turnover of microtubules, and hence the formation of ruffled borders of ruffle-ended ameloblasts (Akita et al. 1983). The concomitant decrease in calcium incorporation implies that events taking place in relation to the ruffled border may affect calcium exchange or accretion within the enamel.     

High cytotoxicity and membrane permeability of Et3Pb+ in mammalian and plant cells

Cells of mammalian origin as well as those of higher plants appear to be very sensitive to triethyllead ion (Et₃Pb⁺). Neuroblastoma cells kept in the presence of 1 μM Et₃Pb⁺ lost their viability within 6 h. Growth of suspension culture cells of soybean (G. max(L.)Merr.) was inhibited by 1 μM Et₃Pb⁺, and finally the cells died. Morphologically, Et₃Pb⁺ caused the complete breakdown of microtubular structures in neuroblastoma cells; thus microtubules appeared to be the main target for the toxin. While in a previous study the effect of Et₃Pb⁺ on microtubules has been well documented at concentrations of 50–200 μM ¹, the present study demonstrates that the formation of microtubules from pig brain tubulin is disturbed at concentrations of Et₃Pb⁺ as low as 0.5 to 1 μM . We conclude from these data that Et₃Pb⁺ freely permeates the plasma membranes of mammalian as well as plant cells.     

Effect of microtubule-disrupting drugs on protein and RNA synthesis in Physarum polycephalum amoebae

The effects of the microtubule-disrupting drugs, colchicine, vinblastine, podophyllotoxin, griseofulvin, and lumicolchicine (10^-5 M), on protein and RNA synthesis were studied in Physarum polycephalum amoebae in culture. All, except lumicolchicine, were found to simultaneously reduce the rate of protein synthesis and stimulate RNA synthesis. These results parallel the effects seen in cells exposed to heat shock. Treatment of the cells with a microfilament-disrupting drug, cytochalasin B (10 g/ml in ethanol), resulted in a reduced rate of protein synthesis after 2 h compared to a similar effect by vinblastine in 5–15 min. A morphological abnormality, microtubule paracystals, were seen associated with centrioles in vinblastine-treated cells in which protein synthesis had been reduced by 50%. Vinblastine and podophyllotoxin were shown to interfere with the recovery of protein synthesis after inhibition by low or elevated temperatures. The possible role of microtubules in regulating the translational response of a cell to an external environmental stimulus is discussed.     

Effect of catecholamines and ovarian hormones on cyclic AMP accumulation in rat hypothalamus

Effect of different monoamines and estradiol were studied on cyclic AMP (cAMP) accumulation in hypothalami from 21 day old female rats. Incubation for 5 min with 10^?4M epinephrine, norepinephrine or dopamine resulted in an increase in cAMP accumulation in the hypothalamus. Incubation of hypothalamic tissue with estradiol (4 × 10^?7M to 2 × 10^?5M) also resulted in an increase in cyclic AMP levels. The increase caused by estradiol was observed only after 50 min of incubation period. The estradiol induced increase in cyclic AMP accumulation was abolished by both α and β blockers. These results suggest that the estradiol-induced increase in cyclic AMP may be mediated by a prior increase in catecholamines in the hypothalamic tissue.     

Investigations of the turnover of the putative cellulose-synthesizing particle “rosettes” within the plasma membrane ofFunaria hygrometrica protonema cells

Summary In youngFunaria protonemata the influence of various inhibitors and treatments on cell elongation, fine-structure, and particle rosettes within the plasma membrane, putative parts of cellulose synthase complexes, was investigated. Cycloheximide (3×10^–5M) inhibited growth, reduced the number of rosettes and evened the gradient of rosette distribution at the beginning of treatment. The cell fine-structure was unaffected. Actinomycin D (10^–5M and 10^–4) caused an initial but transient decrease in rosette number. Alterations in cell elongation and fine-structure have not been observed. Application of 2.6-dichlorobenzonitrile (10^–5 M) for some minutes reduced the number of rosettes remarkably, while cell elongation seemed to be normal after the filaments had been transferred back to normal medium. An incubation of 2 h or longer stopped growth and caused cells to burst. The number of rosettes then rose to about 50% of the control values. When applied for 7 h biofluor (5×10^–4 M) promoted growth slightly, but generally it retarded it when used for a longer time. It did not markedly affect the number of rosettes. A short heat stock stopped elongation, caused the disappearance of rosettes and affected the structure of the mitochondria and of the Golgi apparatus. Plasmolysed cells did not grow and, initially, did not have rosettes. At reduced turgor, wider cells are formed. Freeze fracturing under UHV conditions and shadowing at very low specimen temperature revealed a small, central depression in the 8 nm rosette particles, suggesting that they are composed of subunits. Our results provide further evidence that the rosettes are parts of the cellulose synthase complexes. Their existence clearly depends on protein synthesis and on the constitution of the plasma membrane, but not on cellulose crystallization.     

Disruption of microtubules and retardation of development ofDictyostelium with ethylN-phenylcarbamate and thiabendazole

Summary The effects of ethylN-phenylcarbamate (EPC) and thiabendazole (TB) onDictyostelium discoideum andD. mucoroides cells were examined as a step toward purifying tubulin and clarifying the function of microtubules in cellular slime molds. EPC (1.5 × 10^–3M) or TB (5 × 10^–5M) inhibited the development ofDictyostelium, inducing the formation of aberrant fruiting bodies with stalks irregular in shape and sori containing spores of various sizes and shapes.EPC and TB inhibited cell division but not cell growth, resulting in the production of giant cells up to ten times larger than untreated cells. The giant cells either had a single huge nucleus of irregular shape or contained multiple nuclei. The effects of the inhibitors were reversible. After the removal of the inhibitors, the giant cells underwent successive cell divisions producing many daughter cells. Interestingly, most of the giant cells induced by EPC treatment contained gigantic secondary lysosomes probably produced by extensive lysosomophagy.Light microscopy using Nomarski optics revealed that these inhibitors caused the round-up of the cells resulting in the inhibition of cell locomotion, whereas non-Brownian movement of the cytoplasmic granules was not affected. Indirect immunofluorescence using anti--tubulin revealed that networks of microtubules were apparently destroyed by the EPC or TB treatment.These results show both EPC and TB are potent inhibitors of microtubules inDictyostelium and are effective tools for studying the function of microtubules either in cellular or multicellular organization throughout its life cycle.     

Interaction of vinblastine with steady-state microtubules in vitro

At low concentrations, vinblastine binds rapidly and reversibly to a very limited number of high affinity sites on steady-state bovine brain microtubules (mean K_d, 1.9 × 10^?6m; 16.8 ± 4.3 vinblastine binding sites per microtubule) which appear to be located at one or both ends of the microtubules. At high concentrations, vinblastine binds to a high binding capacity class of sites of undetermined affinity, located on helical strands of protofilaments which form at the ends of depolymerizing microtubules, and/or along the surface of the microtubules. Substoichiometric inhibition of microtubule assembly, which occurs at low vinblastine concentrations, appears to be due to the binding of vinblastine to the high affinity class of sites. Fifty per cent inhibition of tubulin addition to the net assembly ends of steady-state microtubules occurred at 1.38 × 10^?7m-drug, and at this concentration, 1.16 ± 0.27 molecules of vinblastine were bound to the high affinity class of sites. Vinblastine appeared to bind directly to the microtubule ends, and our results indicate that vinblastine inhibits the assembly of steady-state bovine brain microtubules by binding rapidly and with high affinity to one or two molecules of tubulin at the net assembly ends. Splaying and peeling of protofilaments at microtubule ends and the active depolymerization of microtubules occurred only at vinblastine concentrations greater than 1 × 10^?6 to 2 × 10^?6m. This action of vinblastine is associated with and may be due to the binding of vinblastine to the high capacity class of sites. Both actions of vinblastine may be due to the binding of vinblastine to the same binding sites on the tubulin molecule, with the sites exhibiting either a high or low affinity depending upon the location in the microtubule.     

Induction and repair of psoralen cross-links in DNA of normal human and xeroderma pigmentosum fibroblasts

Skin fibroblasts from normal human subjects were exposed in vitro to long-wave ultraviolet radiation (UVA, 320–400 nm) alone, or in combination with 8-methoxypsoralen (8-MOP). DNA damage was analysed with the alkaline elution technique before and after post-treatment incubation of the cells at 37°C for various times.Cells treated with UVA at 1.1 J/cm² showed an increased DNA elution rate, which returned to the normal level within 30 min of post-treatment incubation. In cells treated with PUVA (8-MOP at 20 μg/ml plus UVA at 0.04 J/cm²), the alkaline elution rate was not different from untreated control cells, either before or after post-treatment incubation for times up to 7 days.When the PUVA treatment was followed first by a washing, to remove any unbound 8-MOP, and then by UVA (PUVA + UVA) at 1.1 J/cm², the alkaline elution rate decreased below the control level. During the post-treatment incubation of the PUVA + UVA-treated cells there was a gradual increase of the alkaline elution rate to a level significantly above that in control cells. This increase was observed after 30 min. It reached a miaximum after 24 h and remained after 7 days of post-treatment incubation. Cells from a patient with xeroderma pigmentosum of complementation group A, which were given the same PUVA + UVA treatment, did not show any change in the alkaline elution rate during the post-treatment incubation.If, as seems likely, an increased alkaline elution rate indicates an increase of DNA breaks, and a decreased alkaline elution rate indicates the sealing of breaks and/or the formation of cross-links, the results would suggest the following: (1) UVA irradiation in itself is capable of inducing DNA breaks, which are rapidly sealed during post-treatment incubation; (2) PUVA treatment induces mono-adducts, some of which appear to remain in the DNA for at least 7 days of post-treatment incubation and can be activated to form DNA cross-links by a second dose of UVA; (3) DNA cross-links induced by PUVA + UVA can be recognized by a repair process that involves the formation of DNA breaks. This process is not observed in xeroderma pigmentosum cells of group A.