Rotenone inhibition of spindle microtubule assembly in mammalian cells

Rotenone, a potent inhibitor of mitochondrial respiration is also an effective antimitotic agent. The addition of either rotenone or Colcemid to exponentially growing Chinese hamster ovary cells resulted in a dramatic increase in mitotic index after 90 min. When the cultures were washed free of the drugs, mitosis was completed and the cells progressed into G 1 at approximately the same rate. Further similarity of rotenone-arrested cells to Colcemid-induced mitotic inhibition was apparent at the ultrastructural level. Mitotic cells treated by either drug contained monopolar spindles with chromosomes grouped around centriole pairs near the cell center. Occasional microtubules were seen near the kinetochore and centrioles. These observations, along with the fact that rotenone inhibited the binding of ³H-colchicine to isolated bovine brain tubulin, suggested that rotenone inhibited mitosis by binding directly to tubulin to prevent microtubule assembly.     

Rotenone inhibits mammalian cell proliferation by inhibiting microtubule assembly through tubulin binding

Rotenone, a widely used insecticide, has been shown to inhibit mammalian cell proliferation and to depolymerize cellular microtubules. In the present study, the effects of rotenone on the assembly of microtubules in relation to its ability to inhibit cell proliferation and mitosis were analyzed. We found that rotenone inhibited the proliferation of HeLa and MCF-7 cells with half maximal inhibitory concentrations of 0.2 +/- 0.1 microm and 0.4 +/- 0.1 microm, respectively. At its effective inhibitory concentration range, rotenone depolymerized spindle microtubules of both cell types. However, it had a much stronger effect on the interphase microtubules of MCF-7 cells compared to that of the HeLa cells. Rotenone suppressed the reassembly of microtubules in living HeLa cells, suggesting that it can suppress microtubule growth rates. Furthermore, it reduced the intercentrosomal distance in HeLa cells at its lower effective concentration range and induced multipolar-spindle formation at a relatively higher concentration range. It also increased the level of checkpoint protein BubR1 at the kinetochore region. Rotenone inhibited both the assembly and the GTP hydrolysis rate of microtubules in vitro. It also inhibited the binding of colchicine to tubulin, perturbed the secondary structure of tubulin, and reduced the intrinsic tryptophan fluorescence of tubulin and the extrinsic fluorescence of tubulin-1-anilinonaphthalene-8-sulfonic acid complex, suggesting that it binds to tubulin. A dissociation constant of 3 +/- 0.6 microm was estimated for tubulin-rotenone complex. The data presented suggest that rotenone blocks mitosis and inhibits cell proliferation by perturbing microtubule assembly dynamics.     

Quantitative turbidimetric assay for potency evaluation of colchicine-like drugs.

A modified Shelanski method has been applied to quantitatively compare cochicine-like drugs with regard to their inhibition of the rate of rat brain tubulin polymerisation $\text{in vitro}$. The potency of six known microtubule-disrupting drugs was in increasing order: griseofulvin < colchicine < podophyllotoxin < rotenone < vinblastine < vincristine. Two other drugs which have been claimed to interfere with microtubules, melatonin and isopropyl-n-phenylcarbamate were inactive. Methyl benzimidazol-2-yl-carbamate showed only a marginal effect. The usefulness of the method in screening colchicine-like drugs is discussed.     

Rotenone selectively kills serotonergic neurons through a microtubule-dependent mechanism

As a major co-morbidity of Parkinson's disease (PD), depression is associated with the loss of serotonergic neurons. Our recent study has shown that midbrain dopaminergic neurons are particularly vulnerable to microtubule-depolymerizing agents including rotenone, an environmental toxin linked to PD. Here we show that rotenone also selectively killed serotonergic neurons in midbrain neuronal cultures. Its selective toxicity was significantly decreased by the microtubule-stabilizing drug taxol and mimicked by microtubule-depolymerizing agents such as colchicine and nocodazole. Microtubule depolymerization induced by rotenone or colchicine caused vesicle accumulation in the soma and killed serotonergic neurons through a mechanism dependent on serotonin metabolism in the cytosol. Blocking serotonin synthesis or degradation, as well as application of antioxidants, significantly reduced the selective toxicity of rotenone or colchicine. Inhibition of vesicular sequestration of serotonin exerted a selective toxicity on serotonergic neurons that was mitigated by blocking serotonin metabolism. Over-expression of parkin, a protein-ubiquitin E3 ligase that strongly binds to microtubules, greatly attenuated the selective toxicity of rotenone or colchicine. The protective effects of parkin were abrogated by its PD-linked mutations. Together, our results suggest that rotenone and parkin affect the survival of serotonergic neurons by impacting on microtubules in opposing manners.     

Synthesis of deguelin-biotin conjugates and investigation into deguelin's interactions

Deguelin, a rotenoid, has emerged as an attractive pharmacophore for chemoprevention showing in vivo activity in several xenografts. Recently, several lines of evidence have suggested its mode of action may involve inhibition of HSP90, however binding in a different mode than known pharmacophores. To further probe the target of deguelin and related rotenoids, several biotin conjugates were prepared. None of the conjugates showed significant affinity for HSP90, however two conjugates showed a strong cellular co-localization with mitochondria, consistent with binding to mitochondrial complex 1. Contrarily to rotenone, deguelin and tephrosin were not found to inhibit tubulin polymerization demonstrating a dramatic pharmacological difference between these closely related rotenoids.     

The role of ATP in the cytostructure of the hepatocytes

We have previously described the preparation of hepatocytes from which the plasma membrane was removed by digitonin treatment. Such "nude" cells were found to be very stable in sucrose media containing above 50 mM NaCl or KCl, but they disintegrate near instantly in salt-free media, liberating nuclei, mitochondria, and other organelles. We show here that disintegration occurs at a physiologic pH and in the presence of oxygen. Disintegration was blocked by rotenone, oligomycin, KCN, and carboxyatractyloside, establishing that oxidative phosphorylation and ATP generation is essential for disintegration to occur. The addition of ATP, GTP, ITP, or ADP (but not AMP) in the presence of the inhibitors, induced breakdown. Taxol, an inhibitor of tubulin depolymerization and phalloidin, a drug that stabilizes actin fibers, prevented disintegration in salt-free media. The effect of these drugs was counteracted by the addition of ATP. Our results show that two conditions are essential to induce the disintegration of the nude cell: media of low ionic strength, and ATP generation. The ATP effect is likely to be of physiological significance, suggesting role of ATP generation in affecting polymerization of cytoskeletal elements.     

Food consumption, utilization and detoxification enzyme activity of larvae of three polyphagous noctuid moth species when fed the botanical insecticide rotenone

We assessed the effects of the isoflavonoid rotenone, an insecticidal allelochemical occurring in various legumes, on larval performance of three polyphagous noctuid species: the corn earworm (CEW), the fall armyworm (FAW) and the southern armyworm (SAW). As rotenone concentration was increased up to 1% fresh mass in an artificial diet, neither mortality (for all three species) nor food consumption (for SAW and FAW) was significantly affected, but developmental time of the latter two species was prolonged. In contrast, for CEW developmental time was shortened and food consumption declined, especially at the two highest rotenone concentrations. Final biomass of all three species declined as dietary rotenone increased.Analysis of covariance (ANCOVA) was used to evaluate larval food utilization analogous to, but without the potential statistical problems of, the traditional ratio-based indices approximate digestibility (AD) and efficiency of conversion of digested food (ECD). Frass output, statistically adjusted to account for differences in consumption, increased with rotenone concentration for all three species, suggesting that, when ingested, this allelochemical interfered with the digestion and/or absorption of ingested food, especially at the higher concentrations tested.Significant statistical interactions in the ANCOVA necessitated the use of utilization plots to examine the linear regressions between biomass gain and absorption at each rotenone concentration. At the two highest concentrations, rotenone tended to reduce the amount of food absorbed by the larvae, as well as their ability to convert the absorbed food to biomass.When piperonyl butoxide, an inhibitor of the polysubstrate monooxygenase (PSMO) system known to metabolize rotenone, was added to the diet along with 0.5 or 1% rotenone, mortality increased significantly only for FAW, approaching or exceeding 50%. The only apparent effects of dietary rotenone on PSMO (aldrin epoxidase) activity (adjusted by ANCOVA for the covariate, crude homogenate protein) were for CEW, where activity decreased in all rotenone treatments compared to the control, and for SAW, where activity at the 3 lowest rotenone concentrations (0.001–0.1% fm) declined about 50% below that of larvae on the control diet, whereas at 0.5 and 1% rotenone, it increased approximately 2-fold over that on the control diet.     

星形胶质细胞通过谷胱甘肽保护MN9D细胞抵抗鱼藤酮所致氧化应激

星形胶质细胞维持神经元微环境,给予营养和代谢支持,并调节其对损伤的反应。鱼藤酮特异阻断线粒体复合物Ⅰ,长期暴露于鱼藤酮可能增加患帕金森病的几率,并引起帕金森综合征。然而,星形胶质细胞在鱼藤酮所致多巴胺能神经元损伤过程中的作用尚无报道。本研究采用多巴胺能神经元细胞系MN9D细胞模型,将经过或未经过星形胶质细胞条件培养基处理的MN9D细胞暴露于不同浓度的鱼藤酮中,用计数法测生长曲线,MTT法测细胞活性,DCFH染色流式细胞仪测氧化应激水平,比色法测还原型谷胱甘肽含量。结果显示,MN9D细胞在条件和普通培养基培养条件下生长曲线无明显差别;鱼藤酮浓度依赖性地降低细胞活性;不同浓度鱼藤酮作用24、48h后,经条件培养基处理的细胞其活性显著高于普通培养基培养的细胞：不同浓度的条件培养基都有保护作用,纯的条件培养基保护作用稍弱：预先24h条件培养基处理或同时给予鱼藤酮和条件培养基处理都有保护作用,鱼藤酮作用12h后再给予条件培养基则无保护作用;经条件培养基处理的细胞氧化应激水平降低：另外,条件培养基提高了细胞内还原型谷胱甘肽含量,缓解了鱼藤酮所致的谷胱甘肽耗竭。结果提示,星形胶质细胞可保护MN9D细胞抵抗鱼藤酮所致的氧化应激,还原型谷胱甘肽可能参与了该保护过程。     

The effect of rotenone on respiration in pea cotyledon mitochondria

Respiration utilizing NAD-linked substrates in mitochondria isolated from cotyledons of etiolated peas (Pisum sativum L. var. Homesteader) by sucrose density gradient centrifugation exhibited resistance to rotenone. The inhibited rate of α-ketoglutarate oxidation was equivalent to the recovered rate of malate oxidation. (The recovered rate is the rate following the transient inhibition by rotenone.) The inhibitory effect of rotenone on malate oxidation increased with increasing respiratory control ratios as the mitochondria developed. The cyanide-resistant and rotenone-resistant pathways followed different courses of development as cotyledons aged. The rotenone-resistant pathway transferred reducing equivalents to the cyanide-sensitive pathway. Malic enzyme was found to be inhibited competitively with respect to NAD by rotenone concentrations as low as 1.67 micromolar. In pea cotyledon mitochondria, rotenone was transformed into elliptone. This reduced its inhibitory effect on intact mitochondria. Malate dehydrogenase was not affected by rotenone or elliptone. However, elliptone inhibited malic enzyme to the same extent that rotenone did when NAD was the cofactor. The products of malate oxidation reflected the interaction between malic enzyme and malate dehydrogenase. Rotenone also inhibited the NADH dehydrogenase associated with malate dehydrogenase. Thus, rotenone seemed to exert its inhibitory effect on two enzymes of the electron transport chain of pea cotyledon mitochondria.     

The relationship between energy generation and cholesterol side-chain cleavage reaction in the mitochondria from human term placenta

1. The interrelationship between progesterone (from cholesterol) biosynthesis and oxidative phosphorylation in human placental mitochondria was examined. 2. ADP and ATP stimulated the malate, succinate and alpha-ketoglutarate-supported progesterone biosynthesis probably via the energy-dependent pyridine nucleotide transhydrogenase activation. The effect of ADP was abolished by rotenone and antimycin in the presence of malate or alpha-ketoglutarate. 3. In the non-energized state of mitochondria malate may supported progesterone biosynthesis by the malic enzyme-dependent pathway. 4. The inhibitory effects of antimycin or cyanide, and the stimulatory effect of rotenone on the succinate-supported progesterone biosynthesis indicate that the succinate to malate conversion is a necessary condition for the stimulation of progesterone biosynthesis from cholesterol. 5. alpha-Ketoglutarate plus malonate did support progesterone biosynthesis also in the presence of ADP or ATP and to a lesser degree in the presence of DNP and rotenone. Arsenate in the presence of alpha-ketoglutarate, malonate, dinitrophenol and rotenone did not affect significantly progesterone biosynthesis. These results indicate that NADPH may be generated also by a non-energy-dependent transhydrogenation in placental mitochondria.     

Matrix NADH dehydrogenases of plant mitochondria and sites of quinone reduction by complex I.

In order to distinguish the pathways involved in the oxidation of matrix NADH in plant mitochondria, the oxidation of NADH and nicotinamide hypoxanthine dinucleotide (reduced form) was investigated in submitochondrial particles prepared from beetroot (Beta vulgaris L. cv. Derwent Globe) and soybeans (Glycine max L. cv. Bragg). Nicotinamide-hypoxanthine-dinucleotide(reduced form)-oxidase activity was more strongly inhibited by rotenone than the NADH-oxidase activity but both of the rotenone-inhibited activities could be stimulated by adding ubiquinone-1. The corresponding ubiquinone-1-reductase activities were inhibited by rotenone (to 69%) and further inhibited by N,N'-dicyclohexylcarbodiimide (to 79%), whilst the K3Fe(CN)6-reductase activities were not sensitive to either rotenone or N,N'-dicyclohexylcarbodiimide. Immunological analysis of mitochondrial proteins using an antiserum raised against purified beetroot complex I indicated very few differences between soybean and fresh and aged beetroot mitochondria, despite their varying sensitivities to rotenone. We confirm that there are two dehydrogenases capable of oxidising internal NADH and that only one of these, namely complex I, is inhibited by rotenone. Further, we conclude that complex I has two potential sites of quinone reduction, both sensitive to N,N'-dicyclohexycarbodiimide inhibition but only one of which is sensitive to rotenone inhibition.     

Nrf3通路参与星形胶质细胞对抗鱼藤酮毒性的保护作用

目的：寻找星形胶质细胞在对抗由鱼藤酮导致的氧化应激中发挥保护作用的相关分子并探讨其作用机制。 方法：小鼠多巴胺能MN9D细胞分别在星形胶质细胞条件培养液（ACM）与星形胶质细胞用新鲜培养基中培养24小时后加入鱼藤酮作用48小时。细胞计数,评价星形胶质细胞条件培养液对MN9D细胞的保护作用。利用基因芯片技术寻找MN9D细胞在ACM处理后发生表达上调或下调基因,并对这些基因进行分析,找出有意义基因。结果： 在不同作用时间和鱼藤酮浓度梯度下,经过ACM处理的MN9D细胞活性显著高于在普通培养基中培养的细胞。初步得到104个差异表达基因,其中62个表达上调基因,42个表达下调基因。这些基因主要与凋亡、肿瘤、细胞周期、代谢、信号转导、转录调节、翻译调节和传递蛋白等相关。对其中的Atp5a1,Nrf3基因进行分析,发现Nrf3通路参与了ACM的保护作用。结论： ACM能保护MN9D细胞抵抗鱼藤酮所致的细胞毒性, Atp5a1,Nrf3,GCL,NQO1等基因经ACM处理后发生差异表达,可能是星形胶质细胞保护作用的部分下游信号通路。     

Action of rotenone and related respiratory inhibitors on mammalian cell division. 1 Cell kinetics and biochemical aspects.

Inhibitors of mitochondrial respiration, phosphorylation inhibitors, and uncoupling agents have been reported to delay or inhibit mitosis in cultured mammalian cells. Although the molecular mechanism by which mitosis is delayed in the presence of most respiratory inhibitors presumably involves lowered ATP production for mitotic requirements, one respiratory inhibitor, rotenone, was determined to arrest mitosis by an unrelated mechanism. Cell cycle kinetics studies, oxygen consumption measurements, and viscosity assays indicate that rotenone arrests cultured mammalian cells in mitosis by inhibiting spindle microtubule assembly by a mechanism analogous with colchicine, Colecemid and related antimitotic drugs. Amytal, which blocks electron transport at the same site as does rotenone, failed to arrest cell progression at mitosis. Rotenone delayed cell progression in all phases of the cell cycle, apparently as a direct result of respiration inhibition. Thus, rotenone appears to exert a dual function on events of the cell cycle.     

Characterization and in vitro polymerization of Tetrahymena tubulin

Tetrahymena tubulin was purified from the cell extract using DEAE-Sephadex A-50 ion-exchanger and ammonium sulfate precipitation. About 2.2% of the total protein in the 20,000 X g supernatant was recovered as DEAE-Sephadex-purified tubulin fraction. Applying the temperature-dependent polymerization-depolymerization method to this fraction in the presence of Tetrahymena outer fibers as a seed, almost pure tubulin was obtained. Tetrahymena tubulin dimer showed different behavior on SDS-polyacrylamide gels from porcine brain tubulin, and showed very low affinity for colchicine, amounting to about one-twentieth of the binding to porcine brain tubulin. The tubulin fraction failed to polymerize into microtubules by itself. Addition of a small amount of the ciliary outer fiber fragment induced polymerization as demonstrated by viscometric measurements, but the reconstituted microtubules were very unstable in the absence of glycerol. Microtubule-depolymerizing agents such as Ca2+ ions, low temperature, or colchicine all inhibited in vitro polymerization. Although Tetrahymena tubulin purified by the polymerization-depolymerization method could copolymerize with porcine brain microtubules, the DEAE-Sephadex-purified tubulin fraction suppressed the initial rate of porcine brain microtubule assembly in vitro. There seemed to be no differences between cytoplasmic tubulin and outer fiber tubulin in colchicine binding activity or SDS-gel electrophoretic behavior, or between the fine structure of both reconstituted microtubules observed by electron microscopy.     

The effect of delta mu H+ on the interaction of rotenone with complex I of submitochondrial particles.

The inhibition by rotenone of the forward (NADH-oxidase) and reverse (delta mu H(+)-dependent succinate-NAD+ reductase activities of submitochondrial vesicles was measured. The inhibition of NADH-oxidase, measured in the presence of uncoupler, followed a monophasic inhibition curve with Ki < or = 2 nM. The reverse electron flow was only partially (40%) inhibited at these rotenone concentrations. The rest of the activity was less sensitive to the inhibitor (Ki approximately 30 nM). The lower affinity for the inhibitor of the reverse electron flow is a consequence of enhanced rate of rotenone dissociation caused by the high delta mu H+ value required for this reaction. The analysis of the results indicates that the AS-SMP preparation consists of two subpopulations: one with a relatively low degree of coupling, which exhibits high sensitivity to rotenone and the other which is highly coupled with lower affinity to the inhibitor.     

Interaction of rat brain microtubule proteins and 6S tubulin with rabbit skeletal muscle actomysin.

The interaction between actomyosin from rabbit skeletal muscle and microtubule proteins or 6S tubulin from rat brain was investigated with respect to the change in ATPase activity and physicochemical properties. Myosin bound to both microtubule proteins and 6S tubulin at low ionic strength. In the aggregates the molar ratio of microtubule proteins or 6S tubulin to myosin was 0.5–1.5 or 1.5–2.5. The superprecipitation of actomyosin was inhibited by 6S tubulin. The degree of superprecipitation inhibition was dependent on the mixing order of myosin, actin, 6S tubulin, and ATP. When myosin was preincubated first with 6S tubulin, the inhibition was most marked. The actin activation of myosin Mg-ATPase was inhibited by both microtubule proteins and 6S tubulin with stronger effects by the latter. The preincubation of myosin with 6S tubulin prior to the addition of actin induced not only greater inhibition of ATPase but also the binding of a larger quantity of 6S tubulin to myosin than the preincubation of myosin with actin. The similar results were obtained with microtubule proteins.     

Inhibition of complex I regulates the mitochondrial permeability transition through a phosphate-sensitive inhibitory site masked by cyclophilin D

Inhibition of the mitochondrial permeability transition pore (PTP) has proved to be an effective strategy for preventing oxidative stress-induced cell death, and the pore represents a viable cellular target for drugs. Here, we report that inhibition of complex I by rotenone is more effective at PTP inhibition than cyclosporin A in tissues that express low levels of the cyclosporin A mitochondrial target, cyclophilin D; and, conversely, that tissues in which rotenone does not affect the PTP are characterized by high levels of expression of cyclophilin D and sensitivity to cyclosporin A. Consistent with a regulatory role of complex I in the PTP-inhibiting effects of rotenone, the concentrations of the latter required for PTP inhibition precisely match those required to inhibit respiration; and a similar effect is seen with the antidiabetic drug metformin, which partially inhibits complex I. Remarkably (i) genetic ablation of cyclophilin D or its displacement with cyclosporin A restored PTP inhibition by rotenone in tissues that are otherwise resistant to its effects; and (ii) rotenone did not inhibit the PTP unless phosphate was present, in striking analogy with the phosphate requirement for the inhibitory effects of cyclosporin A [Basso et al. (2008) J. Biol. Chem. 283, 26307-26311]. These results indicate that inhibition of complex I by rotenone or metformin and displacement of cyclophilin D by cyclosporin A affect the PTP through a common mechanism; and that cells can modulate their PTP response to complex I inhibition by modifying the expression of cyclophilin D, a finding that has major implications for pore modulation in vivo.     

Rotenone-Insensitive Malate Oxidation by Isolated Plant Mitochondria

The inhibitory effect of rotenone, and the variability of theinhibition, on malate oxidation by isolated plant mitochondriahas been investigated. Under conditions where oxaloacetate removalis enhanced (by transamination with glutamate) the rotenoneinhibition is less severe. Where oxaloacetate is allowed toaccumulate, inhibition by rotenone is marked. Similarly, underconditions which would tend to increase the steady state levelof reduction of the NAD pool (restricting coupled electron flowwith oligomycin) rotenone inhibition is severe. It is concludedthat the degree of rotenone inhibition is related to factorsaffecting the equilibrium poise of malic dehydrogenase, anddoes not necessarily reflect the interaction between rotenoneand the respiratory chain. There appears to be no correlationbetween the effectiveness of rotenone inhibition and mitochondrialmalic enzyme activity. Although there may be separate pathwaysof intramitochondrial NADH oxidation, it appears to be prematureto postulate separation or compartmentation of intramitochondrialmalate oxidation pathways.