Ennamany R, Marzetto S, Saboureau D, Creppy E E
Faculty of Pharmaceutical Sciences, University of Bordeaux, France.
Cell Biol Toxicol. 1995 Dec;11(6):347-54. doi: 10.1007/BF01305906.
Bolesatine, a glycoprotein from Boletus satanas Lenz, has previously been shown to be mitogenic in rat and human lymphocytes at very low concentrations, whereas higher concentrations inhibited protein synthesis in vitro and in several in vivo systems. The low concentrations (1-10 ng/ml) of bolesatine were shown to activate protein kinase C (PKC) in vitro (cell-free system) and in Vero cells. In the same time, Vero cells significantly proliferated when incubated with bolesatine concentrations ranging from 1 to 10 ng/ml; the DNA synthesis increased by 27-59% as referred to the control, and InsP3 release increased in a concentration-dependent manner, up to 142%. At higher concentrations, 1-10 micrograms in cell-free systems, bolesatine inhibits protein synthesis by hydrolyzing the nucleoside triphosphates GTP and ATP. In the present work, the implication of other toxic mechanisms, such as lipid peroxidation and active radical production, was investigated in relation to inhibition of cell growth, whereas possible modifications of the ratio m5dC/dC+m5dC were determined in order to correlate with the biphasic action of bolesatine in Vero cells. Low concentrations of bolesatine up to 10 ng/ml do not increase malonaldehyde (MDA) production, while they induce hypomethylation (5.2% as compared to 7.1%). Higher concentrations (above 20 ng/ml) increase MDA production, from 58 ng/mg of cellular proteins to 113 ng/mg at a concentration of 50 ng/ml, for example, and induce hypermethylation in Vero cell DNA. It is concluded that low concentrations of bolesatine that are proliferative induce hypomethylation, which could be one of the pathways whereby bolesatine induces cell proliferation. Higher concentrations which enhance lipid peroxidation also induce hypermethylation. These mechanisms could be at least partly implicated in the pathway whereby bolesatine induces cell death.
鬼笔毒素是一种来自毒红菇的糖蛋白,此前研究表明,其在极低浓度下即可促使大鼠和人类淋巴细胞发生有丝分裂,而在较高浓度时,它会在体外及多个体内系统中抑制蛋白质合成。研究显示,低浓度(1-10纳克/毫升)的鬼笔毒素在体外(无细胞系统)及非洲绿猴肾细胞(Vero细胞)中均可激活蛋白激酶C(PKC)。与此同时,当Vero细胞与浓度范围为1至10纳克/毫升的鬼笔毒素一起孵育时,细胞会显著增殖;与对照组相比,DNA合成增加了27%-59%,并且肌醇三磷酸(InsP3)释放呈浓度依赖性增加,最高可达142%。在无细胞系统中,较高浓度(1-10微克)的鬼笔毒素通过水解三磷酸核苷鸟苷三磷酸(GTP)和三磷酸腺苷(ATP)来抑制蛋白质合成。在本研究中,针对其他毒性机制,如脂质过氧化和活性自由基产生,与细胞生长抑制的关系进行了研究,同时测定了5-甲基胞嘧啶(m5dC)与胞嘧啶加5-甲基胞嘧啶(dC+m5dC)比例的可能变化,以便与鬼笔毒素对Vero细胞的双相作用建立关联。低浓度至10纳克/毫升的鬼笔毒素不会增加丙二醛(MDA)的产生,但会诱导低甲基化(与7.1%相比为5.2%)。较高浓度(高于20纳克/毫升)会增加MDA的产生,例如,在50纳克/毫升的浓度下,MDA产量从每毫克细胞蛋白58纳克增加到113纳克,并在Vero细胞DNA中诱导高甲基化。研究得出结论,具有增殖作用的低浓度鬼笔毒素会诱导低甲基化,这可能是鬼笔毒素诱导细胞增殖的途径之一。增强脂质过氧化的较高浓度也会诱导高甲基化。这些机制可能至少部分参与了鬼笔毒素诱导细胞死亡的途径。
