2（4′噻唑）苯丙咪唑对猪脑微管蛋白体外聚合的影响

本研究利用猪脑中分离纯化的微管蛋白聚合和解聚反应,分析了具有争议的非整倍体诱发剂2（4′噻唑）苯丙咪唑（thiabendazole,TBZ）对微管蛋白聚合状态的影响。秋水仙素(colchicine)为本研究的阳性对照物。结果发现：2（4′噻唑）苯丙咪唑能显著抑制体外微管蛋白的聚合,并呈明显的剂量效应关系。研究表明,TBZ可能通过抑制微管蛋白聚合来影响染色体正常分离,诱发非整倍体。 Abstract：Tubulin isolated from porcine brain was employed in the experiment to study the mechanism of aneuploidy induced by thiabendazole(TBZ ) by analyzing the polymerization of tubulin. Colchicine was set as a positive c ontrol of the experiment. The experiment indicated that TBZ could inhibit the tu bulin polymerization significantly and showed a dose effect relationship. The r e sult suggested that TBZ may induce aneuploidy by the pathway of tubulin polymeri zation inhibition which is able to lead to chromosomal malsegregation.     

昆明山海棠根部水抽提物对体外微管蛋白聚合的影响

本研究利用猪脑中分离纯化的微管蛋白聚合和解聚反应,分析了非整倍体诱发剂昆明山海棠根部水抽提物(THH)对微管蛋白聚合状态的影响,从该角度探讨了THH诱发哺乳动物非整倍体的机制。秋水仙素(COL)为本研究的阳性对照物。结果发现THH能显著抑制体外微管蛋白的聚合,该抑制效应呈明显的剂量——效应关系。研究结果与我们以往关于THH为非整倍体诱发剂的实验证据相吻合并进一步提示THH可以抑制微管蛋白聚合作为诱发非整倍体的途径之一。     

多色荧光原位杂交检测小鼠精子非整倍体

比多色荧光原位杂交技术评价了２－（４－噻唑）苯丙咪唑（ＴＢ）在雄性小鼠生殖形成过程中的非整倍体诱发效应。根据小鼠精子发育周期,以口饲法处理动物１１天,间隔２２天后取小鼠精子涂片,聚合应用８号,Ｘ及Ｙ染色体特异性ＤＮＡ探针进行多色ＦＩＳＨ,检测精子中出现的二倍体、双体、和缺本频率。结果发现：在２００ｍｇ／ｋｇ剂量组,上述３类异常精子频率均显著高于溶剂对照,其他２个剂量组的非整倍体精子频率与对照无显著     

红豆杉(Taxus chinensis (Pilger) Rehd.)化学成分研究(简报)

自七十年代发现了紫杉醇（taxol）独特的抗癌机制一促进微管蛋白聚合、抑制微管蛋白解聚后,紫杉醇及其类似物紫杉烷类二该化合物的资源调查和化学研究倍受重视。紫杉醇主要存在于红豆杉科的大多数植物中,红豆杉科（Taxaceae）红豆杉属（TaxuS）植物全球大约有11种,我国有4种和1个变种。我们从采自湖北神农架的红豆杉（Tchinens周树皮中分离得到8个结晶性物质,本文报道其中已鉴定的3个成分,即taxinineJ（l）,ldiydroxybaccatinl（2）和taxol（3）。据文献报道,已经从红豆杉分离得到二十多种紫杉烷类化合物l'l,而我们分离得到的1和2…     

靶向微管抗肿瘤药物研究进展

微管由微管蛋白组成,在细胞分裂、细胞内物质运输、信号传递、维持细胞形态等过程中起着重要作用.一些干扰微管功能的化合物可使细胞停滞在有丝分裂期而抑制细胞增殖.相对于正常细胞,肿瘤细胞有丝分裂异常频繁,以微管作为抗肿瘤的靶点已成为研究热点.作用于微管的微管蛋白抑制剂通过抑制微管蛋白的聚合促进微管解聚或者抑制微管解聚促进微管蛋白聚合来破坏微管动态平衡、干扰肿瘤细胞纺锤体形成、阻断细胞分裂、抑制肿瘤增殖,现就微管蛋白抑制剂的研究进展作一综述.     

三种有丝分裂抑制剂诱发小鼠骨髓细胞非整倍体的比较研究

以秋水仙素有丝分裂(CM)效应、微核(MN)及染色体畸变(CA)三种体内细胞遗传学指标综合评估了有丝分裂抑制剂(秋水仙素、益康唑及对苯二酚)诱发小鼠骨髓细胞非整倍体的效应。结果表明:秋水仙素是典型的多倍体及非整倍体诱发剂。益康唑对细胞有丝分裂有与秋水仙素相类似的效应,进一步分析表明其在哺乳动物体细胞内无非整倍体诱发效应。对苯二酚在哺乳动物活体实验系统中,可能具有诱发非整倍体及染色体结构畸变的多种遗传毒性。结果提示三种细胞遗传学指标能为非整倍体诱发剂的检出提供依据。     

小鼠孤雌胚早期发育过程中γ-微管蛋白的动态变化

微管蛋白是构成微管的主要蛋白,其中α、β亚单位形成异二聚体,而γ-微管蛋白在微管组装中起作用。为了研究小鼠早期孤雌胚中廿微管蛋白的动态变化,本实验采用了免疫荧光化学染色与激光共聚焦显微镜观察相结合的方法,在SrCl2激活的卵母细胞减数分裂以及早期孤雌胚有丝分裂过程中对γ-微管蛋白进行了定位观察。结果显示,SrCl2和细胞松弛素B（cytochalasin B,CB）诱导的第二次减数分裂中期（metaphase Ⅱ ofmeiosis,MII）小鼠卵母细胞恢复减数分裂,并且纺锤体始终与质膜平行,表明纺锤体旋转被抑制,但核分裂不受影响。减数分裂过程中γ-微管蛋白主要定位于中期纺锤体两极和后期分开的染色单体之间;孤雌活化两雌原核形成以后,γ-微管蛋白聚集在两雌原核周围。在早期孤雌胚有丝分裂间期无定形的γ-微管蛋白均匀分布于核;前中期γ-微管蛋白向两极移动,遍布于整个纺锤体区。有丝分裂中期、后期和末期廿微管蛋白的分布变化与减数分裂相似。结果表明,SrCl2和CB激活的MII卯母细胞产生杂合二倍体;γ-微管蛋白具有促微管负极帽形成和稳定微管的功能,从而促进纺锤体的形成;分裂后期和末期廿微管蛋白的重新分布可能是由纺锤体牵引同源染色体分离所诱导的：γ-微管蛋白负责两雌原核的迁移靠近。     

昆明山海棠诱发果蝇生殖细胞非整倍体的研究

以黑腹果蝇的非整倍体测试品系评价了云南地方中草药昆明山海棠水抽提物(THH)在动物生殖细胞中的非整倍体诱发效应,秋水仙素(COL)为本试验的阳性对照物。结果发现,在所有雌雄成虫口饲染毒组中,THH(10-80mg /ml)及COL(2.5-20μg/ml)均显著诱发生殖细胞非整倍体,从而导致X0及X XY例外子代频率显著升高(P<0.001-0.5)。试验表明:THH及COL均能够在蝇生殖细胞形成过程中导致染色体的丢失或不分离;在本研究的受试剂量范围内,雄性果蝇对受试物诱发生殖细胞X染色体遗失效应较为敏感,而雌性果蝇则易检出诱发生殖细胞性染色体不分离的化合物。     

He-Ne激光和增强UV-B辐射对拟南芥叶片微管蛋白的影响

采用He-Ne激光生物辐照仪（632.8 nm,5 mW·mm-2）、UV-B（15.55 KJ·m-2·d-1）及二者复合处理拟南芥幼苗后提取微管蛋白,考马斯亮蓝法测含量和SDS-PAGE凝胶电泳进行初步分析,并用免疫印迹鉴定微管蛋白.结果表明：单独UV-B使微管蛋白解聚,He-Ne激光和UV-B复合处理后,微管蛋白解聚程度减小,单独He-Ne激光处理促进微管聚合.因此认为He-Ne激光在一定程度上缓解了UV-B对微管蛋白的解聚作用.     

微管蛋白亲和力调节激酶4作为药物靶点的研究进展

微管蛋白亲和力调节激酶4（microtubule affinity-regulating kinase，MARK4）是丝氨酸/苏氨酸激酶家族重要成员之一，主要功能是磷酸化微管结合蛋白（microtubule associated protein，MAP），进而导致MAP从微管中分离，从而改变细胞形状，促进细胞分裂，调控细胞周期等。研究表明，MARK4与微管束形成、神经系统发育和程序性细胞死亡等密切相关，并且参与多种疾病的发生，比如阿尔茨海默病（Alzheimer’s disease，AD）、代谢紊乱、癌症以及心衰心梗等疾病，因此MARK4被认为是极具潜力的药物靶点。本文综述了MARK4的三维结构、生物学功能以及MARK4介导的相关疾病，并且总结了MARK4抑制剂的研究进展。     

Aprotic polar solvents inducing chromosomal malsegregation in yeast interfere with the assembly of porcine brain tubulin in vitro

A number of aprotic solvents which had previously been found to induce mitotic aneuploidy in yeast were tested for their effects on re-assembly of twice recycled tubulin from pig brain. Some of the solvents which were strong aneuploidy-inducing mutagens in yeast slowed down tubulin assembly in vitro at concentrations lower than those required for aneuploidy induction. Ethyl acetate, methyl acetate, diethyl ketone and acetonitrile fell into this category. Other strong aneuploidy-inducing agents like acetone and 2-methoxyethyl acetate accelerated tubulin assembly. Non-genetically active methyl isopropyl ketone and isopropyl acetate both accelerated assembly, whereas methyl n-propyl ketone and n-propyl acetate were weak inducers of aneuploidy and slowed down the rate and extent of assembly. Those chemicals which slowed down the assembly rate also reduced the extent of assembly. Most chemicals which accelerated assembly also led to an increased extent of assembly, with the exception of isopropyl acetate. At the higher concentrations, however, a maximum assembly rate was reached which was followed by a slow decline. Although a perfect correlation between effects on the induction of chromosomal malsegregation and the interference with tubulin assembly in vitro was not seen, the experiments with tubulin were carried out using this class of chemicals because some of them strongly induced mitotic aneuploidy under conditions which suggested tubulin to be the prime target. The lack of a perfect coincidence might be due to species differences between the porcine brain and the yeast spindle tubulin, or the test for aneuploidy induction may have been negative because the concentrations required for an effect on yeast tubulin may be greater than the general lethal toxicity limit. Bearing this reservation in mind, the results suggest that the yeast aneuploidy test has a considerable predictive value for mammalian mutagenicity.     

Genetic change may be caused by interference with protein-protein interactions

Several aprotic polar solvents were shown to induce mitotic aneuploidy in yeast: diethyl ketone, γ-valerolactone, pyridine, pivalinic acid nitrile, phenylacetonitrile and fumaric acid dinitrile. Only fumaric acid dinitrile also strongly induced other types of genetic effects including mitotic crossing-over, mitotic gene conversion and point mutation. The other substances only induced aneuploidy and this only over a very narrow dose range.

The treatment protocol used suggested that these chemicals acted via interference with tubulin assembly and disassembly causing a malfunctioning of spindle fiber microtubules. This hypothesis was tested using twice recycled porcine brain tubulin. Diethyl ketone, γ-valerolactone, pyridine and phenylacetonitrile inhibited GTP-promoted assembly of porcine brain tubulin in vitro in the concentration range needed for the induction of mitotic aneuploidy in yeast. Pivalinic acid nitrile accelerated tubulin aggregation whereas fumaric acid dinitrile had no effect even at concentrations 18 times higher than the lowest tested concentration effective in yeast.

The in vitro experiments with porcine brain tubulin further suggest that genetic change can result from interference with specific protein-protein interactions. Fumaric acid dinitrile was the only exception since it did induce aneuploidy but had no effects on the assembly of porcine brain tubulin. This could be caused either by interference with protein-protein interactions other than between molecules during assembly and disassembly of microtubules or species-specific differences in susceptibility between yeast spindle and porcine brain tubulin.     

Aprotic polar solvents that affect porcine brain tubulin aggregation in vitro induce aneuploidy in yeast cells growing at low temperatures

Seven aprotic polar solvents which had previously been shown to interfere with the aggregation in vitro of porcine brain tubulin have been examined for their ability to induce mitotic aneuploidy in Saccharomyces cerevisiae in relation to temperature during exposure. Induction of aneuploidy was in general considerably enhanced when incubation at 28 degrees C was interrupted by overnight storage at low temperature (cold shock). The optimum cold-shock temperatures for individual chemicals varied over a range of 0-16 degrees C. While storage at reduced temperature enhanced the effect of treatment at 28 degrees C, it was also shown that continuous incubation at reduced temperature could greatly enhance the induction of aneuploidy. Only 2 chemicals, 1-methyl-2-pyrrolidinone and gamma-valerolactone, required cold shock to yield a positive response. The other chemicals did not require cold shock for enhanced induction. The observation that the agents examined also interfere with in vitro tubulin aggregation suggests that there is a temperature component to the interaction of these agents with tubulin in vivo. This temperature component is unusual in that the most effective temperature range for aneuploidy induction can be well below the optimal growth temperature for the test organism.     

Selection for thiabendazole resistance in Ostertagia spp. by low efficiency anthelmintic treatment

Thiabendazole (TBZ) treatment of grazing weaners infected with a predominantly susceptible strain of Ostertagia reduced worm burdens by 90%. The surviving sub population had a level of resistance four times greater than the original population when compared to similarly infected, but untreated, weaners. TBZ treated and control weaners were relocated to worm-free pasture so that the contamination on the plots grazed by TBZ treated weaners was from the survivors of the drench. The anthelmintic treated groups were subsequently managed under a two summer drench programme while control groups remained so throughout the experiment. Monitoring both parasite population size and the degree of resistance over the following 2 years indicated that after three anthelmintic treatments, resistance developed to a level where TBZ was ineffective. When compared to control groups, a mean reduction in population size of around 80% was maintained in the TBZ treated groups for 1 year. This difference, however, disappeared by the second year. A similar study over 1 year with a moderately TBZ resistant strain of Ostertagia indicated that TBZ treatment produced no significant reduction in population size but more than doubled the level of resistance. The study indicated the critical need for highly efficient anthelmintic treatment, particularly in situations where, through ecology or management, post treatment contamination is likely to contribute substantially to future generations of worms.     

Bacterial peptidoglycan binds to tubulin

A search for cellular binding proteins for peptidoglycan (PGN), a CD14- and TLR2-dependent macrophage activator from Gram-positive bacteria, using PGN-affinity chromatography and N-terminal micro-sequencing, revealed that tubulin was a major PGN-binding protein in mouse macrophages. Tubulin also co-eluted with PGN from anti-PGN vancomycin affinity column and bound to PGN coupled to agarose. Tubulin-PGN binding was preferential under the conditions that promote tubulin polymerization, required macromolecular PGN, was competitively inhibited by soluble PGN and tubulin, did not require microtubule-associated proteins, and had an affinity of 100-150 nM. By contrast, binding of tubulin to lipopolysaccharide (LPS) had 2-3 times lower affinity, faster kinetics of binding, and showed positive cooperativity. PGN enhanced tubulin polymerization in the presence of 4 M glycerol, but in the absence of glycerol, both PGN and LPS decreased microtubule polymerization. These results indicate that tubulin is a major PGN-binding protein and that PGN modulates tubulin polymerization.     

A porcine brain protein (35 K protein) which bundles microtubules and its identification as glyceraldehyde 3-phosphate dehydrogenase

A protein which binds to both tubulin and tubulin polymer was isolated from porcine brains. This protein has a molecular weight of 35,000 on SDS-polyacrylamide gel electrophoresis (designated as 35 K protein). The 35 K protein was purified through several steps of purification including ammonium sulfate fractionation, Sephadex G-100 gel filtration column chromatography, microtubule protein-agarose gel affinity column chromatography and phosphocellulose column chromatography. The 35 K protein caused pronounced enhancement of the turbidity increase produced by tubulin polymerization in the presence of DMSO, but did not have the ability to initiate polymerization of pure tubulin in the absence of DMSO. It was demonstrated that 35 K protein co-sediments with tubulin polymer in a concentration-dependent manner. Electron microscopic observation revealed the formation of bundles of tubulin polymer. Since the effect of 35 K protein was coupled with tubulin polymerization, 35 K protein did not cause the turbidity increase under conditions where tubulin polymerization was inhibited by Ca2+ or colchicine. The 35 K protein adsorbed on tubulin-Sepharose 4B was eluted by the addition of 2 mM ATP. ATP was shown to inhibit the interaction of 35 K protein with tubulin dimer or polymer. The 35 K protein was finally identified as glyceraldehyde 3-phosphate dehydrogenase from properties such as mobility on SDS-polyacrylamide gel electrophoresis, cleavage pattern on limited proteolysis, ability to bind to tubulin, and so on.     

Influence of maternal dietary zinc intake on in vitro tubulin polymerization in fetal rat brain

The hypothesis that one of the biochemical lesions underlying zinc deficiency-induced teratogenicity is altered microtubule formation was tested. Day 19 fetuses from zinc-deficient Sprague-Dawley dams were characterized by low brain supernate zinc concentrations and slow brain tubulin polymerization rates compared to controls. Brain supernate tubulin and protein concentrations were similar in zinc-deficient and control fetuses. In vitro brain tubulin polymerization rates were increased following addition of zinc to either control or zinc-deficient brain supernates; however, the stimulatory effect of added zinc on polymerization was significantly higher in brain supernates obtained from zinc-deficient fetuses compared to controls. These results support the idea that one effect of fetal zinc deficiency is a reduction in tubulin polymerization, which in turn may result in altered microtubule function.     

Non-disjunction events induced by albendazole in human cells

Albendazole (ABZ), a benzimidazole carbamate used for the treatment of several human helminthiases has high affinity for tubulin, which results in an inhibition of microtubule polymerization, blocking several vital processes in the parasites, such as motility and nutrient uptake. The ability of ABZ to act as mitotic spindle poison leads to a potential risk for aneuploidy induction in exposed human beings. ABZ, as well as albendazole sulphoxide (ABZSO), its main metabolite, induce micronuclei in human cells in a dose-dependent manner. Despite recognition that ABZ and ABZSO increase micronucleus frequency, their potential as inducers of non-disjunction in human cells, an event considered more frequent than chromosome loss, and one of the main mechanisms involved in aneuploidy induction, has not been evaluated. In the present work, we investigated the ability of ABZ and ABZSO to induce non-disjunction in cultured human lymphocytes. Non-disjunction was scored by chromosome-specific FISH using a classical or alpha satellite probe for chromosomes 1 and 7, respectively. Significant increase in non-disjunction events that involved either chromosome were observed in cells treated with ABZ or ABZSO. Both ABZ and ABZSO induced non-disjunction at lower concentrations than those at which MN were observed.