洋葱鳞茎内表皮细胞中的微管

用超薄切片和原生质体负染的方法,在电镜下观察到洋葱鳞茎内表皮细胞周质微管的存在。其出现时间、分布状况以及排列形态,基本上与考马斯亮蓝染色法观察到的网状结构物相一致。讨论了包被囊泡和微管组织中心可能的作用。     

离子胁迫诱导洋葱鳞茎内表皮细胞凋亡

通过不同浓度离子胁迫诱导剂(NaCl、CaCl2)对洋葱鳞茎内表皮细胞进行不同时间的处理,发现0.1M、0.5M的NaCl和CaCl2处理2小时即可诱导出细胞凋亡现象,随处理时间延长直至10小时,细胞核凋亡的形态学变化和凋亡小体更加明显,基因组DNA降解更加梯状条带化。本实验对离子诱导的洋葱鳞茎内表皮细胞凋亡现象做了较系统的描述,为植物细胞凋亡的研究及细胞凋亡实验教学提供了经济、快捷、有效的诱导方法。     

观察洋葱表皮细胞实验的改进

在实验过程中,教师可以想办法培养学生的竞争意识与创新意识。竞争意识的培养可以通过组间或个人间进行比赛的形式获得,如比比谁先观察到玻片标本上的东西。创新意识的培养主要体现在实验的设计方面,不拘泥于书本上的方案,根据现有条件重新设计方案。在此过程中,通过评选最佳方案又可以培养学生的竞争意识。诸如此类的情感教育,完全可以让学生全面体会到实验教学的功效,在情感的指引下唤起学生内部的学习动机,巩固实验的浓厚兴趣。     

利用洋葱鳞叶表皮细胞观察植物细胞结构实验的改进

以洋葱表皮细胞为研究材料,通过中性红液泡染色和质壁分离实验相结合,将能更清晰地观察到细胞壁,细胞质膜,细胞质,液泡膜,液泡,细胞核,核仁等结构,达到光学显微镜下观察植物细胞基本结构的教学目的。改进后的实验大大提高了利用洋葱表皮细胞观察植物细胞结构实验的教学效果,同时可以通过观察不同部位液泡体积变化,了解植物细胞的动态发育,使学生掌握了更多的知识点。     

秋水仙素对洋葱根尖细胞的诱变效应

通过三种浓度的秋水仙素对洋葱根尖进行控时处理,结果发现,该药剂能使洋葱根尖细胞有丝分裂指数下降,促进洋葱根尖膨大,导致染色体加倍,并产生畸变细胞。     

细胞松弛素D、秋水仙素作用下大鼠肝癌细胞中黏弹性的研究

采用微管吮吸技术测定大鼠肝癌细胞的黏弹性;研究了秋水仙素、细胞松弛素D以及两者混合作用后对于肝癌细胞黏弹性的影响。结果表明:用CD处理癌细胞后发现癌细胞的弹性系数K1明显下降。与对照组相比:微丝骨架被CD抑制后,在加入Col后肝癌细胞的弹性系数K1显著降低;而微管骨架被col抑制后,在加入CD后肝癌细胞的弹性系数K1、K2和μ无明显变化。提示在微管骨架系统完整的情况下,微丝对肝癌细胞的黏弹性系数的的影响起主要作用。而微管骨架系统受到破坏后,微丝需借助于微管网络的作用来影响细胞的黏弹性。本研究对揭示癌细胞中骨架系统之间的交互作用对于细胞黏弹性的影响提高实验依据。     

贮藏洋葱抽苔时鳞片叶表皮细胞的细胞学变化

利用透射电镜观察了洋葱抽苔时其鳞片叶表皮细胞的亚显微结构变化。幼嫩鳞片叶表皮细胞结构正常：液泡在细胞中央,细胞质在靠近细胞壁的边缘;细胞质中富含质体、线粒体和核糖体等细胞器;胞间连丝直径约为５０ｎｍ。伴随着细胞的衰退,细胞质变得松散,在液泡中出现大量絮状物,细胞器逐渐解体。少数胞间连丝直径扩大,达到８０ｎｍ左右,它可能在大分子胞间转移中起重要作用。在衰老细胞中,核和质体已解体但多数胞间连丝仍维持正常状态。     

农杆菌介导的MpASR蛋白在洋葱表皮细胞的定位研究

通过比较不同侵染液浓度、侵染时间、取材部位、预处理等条件下的转化效果,优化了农杆菌介导的洋葱鳞茎内表皮细胞转化系统,并且成功检测到大蕉ASR蛋白(MpASR)与GFP的融合蛋白在洋葱表皮细胞中的分布.     

洋葱花药发育过程中的细胞化学研究(简报)

高等植物花药结构复杂,其发育更是一个迅速、多变的过程,如小孢子母细胞减数分裂期间的细胞质改组、胼胝质壁的形成与降解、大液泡的形成与消失、花粉内外壁的形成、绒毡层细胞的降解、营养物质的积累与转化等。除了上述花药组成细胞的形态和结构发生明显变化外。花药发育的另一个显著特点是以花粉为中心的营养物质单向运输和转化,尤其是小孢子有丝分裂形成二胞花粉后开始积累大量的营养储存物以供成熟花粉萌发时利用。     

细胞松弛素B对日本沼虾四倍体的适宜诱导条件的研究

本文研究了用细胞松弛素B(Cytochalasin B,CB)诱导日本沼虾(Macrobrachium nipponense)多倍体的处理条件和方法。试验水温分别为18—19℃、22—23℃,CB浓度为1.0—2.0mg/L,处理的起始时间在受精后5—9h,处理的持续时间为10—20min。结果表明,在水温为18—19℃时,四倍体卵子的最适诱导条件为:受精后7—8h,CB溶液的浓度1.5mg/L,处理20min,四倍体诱导率最高可达56.1%;在水温为22—23℃时,最适诱导条件为:在受精后6 h左右,CB溶液浓度为1.5mg/L,处理15—20min,四倍体诱导率最高可达54.3%。处理的起始时间和CB溶液的浓度对胚胎的四倍体率有显著影响(P<0.05);胚胎的成活率随CB浓度的提高与处理的持续时间的延长而下降。考虑到胚胎成活率因素,建议选择CB浓度为1.5mg/L,处理持续时间15—20min。     

Cellular Networks in Epidermal Peels of Onion

Cellular networks ill epidermal peels of onion bulb can be distinguished by first removal of superficially attached cytoplasmic constituents with Triton phos- phate buffer and then by staining with Coomassie blue R 250(Fig. 4). Two distinct kinds of networks can be further recognized by treatment with colchicine and cytochalasins: one thinner network underneath the periphery of plasmalemma can be abolished by colchicine (Fig. 7, 8); and the other thicker one which associates tangentially with the nucleus was more distinctive after cytochalasin B treatment (Fig. 5, 6). Discussion is made regarding these two networks in wall-enclosed plant cells as revealed by the present technic.     

洋葱鳞茎薄壁细胞原生质体胞质肌动蛋白质微丝骨架的形态与结构

使用四甲基罗丹明标记的鬼笔环碱(TRITC-Ph)探针,以新分离的洋葱鳞茎薄壁细胞原生质体为材料,观察了细胞胞质肌动蛋白微丝骨架的结构与形态。研究结果发现洋葱鳞茎内部细胞的细胞质内存在极丰富而精细的肌动蛋白微丝束。这些肌动蛋白微丝束的直径约1.0—4.5μm,有下列四种不同的排列形式:(1)相互平行排列,方向大体与细胞的长轴垂直;(2)从一些结合位点辐射而出,并向四周延伸,然后再相互交织在一起,形成一个非常密集而复杂的网络;(3)细而稀疏,相互交织成网状,两端分别与质膜不同位置上的结合位点相连;(4)粗而稀疏,相互交织成网状,两端都与质膜相连,或一端与质膜相连,另一端与细胞核周围的微丝束网络相连。部分微丝束具有“Y”形分支。     

The junction between the plasma membrane and the cell wall in fern protonemal cells,as visualized after plasmolysis,and its dependence on arrays of cortical microtubules

Summary The junction between the plasma membrane and the cell wall in the subapical region of tip-growing protonemata of the fernAdiantum capillus-veneris was visualized by plasmolyzing the cells with a 1 M solution of NaCl. When the protonemata were treated with this solution, cells were rapidly plasmolyzed and the plasma membrane became detached from the cell wall around the entire periphery of the cell, with the exception of the subapex. In the subapical region, the connection between the cell wall and the plasma membrane remained undisturbed, whereas the membrane in other regions, as well as at the apex, was detached from the cell wall. As a result, the protoplasm appeared to adhere to the wall by a ringlike band of plasma membrane at the subapex. The location of the junction coincided with that of a circular array of microtubules (MTs) and microfilaments (MFs) at the cell cortex. The subapical junction disappeared when protonemata were treated with colchicine, cytochalasin B (CB), and blue-light irradiation, all of which are known to disrupt circular arrays of MTs. CB and blue light also disrupt the array of MFs but colchicine does not. Thus, the junction depends on the cortical MTs and not on the MFs. This finding indicates that the junction between the plasma membrane and the cell wall is sustained by a cortical array of MTs and suggests the presence of a specific and localized transmembrane structure.Abbreviations CB cytochalasin B - MF microfilament - MT microtubule     

细胞原癌基因在小鼠胚胎癌细胞中的表达

近些年来,细胞原癌基因(cellular onco-gene)的发现和大量研究,使人们相信这类基因的产物在早期胚胎发育过程中有着十分重要的功能,因而它们在转录水平上的变化也特别受到注意。胚胎癌细胞(embryonal carci-noma cell,简称EC细胞)是一类与早期胚胎细胞相类似的恶性细胞,具有多种分化潜能,     

DETERMINATION OF METHYLENE BLUE BIOSORPTION BY Rhizopus arrhizus IN THE PRESENCE OF SURFACTANTS WITH DIFFERENT CHEMICAL STRUCTURES

Methylene blue (MB) biosorption properties of Rhizopus arrhizus were investigated in the presence of surfactants. The effects of cationic and anionic surfactants on MB removal by dead biomass (1 g L^?1) were determined. MB removal was tested as a function of initial pH (2–12), contact time (5–1440 min), and dye (37.4–944.7 mg L^?1) and surfactant (0–10 mM) concentrations. The opposite charged anionic surfactant dodecylbenzenesulfonic acid sodium salt (DBS) enhanced sorption of cationic MB by biomass dramatically. Maximum biosorption capacity was 471.5 mg g^?1 at pH 8 with 0.5 mM DBS at 944.7 mg L^?1 MB concentration. The surfactant-stimulated fungal decolorization method may provide a highly efficient, inexpensive, and time-saving procedure in biological wastewater treatment technologies.     

UV‐A/BLUE LIGHT–INDUCED REACTIVATION OF SPORE GERMINATION IN UV‐B IRRADIATED ULVA PERTUSA (CHLOROPHYTA)1

Recent reduction in the ozone shield due to manufactured chlorofluorocarbons raised considerable interest in the ecological and physiological consequences of UV‐B radiation (λ=280–315 nm) in macroalgae. However, early life stages of macroalgae have received little attention in regard to their UV‐B sensitivity and UV‐B defensive mechanisms. Germination of UV‐B irradiated spores of the intertidal green alga Ulva pertusa Kjellman was significantly lower than in unexposed controls, and the degree of reduction correlated with the UV doses. After exposure to moderate levels of UV‐B irradiation, subsequent exposure to visible light caused differential germination in an irradiance‐ and wavelength‐dependent manner. Significantly higher germination was found at higher photon irradiances and in blue light compared with white and red light. The action spectrum for photoreactivation of germination in UV‐B irradiated U. pertusa spores shows a major peak at 435 nm with a smaller but significant peak at 385 nm. When exposed to December sunlight, the germination percentage of U. pertusa spores exposed to 1 h of solar radiation reached 100% regardless of the irradiation treatment conditions. After a 2‐h exposure to sunlight, however, there was complete inhibition of germination in PAR+UV‐A+UV‐B in contrast to 100% germination in PAR or PAR+UV‐A. In addition to mat‐forming characteristics that would act as a selective UV‐B filter for settled spores under the parental canopy, light‐driven repair of germination after UV‐B exposure could explain successful continuation of U. pertusa spore germination in intertidal settings possibly affected by intense solar UV‐B radiation.