休眠期和营养期包囊游仆虫的纤毛器骨架及其微管蛋白

应用光镜和透射电镜术 ,显示了包囊游仆虫休眠细胞中纤毛器骨架的形态 ,并对该纤毛虫休眠细胞和营养细胞的纤毛器及其α、β -微管蛋白进行了免疫荧光定位的比较研究。由免疫荧光显微术显示 ,包囊游仆虫形成休眠包囊后 ,背部毛基体完整地按原有模式保存下来 ;纤毛杆解聚后微管蛋白多集中在细胞皮层 ,小部分均匀散布在细胞质中。据所得结果认为 ,包囊游仆虫形成包囊后 ,微管蛋白主要有 3个去向 ,即 :①处于自噬泡内被逐步消化 ;②以“微管蛋白库”的形式分布于细胞皮层及细胞质中 ;③保留在残留的基体中。此外 ,以往研究中发现的棘毛基部纤维网络未被标记上 ,提示这些纤维体系可能不属于微管系统     

包囊游仆虫包囊形成和解脱过程中纤毛器的分化

包囊游仆虫(Euplotes encysticus)形成包囊时,各类纤毛器中的纤毛杆被部分地或全部地吸收,毛基体被保留下来。休眠包囊中,背纤毛器的定位无明显变化,但原腹面纤毛器中的口围带和波动膜、额腹棘毛和横棘毛,以及左、右尾棘毛都按序陷入在细胞质内深处,并相互汇聚在一起。脱包囊时,纤毛结构在原毛基体上再分化,新纤毛器按口围带、横棘毛、额腹棘毛和左、右尾棘毛的顺序从细胞内显露出来。     

包囊游仆虫皮层和营养核的超微结构研究

为研究纤毛虫在不同生理条件下结构的分化及其调节机理,本文应用透射电镜术显示,营养期包囊游仆虫背、腹面皮层表膜下含３种方式排列组成的纵微管层以及深部微管;口区皮层内含高电子密度的杆状小体;口围带小腹基部含电子致密带和小腹托架,棘毛基体基部及基体下微管束形成围棘纤维篮;背纤毛基体下方也含微管结构;大核染色质附着在核膜上,核膜其他区域有规则排列的核孔。     

两种纤毛虫营养细胞和休眠细胞蛋白组成的比较分析

应用生化抽提和SDS-PAGE方法显示,膜状急纤虫(Tachysoma pellionella)的营养细胞含38条蛋白谱带,休眠细胞含29条蛋白谱带,两者共有谱带为26条,特有谱带各为12条和3条,相似度为77.6%;休眠细胞的包囊壁含22条蛋白谱带,细胞脱包囊后残留的包囊壁含15条蛋白谱带,两者共有谱带为14条,特有谱带各为8条和1条,相似度为76%。包囊游仆虫(Euplotes encysticus)的营养细胞和休眠细胞均含23条蛋白谱带,两者共有谱带为19条,特有谱带各为4条,相似度为82.6%;休眠细胞的包囊壁和细胞脱包囊后残留的包囊壁均含20条蛋白谱带,两者共有谱带为19条,特有谱带均为1条,相似度为95%。结果表明,两种纤毛虫的营养细胞向休眠细胞转化过程中,细胞结构的主要蛋白质成分发生了明显变化,这些变化与细胞在不同生理状态下结构的分化及其生命活动特征相关。形成“毛基体吸收型包囊”的急纤虫与形成“毛基体非吸收型包囊”的游仆虫相比较,前者营养期和休眠期细胞蛋白组成有更明显的差异,这可能与其细胞结构更大程度的脱分化有关;根据纤毛虫休眠细胞的包囊壁和细胞脱包囊后残留的包囊壁两者蛋白组成的差异推测,前者包囊壁可能含有与休眠细胞生命活动相联系的“活性”成分。     

包囊游仆虫休眠包囊的超微结构研究

包囊游仆虫休眠包囊中,各类纤毛器的纤毛基体上方的大部分纤毛杆退化,或仅保留毛基体,有时部分额腹棘毛的毛基体也瓦解消失。残留纤毛的纤毛杆周围微管和中央微管仍具有“9 2”结构特征,也有少数纤毛杆出现2套“9 2”微管共处于一层纤毛膜内的现象。毛基体中周围三联体微管的中央形成微管形结构聚合体,基体附属结构仅存在基体间连接及纤毛器托架的残余物;非纤毛区皮层表膜下未见微管层。纤毛区皮层含纤毛器腔周围微管层(相当于表膜下微管层)、纤毛器深部及附近的微管束和分散的微管群。并且,纤毛区皮层囊泡内含有呈不同形态的纤毛杆结构;大核核孔明显变大,核孔数目减少,核孔内膜附着染色质。     

不同生理状态下膜状急纤虫大核DNA和线粒体DNA的多态性比较

为探索纤毛虫在营养及休眠条件下两套遗传系统的作用关系,对膜状急纤虫(Tachysomapellionella)营养细胞和休眠包囊大核DNA、线粒体DNA进行了RAPD比较。结果显示,在所选用的34条随机引物中,大核DNA共扩增出203条片段,其中以休眠包囊大核DNA为模板扩增出45条特有片段,以营养细胞大核DNA为模板扩增出36条特有片段,两者存在40%的差异。在所选用的32条随机引物中,线粒体DNA共扩增出216条片段,其中以休眠包囊线粒体DNA为模板扩增出35条特有片段,以营养细胞线粒体DNA为模板扩增出47条特有片段,两者有38%的差异。结果表明,膜状急纤虫休眠包囊与营养期的大核DNA结构存在显著的差异;两者的线粒体DNA结构也存在较大差异。这表明,膜状急纤虫在包囊形成过程中,大核及线粒体DNA结构可能都发生了一定的变化,并且这些变化可能与包囊形成过程中的形态结构和代谢活动等剧烈变化以及休眠状态下的生理生化变化密切相关。     

纤毛虫形成包囊和脱包囊的研究及其意义

原生动物纤毛虫的生活史中,经常涉及到无性生殖或有性生殖过程,这是众所周知的。而除此之外,许多纤毛虫生命活动受到阻碍时,又往往发生形成包囊(encystment)的过程。此封,纤毛虫由活动状态变为静止不动,在细胞团缩并逐渐失去某些结构的同时,分泌物质形成包囊壁(cyst wall),成为圆球形或近圆球形的包囊(cyst)。一旦环境适宜,形成包囊的细胞则会脱包囊(xcystment),恢复正常的活动。     

包囊游仆虫休眠包囊的超微结构研究

包囊游仆虫休眠包囊中,各类纤毛器的纤毛基体上方的大部分纤毛杆退化,或仅保留毛基体,有时部分额腹棘毛的毛基体也瓦解消失。残留纤毛的纤毛杆周围微管和中央微管仍具有“９＋２”结构特征,也有少数纤毛杆出现２套“９＋２”微管共处于一层纤毛膜内的现象。毛基体中周围三联体微管的中央形成微管形结构聚合体,基体附属结构仅存在基体间连接及纤毛器托架的残余物;非纤毛区皮层表膜下未见微管层。纤毛区皮层含纤毛器腔周围微管层     

异毛虫形成包囊过程中细胞皮层及纤毛结构分化的扫描电镜观察

在纤毛虫无性生殖中,生命活动受阻时经常会发生形成包囊的现象。研究纤毛虫的包囊现象,已成为揭示真核细胞的结构与功能、细胞模式形成与控制机理的一个重要方面。目前,对腹毛目纤毛虫中游仆虫类包囊的形态及其生理生化特征已进行了较系统的研究,积累了较多的资料,但对其他类     

体眠期和营养期包裹游仆虫的纤毛器骨架及其微管蛋白

应用光镜和透射电镜术,显示了包囊游仆虫休眠细胞中纤毛器骨架的形态,并对该纤毛虫休眠细胞和营养细胞的纤毛器及其α,β－微管蛋白进行了免疫荧光定位的比较研究。由免疫荧光显微术显示,包囊游仆虫形成休眠包囊后,背部毛基体完整地按原有模式保存下来;纤毛杆解聚后微管蛋白多集中在细胞皮层,小部分均匀散布在细胞质中,据所得结果认为,包囊游仆虫形成包囊后,微管蛋白主要有3个去向,即：91）处于自噬泡内被逐步消失;（2）以“微管蛋白库”的形式分布于细胞皮层及细胞质中;（3）保留在残留的基体中,此外,以往研究中发现的棘毛基部网络未被标记上,提示这些纤维体系可能不属于微管系统。     

Encystment and Excystment of the Heterotrichous Ciliate Blepharisma stoltei Isquith*

SYNOPSIS. The structure and cytochemistry of encystment and excystment of Blepharisma stoltei Isquith are described. The encystment process may be subdivided into 4 stages: (i) in the precystic stage the buccal apparatus overlaps about the posterior, (ii) in early encystment, the buccal apparatus is resorbed and an ectocyst is secreted, (iii) an interwall space, endocyst, and plug are secreted during late encystment, and (iv) the resting cyst stage typically has disc-like structures on the ectocyst, and a vacuole in the macronucleus. In excystment, 6 distinct stages may be defined: (i) partial kineties are formed in early excystment, (ii) permanent kineties give rise to anlagen of the buccal apparatus during stomatogenesis, (iii) the organism elongates and reforms the vegetative shape in late excystment, (iv) some cysts then divide, (v) the redeveloped organism is liberated thru the plug pore, and (vi) the postcystic stage resembles the vegetative form except for its size and lack of pigmentation. Cortical structures, extracellular membranes, and the macronuclear membrane are composed of protein-lipids. Unbound protein and RNA are found in the cytoplasm thruout the cystic cycle. DNA is present only in the nuclei. Polysaccharides, 1st found in the cytoplasm, are shifted to the plug in encystment. The plug material disappears during excystment, while PAS positive granules appear in the cytoplasm.     

Morphological Study of the Encystment and Excystment of Vermamoeba vermiformis Revealed Original Traits

Free‐living amoebae are ubiquitous protozoa commonly found in water. Among them, Acanthamoeba and Vermamoeba (formerly Hartmannella) are the most represented genera. In case of stress, such as nutrient deprivation or osmotic stress, these amoebae initiate a differentiation process, named encystment. It leads to the cyst form, which is a resistant form enabling amoebae to survive in harsh conditions and resist disinfection treatments. Encystment has been thoroughly described in Acanthamoeba but poorly in Vermamoeba. Our study was aimed to follow the encystment/excystment processes by microscopic observations. We show that encystment is quite rapid, as mature cysts were obtained in 9 h, and that cyst wall is composed of two layers. A video shows that a locomotive form is likely involved in clustering cysts together during encystment. As for Acanthamoeba, autophagy is likely active during this process. Specific vesicles, possibly involved in ribophagy, were observed within the cytoplasm. Remarkably, mitochondria rearranged around the nucleus within the cyst, suggesting high needs in energy. Unlike Acanthamoeba and Naegleria, no ostioles were observed in the cyst wall suggesting that excystment is original. During excystment, large vesicles, likely filled with hydrolases, were found in close proximity to cyst wall and digest it. Trophozoite moves inside its cyst wall before exiting during excystment. In conclusion, Vermamoeba encystment/excystment displays original trends as compare to Acanthamoeba.     

海洋浮游纤毛虫包囊的研究进展*

作为微型浮游动物的重要组成部分,海洋浮游纤毛虫是连接微食物环和经典食物链的重要中介。有些浮游纤毛虫在生活周期中会形成包囊,条件适宜时包囊会萌发,这对纤毛虫种群动态有重要的意义。目前国际上对于浮游纤毛虫生态学的研究主要集中在其营养期细胞,浮游纤毛虫包囊的研究尚少,中国还没有这方面的研究。本文对浮游纤毛虫包囊研究进展进行概述,包括包囊的形态、沉积物中包囊的丰度、包囊形成的环境因素、包囊萌发过程及环境因素对包囊萌发的影响等方面,希望对国内开展浮游纤毛虫包囊的研究有所裨益。     

Effects of nitrogen deficiency and light of high intensity onCryptomonas rufescens (Cryptophyceae)

Summary C.rufescens excystment, experimentally induced, corresponds to a general metabolism recovery of the cell, previously in a resting phase. The cytoplasm changes without any polarity, and organelles like gullet and flagella redifferentiate. The thylakoids develop mainly from the stored lipidic compounds which then disappear. Phycoerythrin immediately fills the intrathylakoidal lumen. Pigment synthesis seems closely associated with the development of membranes. The activated cell divides and the cyst wall breaks down. The destruction of the wall begins in the median layer and is followed by a mechanical rupture of the external and internal layers. Each germinative cyst releases two or four fully differentiated cells. There is an exact symmetry between excystment and encystment, all the transformations of theC. rufescens cell being reversible.     

阔口尖毛虫形成包囊期间细胞超微结构的观察

阔口尖毛虫形成囊期间,细胞质内出现条带状或管产产的内质网和由不同大小的囊泡组成的包囊壁前体。并且,前体的产生与内质网有关;细胞质内发生自噬泡消化现象,这是细胞将原有结构和能量进行贮存,利用的一种重要形式;大核向细胞质突出形成阿米巴形结构,这与大核向细胞质排出部分核物质有关。     

DNA-containing polygonal structures detected in somatic nuclei of Bursaria ovata during preparation to cryptobiosis

Supramolecular chromatin organization of the somatic nucleus (macronucleus--Ma) was studied in a free-living unicellular eukaryotic organism, the ciliate Bursaria ovata Beers 1952, at two late successive stages of its encystment (in the state of preparation to cryptobiosis). A modified Miller's method (Sergejeva et al., 1987) and the same technique in combination with high resolution DNA autoradiography were used. In chromatin spread preparations of Ma, not labeled by 3H-thymidine, numerous electron dense structures (rounded, stick-like and polygonal) were revealed, along with rarely occurring typical supramolecular chromatin structures, such as nucleosomic and not nucleosomic threads, nucleomeres, chromomeres, rosette-like looping chromatin, and electron dense chromonemes (Fig. 1). For DNA visualizing in the revealed polygonal structures, the vegetative cells (trophonts) of B. ovata were inoculated into the culture medium, containing 3H-thymidine and food (ciliates Paramecium caudatum). Here, the ciliates passed through 3-4 successive cell division cycles, thus progressively accumulating the radioactive DNA precursor in Ma. After washing the ciliates in 3H-thymidine-free culture medium, the process of their encystment was induced, and Ma were isolated by hand from the ciliates being at two late successive stages of encystment. Isolated Ma were dispersed in the low ionic solutions, as described elsewhere (Sergejeva et al., 1987). The carbon shadowed electron grids, that contained spread Ma preparations, were individually coated with photographic emulsion, according to the loop interference method (Angelier et al., 1976a; Bouteille, 1976). After a 6 month exposure at 4 degrees C, thymidine incorporation was revealed in fibril crowds, rosette-like structures (Fig. 2), and crystal-like plates of different size and morphology (Fig. 3). In all our experiments, non-specific localization of radioactive DNA precursor was not observed. The above data confirm undoubtedly our earlier assumption (Sergejeva et al., 1987; Sergejeva, Bobyleva, 1988) that the Ma chromatin of Bursaria may undergo crystallization during encystment, i.e. in the state of preparation to cryptobiosis. The present data enable us first to suggest that the looping rosette-like chromatin may be transformed into crystal-like structures ("exotic liquid crystal structures") by means of a peculiar loop packing within the limits of an individual resette (Fig. 2-4), these structural transformations taking place without any visible loop destruction. In this paper, we first describe new morphological types of polygonal plates, differing from those earlier reported elsewhere for the Ma of Bursaria (Sergejeva, Bobylova, 1988), and also from the plates earlier described in studies on liquid crystals both in vivo and in vitro (see: Gianonni et al., 1969; Lerman, 1974; Livolant, 1991: Leforestier et al., 1993, 1997, 1999). The technical approaches used in the present work enabled us to obtain, for the first time, a direct evidence of the presence of DNA in the crystallized structures of somatic nuclei of ciliates during their preparation to cryptobiosis, the DNA-containing polygonal structures being highly morphologically diverse. Further studies into the reasons of this diversity are needed.     

Fine Structure of Colpoda steinii During Encystment and Excystment

SYNOPSIS. The encystment and excystment of Colpoda steinii was examined by electron microscopy. Cellular organelles including cilia are retained in the cyst without any fundamental alteration in structure. During encystment, the cell becomes surrounded by 2 coats, the inner of which is the more substanial and regular and is about 1600 A or more thick. It is probably formed in the main from material contained in bodies which have no obvious structure and which may be seen in the cell during cyst formation. Discharging vacuoles containing sheet-like material, probably derived from ingested bacteria, are particularly visible during encystment but probably play no direct role in the formation of the main cyst coat. During excystment, this coat is eroded away and, when it becomes thin enough, the motile cell bursts its way out.