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     

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。     

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。     

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     

华美游仆虫细胞微管胞器的直接荧光和免疫荧光标记

应用直接荧光和免疫荧光标记显示,腹毛目纤毛虫华美游仆虫(Euplotes elegans)细胞微管胞器由口围带、波动膜、额腹横棘毛、缘棘毛、尾棘毛、背触毛等纤毛器微管以及纤毛器基部附属微管和非纤毛区皮层微管骨架组成.其中,口围带基部含有小膜托架、小膜附属微管,波动膜基部含有波动膜托架,额腹横棘毛基部含有前纵微管束、后纵微管束、横微管束或放射微管柬,左缘棘毛和尾棘毛基部微管束分化不明显,背纤毛基部含有攻瑰花状的基体周围骨架,这些微管结构与细胞背腹面皮层纵微管与横微管网一起组织成该类纤毛虫的主要皮层细胞骨架.结果表明,游仆虫皮层细胞骨架是以微管为主要成分构建而成的,并且其棘毛基部微管的组成具有与其他类纤毛虫不同的特征;游仆虫间期细胞及形态发生时期纤毛基体或纤毛原基中存在中心蛋白,其可能与纤毛基体结构的维持及基体发生过程中微管的组装有关.     

用非离子去垢剂抽提获得的小游仆虫皮层细胞骨架的构形

由扫描电镜术显示,应用非离子去垢剂抽提获得的小游仆虫(Euplotes grocilis)皮层细胞骨架是由非纤毛区皮层骨架、纤毛器骨架及其附属纤维等构成的三维结构网架。各类细胞骨架以纤维物质为基本成分组成纤维网、纤维层、纤维束和纤维薄片等不同形态单元。其中：非纤毛区皮层骨架以表面纤维网和表膜下纤维层为形态单元位于细胞的外周层;纤毛器骨架中的口围带骨架、口侧膜骨架、额腹横棘毛骨架按各自的分布图式在皮层内定位,成为主要的皮层骨架结构。尽管这些纤毛器骨架显示不同的形态,但却具有相同的建构特征,即都是由纤毛器的毛基体、纤毛器托架和骨架附属纤维相互联系镶嵌在一起形成的相对独立的结构单元。分析推测,游仆虫皮层表面纤维网使细胞表面形成区域化结构,它也可能与细胞表面各部分的联系及其细胞与环境的相互作用有关;纤毛器骨架中各个纤毛器的毛基体复合结构可能对纤毛器托架和骨架附属纤维等起到微管组织中心的作用。     

腹毛目纤毛虫大尾柱虫腹皮层纤毛器基部微管的荧光标记

应用荧光紫杉醇直接荧光标记,显示腹毛目纤毛虫大尾柱虫Urostyla grandis腹皮层纤毛器微管胞器由口围带、波动膜、额腹横棘毛和左、右缘棘毛等纤毛器微管、纤毛器基部附属微管等组成.其中,口围带小膜托架及其相联系的肋壁微管和波动膜基体托架,额棘毛基部前纵微管束、后纵微管束及横棘毛基部前纵微管束,中腹棘毛及左、右缘棘毛基部前纵微管束、后纵微管束和横微管束,是该纤毛虫皮层纤毛器基部的主要附属微管.据结果推测,尽管腹毛目纤毛虫的纤毛器基部微管具有相同的结构成分,但其结构的组成、分化特征、定位和定向、发达程度等均有差异.所得结果为进一步说明纤毛虫细胞皮层纤毛器的形态及其微管建构的多样性提供了新的证据资料.     

鲩肠袋虫超微结构的研究:侧重体表皮层(英文)

对专性寄生于草鱼肠道的鲩肠袋虫的体表皮层精细构造进行了研究。结果显示其体表皮层由表膜和表膜下纤维系统两部分组成。表膜的组分有细胞质膜,膜泡层(包括外膜、膜泡、内膜),表膜微管层;表膜下纤维系统主要是由毛基体及其附属纤维结构:动纤丝,纤毛后微管,Ⅰ、Ⅱ型横微管和咽微丝组成。这部分结构下连一电子致密的微丝层,将细胞外质与内质分隔开来;且在微丝层的内侧胞质中分布有很多电子透明泡。此外,对表膜微管层、Ⅱ型横微管、外—内质间微丝层及电子透明泡进行了肠袋虫的种间比较并对上述各部分结构的生物功能进行了讨论。     

草丛土毛虫皮层纤毛器的微管胞器研究

本文应用FLUTAX直接荧光标记和抗α-微管蛋白抗体免疫荧光标记．显示了土壤纤毛虫草丛土毛虫（Territricha stramenticola）的皮层纤毛器微管胞器．其中纤毛器基部微管按口围带、波动膜、额腹横棘毛、左右缘棘毛、背触毛等纤毛器图式分布和定位,口围带和波动膜基部含小膜微管托架、小膜附属微管和波动膜微管骨架网;额腹横棘毛基部含前纵微管束、后纵微管束和横微管束：左、右缘棘毛基部含前纵微管束、后纵微管束、横微管束及后微管芽;背触毛基部含前纵微管束、后纵微管柬。横棘毛基部含有较发达的横微管束,缘棘毛基部含后微管芽及其横微管束的定位可能具有本种纤毛虫细胞的特异性。纤毛器微管胞器在细胞表膜下分化形成的基部微管及其微管层使细胞的运动纤毛器与强固的微管骨架结构网相联系．其微管胞器的建构可能是细胞对土壤生存环境的一种适应．是细胞运动胞器的功能活动与环境相互作用的结果。形态发生中,老口围带微管是逐步进行更新的：老棘毛微管胞器对新结构的发生和形成具有定位和物质贡献的作用．并且老结构在新结构分化和成熟期间也经历了行使相应的生理功能及逐渐退化和失去功能的过程．     

腹毛目纤毛虫鬃棘尾虫纤毛器基部微管的荧光标记

腹毛目纤毛虫鬃棘尾虫的纤毛器微管骨架由口围带、波动膜、额腹横尾棘毛、左右缘棘毛和背触毛等纤毛器微管和纤毛器基部附属微管等组成,其中口围带基部含小膜托架、小膜后微管、小膜托架微管及小膜托架间的倒"V"形微管连接;波动膜基部形成微管骨架网;额腹横棘毛和左、右缘棘毛基部含前纵微管束、后纵微管束和横微管束,但不同位置的棘毛基部微管发达程度不一样;背触毛基部以纤毛基体为中心向前、后皮层发出前纵微管和后纵微管,形成背皮层微管网.     

Muciliary transport in newt lungs: the ultrastructure of the ciliary apparatus in isolated epithelial sheets and in functional triton-extracted models

High voltage and conventional electron microscopy were used to investigate the ultrastructure of the ciliary apparatus in intact and in Triton-extracted, reactivated sheets of mucociliary epithelium isolated from newt lung. Each long (about 13 microns) ciliary axoneme terminates on a barrel-shaped basal body which is anchored in the apical cytoplasm by a variety of accessory structures. A basal foot is associated with the midpoint of each basal body and acts as a focal point for numerous microtubules (MTs). In many cases MTs can be seen to interconnect the feet of neighbouring basal bodies. Attached to the proximal end of each basal body and extending in a direction opposite the basal foot is a large 'ciliary root'. Each ciliary root is associated with a distinct bundle of 6-7 nm microfilaments which appear to stain with the specific F-actin probe NBD-phallacidin. A single 3-4 microns long striated rootlet inserts into each ciliary root and extends toward the cell nucleus through an extensive network of microfilaments. At the level of the basal plate 'Y-shaped' structures appear to connect each axonemal outer doublet MT to the plasma membrane. All of these ciliary accessory structures are present in the same relationship in Triton-extracted models. Their morphology and distribution indicates that they serve to anchor the cilia in the apical cytoplasm. In addition some of these structures appear to be responsible for maintaining the structural and functional integrity of the ciliary field in the demembranated and reactivated models.     

Etude Ultrastructurale du CiliéKuklikophrya dragescoi gen. n., sp. n.*

SYNOPSIS The cortical infraciliature of Kuklikophrya dragescoi gen. n., sp. n. is composed of double kinetosomes. Each kinetosome has transverse fibers. The anterior transverse fibers are associated with a sheet of dense material and the posterior transverse fibers are directed toward the posterior part of the body. The posterior kinetosome of a pair has only a short protuberance in the position of the kinetosomal fiber. The cortex has a well developed alveolar layer and a thick ecto-endoplasmic boundary. A distinctive characteristic of the buccal ciliature is the circumoral ciliature whose infraciliature is made up of pairs of cilia-bearing kinetosomes. The antero-posterior polarity of the paroral segment is in inverse relationship to that of the remaining ciliature of the organism. The adoral and preoral ciliary organelles consist of 2 rows of kinetosomes, each of which bears postciliary fibers. A frame of nematodesmata surrounds the cytopharynx which is supported by microtubular bands which impart to it a very specific laminated appearance. The “phagoplasm” is formed by “vermicelli”-like vesicles. The micronucleus is found in the perinuclear area of the macronucleus.     

The Fine Structure of the Mature Tomite of Hyalophysa chattoni

SYNOPSIS. The fine structure of the tomite stage of Hyalophysa chattoni was examined with particular attention to its kinetal apparatus. The pellicle, thick and dense compared with that of other ciliates, is formed of three layers. The inner layer is composed of short fibrils oriented perpendicular to the surface. The cytoplasm around the oral passage and beneath falciform field 8 is crowded with dense inclusion bodies of unknown function. Dorsal to the oral passage is the rosette, a disc-shaped organelle subdivided by septa in the form of incomplete radii about a central chamber containing a tuft of cilia. The septa are composed of 3 membranes enclosing a fine layer of cytoplasm. At their inner ends 20 mμ fibers run dorsally and ventrally. Dense clumps of fibrous material line the luminal surface of the septa. Rows of fusiform trichocysts parallel the kineties. The trichocysts are composed of a finely periodic, moderately electron-dense material surrounded by 20 mμ fibrils oriented along the long axis of the trichocyst. Between and below the kinetosomes and the rows of trichocysts are electron-dense vesicles 300 mμ in diameter and bounded by a loose membrane. The large “trichocysts,” the “gros trichocystes” of Chatton and Lwoff, whose appearance heralds the beginnings of trichocystogenesis, prove to be canaliculi opening to the surface. Four separate ciliary membrane systems—the oral ciliature (XYZ), falciform field 8, falciform field 9, and the ogival field—are located on the ventral surface of the tomite. Each differs from the others and from the somatic kineties in the fibrillar organization around its kinetosomes. In the somatic kineties the kinetodesmos is a dense, periodic fiber which is formed of stacks of up to 18 subfibers, each arising from the base of a kinetosome. The kinetosomes are short (300 mμ) and contain dense central granules. In some kineties, alternating between the kinetosomes, are elliptical kinetosome-like structures which do not bear cilia and perhaps provide a reservoir of kinetosomes for future growth of the kinety.     

Somatic kinetics or paroral membrane: which came first in ciliate evolution?

The ciliate species which lack a distinctive oral ciliature are considered to represent an ancestral state in ciliate evolution. Consequently, the somatic kineties composed of kinetids (kinetosomes plus cilia and associated fibrillar systems) are thought to be the ancestral ciliature. Results on stomatogenesis in 'gymnostomial ciliates' have shown that these ciliates probably have evolved from ancestors already equipped with an oral ciliature. Thus instead of the somatic, the oral ciliature may be regarded an ancestral. Based on these ideas a hypothesis on the evolution of the ciliate kinetome (assembly of all kinetids covering the body of a given ciliate) is presented. The first step in the evolution of the kinetome was the formation of a paroral membrane, a compound ciliary organelle lying along the right side of the oral area which historically but falsely is termed membrane. It was composed of kinetosomal dyads (dikinetids), derived from the kinetid of a dinoflagellate-like ancestor. From the beginning the paroral membrane was responsible for locomotion, ingestion and for the formation of a cytopharyngeal tube which the first ciliate probably had inherited from its flagellate ancestor. In the second step a first somatic kinety was formed from the right row of kinetosomes of the paroral membrane as a result of a longitudinal splitting of the paroral membrane and a subsequent migration of the forming kinety to the right into the somatic cortex. To increase the number of somatic kineties this process was repeated until the kinety produced first reached the left border of the oral area. By this step the locomotive and the nutritional functions were differentiated between somatic and oral structures. In a third step the adoral organelles were formed from somatic kinetids left of the oral area. The primitive type of stomatogenesis was a buccokinetal one derived from the mode the flagellate ancestor used to distribute its replicated kinetosomes to the offspring cells (buccokinetal means that at least parts of the oral anlage for the posterior offspring cell has its origin in the parental oral apparatus). This hypothesis, based on comparative studies on ciliate morphogenesis, is corroborated by molecular data from other laboratories.     

The Resorption of Cilia in Cyathodinium piriforme*

SYNOPSIS. The fine structure of the cilium, kinetosome, kinetodesmal fiber, and basal microtubules has been described in Cyathodinium piriforme. The ciliary axoneme is encased in an electron-dense jacket termed the axonemal jacket. This jacket surrounds the axoneme and is found midway between the axoneme and the ciliary membrane when viewed in cross section. Before division or reorganization the cilia are withdrawn into the cell. Intact cilia surrounded by their jackets are found in the cytoplasm during the early phases of retraction. Degradation of the axonemal microtubules precedes the dissolution of the axonemal jacket. Profiles of the jackets are observed after the microtubules have been resorbed. The cilia appear to detach from the kinetosomes. Barren kinetosomes are seen below the cell surface frequently with kinetodesmal fibers still attached. Whether all or some of these barren kinetosomes contribute to the formation of the new ciliary anlage cannot be ascertained.     

A TEM study on pre—excystment cellular structures of Euplotes encysticus

Right before the excystment of an Euplotes encysticus sawtooth-like folds appeared among the pellicle plasmalemma,the inner and outer alveolar membranes were still sticking together,and were not distinguishable.Microtubular layers already formed at the sites beneath the dorsal cortical pellicle corresponding to vegetative cells,but they still proceed to be organized on the ventral structures.Cristae,highly-tangled with tubular-type structures,appeared on the mitochondria,and were morphologically similar to that of vegetative cells.In the cortical ciliatures,such as ciliary shafts,kinetosomes,surrounding fibrillar cirral baskets,and attached structures of ciliatures,etc.,they are different from those in resting cysts which are degenerated or lost.All the ciliature microtubules of ciliary shafts are of the 9 2 pattern,but the microtubule-like structure aggregates at tripletmicrotubule centers of many kinetosmes,are still under various stages of differentiation.Microtubules beneath the kinetosomal rows are of a developmentally elongated stage;crowded chromatins of various shapes and sizes are found in macronucleus,but there are no nuclear pores (formed by nuclear membrane as in resting cysts) on the nuclear membrane where these chromatins attached.     

THE FINE STRUCTURE OF CORTICAL COMPONENTS OF PARAMECIUM MULTIMICRONUCLEATUM

The electron microscope was used to study the structure and three dimensional relationships of the components of the body cortex in thin sections of Paramecium multimicronucleatum. Micrographs of sections show that the cortex is covered externally by two closely apposed membranes (together ~250 A thick) constituting the pellicle. Beneath the pellicle the surface of the animal is molded into ridges that form a polygonal ridgework with depressed centers. It is these ridges that give the surface of the organism its characteristic configuration and correspond to the outer fibrillar system of the light microscope image. The outer ends of the trichocysts with their hood-shaped caps are located in the centers of the anterior and posterior ridges of each polygon. The cilia extend singly from the depressed centers of the surface polygons. Each cilium shows two axial filaments with 9 peripheral and parallel filaments embedded in a matrix and the whole surrouned by a thin ciliary membrane. The 9 peripheral filaments are double and these are evenly spaced in a circle around the central pair. The ciliary membrane is continuous with the outer member of the pellicular membrane, whereas the plasma membrane is continuous with the inner member of the pellicular membrane. At the level of the plasma membrane the proximal end of the cilium is continuous with its tube-shaped basal body or kinetosome. The peripheral filaments of the cilium, together with the material of cortical matrix which tends to condense around them, form the sheath of the basal body. The kinetodesma connecting the ciliary kinetosomes (inner fibrillar system of the light microscopist) is composed of a number of discrete fibrils which overlap in a shingle-like fashion. Each striated kinetosomal fibril originates from a ciliary kinetosome and runs parallel to other kinetosomal fibrils arising from posterior kinetosomes of a particular meridional array. Sections at the level of the ciliary kinetosomes reveal an additional fiber system, the infraciliary lattice system, which is separate and distinct from the kinetodesmal system. This system consists of a fibrous network of irregular polygons and runs roughly parallel to the surface of the animal. Mitochondria have a fine structure similar in general features to that described for a number of mammalian cell types, but different in certain details. The structures corresponding to cristae mitochondriales appear as finger-like projections or microvilli extending into the matrix of the organelle from the inner membrane of the paired mitochondrial membrane. The cortical cytoplasm contains also a particulate component and a system of vesicles respectively comparable to the nucleoprotein particles and to the endoplasmic reticulum described in various metazoan cell types. An accessory kinetosome has been observed in oblique sections of a number of non-dividing specimens slightly removed from the ciliary kinetosome and on the same meridional line as the cilia and trichocysts. Its position corresponds to the location of the kinetosome of the newly formed cilium in animals selected as being in the approaching fission stage of the life cycle.     

Ciliated band structure in planktotrophic and lecithotrophic larvae of Heliocidaris species (Echinodermata: Echinoidea): a demonstration of conservation and change

The evolution of lecithotrophic (non-feeding) development in sea urchins is associated with reduction or loss of structures found in the planktotrophic (feeding) echinopluteus larvae. Reductions or losses of larval feeding structures include pluteal arms, their supporting skeleton and the ciliated band that borders them. The barrel-shaped lecithotrophic larva of Heliocidaris erythrogramma has, at its posterior end, two or three ciliated band segments comprised of densely packed, elongate cilia. These cilia may be expressions of the epaulettes that would have been present in an ancestral larval form, represented today by the feeding echinopluteus of H. tuberculata . We compared the development and cellular organization of the larval ciliary structures of both Heliocidaris species to assess whether the ciliary bands of H. erythrogramma are expressions of the feeding ciliated band or epaulettes of an echinopluteus. Epaulette development in feeding larvae of H. tuberculata involves separation of specific parts of the ciliated band from the rest of the feeding ciliated band, hyperplastic addition of ciliated cells and hypertrophic growth of the cilia. Like epaulettes, the ciliated bands of H. erythrogramma are composed of long spindle-shaped cells arranged in a cup-shaped collection that bulges into the blastocoel; and these cells have elongated cilia. In their developmental origin and topological arrangement however, the ciliated bands of H. erythrogramma correspond more closely with parts of the pluteal feeding ciliated band than with epaulettes. The larvae of this echinoid appear to develop epaulette-like bands from parts of the original (but reduced) feeding ciliated band. The evolution of development in H. erythrogramma has thus involved both conservation and change in echinopluteal ciliary structures.     

Some Observations on the Morphology and Division of Balantidium coli and Balantidium caviae (?)

SYNOPSIS. Studies of the body ciliature of Balantidium coli and B. caviae (?) after Breslau's opal-blue and Klein's silver nitrate techniques revealed a preoral-dorsal suture area where some of the ciliary rows fail to reach the peristomial margin. The incomplete kineties ranged up to a dozen in number and were variable in arrangement. In a count of 100 specimens of B. caviae (?) the incomplete kineties were at the right of the suture in 39, at the left in 24 and on both sides of the suture line in 37. At the posterior end not many kineties reach the pole but no sutural pattern was seen in that region. Scattered irregularities in the ciliary rows were sometimes seen.
Studies of the oral region tend to confirm the view of Fauré-Fremiet that the peristomial ciliature consists of short rows of cilia which are continuations of the anterior body kineties. Membranelles were not found. Thus, some species of Balantidium , at least, show affinities with the Holotricha in agreement with Nie and Fauré-Fremiet.
Fission commonly produces two equal-sized daughters but many cases of unequal division were observed. In both these species conjugants are much smaller than vegetative animals and two preconjugant divisions are indicated, the first of which may be unequal.
During the early stages of fission, the anterior ends of the kineties of the posterior daughter change direction, becoming oblique in the fission zone. In this region the kinetosomes multiply; possibly some of the kineties also divide but evidence for this is incomplete. No evidence of reorganization at the anterior end of the anterior daughter was seen.
Attempts to infect hamsters with B. coli and B. caviae (?) failed. No parasites were found in two collared peccaries repeatedly examined.