Effects of UV-Radiation on Kinetics of Encystment and on Morphology of Resting Cysts of the Ciliate Laurentiella acuminata1

The effects of ultraviolet radiation (λ= 254 nm) on the kinetics of encystment of the hypotrichous ciliate Laurentiella acuminata and the structure of resting cysts obtained from irradiated precystic cells are reported. High doses of UV-radiation caused a delay of encystment with a linear increase in the average time for obtaining 50% of encystment (EN₅₀). Resting cysts with abnormal cyst walls were obtained when precystic cells were irradiated in the exposure range 720 to 960 J/m². The cystic layer (mesocyst) was approximately twice as thick (6.5 μ m) as normal (3.7 μ m). Microscopical observations of abnormal cysts revealed the presence of two complete mesocysts, and the absence of the spines characteristic of the ectocyst. The UV-dependent effects on the cyst wall were gradually corrected in successive generations of the irradiated cells.     

The Fine Structure of Acanthamoeba astronyxis,with Special Emphasis on Encystment1

ABSTRACT. The fine structure of the trophozoite, encysting cells, and the cyst of Acanthamoeba astronyxis has been examined. In the trophic form a microtubule organizing center was associated with a well developed Golgi complex. During encystment the organelles of the amoeba changed considerably. The profiles of rough endoplasmic reticulum elongated and were often arranged in circles of multilayered concentric systems, enclosing mitochondria, the nucleus, or other inclusions. The mitochondria showed a tendency toward elongation and constriction. One or two nucleolus-like bodies appeared in the nucleus. Lipid droplets increased considerably in amount and were distributed individually or as aggregates. The mature cyst was star-shaped and surrounded by an almost circular exocyst and an endocyst that was closely apposed to the cell membrane. Both walls differed in their thickness and granulation. The exocyst was continuous over the entire cyst, while the endocyst was interrupted by gaps, ostioles. in the region of the rays. Within the ostioles was a bell-shaped structure, the operculum. The latter was composed of a granular material comparable in electron density to that of the endocyst.     

The differentiation of cellular structure during encystment in the soil hypotrichous ciliate Australocirrus cf. australis (Protista,Ciliophora)

Ciliates are able to form resting cysts as a survival strategy in response to stressful environmental factors. Studies on the characteristics of cellular structure during encystment may provide useful information for further understanding of the regulatory mechanism of cellular patterns and supply new clues regarding the phylogeny of ciliates. Scanning and transmission electron microscopies were used to observe the ultrastructure of cells during encystment of the soil ciliate Australocirrus cf. australis. The dedifferentiation of ciliature was revealed for the first time. Ciliary shafts first shortened, and the remaining ciliature, including basal bodies and the fibrillar cirral basket, retracted into the cytoplasm and was surrounded by the autophagic vacuoles and then gradually digested. A large number of autophagic vacuoles were observed in mature resting cysts. Autophagy might not only be necessary for the differentiation of cellular structures during encystment but might also be important to sustain the basic life activities in the resting stage. Australocirrus cf. australis formed a kinetosome-resorbing cyst and contained four layers in the cyst wall: the ectocyst, mesocyst, endocyst and granular layer. The ciliature resorbing state and the number of layers in the cyst wall were consistent with those found in other oxytrichous ciliates. However, the phenomenon wherein the two macronuclear nodules are not fused during encystment is not commonly observed among oxytrichids. Additionally, the octahedral granules in the mesocyst of this species exhibit different morphology from the congeners.     

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.     

Light and Electron Microscopic Observations on Encystment of Acanthamoeba palestinensis, Reich

SYNOPSIS. The ultrastructural changes occurring during encystment of Acanthamoeba palestinensis have been investigated. The cyst wall consists of endocyst and exocyst, both having the same fine structure. At irregular intervals in the cyst wall ostioles occupied by opercula are present. The nuclear membrane forms bulb-shaped projections and releases vesicles bounded by double membranes into the cytoplasm. Dense nucleolus-like bodies of different sizes and variable numbers are found in the nucleus of every cyst. The importance of the cyst structure as a taxonomic criterion is discussed.     

Ultrastructure,encystment and cyst wall composition of the resting cyst of the peritrich ciliate Opisthonecta henneguyi

The cyst wall of Opisthonecta henneguyi has been studied ultrastructurally and cytochemically by light and electron microscopy, as well as by chemical and electrophoretic analyses, to examine the structure of the cyst wall and its composition. The cyst wall consists of four morphologically distinct layers. The ectocyst is a thin dense layer. The mesocyst is the thickest layer and is composed of a compact material. The endocyst is a thin layer like the ectocyst, but less dense. The granular layer varies in thickness and is composed of a granular material. In the resting cyst, kinetosomes of both oral apparatus and trochal band as well as the myoneme system are maintained, and only cilia are resorbed. The sugars present in the cyst wall are predominantly N-acetylglucosamine (90%) and glucose (10%). The mesocyst is composed of chitin, and the endocyst includes glycoproteins and acid mucopolysaccharides. During secretion of the cyst wall, the endocyst and granular layer are secreted from precursors synthesized "de novo". No cytoplasmic precursors of ectocyst and mesocyst have been detected.     

Encystment ofBodo caudatus

Summary Before formation of the cyst wall, the food vacuoles are lost, the cell rounds up and the flagella lie close against the body in a flagellar groove. At this early stage, the contractile vacuole is very active, the Golgi apparatus is prominent and the basophilic cytoplasm is composed of closely packed ribosomes. As the cyst wall is secreted, layer by layer, the large Golgi apparatus is replaced by several smaller membrane stacks and mitochondrial changes occur involving local loss and modification of the cristae. Some parts of the mitochondrion undergo degenerative changes and may become surrounded by bacilliform bodies. These same bodies are also associated with small particles of sequestered cytoplasm which are present throughout the encystment process and are believed to be autophagic vacuoles. As the cyst wall thickens, cell shrinkage is manifest as a number of membrane invaginations. The final cyst wall is of uneven thickness and possesses a single operculum which is visible only by electron microscopy. Probable cyst wall precursor is found in small vesicles scattered throughout the cytoplasm.     

Formation of the Cyst Wall of the Ciliate Colpoda steinii

After a thin membranous envelope surrounding the cell body and cilia of Colpoda steinii has been formed, the main mass of the proteinaceous cyst wall is deposited without exocytosis. It can be composed of two layers, the denser and wrinkled ectocyst and the smooth-walled endocyst; however, the ectocyst may be missing. Evidence is presented that ecto- and endocyst are formed from vesicles derived from abundant rough endoplasmic reticulum which appears at the time of wall formation. The cilia are retained and become embedded in the peripheral cytoplasm. Synthesis of RNA and protein is required as actinomycin C and cycloheximide block cyst formation. Calcium is required during a sensitive phase prior to encystment.     

THE FINE STRUCTURE OF ACANTHAMOEBA CASTELLANII (NEFF STRAIN) : II. Encystment

Encysting cells of Acanthamoeba castellanii, Neff strain, have been examined with the electron microscope. The wall structure and cytoplasmic changes during encystment are described. The cyst wall is composed of two major layers: a laminar, fibrous exocyst with a variable amount of matrix material, and an endocyst of fine fibrils in a granular matrix. The two layers are normally separated by a space except where they form opercula in the center of ostioles (exits for excysting amebae). An additional amorphous layer is probably present between the wall and the protoplast in the mature cyst. Early in encystment the Golgi complex is enlarged and contains a densely staining material that appears to contribute to wall formation. Vacuoles containing cytoplasmic debris (autolysosomes) are present in encysting cells and the contents of some of the vacuoles are deposited in the developing cyst wall. Lamellate bodies develop in the mitochondria and appear in the cytoplasm. Several changes are associated with the mitochondrial intracristate granule. The nucleus releases small buds into the cytoplasm, and the nucleolus decreases to less than half its original volume. The cytoplasm increases in electron density and its volume is reduced by about 80%. The water expulsion vesicle is the only cellular compartment without dense content in the mature cyst. The volume fractions of lipid droplets, Golgi complex, mitochondria, digestive vacuoles, and autolysosomes have been determined at different stages of encystment by stereological analysis of electron micrographs. By chemical analyses, dry weight, protein, phospholipid, and glycogen are lower and neutral lipid is higher in the mature cyst than in the trophozoite.     

The formation of the cyst wall of the metacercaria of Fasciola hepatica L.

Summary The several concentric layers of the cyst wall of Fasciola hepatica are formed from precursors synthesised in the cystogenic cells of the cercaria during its development in the redia. A cinematographic analysis shows that the separate components are released in succession during encystment.The outer portion of the wall consists of two layers: a tanned protein and a carbohydrate-protein complex. The granular precursors of these are formed in separate groups of cells and migrate from these cells into the superficial epithelium (embryonic epithelium) during development. They are released to form the outer wall by the bursting of the embryonic epithelium at the beginning of encystment. This process is rapid and is completed in a few minutes.A pause follows the separation of the outer wall during which a further polysaccharide layer is released and the cells, which contain the rod-like scrolls of sheets of the laminated component of the inner wall, migrate from within the cercaria through gaps in the superficial musculature on to the cercarial surface to form a new epithelium replacing that previously shed.The cercaria now begins a series of complex oscillatory movements within the enveloping outer cyst wall during which the scrolls are secreted into the space underneath the outer wall, unroll and are compacted by the animal's movements into the lamellar inner wall.The rodlets are enclosed in vacuoles and their secretion is effected by the fusion of the vacuolar membrane with the plasma membrane without destroying the integrity of the cells, which remain to constitute the epithelium of the juvenile fluke when this emerges later.     

Identification of Precystic Stages and Encystment Kinetics Analysis of Colpoda inflata by Using an Immunofluorescent Method

ABSTRACT. The application of an immunocytochemical method to identify precystic stages and to analyse the encystment kinetics, by using a polyclonal antiserum against isolated cyst walls from the ciliate Colpoda inflata , is reported for the first time. Three different precystic phases were chosen on the basis of morphological changes and degree of cyst wall formation. By using this procedure a better identification of mature resting cysts with regard to precystic cells or young cysts is provided. An average consensus encystment kinetics of C. inflata , by using an accumulated class frequency analysis, is reported.     

Fine structure of encystment of the quadriflagellate alga,Polytomella agilis

Summary The differentiation of resting cysts of the algaPolytomella agilis was examined by electron microscopy. During encystment the free-swimming, quadriflagellate unicells lose their flagella, sink to the bottom of the culture, and form a thick cell wall. Populations of cells at various stages of encystment were collected on microscope slides placed at the bottom of the culture flasks. The mature cyst wall consists of four layers which are laid down sequentially next to the plasma membrane. Freeze-etching has shown that the first layer of wall deposited consists of fibrils which are formed partly embedded within the plasma membrane. A proliferation of rough endoplasmic reticulum and Golgi bodies is seen in early stages of encystment followed by a reduction in size or number of these organelles and of plastids in the maturing cyst. Microtubular structures, including the basal bodies, dedifferentiate and are not observed in the later stages of encystment. The redifferentiation of the swimming cell during excystment is described in the companion paper.This work was supported by grant A6353 from the National Research Council of Canada to D. L.Brown and by the Inland Waters Directorate of Environment Canada.     

Ultrastructural Changes During Encystment of Schizopyrenus russelli*

Ultrastructural changes associated with the encystment of Schizopyrenus russelli have been studied by electron microscopy. Before encystment small “black bodies” appear in the cytoplasm and later migrate toward the periphery. The outer cyst wall is secreted at this stage as a thin discontinuous layer which thickens and subsequently becomes continuous. Concomitant with this, the endoplasmic reticulum surrounds the mitochondria. The inner cyst wall later appears as a multilayered structure which presumably is cast off from the plasma membrane. Between the inner and outer layers of the cyst wall, there is a middle, less electron-dense layer wherein extruded cytoplasmic material is found embedded at certain places.     

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。     

The Fine Structure of Secretion in Hyalophysa chattoni: Formation of the Attachment Peduncle and the Chitinous Phoretic Cyst Wall

ABSTRACT. The settling tomite stage of the apostome Hyalophysa chattoni secretes a phoretic cyst wall composed of chitin, mucopolysaccharides, and protein. Within 1 1/2 h after settling, an electron-dense proteinaceous cyst layer (the outer layer) is formed from secretions originating at the base of the kineties and from the thick pellicular layer between the kineties. The inner cyst layer, composed primarily of chitin (acidic and neutral polysaccharides are also present), is secreted across the entire cell surface. Cyst wall formation is completed within 6 h. The fine structure of endocyst secretion resembles stages in the secretion of chitin by fungi, yeasts, and arthropods. A proteinaceous attachment peduncle is secreted to anchor the cell to a shrimp host and is formed by the release of electron-dense secretory bodies from the cell's ventral surface.     

EXOCYTOSIS OF LATEX BEADS DURING THE ENCYSTMENT OF ACANTHAMOEBA

Cells of Acanthamoeba castellanii (Neff) are known to form mature cysts characterized by a cellulose-containing cell wall when transferred to a nonnutrient medium. Amebas which engulfed latex beads before encystment formed mature cysts essentially devoid of bead material. The encystment of bead-containing cells appeared to be similar to that of control cells since no important differences between the two were observed with respect to cellular levels of glycogen or protein, cellulose synthetase activity, the amount of cyst wall polysaccharide formed, or the percentage of cysts formed. Actinomycin D and cycloheximide inhibited encystment as well as bead expulsion. Ultrastructural analysis revealed that the beads, which initially were contained in phagocytic vesicles, were released from the cell by fusion of vesicular membranes with the plasma membrane. Exocytosis was observed in cells after 3 hr of encystment, with most of the beads being lost before cyst wall formation. Each bead-containing vesicle involved in expulsion was conspicuously demarcated by an area of concentrated cytoplasm, which was more homogeneously granular than the surrounding cytoplasm. Beads were not observed in the cytoplasm of mature cysts but were occasionally found in the cyst wall.     

Ultrastructure and Description of a Fungus-Feeding Amoeba,Trichamoeba mycophaga n. sp. (Amoebidae,Amoebea), from Australia1

ABSTRACT. An amoeba isolated from a wheatfield and a forest soil in Australia has been identified as Trichamoeba mycophaga n. sp. Trophozoites of this amoeba are palmate to elongate and measure 45–136 μm in length and 25–94 μm in width. Amoebae in continuous locomotion may be limax with a villous-bulb uroid. Both the lobose pseudopodia and the advancing margin of a limax trophozoite bear an ectoplasmic crescent. The plasma membrane is coated with an electron-dense amorphous layer ca. 100 nm thick. Endoplasm is granular with elongate to bipyramidal crystals and contains bacterial endosymbionts. Trophozoites have a single, spherical to oval nucleus, 4–10 μm in diameter, which contains a centrally located, spherical to oval nucleolus, 2.8–5.0 μm in diameter. The nucleoplasm contains aggregations of filaments distributed radially within the nuclear membrane. Cysts are 21–60 μm in diameter, with ecto- and endocyst walls separated by an amorphous layer.     

Evaluation of membrane-bound black bodies in trophozoites and cysts of Naegleria spp

Various Naegleria strains were examined to determine the possible origin and significance of membrane-bound black bodies that were found in all exponentially growing cell populations. The bodies, 40–80 nm in diameter, were distributed randomly in the cytoplasm of Naegleria with ultrastructural features typical of trophozoites. No evidence was obtained that the contents of the black bodies were synthesized in the rough endoplasmic reticulum (ER) and packaged by membranous components, which could be a primitive “Golgi complex” in these amoebae. Examination of cells in various stages of encystment indicated that at least some of the cyst wall material was synthesized and packaged by the rough ER. After condensation into amorphous granules in the cisternae, the cyst wall material appeared in vesicles of the rough ER; these were frequently seen in close proximity to the cell membrane in the vicinity of developing cyst wall. Amorphous granules (～100 nm in diameter), which had variable densities and did not appear to be membrane bound, were seen in the cytoplasm of encysting cells. The substance of these granules also seemed to be incorporated into the cyst wall. The membrane-bound black bodies appeared to be destroyed in lysosomal elements during encystment. The membrane-bound black bodies were concluded to be characteristic of trophozoites and unrelated to encytment of Naegleria.     

DEVELOPMENT AND GERMINATION OF THE AZOTOBACTER CYST

The fine structure of Azotobacter vinelandii has been studied by means of electron microscopy of ultrathin sections made of the encysting and germinating cells. The organisms were fixed with KMnO₄ and embedded in epoxy resin. On an encystment medium the rod-shaped bacteria begin to assume an almost spherical form and then bark-like exine appears in 1½ to 2 days. The exine thickens and an electron permeable intine forms between it and the shrinking cell body. In 5 days the intine makes up more than half of the cyst volume and begins to show a definite two-layered structure. Meanwhile the peripheral bodies, which may be extensions of the cell membrane of the vegetative cell, disappear as the encystment progresses. The cell wall and membrane of the vegetative cell remain demonstrable as the confining structure of the shrinking central body of the mature cyst. In this central body lipoidal globules appear together with aggregations of nuclear material. Cyst germination begins with an increase in the size of the central body at the expense of the intine. The nuclear aggregations become more diffuse and the lipoidal globules disappear. The exine may be pushed outward and the bark-like fragments separate as the emerging vegetative cell develops. Invagination of the cell wall and membrane may occur at this stage leading to cell division. Empty exines remain as horseshoe-shaped structures.