Scale Formation in an Amoeba, Cochliopodium sp.

During excystment of an amoeba, Cochliopodium sp., scale formation was examined with light and electron microscopy. This amoeba was covered with scales. When the amoeba encysted, the scales remained on the external surface of the cyst wall. Soon after the induction of excystment the Golgi complex began to develop. Many vesicles were extruded from it and changed into vacuoles. Scales were observed first in the vacuole adjacent to the Golgi complex and later in inside the cyst wall. When the amoeba excysted it had been coated by the newly formed scales. It is suggested that the scale formation is dependent on the activity of the Golgi complex.     

In vitro excystment of the metacercaria of Maritrema arenaria (Digenea: Microphallidae)

Metacercarial cysts of Mantrema arenaria were subjected to a solution containing trypsin and bile salts at 41°C. This treatment induced intense metacercarial activity and after 15 min metacercariae burst through their cyst walls and emerged. Electron microscopy demonstrated that during the process of excystment the inner layer of the cyst wall changed from a compact to a loose fibrous state. Experiments showed that only cysts containing viable metacercariae underwent this change whereas cysts which had been forcibly vacated before treatment did not. This indicated that the structural change of the inner layer of the cyst wall could not be attributed to the excystment medium. Also there was much less acid phosphatase activity in and on the surface of newly excysted metacercariae compared with encapsulated specimens. It was concluded that the excystment medium induced physical activity in, and the release of enzymic material by, the metacercariae. Together these activities rendered the cyst wall soft and susceptible to rupture by physical pressure.     

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.     

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。     

Fine structure of excystment of the quadriflagellate algaPolytomella agilis

Summary Populations of mature resting cysts of the algaPolytomella agilis were purified from asynchronously encysting cultures and incubated in fresh culture medium to promote excystment. Up to 90 percent of the cysts germinated, with approximately 50 percent excysting between 3 and 7 hours of incubation. Each germinating cyst releases a single, fully differentiated, swimming cell. The entire excystment process of individual cysts was followed by light microscopy to establish the time course of release and cells at comparable stages of excystment were examined by electron microscopy. During the first 3 hours of incubation the cysts increase in size, presumably due to uptake of water, and a polarity is established in the cytoplasm which makes it possible to identify the site of subsequent release. Release involves a selective degradation of a portion of the cyst wall at this site followed by a physical rupturing of the weakened area. Details of the structural alterations in the wall and cytoplasm are described. The cytoplasmic organelles observed to dedifferentiate during encystment (preceding paper) are completely redifferentiated during excystment. The emergent cell is flagellated and possesses the elongate form typical of the swimming cell.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.     

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.     

The Excystment Process in the Ciliate Nassula ornata Ehrbg.

SYNOPSIS. The ciliate was cultured in natural lake water on Oscillatoria curviceps. Encystment was induced by lack of food. The resting cyst has 2 membranes—a faceted, lamellate ectocyst and a thin endocyst. The kinetosomal rows and the cytopharynx are retained in the cyst, and the position of the cytopharynx with respect to the rows remains unchanged. Thus, the usual polarity of the organism is preserved. Distilled water and plant infusions were relatively ineffective excystment-inducing agents, but a 0.1% (w/v) aqueous solution of peptone, pre-inoculated with wild bacteria, was highly effective. At 21 C it induced the excystment of 97% of the cysts within 2-3.5 hr. During excystment, the contractile vacuole enlarges, thereby producing pressure which ruptures the membranes. The ectocyst tears first—always at the posterior end of the cyst—the endocyst somewhat later. Emergence is largely by cytoplasmic streaming through a relatively small slit in the ectocyst, and the posterior end of the ciliate always emerges first.     

Ultrastructure of Cysts of Naegleria spp: A Comparative Study*

SYNOPSIS. Ultrastructure of cysts of Naegleria gruberi, Naegleria fowleri, and Naegleria jadini was compared by transmission electron microscopy. Pores in the cyst wall were observed in all 3 species. In N. gruberi they were surrounded by a collar and sealed with a relatively large mucoid plug; no such collar was seen around the pores in the other 2 species, in which the plug was smaller than that in N. gruberi. An electron-dense plaque serving as an additional pore closure was present in all 3 species. In N. gruberi, the cyst wall consisted of an inner thick and an outer thin layer; however, only the inner component was present in cysts of N. fowleri and N. jadini, which had a smooth appearance. At the ultrastructural level, excystment of N. fowleri involved digestion of the mucoid plug and emergence of the trophozoite through the pore. Some digestion of the cyst wall also appeared to take place during excystment.     

MORPHOLOGICAL CHANGES AND THE REQUIREMENTS FOR MACROMOLECULE SYNTHESIS DURING EXCYSTMENT OF ACANTHAMOEBA CASTELLANII

Light and phase-contrast microscopic observations of excystment in Acanthamoeba castellanii have been used to classify cells in excysting populations as free trophozoites, or mature, activated, or preemergent cysts. These categories have been used to describe the kinetics of excystment. A pH of 7 and a temperature of 30°C have been found to be optimal for the activation of mature cysts. Both activation and emergence are inhibited by cycloheximide and actinomycin D, but neither process is much affected by hydroxyurea. Cell-free extracts of high molecular weight components of cyst cytoplasm can support protein synthesis in vitro, although less efficiently than similar extracts from trophozoites. Evidence indicates that some of the functional RNA in the cyst extracts is synthesized before excystment.     

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。     

ROLE OF ENCYSTMENT AND EXCYSTMENT OF PERIDINIUM BIPES F. OCCULATUM (DINOPHYCEAE) IN FRESH WATER RED TIDES IN LAKE KIZAKI,JAPAN1

The encystment flux of Peridinium bipes f. occulatum (Dinophyceae) was investigated with sediment traps from 1968 to 1990 in Lake Kazki. Cysts of P. bipes were formed throughout the blooms, Encystment flux of P. bipes in the pelagic zone was usually lower than those at shallow sites, and the density of P. bipes cysts in lake sediment was higher in the shallow region than in the pelagic zone. However, in the shallower region, The concentration of P. bipes cysts varied widely, possibly due to high rates of encystment and excystment. Peridinium bipes encystment occurred between 15° and 25° C in the laboratory, with very little cyst formation below 10°C. Though cyst formation was observed in continous darkness, the rate increased with irradiance. Under continuous darkness, no excystment was observed at any temperature from 5° to 25° C. Eighty-one percent of the cysts illuminated at 105 μE m^?2 s^?1 excysted after 13 days incubation at 15° C, and lower irradiances decreased germination success. Results from laboratory experiments suggest that light is a critical factor in the germination of P. bipes cysts. Bottom depth thus can have a significant effect on germination because cysts only can excyst from depths where light is sufficient. The shallow region of the lake is thus very important as a seed bed for P. bipes during early spring. Cyst deposited in deeper waters may not ever germinate unless they are resuspended and transported to shallow areas where light reaches the bottom.     

OBSERVATIONS ON “VAMPYRELLA PENULA-STYLODINIUM SPHAERA” AND THE ULTRASTRUCTURE OF THE REPRODUCTIVE CYST

“Vampyrella-Stylodinium,” an artificial name for a predaceous organism of uncertain taxonomic position, has at least three distinct phases in its life history: the amoeboid phase, both free-floating and attached; the feeding cyst or immobile phase; and flagellated gymnodinoid swarmers. The orange free-floating amoeba has unbranched, filose pseudopodia and several contractile vacuoles. When feeding on the filamentous green alga Oedogonium, the pseudopodia shorten and rearrange. After dissolution of part of the Oedogonium cell wall, the amoeba ingests the host protoplast. Then a stalked reproductive cyst may form. This cyst changes color from green to light orange as it matures. At the time of excystment, the cyst has a smooth outer wall, a spinose inner wall, and a well-delineated phagocytic vacuole. As this vacuole moves from its central position to the cyst's periphery, the walls rupture and 2-4 amoebulae emerge. With TEM observations, the reproductive cyst is shown to be multinucleate. Each nucleus is eukaryotic in organization and possesses one nucleolus. Mitochondria have tubular cristae and no structures unique to the division Pyrrhophyta are observed. Although this stage of the life history does not have a dinokaryotic nucleus, the gymnodinoid swarmers that can emerge from the reproductive cyst, do. Like other parasites which have been assigned to the division Pyrrhophyta, “Vampyrella-Stylodinium” does not conform well to the generalized concept of a dinoflagellate.     

Different excystment patterns in two calcareous cyst-producing species of the dinoflagellate genus Scrippsiella

Scrippsiella rotunda and Scrippsiella trochoidea var. aciculifera (order Peridiniales, subfamily Calciodinelloideae) are autotrophic orthoperidinioid dinoflagellates producing calcareous resting cysts which are at times abundant in coastal marine sediments. We have carried out laboratory experiments to investigate features of cyst germination in the two species, including dormancy length, germination pattern and germination success, over an annual cycle and under different light and temperature conditions. The maturation period for S. rotunda cysts was between 17 and 24 weeks, while that of S. trochoidea var. aciculifera was much shorter, ranging between 2 and 5 weeks. Both species required exposure to light for germination, while temperature shifts (from 14 to 20C) in the dark did not induce excystment of mature cysts. In both species, germination was not synchronous, but distributed over a variable time interval, suggesting a high physiological diversity within the cyst pool. Moreover, exposure to light of S. rotunda cysts that had not completed maturation impaired the germination of a great percentage of the cysts. Differences in dormancy length may partially explain the distinct cyst production patterns observed for the two species in the Gulf of Naples.      

POTENTIAL IMPORTANCE OF BENTHIC CYSTS OF GONYAULAX TAMARENSIS AND G. EXCAVATA IN INITIATING TOXIC DINOFLAGELLATE BLOOMS1,2,3

Thick-walled, nonmotile cysts (termed hypnocysts) of two dinoflagellates were isolated from estuarine sediments in Cape Cod, Massachusetts, and germinated to produce their respective motile, thecate stages. Hypnocysts from Orleans district were identified as Gonyaulax excuvata (Braarud) Balech sensu Loeblich & Loeblich. Visually identical hypnocysts from Falmouth district were provisionally identified as Gonyaulax tamarensis Lebour. Both species were toxic. A geographic survey in September detected hypnocysts in only the sediments of locations where toxic blooms developed the preceding and following Spring. Laboratory incubation (16 C) of hypnocysts from sediment samples stored in the dark (5 C) for 6 mo initiated excystment by the temperature increase, with no appreciable effect from light regime, nutrient, or chelator concentrations. Motility of excysted germlings was optimum in highly chelated medium and in the presence of light. We conclude that hypnocysts of both tasa are important in seeding recurrent annual blooms, synchronizing early bloom development with vernal warning of seawater and increasing the geographic range of the species. We suggest that many red tides in New England and eastern Canadian waters are initiated through the displacement of motile estuarine populations into nearshore area by tidal advection and surface runoff, although the potential existence and importance of offshore cyst reservoirs cannot be discounted. Evidence is presented that hypnocysts are probable sexual zygotes whereas the thin-walled cysts readily formed in laboratory cultures (pellicle cyst) are asexual. Pellicle cysts are of limited durability, do not overwinter in nature, and therefore do not play a significant role in initiating toxic blooms.     

Behavior of Peridinium bipes (Dinophyceae) resting cysts in the Asahi Reservoir

The role of resting cysts includes short- and long-term survival under extreme conditions, bloom initiation, species dispersal, reproduction, and preservation of genetic variation. Accordingly, it is important to understand their behavior in a water environment, especially in lakes and reservoirs where dinoflagellate blooms are observed. In this study, we estimated the behavior of the Peridinium bipes cysts in the Asahi Reservoir using laboratory experiments and field surveys. It was observed that the amount of light strongly influenced excystment, and few cysts germinated under dark conditions in the laboratory experiment. The minimum temperature on excystment was inferred from the laboratory experiment and field surveys to be about 5°C. Although the frequency of excystment did not depend on the water temperature from 10° to 20°C, the average preparation period for excystment decreased with the increase of water temperature. In the Asahi Reservoir, the excystment was estimated to occur during the months of March and April. If excystment did not occur in spring, the dinoflagellate bloom was not be observed until about July, although the bloom often began to appear in about May in the Asahi Reservoir. Consequently, the blooming season in the Asahi Reservoir is affected by the biomass of the germinated cysts in spring. Received: August 31, 2000 / Accepted: March 1, 2001     

Seasonality in the excystment of Alexandrium minutum and Alexandrium tamarense in Irish coastal waters

Excystment experiments were carried out on cysts of Alexandrium minutum and A. tamarense (Group III) taken from Cork Harbour, Ireland. Freshly sampled cysts were isolated into well plates and their excystment was monitored over a 30 day period. A pronounced seasonality was observed in the excystment behaviour in both species when measurements were carried out seasonally. Between 80 and 100% of the isolated cysts excysted within 30 days when samples were taken between March and June. However, between only 0 and 15% excysted in samples taken between August and early February. This seasonal characteristic was observed repeatedly over a 3 year period (2004–2007). The effect was observed in cysts which had been sampled from both inter-tidal and sub-tidal locations. No endogenous clock was evident in the germination of A. tamarense and A. minutum cysts taken from Cork Harbour which had been stored cool and in the dark under anoxic conditions for up to 18 months. The seasonal effect observed was independent of water temperature, although temperature did affect the rate of excystment. Temperature also affected the maturation of cysts which had been freshly formed in the laboratory. The significance of incorporating seasonality in excystment of Alexandrium into models describing its growth is also discussed.     

Scanning electron microscopy of pathogenic and non-pathogenic Naegleria cysts

Scanning electron microscopy of pathogenic and non-pathogenic Naegleria cysts. International journal for Parasitology4: 139–142. Cysts of 4 strains of non-pathogenic Naegleria gruberi and 5 strains of pathogenic Naegleria fowleri were examined in the scanning electron microscope. Excystment of the Naegleria gruberi amoebae occurred via preformed exit pores in the cyst wall. Similar structures were not found in the cysts of Naegleria fowleri, and excystment occurred by rupture of the cyst wall. The sequence of cyst wall rupture is illustrated for one of the pathogenic strains.     

Cysts of Danish Gymnodinium nolleri Ellegaard et Moestrup sp. ined. (Dinophyceae): studies on encystment, excystment and toxicity

Life cycle dynamics of Gymnodinium nolleri Ellegaard et Moestrupsp. ined. were studied under different temperature and nutrientconditions. Five culture strains originating from cysts foundin Danish marine sediments were used for the experiments. Bothencystment and excystment were found to vary with temperature.Maximal encystment occurred at 22–28°C, with no cystsformed below 13°C or above 33°C. Cyst production wasslightly higher under phosphorus limitation than under combinednitrogen and phosphorus limitation. Maximal excystment occurredat 26.5°C with negligible excystment under 11°C andover 35°C. The resting period for cyst maturation was typically3–4 weeks. Cysts produced under both phosphorus and nitrogenlimitation were tested for paralytic shellfish poisoning (PSP)toxins by HPLC, and none were detected. It remains unclear whyvegetative cells of this species have not yet been recordedin plankton samples from Scandinavia, despite the widespreaddistribution of the cysts.     

The Formation and Fate of Tetrahymena patula Cryptostomes

A reliable method for producing reproductive cysts in Tetrahymena patula is described. The procedure involves the isolation of macrostomes without cytopharyngeal pouches in microdrops of distilled water under oil. The study of silver-impregnated specimens has shown that a complex pattern of oral resorption and reformation occurs within the cyst that leads to the formation of a group of small cells with recessed oral apparatuses. These cells, called “cryptostomes,” swim very rapidly on excystment and are incapable of either feeding or reproducing. They are presumably dispersal forms. Oral morphogenesis during the transformation of excysted cryptostomes into microstomes and macrostomes is also described.