An Ultrastructural Study of Eimeria iroquoina Molnar & Fernando, 1974 in Experimentally Infected Fathead Minnows (Pimephales promelas,Cyprinidae) 3. Merogony1

Fathead minnows, Pimephales promelas, raised from eggs in the laboratory, were experimentally infected with oocysts of Eimeria iroquoina from either P. promelas or the common shiner, Notropis cornutus. Within intestinal epithelial cells, trophozoites thought to be derived from the sporozoites contained a prominent electron-dense refractile body. Merozoites dedifferentiated into trophic forms by losing components of their apical complex and pellicle. The inner membrane components of the pellicle appeared discontinuous, and the micronemes became enclosed within vacuoles. Prior to merozoite formation, multinucleate meronts were limited by a single membrane. Golgi complexes were associated with the nuclei of this stage. Merozoites were formed by ectomerogony in one generation and by endomerogony in the final generation. In both forms of merogony the final nuclear division was coupled with the onset of differentiation of the merozoites and featured eccentric mitotic spindles associated with centrocones located within the nuclear envelope and with the precursors of the apical complex. A Golgi complex was closely associated with the nucleus and apical tip of the forming merozoite. Unlike other Eimeria species, the complete pellicle of the merozoites of the final asexual generation of E. iroquoina was formed within the cytoplasm of the meront, without association with the limiting membrane, thus, all pellicular components are synthesized de novo. The inner membranes of the pellicle initially appeared as longitudinal strips, each of which was associated with a pair of the 22–24 subpellicular microtubules. Mature meronts of the final asexual generation averaged 9 μm in diameter and produced 13–16 merozoites. With the exception of the internal completion of the pellicle of the final generation merozoites, the basic processes of merogony in fish Eimeria species are similar to those recorded in terrestrial hosts.     

Light optical and electron microscopic study of the cystic stages in Sarcocystis fusiformis from the buffalo

Three different cell types are distinguished in the sarcocysts of Sarcocystis fusiformis from the water buffalo: metrocytes, intermediate cells, and merozoites. The former lines the cyst near the border, the two latter lie more inside forming groups of cells separated from each other by septae. The pattern of metrocyte division giving rise to another metrocyte population has not been observed, still remaining obscure. Merozoites do not divide asexually due to their gamont nature to be realized in the final host only. The intermediate cells divide asexually by endodyogeny giving rise, on the one hand, to another population of intermediate cells, and on the other--to merozoites which divide no longer. Cytophotometrical measurements (G. D. Gaibova, 1987) revealed the amounts of DNA per cell nucleus within 1 and 2 c. This quantity corresponds to the stable DNA content in the most numerous population of merozoites (gamonts), whereas the amount between those higher than 1 c and 2 c may be attributed to the nuclei of metrocytes and intermediate cells, respectively.     

Electron microscopic research on Cryptosporidium. I. The asexual stages in the development of Cryptosporidium parvum

Ultrastructural studies were conducted on asexual developmental stages of C. parvum in the ileal fragment of the intestine of 10-11 day old rats experimentally infected with oocysts isolated from calf feces. A young trophozoite is covered with the typical trimembranous apicomplexan pellicle. As the parasite grows, the inner complex of its apical pellicle, facing the host enterocyte, is seen to reduce up to a unit membrane to make a complex multimembranous "feeding organelle" which is in contact with a thick electron dense band bordering the host-parasite interface. It looks likely that no micropores or any other feeding structures exist in the parasite. Unlike, the opposite body part of the trophozoite, facing the lumen of the intestine, preserves its trimembranous pellicle. Two merozoite generations were followed. In addition to numerous ribosomes, rhoptries, micronemes, and trimembranous pellicle, subpellicular microtubules were observed in the segmenting merozoites. The merogony follows the pattern of ectomeric schizogony. However, no details of nuclear division were detected. The whole cytoplasm of the mother meront is completely used up for the merozoite formation without any residual mass to be left.     

Fine Structure of Gametogony and Oocyst Formation in Sarcocystis sp. in Cell Culture

Fine structure of gametocytes and oocyst formation of Sarcocystis sp. from Quiscalus quiscula Linnaeus grown in cultured embryonic bovine kidney cells was studied. Microgametocytes measured up to ～5 μm diameter. During nuclear division of the microgametocyte, dense plaques were found adjacent to the nucleus just beneath the pellicle; occasionally microtubules were present within these plaques. These microtubules subsequently formed 2 basal bodies with a bundle of 4 microtubules between them. Microgametocytes also contained numerous mitochondria, micropores, granules, vacuoles, and free ribosomes. Each microgamete was covered by a single membrane and consisted of 2 basal bodies, 2 flagella, a bundle of 4 microtubules, a perforatorium, a mitochondrion, and a long dense nucleus which extended anteriorly and posteriorly beyond the mitochondrion. The bundle of 4 microtubules is thought to be the rudiment of a 3rd flagellum. Macrogametes were covered by a double membrane pellicle, and contained a large nucleus (～2.5 μm), vacuoles, and a dilated nuclear envelope connected with the rough endoplasmic reticulum (ER). In young macrogametes (～4 μm), the ER was arranged in concentric rows in the cortical region, and several sizes of dense granules were found in the cytoplasm. However, in later stages (～8 μm) the ER was irregularly arranged and was dilated with numerous cisternae; only large dark granules remained and a few scattered polysaccharide granules were found. No Golgi apparatus or micropores were observed. After the disappearance of dark granules 5 concentric membranes appeared. Four of these fused to form an oocyst wall composed of a dense outer layer (～66 nm thick) and a thin inner layer (～7 nm). The 5th or innermost membrane surrounded the cytoplasmic mass which was covered by a 2-layered pellicle and contained a nucleus, small amounts of ER, large vacuoles, and mitochondria. The sexual stages described greatly resemble those of Eimeria and Toxoplasma.     

Ultrastructure of Cryptosporidium wrairi from the Guinea Pig

SYNOPSIS. The ultrastructure of the known tissue stages of Cryptosporidium wrairi Vetterling, Jervis, Merrill, and Sprinz, 1971 parasitizing the ileum of guinea pigs is described. Young trophozoites are surrounded by 4 unit membranes, the outer 2 of host origin, the inner 2 the pellicle of the parasite. Each trophozoite contains a vesicular nucleus with a large nucleolus. Its cytoplasm contains ribosomes, but eventually fills with cisternae of the rough endoplasmic reticulum. As the trophozoite matures the area of attachment of the parasite to the host cell becomes vacuolated, with vertical membranous folds. It is apparent that the parasite acquires nourishment from the host cell thru this area of attachment. As schizonts develop, (a) multiple nuclei appear, (b) the endoplasmic reticulum enlarges, (c) the attachment zone increases in area, (d) large vacuoles, which develop as endocytotic vesicles in the attachment area, are found in the cytoplasm and (e) the inner unit membrane of the parasite pellicle is resorbed around the sides of the developing schizont. Following nuclear division, merozoites develop from the schizont by budding. Merozoites have an ultrastructure similar to that described for other coccidia except that no mitochondria, micropores, or subpellicular tubules were observed. Merozoites penetrate the epithelial cell causing invagination of the microvillar membrane and lysing it. No unit membrane is formed between the parasite and the host cell. However, the cell produces one or 2 dense bands adjacent to the parasite attachment area. The macrogamete contains a nucleus, endoplasmic reticulum, attachment zone, and large vacuoles. It also contains a variety of granules, some of which are polysaccharide. The immature microgametocyte contains multiple compact nuclei. No mature microgametocytes or zygotes were found.     

Microsporogenesis,Megasporogenesis and the Formation of Male and Female Gametophyte in Coix lacryma-jobi L.

The development of the anther wall follows the monocotyledonous type. During meiotic stages of prophase I, some cytoplasmic channels are observed on the walls between meiotic cells. which divide synchronously. Cytokinesis in the microspore mother cell is of the successive type and gives rise to iscbilateral tetrad. The cell wall between the generative cell and the vegetative cell in early stage shows PAS positive reaction. The mature pollen grain is of 3-celled type. The development of the female gametophyte follows the polygonum-type; the antipodal cells proliferate to form a multicellular tissue mass. Many starch grains are present in the central cell. The nucleus of the mature egg cell is located at the micropylar end; a great deal of starch grains are in the cytoplasm surrounding the nucleus, while vacuoles of various size distribute throughout its cytoplasm but are more and larger at the chalaza,1 end. The nucleus of the synergid cell is located at the micropytar end where a filiform apparatus is formed and many small vacuoles are present at the chalazal part.     

Light optical and electron microscopy research on the cyst-forming coccidium Sarcocystis muris

Part of the complicated life cycle of Sarcocystis muris, confined to the muscle cyst (sarcocyst), has been studied by light and electron microscopy. The early development of the sarcocyst proceeds strictly intracellularly, whereas the older and larger cysts tend to destroy the harbouring muscle cell, and since then their development seems to be intercellular rather than intracellular. Three different cell types are distinguished within the growing sarcocyst of S. muris differing from each other both structurally and functionally: metrocytes, intermediate cells and merozoites. These differ as well in the structure of their nuclei. The metrocyte nuclear chromatin is mainly in decondensed state with some minute granules taking the central part of the nucleus. The condensed chromatin of the intermediate cell is accumulated into some relatively large peripheral granules, whereas numerous RNP-granules appear in the karyolymph. The nuclear chromatin of merozoites is condensed to be seen as separate chromocenters scattered over the nucleus; the karyolymph is packed with RNP-granules. Metrocytes are seen to divide in young sarcocysts, although the mode of their division is still obscure. In sarcocysts of advanced age (2.5 months or more), only intermediate cells are seen to divide, their mode of division being endodyogeny.     

Ontogenesis of Tannin Coenocytes in Sambucus racemosa L. II. Mother Tannin Cells

Tannin coenocytes develop from mononucleate tannin mother cells.The process occurs within the whole of the first (youngest)internode and its development can be divided into three stages.In stage I the MTC is isodiametric and similar to the surroundingcells of the flank meristem, being present in the ninth celllayer from the apex surface. The nucleus becomes lanceolateand elongates, and large cytoplasmic vacuoles appear. A twofoldelongation of both the cell and nucleus continues in the secondstage, the cell-nucleus ratio indicating that it is due to theenlarged vacuole, which pushes a thin layer of cytoplasm closeto the cell wall. In this layer of cytoplasm dilated ER cisternaoccur together with small and large vacuoles, a fusion of thevacuoles increasing their volume. Such cells are diploid inspite of larger nuclear volume and rough structure of its chromatin. Sambucus racemosa L., tannin cells, development, ontogenesis     

The Fine Structure of the Macrogametocytes of Adelina tribolii Bhatia, 1937 (Eucoccidia, Telosporea) from the Fat Body of the Beetle Tribolium castaneum Hbst.

SYNOPSIS. Macrogametocytes of the coccidium Adelina tribolii Bhatia, 1937 are described from the time when they settle in the fat body of the host and form periparasitic vacuoles around them to the stage of microgametocyte occurrence and the beginning of syzygy formation.
The macrogametocyte is surrounded by a 2-layered pellicle 50 mμ thick. Its continuity is interrupted by one or several micropores 40 mμ across and 86 mμ deep.
The cytoplasm of the parasite contains numerous vesicles and lamellae of rough and smooth endoplasmic reticulum. Mitochondria of various sizes have short tubules. The macrogametocyte contains a variable number of dark bodies 1.4-2.4 μ in diameter. It also contains several vacuoles up to 1.2 μ which are covered with a 3-layered membrane and enclose a granular material.
In old macrogametocytes in syzygy multivesicular bodies develop which measure up to 2.4 by 1.6 μ. Several smaller vacuoles containing granular material are also a constituent of the electrondense basic substance of these corpuscles.
Paraglycogen granules 1.4 by 0.9 A occur in old macrogametocytes and are situated inside the vacuoles which are not bordered by a membrane. The numbers and size of these granules increase with the age of the parasite. The Golgi complex lies close to the nucleus.
The nucleus, 6-8.5 μ in diameter, is in the center of the macrogametocyte and contains a large eccentric nucleolus. The nuclear membrane is 2-layered and has many pores.     

Light and electron microscopy on the sporulation of the oocysts of Eimeria brunetti. II. Development into the sporocyst and formation of the sporozoite

The later stages of sporulation in oocysts of Eimeria brunetti were examined in samples which had been allowed to sporulate at 27 degrees C for 24, 36 and 48 hours. It was observed that the sporoblasts became ellipsoidal and the nucleus underwent the final division. A nucleus with associated Golgi bodies was not observed at either end of the organism. The cytoplasm was limited by two unit membranes and contained rough endoplasmic reticulum, dense bodies, electron translucent vacuoles and mitochondria. The first evidence of sporozoite formation was the appearance of a dense plaque at either end of the organism. This appeared in the vicinity of the nuclei, and adjacent to the limiting membrane of the soroblast. At this stage the sporocyst wall was still unformed. Then the two sporozoites were formed from opposite ends of the organism by growth of the dense plaques and invaginations of the plasmalemma which thus formed the pellicles of the developing sporozoites. A conoid and subpellicular microtubules were observed at this stage as development continued, a number of vacuoles were found between the nucleus and the conoid. These vacuoles constituted the precursors of the rhoptries and micronemes. At the same stage a large dense body had appeared within the forming sporozoite. As the sporozoite developed, this body, anterior refractile body, is followed by the nucleus and another dense body which formed the posterior refractile body. During this period, the thin sporocyst wall was formed and Stieda and sub-Stieda bodies were now present at one end of the sporocyst. Each mature sporocyst contained two sporozoites.     

Distribution of actin and tropomyosin in Cryptosporidium muris

Actin and tropomyosin of Cryptosporidium muris were localized by immunogold labeling. Two kinds of antibodies for actin labeling were used. The polyclonal antibody to skeletal muscle (chicken back muscle) actin was labeled on the pellicle and cytoplasmic vacuoles of parasites. The feeder organelle has showed a small amount of polyclonal actin antibody labeling as well. Whereas the monoclonal antibody to smooth muscle (chicken gizzard muscle) actin was chiefly labeled on the filamentous cytoplasm of parasites. The apical portion of host gastric epithelial cell cytoplasm was also labeled by smooth muscle actin together. The polyclonal antibody to tropomyosin was much more labeled at C. muris than host cells, so it could be easily identified even with low magnification (×2,000). The tropomyosin was observed along the pellicle, cytoplasmic vacuoles, and around the nucleus also. The skeletal muscle type actin seems to play a role in various cellular functions with tropomyosin in C. muris; on the other hand, the smooth muscle type actin was located mainly on the filamentous cytoplasm and supported the parasites'' firm attachment to host cells. Tropomyosin on the pellicle was thought to be able to stimulate the host as a major antigen through continuous shedding out by the escape of sporozoites or merozoites from their mother cells.     

The ultrastructure of the rabbit oocyte at the bilaminar follicle stage]

The electron microscope study of the nucleus and organoids of the rabbit oocytes cytoplasm during growth showed nucleoluslike bodies (RNP-granules) on the lampbrushen chromosomes to reach their maximal size at the stage of bilaminar follicle. The RNP-granules differ from the nucleoli by the time of their occurrence cytochemical characteristics, and by their ultrastructural pattern. Throughout the bilaminar follicle stage four components may be seen in the oocyte nucleolus: a dense fibrillar framework around the vacuoles, islets of the granular mass loosely dispersed, and electron dense fibrillar elements filling up the numberous electrontransparant vacuoles. The nucleolus-like bodies are round in shape and have no vacuoles, consisting to two components only: distinctly outlined granules, and weakly developed fibrillar component. The nuclear envelope is seen blebbing. Separation of two nuclear membranes forms a pocket-like enlargements of the perinuclear space. The pockets are limited by small regions between the adjacent nuclear pores. The outer membrane may bulge producing lacuma and large channels in the cytoplasm, which are interconnected making a closed branched network extending inside of the cytoplasm. The nuclear envelope is suggested to be involved in formation of the endoplasmic reticulum through the blebbing process.     

Pelargonium embryogenesis: cytological investigations of organelles in early embryogenesis from the egg to the two-celled embryo

. Changes in the distribution of organelles and organelle-DNA in Pelargonium zonale from the mature egg cell stage to the first zygotic division during the early stages of embryogenesis were investigated using electron microscopy and fluorescence microscopy. The mature egg is a large, polarized bulbous-shaped cell, tapering toward its micropylar end. The wide chalazal region has a large nucleus that is surrounded by cytoplasm containing many giant mitochondria and large amyloplasts. The mitochondria contain a large amount of mitochondrial DNA and appear as long stretched rods or complex rings, sometimes consisting of several concentric or half-concentric circles in sections. The time from pollination to cell fusion is approximately 6-9 h and it is 20-24 h until the first zygotic division. The changes in the zygote and its organelles preparatory to division occur in 3 stages. At stage 1 (6-9 h after pollination), cell fusion occurs and the zygote begins to elongate. Many vacuoles of varying size appear surrounding the nucleus. At stage 2 (9-15 h), the zygote nucleus migrates to a central position in the cell and the mitochondria form a single ring that becomes either irregularly crushed or appears as long thin strings. Amyloplasts exhibit a gradual decrease in the number of starch grains. At stage 3 (15-20 h), the vacuoles disappear, except for a few that remain in the micropylar region, and cell size decreases. Mitochondria become short, fine strings or small rings. Amyloplasts with starch grains are no longer observed, but are transformed into large proplastids. Following the first division of the zygote, approximately equal-sized apical and basal cells are formed. Short rod-shaped or small ring-shaped mitochondria are randomly distributed near the nucleus of the apical cell, whereas mitochondria in the basal cell are long and rod-shaped. In the electron microscope, two types of plastids can be distinguished: dark oval plastids originating from the sperm cell, which are observed in both the apical and basal cell, and others with a less dense, amorphous matrix, believed to originate from egg amyloplasts, which are unevenly distributed in the micropylar region of the basal cell. Fluorometry using a video-intensified microscope photon counting system reveals that, correlated with changes in mitochondrial morphology, DNA amount within the mitochondrion decreases linearly during these stages.     

Observations on the Neocytoplasm and Proteid Vacuoles During the Fertilization of Keteleeria evelyniana

Distributions and dynamics of the neocytoplasm and proteid vacuoles during the fertilization of Keteleeria evelyniana were studied by histochemical methods. Before fertilization cytoplasmic sheath surrounding the male and female gametes was indistinct. After fertilization, the dense neocytoplasm appeared around the zygote. Part of the neocytoplasm is invaded by mitochondria of maternal origin which had collected in large numbers in the perinuclear zone. The mitochondria contain electron compact little body which looks like a nucleus in the cytoplasm, but not observed in the rosette tier cell of proembryo and jacket cells. Hence, it was showed that the neocytoplasm participated in the development of embryo by all these observations. By using Feulgen reaction, the staining reaction of neocytoplasm was positive, the egg nucleus or zygote nucleus was weaker in positive reaction, while the proteid vacuoles were negative. When the proembryo developed, there were a few starch grains accumulated in the other three tiers except the upper tier. The Feulgen reaction was in- creased in intensity in the suspensor tier and embryonal cell tier nuclei. When the young embryo developed, Feulgen reaction became normal in the nuclei of the embryo initials. The embryo initials and Suspensor cells showed very weak Feulgen positive reaetion in the proembryo and young embryo. The development of the large proteid vacuoles was from plastid. During the early stage of egg nucleus, contents of large proteid vacuoles were less. When the zygote was formed, they reached the highest. However, after the zygote produced, the proteid vacuoles and egg cytoplasm were getting disintegrated following the course of fission of free nuclei. After the proembryo formed, the proteid vacuoles were wholly disintegrated.     

Nuclear functions in postconjugational development of Paramecium caudatum: Ability to form food vacuoles analyzed by nuclear elimination and implantation

Paramecium caudatum loses the ability to form food vacuoles at the crescent stage of the micronucleus from 5 to 6 hr after the initiation of conjugation and regains it immediately after the third division of the zygotic nucleus. To assess the micronuclear function in the development of the oral apparatus after coniugation, prezygotic micronuclei was removed from cells at various stages of conjugation, and their ability to form food vacuoles were examined. (1) When all of the prezygotic micronuclear derivatives were eliminated before the stage of formation of the zygotic nucleus, the exconjugant did not regain its ability. (2) When a zygotic nucleus or postzygotic nuclei were removed, in some cases the cell formed as many food vacuoles as did nonoperated cells after conjugation, while in other operated cells the number of food vacuoles was subnormal. (3) When a micronucleus from a cell at vegetative phase (G1) was transplanted into a cell of an amicronucleate mating pair at the stage between 8 and 9 hr after the initiation of conjugation, the implanted cell regained the ability to form food vacuoles. However, no cell regained the ability when the implantation was carried out within 1 hr after the separation of the mates. The results show that the micronucleus plays an indispensable role in the development of the oral apparatus at the stages of exchange of gametic nuclei and fertilization and that the micronucleus transplanted from asexual cells can fulfill this function. On the other hand, removal of the macronucleus from exconjugants showed that the maternal macronucleus also has an indispensable function in regaining the ability to form food Vacuoles. © 1992 Wiley-Liss, Inc.     

An Ultrastructural Study of the Hemocytes of the Pericardial Body in the Ascidian Ciona intestinalis (L.)

Abstract The hemocytes of the pericardial body of Ciona intestinalis were studied by electron microscopy. Our findings showed that stem cells, clear vesicular granulocytes, microgranulocytes, unilocular granulocytes and globular granulocytes are present at the periphery of the smaller-sized pericardial bodies. The stem cells are small round cells with a large nucleus, with or without nucleolus, and homogeneous cytoplasm containing numerous ribosomes. The clear vesicular granulocytes are characterized by an ameboid shape and cytoplasm containing several large electron-lucent vacuoles and small electron-dense granules. The microgranulocytes are variable in shape and contain numerous large electron-dense granules. The unilocular granulocytes show a single large vacuole with an electron-dense or electron-lucent content and a thin layer of peripheral cytoplasm that contains the flattened nucleus. The globular granulocytes are characterized by the presence of large vacuoles containing either fibrogranular material or electron-dense aggregates.     

莴苣卵细胞、合子与原胚细胞中钙的分布

用焦锑酸盐沉淀法对莴苣开花前后的卵细胞、合子与原胚细胞中的钙颗粒分布变化进行了观察。结果表明,开花前三天,刚形成的卵细胞内钙颗粒很少,开花前二天的卵细胞内钙颗粒开始增多,开花前一天的卵细胞形成了大液泡,建立了极性,细胞内的钙颗粒又减少。开花后、受精前的卵细胞的钙颗粒主要聚集在细胞核中。受精后合子中的钙颗粒又明显增多,在核质中分布一些较大的钙颗粒,在珠孔端大液泡中聚集了较多的絮状钙。二胞原胚中的钙颗粒又开始减少,多胞原胚细胞中的钙进一步减少,但原胚表面分布一层丰富的钙颗粒。探讨了钙在卵细胞分化成熟、受精以及原胚发育初期中的作用。     

CAPSELLA EMBRYOGENESIS: THE EGG,ZYGOTE, AND YOUNG EMBRYO

The ultrastructure and composition of the egg, zygote, and young embryo of Capsella bursa-pastoris were examined. The egg is a highly polarized cell; one-half to one-third of the micropylar end is filled with a large vacuole while the chalazal end contains the nucleus and much of the cytoplasm of the cell. The wall which surrounds the cell is incomplete at the chalazal end. Ribosomes fill the cytoplasm and show little or no aggregation into polysomes. The structure of the nucleolus suggests that ribosomes are not being produced. Following fertilization and the formation of the zygote, the cell decreases slightly in volume as the large central vacuole becomes smaller. The zygote soon increases in size as the small chalazal vacuoles present before fertilization begin to enlarge. The dictyosomes become active and a continuous wall forms around the zygote. Aggregation of the ribosomes begins and numerous polysomes are formed. Before division of the zygote all plasmodesmata between the zygote and the surrounding cells are lost. The first division of the zygote is unequal as a result of its marked polarity. A large basal cell and a small terminal cell are produced. The basal cell appears to contain more protein, RNA, carbohydrate, and cell organelles than the terminal cell. Ribosomal aggregation is even more pronounced at this stage. Starch accumulates in the plastids. Numerous plasmodesmata are present between the terminal and basal cells but there are no connections between the endosperm or other cells. The basal cell divides next to give rise to a three-celled linear embryo consisting of the basal cell, the suspensor cell, and the terminal cell. The terminal cell stains more intensely for protein and RNA as a result of increased numbers of ribosomes. Starch in all the cells is about equal and reaches a maximum in the embryo at this stage.     

Ultrastructure of the Giant Amoeba Pelomyxa palustris*

SYNOPSIS. The ultrastructure of the herbivorous amoeba Pelomyxapalustris was studied. Nuclear division is not understood in this amoeba, and evidence for the method of nuclear division was sought. This species typically has many spheroidal nuclei which are similar within a given cell. However, some amoebae from our collections differed from this common type in both the number and structure of their nuclei. This suggested stages associated with nuclear division. One current hypothesis of nuclear division in this organism is that of nuclear budding. Our evidence is more in accord with this method than with mitosis. The cytoplasm contained no mitochondria, Golgi bodies, contractile vacuoles or crystals. Most amoebae had 2 types of bacteria (bacteroids or endosymbionts) in their cytoplasm; a separate vesicle enclosed each of these. Characteristically, only 1 type of bacterium (B_n) surrounded the nucleus. Another type (B) was found elsewhere in the cytoplasm. Also in the cytoplasm were the following: food vacuoles enclosing various algae, relatively clear vacuoles and vesicles, glycogen, various electron-opaque particles, and occasional microtubules. The plasmalemma was smooth, lacking the external fringe which characterizes other large fresh-water amoebae.     

莴苣花药发育过程中钙的分布特征

减数分裂前,莴苣花药中的钙颗粒很少。减数分裂后,花药绒毡层细胞中的钙颗粒明显增加。同时在花药药室基质中也出现许多细小的钙颗粒。刚从四分体中释放出的小孢子内钙颗粒很少。伴随着花粉外壁物质在小孢子表面的沉积,钙颗粒开始积累在花粉壁部位。随后。小孢子中开始出现钙颗粒。当小孢子开始形成液泡后,钙颗粒向其中聚集,伴随着小液泡融合成大液泡。体积较大的钙颗粒主要集中在液泡中,而细胞质基质中的钙颗粒很少。随着二胞花粉中的大液泡消失,花粉细胞质中的钙颗粒变得很少。在以后的发育中,只有花粉壁中积累较多的钙颗粒。在莴苣花药发育过程中,钙与绒毡层细胞的退化和小孢子液泡形成以及二胞花粉中大液泡的消失有关。而花粉外壁表面积累丰富的钙与以后花粉的萌发有关。