金黄滴虫细胞同步分裂的诱导

无菌培养的金黄滴虫在25℃及连续通气的条件下,经12小时光照(2500Lux)和12小时黑暗的相间处理,可连续出现三次同步分裂,同步分裂率最高可达92％,即细胞数在一小时内可陡增92％。 细胞核动态的观察表明,在黑暗处理期中细胞被阻止于细胞分裂的前期。当黑暗处理11小时后,前期细胞突破阻拦,实现了同步分裂。     

THE FINE STRUCTURE OF MITOSIS IN RAT THYMIC LYMPHOCYTES

The fine structure of rat thymic lymphocytes from early prophase to late telophase of mitosis is described, using material fixed at pH 7.3 either in 1 per cent OsO4 or in glutaraldehyde followed by 2 per cent OsO4. The structure of the centriolar complex of interphase thymocytes is analyzed and compared with that of centrioles during division. The appearance of daughter centrioles is the earliest clearly recognizable sign of prophase. Daughter centrioles probably retain a secondary relation to the primary centriole, while the latter appears to be related, both genetically and spatially, to the spindle apparatus. The nuclear envelope persists in recognizable form to help reconstitute the envelopes of the daughter nuclei. Ribosome bodies (dense aggregates of ribosomes) accumulate, beginning at late prophase, and are retained by the daughter cells. Cytokinesis proceeds by formation of a ribosome-free plate at the equator with a central plate of vesicles which may coalesce to form the new plasma membrane of the daughter cells. Stages in the formation of the midbody are illustrated.     

MITOSIS AND CELL DIVISION IN HYDRURUS FOETIDUS (CHRYSOPHYCEAE)1

Mitosis and cell division have been examined ultrastructurally in the vegetative cells of Hydrurus foetidus (Vill) Trev. and found to resemble that of Ochromonas in two important aspects. First, the rhizoplast acts as the spindle organizing body and second, the spindle elongates considerably during anaphase. It differs from Ochromonas in that there is no movement of the basal bodies and flagella towards the poles. Moreover, the nuclear envelope remains relatively intact throughout early stages of mitosis, with gaps developing at the poles during prophase to permit entry of spindle microtubules. Disruption of the nuclear envelope does not occur in the equatorial plane until late anaphase. The spindle persists into telophase and is bent towards the posterior of the cell by the ingrowing edge of the cleavage furrow. Persistence of the spindle and lack of Ochromoms-type cell elongation may be related to the constricting presence of the sheath during cell division—a completely different strategy to that adopted by the green algae under conditions of similar constraint.     

MITOSIS AND CELL DIVISION IN CYLINDROCAPSA GEMINELLA (CHLOROPHYCEAE)1

Mitosis and cell division were studied in the green alga Cylindrocapsa geminella Wolle with transmission electron microscopy. Vegetative cells possess a parietal, lobed chloroplast, and a central pyrenoid. Prophase and metaphase nuclei are surrounded by 1–3 layers of perinuclear endoplasmic reticulum. At early prophase a small number of perinuclear microtubules (MTs) are present while at late prophase MTs are concentrated at the presumptive spindle poles. At the same time, MTs begin to appear in the nucleoplasm. Metaphase spindles are diamond-shaped and centric. During telophase, centrioles migrate towards the center of the equatorial zone, presumably guided by a small group of perinuclear MTs. A second system of MTs develops in the equatorial plane, initially consisting of randomly orientated microtubular elements. Later they tend to run in a predominantly radial direction although a common MT focal point or organizing center is not apparent. The two centriole complexes remain at the center of the equatorial plane until well into interphase, facing each other across the newly formed transverse septum. Centrioles are associated with root templates and connecting fibers. The present observations corroborate the view that C. geminella does not form a true filament in the ulotrichalean or chaetophoralean sense, but rather consists of a row of autospores. Its affinity with other “pseudo-filamentous” green algae and the Chlorococcales is discussed. The interpretation of the cytokinetic MTs in C. geminella as a phycoplast appears to be problematic.     

FINE STRUCTURE OF CELL DIVISION IN PYRAMIMONAS PARKEAE NORRIS AND PEARSON (CHLOROPHYTA,PRASINOPHYCEAE)1

Cell division in Pyramimonas parkeae is described and compared with some other green algae. The first indication of mitosis is division of the chloroplast, accompanied by growth of a prominent microbody, followed by replication of the 4 basal bodies. Also closely timed with this is the replication of the Golgi and other components of the basal body complex. Two basal body complexes separate, each taking a position at either pole of the nucleus which has migrated to a characteristic position just beneath the plasmalemma of a broadened and flattened flagellar pit. Cytokinesis is accomplished by the fusion of ducts and vesicles with the simultaneous release of scales to the newly formed exterior. Cells swim throughout division.     

CELL DIVISION AND COLONY FORMATION IN THE GREEN ALGA COELASTRUM (CHLOROCOCCALES)1

Multinucleate cells of Coelastrum undergo precisely directed cytokinesis, guided by phycoplast microtubules, to form a number of uninucleate daughter cells which subsequently adhere to form characteristically patterned aggregates. As there is no movement of the daughter cells relative to one another before their adhesion, the disposition of cells in daughter colonies reflects the pattern of cytokinesis of parent cells. Centrioles lie at the poles of the mitotic nuclei which are partially enclosed by a perinuclear envelope of endoplasmic reticulum. The centrioles disappear at the time of cytokinesis of the parental cell and apparently reform de novo once the daughter cells have acquired a cell wall following their adhesion. The trilaminar layer of cell wall, often termed the pectic layer, does not stain with ruthenium red and resists acetolysis suggesting that it contains sporopollenin rather than pectin.     

MITOSIS AND CYTOKINESIS IN THE CHLOROMONADOPHYCEAN ALGA GONYOSTOMUM SEMEN1

Mitosis and cytokinesis in Gonyostomum semen (Ehrenberg) Diesing have been investigated with the light microscope. During prophase nucleoli disappear and the chromatid structure of the chromosomes becomes apparent. Separation of chromatids at anaphase is accompanied by progressive fusion of the progeny chromosomes. This process continues into telophase by which stage the progeny nuclei consist of dense masses of chromatin with occasional chromosomes extending from their equatorial surfaces. By the end of telophase, nucleoli are reforming and the interphase nuclear morphology is reestablished. Mitosis is followed by cytokinesis, which is a relatively lengthy phase. In early cytokinesis the 2 interphase nuclei are present, and there is no indication of the forthcoming division of the cytoplasm. Later in cytokinesis a membrane is formed between the 2 nuclei. Final separation of the progeny individuals is accomplished by vigorous movements of swimming cells or, in the case of palmelloid cells, by the deposition of a mucilaginous layer.     

金黄滴虫叶绿体拟核的荧光镜检及电镜观察

金黄滴虫细胞在用DNA特异的荧光染料DAPI处理后,在荧光显微镜下细胞核和叶绿体拟核均散发蓝色荧光,穗晰可见。每一叶绿体有一拟核,拟核沿叶绿体的周缘排列,形状相当于叶绿体的轮廓,成不规则的两叶形环。环的全长约在20—30υm之间。 拟核环大多是单线的,有些拟核环出现或短或长的双线部分,有时甚至几乎整个拟核环都可变为双线。这表明拟核环通过“纵裂”而形成双环,在叶绿体分裂时,分别进入两个子叶绿体。这一情况在电镜照片上得到了证实。 叶绿体分裂和细胞分裂之间似乎不存在严格的相关性,这是导致细胞中叶绿体数目多于1个的原因。     

EFFECT OF INCUBATION TEMPERATURE ON THE MACROMOLECULAR AND LIPID CONTENT OF THE PHYTOFLAGELLATE OCHROMONAS DANICA1

Ochromonas danica grown in a chemically defined medium under controlled conditions at different incubation temperatures showed marked changes in chemical composition and secretory pattern. As the incubation temperature rose from 15 to 30 C, the cell number per unit volume of medium increased; the cell mass reached a maximum and then declined slightly, and the weight per single cell decreased. The chemical composition of the cells changed with increasing temperature: carbohydrates decreased dramatically; proteins quadrupled at 20 C and then declined 25%; lipids increased; and RNA increased to 25 C and then decreased to about 40% of maximum at 30 C. The extracellular secretion by the cells of carbohydrates seemed to increase and then decline; RNA decreased; proteins increased; and lipids remained approximately constant, as the temperature increased. The implications of these findings for thermal pollution are discussed.     

THE FINE STRUCTURE OF SPOROGENESIS IN THE XANTHOPHYCEAN ALGA PSEUDOBUMILLERIOPSIS PYRENOIDOSA1,2

The fine structure of vegetative cells, sporogenesis, and zoospores of the xanthophycean alga Pseudo-bumilleriopsis pyrenoidosa is described. Cleavage in sporogenesis closely resembles that of certain aquatic fungi.     

金黄滴虫粘液泡的研究

用酸性粘多糖特异性染料(阿利新蓝或阿利新蓝 甲基绿)和脂肪特异性染料(如苏丹Ⅲ等)同时染活细胞,粘液泡染成蓝色,脂肪滴染成红色。活细胞的粘液泡有自发的蓝色荧光。脂肪滴无荧光。用含有阿利新蓝的戊二醛固定样品,再用O_s真O_4后固定,进行电镜观察,粘液泡呈电子致密的深黑色小泡,而脂肪滴呈灰色小泡,粘液泡的表面常盖有毛状的附属物,其形态反映了粘液泡的液体性质。在同泽的固定材料中,细胞表膜也常存在一厚层与粘液泡表面相似的毛状物质。二者应含有相同的成分,即都含有酸性粘多糖。表膜的粘多糖外被可能主要是由粘液泡向外释放的物质所形成的。电镜细胞化学的检定还表明粘液泡的表面有酸性磷酸酶的活性。粘液泡和盘状泡是同源的细胞器。     

FINE STRUCTURE OF THE SNOW ALGA (CHLAMYDOMONAS NIVALIS) AND ASSOCIATED BACTERIA1

Chlamydomonas nivalis (Bau.) Wille is present in red snow as large spherical resting cells. Fine structural studies reveal an abundance of clear granules in the cytoplasm and occasional starch grains in the chloroplast. Individual cells display a thick cell wall with a smooth outer surface. Cells may be surrounded by a loose fibrous network in which encapsulated bacteria are seen. The bacteria have a characteristic Gram-negative cell wall and constrictive mode of division. The algal-bacterial association appears to be characteristic of red snow populations.     

EFFECTS OF CHLORAMPHENICOL ON CHLOROPLAST AND MITOCHONDRIAL ULTRASTRUCTURE IN OCHROMONAS DANICA

The effect of chloramphenicol (CAP) on cell division and organelle ultrastructure was studied during light-induced chloroplast development in the Chrysophyte alga, Ochromonas danica. Since the growth rate of the CAP-treated cells is the same as that of the control cells for the first 12 hr in the light, CAP is presumed to be acting during that interval solely by inhibiting protein synthesis on chloroplast and mitochondrial ribosomes. CAP markedly inhibits chloroplast growth and differentiation. During the first 12 hr in the light, chlorophyll synthesis is inhibited by 93%, the formation of new thylakoid membranes is reduced by 91%, and the synthesis of chloroplast ribosomes is inhibited by 81%. Other chloroplast-associated abnormalities which occur during the first 12 hr and become more pronounced with extended CAP treatment are the presence of prolamellar bodies and of abnormal stacks of thylakoids, the proliferation of the perinuclear reticulum, and the accumulation of dense granular material between the chloroplast envelope and the chloroplast endoplasmic reticulum. CAP also causes a progressive loss of the mitochondrial cristae, which is paralleled by a decline in the growth rate of the cells, but it has no effect on the synthesis of mitochondrial ribosomes. We postulate that one or more chloroplast ribosomal proteins are synthesized on chloroplast ribosomes, whereas mitochondrial ribosomal proteins are synthesized on cytoplasmic ribosomes.     

THE FINE STRUCTURE OF THE PURKINJE CELL

This paper describes the fine structure of the Purkinje cell of the rat cerebellum after fixation by perfusion with 1 per cent buffered osmium tetroxide. Structures described include a large Golgi apparatus, abundant Nissl substance, mitochondria, multivesicular bodies, osmiophilic granules, axodendritic and axosomatic synapses, the nucleus, the nucleolus, and the nucleolar body. A new and possibly unique relationship between mitochondria and subsurface cisterns is described. Possible functional correlations are discussed.     

ULTRASTRUCTURE OF MITOSIS AND CYTOKINESIS IN THE MULTINUCLEATE GREEN ALGA ACROSIPHONIA

The processes of mitosis and cytokinesis in the multinucleate green alga Acrosiphonia have been examined in the light and electron microscopes. The course of events in division includes thickening of the chloroplast and migration of numerous nuclei and other cytoplasmic incusions to form a band in which mitosis occurs, while other nuclei in the same cell but not in the band do not divide. Centrioles and microtubules are associated with migrated and dividing nuclei but not with nonmigrated, nondividing nuclei. Cytokinesis is accomplished in the region of the band, by means of an annular furrow which is preceded by a hoop of microtubules. No other microtubules are associated with the furrow. Characteristics of nuclear and cell division in Acrosiphonia are compared with those of other multinucleate cells and with those of other green algae.     

ENDOCYTOSIS OF MICROCYSTIS AERUGINOSA BY OCHROMONAS DANICA1

Ochromonas danica Prings., a chrysomonad alga which demonstrates a high degree of nutritional versatility, is capable of feeding on the toxic blue-green alga Microcystis aeruginosa Kuetz. In this paper light microscopic, electron microscopic, and cytochemical examinations of endocytosis in O. danica are reported, with particular emphasis on the vicissitudes of endocytic and lysosomal activities during intra-cellular digestion. An interpretation of the function of organelles associated with endocytosis is presented.     

FINE STRUCTURE OF CAPITULAR FILAMENTS IN THE COENOCYTIC GREEN ALGA PENICILLUS1,2,3

Capitular filaments of Penicillus capitatus contain a large central vacuole. The parietal cytoplasm is densely packed, devoid of chloroplasts in the growing tip, and becomes convoluted and sponge-like as extensions of the vacuole penetrate the cytoplasm in mature portions of the filament. Structure of organelles and their distribution in the filament are described. The vacuole contains a variety of inclusions, such as membranous configurations, spherical bodies, electron dense bodies, and calcium oxalate monohydrate crystals, each of the latter surrounded by a chamber associated with microtubules. Endophytic bacteria are present throughout the vacuole and occasionally in the tip cytoplasm. Some vacuolar components of P. pyriformis are described for comparison.     

CELL DIVISION IN SPIROGYRA. I. MITOSIS

Dividing cells of Spirogyra sp. were examined with both the light and electron microscopes. By preprophase many of the typical transverse wall micro-tubules disappeared while others were seen in the thickened cytoplasmic strands. Microtubules appeared in the polar cytoplasm at prophase and by prometaphase they penetrated the nucleus. They were attached to chromosomes at metaphase and early anaphase, and formed a sheath surrounding the spindle during anaphase; they were seen in the interzonal strands and cytoplasmic strands at telophase. The interphase nucleolus, containing 2 distinct zones and chromatinlike material, fragmented at prophase; at metaphase and anaphase nucleolar material coated the chromosomes, obscuring them by late anaphase. The chromosomes condensed in the nucleoplasm at prophase, moving into the nucleolus at prometaphase. The nuclear envelope was finally disrupted at anaphase during spindle elongation; at telophase membrane profiles coated the reforming nuclei. During anaphase and early telophase the interzonal region contained vacuoles, a few micro-tubules, and sometimes eliminated n ucleolar material; most small organelles, including swollen endoplasmic reticulum and tubular membranes, were concentrated in the polar cytoplasm. Quantitative and qualitative cytological observations strongly suggest movement of intact wall rnicrotubules to the spindle at preprophase and then back again at telophase.