Alkaline bismuth solution as an en bloc stain for formaldehyde-glutaraldehyde potassium permanganate fixed fungal spores

An alkaline solution of bismuth subnitrate reacted well with the cell membranes and cell walls of formaldehyde-glutaraldehyde potassium permanganate fixed Alternaria spores, demonstrating them with greater contrast than in sections stained with uranyl acetate and lead citrate. Optimal fine structure of fungal spores was obtained by en bloc staining with alkaline bismuth solution after aldehyde and permanganate fixation. The contrast of the cell organelles and cell walls was high enough in sections cut after the alkaline bismuth en bloc stain for direct ultrastructural observation. Our results indicate that the alkaline bismuth stain is useful either as an en bloc or section stain for aldehyde and permanganate fixed fungal spores.     

Ca2+-homeostasis Differs Between Plant Species with Different Cold-tolerance at 4℃ Chilling

Electron microscopic observations revealed that the tissues of poplar (Populus deltoides Bartr. ex Marsh) apical bud cells, which were fixed by a modified procedure of potassium permanganate fixative, showed a distinct endomembrane organization, in particular, the structural associations of the endoplasmic reticulum (ER) with other membrane systems. The striking findings are that some ER elements were in connection with the nuclear envelopes of two adjacent cells through plasmodesmata, and many ER elements were also associated with mitochondria, plastids, Golgi bodies or the plasma membrane (PM), forming a bridge-like continuum among various endomembrane systems or between nucleus to nucleus. A great number of plasmodesmata existed between cells, indicating a perfectly integrated symplasmic structure in poplar apical bud meristem grown in a long day environment. During the short day-induced dormancy, ER contracted, leading to its disassociation between nuclei, and between the nucleus and organelles/plasmalemma in many cells. After dormancy broke and shoots growth resumed, contracted ER was no longer observed in the apical bud cells. The ER associations with other endomembrane systems and the intercellular communication channels were re-established similar to that of plants before dormancy induction. These observations suggest that ER may play an important role in linking-up between the nucleus and organelles, and between the nucleus and the nucleus (or cell-to-cell), and seemingly coordinating various physiological processes by the bridging-like associations. And the contraction of ER under short-day may result in the growth cessation and the development of dormancy in poplar.     

杨树顶芽细胞内质网与其他膜系统的结构联系及其在休眠过程中的变化

杨树（Ｐｏｐｕｌｕｓ ｄｅｌｔｏｉｄｅｓ Ｂａｒｔｒ．ｅｘ Ｍａｒｓｈ）顶芽分生组织细胞经一种改良的高锰酸钾固定法固定后,显示出一种十分清晰的内膜结构,尤其展现了内质网与其他膜系统存在一种结构上的密切联系。一些与核膜相连接的内质网伸展到细胞质中与线粒体、质体及高尔基体发生联系,可延伸到质膜。还有些内质网的一端与一个细胞的核膜相连结,其另一端穿过胞间连丝与邻近的另一个细胞的核膜相连结,在两个相邻的细     

The Sertoli cell membrane body in the skink.

The structure of the Sertoli cell and its physical relationship with the germ cells was studied in laboratory maintained skinks, Eumeces laticeps (Schneider) in January, and September, corresponding to the periods of prenuptial and postnuptial spermatogenesis respectively. Light micrographs obtained using 1 micron thick plastic sections, show the Sertoli cell to have a large polymorphic nucleus located in the basal portion of the cell, and a darkly staining juxtanuclear body. In ultrathin sections, this body consists of a complex array of thin, electron dense membranous structures resembling the endoplasmic reticulum. The lumina of these membranous channels appear empty. Between the channels, there are structures that resemble the expanded cisternae of the endoplasmic reticulum. In some sections, these dilated cisternae are confluent with the channels, indicating that the channels and the cisternae are parts of the same structure. Three organelles, namely, mitochondria, lysosomes and microfilaments are found among the elements of the membrane body. There is no structural modification of the channels where they come in contact with mitochondria, but they are dilated in proximity to lysosomes. In some sections bundles of microfilaments are clearly visible within the diamond shaped region of contact between two channels, suggesting that these organelles are involved in structural or functional organization of the membrane body.     

Alkaline Bismuth Solution as an En Bloc Stain for Formaldehyde-Glutaraldehyde Potassium Permanganate Fixed Fungal Spores

An alkaline solution of bismuth subnitrate reacted well with the cell membranes and cell walls of formaldehyde-glutaraldehyde potassium permanganate fixed Alternaria spores, demonstrating them with greater contrast than in sections stained with uranyl acetate and lead citrate. Optimal fine structure of fungal spores was obtained by en bloc staining with alkaline bismuth solution after aldehyde and permanganate fixation. The contrast of the cell organelles and cell walls was high enough in sections cut after the alkaline bismuth en bloc stain for direct ultrastructural observation. Our results indicate that the alkaline bismuth stain is useful either as an en bloc or section stain for aldehyde and permanganate fixed fungal spores.     

Segmental variations in the organization of the endoplasmic reticulum of the rat nephron

Summary The spatial organization of endoplasmic reticulum (ER) was examined in all segments of rat nephron. Tissues were fixed with glutaraldehyde, impregnated en bloc with osmium tetroxide, prepared for and examined by standard (80–100 kV) and high voltage (1 mEV) transmission electron microscopy.In all proximal tubule cells, ER forms a continuous and extensive network of canaliculi and abundant fenestrated saccules which surround mitochondria and cytoplasmic bodies; the cage-like structure of the fenestrated saccules was most evident around the spherical mitochondria of the S₃ segment. In the cells of the distal straight and convoluted tubules, the network consists mostly of canaliculi with rare non-fenestrated saccules. The ER network of canaliculi is particularly rich in intercalated cells, in contrast with its rudimentary appearance in the adjacent principal cells of the collecting tubule. In fact, in these cells there are few isolated ER cisternae and they are rarely impregnated. The nuclear envelope is well impregnated in most cells throughout the various segments. Segmental variations in ER organization and its relative abundance are most likely related to the well, established functional heterogeneity of the nephron segments. Moreover, the extensive and unique organization among mitochondria, ER and the basolateral membrane suggests that these three organelles function as a unit which is related to active electrolyte transport. In addition, because of its transepithelial organization, ER may well constitute a transcellular pathway for molecules.     

Applicability of imprints to immuno-ultrastructural studies of lymphoid tissues

In order to evaluate the applicability of imprints to immuno-ultrastructural studies of lymphoid tissues, we compared distribution pattern and morphology of B cells, T cells, T-cell subsets, and follicular dendritic reticulum cells (DRC) at the light and ultrastructural level in imprints and sections of tonsils and lymph nodes. The surface antigenic profile of lymphoid cells was revealed with monoclonal antibodies in an avidin-biotin-peroxidase complex (ABC) method. Distribution of lymphoid cells in coherent areas of imprints recapitulated their disposition in sections of respective lymphoid tissues. Preservation of microanatomical relationships and ultrastructure of lymphoid cells in imprints allowed evaluation of associations and fine structural detail of lymphoid cells. Morphologic configurations of B cells in imprints, confined to round aggregates, were similar to fine structural morphology of B cells in mantle zones (MZ) and germinal centers (GC). Processes of DRCs in imprints formed conformations resembling their meshwork within follicles and mantled lymphoid cells. In imprints and sections, lymphocytes of cytotoxic/suppressor phenotype had a large amount of cytoplasm with many organelles. In contrast, cells of helper/inducer phenotype displayed a high nucleocytoplasmic (N/C) ratio and small numbers of organelles. Thus, imprints represent an easy, fast, and reliable method that lends itself to immunoultrastructural studies of lymphoid tissues.     

Spatial structure of mitochondria and ER denotes changes in cell physiology of cultured tobacco protoplasts

The structure of mitochondria and of the endoplasmic reticulum (ER) in mesophyll protoplasts and regenerated cells was studied in vivo using the dye DiOC₆(3) (3,3'-dihexyloxacarbocyanine iodide) and confocal laser scanning microscopy (CLSM). The relation to the cell's physiology was investigated using a hormone-based model system for elongation and division. The structure of the mitochondria and of their population depends on the status of the cell. In freshly isolated protoplasts small spherical mitochondria are clustered around the nucleus and the chloroplasts. During the first 4 days of culture they are transformed into long vermiform organelles which distribute evenly throughout the cytoplasm. In a medium containing only auxins, cells then enter a period of expansion. Their mitochondria retain the same structure but increase in quantity. In a medium with auxins and cytokinins cells start dividing. Their mitochondria typically become numerous and very small, and are distributed throughout the cytoplasm. Both types of organization were observed during weeks of ongoing expansion or division. The ER is always present as a network close to the cell membrane. In freshly isolated protoplasts a considerable part of the ER is clustered around the chloroplasts, the remaining part of the network has a reduced complexity and is partly broken. During subsequent protoplast culture the network grows into a complex web with fine meshes incorporating lots of plate-like structures. This is the case in elongating cells as well as in dividing cells. Finally, the ER looks similar to the structure found in epidermal cells of the intact plant.     

The role of the vimentin intermediate filaments in rat 3Y1 cells elucidated by immunoelectron microscopy and computer-graphic reconstruction

The three-dimensional arrangement of vimentin intermediate filaments (IF) was studied in 3Y1, rat fibroblastic cell line, to elucidate its biological role in the cell. While actin filaments were observed exclusively in the superficial part of the cell, vimentin IF were found to be abundantly present in the inside of the cell where microtubules were occasionally discovered. By whole-mount immunoelectron microscopy and computer-graphic reconstruction of serial thin sections, it was observed in more detail that vimentin IF are located very close to the nucleus, endoplasmic reticulum, and mitochondria. Vimentin IF were observed to be attached to these organelles laterally or terminally. Thus, we can reasonably assume that vimentin IF are major cytoskeletal structures deep inside the cell and that they play an important role in supporting the location of the organelles. This is the first report which has visualized the three-dimensional relationship between vimentin IF and the organelles of the cell.     

The role of the vimentin intermediate filaments in rat 3Y1 cells elucidated by immunoelectron microscopy and computer-graphic reconstruction

The three-dimensional arrangement of vimentin intermediate filaments (IF) was studied in 3Y1, rat fibroblastic cell line, to elucidate its biological role in the cell. While actin filaments were observed exclusively in the superficial part of the cell, vimentin IF were found to be abundantly present in the inside of the cell where microtubules were occasionally discovered. By whole-mount immunoelectron microscopy and computer-graphic reconstruction of serial thin sections, it was observed in more detail that vimentin IF are located very close to the nucleus, endoplasmic reticulum, and mitochondria. Vimentin IF were observed to be attached to these organelles laterally or terminally. Thus, we can reasonably assume that vimentin IF are major cytoskeletal structures deep inside the cell and that they play an important role in supporting the location of the organelles. This is the first report which has visualized the three-dimensional relationship between vimentin IF and the organelles of the cell.     

几种不同进化程度动物细胞内质网超微结构的比较研究

应用稼射电镜技术,高锰酸钾固定扫描电镜技术及生化分离技术,比较研究了家兔、家鸽、蟾蜍,鲤鱼、脉红螺肝细胞和眼虫的内质网超微结构及含量。透射电镜观察结果显示：在高等哺乳动物肝细胞内质网丰富,以扁囊结构为主,在整个细胞质内均有分布,主要存在于核周围,并伴有伴随线粒体分布的特征;蟾蜍肝细胞内质网稀少,以长管状平行排列,分布在细胞质的局部,鲤鱼肝细胞内质网呈小泡状均匀分布在细胞质中,脉红螺肝细胞及眼虫细胞     

THE FINE STRUCTURE OF THE ELECTRIC ORGAN OF TORPEDO MARMORATA

The fine structure of the electric organ of the fish Torpedo marmorata has been examined after osmium tetroxide or potassium permanganate fixation, acetone dehydration, and Araldite embedment. This organ consists of stacks of electroplaques which possess a dorsal noninnervated and a ventral richly innervated surface. Both surfaces are covered with a thin basement membrane. A tubular membranous network whose lumen is continuous with the extracellular space occupies the dorsal third of the electroplaque. Nerve endings, separated from the ventral surface of the electroplaque by a thin basement membrane, contain synaptic vesicles (diameter 300 to 1200 A), mitochondria, and electron-opaque granules (diameter 300 A). Projections from the nerve endings occupy the lumina of the finger-like invaginations of the ventral surface. The cytoplasm of the electroplaques contains the usual organelles. A "cellular cuff" surrounds most of the nerve fibers in the intercellular space, and is separated from the nerve fibre and its Schwann cell by a space containing connective tissue fibrils. The connective tissue fibrils and fibroblasts in the intercellular space are primarily associated with the dorsal surface of the electroplaque.     

PLANT MICROTECHNIQUE: SOME PRINCIPLES AND NEW METHODS

Some easily seen structural features of living plant cells are destroyed or badly distorted by most of the common fixatives and embedding media used in plant histology. In stained sections of plant tissues fixed in FAA (formalin-acetic acid-alcohol mixtures) and embedded in paraffin wax, for example, mitochondria and fine transvacuolar strands of cytoplasm are usually not visible. Many structural features such as these can be preserved, however, with suitable fixatives and embedding media. Specifically we recommend fixation in non-coagulant fixatives (e.g., osmium tetroxide, acrolein, glutaraldehyde, formaldehyde) and the use of plastics as embedding media, and we describe in detail a method of fixation in acrolein and embedding in glycol methacrylate polymer. In a wide range of plant specimens prepared in this way, stained sections 1–3 microns thick showed excellent preservation of tissue and cell structures.     

Differential Translocation of Host Cellular Materials into the Chlamydia trachomatis Inclusion Lumen during Chemical Fixation

Chlamydia trachomatis manipulates host cellular pathways to ensure its proliferation and survival. Translocation of host materials into the pathogenic vacuole (termed ‘inclusion’) may facilitate nutrient acquisition and various organelles have been observed within the inclusion, including lipid droplets, peroxisomes, multivesicular body components, and membranes of the endoplasmic reticulum (ER). However, few of these processes have been documented in living cells. Here, we survey the localization of a broad panel of subcellular elements and find ER, mitochondria, and inclusion membranes within the inclusion lumen of fixed cells. However, we see little evidence of intraluminal localization of these organelles in live inclusions. Using time-lapse video microscopy we document ER marker translocation into the inclusion lumen during chemical fixation. These intra-inclusion ER elements resist a variety of post-fixation manipulations and are detectable via immunofluorescence microscopy. We speculate that the localization of a subset of organelles may be exaggerated during fixation. Finally, we find similar structures within the pathogenic vacuole of Coxiella burnetti infected cells, suggesting that fixation-induced translocation of cellular materials may occur into the vacuole of a range of intracellular pathogens.     

Spatial associations between actin filaments, endoplasmic reticula, mitochondria and fungal hyphae in symbiotic cells of orchid protocorms

The relationships between endoplasmic reticula (ER), mitochondria, and actin filaments (Afs) were observed in uncolonized and colonized cells of symbiotic protocorms ofSpiranthes sinensis (Orchidaceae) germinated in the presence of the fungus,Ceratobasidium cornigerum. Mitochondria and ER were observed by transmission electron microscopy, and with the fluorescent probe DiOC₆ (3) (3,3′-dihexyloxacarbocyanine) combined with confocal laser scanning microscopy (CLSM). An indirect immunofluorescence method using CLSM and an indirect, pre-embedding immunogold method at the ultrastructural level were used for observation of Afs. In uncolonized cells, cortical ER showed a polygonal pattern and ER formed a network throughout the cytoplasm. In the cortex, a smooth face of ER contacted the plasma membrane. Mitochondria were associated with ER. Afs were in close proximity to ER, mitochondria and amyloplasts. Colonized cells retained cortical ER, and a smooth face of ER was also closely associated with the perifungal membrane. ER and mitochondria were present in the cytoplasmic channels bridging between the central peloton and the peripheral cytoplasm. This distribution of ER and mitochondria during fungal colonization and senescence coincided with that of Afs. The changes in the arrays of Afs accompanying symbiotic fungal colonization and senescence occurred concomitantly with the changes in ER.     

Three dimensional visualization of the Golgi apparatus and endoplasmic reticulum in the subcommissural organ cells with high voltage electron microscopy

Fine structure and stereo-images of the Golgi apparatus and endoplasmic reticulum (ER) in the subcommissural organ (SCO) cells were visualized by the application of zinc-iodide osmium tetroxide (ZIO) impregnation, conventional electron microscopy and high voltage electron microscopy (HVEM). The Golgi apparatus in the SCO cells of rats, gerbils and hamsters consisted of flattened saccules stacked in parallel array. It showed a selective staining toward ZIO mixture and might form a complex network of tubular structures because of the presence of numerous fenestrations in the flattened Golgi saccules. The cytoplasm of the SCO cells in the rat and gerbil was crowded by dilated cisternae of the ER with a few flattened profiles. In the hamster SCO cells, however, the dilated cisternae of the ER were not observed. Flattened cisternae of ER in all species studied showed a positivity for ZIO impregnation and formed a complex tubular network, whereas dilated cisternae of the ER in the rats and gerbils did not show any reactivity. It was thus determined that the observation of thin and thick sections selectively stained with appropriate reagent for defined cellular organelles under conventional electron microscopy and HVEM offered valuable information about three-dimensional organization of the cell. A definite species-specific variation of SCO ultrastructure and cytochemistry was also demonstrated.     

INTRAMITOCHONDRIAL FIBERS WITH DNA CHARACTERISTICS : I. Fixation and Electron Staining Reactions

Chick embryo mitochondria, studied with the electron microscope, show crista-free areas of low electron opacity. These areas are observable after fixation with osmium tetroxide, calcium permanganate, potassium permanganate, formaldehyde, acrolein, acrolein followed by osmium tetroxide, uranyl acetate followed by calcium permanganate, and acetic acid-alcohol. Staining of sections with lead hydroxide or uranyl acetate, or with both, resulted in an increased density of a fibrous material within these areas. The appearance of the fibrous structures varied with the fixative employed; after fixation with osmium tetroxide the material was clumped and bar-like (up to 400 A in diameter), whereas after treatment of osmium tetroxide-fixed tissues with uranyl acetate before dehydration the fibrous structures could be visualized as 15 to 30 A fibrils. Treatment with ethylenediaminetetraacetate (EDTA) in place of uranyl acetate coarsened the mitochondrial fibrils. After fixation with calcium permanganate or potassium permanganate, or a double fixation by uranyl acetate followed by calcium permanganate, the fibers appeared to have a pattern and ultrastructure similar to that observed after the osmium tetroxide-uranyl acetate technique, except that some of them had a slightly greater diameter (up to 50 A). Other fixatives did not preserve the fibers so well. The fibers appeared strongly clumped by formaldehyde fixation, and were difficult to identify after fixation with acrolein or acetic acid-alcohol. The staining of nucleic acid-containing structures by uranyl acetate and lead hydroxide was improved by treatment of osmium tetroxide-fixed sections with hydrogen peroxide, and the mitochondrial fibers also had an increased density in the electron beam after this procedure. The staining characteristics suggest the fibrous material of chick embryo mitochondria to be a nucleic acid-containing structure, and its variable appearance after different fixations parallels that previously reported, or described in this paper, for the nucleoplasm of bacteria and blue-green algae. The results, in addition to those described in the accompanying communication, indicate that these mitochondria contain DNA.     

TISSUE PREPARATION AND FINE STRUCTURE OF THE RADICLE APEX FROM COTTON SEEDS

A comparative methodological study was made of the fine structure of apical cortical cells in excised radicles from cotton (Gossypium hirsutum L. var M-8) seeds. Radicles from dry seed had 12% moisture content and were prepared for electron microscopy using several different techniques. These included different methods of chemical fixation or freeze-fracture and etching of unfixed tissue for transmission electron microscopy (TEM) and cryofracturing of fixed and dehydrated radicles for scanning electron microscopy (SEM). Cortical cells had a similar appearance regardless of the method used in tissue preparation. Cell walls had a pronounced waviness which was particularly evident in SEM images of cells lining the elongated intercellular air spaces. The plasma membrane (PM) delimited the cytoplasm of each cell as an intact unit membrane. Single layers of tightly-packed lipid bodies (LB) were apposed to the PM and protein bodies (PB). Distension of cells, membranous organelles and LB was observed in radicles fixed by immersion in aqueous solutions, suggesting that a certain amount of hydration occurred during fixation. This interpretation was supported by the compact appearance of cells and organelles in tissue prepared by freeze-etch or vapor fixation. We conclude that freeze-fracture and etching of unfixed tissue provided the best information for cell morphology and structure of membranes and organelles in dry tissue. Complementary data on the fine details of nuclei and cytoplasmic organelles were best observed with TEM of fixed tissue. These data when viewed collectively indicate the advantage of using several techniques to obtain analogous and complementary information essential for establishing a baseline level of information on the fine structure of cells in dry tissue.     

Localization of endoplasmic reticulum in living and glutaraldehyde-fixed cells with fluorescent dyes

Certain fluorescent dyes, previously reported to localize mitochondria, when used at higher concentrations also localize a continuous net-like structure in both living and glutaraldehyde-fixed cells. A similar reticular structure can be detected by phase-contrast microscopy and whole-mount electron microscopy in potassium permanganate-fixed cells as well. This structure is mostly tubular, with some patch-like areas, and is likely to be the endoplasmic reticulum (ER). The organization of the reticular structure is sensitive to colchicine and rotenone but not to cytochalasin B, taxol, monensin, the calcium ionophore A23187, 12-O-tetradecanoylphorbol 13-acetate, or hydrocortisone.