STRATIFICATION AND SUBSEQUENT BEHAVIOR OF PLANT CELL ORGANELLES

Living excised roots of pea were centrifuged at 20,000 g for 24 hours, and the behavior of organelles was followed by electron microscopy at various intervals after centrifugation. With these forces, organelles are not perceptibly or irreversibly damaged, nor is the viability of the whole root destroyed. Organelles stratify generally in the order of lipid (centripetal pole), vacuoles, smooth endoplasmic reticulum and dictyosomes, proplastids (without starch), mitochondria, rough endoplasmic reticulum, proplastids with starch. The nucleus distends from the vacuolar region to the extreme centrifugal pole of the cell, while the chromatin and nucleolus seek the centrifugal pole of the nucleus. During the redistribution of organelles the rough endoplasmic reticulum is among the first to reorient, and possible explanations for this are discussed. Mitochondria can be stretched elastically many times their original length, but proplastids seem fairly rigid. Small vacuoles, forced together during centrifugation, apparently may fuse to form a large unit. Lipid droplets, on the other hand, tend to remain separate. Dictyosomes and smooth endoplasmic reticulum layer in the same region of the centrifuged cell, indicating a density similarity between these two organelles.     

Changements de l'ultrastructure des cellules radiculaires de Zea mays au début de la germination

Summary The ultrastructure of root cells of the germinating corn embryo has been studied during the first 72 hours of soaking. The most spectacular ultrastructural modifications occur in the nucleus. In the dry seed, the chromatin is heavily condensed and complete dispersion occurs during the first 8 hr of germination. The nucleolus appears as a compact structure in the dormant embryo, and as a uniform granular structure after 3 hr. At the 8th hour, large nucleolar vacuoles appear filled with material structurally similar to chromatin. Later on, the nucleolus is composed of a central, fibrillo-granular region surrounded by a thin, peripheral, granular region and fewer nucleolar vacuoles are found.In a previous autoradiographic study (Deltour, 1970), it was shown that the onset of RNA synthesis in these cells occurs 4 hr after soaking. From that time to the 8th hour, uridine-³H is incorporated exclusively into the chromatin. Incorporation of radioactive uridine into the nucleolus begins only after the 8th hour.It is interesting that the onset of RNA synthesis in the chromatin occurs simultaneously with the dispersion of this cell component, and that the appearance of vacuoles in the nucleolus is correlated with the beginning if uridine incorporation into this organelle.The following ultrastructural changes take place in the cytoplasm; (a) the lamellae system of proplastids increases slightly; (b) phytoferritin granules present in the proplastids of the dry seed disappear very rapidly; (c) polysomes appear 72 hr after soaking; (d) the spherosomes which are essentially localized in the vicinity of the wall in the dormant embryo become uniformly distributed throughout the cytoplasm at the 72nd hr.

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Changements de l'ultrastructure des cellules radiculaires de Zea mays au début de la germination

     

THE NUCLEOLUS OF PARACENTROTUS LIVIDUS DURING THE DEVELOPMENT IN THE PRESENCE OF ACTINOMYCIN D*

An ultrastructural study of the nucleolus of embryos of Paracentrotus lividus was carried out after treatment with Actinomycin D. It was shown that the fibrillar component of the nucleolus persists in the embryos treated with Actinomycin D in the mesenchyme blastula stage and fixed 24 and 48 hr after fertilization. The results are discussed in relation to the synthesis of RNA.     

STUDIES IN THE QUIESCENT ROOT MERISTEM OF THE BULB OF ALLIUM CEPA L.: FINE STRUCTURE AND DNA SYNTHESIS *

Study of the quiescent root meristem of Allium cepa L. bulbs has revealed that its histological organization does not differ significantly from the growing meristem, except for the fact that the cells are all arrested in interphase. Ultrastructure of the quiescent tissue is, however, different in the organization of the nucleolus and in the absence of prominent endoplasmic reticulum, microtubules and golgi complexes. A variety of lomasome-like structures, plasma membrane modifications and vacuoles have been recorded. Most of the cells except for the ones in the root cap and quiescent center are highly vacuolated; vacuolation is maximum in the cortical zone of the meristem. The pattern of ³H thymidine incorporation during early stages of sprouting indicates that asynchrony of the mitotic cycle, which is the characteristic of the growing meristem, is maintained during quiescence by the arrest of nuclei at different subphases of interphase.     

DEVELOPMENT OF PERIPHERAL VACUOLES IN PLANT CELLS

The vacuolar apparatus of various plant cells consists of two distinct features: the large central vacuole and peripheral vacuoles which are derived from invaginations of the plasma membrane. Peripheral vacuoles are conspicuous structures in both living and fixed hair or filament cells of Tradescantia virginiana. They occur as spherical structures along the inner boundary of the peripheral cytoplasm and can be recognized as projections into the central vacuole. These structures are variable in size and number within a cell and can represent a significant proportion of the volume of the vacuole. Peripheral vacuoles most frequently are observed in motion with the streaming cytoplasm although their velocity is usually somewhat slower that that of the cytoplasmic organelles. Ultrastructural studies show two closely approximated membranes, one for each vacuole, in areas where a peripheral vacuole projects into the central vacuole. These are separated by an intermembrane zone continuous with the peripheral cytoplasm. The movement of organelles over the perimeter of the peripheral vacuole is presumed to occur along this intermembrane zone. The internal area of the peripheral vacuoles may appear empty although some contain a vesicular content of unknown origin and function.     

THE FINE STRUCTURE OF SYMPATHETIC NEURONS IN X-IRRADIATED FROGS

The effects of whole body x-irradiation on the fine structure of sympathetic neurons were studied in 15 unanesthetized adult frogs (Rana pipiens), as seen at intervals ranging from 1 hour to 2 weeks after single exposures to 1000 r and 2000 r. Using standard procedures, the lumbar sympathetic ganglia of experimental and 20 control animals were prepared for electron microscope examination. Radiation produced conspicuous but irregular and variable deterioration, swelling, and clearing of neuronal lysosomes. These changes may have been due to an increased permeability of lysosomal membranes, causing the entry of fluid into lysosomes and their swelling and deterioration, but a pronounced escape of lysosomal enzymes into the cytoplasm was questionable. Less frequent were the dilatation and the parallel layering or complete fusion and tight packing of the rough-edged endoplasmic reticulum. The number of vacuoles, probably derived from Golgi cisternae, was somewhat increased. These vacuoles were conjectured to serve the "sequestration" of damaged cytoplasmic areas. Abnormal amounts of presumptive glycogen granules occupied some axons of myelinated and unmyelinated fibers, especially of presynaptic nerve fibers. This was assumed to be due to a decreased breakdown of glycogen and probably caused the interruption of the transmission of nerve impulses in presynaptic fibers. The maximal incidence of these alterations seemingly occurred 8 days after exposure to 1000 r, and 1 hour after x-irradiation with 2000 r. Signs of recovery appeared 2 weeks after exposure to 2000 r.     

Megasporogenesis in Arabidopsis thaliana L.: an ultrastructural study

 In this study, megasporogenesis of the plant model Arabidopsis thaliana was investigated by electron microscopy for the first time. The data described here could constitute a reference for future investigations of Arabidopsis mutants. During the beginning of meiosis the megaspore mother cell shows a polarity created by unequal distribution of organelles in the cytoplasm. Plastids accumulate in the chalazal region and long parallel saccules of endoplasmic reticulum, small vacuoles and some dictyosomes are found in the micropylar region. Plasmodesmata are abundant in the chalazal cell wall. The nucleus is almost centrally localized and contains a prominent excentric nucleolus and numerous typical synaptonemal complexes. After the second division of meiosis the four megaspores are separated by thin cell walls crossed by numerous plasmodesmata and do not show significant cellular organization. The young functional megaspore is characterized by a large nucleus and a large granular nucleolus. The cytoplasm is very electron dense due to the abundance of free ribosomes and contains the following randomly distributed organelles: mitochondria, a few short saccules of endoplasmic reticulum, dictyosomes and undifferentiated plastids. However, there is no apparent polarity, except for the distribution of some small vacuoles which are more abundant in the micropylar region of the cell. The degenerating megaspores are extremely electron dense and do not show any substructure. Received: 30 July 1998 / Revision accepted: 3 February 1999     

Inhibition of inward rectifying tonoplast channels by a vacuolar factor: Physiological and kinetic implications

Summary Regulation of ion-channel activity must take place in order to regulate ion transport. In case of tonoplast ion channels, this is possible on both the cytoplasmic and the vacuolar side. Isolated vacuoles of youngVigna unguiculata seedlings show no or hardly any channel activity at tonoplast potentials >80 mV, in the vacuole-attached configuration. When the configuration is changed to an excised patch or whole vacuole, a fast (excised patch) or slow (whole vacuole) increase of inward rectifying channel activity is seen. This increase is accompanied by a shift in the voltage-dependent gating to less hyperpolarized potentials. In the whole vacuole configuration the level of inward current increases and also the activation kinetics changes. Induction of channel activity takes up to 20 min depending on the age of the plants used and the diameter of the vacuole. On the basis of the estimated diffusion velocities, it is hypothesized that a compound with a mol wt of 20,000 to 200,000 is present in vacuoles of young seedlings, which shifts the population of channels to a less voltage-sensitive state.Ecotrans publication no. 27.     

Polysaccharide Complexes in Full-Grown Oocytes of the Newt, Pleurodeles, and Changes in their Distribution During Progesterone-Induced Maturation

Immature full-grown oocytes of Pleurodeles waltlii contain large amounts of small electron-dense polysaccharidic granules. These granules lack a limiting membrane, and have a dense but heterogeneous matrix and an apparent diameter of 24–36 nm. Their structure, organization and distribution strongly suggest that they are glycogen granules. On the other hand, mature oocytes both after oviposition or 22–24 hr after in vitro progesterone stimulation contain no polysaccharide granules or complexes. During the first 9–10 hr after hormonal stimulation, granules were abundant and present both individually and as large strands occupying most of the space between the organelles. Granules were frequently found packed together and arranged in regularly arrayed stacks within large subcortical ant cortical vacuoles. Between 4 and 6 hr after progesterone addition, oocytes released the contents of vacuoles to the outside. Between about 11 and 14 hr after progesterone addition, oocytes still contained large amounts of polysaccharide complexes, but the vacuoles were empty. From about 15 hr after progesterone treatment until the end of maturation, the complexes progressively disappeared from the cytoplasm, coincident with the detachment of the follicle cell layer from the oocytes and a reduction in the number and size of microvilli.     

FINE STRUCTURAL STUDIES ON THE INTERPHASE AND DIVIDING APICAL CELLS OF SPHACELARIA TRIBULOIDES (PHAEOPHYTA)1

The apical cells of Sphacelaria tribuloides Menegh. are larger than other thallus cells, contain more organelles and appear polarized. Their tip portion, where they grow, contains a well developed Golgi apparatus, abundant endoplasmic reticulum (ER) membranes, mitochondria, chloroplasts and a large number of small vacuoles. It seems likely that a continuous flow of membranous material from the ER membranes to the dictyosomes and from the latter to the plasmalemma of the extending tip portion takes place. In contrast, the basal pole possesses fewer organelles and is occupied mainly by large-sized, sometimes central vacuoles. The apical cells undergo two distinct types of highly asymmetrical differential divisions giving rise to cells of the thallus and hair initials. During the early stages of mitosis the nuclear envelope remains intact, except for fenestrated poles. Microtubules pass through the fenestrae into the nucleoplasm. During meta-phase, a typical chromosome plate is organized. The sites of attachment of spindle microtubules to the chromosomes are structurally different from the rest of the chromosomes. At late anaphase, the nuclear envelope breaks down completely. During telophase, a new membrane encloses the chromosomes which are decondensed and the nucleoli are reorganized. Cytokinesis proceeds long after mitosis at a stage in which the nuclei have increased in size and have moved farther apart. A membranous furrow develops centripetally, without the participation of microtubules. However, microtubules traverse the thin cytoplasmic strands which, in both interphase and cytokinetic cells, meander among the vacuoles of the basal pole of the cell and the internuclear space. Dictyosomes appear to be involved in the subsequent wall deposition.     

Electron-cytochemical demonstration of acid phosphatase in saprophytic Claviceps purpurea

p-Nitrophenylphosphate in combination with lead salt technique was used for the cytochemical localization of acid phosphatase (EC 3.1.3.2) in saprophytic submerged culture of Claviceps purpurea Tul. The lead reaction product was found in capsular fibrils, in the newly formed parts of the well wall and in the vacuoles of aged cells (autolysosomes). Phosphatase activity was present also in particulate intracytoplasmatic organelles. The concentric layering of lead deposits in these organelles indicates their relationship to endoplasmic reticulum membranes.Abbreviation Used pNPP p-nitrophenylphosphate     

An electron microscopical study of epididymal epithelium of rats treated with gonadotropic hormone

The ultrastructural modifications of the epithelial cells of rat corpus epididymis stimulated with gonadotropic hormone were studied. The structural variety of the cells depending on functional conditions becomes more prominent 6 h after the injection of gonadotropic hormone. Light large cells have one or often two nucleus-containing bing nucleoli, in their cytoplasm there are numerous vesicles, a well-developed Golgi apparatus, other organelles and lysosomal bodies. Some other cells are filled with many large vacuoles of different density, dense bodies and vesicles. Cells of another type which are in the majority show an unusually active structure reflecting the function of synthesis. The more prominent nucleolus is associated to clumps of chromatin. Their apical cytoplasm is filled by a structure related to absorption. The whole remaining part of their cytoplasm is covered with a very extensive Golgi apparatus and a very well developed granular endoplasmic reticulum. The extremely enlarged cisternae of this reticulum were found to be very closely applied to the basal cell membrane. There is a flocculent material inside the cisternae. Similar material is observed in the extracellular medium under the basal membrane. The epithelium seems normal 10 h after the injection of hormone, but large light cells make up the majority of them.     

A STUDY OF THE SPERMATOZOIDS OF DICHOTOMOSIPHON TUBEROSUS (CHLOROPHYCEAE)1

Spermatozoids of the siphonous green alga Dichotomosiphon tuberosus (A. Br.) Ernst are specialized gametes which differ in many respects from other green algal motile cells, but whose microanatomy nevertheless indicates its chlorophycean affinities. Each cell is anteriorly biflagellate and contains an irregularly shaped nucleus attached to the flagellar bases by a complex support apparatus. There is a single reduced chloroplast in each spermatozoid and numerous (50–100) minute spherical mitochondria, only 0.3 μm diam. These move vigorously in the living cell and when viewed with the light microscope they bear a striking resemblance to bacteria. Rather unexpectedly, no contractile vacuoles could be detected, even though the gametes are naked freshwater cells. Daring spermatogenesis the nucleoli of the vegetative cells disperse and are replaced by a large dense body presumably formed from either nucleolar material or condensed chromatin. The flagellar apparatus includes a cruciate flagellar root system, a feature now known to be characteristic of most green algae, exceptions being those putative ancestors of the higher plants and bryophytes. Discharge of spermatozoids from the antheridia is extremely rapid and the whole process may be finished in 30 sec. The antheridium lacks a pore apparatus, but at maturity bursts open explosively at the apex. Phyletic affinities are discussed and it is concluded that the ultrastructure of the motile cells does not, at this time, support the separation of the siphonous green algae from other green algae into a separate class.     

THE EARLY ACTION OF THE FLORAL STIMULUS ON MITOTIC ACTIVITY AND DNA SYNTHESIS IN THE APICAL MERISTEM OF XANTHIUM STRUMARIUM

Vegetative plants of Xanthium strumarium (a short-day species) were induced to flower by exposure to a single 16-hr long night. By cutting off the induced leaf (half-expanded leaf) at various times, it was established that, by 8 hr after the end of the long night, a sufficient amount of floral stimulus had reached the meristem to induce a flowering response. The following sequence of events occurred in both the peripheral and central zones of the apical meristem of induced plants: 1) a rise in the mitotic index beginning at 28 hr after the end of the long night and culminating at 36 and 56 hr; 2) a stimulation of DNA synthesis starting at 32–36 hr and reaching a maximum at 60 hr; 3) an increase in nucleolus diameter starting at 32 hr. The cell population in the meristems of both vegetative and induced plants displayed a similar distribution, with about 80 % of the nuclei with the 2C amount of DNA. The comparison of the kinetic data concerning the mitotic index and DNA synthesis indicated that one of the early effects of the floral stimulus in the peripheral and central zones was the release in mitosis of cells whose nuclei were in the postsynthetic (G₂) phase of the mitotic cycle. In the pith-rib meristem, the following events were recorded: 1) a stimulation of DNA synthesis starting at 20 hr; 2) a rise of the mitotic index beginning at 28 hr; 3) the vacuolation and elongation of cells starting at 48 hr. All these events occurred well before the initiation of bract and flower primordia, which began at 96 and 136 hr, respectively. Neither stimulation of mitotic activity nor flowering occurred in the meristems of plants subjected to a long night interrupted at its midpoint by a 5-min light break. The results are discussed in relation to the early events which are known to occur in the meristems of other photoperiodic species in transition to flowering.     

Movement of Cell Organelles and the Geotropic Curvature in Roots of Norway Spruce (Picea abies)

The geotropic development in roots of Norway spruce [(Picea abies (L.)] H. Karst, has been followed by light and electron microscopy and compared with the movement of cell organelles (statoliths) in the root cap cells. The geotropic curvature develops in two phases: (a) an initial curvature in the root cap region, which results in an asymmetry in the extreme root tip and which appears after about 3 h stimulation in the horizontal position; and (b) the geotropic curvature in the basal parts of the root tip, which after 8 h is distributed over the entire elongation zone. A graphic extrapolation, based on measurements of the root curvatures after various stimulation periods, indicates a presentation time in the range of 8 to 10 min. The root anatomy and ultrastructure have been examined in detail in order to obtain information as to which organelles may act as gravity receptors. The root cap consists of a central core (columella) distinct from the peripheral part. The core contains three to four rows of parenchymatic cells each consisting of 15 to 18 storeys of statocyte cells with possibly mobile cell organelles. Amyloplasts and nuclei have been found to be mobile in the root cap cells, and the movement of both types of organelles has been followed after inversion of the seedlings and stimulation in the horizontal position for various periods of time at 4°C and 21°C. Three-dimensional reconstructions of spruce root cap cells based on serial sectioning and electron microscopy have been performed. These demonstrate that the endoplasmic reticulum (ER)-system and the vacuoles occupy a considerable part of the statocyte cell. For this reason the space available for free movement of single statolith particles is highly restricted.     

The Effect of Ultracentrifugation on Fine Structure and α-Amylase Production in Barley Aleurone Cells

Ultracentrifugation of barley aleurone cells results in the stratification of organelles thus allowing for a quantitation of those organelles. Gibberellic acid (GA₃)-stimulated α-amylase production in stratified cells is reduced by centrifugation at gravitational forces greater than 40,000g. Forces below 30,000g do not affect GA₃-stimulated α-amylase production although stratification of organelles occurs at these forces. The ability of centrifuged cells to respond maximally to GA₃ by producing α-amylase is related to the degree of redistribution of organelles within these cells. Thus, recovery of cells from centrifugation at forces below 30,000g is rapid, while recovery from forces above 40,000g is slow.     

Ultrastructure of poplar cortical cells during the transition from growing to wintering stages and vice versa

Summary Electron microscopic studies revealed that major cytological changes in the cortical cells of poplar (Populus euramericana cv. gelrica) began to occur in early September in conjunction with the metabolic transition from the growing to the wintering stage. During this transition, the cells became temporarily rich in endoplasmic reticulum, polysomes and vesicles. As the conspicuous formation of organelles progressed, the large vacuoles became smaller and filled with osmiophilic materials. Undefined organelles (protein-lipid bodies) also increased in number. From late October until March, organelles involved in protein synthesis were sparsely distributed in the cells, indicating that the number of these organelles is probably linked to the seasonal cycle of protein synthesis. In early February, after release from dormancy, fusion of vacuoles proceeded in the cells. The inclusion of organelles and a gradual decrease in the amount of osmiophilic materials in the vacuoles occurred at this stage. Subsequently, the structure of the cells continued to undergo changes to accommodate growth, which occurred in early May.     

Hydrogen Uptake and Methylene Blue Reduction Activities of Hydrogenase in Azotobacter agile

The Tritium (T) uptake method for detecting hydrogenase (Hase) was applied to measure the Hase activity of aerobic nitrogen-fixing bacterium Azotobacter agile. The cell-free extract of this bacterium contains the ATP-stimulated T-uptake activity, and this activity was separated from the nitrogenase activity. In the supernatant obtained by centrifugation at 20,000 × g for 30 min, this ATP-stimulated T-uptake activity existed mainly in large molecular weight fraction and was distributed to precipitate at 184,000 × g for 1 hr. After this ultra-centrifugation, the distribution patterns of methylene blue (MB) reduction and T-uptake activities were significantly different from each other, and MB reduction activity remained much more in the supernatant. The Hase activity detected by both T-uptake and MB reduction was mainly in the particle fraction precipitated at 20,000 × g for 30 min from the cell-free extract. When the activities of the praticle fraction were solubilized with Triton X–100, the ATP-stimulated T-uptake activity was effectively solubilized. These results imply that the cell-free extract of Azotobacter agile contained some different kinds of hydrogenases which catalyzed MB reduction, T-uptake and ATP-stimulated T-uptake activities at different intensities from each other.     

Cine-photomicrography of low temperature effects on cytoplasmic streaming, nucleoar activity and mitosis in single tobacco cells in microculture

Living, unstained, single tobacco (Nicoliana tabacum × N. glutinosa) cells (clone H-196) were grown in microcultures in liquid medium containing sucrose, mineral salts, coconut milk and 2,4-dichlorophenoxyaeetic acid. Time-lapse motion pictures were taken through interference and phase microscopes. The movement of cytoplasm and cell organelles gradually slowed and ultimately completely ceased as the cell was cooled by dry ice. The cessation of the movement of cell organelles took place between 5 and –7C. The typical cytoplasmic morphology was lost as the movement slowed. The cytoplasmic strands thinned out and numerous small vacuoles formed. During rewarming of the cell to room temperature, the vacuoles were replaced by numerous small globular masses of cytoplasm which reorganized into cytoplasmic strands. The normal movement of cytoplasmic strands and cell organelles was resumed. A number of small nucleolar vacuoles at room temperature gradually expanded and coaleseed to form a large central vacuole which underwent further expansion and then contracted rapidly. Four different concentric zones were visible across the nucleolar region. A white, highly reflecting, glossy substance appeared on the surface of the expanding vacuole. The position of the nucleus during contraction and expansion was never stationary. Some nucleolar vacuoles remained open for an indefinite period of time when the cell was cooled to 5C. No change was noticed during cooling, but during rewarming to room temperature, the nucleolar vacuole was partially closed. The pumping action of the nucleolar vacuole suggested important exchanges of metabolites between the nucleolus and the cytoplasm. A single cell of tobacco did not divide at –10C, but mitosis proceeded upon cooling the cell to – 12–15C for a brief period. Different phases of mitosis, specifically formation of the cell plate, cell wall, and separation of nuclei, were delayed by low temperature treatment.     

AUTOPHAGIC DEGRADATION OF GLYCOGEN IN SKELETAL MUSCLES OF THE NEWBORN RAT

Large amounts of glycogen accumulate in rat skeletal muscle fibers during the late fetal stages and are mobilized in the first postnatal days. This glycogen depletion is relatively slow in the immature leg muscles, in which extensive deposits are still found 24 hr after birth and, to some extent, persist until the 3rd day. In the more differentiated psoas muscle and especially in the diaphragm, the glycogen stores are completely mobilized already during the early hours. Section of the sciatic nerve 3 days before birth or within the first 2 hr after delivery does not affect glycogen depletion in the leg muscles. Neonatal glycogenolysis in rat muscle fibers takes place largely by segregation and digestion of glycogen particles in autophagic vacuoles. These vacuoles: (a) are not seen in fetal muscle fibers or at later postnatal stages, but appear concomitantly with the process of glycogen depletion and disappear shortly afterwards; (b) are prematurely formed in skeletal muscles of fetuses at term treated with glucagon; (c) contain almost exclusively glycogen particles and no other recognizable cell constituents; (d) have a double or, more often, single limiting membrane and originate apparently from flattened sacs sequestering glycogen masses; (e) are generally found to contain reaction product in preparations incubated from demonstration of acid phosphatase activity. The findings emphasize the role of the lysosomal system in the physiological process of postnatal glycogen mobilization and appear relevant in the interpretation of type II glycogen storage disease.