A STUDY OF NUCLEOLAR VACUOLES IN CULTURED TOBACCO CELLS USING RADIOAUTOGRAPHY, ACTINOMYCIN D, AND ELECTRON MICROSCOPY

Previously it has been found that in tobacco callus cells nucleolar vacuoles repeatedly form and contract. In this study, nucleolar vacuoles were investigated by using radioautography, actinomycin D, and electron microscopy. It was found, from grain counts of nucleoli labeled with uridine-³H, that nucleoli containing vacuoles had more than three times as many grains/µ² of nucleolar substance as did nucleolei without vacuoles. Treatment of tobacco callus cells with various concentrations of actinomycin D caused the percentage of cells containing nucleolar vacuoles to decrease; with the highest concentration the percentage of these cells dropped from the normal level of about 70% to less than 10%. However, after removal of actinomycin D the cells regained nucleolar vacuoles up to the control level. When radioautography was used with actinomycin D, it was found that the actinomycin D inhibited the uptake of uridine-³H, i.e. inhibited RNA synthesis, in those nucleoli which lost their nucleolar vacuoles. In addition, after removal of the cells from actinomycin D, it was found that as the cells regained nucleolar vacuoles the nucleoli also began to incorporate uridine-³H. Electron micrographs showed the nucleoli to be composed of a compact, finely fibrous central portion surrounded by a layer of dense particles 100–150 A in diameter. Nucleolar vacuoles occurred in the fibrous central portion. Dense particles similar to those in the outer layer of the nucleoli were found scattered throughout the vacuoles and in a dense layer at their outer edge. These data suggest that in cultured tobacco callus cells the formation and contraction of nucleolar vacuoles is closely related to RNA synthesis in the nucleolus.     

Organization of argyrophilic nucleolar material throughout the division cycle of meristematic cells

Summary The silver impregnation of nucleolar material facilitated the study of the morphological changes which take place in the nucleolus throughout the division cycle in root tip cells ofAllium cepa. The nucleolus appears to undergo no morphological changes throughout the interphase. It undergoes disorganization during the prophase, while in the telophase it appears uniformly on the chromatin as condensing into prenucleolar bodies.The appearance of the prenucleolar bodies is unaffected by puromycin, cordycepin, or ethidium bromide. This suggests that the argyrophilic material does not undergo synthesis during the telophase, nor require RNA or protein synthesis to effect the aggregation into prenucleolar bodies. However, the organization of nucleoli from prenucleolar bodies is inhibited by both cordycepin and ethidium bromide, suggesting that RNA synthesis is involved in this proccess.In aneuploid nuclei induced by treatment with colchicine we observed the appearance of prenucleolar bodies during the telophase even in the absence of the nucleolar organizer, but in this case the formation of nucleoli fails to take place. The nucleolar organizers proved to be capable of acting only in the nucleus to which they belong, but not on other nuclei within the same cytoplasm belonging to multinucleate cells.It seems logical to assume that one of the roles of the nucleolar organizer is related with the above-mentioned RNA synthesis, which is required to the aggregation of prenucleolar bodies into nucleoli.The work reported in the paper was undertaken during the tenure of a Research Training Fellowship awarded by the International Agency for Research on Cancer.     

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.     

THE FINE STRUCTURE OF THE NUCLEOLUS IN MITOTIC DIVISIONS OF CHINESE HAMSTER CELLS IN VITRO

The nucleolus of Chinese hamster tissue culture cells (strain Dede) was studied in each stage of mitosis with the electron microscope. Mitotic cells were selectively removed from the cultures with 0.2 per cent trypsin and fixed in either osmium tetroxide or glutaraldehyde followed by osmium tetroxide. The cells were embedded in both prepolymerized methacrylate and Epon 812. Thin sections of interphase nucleoli revealed two consistent components; dense 150-A granules and fine fibrils which measured 50 A or less in diameter. During prophase, distinct zones which were observed in some interphase nucleoli (i.e. nucleolonema and pars amorpha) were lost and the nucleoli were observed to disperse into smaller masses. By late prophase or prometaphase, the nucleoli appeared as loosely wound, predominantly fibrous structures with widely dispersed granules. Such structures persisted throughout mitosis either free in the cytoplasm or associated with the chromosomes. At telophase, those nucleolar bodies associated with the chromosomes became included in the daughter nuclei, resumed their compact granular appearance, and reorganized into an interphase-type structure.     

An electron-microscope study of the intranucleolar chromatin during nucleologenesis in root meristematic cells of Allium cepa.

The various states of condensation of the chromatin material contained inside the lacunar regions of the reforming nucleolus in Allium cepa, have been investigated by means of conventional electron-microscope techniques. The observations reveal that, in the emerging early to late telophase nucleoli, the intralacunar chromatin material in question appears both in an extended and a condensed condition; from late telophase th the mid G1 period of interphase, the intralacunar chromatin material of the rapidly growing and developing nucleoli is present in an extended state only. An attempt is made to interpret these morphological findings in the light of current knowledge concerning the structural relationship of the nucleolar organizing region of the nucleolar chromosome with the interphase nucleolus in plant cells. The relevant observational evidence would be consistent with the view that the chromatin-containing lacunar regions of the reforming nucleolus in Allium cepa correspond, in fact, to cross- or oblique sections of a meandering channel through which the nucleolar organizing segment of the nucleolar chromosome passes. Assuming the applicability to intranucleolar chromatin of the general concept of condensed-inactive versus extended-active chromatin, it is concluded that gradual uncoiling and subsequent decondensation of the chromatin of the nucleolar organizing region in the form of a convoluted loop structure are key morphological and functional events associated with the process of nucleologenesis in the species investigated.     

THE FINE STRUCTURE OF THE NUCLEOLUS DURING MITOSIS IN THE GRASSHOPPER NEUROBLAST CELL

The behavior of the nucleolus during mitosis was studied by electron microscopy in neuroblast cells of the grasshopper embryo, Chortophaga viridifasciata. Living neuroblast cells were observed in the light microscope, and their mitotic stages were identified and recorded. The cells were fixed and embedded; alternate thick and thin sections were made for light and electron microscopy. The interphase nucleolus consists of two fine structural components arranged in separate zones. Concentrations of 150 A granules form a dense peripheral zone, while the central regions are composed of a homogeneous background substance. Observations show that nucleolar dissolution in prophase occurs in two steps with a preliminary loss of the background substance followed by a dispersal of the granules. Nucleolar material reappears at anaphase as small clumps or layers at the chromosome surfaces. These later form into definite bodies, which disappear as the nucleolus grows in telophase. Evidence suggests both a collecting and a synthesizing role for the nucleolus-associated chromatin. The final, mature nucleolar form is produced by a rearrangement of the fine structural components and an increase in their mass.     

Control of nucleolar growth during interphase in higher plant meristem cells

Summary The evolution of nuclear and nucleolar sizes throughout interphase have been studied in synchronous caffeine-labeled binucleate cells of onion root meristems by using silver impregnation and stereological methods over semithin sections. Nucleus and nucleolus grow independently, since nucleolus enlarges at its fastest rate in G 1, while nucleus grows mostly in two periods: onset of replication and G 2. Nucleolar size in the cycle seems to be a genecontrolled function, hardly affected by protein synthesis inhibition. Hence, there is a biphasic response to cycloheximide (CHM) in the fast growing nucleoli of both early and late G 1 with an initial stimulation later counterbalanced by a depressed rate, so that nucleolar size in S was similar to control shortly afterwards the start of the CHM treatment. The initial enlargement under CHM was due to an increase of all nucleolar structural components, i.e., fibrillar, granular, vacuolar, and lacunar regions. No cycloheximide effect whatsoever was detected in S and G 2 nucleoli.Abbreviations CHM cycloheximide - F fibrillar component - G granular component - L lacunae - V vacuoles - VN nuclear volume - VNu nucleolar volume - VvNu volume density of the nucleoli     

ULTRASTRUCTURE OF THE NUCLEOLUS DURING THE CHINESE HAMSTER CELL CYCLE

Changes in the structure of the nucleolus during the cell cycle of the Chinese hamster cell in vitro were studied. Quantitative electron microscopic techniques were used to establish the size and volume changes in nucleolar structures. In mitosis, nucleolar remnants, "persistent nucleoli," consisting predominantly of ribosome-like granular material, and a granular coating on the chromosomes were observed. Persistent nucleoli were also observed in some daughter nuclei as they were leaving telophase and entering G₁. During very early G₁, a dense, fibrous material characteristic of interphase nucleoli was noted in the nucleoplasm of the cells. As the cells progressed through G₁, a granular component appeared which was intimately associated with the fibrous material. By the middle of G₁, complete, mature nucleoli were present. The nucleolar volume enlarged by a factor of two from the beginning of G₁ to the middle of S primarily due to the accumulation of the granular component. During the G₂ period, there was a dissolution or breakdown of the nucleolus prior to the entry of the cells into mitosis. Correlations between the quantitative aspects of this study and biochemical and cytochemical data available in the literature suggest the following: nucleolar reformation following division results from the activation of the nucleolar organizer regions which transcribe for RNA first appearing in association with protein as a fibrous component (45S RNA) and then later as a granular component (28S and 32S RNA).     

Persistent Nucleoli in Early Postimplantation of Rat Embryos

Ultrastructural changes of the nucleolus in mitotic embryonic ectodermal cells of 7 1/2-day and 7 2/3-day rat embryos were examined. It was found that the nucleolus was broken down into small fragments during late prophase and metaphase, and that some of these fragments persisted in the cytoplasm of telophase cell (persistent nucleoli). No interphase embryonic ectodermal cells contained persistent nucleoli. Persistent nucleoli were also found in telophase cells of extraembryonic ectoderm, extraembryonic visceral endoderm and parietal endoderm of the embryos, but they disappeared in interphase cells. Persistent nucleoli in telophase cells tended to decrease in size with embryonic age, and they had almost completely disappeared in neuroectodermal cells of the telencephalon in 14 1/2-day embryos. They were concluded to be remnants of disappearing nucleoli in embryonic cells that were cycling too rapidly to permit their nucleoli to disappear completely.     

Ultrastructural Changes of the Nucleolus During Cell Cycle in Triticum aestivum

The ultrastructural changes of the nticleolus during cell cycle in common wheat (Triticum aestivum L. ) were studied by an "en bloc" silver-staining method. It was observed that in interphase, the nucleolus was heavily stained, within which fibrillar centres, dense fibrillar component, granular component and nucleolar vacuoles could be identified. A large quantity of argentine fine granules were distributed in the condensed chromatin. Dur-ing prophase, along with the disintegration of the nucleolus and condensation of the chromatin, the larger heavily-stained granules gradually appeared at the periphery of the chromatin. At late prophase, the materials derived from the nucleolus were spread and deposited on the surface of the chromosomes. The silver-stained, larger granules, deriving from the disintegrated nucleolus, accumulated at the periphery of the metaphase chromosomes and formed an uneven and discontinuous "sheath"-like structure. This "sheath"-like structure was also observed at anaphase. In telophase, the silver-stained nucleolar materials were progressively separated from the "sheath' and fused with each other to form prenucleolar bodies, and at last, participating in the formation of new nucleoli. The results showed that the nucleolar materials were transferred directly to the surface of the chromosomes and formed a discontinuous coat, but not incorporated into the interior of the chromosomes. The silverstained granules inside the chromosomes were neither related to the nucleolus nor to the materials from the disintegrated nucleolus.     

小麦核仁在细胞周期中的变化

运用Bernhard染色方法研究了小麦根端分生组织细胞核仁在细胞周期中的变化。结果显示,间期核仁染色很深,能够区分出纤维中心（FC）、致密纤维组分（DFC）和颗粒组分（G）,而染色质被漂白,在染色质间可以观察到细小的RNP颗粒。进入前期,在染色质的边缘有小的RNP颗粒分布。中期,染色体周边分布着类似于间期核仁的深染的大RNP颗粒,形成一个不完全连续的“鞘”状结构;在染色体内部看不到类似核仁的深染颗粒。到了后期时,仍可见RNP“鞘”状结构的存在。进入末期,这些RNP植物逐渐由“鞘”脱离,最后参与新核仁的形成。这些结果表明,核仁解体后的物质直接转移到了中期染色的表面,并形成不连续的表层,没有进入染色体的内部。     

Behavior of silver stainable material during mitosis inVicia faba

To reveal the behavior of silver stainable material localized mainly in the nucleoli and nucleolar organizing regions (NORs), the somatic cells ofVicia faba were investigated by silver staining throughout the mitotic cell cycle. Nucleoli of interphase and early prophase nuclei were darkly stained. From late prophase to anaphase the secondary constrictions were discriminated as silver stained NORs and many silver grains appeared throughout the cytoplasm. At late prophase the NOR condensed at the same rate as the chromosome arm. Small spherical bodies and two new nucleoli appeared in telophase nuclei and at the same time the cytoplasmic grains disappeared. On the basis of the above observations on the silver stainable material during each mitotic phase, the behavior of silver stainable material is interpreted.     

The structure of the mitotic spindle and nucleolus during mitosis in the amebo-flagellate Naegleria

Mitosis in the amebo-flagellate Naegleria pringsheimi is acentrosomal and closed (the nuclear membrane does not break down). The large central nucleolus, which occupies about 20% of the nuclear volume, persists throughout the cell cycle. At mitosis, the nucleolus divides and moves to the poles in association with the chromosomes. The structure of the mitotic spindle and its relationship to the nucleolus are unknown. To identify the origin and structure of the mitotic spindle, its relationship to the nucleolus and to further understand the influence of persistent nucleoli on cellular division in acentriolar organisms like Naegleria, three-dimensional reconstructions of the mitotic spindle and nucleolus were carried out using confocal microscopy. Monoclonal antibodies against three different nucleolar regions and α-tubulin were used to image the nucleolus and mitotic spindle. Microtubules were restricted to the nucleolus beginning with the earliest prophase spindle microtubules. Early spindle microtubules were seen as short rods on the surface of the nucleolus. Elongation of the spindle microtubules resulted in a rough cage of microtubules surrounding the nucleolus. At metaphase, the mitotic spindle formed a broad band completely embedded within the nucleolus. The nucleolus separated into two discreet masses connected by a dense band of microtubules as the spindle elongated. At telophase, the distal ends of the mitotic spindle were still completely embedded within the daughter nucleoli. Pixel by pixel comparison of tubulin and nucleolar protein fluorescence showed 70% or more of tubulin co-localized with nucleolar proteins by early prophase. These observations suggest a model in which specific nucleolar binding sites for microtubules allow mitotic spindle formation and attachment. The fact that a significant mass of nucleolar material precedes the chromosomes as the mitotic spindle elongates suggests that spindle elongation drives nucleolar division.     

Nucleoli of cultured human lymphocytes

Summary Nucleolar fusion and nucleolus formation occurred simultaneously, immediately after mitosis, in cultured human lymphocytes. Evidence is presented that in late telophase and post-telophase, the individual nucleolar organising site includes two components, represented in post-telophase by the nucleolus and its attached process; that fusion can be either directly between the nucleoli or via the processes; and that the latter type of fusion persists into metaphase as acrocentric associations, whilst the former is lost.     

REFORMATION OF NUCLEOLUS-LIKE BODIES IN THE ABSENCE OF POSTMITOTIC RNA SYNTHESIS

The dependence of nucleolar reformation on RNA synthesis that resumes in late anaphase or early telophase has been investigated in synchronously dividing Amoeba proteus. RNA synthesis was completely inhibited throughout all stages of mitosis and the early hours of interphase with high concentrations of actinomycin D. In such cells, nucleolus-like bodies that bind azure B and pyronin were apparent in the reformed nuclei. The bodies appear as dense, fibrous masses with loosely associated, finely fibrillar material. There are no characteristic granular regions in the reformed structures. It is suggested that the bodies probably represent mainly nucleolar protein and residual RNA which can bring about the reorganization of nucleoli in the absence of postmitotic RNA synthesis.     

An autoimmune antibody from scleroderma patients recognizes a component of the plant cell nucleolus

Summary An auto-antibody from human serum of patients with the autoimmune disease scleroderma was used to localize the nucleolus in meristematic cells of onion and soybean roots using indirect immunofluorescence microscopy. Similar lots of antiserum recognized a single 34 kD, nucleolar protein, fibrillarin, in a variety of animal cells (Ochs, et al. 1984, 1985). In both plants, antibody linked fluorescence is associated with the one to several nucleoli present in the interphase nucleus. The fluorescence becomes diffuse around condensing prophase chromosomes and becomes more diffused at metaphase with slightly more intense fluorescence surrounding the chromosomes. At anaphase-telophase the fluorescence is localized in dense areas within the chromosomes, presumably representing prenucleolar bodies which will form the interphase nucleoli of the daughter nuclei. This antiserum provides a new, valuable tool for the study of the nucleolus and the highly conversed nucleolar antigen(s) that it recognizes.     

Structure of the nucleoli of developing microsporangiate strobili and root tips of scotch pine

Summary The characteristics of the nucleoli of the microsporangiate strobili and the root tips of Scotch pine (Pinus sylvestris L.) vary both during the course of the cellular cycle and, with regard to the pattern and stage of organ and tissue differentiation. Nucleologenesis takes place in interphase and the nucleoli last until prophase. Several types of nucleoli occur during the nucleolar cycle, the pattern and age of tissues determining which type or types dominate. In the strobilus primordia collected at the end of July and in August, the mitotic frequency is high. Nucleoli remain small throughout the nucleolar cycle, and at the electron microscopic level, they display intermingled fibrillar and fibrillogranular components. Strobilus primordia collected in September contain larger nucleoli in the sporogenous nuclei than in the nuclei of the tapetum or of the wall cells. Amongst the nucleoli with completely intermingled fibrous and granular material, nucleoli with nucleolonema or with vacuoles occur frequently. Small balls of fibrous material are seen on the nucleolar surface and in the nucleoplasm. In October, the mitotic frequency of strobilal cells is low. Nucleoli with completely intermingled fibrillar and granular components have vanished whereas a new, compact type of nucleolus with a dense fibrillogranular main portion and with nucleolonema, has developed. The nucleoli of the sporogenous cells have enlarged continuously whereas those of the wall cells are small. The nucleoli of the root tip cell resemble, to a certain extent, those of the strobilus primordia collected in September. In squashed preparations, the nucleoli of the strobilal cells bind the common nucleolar stains poorly whereas the nucleoli of the root cells can be stained with all the methods used. In certain cases, DNase treatment improves the stainability of the strobilal nucleoli. AgNO₃-staining is successful after acetic acid: alcohol fixation but not after formalin: hydrochinone fixation.