Localization of chromatin in "persistent" nucleoli in okadaic acid treated HeLa cells.

In okadaic acid treated HeLa cells, the chromosomes sometimes condense without being accompanied by nuclear envelope breakdown. These cells show "persistent" nucleoli. Within these "persistent" nucleoli the intranucleolar chromatin condenses and can be observed in the region of the dense nucleolar component (DNC) of the nucleoli. Other nucleolar components, namely the fibrillar centre (FC) and the granular component (GC) remain unchanged. These observations strongly speak for the localization of nucleolar chromatin (ribosomal cistrons) within the dense nucleolar component of the interphase nucleolus.     

Ultrastructural Distribution of DNA within Plant Meristematic Cell Nucleoli during Activation and the Subsequent Inactivation by a Cold Stress

We have investigated the precise location of DNA within the meristematic cell nucleolus ofZea maysroot cells andPisum sativumcotyledonary buds, in the course of their activation and induced inactivation following a subsequent treatment at low temperature. For this purpose, we combined the acetylation method, providing an excellent distinction between the various nucleolar components, with thein situterminal deoxynucleotidyl transferase-immunogold technique, a highly sensitive method for detecting DNA at the ultrastructural level. In addition to the presence of DNA in the condensed chromatin associated with the nucleolus, we demonstrated that a significant label was detected in the nucleolus of quiescent cells in both plant models. Evident labels were also found in the dense fibrillar component of actived nucleoli. Whereas in inactivated nucleoli no significant label was observed within the dense fibrillar component, an intense label was seen over the large heterogeneous fibrillar centres only during inactivation. The granular component was never significantly labelled. These results appear to indicate that the DNA present in the dense fibrillar component of activated nucleoli withdraws from this structure during its inactivation and becomes incorporated in the large fibrillar centres. These observations suggest that in plant cells inactivation of rRNA genes is clearly accompanied by changes in the conformation of ribosomal chromatin.     

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).     

A comparative study of the main components of the nucleolus in different populations of rat trophoblast cells during differentiation. II. The nucleoli of the trophospongium cells, the glycogen cells and the secondary giant cells

A comparative study was performed of the arrangement of different nucleolar components during differentiation of trophoblast cell populations in the junctional zone of placenta (glycogen cells and trophospongium) and in the secondary giant cells. Each cell type is characterized by specific interrelation of nucleolar components. Some glycogen cells show signs of segregation of nucleolar components: strands of nucleolar components with fibrillar centers (FCs) are displaced to the periphery of the nucleolus and contact with the perinucleolar chromatin. Large reticular nucleoli in trophospongium cells contain many FCs which are gathered into several "chains" by strands of dense fibrillar component. Such a "chain" has also been found in nucleoli of secondary giant cells, with greater number of FCs in each "chain". Relationship between the arrangement of nucleolar components and the level of cell differentiation is discussed.     

The fine structure of nuclei as revealed by electron microscopy

Summary The process of nucleolus formation has been studied by electron microscopy in spermatogonia of new-born, 15-day-old mice. One of two heteropycnotic sex chromosomes is concerned with nucleolus formation in the type A spermatogonia. The evidence for such formation has been presented with regard to behaviour and fine structure of both sex chromosome and nucleolus, Nucleolar material appears at one of two heteropycnotic sex chromosomes which are closely attached to the nuclear envelope. The two sex chromosomes approach each other, and subsequently one of them migrates into the central part of the nucleoplasm, being related to the nucleolar material which develops to show a nucleolar configuration. The sex chromosomes are homogeneously electron dense during the nucleolus formation, but assume a vesicular form at the middle stage of its development. The nucleolus is mostly of fibrillar and amorphous components at early stages of its development, but the granular components increases in amount as development proceeds. The final, mature nucleolus is composed of irregularly twisted nucleolonemata consisting of granular components, separated from fibrillar and amorphous areas. The compactly dense sex chromosome remains closely connected with the mature nucleolus.     

Relative position of nucleolar chromatin and nucleolar components in ciliate <Emphasis Type="Italic">Didinium nasutum</Emphasis> somatic nuclei

According to our computer modeling data obtained earlier, nucleoli in interphase ciliates Didinium nasutum are complex netlike structures, in which the trabeculumor lamella-shaped fibrillar component is located on the periphery, and the granular component in the central part of the nucleolus. Chromatin bodies connected with nucleoli act as the nucleolar organizers in D. nasutum. In the present work, the arrangement of all chromatin bodies, which could correspond to nucleolar organizers by morphological criteria, is studied by means of a 3D-reconstruction. It is shown that all of these chromatin bodies are localized outside the nucleoli, on the fibrillar component’s periphery. Even those chromatin bodies which appeared to be completely surrounded by the fibrillar nucleolar component on single ultrathin sections are actually settled down in nucleolus cavities open to the nucleoplasm. This proves that the RNA processing in D. nasutum nucleoli is directed toward the center of nucleoli, where the granular component is located. The analysis of the nucleolar chromatin distribution made it possible to conclude that different parts of the complex interfase netlike nucleoli of D. nasutum have approximately the same activity.     

Conformation of RNA in situ as studied by acridine orange staining and automated cytofluorometry.

Human erythroblasts which are prereticulocyte maturation stages of red blood cells were studied by light microscopic cytochemistry and electron microscopy to provide more information on the ultrastructure of the micronucleoli which are terminal stages of nucleolar changes found during maturation of these cells. As indicated by light microscopy of smeared cells, micronucleoli were virtually the only types of nucleoli present in the last stages of maturing erythroblasts, i.e., polychromatic and orthochromatic (late polychromatic) erythroblasts. Accordingly, they were not portions of the periphery of other nucleoli. Inasmuch as most of the micronucleoli exhibited characteristic segregation of nucleolar fibrillar and granular components they presumably are producing little if any preribosomal RNA, since such segregation generally reflects inhibition of nucleolar RNA synthesis.     

The nucleolus and its modifications during oogenesis of Torpedo marmorata

The structural organisation of the nucleolar apparatus during oogenesis of the spotted ray Torpedo marmorata was investigated. The observations showed that unlike other cartilaginous fishes, in T. marmorata the nucleolar apparatus was always represented by one or two conspicuous nucleoli, whose organization significantly changed during oocyte development. In the smallest follicles (follicles <300 μm in diameter) the nucleolus was made up of granular and fibrillar components, and actively incorporated ³H uridine; later it becomes more and more electron‐dense so in follicles of 400 μm in diameter its components and ³H uridine incorporation were no longer evident. These results indicate that in T. marmorata the nucleolar apparatus significantly changes and undergoes a possible impairment in rRNA synthesis. After nucleolus inactivation, the synthesis of rRNA may be substained by granulosa.     

Fine structure of nucleoli in micronucleated cells

The correlation between the number of nucleolus organizing regions (NOR) on metaphase chromosomes and the number of nucleoli was studied in normal and micronucleate cells. Many micronuclei, but not all, were able to form complete nucleoli with fibrillar and granular RNP components and fibrillar centers. Micronuclei which failed to form complete nucleoli often contained multiple electron-dense bodies of fibrillar material. These structures, which were much smaller than nucleoli, reacted with nucleolus-specific antibodies and the Ag-As method in the same way as complete nucleoli, but lacked fibrillar centers and granular RNP components. The data suggest that these nucleolus-like ‘blobs’ contain nucleolar material which, following mitosis, has been enclosed in micronuclei which do not contain nucleolus organizing chromosomes. No evidence was found for the activation of latent NORs not expressed in mononucleate cells.     

An InCytes from MBC Selection: Nucleolar Separation from Chromosomes during Aspergillus nidulans Mitosis Can Occur Without Spindle Forces

How the nucleolus is segregated during mitosis is poorly understood and occurs by very different mechanisms during closed and open mitosis. Here we report a new mechanism of nucleolar segregation involving removal of the nucleolar-organizing regions (NORs) from nucleoli during Aspergillus nidulans mitosis. This involves a double nuclear envelope (NE) restriction which generates three NE-associated structures, two daughter nuclei (containing the NORs), and the nucleolus. Therefore, a remnant nucleolar structure can exist in the cytoplasm without NORs. In G1, this parental cytoplasmic nucleolus undergoes sequential disassembly releasing nucleolar proteins to the cytoplasm as nucleoli concomitantly reform in daughter nuclei. By depolymerizing microtubules and mutating spindle assembly checkpoint function, we demonstrate that a cycle of nucleolar “segregation” can occur without a spindle in a process termed spindle-independent mitosis (SIM). During SIM physical separation of the NOR from the nucleolus occurs, and NE modifications promote expulsion of the nucleolus to the cytoplasm. Subsequently, the cytoplasmic nucleolus is disassembled and rebuilt at a new site around the nuclear NOR. The data demonstrate the existence of a mitotic machinery for nucleolar segregation that is normally integrated with mitotic spindle formation but that can function without it.     

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.     

Nucleolus-like bodies in micronuclei of cultured Xenopus cells

Two of the 36 chromosomes in Xenopus laevis are known to carry nucleolar organizer loci. Partitioning of the chromosomes of cultured, early-passage Xenopus cells among variable numbers of micronuclei could be induced by extended colcemid treatment. A large, obvious nucleolus occurred in a maximum of 4 micronuclei per colcemid-induced tetraploid cell. The large, deeply-stained nucleoli incorporated [³H]uridine and appeared by electron microscopy to have typical nucleolar morphology with fibrillar and granular areas disposed in nucleolonema. In situ hybridization to radioactive ribosomal RNA (rRNA) resulted in heavy labelling of nucleoli in no more than 4 micronuclei per cell. The other micronuclei generally contained small bodies (blobs) which stained for RNA and protein as well as with ammoniacal silver. In the electron microscope, these appeared as round, dense bodies resembling nucleoli segregated by actinomycin D treatment. Nucleoplasmic RNA synthesis occurred in all micronuclei regardless of whether they contained definitive nucleoli. These observations suggest that micronuclei which formed large, typical, RNA-synthesizing nucleoli contained nucleolar organizer chromosomes, while the other micronuclei, which contained nucleolus-like “blobs” probably lacked nucleolar organizer loci. It is possible that the nucleolus-like bodies may have been aggregates of previously synthesized nucleolar RNA and protein trapped in micronuclei after mitosis.     

REFORMATION OF NUCLEOLI AFTER ETHIONE-INDUCED FRAGMENTATION IN THE ABSENCE OF SIGNIFICANT PROTEIN SYNTHESIS

The rat liver nucleolus, after fragmentation induced by ethionine treatment, has been found to undergo complete reformation by adenine in the presence of a dose of cycloheximide sufficient to cause inhibition of protein synthesis by 90–95%. In contrast, actinomycin D given along with adenine was followed by the appearance of a small compact mass containing only the fibrillar component with no evident granules. This structure resembled pseudonucleoli seen in the anucleolate mutant of Xenopus laevis or in certain early stages of amphibian oocytes. Actinomycin D administered 2 hr after adenine induced a segregation of the fibrillar and granular components of nucleoli similar to that induced in the normal nucleolus. The implications of these findings in relation to nucleolar organization are briefly discussed.