Scattering of the silver-stained proteins of nucleolar organizer regions in Ishikawa cells by actinomycin D.

Scattering of the silver-stained proteins of nucleolar organizer regions (Ag-NOR proteins) was produced by actinomycin D in Ishikawa cells. Scattering of Ag-NOR proteins was found only in cells treated with actinomycin D and various other agents had no effect. Scattering was dose-dependent up to 10(-2) micrograms/ml of actinomycin D, but it was not found at higher concentrations that caused marked inhibition of total DNA and RNA synthesis. Actinomycin D (10(-2) micrograms/ml) caused the following changes: (i) nucleolar segregation and (ii) emergence of dense fibrillar bodies in the nucleoplasm. Ag-NOR proteins were observed on the fibrillar centers and surrounding fibrillar components in control nucleoli, on the fibrillar and amorphous zones in segregated nucleoli, and on the dense fibrillar bodies emerging in the nucleoplasm. The scattering of Ag-NOR proteins was due to the argyrophilic nature of the dense fibrillar bodies. Actinomycin D (10(-1) micrograms/ml) also caused similar morphological alterations in the nucleolus and nucleoplasm, but Ag-NOR proteins were observed only on nucleolar remnants.     

Structural organization of chromatin in nucleolar organizer regions of nucleoli with a nucleolonema-like and compact ribonucleoprotein distribution

We have studied the relationship between the structural organization of intranucleolar chromatin and fibrillar nucleolar structures, fibrillar centers, and RNP fibrillar component, which are the interphase counterpart of metaphase nucleolar organizer regions (NORs), in regenerating rat hepatocytes and in a human tumor cell line (TG cells). These two cell types were characterized by a nucleolonema-like and compact nucleolar RNP distribution, respectively. We found that, in sections selectively stained for DNA, the intranucleolar chromatin composed of extended, nonnucleosomal DNA filaments formed roundish agglomerates with a spatial distribution which was superimposable on that of the fibrillar centers and the RNP fibrillar component around them and on sites of the silver reaction in samples selectively stained for Ag-NOR proteins. The agglomerates of extended nonnucleosomal DNA filaments were small and numerous in regenerating hepatocyte nucleoli, in which the RNP components had a nucleolonema-like distribution, whereas they were large and few in TG cell nucleoli, in which the RNP components showed a compact organization. Since the pattern of ribosomal RNA synthesis and processing was similar in the two cell types, a model was proposed in which the difference in size and shape of the agglomerates of extended DNA might be responsible for the different structural organization of the RNP components.     

DISTINCTIVE CHARACTERISTICS OF NUCLEOLI OF TWO ESTABLISHED CELL LINES

Nucleoli of cultured cells of the established lines KB and L were found to possess a distinctive fine structural organization. The major portion of the nucleolar volume was composed of compact, particulate material. Spheroidal fibrillar zones about 0.4 µ in diameter occurred within the particulate mass. These fibrillar zones had a central light area and a denser rim. Toyocamycin treatment, which sharply inhibited the appearance of newly synthesized RNA in the cytoplasm, caused the gradual disappearance of the fibrillar material from nucleoli. Actinomycin D treatment, which inhibited virtually all RNA synthesis, caused varying types of segregation of nucleolar components. The morphology of nucleoli of KB and L cells and the reorganization of these nucleoli in response to drugs appear to be different from those of nucleoli of freshly initiated Chinese hamster and mouse cell lines.     

Response of interphasic nucleoli to hypoxia in root meristems

Hypoxia produces structural changes in interphasic nucleoli of Allium cepa L. root meristems. Following segregation, the fibrillar portion of nucleoli seems to be extruded in masses, accessory bodies, which stay in nucleoplasm. Such bodies apparently leave the fibrillar portion in places which seem to correspond to insertion areas of the nucleolar organizers in nucleoli. Reversal of these changes is rapidly obtained when oxygenation is restored. Accessory bodies differ from prenucleolar bodies since they are compact and homogeneous and they do not display segregation under hypoxia.     

REPOPULATION OF POSTMITOTIC NUCLEOLI BY PREFORMED RNA : II. Ultrastructure

The reconstruction of the nucleolus after mitosis was analyzed by electron microscopy in cultured mammalian (L929) cells in which nucleolar RNA synthesis was inhibited for a 3 h period either after or before mitosis. When synchronized mitotic cells were plated into a concentration of actinomycin D sufficient to block nucleolar RNA synthesis preferentially, nucleoli were formed at telophase as usual. 3 h after mitosis, these nucleoli had fibrillar and particulate components and possessed the segregated appearance characteristic of nucleoli of actinomycin D-treated cells. Cells in which actinomycin D was present for the last 3 h preceding mitosis did not form nucleoli by 3 h after mitosis though small fibrillar prenucleolar bodies were detectable at this time. These bodies subsequently grew in size and eventually acquired a particulate component. It took about a full cell cycle before nucleoli of these cells were completely normal in appearance. Thus, nucleolar RNA synthesis after mitosis is not necessary for organization of nucleoli after mitosis. However, inhibition of nucleolar RNA synthesis before mitosis renders the cell incapable of forming nucleoli immediately after mitosis. If cells are permitted to resume RNA synthesis after mitosis, they eventually regain nucleoli of normal morphology.     

Inhibition of nucleolar reformation after microinjection of antibodies to RNA polymerase I into mitotic cells

The formation of daughter nuclei and the reformation of nucleolar structures was studied after microinjection of antibodies to RNA polymerase I into dividing cultured cells (PtK2). The fate of several nucleolar proteins representing the three main structural subcomponents of the nucleolus was examined by immunofluorescence and electron microscopy. The results show that the RNA polymerase I antibodies do not interfere with normal mitotic progression or the early steps of nucleologenesis, i.e., the aggregation of nucleolar material into prenucleolar bodies. However, they inhibit the telophasic coalescence of the prenucleolar bodies into the chromosomal nucleolar organizer regions, thus preventing the formation of new nucleoli. These prenucleolar bodies show a fibrillar organization that also compositionally resembles the dense fibrillar component of interphase nucleoli. We conclude that during normal nucleologenesis the dense fibrillar component forms from preformed entities around nucleolar organizer regions, and that this association seems to be dependent on the presence of an active form of RNA polymerase I.     

Ultrastructure of trophocyte nuclei in polytrophic ovarioles of Chrysopa perla (Neuroptera)]

The light and electron microscope and autoradiographic studies (H3-uridin incorporation) were carried out on the trophocyte nuclei of imago polytrophic ovarioles of Chrysopa perla (Neuroptera), from the trophocyte differentiation up to their degeneration. Like the oocytes, one of the seven nurse cells o every ovariole chamber contains extrachromosomal DNA bodies. This nurse cell is formed during differential mitoses in the germarium as one of two prooocytes. In contrast to extrachromosomal DNA of oocytes the trophocyte DNA bodies are less active structures. Several (2--4) complex nucleoli develop in the trophocytes of Chrysopa in the early stages of oogenesis. They consist of three main components: the chromatin mass, fibrillar bodies and granular strands. Such nucleoli grow, through increasing in number of fibrillar bodies and granular strands. They are most developed by the start of the vitellogenesis. At the middle vitellogenesis the general nucleolar structure modify due to the beginning of trophocyte degeneration. The consecutive stages of nuclear degeneration are described. The trophocyte nucleoli synthesize RNA still in germarium. The most intensive RNA synthesis is observed at the beginning of the vitellogenesis to decrease by the beginning of trophocyte degeneration.     

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.     

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.