Further evidence that phosphoprotein C23 (110 kD/pI 5.1) is the nucleolar silver staining protein

Previously we demonstrated a similar distribution between nucleolar organizing region-(NOR)-specific silver staining and localization of nucleolar phosphoprotein C23 (MW 110 kD/pI 5.1) [1, 2]. We now report that under fixation conditions which allow for antibody binding and subsequent silver staining, monoclonal antibody against protein C23 blocks NOR silver staining as well as silver staining in interphase nucleoli. Monoclonal antibody against nucleolar phosphoprotein B23 (MW 37 kD/pI 5.1) did not block silver staining in either NORs or interphase nucleoli. These, along with earlier observations, provide evidence that nucleolar phosphoprotein C23 is the major silver staining protein of the nucleolus and that it is directly or indirectly associated with rDNA.     

Aurora-B regulates RNA methyltransferase NSUN2

Disassembly of the nucleolus during mitosis is driven by phosphorylation of nucleolar proteins. RNA processing stops until completion of nucleolar reformation in G(1) phase. Here, we describe the RNA methyltransferase NSUN2, a novel substrate of Aurora-B that contains an NOL1/NOP2/sun domain. NSUN2 was concentrated in the nucleolus during interphase and was distributed in the perichromosome and cytoplasm during mitosis. Aurora-B phosphorylated NSUN2 at Ser139. Nucleolar proteins NPM1/nucleophosmin/B23 and nucleolin/C23 were associated with NSUN2 during interphase. In mitotic cells, association between NPM1 and NSUN2 was inhibited, but NSUN2-S139A was constitutively associated with NPM1. The Aurora inhibitor Hesperadin induced association of NSUN2 with NPM1 even in mitosis, despite the silver staining nucleolar organizer region disassembly. In vitro methylation experiments revealed that the Aurora-B-phosphorylation and the phosphorylation-mimic mutation (S139E) suppressed methyltransferase activities of NSUN2. These results indicate that Aurora-B participates to regulate the assembly of nucleolar RNA-processing machinery and the RNA methyltransferase activity of NSUN2 via phosphorylation at Ser139 during mitosis.     

Evidence from studies on segregated nucleoli that nucleolar silver staining proteins C23 and B23 are in the fibrillar component

Several procedures for the silver staining of nucleoli have been evaluated at the electron microscopic level to determine optimal conditions for ultrastructural preservation and staining specificity. The present study shows that a brief fixation with 1% buffered formaldehyde followed by methanol: acetic acid (3 : 1) fixation yielded optimal preservation and silver staining of nucleoli. Using this procedure for electron microscopic studies of interphase nucleoli, it was found that the punctate silver grains observed by light microscopy were composed of fine silver granules, of approx. 100 Å diameter, organized in discrete clusters. In similar studies on adriamycin-induced segregated nucleoli, it was observed that the silver staining reaction was mainly limited to the fibrillar portion of the nucleolus. Accordingly, nucleolar proteins C23 and B23, found earlier to be the major silver binding proteins of the nucleolus, are mainly concentrated in the fibrillar nucleolar component.     

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     

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.     

Phosphoprotein pp135 is an essential component of the nucleolus organizer region (NOR)

The association of phosphoproteins pp135 and pp105 with distinct substructures of the nucleolus was studied by cytochemical and immunological methods at the light microscopic and electron microscopic level. Both phosphoproteins exhibited a very high affinity for silver and Giemsa staining compared to other nucleolar proteins. Immunolocalization of pp135 and pp105 during mitosis by light microscopy revealed a tight association of pp135 with the silver staining nucleolus organizer region (NOR), whereas pp105 (cross-reacting with C23) appeared to be only partially associated with the NOR, exclusively at telophase. At the immunoelectron microscopic level the distribution of pp135 and pp105 was investigated in interphase nucleoli. Phosphoprotein pp135 was located in the fibrillar shell and pp105 in the fibrillar shell and the granular zone. The fibrillar centers were essentially free of both phosphoproteins..     

Behaviour of nucleolus during mitosis

The aim of the present work was to study the distribution and the behaviour of the silver-staining nucleolar organizer region (Ag-NOR) proteins at the ultrastructural level during interphase and mitosis in five human and murine cancerous cell lines each characterized by a typical nucleolar morphology. During interphase the Ag-NOR proteins are restricted to the fibrillar centres (F.C.) and/or to the dense fibrillar component (D.F.C.). During prophase the silver-staining components come into close contact with some chromosomes and are arranged with a typical polarity: chromosome, F.C. and D.F.C. Then F.C. and D.F.C. together form roundish silver-stained structures and integrate in part within indentations at the periphery of the metaphase chromosomes. During anaphase and telophase large and small spherical silver-staining structures may be seen. They correspond respectively to the metaphase NORs and to numerous structures which appear de novo within ribonucleoprotein (RNP) material localized between the chromosomes. During late telophase the number of the small silver-staining structures decreases whereas the size of the larger ones increases. Then the interphase nucleoli recover their typical shape. These results suggest that when rRNA synthesis is impaired during mitosis the inactive NORs assume a structure and a localization which are not typical of the cell line. In contrast the F.C. and D.F.C. are probably two aspects of the NORs whose typical distribution, relative to the other nucleolar components, gives the interphasic nucleolus its characteristic morphology.     

The induction of nucleolar fragmentation and the inhibition of RNA synthesis in HeLa cells by MPB and their restoration

The effects of MPB on the staining intensity of pyronine G, the fine structure of HeLa cell nucleoli and RNA synthesis were investigated. MPB (50 μg/ml) produced a loss of pyronine G staining material (RNA) and fragmentation of nucleoli in HeLa cells within 3 h; however, these changes in nucleoli were rapidly reversed by removal of the drug. These morphological alterations of nucleoli were apparently related to the inhibitory action of MPB on nucleolar RNA synthesis in HeLa cells, and its reversibility.     

Localization of histones and their synthesis by ammoniacal silver reaction in meristematic root tip cells of Allium cepa

Summary The ammoniacal silver reaction was used for localization of histones in meristematic root tip cells of Allium cepa. Electron microscopic observations showed that yellow or brown colour of interphase and prophase nuclei and brown nucleolar colour produced in the reaction coincides with the appearance of silver grains, about 400 Å in diameter, in the interphase and prophase chromatin and nucleoli. This together with the complete absence of staining reaction and silver grains in the cytoplasm could mean quite a specific reaction with histones and might suggest also that in these cells the site of histone synthesis is in the nucleolus.     

Nucleolar silver-staining patterns related to cell cycle phase and cell generation of PHA-stimulated human lymphocytes

Silver staining (Ag-I) was used to investigate changes in the nucleolar structure of PHA-stimulated human lymphocytes through the phases of the cell cycle, G1, S and G2. Ag-I patterns and cell cycle phases of individual cells were assessed by sequential silver staining, Feulgen staining, DNA microdensitometry and 3H-thymidine autoradiography. The morphology and number of Ag-I nucleoli in a particular cell depended upon the phase of the cell cycle reached and on the number of generations the cell had passed through in culture. Resting, unstimulated cells usually had one small silver positive nucleolus. During blast transformation, the silver stained nucleoli increased in number and size, and then fused to form one very large, rounded or irregular-shaped nucleolus which was present through all cell cycle phases of the first reproductive cycle. Many lymphocytes developed a band-shaped nucleolus during their first S phase in culture. Lymphocytes at all cell cycle stages of the second and third generations after PHA-stimulation had multiple nucleoli whose combined areas approximated that of the single large nucleolus observed in first generation cells.     

Localization of nucleolar phosphoproteins B23 and C23 during mitosis

Nucleolar phosphoproteins B23 and C23 were simultaneously localized in unsynchronized male rat-kangaroo PtK2 cells during mitosis using a mouse monoclonal antibody against protein B23 and a rabbit antibody against protein C23. The distribution of proteins B23 and C23 during mitosis was compared with the distribution of the silver staining protein. During interphase, proteins B23 and C23 were both localized to the nucleolus. As the nucleolus disappeared in prophase, the distribution of protein B23 became nucleoplasmic, whereas most of protein C23 remained associated with the disappearing nucleolus. Throughout metaphase and anaphase protein B23 was found associated with the chromosomes, whereas protein C23 seemed to disappear. When the nucleolus reformed during telophase, protein C23 appeared first in ‘prenucleolar bodies’ and then in the nucleolus, whereas protein B23 did not appear in the nucleolus until late telophase or early G1 phase. Silver staining during mitosis closely paralleled the distribution of protein C23, supporting previous conclusions that protein C23 is a silver staining nucleolus organizer region (NOR) protein [19, 20].     

Laser microbeam irradiation of the juxtanucleolar region of prophase nucleolar chromosomes

To further understand the function of the nucleolus organizer (NO), especially as it relates to the mitotic cycle, we extended our previous irradiation studies to prophase chromosomes and nucleoli. The juxtanucleolar region of nucleolar chromosomes was irradiated with the argon laser microbeam, and cells were observed for several days. Nuclei with two nucleoli were generally chosen for irradiation because of their two clear secondary constrictions. Summarized results are as follows: (1) When either one or several juxtanucleolar sites of both or all nucleoli are irradiated, the mitotic process is blocked and the cells return to interphase. (2) When only the chromosomes associated with the largest nucleolus are irradiated, mitosis is also blocked. (3) When the juxtanucleolar regions of the smallest nucleolus are irradiated, the cells generally go into metaphase and complete division, but with a reduction in the number of resulting nucleoli. (4) When the nucleoli themselves are irradiated, mitosis proceeds and daughter nuclei show no reduction in nucleolar number. (5) When chromosomes are randomly irradiated at non-juxtanucleolar regions, the nucleus divides and produces the same number of nucleoli in each daughter nucleus as were present in the mother cell.     

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.