Electron Microscopic Studies on the Silver-stained Nucleolar Cycle of Physarum polycephalum

The dynamic changes of nucleolar ultrastructure in the cell cycle of Physarum polycephalum Schw. were studied by an en bloc silver-staining method. The results showed that the nucleolus was large in size and situated in the center of the nucleus in late G2-phase, and the fibrillar centers, dense fibrillar components and granular components could be observed in the nucleolus. During prophase, the nucleolus moved towards the periphery of the nucleus and in late prophase disintegrated near the nuclear envelope. In metaphase, the disintegrated nucleolar components were dispersed in masses and located at the periphery of the chromosomal region of the nucleus. No specifically silver-stained area and argentophilic protein sheath were observed on the chromosomes, but there were some big dispersed silver particles within the chromosomes. During telophase the nucleolar components moved towards the two poles along with the chromosomes and co-existed with the decondensing chromatin in daughter nuclei. The nucleolar components then gradually converged with one another and separated from the chromatin. A big nucleolus was formed in the nucleus about 120 min after the completion of mitosis.     

Semiautomatic quantification of silver-stained nucleolar organizer regions in tissue sections and cellular smears.

Silver staining of nucleoli reveals argyrophilic proteins associated with nucleolar organizer region (Ag-NOR) proteins. Argyrophilic components appear as dots about 1 micron in diameter dispersed throughout the nucleolus (Ag-NOR dots). The count of Ag-NOR dots is a useful index for improving the cancer diagnosis and determination of prognosis. Here we describe software developed on a medium-cost image analyzer in order to evaluate the mean area of NORs and their number relative to an internal reference, the number and areas of clusters of NORs and the area of the nucleus. Statistical analysis of the data was performed during counting. The first application concerned counting NOR dots during mitosis in cell imprints; those counts were 2.3, 15.3 and 55.56 for the metaphase, telophase and interphase, respectively (relative to unitary dots of metaphase cells). In the second application we demonstrated a significant difference in NOR numbers between two groups of prostatic cancers with good and poor prognoses (6.05 +/- 2.79 SD and 7.96 +/- 3.01, respectively; with Student's t test, = 1.999; P = .05).     

Morphometric study of nucleolus-organizing regions of chromosomes from swine embryo kidney cells during Go-, G2-period and mitosis

Quantitative characteristics of nucleolus-organizing regions of chromosomes (NORs, or fibrillar centers, FCs) and some other nucleolar components have been studied with the aid of complete series of ultrathin sections of PK-cells. It has been found that: 1) the number of FCs per cell in the G0-period, in the G2-period and at metaphase is equal to 7.0, 33.7 and 8.0, respectively; 2) volumes of individual FCs in the G0-period (0.033 micron 3), G2-period (0.014 micron 3) and at metaphase (0.025 micron 3) are different; 3) the total volume of FCs, calculated for a haploid set of chromosomes, do not differ in the G0 (0.105 micron 3) and G2 (0.107 micron 3) periods, but exceed twice the FCs volume at metaphase (0.04-0.05 micron 3). These data show that the activation and inactivation of ribosomal genes in interphase PK-cells are not accompanied by a change in the total volumes of FCs and are probably connected with the "fragmentation" and fusion of FCs. Complete inactivation of ribosomal genes at mitosis leads to a decrease in the total volumes of FCs; 4) the nucleolus volume is proportional to the volume of the dense fibrillar RNP-component; in the G2-period the nucleolus volume also correlates with the number of FCs (r = 0.99); 5) the volume of the dense fibrillar component within individual fibrillar complexes--the structures corresponding to one nucleolus-organizing region--is not constant. This is an indirect evidence for the differences in the functional activity of NORs of different chromosomes.     

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.     

Nucleologenesis: use of non-isotopic in situ hybridization and immunocytochemistry to compare the localization of rDNA and nucleolar proteins during mitosis

Using in situ hybridization and immunocytochemistry during interphase and mitosis, we have compared the distribution of ribosomal DNA (rDNA) to that of the nucleolar proteins fibrillarin and RNA polymerase I. During interphase, nucleolar proteins were localized at sites throughout the nucleolus while the bulk of rDNA was localized in a single restricted nucleolar area. During metaphase and anaphase, all six NORs were detected by in situ hybridization, Ag-staining, or by the immunolocalization of RNA polymerase I. During telophase, rDNA and RNA polymerase I were found in a distinct subset of the prenucleolar bodies (PNBs) which obviously must contain the nucleolar organizers. Other numerous PNBs are smaller in size and do not contain detectable amounts of rDNA or RNA polymerase I. Therefore, reconstruction of the nucleolus originates in telophase-specific domains which contain both rDNA and RNA polymerase I.     

多头绒泡菌银染核仁周期的电镜研究

以同步化培养的多头绒泡菌（Physarum poldycephalum Schw.)原生质团为材料,应用整体银染技术,电镜下研究了核仁在细胞周期中的超微结构变化。结果变化：核仁成熟时比较大,位于细胞核中央,核仁内可区分出纤维中心、密集纤维成分和颗粒成分等。前期时,核仁向边缘移动,前期末在近核膜处解体,解体的核仁物质主要呈团块状散开。中期时,解体的核仁物质位于细胞核中央染色体区域的周围,染色体上没有特异的银染区域,染色体周边也看不到银染的“鞘”状结构,但在染色体中可见一些散在的银染大颗粒。末期时,核仁物质与染色体一起到达两极,在子细胞核中与正在解集缩的染色质共存一起,以后核仁物质逐渐汇合并与染色质分开。大约在有丝分裂结束120min后,在细胞核中形成一候 中央位置的大核仁,结果提示,低等真核生物的核仁结构和周期变化与高等真核生物的不完全相同。     

Ultrastructural localization of Ag-NOR stained proteins in the nucleolus during the cell cycle and in other nucleolar structures

EM investigation of Ag-AS-NOR staining after short glutaraldehyde prefixation followed by Carnoy fixation maintained good ultrastructural preservation and reactive selectivity. This enables exact localization of silver deposits both in the fibrillar centers of typical or segregated nucleoli during interphase, and in chromosome NORs during mitosis. These results argue in favour of the possibility that fibrillar centers are the interphasic counterpart of chromosome NORs. Special structures such as nucleolar blobs and remnants usually considered to be of nucleolar origin, were also stained. — These findings seem to indicate a relationship between the distribution of the silver-stained proteins, the arrangement of the nucleolar structures and the degree of nucleolar activity resulting from the experimental conditions. These results are of interest at the time when the concept of the nucleolar matrix is gradually emerging.     

MITOSIS IN THE ALGA VACUOLARIA VIRESCENS

Details of mitosis in the chloromonadophycean alga Vacuolaria virescens Cienk. have been studied with the light microscope. The chromosomes are relatively large (up to μ in length at metaphase) and so mitotic stages are readily distinguishable. Chromosomes can be recognized in interphase nuclei as fine strands of chromatin. Contraction of these chromosomes marks the beginning of mitosis and continues progressively until the transition from metaphase to anaphase. Disintegration of nucleoli is complete by late prophase and nucleolar reformation begins in telophase. Some chromosomes exhibit less densely stained regions; centromeres are also present as indicated by their differential staining and by the behavior of chromosomes at metaphase and anaphase. At anaphase progeny chromosomes move apart parallel to the division axis of the nucleus. As anaphase progresses the chromosomes fuse at the polar surface of the progeny chromosome groups. This process continues in telophase and the chromosome groups become more spherical. By the end of telophase nucleolar reformation has begun and the chromosomes have relaxed to their interphase condition.     

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.     

Silver staining,immunofluorescence, and immunoelectron microscopic localization of nucleolar phosphoproteins B23 and C23

Nucleolar organizer region (NOR)-specific silver staining and immunolocalization of nucleolar phosphoproteins B23 and C23 were compared in Novikoff hepatoma ascites cells. Silver staining and protein C23 immunostaining were both localized in the fibrillar shell surrounding the fibrillar center and in the fibrillar center. During mitosis, silver staining and protein C23 were localized at the NORs. Therefore, protein C23 and the silver-staining protein both seem to be associated with rDNA-containing structures (Mirre and Stahl 1981). A comparison of toluidine blue staining specific for RNA and B23 immunostaining demonstrated that protein B23 was associated with RNA-containing regions of the nucleolus and was absent from the fibrillar centers. Localization of these proteins and their functions are discussed in relation to the organization of the nucleolus.     

Localization of Nopp140 within mammalian cells during interphase and mitosis

We investigated distribution of the nucleolar phosphoprotein Nopp140 within mammalian cells, using immunofluorescence confocal microscopy and immunoelectron microscopy. During interphase, three-dimensional image reconstructions of confocal sections revealed that nucleolar labelling appeared as several tiny spheres organized in necklaces. Moreover, after an immunogold labelling procedure, gold particles were detected not only over the dense fibrillar component but also over the fibrillar centres of nucleoli in untreated and actinomycin D-treated cells. Labelling was also consistently present in Cajal bodies. After pulse-chase experiments with BrUTP, colocalization was more prominent after a 10- to 15-min chase than after a 5-min chase. During mitosis, confocal analysis indicated that Nopp140 organization was lost. The protein dispersed between and around the chromosomes in prophase. From prometaphase to telophase, it was also detected in numerous cytoplasmic nucleolus-derived foci. During telophase, it reappeared in the reforming nucleoli of daughter nuclei. This strongly suggests that Nopp140 could be a component implicated in the early steps of pre-rRNA processing.     

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.     

The three-dimensional ultrastructure of interphasic and metaphasic nucleolar argyrophilic components studied with high-voltage electron microscopy in thick sections

The three-dimensional structure of the nucleolar argyrophilic components was studied by recording stereo-pairs of tilted thick sections--0.5-2 microns thick--observed with 200 and 300 kV high-voltage electron microscopy (HVEM). Using a very specific silver staining method, the argyrophilic components were stained with a high contrast relatively to the unstained background, thus allowing their study with a high resolution within thick sections. This study was performed on compact nucleoli (of HL60 and K562 cells), on reticulated nucleoli (of human breast cancerous cells) and on metaphasic nucleolar organizer regions (NORs). In compact nucleoli argyrophilic components show a 'knotted rope-like' structure in which knots are constituted of one central fibrillar centre surrounded at some distance by loops of the dense fibrillar component and in which the rope is constituted of dense fibrillar component. In reticulated nucleoli silver deposits are confined to the surface of the nucleolonema as several strands twisted at the periphery of the fibrillar component. During metaphase some NORs get a characteristic crescent-shaped structure disposed at the periphery of some chromosomes.     

Studies on changes in nucleolar organizer region of human promyelocytic leukemia cells (HL-60) treated with retinoic acid

Changes of nucleolar organizer region in HL-60 cells after treated with retinoic acid (RA) were studied with techniques of silver-staining nucleolar organizer region (Ag-NOR) in metaphase karyotypes, Brachet's reaction and with our improved TEM techniques for studying silver-stained active nucleolar organizer region (Ag-aNOR) in interphase nucleoli. Number of Ag-NOR in HL-60 cells is 4.5/cell on average. The Ag-NOR number of cells treated with RA showed no remarkable difference from that of control group. Ag-aNOR number treated with RA was reduced obviously as compared with that of control group. Meanwhile, the changes of nucleolus number showed by Brachet's reaction were in accordance with those of Ag-aNOR. Therefore, it may be concluded: (1). Though the number of active rRNA genes did not changed after the differentiation of HL-60 cells induced by RA, their expression was clearly inhibited: (2). The relationship between the changes of Brachet-No and Ag-aNOR is in positive correlation (r = 0.98, p less than 0.01). EM examination of Ag-aNOR of HL-60 cells reveals that Ag-protein (RNA polymerase I) only presented in fibrillar centers (FC) and the dense fibrillar components (DFC) of nucleolus. In addition, in control group, large amount of Ag-protein, FC, DFC and granular components (GC) were observed, and there were many large nucleoli in a nucleus, meanwhile, the cells of the treated group tended to be mature, with a decrease in the amount of Ag-protein, FC, DFC and GC accordingly, and the nucleoli reduced both in size and number significantly.(ABSTRACT TRUNCATED AT 250 WORDS)     

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。     

Simultaneous high resolution localization of Ag-NOR proteins and nucleoproteins in interphasic and mitotic nuclei

Summary Silver stainable proteins of the Nucleolar Organizer Regions (Ag-NOR proteins) of human breast cancer tissues have been localized at the electron microscopical level with a new method which combines a simple and reproducible one step Ag-NOR staining method combined with an acetylation procedure. This new method allows the fine identification of nucleolar components, particularly those which are stained by silver.In order to determine the cytochemical nature of the components associated with Ag-NOR proteins, the EDTA regressive preferential staining procedure for ribonucleoproteins has been applied to sections. By this means the precise localization of the Ag-NOR proteins was studied simultaneously with that of ribonucleoprotein within interphasic nucleoli and mitotic chromosomes.In interphasic nucleoli, stainable Ag-NOR proteins were localized in fibrillar centres and part of the dense fibrillar component. No silver deposits were seen on perichromatin or interchromatin fibrils and granules.In metaphasic nuclei, Ag-NOR proteins were only found on roundish fibrillar ribonucleoprotein structures, which could correspond to secondary constrictions. No silver deposits were seen on the well defined ribonucleoprotein sheet surrounding the chromosomes.In telophasic nuclei, Ag-NOR proteins were seen on the central part of roundish ribonucleoprotein fibrillar structures integrated in decondensing chromosomes. These structures have been interpreted as the nucleolar organizer regions around which rRNA synthesis resumes.In interphasic and mitotic nuclei, Ag-NOR proteins were never found within condensed chromatin but always in association with ribonucleoprotein components.The new method proposed here appears to be a useful tool for the simultaneous study of the localization of ribonucleoprotein and Ag-NOR proteins during the cell cycle.     

Double immunolocalization of major nucleolar proteins, fibrillarin and B23, in dividing mammalian cultured cells.

Using specific autoimmune sera to the nucleolar protein fibrillarin and monoclonal antibodies to B23/nucleophosmin, we localized early and late nucleolar rRNA-processing factors in cycling human HeLa and pig PK cells. It was shown that, at the electron microscopic level, fibrillarin was located over the nucleolar fibrillar compartment, but was absent in the fibrillar centres. During mitosis, fibrillarin was located within the same domains as B23, namely, the cytoplasm, the perichromosomal layer, prenucleolar bodies, and the nucleolar cytoplasmic derivatives, but the kinetics of the two proteins during mitosis was essentially different. Thus, fibrillarin dissociated from the nucleolar remnant at prophase of mitosis or following actinomycin D treatments after B23, but was found to be more prominent within the perichromosomal layer at metaphase, and earlier migrated to the reassembled nucleoli at telophase. In contrast to B23, fibrillarin was found to be resistant to the treatment with 2 M NaCl.