Nucleolar structure and synthetic activity during meiotic prophase and spermiogenesis in the rat

The ultrastructure of nucleoli was examined in developing rat spermatocytes and spermatids, with the help of serial sections. In addition, the radioautographic reaction of nucleoli as examined in rats sacrificed 1 hr after intratesticular injection of 3H(5')-uridine and taken as an index of the rate of synthesis of ribosomal RNA (rRNA). Primary spermatocytes from preleptotene to zygotene have small nucleoli typically composed of fibrillar centers, a fibrillar component, and a granular component, within which are narrow interstitial spaces. During early and mid-pachytene, nucleoli enlarge to about nine times their initial size, with the fibrillar and granular components forming an extensive network of cords--a nucleolonema--within which are wide interstitial spaces. Meanwhile, there appear structures identical to the granular component but distinct from nucleoli; they are referred to as extranucleolar granular elements. Finally, from late pachytene to the first maturation division, nucleoli undergo condensation, as shown by contraction of fibrillar centers into small clumps, while fibrillar and granular components condense and segregate from each other, with a gradual decrease in interstitial spaces. In secondary spermatocytes, nucleoli are compact and rather small, while in young spermatids they are also compact and even smaller. Nucleoli disappear in elongating spermatids. In 3H-uridine radioautographs, nucleolar label is weak in young primary spermatocytes, increases progressively during early pachytene, is strong by the end of mid pachytene, but gradually decreases during late pachytene up to the first maturation division. In secondary spermatocytes and spermatids, there is no significant nucleolar label. In conclusion, rRNA synthesis by nucleoli is low in young spermatocytes. During pachytene, while nucleoli enlarge and form a lacy nucleolonema, rRNA synthesis increases gradually to a high level by the end of mid pachytene. However, during the condensation and segregation of nucleolar components occurring from late pachytene onward, the synthesis gradually decreases and disappears. The small, compact spermatids arising from the second maturation division do not synthesize rRNA.     

NUCLEOLAR AGING IN TETRAHYMENA DURING THE CULTURAL GROWTH CYCLE

Nucelolar morphology was studied by electron microscopy in control and actinomycin D-treated populations of Tetrahymena pyriformis (W) during the cultural growth cycle. Nucleoli exhibit an "aging" cycle concomitant with the cultural growth cycle, but independent of the individual cell cycle. Four different stages in the course of this aging process have been defined. Stage 1 occurs upon inoculation (low number of cells per milliliter) and lasts through lag and accelerating growth phases. In this stage, many small nucleoli are found at the nuclear periphery. In stages 2 and 3, nucleolar fusion begins. Stage 2 dominates the first half of logarithmic growth, and stage 3 dominates the second half. In late decelerating growth phase, the nucleoli enter stage 4. In this stage, only a few large nucleoli are present and these are apparently inactive in ribosome production. In stationary phase, where total RNA remains constant, only stage 4 nucleoli are present. The relative preponderance of granular vs. fibrous components in the nucleoli changes during this cycle, the granular component dominating stage 1 nucleoli and the fibrillar, stage 4 nucleoli. There is a shortening of the intermediate nucleolar stages in the treated cultures; fusion occurs early and is now pronounced. Not enough ribosomes accumulate to carry the treated cultures through the number of generations equivalent to those of the control, which produces a premature stationary phase.     

Laser microdissection of actinomycin D segregated nucleoli

Nucleoli of tissue culture cells were segregated into their fibrillar (light) and granular (dark) components by treatment with actinomycin D. Following this segregation, the cells were treated with quinacrine hydrochloride, an agent which selectively sensitizes the nucleoli to argon laser light. The actinomycin D-segregated, quinacrine-sensitized nucleolar components (dark and light) were selectively irradiated with the laser microbeam and subsequent uridine uptake assayed. The data indicate that selective damage to the light (fibrillar) area is generally more damaging than damage to the dark (granular) area. These results support the idea that DNA is closely associated with the nucleolar fibrillar component.     

Behaviour of ribosomal genes and nucleolar domains during activation in sugarcane (Saccharum officinarum L.) root primordia: from the unsoaked quiescent state to the steady state of proliferation

Changes in the organisation of ribosomal genes and nucleolar protein components were analysed in sugarcane (Saccharum officinarum L. cv Cristalina) from the time the quiescent primordia of the radical bands of nodes were stimulated to proliferate by water imbibition, until the meristematic population reached the steady state of proliferation in the growing roots. The kinetics of proliferation was evaluated by flow cytometry, and by the mitotic indexes, in roots of different lengths. All the quiescent cells were in a pre-replicative state (G0), with a 2C DNA content. During their activation process, they progressively reached the steady state of proliferation (mitotic index 7%), with rather fixed frequencies for cells with 2C (G1), 4C (G2), and values between them corresponding to cells replicating their DNA. Decondensation of the ribosomal genes was followed by FISH with probes for the major 25S and 18S rRNAs, and variations in the numbers of nucleoli were recorded in squashed cells after silver staining. The ultrastructure of nucleoli was analysed by electron microscopy, using the EDTA regressive staining for ribonucleoproteins. Quiescent nucleoli showed a clear segregation of their main components: Fibrillar Centre, Dense Fibrillar Component and Cajal's bodies while lacked any Granular Component. However the proliferating ones showed them highly intermingled, except for the Cajal's bodies. Our results revealed a high plasticity of the nucleolar domains in response to cell activation, and allowed to establish a correlation between dispersion of NORs with formation of small fibrillar centers and a nucleolus with all its domains intermingled, and the activation of cell proliferation during root sprouting.     

Rearrangement of nucleoli in hepatocytes stimulated for proliferation and enhancement of their transcription function

The nucleoli of normally functioning guinea-pig hepatocytes that have a nucleolonemal (strand-like) organization differ from identical nucleoli of other cells. Their nucleolonema consists as a rule of a fibrillar component with 45S RNA and is poor in granulas that contain pre-rNA molecules of an intermediate size and 28S rRNA, a dense fibrillar component with nascent rRNPs in its composition was not revealed. In hepatocytes stimulated by a 2/3 liver resection rearrangements in nucleoli were found. This brought to a conclusion that rRNA metabolism undergoes some changes. In 2.5 and 5 hours after the resection the hepatocytes' nucleoli were characteristic of a greater thickness of strands and a smaller size of vacuoles, appearance of distinct zones of the dense fibrillar component and an increased amount of RNP-granules. All these observations taken together point out at an increased synthesis and processing of rRNA at early stages of the prereplicative period. In 9 hours the character of changes in nucleoli was different: the vacuoles were considerably widened, whereas the thickness of strands that consisted of a well-expressed dense fibrillar, fibrillar and granular components was lesser. Such rearrangement points out at an increased transport of preribosomes from the nucleolus, a high level of synthesis and processing of nascent RNP-product being maintained. The changes of nucleolar RNP-component were followed by appearance of greater blocks of perinucleolar condensed chromatin, which may be connected with "cutting-off" some tissue-specific genes and initiation of functioning of the mitotic operon genes.     

Initiation of transcription and nucleologenesis in equine embryos

The time of activation of the embryonic genome (maternal-embryonic transition) in equine embryos was investigated by assessing incorporation of ³H-uridine and nucleolar development. In Experiment 1, embryos were recovered from the oviduct (n = 15) and the uterus (n = 3). Recovered embryos were assessed for morphologic development and quality score. Recovered embryos with less than 8 cells (two cells, n = 4; four cells, n = 5; five cells, n = 2) were incubated with ³H-uridine (560 μCi/ml) for 10 hr, while eight-cell embryos (n = 2), morulae (n = 2), and blastocysts (n = 3) were incubated with 280 μCi/ml for 0.5–1 hr. At the end of incubation, embryos were washed twice in PBS with 10% FBS and incubated for 30 min with 2.5 mg/ml of unlabelled uridine. Embryos were spread onto glass slides, dipped into emulsion, and exposed for 8 d, then developed and counter-stained with Giemsa and propidium iodide. Embryos at the blastocyst, morula, eight-cell, and five-cell stages incorporated ³H-uridine into their cell nuclei as detected by autoradiography. In a second experiment, nucleologenesis in equine embryos was examined by transmission electron microscopy. Nucleoli or nucleolar precursors were found in 12 of 23 embryos examined. Most embryos in the four- to six-cell stage (n = 7) had nucleolar precursor bodies (npb) consisting of homogeneous fibrillar structures. Two five- to six-cell embryos also possessed reticulated nucleoli with both fibrillar and granular components as did all eight-cell embryos (n = 3). Nucleoli in one morula and one blastocyst were reticulated with prominent granular components, fibrillar components, and apparent fibrillar centers. These results indicate that incorporation of ³H-uridine and the formation of functional nucleoli with typical fibrillar and granular components occurs between the four- to eight-cell stage in equine embryos. © 1995 wiley-Liss, Inc.     

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.     

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     

Increased functional load on mouse kidney proximal tubule epithelial cells causes changes in nucleolar 3-D architecture

Ultrastructural 3-D analysis of nucleolar architecture and Ag-NOR protein distribution in mouse kidney-cortex proximal-tubule epithelium has been performed. A principal scheme of structural changes of the nucleolus and organization of its components during the intensification of pre-rRNA synthesis (dynamic model of a nucleolus) based on computer spatial modelling has been advanced. According to the nucleolar composition, three groups of cells, which differ from each other by rRNA synthesis, are defined in normal kidney. Most nephron proximal-section cells (about 52%) are characterized by lower activity of RNA synthesis. Such kind of cells are defined as group I (nucleolar diameter 0.7–1.5 µm) and always contain resting, ring-shaped or close to ring-shaped dense nucleoli, which have 2 or 3 fibrillar centers. Nucleoli of group II cells (about 37%, nucleolar diameter 1.5–2.5 µm) have a higher level of activity, contain 4–7 fibrillar centers, and their structural organization is close to reticulated forms due to the first indications of vacuolar network (identified as prereticulated nucleoli). The most active cells of group III (about 11%, nucleolar diameter 2.5–3.5 µm) include cells with typical reticulated nucleoli with a well expressed vacuolar network and numerous fibrillar centers (18–22). Increased functional load of the epithelium caused by unilateral nephrectomy and diuretic (4-chlor-H [2-furylmethyl] 5-sulphamyl-antranic acid) injection changed the proportion of the different cell groups: group I decreased (about 25%), whereas groups II and III increased (about 8% and 17%, respectively). The increase of nucleolar activity first causes a deformation of the individual fibrillar centers as well as complication and growth of their surface. Further, a progressive fragmentation of the fibrillar centers and the growth of their total volume is observed. The complication and growth of the total volume of Ag-positive zones is another indication of the nucleolar activation. The vacuolar system develops by a gradual fusion of small isolated cavities into a united vacuolar network. Nucleoli with 2–7 fibrillar centers are considered to be intermediate forms reflecting successive stages of its activation or inactivation: from the resting ring-shaped nucleolus via transient stages of increasing functional activity to the active reticulated nucleoli and vice versa. The observed differences in the nucleolar ultrastructure are regarded as evidence of the functional heterogeneity of cell populations within one functional segment of nephron.     

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.     

The 3-dimensional organization of the nucleoli of benign and malignant tumor cells from different human organs]

The method of ultrathin serial sections was used to perform a comparative ultrastructural and 3-dimensional analysis of nucleoli for the following variants of human tumours: benign (fibroadenoma) and malignant (infiltrating ductal carcinoma) tumours of one organ (mammary gland); malignant tumours of epidermal genesis in different organs (squamous cell carcinomas of skin, larynx, lung, gullet, uterus); two forms of malignant tumours (squamous cell and small cell carcinomas) of one organ (lung). The spatial models of nucleoli in these tumour cells are given. The specific signs in architecture of tumour nucleoli was found. Nucleoli of fibroadenomas have well pronounced 1-4 fibrillar centres forming a united system with a lacunar component and intranucleolar chromatin. Unlike benign tumour cells, nucleoli of infiltrating ductal carcinomas are characterized by large, prominent nucleoli containing giant, multiform fibrillar centres with a complicated surface, a well developed granular component and an unusually organized lacunar system. In squamous cell carcinomas of various localization, active, hypertrophied nucleoli with pseudonucleolonemal organization were found. The small cell carcinoma of lung differs from the squamous cell cancer of the same organ by dense, fibrillar nucleoli with a small amount of granular component located on the periphery of the nucleolar body. Nucleolar type reflecting the functional state of malignization process may serve as an additional diagnostic criterion for tumour identification.     

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.     

Ultrastructural studies of H-1 parvovirus replication. II. Induced changes in the deoxyribonucleoprotein and ribonucleoprotein components of human NB cell nuclei.

Ultrastructural changes in the nuclear DNP and RNP components of human NB cells induced by synchronous infection with H-1 parvovirus were studied using Bernhard's EDTA method of staining. Early events (12 h after infection) occurred in the nucleolus. Chromatin within the nucleolar fibrous centers condensed thereby converting the centers to vacuoles. DNP associated with the granular nucleolonema also contracted markedly, causing a disruption of this skein-like structure; it then migrated peripherally forming a heterochromatic cortex surrounding the granular nucleolar vestige. Subsequently (24–36 h after inoculation), condensation of extranucleolar chromatin took place concurrently with the accumulation of extensive amounts of interchromatin granules in the nucleus and cytoplasm. Conglomerates of perichromatin fibrils and interchromatin granules were frequently juxtapposed to the condensing chromatin. Large clumps of interchromatin granules were also closely associated with fragmenting nucleoli, and the apparent transformation of nucleolar granules into interchromatin granules was observed. Accumulation of H-1 protein on chromatin evidently fostered its condensation resulting in the pathology described.     

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).     

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.     

Conservation of nucleolar structure in polytene tissues of Ceratitis capitata (Diptera: Tephritidae)

Nucleolar structure was studied in mitotic and three polytene tissues of the Mediterranean fruit fly, Ceratitis capitata using in situ hybridization with a tritium-labelled rDNA probe and silver staining. In mitotic metaphase chromosomes nucleolar organiser regions were localised in the short arms of both sex chromosomes. In polytene nuclei of trichogen cells, salivary glands and fat body rDNA was detected within nucleoli. Nucleoli in these tissues have a similar structure with rDNA labelling concentrated in a central core. Silver staining resulted in very heavy staining of polytene nucleoli and interphase nucleoli in diploid cells. Silver staining of nucleolar organisers in metaphase chromosomes is weak or absent although the X chromosome has numerous dark silver bands in other locations. The results suggest that nucleolar structure is conserved in polytene tissues contrasting with the variability of autosomal banding patterns and sex chromosome structure. They also indicate that silver staining is not necessarily specific for nucleolar regions.