Functional organization of the nucleus in the oogenesis of Chrysopa perla L. (Insecta,Neuroptera)

On the basis of light, autoradiographic (uridine-³H incorporation) and electron microscopic investigation changes of nuclear structures were examined during the oogenesis in Chrysopa perla L. — In early meiotic prophase the oocyte nuclei were found to contain a large body of extrachromosomal DNA. In certain cases the latter splits up into several DNA clumps giving rise to a few (4–7) primary nucleoli, 3–5 in diameter. The primary nucleoli consist of densely packed fibrils 50–100 Å thick. They contain no granular component and are inactive in RNA synthesis. — At the beginning of large growth the extrachromosomal DNA bodies disappear and numerous electron-dense clumps, 0,5–1 in diameter, appear in the nucleus. Instead of the primary nucleoli, the nucleus now contains a great number of ring nucleoli about 0,5–1 in diameter with a granular component (granules are 150 Å). The space between them is filled up with nucleolar strands running from the surface of the ring nucleoli. — At the stage ring nucleoli of uridine^–3 H incorporation into the oocyte nucleus begins. — During later previtellogenesis and at the beginning of vitellogenesis the ring nucleoli disappear and the nucleus is filled with the network of nucleolar strands. Among them there are specific complexes. These consist of electron dense masses, of granular clusters (granules 500 Å in diameter) and large fibrillar electron light bodies. At this stage the nucleus takes the most active part in RNA synthesis. — The process of karyosphere capsule formation was studied by electron microscopy. The capsule was found to be of fibrillar nature; its structure is very peculiar and unlike any known membrane components of the cell. On the basis of cytochemical evidences the characteristics of the capsule are given. — The development of a powerful nucleolar apparatus based on the extrachromosomal DNA and a possible role of the synaptonemal complex and extrachromosomal DNA in formation of the karyosphere capsule is discussed.     

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.     

Lampenbürstenchromosomen und multiple Nukleolen bei Orthopteren

Isolated unfixed chromosomes from the oocytes of several grasshopper species, of Gryllus domesticus, and of two cockroaches have been investigated under phase contrast. As demonstrated previously in Locusta migratoria (Kunz, 1967), these chromosomes resemble the lampbrush chromosomes in amphibian oocytes. From these the lateral loops of the orthopteran chromosomes differ in that they are only one third as long (Fig. 3). The distinctness of chromomeres and chiasmata is considerably lower than that in amphibian oocytes (Fig. 4). — Besides the lampbrush chromosomes the oocyte nuclei of Orthoptera contain several hundred spheres or granules which are thought to be the multiple nucleoli (Fig. 6). In young oocytes, these nucleoli are vacuolated spheroids aggregated compactly in the center of the nucleus (Fig. 7). In the oocyte of the cricket, this center contains Feulgen-positive material which disappears in the early growth period when the nucleoli transform from solid structures to several hundred spheres. In oocytes of an intermediate size, both in the grasshoppers and Gryllus such spheroids are present. In the larger mature oocytes these spheres are localized peripherally around the nuclear envelope (Decticus; Fig. 10b), or the become extended into beaded ring forms (Gryllus; Fig. 12), or these rings are opened, stretched and connected in a row to form long “pearl-string” threads (Locusta, Acrida, Homorocoryphus). The spheroids around the nuclear envelope of Decticus look very similar to the solid and spheroidal nucleoli in young oocytes of the axolotl (Callan, 1966). The beaded rings of Gryllus resemble the ring-shaped nucleoli in the amphibian oocytes during their intermediate growing phase. — Following Keyl's (1966) hypothesis for the construction of replication units, these different appearances of multiple nucleoli are proposed to be results of a similar mode of extra-replication, but of different arrangement. In the case of Gryllus and Decticus the nucleolar DNA Anlagen are set free from the chromosomes, but they remain attached one behind the other in Locusta and some other grasshoppers.     

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.     

Three-dimensional structure of the ciliate Didinium nasutum nucleoli

The nucleolar organization in ciliate Didinium nasutum somatic interphase nuclei was studied using serial ultrathin sections and compared for various physiological states of the cell, namely, fed ciliates, starved ciliates, and dormant cysts. It has been shown that the interphase nucleoli are large structures with a complex architecture: the fibrillar component forms an intricate network in the macronucleus space, while the granular component is located inside this network. The structures looking as individual nucleoli in single sections are actually parts of branched nucleolar networks. The intricate nucleolar networks do not disintegrate after a 30-h starvation; however, the granular component becomes denser and develops numerous cavities filled with fine fibrils of a nonribonucleoprotein nature. In fed D. nasutum, the fibrillar structures on the periphery of nucleoli contain numerous pores (virtually absent in starved cell nucleoli), which can potentially serve for transporting newly synthesized rRNP. Branched nucleolar networks are undetectable in cysts. Their nucleoli are individual structures consisting mainly of the fibrogranular component.     

Interlocking and knotting of ring nucleoli in amphibian oocytes

Various configurations of interlocking and knotting of ring nucleoli from amphibian oocytes have been identified in material taken from 2 females of Eurycea bislineata and one female of Plethodon cinereus. The simplest configuration is a simple interlock between 2 rings of similar or different lengths. More complex interlocks have been seen, in which 3 rings are linked together in such a way that they cannot be extended into a chain. A third configuration involves complex knotting of single long rings. It is suggested that the interlocked configurations arise through the replication of rings of DNA that have low levels of supercoiling, and that the knotted rings arise by misjoining of the ends of linear molecules that have become wound around one another. Models are suggested in support of these proposals and the significance of interlocking of ring nucleoli in relation to the mechanism of gene amplification is discussed.     

Ovarian nests in cultured females of the Siberian sturgeon Acipenser baerii (Chondrostei,Acipenseriformes)

Ovaries of Acipenser baerii are of an alimentary type and probably are meroistic. They contain ovarian nests, individual follicles, inner germinal ovarian epithelium, and fat tissue. Nests comprise cystoblasts, germline cysts, numerous early previtellogenic oocytes, and somatic cells. Cysts are composed of cystocytes, which are connected by intercellular bridges and are in the pachytene stage of the first meiotic prophase. They contain bivalents, finely granular, medium electron dense material, and nucleoli in the nucleoplasm. Many cystocytes degenerate. Oocytes differ in size and structure. Most oocytes are in the pachytene and early diplotene stages and are referred to as the PACH oocytes. Oocytes in more advanced diplotene stage are referred to as the DIP oocytes. Nuclei in the PACH oocytes contain bivalents and irregularly shaped accumulation of DNA (DNA‐body), most probably corresponding to the rDNA‐body. The DNA‐body is composed of loose, fine granular material, and comprises multiple nucleoli. At peripheries, it is fragmented into blocks that remain in contact with the inner nuclear membrane. In the ooplasm, there is the rough endoplasmic reticulum, Golgi complexes, free ribosomes, complexes of mitochondria with cement, fine fibrillar material containing granules, and lipid droplets. The organelles and material of nuclear origin form a distinct accumulation (a granular ooplasm) in the vicinity of the nucleus. Some of the PACH oocytes are surrounded by flat somatic cells. There are lampbrush chromosomes and multiple nucleoli present (early diplotene stage) in the nucleoplasm. These PACH oocytes and neighboring somatic cells have initiated the formation of ovarian follicles. The remaining PACH oocytes transform to the DIP oocytes. The DIP oocytes contain lampbrush chromosomes and a DNA‐body is absent in nuclei. Multiple nucleoli are numerous in the nucleoplasm and granular ooplasm is present at the vegetal region of the oocyte.     

A STUDY OF NUCLEOLAR VACUOLES IN CULTURED TOBACCO CELLS USING RADIOAUTOGRAPHY, ACTINOMYCIN D, AND ELECTRON MICROSCOPY

Previously it has been found that in tobacco callus cells nucleolar vacuoles repeatedly form and contract. In this study, nucleolar vacuoles were investigated by using radioautography, actinomycin D, and electron microscopy. It was found, from grain counts of nucleoli labeled with uridine-³H, that nucleoli containing vacuoles had more than three times as many grains/µ² of nucleolar substance as did nucleolei without vacuoles. Treatment of tobacco callus cells with various concentrations of actinomycin D caused the percentage of cells containing nucleolar vacuoles to decrease; with the highest concentration the percentage of these cells dropped from the normal level of about 70% to less than 10%. However, after removal of actinomycin D the cells regained nucleolar vacuoles up to the control level. When radioautography was used with actinomycin D, it was found that the actinomycin D inhibited the uptake of uridine-³H, i.e. inhibited RNA synthesis, in those nucleoli which lost their nucleolar vacuoles. In addition, after removal of the cells from actinomycin D, it was found that as the cells regained nucleolar vacuoles the nucleoli also began to incorporate uridine-³H. Electron micrographs showed the nucleoli to be composed of a compact, finely fibrous central portion surrounded by a layer of dense particles 100–150 A in diameter. Nucleolar vacuoles occurred in the fibrous central portion. Dense particles similar to those in the outer layer of the nucleoli were found scattered throughout the vacuoles and in a dense layer at their outer edge. These data suggest that in cultured tobacco callus cells the formation and contraction of nucleolar vacuoles is closely related to RNA synthesis in the nucleolus.     

Structural changes in oocyte nucleoli ofXenopus laevis during oogenesis and meiotic maturation

Immunoelectron microscopy with anti-nucleolin defined substructures within the multiple nucleoli of biosynthetically active stage II–III oocytes and within the nucleoli of relatively quiescent stage VI oocytes of Xenopus laevis. Dense fibrillar components (DFCs) of nucleoli from stage II–III oocytes consisted of nucleolonemas that radiated from a continuous DFC sheath surrounding fibrillar centers (FCs). Discernible granular regions (GRs) were absent in these same nucleoli. Conversely, stage VI oocyte nucleoli displayed compacted DFCs and prominent GRs. Immunofluorescence microscopy then tracked fibrillarin, nucleolin, and condensed DNA through oogenesis and into progesterone-induced meiotic maturation and nuclear breakdown. In stage II–III oocyte nucleoli, fibrillarin was enriched near the FC-DFC boundaries, while nucleolin was distributed throughout these same DFCs. Both proteins were enriched within the compacted DFCs of stage VI oocyte nucleoli. Staining with (DAPI) 4′,6-diamidino-2-phenylindole showed condensed DNA within nucleolar FCs of both stage II–III and stage VI oocyte. Upon nuclear breakdown, we found fibrillarin and nucleolin in small particles and in the surrounding cytoplasm. Although we saw no trace of fibrillarin or nucleolin in nuclear remnants prepared just minutes later, DAPI-stained particles remained within these preparations, thus suggesting that FCs were at least slow to disassemble. Received: 18 March 1996 / Accepted: 16 April 1996     

Characterization of Astasia longa ribonsomal DNA.

Ehrlich tumour cell nucleoli contain fibrillar and granular components and low electron density areas called “fibrillar centres”. Analysis by high-resolution autoradiography using [³H]actinomycin D or [³H]TdR reveals that a small amount of DNA is present inside the fibrillar centres. Newly synthesized RNA is also present within the fibrillar centres or at their periphery, already 3 min after the precursor is given. According to these results, RNA is synthesized on DNA in the fibrillar centres. It is possible that the latter contain dispersed genetically active chromatin. These observations add further support to the hypothesis that fibrillar centres have a chromosomal origin and are related to the nucleolar organizers.     

SITES OF NUCLEOLUS PRODUCTION IN CULTURED CHINESE HAMSTER CELLS

Chinese hamster cell strains in the early passages in culture display wide variation in number of nucleolus-like bodies per cell, though such strains are characteristically euploid. A variety of criteria indicate that the nucleolus-like bodies are true nucleoli. Their Azure B- and fast green-staining properties indicate the presence of RNA and protein; they have typical nucleolar fine structure, including both fibrous and granular components; radioautography reveals that their patterns of uptake of uridine-³H into RNA are similar to those reported for nucleoli of other cell types; actinomycin D, at a level which selectively inhibits ribosomal RNA synthesis, greatly reduces their RNA synthesis and also causes segregation of fibrous and granular nucleolar components. Colchicine was used to experimentally fragment the nuclei of these cells into a number of separate karyomeres, each presumably containing some, or only one, of the chromosomes of the complement. Almost all the karyomeres contain nucleolus-like bodies which, by the same criteria applied to the multiple nucleolus-like bodies of uninuclear cells, appear to be true nucleoli. The nucleoli of individual karyomeres of the same cell often differ from each other in fine structure while the multiple nucleoli of a uninuclear cell generally resemble each other. The evidence presented in this study indicates that Chinese hamster cells contain many nucleolus-producing sites scattered through the genome.     

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.     

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.     

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.     

RNA SYNTHESIS IN CHINESE HAMSTER CELLS : II. Increase in Rate of RNA Synthesis during G1

Cultures of mitotic Chinese hamster cells, prepared by mechanical selection, were pulse-labeled with methionine-methyl-¹⁴C or with uridine-³H at different stages in the life cycle. The rate of ¹⁴C incorporation into 18S RNA was measured, as was the rate of uridine-³H incorporation into total RNA for both monolayer and suspension cultures. The rate of incorporation increased continuously throughout interphase in a fashion inconsistent with a gene-dosage effect upon RNA synthesis.