Nuclear structures in the telotrophic ovarioles of nocturnal ground beetles (Tenebrionidae, Polyphaga). III. The oocyte nucleus. Electron microscopic data]

The fine structural organization of nuclei was studied in the growing oocytes of Blaps lethifera, B. mortisaga and Gnaptor spinimanus. In the beginning of diplotene the nuclei contain primary fibrillar nucleoli and numerous electron dense globules dispersed all over the nucleus; the loose chromosome material (lampbrush chromosomes) is distributed all over the nucleus. With the oocyte growth the chromosomes are spiralized and join into the karyosphere. A capsule of fibrous material forms around the karyosphere. The karyosphere nucleoli appear on the chromosomes and, then, move to the capsule region and outside its limits, to the nuclear envelope. They are fibrillar and non-active with respect to RNA synthesis. The fibrous material of the capsule is represented by strands which consist of bundles of cross-striated filaments. These latter contact directly with the chromosomes in the karyosphere and with the surface of the karyosphere nucleoli. The fibrillar-granular bodies are distributed along the strands in the capsule; they contain both RNA and DNA. The nature of extrachromosomal DNA in the karyosphere capsule and its participation in the formation of the capsule material are discussed. A suggestion is put forward on the similarity of the capsule strands with the modified central elements of synaptinemal complex.     

Nuclear structures in the telotrophic ovarioles of nocturnal ground beetles (Tenebrionidae, Polyphaga). II. The oocyte nucleus of Blaps lethifera and Gnaptor spinimanus. Light optical data]

Changes in the nuclear structures and their participation in RNA synthesis in the growing oocytes were followed in two species of beetles Blaps lethifera and Gnaptor spinimanus. In the oocytes of both the species, the chromosomes join into the karyosphere following the short-term lampbrush stage. A large capsule appears around the karayosphere which consists of the fibrous substance, granules and karyosphere nucleoli. The latter form in the karyosphere and contain RNP but they are not true nucleoli since they do not include 3H-uridine. RNA synthesis on the chromosomes, active at the lampbrush stage, falls markedly following their joining into the karyosphere. The oocyte nuclei of these beetles are, thus, characterized by the absence of RNA synthesizing nucleolar system and, as compared with the trophocytes, by the low level of RNA synthesis on the chromosomes.     

Nuclear structures in the late oogenesis of Rana temporaria. III. Electron microscopic studies]

The ultrastructural organization of the vitellogenic oocyte nucleus (stage VI, according to Duryee, 1950) was studied in normal and in vitro hormone-stimulated maturing oocytes of Rana temporaria. At this stage, numerous nucleoli are gathered around the knot of highly contracted chromosomes (the karyosphere) thus making the karyosphere capsule. Light microscope observations reveal three zones in the capsule: a central fibrous zone separating the chromosomes from the nucleoli, a middle zone, consisting of numerous nucleoli and a distinct fibrous componen; in addition a fibrous zone on the capsule periphery is seen. The nucleoli are fibrillar, bear no proribosomal granules and do not synthesize RNA. This period is characterized by an intensive fragmentation and segregation of the nucleolar material. Numerous micronucleoli and nuclear bodies occur in the nucleus. The nucleoli are normally compound and irregular in shape to become spherical in hormone-stimulated maturing oocytes. In the central fibrous zone of the capsule, separating the chromosomes from the nucleoli, some peculiar abundant accumulations of annuli were detected lacking the membranes component. Annuli are linked with the fibrous material and are regularily packed making peculiar pseudomembranes (PMM). The chromatin is connected with PMM directly. In the middle zone of the capsule, accumulations of PMM are also seen, though less abundant and less regularly packed; along with annuli, membranous areas of various size and form are met in PMM. PMM are connected with the micronucleoli with filaments 20 nm thick. In the peripheral zone of the capsule, a variety of membranous structures is detected: intranuclear annuli lamellae, component of the capsule consists of different membranous and pseudomembranous (with annuli) structures. A question of the contribution of the chromatin material in the formation of the fibrous capsular component (PMM and membranous structures) is discussed.     

The karyosphere capsule in oocytes of hibernating frogs <Emphasis Type="Italic">Rana temporaria</Emphasis> contains actin,lamins, and SnRNP

The nuclei of late vitellogenic oocytes of hibernating frogs Rana temporaria were studied. During this period of oogenesis, chromosomes are inactivated and surrounded by a fibrillar karyosphere capsule. Formation of the karyosphere capsule in grass frog oocytes has been investigated in detail at the light and electron microscopic levels, but the molecular composition of the capsule remains uncertain. Immunofluorescent staining of whole-mount preparations of oocyte nuclei revealed that the karyosphere capsule contained actin, lamins A, C, and B and snRNPs proteins. A putative role of these proteins in formation of the karyosphere capsule is discussed.     

Intranuclear actin microfilaments in the oocytes of the common frog

For identification and distribution of actin microfilaments in hand-isolated nuclei of R. temporaria oocytes (stage 6, according to Dumont, 1972) different methods were used: heavy meromyosin decoration, antiactin immunofluorescence with monoclonal antibodies, staining with rhodamine phalloidin, and electrophoresis in polyacrylamide gel. The nuclei of R. temporaria oocytes contain a considerable quantities of actin microfilaments which form intranuclear meshwork. Microfilaments are connected with the nucleoli, nucleolar RNP-complexes and nuclear envelope. Immunofluorescence with antiactin monoclonal antibodies reveals a strong staining of microfilaments and nucleoli. A slight staining of nucleoli is observed after the treatment of nuclei with rhodamine phalloidin. A specific role of intranuclear microfilaments in direct transport of nucleolar material from the nucleus into the oocyte cytoplasm, in stabilization of the karyosphere (the late diplotene oocyte complex of chromosomes with numerous nucleoli) is discussed in addition to its keeping in a definite region of the nucleus. A supposition is drawn on the functional significance of the connection between microfilaments and nuclear matrix. Based on our own and literature data, a conclusion is drawn, that the intranuclear filament actin may be one of the leading components in morpho-functional organization of the nucleus as the whole.     

Nuclear ultrastructure of the oocytes from human antral follicles. Formation of the karyosphere

The organization of the nucleus in the oocytes from human antral follicles was examined at the electron microscopic level. At this time all the chromosomes are aggregated around an inactivated nucleolus forming a karyosphere 5-7 micron in diameter. The nucleolus bears no granular component and consists of densely packed delicate fibrillar material. The peripheral zone resembling a ring 0.5 micron thick is separated in the nucleolus. Nucleolus-like bodies (NLB), consisting of granules 20 nm in diameter embedded in finely fibrillar material, are constantly observed in contact with the chromatin. The eventually formed karyosphere is a complex of intimately interconnecting structures--the nucleolus, chromosomes and NLB. However, the chromatin surrounding the nucleolus does not form a continuous (compact) mass as it is observed at the light microscopic level. It is determined that the human karyosphere is formed during the preovulatory period when the connection between oocyte and follicular cells of cumulus oophorus is lost. The duration of karyosphere existence in the human oocytes, and relation of the karyosphere to the processes of antral follicle atresia are discussed.     

Karyosphere in oogenesis]

The purpose of this review is to draw attention to the peculiar phenomenon during gametogenesis: the formation of the karyosphere. This phenomenon is characterized by concentration of all chromosomes in the limited area of the nucleus and may be considered as alternative of the genome in the state of lumpbrush chromosomes. The formation of the karyosphere is a widely spread phenomenon during oogenesis of different animal classes. The karyosphere can be developed during different stages of oogenesis in different organisms; but as a rule the chromosomes of diploten stage of meiosis take part in its formation. As to functional identity of the karyosphere in different species, special investigations are to be done, but contemporary knowledge of the karyosphere formation reveals some common feature:1) in the karyosphere the chromosomes are in a relatively spiral state as demonstrated by the positive Feulgen reaction; 2) there is a low level of RNA synthesis or the absence of it in the karyosphere; 3) during the karyosphere formation the nucleus is enriched by the acid proteins and a lot of protein granules and structures appearing in a close contact with the karysphere. The more typical examples of the karyosphere formation can be observed in the insect oocytes belonging to the nutrimentary type of oogenesis. In the oocytes of some animals the peculiar protein substances are formed around the chromosome knot and appear as a fibrillar zone. Such karyosphere appears to be a kind of capsule inside the nucleus. The capsules are developed as a result of complex interaction between the main nuclear structures; chromosomes, nucleoli, and nuclear membrane as it is manifested by the analysis of some recent ultrastructural date obtained in some insect and amphibian oocytes. The function of the karyosphere capsule and the role of the nuclear structure (sinaptonemal complex, extrachromosomal DNA, and nuclear membrane) in formation of the capsule, are discussed as well as the ultrastructural and cytochemical similarity between the karyosphere capsule of oocytes and nuclear bodies of somatic cells.     

An immunoelectron study of karyosphere and nuclear bodies in oocytes of mealworm beetle, Tenebrio molitor (Coleoptera: Polyphaga)

The karyosphere and nuclear bodies (NBs) were studied in Tenebrio molitor oocytes using immunoelectron cytochemistry. During early diplotene (previtellogenic stage), oocyte chromosomes begin to unite in a small nuclear volume forming the karyosphere. In vitellogenic oocyte nuclei, the chromatin undergoes condensation, and the karyosphere acquires a ring-shaped structure. The karyosphere is the only structure containing DNA in the oocyte nucleus. Pre-mRNA splicing factors [small nuclear ribonucleoproteins (snRNPs) and SC35] are not found in the karyosphere itself. In previtellogenic oocyte nuclei, these factors are present in NBs and in a fibrogranular substance surrounding the chromosomes in the early stages of karyosphere formation. At this stage, larger fibrillar NBs contain the non-snRNP splicing factor SC35. Smaller roundish NBs were shown to contain snRNPs. Some NBs with the same morphology contain neither snRNPs nor SC35. In the vitellogenic oocyte, there are fibrogranular NBs containing both snRNPs and SC35 splicing factors, fibrillar NBs containing snRNPs only, and complex NBs containing both. Complex NBs are often connected with the ring-shaped karyosphere. Based on the obtained immunoelectron data, we suggest that T. molitor oocyte NBs containing both snRNPs and the non-snRNP splicing factor SC35 are homologs of the well-characterized B-snurposomes in amphibian germinal vesicles and clusters of interchromatin granules in mammalian oocyte nuclei. Other NBs containing only snRNPs are suggested to represent a special class of insect oocyte snurposomes. The nuclear organelles mentioned seem to play a role as storage domains for pre-mRNA splicing factors during T. molitor oogenesis.     

The karyosphere capsule in Tribolium castaneum oocytes

The structure and composition of the karyosphere (karyosome) capsule of the laboratory insect, Tribolium castaneum, were studied with the use of electron and immunoelectron microscopy. Eight stages that characterized the period of oocyte growth have been established basing on the study of nuclear structure dynamics. At the diplotene stage, T. castaneum oocyte chromosomes are being united early to form a compact karyosphere; however, prominent chromatin condensation does not occur at the same time. The process of karyosphere formation is accompanied by the development of a spacious extrachromosomal capsule surrounding chromatin. The capsule consists of a fibrous material of different morphological types. The most prominent molecular components of T. castaneum karyosphere capsule are represented by the proteins of nuclear matrix, including F-actin and lamin B. Apart from the structural proteins, immunocytochemical approach allowed revealing Sm proteins of small nuclear (sn) RNPs and “mature” snRNAs with 2,2,7-trimetyl guanosine (TMG) cap at the 5’-end of their molecules. These data may serve as a base for further broadening of the conception about the functions of the karyosphere capsule as a specialized oocyte nuclear domain. We believe that T. castaneum karyosphere capsule plays not only a structural role, but may be involved directly in the processes related to gene expression.     

Oogenesis in the malaria mosquito Anopheles gambiae

Summary Oogenesis has been followed with the electron microscope in 2 strains of the malaria mosquito Anopheles gambiae, from the emergence of the adult (oocytes at leptonema) till shortly before the oocytes are ready for oviposition. After pachynema the chromosomes form a karyosphere and a fibrous capsule develops around it. Work on other mosquitoes suggests that the capsule may be related to the synaptonemal complexes. Both Anopheles strains contain at some time an extrachromosomal (not DNA-containing) body comparable to the karyosphere in size. Clusters of granules are present at the surface of the nucleolus and free in the nucleoplasm. Tentative results indicate that they may contain DNA. During oogenesis the nucleolus becomes very large, mainly because of proliferation of the nucleolonema. Towards the end of oocyte development the nucleus assumes the large canoe-shape also seen in Aedes and Culex. Nucleolonema traverse the entire nucleus, and modified granular clusters are found throughout.     

Localization of the chromatin-remodeling protein ATRX in the oocyte nucleus of some insects

A comparative study of nuclear distribution of the chromatin-remodeling protein ATRX in the oocytes of three species of insects in which the oocyte nucleus at the diplotene stage differs in structure, has been carried out using fluorescent and immunoelectron microscopy. In tóhe oocyte nucleus of the tenebrionid beetles, Tribolium castaneum and Tenebrio molitor, ATRX preferably associates with the karyosphere (karyosome) that represents a result of concentration of the condensed chromosomes in a limited volume of the nucleus. In the oocyte nucleus of the house cricket, Acheta domesticus, in which a karyosphere does not form, the protein ATRX is distributed in the entire nuclear volume in association with the chromatin. The fact of ATRX presence in the extrachromosomal structures of the insect oocyte nucleus, the karyosphere capsule and specific nuclear bodies, is documented for the first time.     

Karyosphere and extrachromosomal nuclear bodies in oocytes of the scorpionfly, Panorpa communis

Oocyte nuclear structures were studied for the scorpionfly Panorpa communis at different stages of oocyte growth, from pachytene to the first meiotic division. Using immunofluorescent and immunogold microscopy, we analyzed the nuclear distribution of RNA polymerase II, splicing factors and coilin. These factors were revealed in close association with perichromatin fibrils and, later, with some elements of the karyosphere and extrachromosomal nuclear bodies (NBs). Besides, it was shown that large amounts of P. communis oocyte NBs represent Cajal bodies (CBs) and contain CB marker protein, coilin, as well as RNA polymerase II, and in some cases an essential splicing factor, SC35. The presence of SC35 is commonly not characteristic of CBs in somatic cells. CB dynamics was traced in inactivated oocyte nuclei, during a gradual condensation of chromosomes and their final assembling into the karyosphere. It has been shown that coilin, RNA polymerase II and SC35 protein are common compounds shared by CBs and some granular material associated with these condensed chromosomes. CB remnants were demonstrated in the ooplasm after the breakdown of nuclear envelope before the first meiotic division. In inactivated oocyte nuclei, CBs serve presumably as storage compartments for some inactive components essential for gene expression.     

Transformation of sperm nuclei to metaphase chromosomes in the cytoplasm of maturing oocytes of the mouse

Zona-free oocytes of the mouse were inseminated at prometaphase I or metaphase I of meiotic maturation in vitro, and the behavior of the sperm nuclei within the oocyte cytoplasm was examined. If the oocytes were penetrated by up to three sperm, maturation continued during subsequent incubation and became arrested at metaphase II. Meanwhile, each sperm nucleus underwent the following changes. First, the chromatin became slightly dispersed. By 6 h after insemination, this dispersed chromatin had become coalesced into a small mass, from which short chromosomal arms later became projected. Between 12 and 18 h after insemination, each mass of chromatin became resolved into 20 discrete metaphase chromosomes. In contrast, if oocytes were penetrated by four to six sperm, oocyte meiosis was arrested at metaphase I, and each sperm nucleus was transformed into a small mass of chromatin rather than into metaphase chromosomes. If oocytes were penetrated by more than six sperm, the maternal chromosomes became either decondensed or pycnotic, and the sperm nuclei were transformed into larger masses of chromatin. As control experiments, immature and fully mature metaphase II oocytes were inseminated. In the immature oocytes, which were kept immature by exposure to dibutyryl cyclic AMP, no morphological changes in the sperm nucleus were observed. On the other hand, in the fully mature oocytes, which were activated by sperm penetration, the sperm nucleus was transformed into the male pronucleus. Therefore, the cytoplasm of the maturing oocyte develops an activity that can transform the highly condensed chromatin of the sperm into metaphase chromosomes. However, the capacity of an oocyte is limited, such that it can transform a maximum of three sperm nuclei into metaphase chromosomes. Furthermore, the presence of more than six sperm causes a loss of the ability of the oocyte to maintain the maternal chromosomes in a metaphase state.     

F-actin is a component of the karyosome in neuropteran oocyte nuclei

The principles underlying the assembly of intranuclear compartments are only beginning to be understood. The karyosome is an organelle typical of oocyte nuclei. It represents the tightly packed oocyte chromosomes, arrested at the diplotene of meiotic prophase. It has been known from several insect orders that a prominent capsule of unknown materials is built around the karyosome in the course of previtellogenesis and vitellogenesis. Here we show that F-actin, detected by dye-coupled phalloidin, is a major molecular component of the karyosome capsule in Neuroptera. We investigated capsule formation in six species belonging to the family Chrysopidae. Though F-actin was present in the capsules of all six species there were striking interspecific differences in the morphological array of actin filaments and the developmental dynamics of actin deposition in the capsule. The potential biological significance of the karyosome capsule is discussed with respect to the presence of extrachromosomal rDNA in neuropteran oocytes and the molecular functions known from F-actin. Our results corroborate the still controversial hypothesis of a role for actin as a nuclear protein.     

Nuclear structures in the ovarioles of the butterfly Laspeyresia pomonella. Sex chromatin in trophocytes

The nuclear structures in the ovarioles have been studied in Laspeyresia pomonella by means of light and electron microscopy, autoradiography (RNA and DNA synthesis) and molecular hybridization in situ. The karyosphere was shown to form in oocyte nuclei at the beginning of oocyte growth. Numerous protein granules appeared in close contact with the karyosphere chromosomes; the true nucleolus was absent and the whole nucleus was inactive in RNA synthesis. A special attention was paid to studying nuclear structures in trophocytes. Numerous complex nucleoli actively synthesizing RNA formed in highly endopolyploid nuclei of trophocytes. Besides, each trophocyte had a spheroid vacuolized body of DNA which developed from one of meiotic bivalents soon after trophocyte differentiation and increased in diameter up to 10-15 mu. The DNA body in trophocytes and follicle cells was in close contact with the nucleolar material. Ribosomal DNA was present in these bodies as was shown by molecular hybridization in situ. A suggestion is put forward to the effect that the DNA bodies take part in the formation of complex nucleolar apparatus of trophocytes. On the basis of both the author's and literary data, a conclusion is drawn that DNA spheres in trophocytes and follicle cells are sex chromatin bodies formed, however, by both the X- and Y-chromosomes, rather than by one Y-chromosome.     

Formation of the karyosome in developing oocytes of weevils (Coleoptera, Curculionidae)

A complex structure termed the karyosome forms in the nuclei of the developing oocytes of Anthonomus pomorum, Hylobius abietis and Phyllobius sp. (Coleoptera: Curculionidae). It is composed of highly condensed chromosomes, fused with an electron-dense granular material. There are two types of nuclear body associated with the karyosome. The smaller bodies are found in the immediate vicinity of the karyosome. The larger, and more electron-dense, bodies originate next to the condensing chromosomes. During vitellogenesis, the latter bodies disperse in the karyoplasm, and at least some of them locate in the characteristic irregular projections of the germinal vesicle. Morphologically, these projections resemble the accessory nuclei described in other insects. In the studied species, a proteinaceous sheath, the so-called karyosome capsule, surrounds the karyosome. The formation of the karyosome and its capsule occurs during previtellogenesis, so that these structures are fully formed at the onset of vitellogenesis. An extraction of the oocyte cytoplasm with Triton X-100 showed that the material constituting the karyosome capsule is filamentous. Staining with rhodamine-conjugated phalloidin reveals large amount of F-actin in the karyosome capsule.