The karyosphere during late oogenesis in Rana ridibunda.

The organization of the nucleus in the oocytes of Rana ridibunda was examined during late diplotene at the light and electron microscopic level. At this stage the chromosomes are relatively condensed and assembled in the centre of the nucleus, constituting a karyosphere. The chromosomes here are associated with the central "protein sphere" (15--20 microns in diameter), obviously at their telomeres. Numerous nucleoli are accumulated around the chromosomes, forming a karyosphere capsule and contain segregated fibrillar and granular components; structures resembling perinucleolar chromatin and fibrillar bodies (spherules) are associated with the nucleoli. Granules 30 to 40 nm in diameter are seen to surround the fibrillar spherules. "Nucleolus-like bodies" consisting of granules 10 to 15 nm in diameter which are embedded in finely fibrillar material are often associated in contact with the chromosomes. The central sphere is an accumulation of annular structures similar to those of the pore complexes of the nuclear envelope. These structures are bound to the chromosome material, the "nucleolus-like bodies" and the fibrillar bodies. A participation of "nucleolus-like bodies" in the formation of the central sphere is suggested. A possible role of the nuclear protein matrix in the construction of the karyosphere elements 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.     

Nuclear ribonucleoprotein complexes of amphibian liver. II. Changes in the protein moiety during development.

Ribonucleoprotein complexes composed of small molecular weight nuclear RNA (4--9 S) and proteins were isolated from hepatic nuclei of Rana catesbeiana (bullfrog) and the protein moiety of this nuclear ribonucleoprotein complex compared during different stages of development. SDS-polyacrylamide gel analysis of premetamorphic tadpoles and adult frog nuclear ribonucleoprotein complexes revealed that while the protein profiles of these two particles were very similar polypeptides of 47,000, 70,000, and 11,000 molecular weight were present in significantly higher concentrations in the frog ribonucleoprotein complexes. Comparison of the chromatin proteins isolated from these two developmental stages demonstrated that these three polypeptides of frog ribonucleoprotein were not contaminants from chromatin. Since these three polypeptides could not be preferentially extracted from the frog ribonucleoprotein complex by 0.5 M KCl or 1 M urea, it was unlikely that these polypeptides were bound nonspecifically to the ribonucleoprotein particle. Polypeptide analysis of the nuclear ribonucleoprotein complexes isolated from tadpoles immersed in the thyroid hormone L-thyroxine revealed an increase in two polypeptides of 37,000 and 45,000 molecular weight during metamorphosis. The absence of reduced amount of these two polypeptides in either the premetamorphic tadpole or adult frog demonstrated that their presence in Rana catesbeiana nuclear ribonucleoprotein was transient during development and specifically associated with tadpole metamorphosis. We conclude from these experiments that the nuclear ribonucleoprotein complex is a dynamic structure during Rana catesbeiana development and that specific changes in its protein composition are associated with discrete stages of amphibian development.     

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.     

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 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.     

hnRNA and its attachment to a nuclear protein matrix

In this study, DNA-depleted nuclear protein matrices are isolated from HeLa S3 cells. These nuclear matrices consist of peripheral laminae, residual nucleoli, and internal fibrillar structures. High molecular weight, heterogeneous nuclear RNA (hnRNA) is quantitatively associated with these structures and can be released intact only by affecting the integrity of the matrices. It is, therefore, concluded that hnRNA is part of a highly organized nuclear structure. By irradiation of intact cells or isolated nuclear matrices with ultraviolet light, proteins tightly associated with hnRNA can be induced to cross-link with the RNA. Performing the cross-linking in vivo is an extra guarantee that only hnRNA-protein (hnRNP) complexes existing in the intact cell are covalently linked. Such hnRNP complexes were isolated and purified under conditions that completely dissociate nonspecific RNA-protein complexes. By comparison of the hnRNP found in nuclear matrices and the published data on the composition of hnRNP particles, it was found that the so-called hnRNP "packaging" proteins (32,000-38,000 mol wt) were not efficiently cross-linked to hnRNA by UV irradiation. They were, however, present in the matrix preparations, bound to hnRNA, because they were released from nuclear matrices after ribonuclease treatment of these structures. On the other hand, two major hnRNPs (41,500 and 43,000 mol wt) were efficiently cross-linked to hnRNA. These proteins were not released by ribonuclease treatment, which suggests that they are involved in the binding of hnRNA to the nuclear matrix.     

Synaptonemal complexes,telomeric nucleoli and the karyosphere in achiasmatic oocyte meiosis of the carob moth

Synaptonemal complexes and telomeric nucleoli are involved in the spatial organization and regular distribution of homologous chromosomes in meiosis of the achiasmatic female carob moth. The bivalents are held together from zygotene to metaphase by the Synaptonemal complexes. These are attached to telomeric nucleoli which appear during early meiotic prophase and are unique to the oocyte. The telomeric nucleoli fuse during prophase and the chromosomes concentrate into a small karyosphere before prometaphase. During the final stages of prophase elements of the Synaptonemal complex are found in the periphery of the fibrillar region of the telomeric nucleoli.     

Nuclear ribonucleoprotein complexes of amphibian liver. I. Characterization of the complex and its small molecular weight RNA moiety.

Nuclear RNA-protein complexes containing small molecular weight RNAs were isolated from hepatic nuclei of Rana catesbeiana tadpoles and frogs according to a procedure normally used for the isolation of heterogeneous nuclear ribonucleoprotein complexes from other eukaryotic tissues. Preliminary characterization of the tadpole nuclear RNP indicated a particle size of 50--70 S in sucrose density gradients and a buoyant density of 1.40 gm/ml in CsCl gradients. When analyzed on SDS-polyacrylamide gels, this complex was observed to contain at least 40 polypeptides ranging in molecular weight from 15,000 to 200,000. Nuclear RNA-protein complexes were also isolated from adult frog hepatic nuclei by the same protocol and the RNA moiety which had been purified from the frog complex was compared with the nuclear RNA isolated from the tadpole particles. Electrophoretic analysis of the nuclear RNA-protein-associated RNA revealed minor qualitative and quantitive differences in the more than 25 discrete bands (4--9 S) associated with each particle. Base analysis of tadpole and frog nuclear RNA revealed a nucleotide composition of approximately 50% adenosine plus uridine nucleotides, with an unusually high content of cytosine residues (approximately 30%). Comparison of the two RNA samples demonstrated a large increase in the adenosine content of frog unclear RNA, and the presence of a minor base in frog nuclear RNA which was absent in the tadpole sample. These results indicated that changes in the RNA content of the amphibian nuclear RNP complex had occurred during bullfrog development.     

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.     

Binding of the glucocorticoid receptor to the rat liver nuclear matrix. The role of disulfide bond formation

The nuclear matrix is a putative skeletal structure which has been implicated in many nuclear functions. To assess a possible role of the nuclear matrix in glucocorticoid action, purified rat liver nuclei containing glucocorticoid-receptor complexes were treated with DNase I +/- RNase A followed by 1.6 M NaCl, thus yielding salt-extractable and salt-resistant (nuclear matrix) fractions. The subnuclear distribution of hormone-receptor complexes was determined by following the fate of unmetabolized radiolabel after injection of labeled triamcinolone acetonide into adrenalectomized animals and subjecting various subfractions to immunoblotting using a monoclonal antibody which recognizes the glucocorticoid receptor. Both techniques indicated that 50-70% of the total nuclear hormone-receptor complexes were recovered in the nuclear matrix fraction. Previous results (Kaufmann, S. H., and Shaper, J. H. (1984) Exp. Cell Res. 155, 477-495) suggest that a variety of nuclear polypeptides become nuclease- and salt-resistant as a result of the formation of intermolecular disulfide bonds. The following evidence suggests that disulfide bonds mediate the association between the glucocorticoid receptor and the nuclear matrix. When nuclei were isolated in the absence of sulfhydryl-blocking and -cross-linking reagents, sodium dodecyl sulfate-polyacrylamide gel electrophoresis under nonreducing conditions revealed that the receptor was present as a high molecular weight disulfide-cross-linked complex. When nuclei were isolated in the presence of the irreversible sulfhydryl-blocking reagent iodoacetamide, the disulfide bonds which cross-linked the receptor into high molecular weight complexes were absent; and 85-100% of the hormone-receptor complexes were salt-extractable. When nuclei (isolated in the absence of iodoacetamide) were treated with the sulfhydryl-cross-linking reagent sodium tetrathionate, greater than 95% of the nuclear hormone-receptor complexes became resistant to extraction with nucleases and 1.6 M NaCl. The implications of these results for other matrix-associated nuclear functions are discussed.     

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.     

Isolation of galactosyltransferase from human milk and the determination of its N-terminal amino acid sequence

Galactosyltransferase (EC 2.4.1.22), purified to homogeneity from human milk by affinity chromatography, had an apparent molecular weight of 53,000 as determined by denaturing polyacrylamide gel electrophoresis. Subtraction of the estimated contribution of the oligosaccharide portion of the molecule leaves a Mr of 47,000. An N-terminal amino acid sequence analysis of the isolated protein revealed a sequence similar to that found near the 5' end of a cDNA clone isolated by Shaper et al, which encodes a 35,000 molecular weight protein. Either the molecular weight of galactosyltransferase, has been overestimated, or a discrepancy exists between the actual molecular weight of galactosyltransferase and that predicted by the bovine cDNA clone isolated by Shaper et al.     

Nuclear matrix network in Allium cepa

The presence of a nuclear matrix network in animal cells has been claimed by many workers in the last decade. The purpose of our study was to see whether a similar structure could be identified in the cells of higher plants. Our work revealed the presence of a fibrillar nonchromatinic network in Allium cepa nuclei. This could be impregnated with AgNO₃ in intact cells as well as in isolated matrices at the light microscope level. It was seen to be associated with the chromosomes from early to late prophase and also in telophase. Ultrastructurally a fibrillar network comparable to that reported earlier from animal cells was observed. This network remained associated with metaphase and anaphase chromosomes and could be digested with pepsin. Biochemical estimation of the isolated matrix revealed it to be made up mainly of proteins (more than 90%), traces of DNA (less than 1%) and a small quantity of RNA. SDS PAGE showed three polypeptide bands in the molecular weight range of 55,000–63,000 daltons.