The changes in chromosome 6 spatial organization during chromatin polytenization in the Calliphora erythrocephala Mg. (Diptera: Calliphoridae) nurse cells

Localization of Calliphora erythrocephala chromosome 6 in a 3D nuclear space at different stages of nurse cell chromatin polytenization was analyzed by fluorescence in situ hybridization and 3D microscopy. The obtained results suggest a large-scale chromatin relocation in the C. erythrocephala nurse cell nuclei, which is accompanied by a change in the chromosome territory of chromosome 6 associated with the change in expression activity of the nucleus and formation of reticular chromatin structure. It was revealed that the relocation of chromosome 6 (nucleolus organizer chromosome) is accompanied by fragmentation of the single large nucleolus into micronucleoli, which are spread over the entire nuclear space being associated with their nucleolar organizer regions. Presumably, the chromosome 6 material during transition to a highly polytenized structure is redistributed in the nucleus so that the inactive pericentromeric regions are displaced to the nuclear periphery, while the chromosome regions carrying rDNA sequences loop out beyond the chromosome territory. Being dispersed over the entire nuclear space, rDNA sequences are likely to be amplified, thereby providing numerous small signals from the chromosome 6-specific DNA probe. Micronucleoli are formed around the actively transcribed nucleolar organizer regions.     

Fine structural organization of a non-reticulate plant cell nucleus

We studied the fine structural organization of the meristematic nucleus in roots of Lycopesicon esculentum (tomato) using ultracytochemical and immunocytochemical approaches. The nucleus has a non-reticulate (i.e. low DNA content) structure whose supramolecular organization differs in some respects from that in reticulate nuclei, principally in the organization of the chromocentres associated with the nuclear envelope, with which centromeric structures appear to be associated. The main difference at the nucleolar level is found in the fibrillar centres, which have a low amount of DNA labelling and in which inclusions of condensed chromatin are present only very rarely. The distribution of nucleolar DNA amongst the nucleolar compartments is similar to that in reticulate nucleoli as demonstrated using an anti-DNA monoclonal antibody. Tomato nuclei have nucleolus-associated bodies or karyosomes, like other plant species with a low DNA content and non-reticulate nuclear organization. The nuclear ribonucleoprotein structures in the inter- and perichromatin regions, namely inter- and perichromatin fibrils and granules, show similar ultrastructural and cytochemical characteristics in both types of nuclei.Abbreviations NAC nucleolus associated chromatin - CES centromeric structures - NOR nucleolar organizing region - NAB nucleolus associated body - IG interchromatin granules - RNP ribonucleoprotein - Mab monoclonal antibody by M.F. Trendelenburg     

Studies on chromatin organization in a nucleolus without fibrillar centres

In embryonic cell-line derivative KCo of Drosophila melanogaster, the nucleolus, like most nucleoli, contains a small proportion of ribosomal DNA (1-2% of the total nucleolar DNA). The ribosomal DNA is virtually the only active gene set in the nucleolus and is found among long stretches of inactive supercoiled heterochromatic segments. We have demonstrated by use of a Feulgen-like ammine-osmium staining procedure that, depending on the state of growth, more or less fibres of decondensed DNA emanating from the intra-nucleolar chromatin (which is in continuity with the nucleolus-associated chromatin) ramify and unravel within the central nucleolar core to be transcribed. The nucleolus expands or contracts with the variation of activity and could belong to a supramolecular matricial structure such as is shown after extraction of the nuclei. After a long period of exposure to high doses of actinomycin D, the central nucleolar core became an homogeneous fibrous structure that could be interpreted as an aggregate of protein skeletal elements. The mechanism of repression and derepression of the nucleolar chromatin could thus be explained by a mechanism involving in part a sub-nucleolar structure. We propose a schematic organization of the nucleolar chromatin in KCo cells of Drosophila and discuss it in relation with other nucleolar organizations.     

Localization of rRNA genes in the nuclear space of Calliphora erythrocephala Mg. nurse cells during polytenization

Multicolor 3D fluorescence in situ hybridization was used to study arrangement of rRNA genes in Calliphora erythrocephala nurse cell nuclei with different levels of polyteny. It has been shown that the rRNA genes are exclusively localized to chromosome 6, suggesting that chromosome 6 is the only C. erythrocephala chromosome responsible for nucleolar formation. We have also described changes in localization of ribosomal genes within the chromosome territory during polytenization, namely, that rDNA signals are detected in the peripheral region of chromosome territory starting from the stage of polytene chromosomes. In addition, it has emerged that large nucleolus associated with chromosome 6 starts to develop in the central nuclear region in the C. erythrocephala nurse cell nuclei at the stage of a primary reticular structure. The central position and nucleolar structure are retained at the stages when chromosome 6 occupies the central position, that is, at the stages of polytene and bloblike chromosomes. When the nucleus restores a reticular structure but at a higher polyteny level, the displacement of chromosome 6 to the nuclear periphery is accompanied by disruption of the large nucleolus into micronucleoli. The micronucleoli are distributed in the nuclear space retaining their association with the nucleolar-organizing regions of chromosome 6. Thus, our data suggest that the large-scale alterations in the organization of chromosome 6 and the nucleolus during polytenization are the correlated processes directly dependent on the rRNA gene activity. The earlier described dynamics of nucleolar-organizing chromosome territory and nucleolus in the nuclear space is likely to be associated with the change in the total expression activity of the nucleus, which complies with the hypothesis on the correlation between spatial nuclear organization and expression regulation of genetic material.     

Conformation of RNA in situ as studied by acridine orange staining and automated cytofluorometry.

Human erythroblasts which are prereticulocyte maturation stages of red blood cells were studied by light microscopic cytochemistry and electron microscopy to provide more information on the ultrastructure of the micronucleoli which are terminal stages of nucleolar changes found during maturation of these cells. As indicated by light microscopy of smeared cells, micronucleoli were virtually the only types of nucleoli present in the last stages of maturing erythroblasts, i.e., polychromatic and orthochromatic (late polychromatic) erythroblasts. Accordingly, they were not portions of the periphery of other nucleoli. Inasmuch as most of the micronucleoli exhibited characteristic segregation of nucleolar fibrillar and granular components they presumably are producing little if any preribosomal RNA, since such segregation generally reflects inhibition of nucleolar RNA synthesis.     

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

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

多头绒泡菌银染核仁周期的电镜研究

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

A light and electron microscopic study of mitosis inBullera alba and the histochemistry of some cytoplasmic substances

Summary Mitosis in the imperfect yeast-like basidiomyceteBullera alba was studied by comparative light and electron microscopy. During mitosis the chromatin containing part of the nucleus moved into the progeny cell, and the nucleolus containing part of the nucleus remained in the parent cell. The two portions of the nucleus then separated and the nucleolar part degenerated. Metaphase and anaphase took place in the progeny cell. Subsequently one mass of chromatin returned to the parent cell, and two new nuclei were formed. The study concentrated on the nuclear envelope, nucleolus, spindle pole body, chromatin, spindle, and cytoplasmic microtubules. Mitosis inB. alba was compared with reports of mitosis in other basidiomycetes, theUredinales, and theAscomycotina and was deemed closest to the heterobasidiomycete yeasts.Histochemical evidence for the presence of lipid, glycogen, and polyphosphate in the cytoplasm was presented.     

Coiled bodies in supraoptic nuclei of the rat hypothalamus during the postnatal period

In electron microscopic studies of the supraoptic nuclei of the rat hypothalamus, structures identified as "coiled bodies" were found in magnocellular neurons. Although they could be seen elsewhere in mature neurosecretory cells, coiled bodies were commonly encountered in developing neurons during the postnatal period in both sexes. They appeared as distinctive nuclear inclusions consisting of round-to-oval networks of short electron-dense strands embedded in a less dense, fibrillar matrix, and lacking a limiting membrane. In fine structure and stain-affinity, they bore a resemblance to the fibrillar component of the nucleolus. Coiled bodies were located either in close association with the nucleolus or free within the nucleoplasm, showing no specific relationships with the perinucleolar chromatin or with the nuclear envelope. Their origin and functional meaning is discussed in the light of recent ultrastructural and biochemical data on cellular differentiation and nucleolar behavior.     

多头绒泡菌细胞核周期的电镜研究

多头绒泡菌PhysarumpolycophalumSchw的营养生长阶段为没有细胞壁的原生质团（合胞体）,内部众多的细胞核进行着同步的核内有丝分裂,本文电镜下研究了细胞核在有丝分裂周期中的结构变化。有丝分裂前期,染色质经松散改组和集缩形成染色体,核仁由中央移向边缘,并在近核膜处解体;中期核膜不消失,在核内形成纺锤体,核仁解体后的物质是不规则状散在于核内;有丝分裂后核膜的破裂处重新愈合,染色体解集缩成染色质,分散的核仁物质逐渐合并形成新的核仁。     

Ultrastructural Changes of the Nucleolus During Cell Cycle in Triticum aestivum

The ultrastructural changes of the nticleolus during cell cycle in common wheat (Triticum aestivum L. ) were studied by an "en bloc" silver-staining method. It was observed that in interphase, the nucleolus was heavily stained, within which fibrillar centres, dense fibrillar component, granular component and nucleolar vacuoles could be identified. A large quantity of argentine fine granules were distributed in the condensed chromatin. Dur-ing prophase, along with the disintegration of the nucleolus and condensation of the chromatin, the larger heavily-stained granules gradually appeared at the periphery of the chromatin. At late prophase, the materials derived from the nucleolus were spread and deposited on the surface of the chromosomes. The silver-stained, larger granules, deriving from the disintegrated nucleolus, accumulated at the periphery of the metaphase chromosomes and formed an uneven and discontinuous "sheath"-like structure. This "sheath"-like structure was also observed at anaphase. In telophase, the silver-stained nucleolar materials were progressively separated from the "sheath' and fused with each other to form prenucleolar bodies, and at last, participating in the formation of new nucleoli. The results showed that the nucleolar materials were transferred directly to the surface of the chromosomes and formed a discontinuous coat, but not incorporated into the interior of the chromosomes. The silverstained granules inside the chromosomes were neither related to the nucleolus nor to the materials from the disintegrated nucleolus.     

A STUDY OF THE NUCLEOLAR MATERIAL IN SCIARA COPROPHILA

In the polytene chromosomes of Sciara coprophila, in addition to a nucleolus, large numbers of nucleolarlike structures or micronucleoli are formed. A detailed mapping localized the nucleolar organizer at one end of the X chromosome and revealed that approximately 18% of the bands of each chromosome are potentially capable of producing micronucleoli. Most of these sites are in regions known from a previous study to show asynchronous DNA replication: DNA puffs and certain heterochromatic regions. Micronucleoli are rarely found in association with bulbs. The RNA metabolism of the polytene chromosomes during late fourth instar was studied using radioautographic techniques. Isolated glands were incubated in tritiated uridine for 10 to 30 min, and radioautographs were made of squash preparations. Despite the wide range of variation found among different larval cultures, the following pattern was observed. Just prior to and at the beginning of DNA puff formation, a period of intense extrachromosomal nucleolar and micronucleolar RNA synthesis occurs. After maximal development of the DNA puffs, the synthesis of extrachromosomal RNA is at a low point, while incorporation into bulbs and DNA puffs remains high. With the onset of the prepupal stage, all nuclear RNA synthesis ceases.     

‘Nucleolar dominance’ as observed in barley translocation lines with specifically reconstructed SAT chromosomes

Summary Diploid homo- and heterokaryotypes of barley translocation lines with only one satellite chromosome pair containing two nucleolus organizer regions (NORs) in opposite arms were found to show repressed nucleolus formation by the transposed NOR as evident from the formation of only micronucleoli. The same was true for auto-tetraploid homokaryotypes and for translocation lines with all NORs tandemly arranged into the same chromosome arm. When NORs were transposed to chromosomes without NOR in the standard karyotype, the normal pattern of nucleolus formation remained unaffected. The modified mode of nucleolus formation after the combination of all NORs in one chromosome pair is interpreted to be due to intrachromosomal nucleolar dominance analogous to interchromosomal nucleolar dominance observed in certain interspecific hybrids.     

Detection of intranuclear forces by the use of laser optics during the recovery process of elongated interphase nuclei in centrifuged protenemal cells ofAdiantum capillus-veneris

For the direct investigation of intranuclear dynamics in living cells, extremely deformed nuclei of basipetally centrifuged protonemal cells of the fernAdiantum capillus-veneris were manipulated by the laser trap and the laser scalpel. Whereas the nucleolus was tightly fixed at the central position inside the non-centrifuged nucleus and proved to be immovable by the optical trap, it could easily be trapped and moved towards three directions inside the bubble-like terminal widening of the basal thread-like extension of centrifuged nuclei. Due to the connection of the nucleolus to the chromatin inside the nuclear thread (NT), moving was not possible against the direction of the nuclear apical main body. Nucleoli in recovered nuclei were again immovable, thus indicating the presence of a dynamic nucleolar anchoring system inside the nucleus. When the nucleolus in the bubble was arrested during the thread shortening process by the optical trap, the acropetal movement of the bubble continued. Probably due to dragging forces, some nucleoli became stretched, and a thick strand of a still unknown composition stretched between the nucleolus and the insertion site of the shortening NT. To assess whether the shrinking of the nuclear envelope (NE) and the shortening of the chromatin inside the NT were independent processes, the chromatin above the bubble was cut inside the NT by the laser scalpel. After severance, a gap between the nucleolus and the end of the chromatin strand in the NT indicated the shortening of the chromatin inside the NT. From these findings it was concluded that a shortening force was existing in the chromatin of the NT and that probably no physical link existed between the chromatin and the NE.     

THE FINE STRUCTURE OF THE NUCLEOLUS DURING MITOSIS IN THE GRASSHOPPER NEUROBLAST CELL

The behavior of the nucleolus during mitosis was studied by electron microscopy in neuroblast cells of the grasshopper embryo, Chortophaga viridifasciata. Living neuroblast cells were observed in the light microscope, and their mitotic stages were identified and recorded. The cells were fixed and embedded; alternate thick and thin sections were made for light and electron microscopy. The interphase nucleolus consists of two fine structural components arranged in separate zones. Concentrations of 150 A granules form a dense peripheral zone, while the central regions are composed of a homogeneous background substance. Observations show that nucleolar dissolution in prophase occurs in two steps with a preliminary loss of the background substance followed by a dispersal of the granules. Nucleolar material reappears at anaphase as small clumps or layers at the chromosome surfaces. These later form into definite bodies, which disappear as the nucleolus grows in telophase. Evidence suggests both a collecting and a synthesizing role for the nucleolus-associated chromatin. The final, mature nucleolar form is produced by a rearrangement of the fine structural components and an increase in their mass.     

Ultrastructural cytochemistry of the mammalian cell nucleolus

In the present review on the organization of the mammalian cell nucleolus, we report and discuss data obtained during the past 10 years by means of cytochemical and immunocytochemical ultrastructural techniques. Particular emphasis is placed on the following topics: location of the nucleolus organizer regions in interphasic nucleolar components, structure of nucleolar chromatin in situ, and the structure-function relationship of the nucleolar components. The cytochemical and immunocytochemical results are compared and the concordant data are stressed for each topic.