THE FINE STRUCTURE OF THE NUCLEOLUS IN MITOTIC DIVISIONS OF CHINESE HAMSTER CELLS IN VITRO

The nucleolus of Chinese hamster tissue culture cells (strain Dede) was studied in each stage of mitosis with the electron microscope. Mitotic cells were selectively removed from the cultures with 0.2 per cent trypsin and fixed in either osmium tetroxide or glutaraldehyde followed by osmium tetroxide. The cells were embedded in both prepolymerized methacrylate and Epon 812. Thin sections of interphase nucleoli revealed two consistent components; dense 150-A granules and fine fibrils which measured 50 A or less in diameter. During prophase, distinct zones which were observed in some interphase nucleoli (i.e. nucleolonema and pars amorpha) were lost and the nucleoli were observed to disperse into smaller masses. By late prophase or prometaphase, the nucleoli appeared as loosely wound, predominantly fibrous structures with widely dispersed granules. Such structures persisted throughout mitosis either free in the cytoplasm or associated with the chromosomes. At telophase, those nucleolar bodies associated with the chromosomes became included in the daughter nuclei, resumed their compact granular appearance, and reorganized into an interphase-type structure.     

Ultrastructural composition of nonhistone chromosomal skeleton at different stages of mitosis in situ

In interphase cells of the SPEV culture treated with Triton X-100, 2 M NaCl, and DNAse, in the presence of 2 mM CuCl₂, we clearly revealed a stabilized nuclear protein material (NPM) composed of a peripheral lamina, residual nucleolus, and internal fibrillar network. This network is formed by thin fibrils 10–20 nm in diameter, which are also revealed in the nonhistone matrix of mitotic chromosomes at all stages of mitosis. In mitotic chromosomes, NPM is represented as a network of the 10–20-nm-thick fibrils without any features of the central-axial structures. Beginning from the middle prophase, it is possible to see approached sister chromatids in contact with each other in certain sites, similar to centromeres. At these sites, the thickness of fibrils increases up to 40–50 nm, whereas the fibrils themselves are disposed more tightly; this structure can be seen in the chromosome until telophase. At the end of telophase, the decondensation of chromosomes and formation of two new nuclei whose NPM is analogous to NPM of usual interphase nucleus are observed. Thus, the NPM elements can perform the role of a skeleton in both the interphase nucleus and mitotic chromosomes.     

Chromonema and chromomere

A study of ultrathin sections of normal Chinese hamster cells and cells treated with decreasing concentrations of bivalent cations (Ca²⁺ and Mg²⁺) in situ revealed several discrete levels of compaction of DNA-nucleoprotein (DNP) fibrils in mitotic chromosomes and the chromatin of interphase nuclei. At concentrations ranging from 3 mM CaCl₂ and 1 mM MgCl₂ to ten times less, the chromosomes are found to contain fibrous elements (chromonemata) about 100 nm in diameter. As Ca²⁺ concentration is gradually decreased to 0.2–0.1 mM, the chromosomes decondense into a number of discrete chromatin structures, the chromomeres. As decondensation proceeds, these chromomeres acquire a rosettelike structure with DNP fibrils radiating from an electron-dense core. Upon complete decondensation of chromosomes, individual chromomeres persist only in the centromeric regions. The following levels of DNP compaction in mitotic chromosomes are suggested: a 10-nm nucleosomal fibril, a 25-nm nucleomeric fibril, and the chromonema, a fibrous structure, about 100 nm in diameter, composed of chromomeres. Interphase nuclei also contain structures which are morphologically similar to the chromomeres of mitotic chromosomes.     

Dynamics of chromosome compaction during mitosis

We have quantitatively studied the space-time dynamics of mitotic chromosome compaction in cultured amphibian cells. After collecting digital phase-contrast images we have done digital image analysis to study spatial correlations in density. We find a characteristic distance at which the strongest correlations occur, which provides a quantitative measure of the size of patches of dense chromatin during interphase and early prophase. Later in mitosis, this length corresponds to the thickness of prophase and metaphase chromosomes. We find that during interphase strong correlations exist at a few-micrometer length; during prophase this correlation length progressively drops as the chromosomes are compacted. Our data are explained by a model based on assembly of chromatin loops onto already fiberlike interphase chromosomes. To test this model we have microinjected cobalt hexamine trichloride into interphase nuclei and have observed the rapid condensation of the interphase chromatin into thick fibers with a spacing similar to the native-state interphase correlation length determined from our image analysis.     

The ultrastructure of human mitotic chromosomes and interphase nuclei treated by Giemsa banding techniques

Total preparations of mitotic chromosomes and interphase nuclei prepared as for Giemsa banding techniques were investigated by standard transmission electron microscopy and by a method of a three dimensional representation. Chromosomes as well as interphase nuclei appear to be composed of irregularely folded fibrils of at least 300 Å thickness. In the G-band regions the chromosomes are thicker containing more foldings of fibrils. Also the fibrils are darker stained in the G-band regions. Loops of fibrils stick out from chromosomes as well as from interphase nuclei. When chromosomes or interphase nuclei come to lie close enough, such loops may stick together and form fibrillar bridges between them. These as well as interchromatid bridges are considered to be artefacts. The fibrils seem to be built up either of one or of several finer fibrils. No further conclusions regarding the fine structure of the fibrils can be drawn.     

ELECTRON MICROSCOPIC STUDIES OF MITOSIS IN AMEBAE : I. Amoeba proteus

Individual organisms of Amoeba proteus have been fixed in buffered osmium tetroxide in either 0.9 per cent NaCl or 0.01 per cent CaCl₂, sectioned, and studied in the electron microscope in interphase and in several stages of mitosis. The helices typical of interphase nuclei do not coexist with condensed chromatin and thus either represent a DNA configuration unique to interphase or are not DNA at all. The membranes of the complex nuclear envelope are present in all stages observed but are discontinuous in metaphase. The inner, thick, honeycomb layer of the nuclear envelope disappears during prophase, reappearing after telophase when nuclear reconstruction is in progress. Nucleoli decrease in size and number during prophase and re-form during telophase in association with the chromatin network. In the early reconstruction nucleus, the nucleolar material forms into thin, sheet-like configurations which are closely associated with small amounts of chromatin and are closely applied to the inner, partially formed layer of the nuclear envelope. It is proposed that nucleolar material is implicated in the formation of the inner layer of the envelope and that there is a configuration of nucleolar material peculiar to this time. The plasmalemma is partially denuded of its fringe-like material during division.     

The position of interphase chromosomes and late replicating DNA in centromere and telomere regions of Allium cepa L.

Chromosomes in G₁, S, G₂ and early prophase of Allium cepa root tip nuclei are oriented in the same position as telophase chromosomes. The centromeric heteroehromatin is aggregated in a chromocenter at one side of the nucleus, the telomeres scattered at the opposite side. Telomeres appear to associate with other telomeres in interphase in a roughly two by two fashion. Telomere-centromere DNA is late replicating. These results support the conclusion that chromosomes in higher organisms frequently maintain their telophase orientation from the end of telophase, during interphase and well into the next prophase.     

Karyomorphology of the genus Pomatosace Maxin. (Primulaceae)

Reported in this paper was the karyomorphology of the monotypic genus Pomatosace Maxim. The interphase nuclei and prophase chromosomes of P. filicula Maxim. were categorized to be complex chromocenter type and interstitial type respectively; themetaphase chromosomes were counted to be 2n = 20, ranging in length from 6.4µm to 4.1µm; the karyotype was formulated as 2n= 18m + 2sm, with the karyotype asymmetry belonging to 2A. The similar karyomorphological characteristics of interphase nuclei and　prophase chromosomes between Pomatosace and Androsace, together with the similar sizeand morphology of their metaphase chromosomes, support the viewpoint that they are closelyrelated.     

F-actin is a Nuclear and Chromosomal Component of the Meristematic Cells of Allium sativum

It is known that actin functionates in the form of F-actin. However, the presence of Factin in eukaryotic nuclei and chromosomes has not been well established. The authors labeled meristematic cells of Allium sativum L. with rabbit anti-chicken actin antibody and FITC-conjugated goat anti-rabbit IgG antibody and observed with fluorescence microscopy. Both the nuclei and chromosomes showed prominent yellow-green fluorescence, indicating the presence of actin in them. Fluorescence examination with TR1TC-conjugated phalloidin demonstrated prominent red fluorescence in the intact interphase cells, cytoplasm-free interphase nuclei, prophase and metaphase chromosomes as well as the daughter nuclei at telophase indicating the presence of F-actin; but the fluorescence was absent or very weak in the cells exposed to cytochalasin D before fixation. When double labeling of the anti-actin antibody and phalloidin was applied, the same nuclei and chromosomes were found to emanate yellow-green fluorescence representing actin at the excitation wavelength of F1TC, and red fluorescence representing F-actin at the excitation wavelength of TRITC, respectively. The FITC fluorescence and TRITC fluorescence shared the same distribution among the nuclei and chromosomes. These results indicate that F-actin is a component of the nuclei and chromosomes of the meristematic cells of A. sativum. It also suggests that F-actin may be the major existing form of actin in them.     

Entry into Mitosis in Vertebrate Somatic Cells Is Guarded by a Chromosome Damage Checkpoint That Reverses the Cell Cycle When Triggered during Early but Not Late Prophase

When vertebrate somatic cells are selectively irradiated in the nucleus during late prophase (<30 min before nuclear envelope breakdown) they progress normally through mitosis even if they contain broken chromosomes. However, if early prophase nuclei are similarly irradiated, chromosome condensation is reversed and the cells return to interphase. Thus, the G₂ checkpoint that prevents entry into mitosis in response to nuclear damage ceases to function in late prophase. If one nucleus in a cell containing two early prophase nuclei is selectively irradiated, both return to interphase, and prophase cells that have been induced to returned to interphase retain a normal cytoplasmic microtubule complex. Thus, damage to an early prophase nucleus is converted into a signal that not only reverses the nuclear events of prophase, but this signal also enters the cytoplasm where it inhibits e.g., centrosome maturation and the formation of asters. Immunofluorescent analyses reveal that the irradiation-induced reversion of prophase is correlated with the dephosphorylation of histone H1, histone H3, and the MPM2 epitopes. Together, these data reveal that a checkpoint control exists in early but not late prophase in vertebrate cells that, when triggered, reverses the cell cycle by apparently downregulating existing cyclin-dependent kinase (CDK1) activity.     

Polysaccharides associated with chromosomes and their behavior in the cell cycle

Summary The interphase nuclei, especially of the latest stages (G₂ or early prophase), in the mouse and rat livers were stained blue in the histochemical demonstration of acidic polysaccharide according to the method of Mowry, while the mitotic chromosomes (meta-, ana- and telophase) in the livers, sea urchin embryos as well as root tips of broad beans were stained red, suggesting the presence of neutral polysaccharide. The giant polytenic interphase chromosome of the salivary gland of Chironomus larvae was stained blue in the puffing and nucleolar regions while stained red in the condensed part of the chromosome. ³H-Glucosamine as well as ³H-glucose incorporations into the regenerating rat liver nuclei reached a peak at 30 h after partial hepatectomy when the highest mitosis is seen. These results suggest that the nuclear acid mucopolysaccharide present in the swollen chromosomes may be converted to or replaced with the neutral polysaccharide in the condensed chromosomes such as mitotic chromosomes or polytenic giant interphase chromosomes.     

Reversible chromosome condensation induced in Drosophila embryos by anoxia: visualization of interphase nuclear organization

We have studied the morphology of nuclei in Drosophila embryos during the syncytial blastoderm stages. Nuclei in living embryos were viewed with differential interference-contrast optics; in addition, both isolated nuclei and fixed preparations of whole embryos were examined after staining with a DNA-specific fluorescent dye. We find that: (a) The nuclear volumes increase dramatically during interphase and then decrease during prophase of each nuclear cycle, with the magnitude of the nuclear volume increase being greatest for those cycles with the shortest interphase. (b) Oxygen deprivation of embryos produces a rapid developmental arrest that is reversible upon reaeration. During this arrest, interphase chromosomes condense against the nuclear envelope and the nuclear volumes increase dramatically. In these nuclei, individual chromosomes are clearly visible, and each condensed chromosome can be seen to adhere along its entire length to the inner surface of the swollen nuclear envelope, leaving the lumen of the nucleus devoid of DNA. (c) In each interphase nucleus the chromosomes are oriented in the "telophase configuration," with all centromeres and all telomeres at opposite poles of the nucleus; all nuclei at the embryo periphery (with the exception of the pole cell nuclei) are oriented with their centromeric poles pointing to the embryo exterior.     

The chromosomes of Puschkinia libanotica during mitosis

The chromosome complement of Puschkinia libanotica is described. In addition to five pairs of A chromosomes plants may possess up to 7 B chromosomes. Part of the long arm of the B chromosome gives rise to a heterochromatic mass in interphase nuclei and this can be seen to be a double structure in G₁ nuclei and a quadruple structure in G₂ nuclei. It is believed that these configurations represent the pre- and post-replication forms of subchromatids in the heterochromatic segment of the B chromosome. Microdensitometry of metaphase chromosomes shows that the segment of the B chromosome that is heterochromatic during interphase has no more DNA per unit volume than any of the euchromatic A chromosomes.     

Presynaptic chromosome behavior in Lilium

The orientation and movement of chromosomes throughout premeiotic interphase in Lilium speciosum has been studied through three-dimensional reconstruction of electron micrographs of serial thin sections through microsporocyte nuclei. Anthers were chosen based upon the correlation between their length and the stage of the microsporocytes within, and were fixed for light and electron microscopy. A light microscopic survey of both squash preparations and thick sections was done to select the material for electron microscopic analysis. Microsporocytes from the selected anthers were serially sectioned (200–300 consecutive gold sections), stained for electron microscopy, and alternate sections of entire nuclei were photographed. Prints were traced, and these tracings were compiled to produce a composite of each nucleus in which the locations of the centromeres were indicated. The position of the centromeric structures (CeS) in each nucleus was characterized by the average distance between CeSs, the average distance between CeSs and the nuclear envelope, and the coefficients of variation of these distances. A test was made to determine if CeSs were positioned evenly throughout the nucleus. — The results indicate that centromeres do not exhibit extensive movement during PMI in Lilium speciosum cv. Rosemede and that homologous chromosomes do not undergo a prealignment during PMI which facilitates their pairing during later meiotic stages. A model of centromere movement in the interphase nucleus is proposed.     

Nuclear and microtubular cycles in heterophasic multinuclearTriticum root-tip cells induced by caffeine

Summary Nuclear and microtubular cycles were studied in large heterophasic multinuclear cells induced in root tips ofTriticum turgidum by caffeine treatment. Multinuclear cells and cells with polyploid nuclei exhibited various configurations of multiple and complex preprophase microtubule (Mt) bands (PPBs), including helical ones. The developmental stages of PPBs in some heterophasic cells did not comply with the cell cycle stages of the associated nuclei, a fact indicating that these events are not directly controlled by the associated nuclei. The heterophasic cells exhibited asynchronous nuclei at different stages of mitosis. In cells displaying prophase and interphase nuclei, the prophase spindle was either absent or developed around both of them or developed around the prophase nuclei earlier than around the interphase ones. During prometaphase-metaphase of the advanced nuclei the lagging interphase nuclei were induced to form prematurely condensed chromosomes (PCCs) along with spindle formation around them. These observations suggest that the mitotic transition in heterophasic cells is delayed but is ultimately achieved due to the effect of the advanced nuclei, which induces a premature mitotic entry of the lagging nuclei. Although kinetochore Mt bundles were found associated with PCCs, their metaphase and anaphase spindles were abnormal resulting in abnormal or abortive anaphases. In some heterophasic cells, metaphase-anaphase transition did not take place simultaneously in different chromosome groups, signifying that the cells do not exit from the mitotic state after anaphase initiation of the advanced nuclei. Asynchronous pace of mitosis of different chromosome groups was also observed during anaphase and telophase. Implications of these observations in understanding plant cell cycle regulation are discussed.Abbreviations cdk cyclin dependent kinase - Mt microtubule - PCC prematurely condensed chromosome - PPB preprophase band     

Large-scale chromatin structural domains within mitotic and interphase chromosomes in vivo and in vitro

Higher-order chromatin structural domains approximately 130 nm in width are observed as prominent components of both Drosophila melanogaster and human mitotic chromosomes using buffer conditions which preserve chromosome morphology as determined by light microscopic comparison with chromosomes within living cells. Spatially discrete chromatin structural domains of similar size also exist as prominent components within interphase nuclei prepared under equivalent conditions. Examination of chromosomes during the anaphase-telophase transition suggests that chromosomes decondense largely through the progressive straightening or uncoiling of these large-scale chromatin domains. A quantitative analysis of the size distribution of these higher-order domains in telophase nuclei indicated a mean width of 126±36 nm. Three-dimensional views using stereopairs of chromosomes and interphase nuclei from 0.5 m thick sections suggest that these large-scale chromatin domains consist of 30 nm fibers packed by tight folding into larger, linear, fiber-like elements. Reduction in vitro of either polyamine or divalent cation concentrations within two different buffer systems results in a loss of these large-scale domains, with no higher-order chromatin organization evident above the 20–30 nm fiber. Under these conditions the DNA distribution within mitotic chromosomes and interphase nuclei appears significantly diffuse relative to the appearance by light microscopy within living cells, or, by electron microscopy, within cells fixed directly without permeabilization in buffer. These results suggest that these large-scale chromatin structural domains are fundamental elements of chromosome architecture in vivo.     

Electron microscopic study of preleptotene-stage oocyte nuclei in the prophase of meiosis in the hen

The morphology of oocyte nuclei at preleptotene and early leptotene stages of meiotic prophase I in the chick embryo was examined by electron microscopy and light cytochemistry. The intrenuclear fibrillar body (IFB) of proteinaceous nature is described. The IFB has a spherical or irregular form and consists of the disoriented fibrils ranging from 3 to 18 nm in diameter and of globules lying along the course of fibrils. The condensed chromatin in the oocyte nuclei at the early--late preleptotene stages and the thread-like chromosomes in the oocyte nuclei at the middle preleptotene--early leptotene stages either closely adjoin to IFB, localized in the centre of the nucleus, or are situated at some distance from it, and then the fibrils or fibrillar filaments are seen between chromosome material and IFB. The chromosomes are attached to IFV by the telomer or interstitial segment. The chromosomes lose the connection with IFB after the attachment of both the telomeres to the nuclear envelope (middle--late leptotene), and IFB removes from the centre of the nucleus to its periphery. It is supposed that IFB represents a nuclear skeleton element and takes part in the spatial organization of the chromosomes in the oocyte nuclei at the early stages of meiotic prophase I.     

Light and electron microscopy of rat kangaroo cells in mitosis

Kinetochores in rat kangaroo (PtK₂) cells in prophase of mitosis are finely fibrillar, globular bodies, 5000–8000 Å in diameter. Sister kinetochores are attached to opposite lateral faces in the primary constriction of chromosomes. No microtubules (MTs) occur in prophase nuclei. During prometaphase the ball-shaped kinetochores differentiate into trilaminar plaques. An outer kinetochore layer, less electron dense than chromatin, appears first in the fibrillar matrix. The inner layer, continuous with, but more electron dense than the chromosome, is formed later. Kinetochore-spindle MT interaction is evident at the very beginning of prometaphase. As a result, kinetochore shape is very variable, but three types of kinetochores can be distinguished by fine structure analysis. A comparison of kinetochore structure and chromosome position in the mitotic spindle yielded clues regarding initial orientation and congression. At the time the nuclear envelope (NE) breaks down chromosomes near asters orient first. Chromosomes approximately equidistant from the two spindle poles amphi-orient immediately. Chromosomes closer to one pole probably achieve mono-orientation first, then amphi-orient and congress. In normal metaphase all the chromosomes lie at or near the spindle equator and kinetochores are structurally uniform. Paraxial and para-equatorial sections revealed that they are trilaminar, roughly circular plaques of 4000–6000 Å diameter. Inner and outer layers are 400 Å, and the electron translucent middle layer which separates them is 270 Å thick. From 16 to 40 MTs are anchored in the outer layer. In cold-treated cells the kinetochores are trilaminar, but in colcemid-treated cells the inner layer is lacking. Both kinetochores and their MTs are disorganized beginning in late anaphase. In telophase the inner layer persists for some time as an electron dense patch apposed to the NE, while the outer layer disintegrates.     

星叶草属的核形态及其系统位置

本文研究了星叶草属的核形态。其间期核和前期染色体分别为简单染色中心型和中间型;中期染色体较小,长度介于3.00μm到1.20μm之间;核型公式为2n=30=22m+8sm。其明显很高的染色体基数以及其它退化和特化的形态学性状,表明该属是一个孑遗的古多倍体类群。该属与独叶草属在间期核形态、前期染色体形态以及中期染色体的大小和形态方面极为相似。结合其它方面的资料,本文认为星叶草属和独叶草属有较近的亲缘关系,支持将它们一起置于星叶草科的观点。     

Distribution of kinetochore (centromere) antigen in mammalian cell nuclei

Antigens associated with mammalian centromeres were localized at the high and electron microscopic levels using the peroxidase-labeled antibody method. The antibody used was of a type naturally occurring in the sera of patients with scleroderma. At the light microscopic level, it reacts specifically with the centromere regions of chromosomes in a variety of mammalian species and strains in discrete foci in interphase nuclei. We find that the number of foci approximates the number of chromosomes present in the various cell types. At the ultrastructural level, the antigenic foci are confirmed to lie in the kinetochore regions of each chromosome. In interphase nuclei, the antigenic foci were usually associated either with the inner surfaces of the nuclear envelope or with the nucleoli. These observations indicate that the centromere regions of the chromosomes in interphase are not randomly distributed within the nucleus but are usually fixed either to the inner surface of the nuclear envelope or to nucleoli.