Nucleolar organizers and fibrillar centres in Triticum aestivum L., cv. Chinese spring

Serial sectioning of wheat roots prepared for electron microscopy was used to count the number of fibrillar centres per nucleus and nucleolus and to calculate their sizes. After growth at 35 ° C for two days the nucleoli became segregated and a one to one relationship was evident between chromosomal nucleolar organizers and fibrillar centres. This was confirmed using an aneuploid line carrying an additional pair of organizers. Quantitative studies showed that the fibrillar centres occupied a volume 0.24% of the total chromatin reticulum. From this it was calculated that only about 1/3 of the fibrillar centre material was likely to be nucleolar organizer chromatin. The other material was considered to be the protein revealed in silver staining studies. The importance of this was shown by its constant ratio to the size of all nucleoli in a given nucleus. — Evidence was found for the movement and fusion of organizer flanking regions during growth at 35 ° C. The number of junctions between chromatin and nucleolar organizers drops by about half giving one per organizer after segregation, and serial sectioning demonstrated such junctions in close proximity, an arrangement suggestive of incipient fusion.     

Laser microbeam irradiation of the juxtanucleolar region of prophase nucleolar chromosomes

To further understand the function of the nucleolus organizer (NO), especially as it relates to the mitotic cycle, we extended our previous irradiation studies to prophase chromosomes and nucleoli. The juxtanucleolar region of nucleolar chromosomes was irradiated with the argon laser microbeam, and cells were observed for several days. Nuclei with two nucleoli were generally chosen for irradiation because of their two clear secondary constrictions. Summarized results are as follows: (1) When either one or several juxtanucleolar sites of both or all nucleoli are irradiated, the mitotic process is blocked and the cells return to interphase. (2) When only the chromosomes associated with the largest nucleolus are irradiated, mitosis is also blocked. (3) When the juxtanucleolar regions of the smallest nucleolus are irradiated, the cells generally go into metaphase and complete division, but with a reduction in the number of resulting nucleoli. (4) When the nucleoli themselves are irradiated, mitosis proceeds and daughter nuclei show no reduction in nucleolar number. (5) When chromosomes are randomly irradiated at non-juxtanucleolar regions, the nucleus divides and produces the same number of nucleoli in each daughter nucleus as were present in the mother cell.     

Tissue and sex differences in the expression of nucleoli in mouse somatic cells.

In Mus musculus, the nucleolus organizer regions (NORs), or sites of ribosomal RNA-encoding genes, map at three chromosomal pairs. A silver procedure was modified to stain nucleoli in interphasic somatic cells of mice. The number of nucleoli per cell nucleus was determined in squashed cells of kidney, liver and pancreas obtained from male and female mice. In liver and pancreas cells the average number of nucleoli per cell was 4.84 and 4.66, respectively, and only 2.83 in kidney cells (p < 0.001). Less than 8% of pancreas cells and about 15% of liver cells contained more than 6 nucleoli per cell, which was the maximum expected number. In addition, the number of nucleoli per cell was significatively different (p < 0.01) when male and female liver or pancreas cells (not kidney cells) were compared. In both cases, female cells presented more nucleoli than the respective male cells. Assuming that the available NORs are the same, the variable number of nucleoli in the examined cell types would be the consequence of a tissue specific NOR regulation. The apparent influence of sex on this regulation is noted.     

Analysis of nucleolus organizer regions (NORs) in mitotic and polytene chromosomes ofPhaseolus coccineus by silver staining and Giemsa C-banding

Chromosomes with active nucleolus organizer regions (NORs) were visualized in root tip metaphases ofPhaseolus coccineus using the silver staining technique. A mean number of 5.5 Ag-NORs per cell was observed in 54 cells from eight plants. In the endopolyploid nuclei of the suspensor the silver technique did not demonstrate the reported specificity for nucleolus organizer activity, because there was usually pale staining of nucleoli and preferential staining of heterochromatic regions in the polytene chromosomes including pericentromeric material, telomeres and NORs. The mean number of NORs per nucleolus as detected by this method was 5.8 (28 nucleoli analysed). Using a modified preparation technique, giant chromosomes stained pale, but nucleoli of suspensor cells displayed darkly silver staining internal domains, each of which originating from a nucleolus organizer.—Giemsa C-banding of endopolyploid suspensor nuclei revealed C-positive nucleolus organizers with darkly staining intranucleolar fibrils. The latter were frequently involved in inter-NOR associations. In 34 nucleoli analysed, the mean number of Giemsa C-positive NORs per nucleolus was 6.0.Dedicated to Professor Dr.Lothar Geitler on the occasion of his 80th birthday.     

Silver staining of the nucleoli of pig embryonic kidney cells during the hyperactivation and inhibition of the synthesis of nucleolar RNA by UV microirradiation

Silver staining of the nucleoli in pig embryo kidney cells (PK) was studied during the cell cycle and also upon mature nucleoli modifications induced by UV microirradiation. During anaphase only four silver-stained granules were revealed in each daughter set of chromosomes in the four nucleolus-organizing regions (NORs). In the following 1-2 hours, the number of granules in the NORs rapidly increased up to 25-30 per nucleus. During the next 20-25 hours of the cell cycle, the number of silver-stained granules was slowly doubling as the nucleoli grew in size. UV microirradiation of one nucleolus in the nucleus with two nucleoli induced a profound degradation of the injured nucleolus and a compensatory hypertrophy of the intact one. Such nucleolar modifications were accompanied by redistribution of the silver-stained granules between the injured and non-injured nucleoli and by alterations in the levels of nucleolar RNA synthesis in the NORs. These data support a hypothesis that silver-stained proteins may be involved in the regulation of the nucleolar activity.     

Studies on changes in nucleolar organizer region of human promyelocytic leukemia cells (HL-60) treated with retinoic acid

Changes of nucleolar organizer region in HL-60 cells after treated with retinoic acid (RA) were studied with techniques of silver-staining nucleolar organizer region (Ag-NOR) in metaphase karyotypes, Brachet's reaction and with our improved TEM techniques for studying silver-stained active nucleolar organizer region (Ag-aNOR) in interphase nucleoli. Number of Ag-NOR in HL-60 cells is 4.5/cell on average. The Ag-NOR number of cells treated with RA showed no remarkable difference from that of control group. Ag-aNOR number treated with RA was reduced obviously as compared with that of control group. Meanwhile, the changes of nucleolus number showed by Brachet's reaction were in accordance with those of Ag-aNOR. Therefore, it may be concluded: (1). Though the number of active rRNA genes did not changed after the differentiation of HL-60 cells induced by RA, their expression was clearly inhibited: (2). The relationship between the changes of Brachet-No and Ag-aNOR is in positive correlation (r = 0.98, p less than 0.01). EM examination of Ag-aNOR of HL-60 cells reveals that Ag-protein (RNA polymerase I) only presented in fibrillar centers (FC) and the dense fibrillar components (DFC) of nucleolus. In addition, in control group, large amount of Ag-protein, FC, DFC and granular components (GC) were observed, and there were many large nucleoli in a nucleus, meanwhile, the cells of the treated group tended to be mature, with a decrease in the amount of Ag-protein, FC, DFC and GC accordingly, and the nucleoli reduced both in size and number significantly.(ABSTRACT TRUNCATED AT 250 WORDS)     

A chromosome rearrangement in Neuvospora that produces viable progeny containing two nucleolus organizers

In rearrangement T(VLIVL)AR33 the segment of chromosome 2 bearing the nucleolus organizer is translocated to the end of chromosome 4. When AR33 is crossed by Normal sequence (N), one third of the viable progeny contain a stable nontandem duplication with two organizers per nucleus. The organizer-deficient complementary products are inviable. Chromosomes and nucleoli have been examined during meiosis and postmeiotic nuclear divisions in the ascus, comparing heterozygous AR33 × N crosses with N × N and with crosses heterozygous for other interchanges. When AR33 is heterozygous, asci are of three types having the nucleolus organizer duplicated in 0, 1 or 2 of the meiotic products. Frequencies of the ascus types are as expected from the known positions of rearrangement break points. Nucleoli formed by two organizers frequently fuse. Deficiency nuclei that contain no nucleolus organizer may form one or more small nucleolus-like bodies.     

The genetic control of nucleolus formation in wheat

The wheat variety Chinese Spring has four pairs of nucleolus organisers of known rDNA content. The genetic control of these has been investigated in root tip cells by cytologically scoring the number of nucleoli per cell in (a) aneuploid derivatives each having a different dosage of a particular chromosome or chromosome arm and (b) in substitution lines where nucleolus organiser chromosomes have been replaced by homologues possessing different amounts of rDNA. It has been assumed that nucleolus organiser activity is correlated with nucleolus size and thus with the presence of a cytologically visible nucleolus. Those nucleolus organisers on chromosomes 1A and 5D, which together possess only 10% of the rDNA form a visible nucleolus only infrequently in the presence of the larger nucleolus organisers on chromosomes 1B and 6B. When a major pair of organisers on chromosomes 1B or 6B is deleted, the smaller nucleolus organisers form a visible nucleolus more frequently. Similarly, when the major nucleolus organisers are replaced by organisers with less rDNA, the smaller nucleolus organisers form visible nucleoli more frequently. When a small nucleolus organiser is replaced by one with much more rDNA, a larger nucleolus is formed. These and other findings lead to the general conclusions that there is a frequently, but not invariably, seen correlation between rRNA gene number and nucleolus size. However the relative size of the nucleolus formed depends principally upon the proportion of the total active rRNA genes in the cell which are localised at the nucleolus organiser in question. Varying the dosage of at least 13 non nucleolus organiser chromosomes also resulted in changes in the number of visible nucleoli per cell. This implies the genetic control of individual nucleolus organisers is complex. Inclusion in the wheat genome of the nucleolus organiser chromosome from Aegilops umbellulata, causes suppression of the wheat nucleolus organisers, the Aegilops umbellulata organiser remaining active. This suppression is similar to that observed in many interspecific plant and animal hybrids.     

A chromosome rearrangement in Neurospora that produces segmental aneuploid progeny containing only part of the nucleolus organizer

In translocation T(ILVL)OY321 of Neurospora crassa a distal portion of the nucleolus organizer chromosome, including ribosomal DNA sequences and the nucleolus satellite, is interchanged with a long terminal segment of IL. When OY321 is crossed by Normal sequence, one-fourth of the meiotic products are segmental aneuploids that contain two copies of the long IL segment and that are deficient for the distal portion of the organizer. Each such product forms a nucleolus and is viable. The complementary aneuploid products are deficient for the IL segment and are therefore inviable. — In crosses of OY321xOY321, each product is capable of making two nucleoli; nucleoli formed by the separated nucleolus organizer parts usually fuse, but most 8-spored asci contain some nuclei in which two separate nucleoli can be seen. One nucleolus is then terminal on its chromosome while the second is interstitial and somewhat smaller. — In crosses of OY321 x Normal, half of the meiotic products are capable of making two nucleoli. However, only about 15% of 8-spored asci have one or more nuclei containing separate nucleoli. At pachytene and later in prophase I, the single fusion nucleolus is associated with three bivalent chromosome segments. Each nucleus of every ascus contains at least one nucleolus, even in asci where some nuclei display two nucleoli. — Crosses of Aneuploid x Normal are usually semibarren, producing a reduced number of ascospores, some of which are inviable. Some aneuploid cultures become fully fertile by reverting to a quasinormal sequence lacking a satellite. In some crosses of Aneuploid x Normal, individual asci may show at prophase I either complete loss, partial loss, or pycnosis of the translocated IL segment. This observation of pycnosis suggests chromosome inactivation. — Growth from aneuploid ascospores is initially slow, but can accelerate to the wild-type rate.     

Imaging of Nucleolar Dynamics During the Cell Cycle of Cancer Cells in Live Mice

The synthesis and assembly of ribosomal subunits take place in the nucleolus. The nucleolus forms in the nucleus around the repeated ribosomal gene clusters and undergoes cyclic changes during the cell cycle. Although the nucleolus is easily visualized by light microscopy of cells in vitro, the nucleolus has not been imaged in cells in vivo. We report here development of a mouse model to visualize the nucleolus cycle of cancer cells in live mice. HT-1080 human fibrosarcoma cells were labeled in the nucleus with histone H2B-GFP and with retroviral RFP in the cytoplasm. The nucleolus was visualized by contrast to the fluorescence of GFP expressed in the nucleus. HT-1080 dual-color cells were seeded on the surface of a skin-flap of nude mice. The inside surface of the skin-flap was directly imaged with a laser scanning microscope 24 hours after seeding. The nucleoli of the cancer cells were clearly imaged in real-time. The appearance of the nucleoli changed dramatically during the cell cycle. During mitosis, the nucleolus disappeared. After mitosis, the nucleoli decreased in number and increased in size. The nucleolus appears to have a major role in cell cycle regulation effected at least in part by sequestering proteins which affect cell cycle progression. Nucleolar imaging could be used for more precise determination of cancer-cell position in the cell cycle in vivo.     

A further study on nucleolar silver stained granules in some mononuclear-lymphoid bone marrow cells

Nucleolar silver stained granules (SSGs) representing nucleolus organizer regions (NORs) were investigated in human as well as rabbit bone marrows after visualization with standardized silver reaction for non-histone nucleolar argyrophilic proteins. The results indicated that few mononuclear lymphoid blast-like cells in investigated bone marrows are characterized by large irregularly shaped nucleoli which contain a larger number of SSGs than myeloblasts or proerythroblasts as well as immature or stimulated lymphocytes. Since according to previous studies the number of nucleolar SSGs decreased in the course of the erythroid, granulocytic and lymphocytic differentiation and maturation, a possibility exists that the described mononuclear lymphoid blast-like cells are even less differentiated and immature than committed stem cells for mentioned cell lines.     

沙打旺组织培养中脱分化细胞的超微结构及细胞核的动态变化

对沙打旺的下胚轴、子叶、幼叶组织培养中脱分化细胞进行了超微结构观察,并着重讨论了细胞核的动态变化。脱分化细胞的细胞质中线粒体墙加,嵴明显;多聚核糖体增多;高尔基体增加;质体中积累淀粉。核仁与核内异染色质之间有一个动态过程。此过程暂称“核仁物质喷射“现象。在致有以下：１．核体出现,半嵌在增大的核仁上,核内异染色质沿核膜凝聚;２．异染色质移向核仁,并与核仁接触,核体消失,部分异质进入核仁;３．核仁物质     

Ultrastructure and functions of ring-shaped nucleoli, fibrillar centers and nucleolar vacuoles

Evidence on the ultrastructure of ring-shaped nucleoli in several cell types is reviewed. Detailed attention is paid to these structures in PEK culture cells after the action of actinomycin D, to infiltrating carcinomas of human breast after different degrees of malignization, and to hepatocytes of 11 day old chick embryos. On the basis of our own and literary data, the ring-shaped nucleoli are classified into two groups: 1) those with centrally located fibrillar centres, and 2) those containing large central vacuole. Connections of fibrillar centres with the nucleolus organizer regions in the interphase nucleolus and mitotic chromosomes are considered in detail. Literary and our own data on the genesis and functional activity of ring-shaped nucleoli with the central vacuole, as well as nucleoli with different degrees of vacuolization (vacuolized nucleoli) are specially analyzed. Cellular function, properties and significance of the central vacuole in low differentiated cells are discussed.     

The behavior of nucleolus organizers in structurally changed karyotypes of barley

Two standard karyotype barley lines and 18 lines with karyotypes reconstructed by means of induced reciprocal translocations have been studied with respect to nucleolus formation. The standard karyotype contains two pairs of satellite chromosomes (pairs 6 and 7). Five of the structurally changed karyotypes contain, as a result of reciprocal translocations between the standard satellite chromosomes, only one satellite chromosome pair, each chromosome with two satellites and two nucleolus organizing regions. Under these circumstances, only two of the four NORs are active in nucleolus formation while the other two — probably the transposed ones — remain inactive; hence the maximum number of primary nucleoli per nucleus is two. — When NORs are translocated to chromosomes with no NOR in the standard karyotyp, the normal pattern of nucleolus formation remains unchanged. The same is true after transposition of segments from other chromosomes to the satellites of the standard SAT-chromosome pairs 6 and 7. The results obtained are discussed with respect to effects of translocations on the activity and behaviour of nucleolus organizing regions.