scholarly journals Nesprin-2 Interacts with Condensin Component SMC2

2017 ◽  
Vol 2017 ◽  
pp. 1-15 ◽  
Author(s):  
Xin Xing ◽  
Carmen Mroß ◽  
Linlin Hao ◽  
Martina Munck ◽  
Alexandra Herzog ◽  
...  
Keyword(s):  
Cell Cycle ◽  
Nuclear Envelope ◽  
Envelope Proteins ◽  
S Phase ◽  
Nuclear Shape ◽  
The Core ◽  
Chromatin Interactions ◽  
Dividing Cells ◽  
Chromatin Bridges

The nuclear envelope proteins, Nesprins, have been primarily studied during interphase where they function in maintaining nuclear shape, size, and positioning. We analyze here the function of Nesprin-2 in chromatin interactions in interphase and dividing cells. We characterize a region in the rod domain of Nesprin-2 that is predicted as SMC domain (aa 1436–1766). We show that this domain can interact with itself. It furthermore has the capacity to bind to SMC2 and SMC4, the core subunits of condensin. The interaction was observed during all phases of the cell cycle; it was particularly strong during S phase and persisted also during mitosis. Nesprin-2 knockdown did not affect condensin distribution; however we noticed significantly higher numbers of chromatin bridges in Nesprin-2 knockdown cells in anaphase. Thus, Nesprin-2 may have an impact on chromosomes which might be due to its interaction with condensins or to indirect mechanisms provided by its interactions at the nuclear envelope.

scholarly journals Cell cycle–dependent localization of macroH2A in chromatin of the inactive X chromosome

2002 ◽  
Vol 157 (7) ◽  
pp. 1113-1123 ◽  
Author(s):  
Brian P. Chadwick ◽  
Huntington F. Willard
Keyword(s):  
Cell Cycle ◽  
X Chromosome ◽  
Degradation Pathway ◽  
S Phase ◽  
Histone H2a ◽  
The Core ◽  
Inactive X Chromosome ◽  
Inactivation Center ◽  
Chromatin Proteins ◽  
Cycle Dependent

One of several features acquired by chromatin of the inactive X chromosome (Xi) is enrichment for the core histone H2A variant macroH2A within a distinct nuclear structure referred to as a macrochromatin body (MCB). In addition to localizing to the MCB, macroH2A accumulates at a perinuclear structure centered at the centrosome. To better understand the association of macroH2A1 with the centrosome and the formation of an MCB, we investigated the distribution of macroH2A1 throughout the somatic cell cycle. Unlike Xi-specific RNA, which associates with the Xi throughout interphase, the appearance of an MCB is predominantly a feature of S phase. Although the MCB dissipates during late S phase and G2 before reforming in late G1, macroH2A1 remains associated during mitosis with specific regions of the Xi, including at the X inactivation center. This association yields a distinct macroH2A banding pattern that overlaps with the site of histone H3 lysine-4 methylation centered at the DXZ4 locus in Xq24. The centrosomal pool of macroH2A1 accumulates in the presence of an inhibitor of the 20S proteasome. Therefore, targeting of macroH2A1 to the centrosome is likely part of a degradation pathway, a mechanism common to a variety of other chromatin proteins.

Morphology and behaviour of dinoflagellate chromosomes during the cell cycle and mitosis

2000 ◽  
Vol 113 (7) ◽  
pp. 1231-1239 ◽  
Author(s):  
Y. Bhaud ◽  
D. Guillebault ◽  
J. Lennon ◽  
H. Defacque ◽  
M.O. Soyer-Gobillard ◽  
...  
Keyword(s):  
Electron Microscopy ◽  
Cell Cycle ◽  
Confocal Microscopy ◽  
Nuclear Envelope ◽  
Chromosome Segregation ◽  
Morphological Changes ◽  
S Phase ◽  
Chromosome Behaviour ◽  
Double Number ◽  
Do So

The morphology and behaviour of the chromosomes of dinoflagellates during the cell cycle appear to be unique among eukaryotes. We used synchronized and aphidicolin-blocked cultures of the dinoflagellate Crypthecodinium cohnii to describe the successive morphological changes that chromosomes undergo during the cell cycle. The chromosomes in early G(1) phase appeared to be loosely condensed with numerous structures protruding toward the nucleoplasm. They condensed in late G(1), before unwinding in S phase. The chromosomes in cells in G(2) phase were tightly condensed and had a double number of arches, as visualised by electron microscopy. During prophase, chromosomes elongated and split longitudinally, into characteristic V or Y shapes. We also used confocal microscopy to show a metaphase-like alignment of the chromosomes, which has never been described in dinoflagellates. The metaphase-like nucleus appeared flattened and enlarged, and continued to do so into anaphase. Chromosome segregation occurred via binding to the nuclear envelope surrounding the cytoplasmic channels and microtubule bundles. Our findings are summarized in a model of chromosome behaviour during the cell cycle.

Transcription of the histone H5 gene is not S-phase regulated

1986 ◽  
Vol 6 (2) ◽  
pp. 601-606
Author(s):  
S Dalton ◽  
J R Coleman ◽  
J R Wells
Keyword(s):  
Cell Cycle ◽  
Steady State ◽  
Northern Blotting ◽  
S Phase ◽  
Erythroid Cells ◽  
Dividing Cells ◽  
Steady State Levels ◽  
Avian Erythroblastosis Virus ◽  
Histone H5

Levels of the tissue-specific linker histone H5 are elevated in mature erythroid cells as compared with levels in dividing cells of the same lineage. We examined levels of H5 mRNA in relation to the cell cycle in early erythroid cells transformed by avian erythroblastosis virus to determine whether the gene for this unusual histone is S-phase regulated. Northern blotting analyses revealed that during the cell cycle steady-state levels of H5 mRNA remained relatively constant in contrast to levels of the major core and H1 mRNAs which increased approximately 15-fold during S phase. In vitro pulse-labeling experiments involving nuclei isolated from synchronized cells at various stages of the cell cycle revealed that transcription of the H5 gene was not initiated at any particular stage of the cell cycle but was constitutive. In contrast, transcription of the H2A gene(s) initiated in early S phase, was present throughout the DNA replicative phase, and was essentially absent in G1 and G2 phases.

Excision and replication of extrachromosomal DNA of pea (Pisum sativum)

1983 ◽  
Vol 3 (2) ◽  
pp. 172-181
Author(s):  
J Van't Hof ◽  
C A Bjerknes ◽  
N C Delihas
Keyword(s):  
Cell Cycle ◽  
Pisum Sativum ◽  
S Phase ◽  
Velocity Sedimentation ◽  
Extrachromosomal Dna ◽  
Chromosomal Dna ◽  
Root Tips ◽  
Dividing Cells ◽  
G2 Phase ◽  
Pea Roots

Experiments with cultured pea roots were conducted to determine (i) whether extrachromosomal DNA was produced by cells in the late S phase or in the G2 phase of the cell cycle, (ii) whether the maturation of nascent DNA replicated by these cells achieved chromosomal size, (iii) when extrachromosomal DNA was removed from the chromosomal duplex, and (iv) the replication of nascent chains by the extrachromosomal DNA after its release from the chromosomal duplex. Autoradiography and cytophotometry of cells of carbohydrate-starved root tips revealed that extrachromosomal DNA was produced by a small fraction of cells accumulated in the late S phase after they had replicated about 80% of their DNA. Velocity sedimentation of nascent chromosomal DNA in alkaline sucrose gradients indicated that the DNA of cells in the late S phase failed to achieve chromosomal size. After reaching sizes of 70 X 10(6) to 140 X 10(6) daltons, some of the nascent chromosomal molecules were broken, presumably releasing extrachromosomal DNA several hours later. Sedimentation of selectively extracted extrachromosomal DNA either from dividing cells or from those in the late S phase showed that it replicated two nascent chains, one of 3 X 10(6) daltons and another of 7 X 10(6) daltons. Larger molecules of extrachromosomal DNA were detectable after cells were labeled for 24 h. These two observations were compatible with the idea that the extrachromosomal DNA was first replicated as an integral part of the chromosomal duplex, was cut from the duplex, and then, once free of the chromosome, replicated two smaller chains of 3 X 10(6) and 7 X 10(6) daltons.

scholarly journals Fate of the M-phase-assembled centrioles during the cell cycle in the TP53;PCNT;CEP215-deleted cells

2020 ◽  
Author(s):  
Gee In Jung ◽  
Kunsoo Rhee
Keyword(s):  
Cell Cycle ◽  
Cancer Cells ◽  
Cell Lines ◽  
S Phase ◽  
M Phase ◽  
Dividing Cells ◽  
Centriole Assembly

ABSTRACTCancer cells frequently include supernumerary centrioles. Here, we generated TP53;PCNT;CEP215 triple knockout cell lines and observed precocious separation and amplification of the centrioles at M phase. Many of the triple KO cells maintained supernumerary centrioles throughout the cell cycle. The M-phase-assembled centrioles lack an ability to function as templates for centriole assembly during S phase. They also lack an ability to organize microtubules in interphase. However, we found that a fraction of them acquired an ability to organize microtubules during M phase. Our works provide an example how supernumerary centrioles behave in dividing cells.

Stage specificity in the mesenchyme requirement of rodent lung epithelium in vitro: a matter of growth control?

Development ◽  
1983 ◽  
Vol 74 (1) ◽  
pp. 183-206
Author(s):  
Kirstie A. Lawson
Keyword(s):  
Cell Cycle ◽  
Bronchial Epithelium ◽  
Branching Morphogenesis ◽  
S Phase ◽  
Growth Fraction ◽  
Early Event ◽  
Rat Lung ◽  
Lung Epithelium ◽  
Dividing Cells

Epithelia from lung rudiments in which secondary bronchial buds are already established (14th and 13th gestational day for rat and mouse respectively) are able to undergo branching morphogenesis and cytodifferentiation in submandibular mesenchyme in vitro, whereas lung epithelium from one day younger foetuses rarely gives a morphogenetic response to submandibular mesenchyme and usually differentiates into primary (non-budding) bronchial epithelium. The failure of 13-day rat lung epithelium to respond to submandibular mesenchyme can be prevented by peeling off the submandibular mesenchyme from the lung epithelium after 2½ days culture and replacing the same mesenchyme, or renewing it with fresh salivary mesenchyme ex vivo. Changes in the epithelial contour are visible by 10 h and buds form within 24 h; this is followed by branching morphogenesis in more than 66% of the samples. The number of cells in S-phase in the epithelium is doubled within 3 to 5 h after the operation and the number of mitotic cells (colchicine block) is increased during an 11 to 19 h period after the operation. Substituting stomach mesenchyme for submandibular mesenchyme after the operation failed to elicit morphogenesis or an increase in the number of S-phase cells in the epithelium. The proportion of epithelial cells in S-phase in unoperated recombinates does not differ from the proportion in the primary bronchial epithelium (non-budding) of homotypic lung recombinates, whereas the proportion of S-phase cells in operated recombinates approaches that found in the buds of homotypic lung recombinates. The distribution of S-phase cells in visibly responding recombinates 15 to 17 h after operation shows the same heterogeneity as in homotypic lung recombinates, newly formed buds having twice as many cells labelled with [3H]thymidine as the non-budding area. Cell cycle parameters of intact rat lung growing in vitro were estimated using the labelled mitoses method. Primary bronchial epithelium and bronchial buds both had a total cell cycle time of about 13 h and an S-phase of about 10 h. The growth fraction was 0·54 in the primary bronchus and 0·95 in the buds. It is suggested that, also in the recombinates, differences in the proportion of S-phase cells at any one time in morphogenetically active and inactive areas of the epithelium are due to differences in the growth fraction. It is concluded that an early event in the morphogenetic response of lung epithelium to submandibular mesenchyme after removing and restoring the mesenchyme is an increase in the size of the population of dividing cells and it is suggested that a high proportion of dividing cells in an epithelial population is a prerequisite for further interaction of epithelium and mesenchyme leading to branching morphogenesis.

scholarly journals Excision and replication of extrachromosomal DNA of pea (Pisum sativum).

1983 ◽  
Vol 3 (2) ◽  
pp. 172-181 ◽  
Author(s):  
J Van't Hof ◽  
C A Bjerknes ◽  
N C Delihas
Keyword(s):  
Cell Cycle ◽  
Pisum Sativum ◽  
S Phase ◽  
Velocity Sedimentation ◽  
Extrachromosomal Dna ◽  
Chromosomal Dna ◽  
Root Tips ◽  
Dividing Cells ◽  
G2 Phase ◽  
Pea Roots

Experiments with cultured pea roots were conducted to determine (i) whether extrachromosomal DNA was produced by cells in the late S phase or in the G2 phase of the cell cycle, (ii) whether the maturation of nascent DNA replicated by these cells achieved chromosomal size, (iii) when extrachromosomal DNA was removed from the chromosomal duplex, and (iv) the replication of nascent chains by the extrachromosomal DNA after its release from the chromosomal duplex. Autoradiography and cytophotometry of cells of carbohydrate-starved root tips revealed that extrachromosomal DNA was produced by a small fraction of cells accumulated in the late S phase after they had replicated about 80% of their DNA. Velocity sedimentation of nascent chromosomal DNA in alkaline sucrose gradients indicated that the DNA of cells in the late S phase failed to achieve chromosomal size. After reaching sizes of 70 X 10(6) to 140 X 10(6) daltons, some of the nascent chromosomal molecules were broken, presumably releasing extrachromosomal DNA several hours later. Sedimentation of selectively extracted extrachromosomal DNA either from dividing cells or from those in the late S phase showed that it replicated two nascent chains, one of 3 X 10(6) daltons and another of 7 X 10(6) daltons. Larger molecules of extrachromosomal DNA were detectable after cells were labeled for 24 h. These two observations were compatible with the idea that the extrachromosomal DNA was first replicated as an integral part of the chromosomal duplex, was cut from the duplex, and then, once free of the chromosome, replicated two smaller chains of 3 X 10(6) and 7 X 10(6) daltons.

scholarly journals Centripetal nuclear shape fluctuations associate with chromatin condensation towards mitosis

2021 ◽  
Author(s):  
Viola Introini ◽  
Gururaj Rao Kidiyoor ◽  
Giancarlo Porcella ◽  
Marco Foiani ◽  
Pietro Cicuta ◽  
...  
Keyword(s):  
Cell Cycle ◽  
Nuclear Envelope ◽  
Cell Cycle Progression ◽  
Chromatin Condensation ◽  
Nuclear Shape ◽  
Cycle Progression ◽  
Cellular Processes ◽  
Nuclear Envelope Breakdown ◽  
Nuclear Mechanics ◽  
Nuclear Processes

The cell nucleus plays a central role in several key cellular processes, including chromosome organisation, replication and transcription. Recent work intriguingly suggests an association between nuclear mechanics and cell-cycle progression, but many aspects of this connection remain unexplored. Here, by monitoring nuclear shape fluctuations at different cell cycle stages, we uncover increasing inward fluctuations in late G2 and early mitosis, which are initially transient, but develop into instabilities that culminate into nuclear-envelope breakdown in mitosis. Perturbation experiments and correlation analysis reveal an association of these processes with chromatin condensation. We propose that the contrasting forces between an extensile stress and centripetal pulling from chromatin condensation could link mechanically chromosome condensation and nuclear-envelope breakdown, the two main nuclear processes during mitosis.

Observations on the Origin and Significance of the Nuclear Envelope-Limited Monolayers of Chromatin Unit Threads associated with the Cell Nucleus

1973 ◽  
Vol 13 (1) ◽  
pp. 139-171
Author(s):  
M. E. HAYNES ◽  
H. G. DAVIES
Keyword(s):  
Cell Cycle ◽  
Nuclear Envelope ◽  
Cultured Cells ◽  
Cell Types ◽  
S Phase ◽  
Marked Diminution ◽  
Circular Configuration ◽  
Chromatin Structural ◽  
Type C ◽  
G2 Phase

Monolayers of chromatin structural units about 33.0 nm in width enclosed on both sides by extensions of the nuclear envelope, called sheets, and located either in the cytoplasm (c. .n. .c type), or within the nucleus (c. .n. .n type), are common in cultured cells of Burkitt's lymphoma. The sheets are absent from mitotic cells except at telophase where, unlike interphase, type c. .n. .n is more numerous than c. .n. .c. The degree of nuclear asymmetry is defined in terms of the increase in enclosing membranes over that required to enclose the same area in a circular configuration. The percentage number (Ps) of cells with nucleus-associated sheets averaged over all stages in the cell cycle, increases with cell viability and with nuclear asymmetry. However, during the cycle there is a marked diminution in Ps during the S-phase of DNA synthesis when nuclear asymmetry itself does not change. Hence, it is suggested, and data on other cell types support the hypothesis, that nuclear asymmetry is a necessary but not sufficient factor in causing sheets to form. Microtubules are present within the cytoplasm and their morphological arrangement suggests a role in determining nuclear asymmetry. Treatment with a microtubule depolymerizing agent, colcemid, does not alter either the existing nuclear asymmetry or Ps, but when cells are treated early in S-phase the reappearance of sheets in the G2 phase of the cell cycle is considerably delayed. The reappearance takes place when the microtubules are still depolymerized. It is suggested that synthesis of membrane in excess of what is needed to enclose a sphere results in nuclear asymmetry and associated membrane-enclosed monolayers, the resulting nuclear conformation, including the distribution of membrane between types c. .n. .n and c. .n. .c, depending on what is energetically favoured. No biochemical function has yet been assigned to sheets.

scholarly journals The permeability of the nuclear envelope in dividing and nondividing cell cultures.

1990 ◽  
Vol 111 (1) ◽  
pp. 1-8 ◽  
Author(s):  
C M Feldherr ◽  
D Akin
Keyword(s):  
Cell Cycle ◽  
Nuclear Envelope ◽  
Hela Cells ◽  
Pore Formation ◽  
Maximum Diameter ◽  
Transport Channel ◽  
Permeability Characteristics ◽  
Dividing Cells ◽  
Pore Complexes ◽  
Nondividing Cell

The objective of this study was to determine whether the permeability characteristics of the nuclear envelope vary during different phases of cellular activity. Both passive diffusion and signal-mediated transport across the envelope were analyzed during the HeLa cell cycle, and also in dividing, confluent (growth-arrested), and differentiated 3T3-L1 cultures. Colloidal gold stabilized with BSA was used to study diffusion, whereas transport was investigated using gold particles coated with nucleoplasmin, a karyophilic Xenopus oocyte protein. The gold tracers were microinjected into the cytoplasm, and subsequently localized within the cells by electron microscopy. The rates of diffusion in HeLa cells were greatest during the first and fifth hours after the onset of anaphase. These results correlate directly with the known rates of pore formation, suggesting that pores are more permeable during or just after reformation. Signal-mediated transport in HeLa cells occurs through channels that are located within the pore complexes and have functional diameters up to 230-250 A. Unlike diffusion, no significant differences in transport were observed during different phases of the cell cycle. A comparison of dividing and confluent 3T3-L1 cultures revealed highly significant differences in the transport of nucleoplasmin-gold across the envelope. The nuclei of dividing cells not only incorporated larger particles (230 A versus 190 A in diameter, including the protein coat), but the relative uptake of the tracer was about seven times greater than that in growth-arrested cells. Differentiation of confluent cells to adipocytes was accompanied by an increase in the maximum diameter of the transport channel to approximately 230 A.

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