scholarly journals High-Resolution Microscopy to Learn the Nuclear Organization of the Living Yeast Cells

2021 ◽  
Vol 2021 ◽  
pp. 1-7
Author(s):  
Renjie Wang ◽  
Aiwen Huang ◽  
Yan Wang ◽  
Pengxin Mei ◽  
He Zhu ◽  
...  
Keyword(s):  
Cell Cycle ◽  
Carbon Source ◽  
Spatial Organization ◽  
Nuclear Organization ◽  
Nuclear Periphery ◽  
Spherical Geometry ◽  
Yeast Cells ◽  
Poor Region ◽  
High Resolution Microscopy ◽  
Nuclear Geometry

The spatial organization of the nucleus is a key determinant in all genome activities. However, the accurate measurement of the nuclear organization is still technically challenging. Here, the technology NucQuant we created previously was utilized to detect the variation of the nuclear organization, including the heterogeneity of the nuclear geometry, the change of the NPC distribution along different cell cycle stages during interphase, and the organization of the nucleolus. The results confirmed that not only the growth rate and the NPC distribution are influenced by the carbon source; the nuclear shape is also impacted by the carbon source. The nuclei lost their spherical geometry gradually when the cell was cultured from the most to a less favorable carbon source. We also discovered that the nucleolus prefers to locate at the nuclear periphery, which was called the “genes poor region,” especially when the cells entered quiescence. Furthermore, the distribution of the NPC along the different stages during the interphase was analyzed. We proposed that with the growth of the cell, the nucleus would grow from the surface of the NE flanking the nucleolus firstly.

scholarly journals Essential Roles for Caenorhabditis elegans Lamin Gene in Nuclear Organization, Cell Cycle Progression, and Spatial Organization of Nuclear Pore Complexes

2000 ◽  
Vol 11 (11) ◽  
pp. 3937-3947 ◽  
Author(s):  
Jun Liu ◽  
Tom Rolef Ben-Shahar ◽  
Dieter Riemer ◽  
Millet Treinin ◽  
Perah Spann ◽  
...  
Keyword(s):  
Cell Cycle ◽  
Caenorhabditis Elegans ◽  
Cell Cycle Progression ◽  
Spatial Organization ◽  
Nuclear Periphery ◽  
Nuclear Pore ◽  
Nuclear Pore Complexes ◽  
Cycle Progression ◽  
Nuclear Lamins ◽  
Pore Complexes

Caenorhabditis elegans has a single lamin gene, designated lmn-1 (previously termed CeLam-1). Antibodies raised against the lmn-1 product (Ce-lamin) detected a 64-kDa nuclear envelope protein. Ce-lamin was detected in the nuclear periphery of all cells except sperm and was found in the nuclear interior in embryonic cells and in a fraction of adult cells. Reductions in the amount of Ce-lamin protein produce embryonic lethality. Although the majority of affected embryos survive to produce several hundred nuclei, defects can be detected as early as the first nuclear divisions. Abnormalities include rapid changes in nuclear morphology during interphase, loss of chromosomes, unequal separation of chromosomes into daughter nuclei, abnormal condensation of chromatin, an increase in DNA content, and abnormal distribution of nuclear pore complexes (NPCs). Under conditions of incomplete RNA interference, a fraction of embryos escaped embryonic arrest and continue to develop through larval life. These animals exhibit additional phenotypes including sterility and defective segregation of chromosomes in germ cells. Our observations show thatlmn-1 is an essential gene in C. elegans, and that the nuclear lamins are involved in chromatin organization, cell cycle progression, chromosome segregation, and correct spacing of NPCs.

scholarly journals Lamin B1 acetylation slows the G1 to S cell cycle transition through inhibition of DNA repair

2021 ◽  
Author(s):  
Laura A Murray-Nerger ◽  
Joshua L Justice ◽  
Pranav Rekapalli ◽  
Josiah E Hutton ◽  
Ileana M Cristea
Keyword(s):  
Cell Cycle ◽  
Dna Repair ◽  
Posttranslational Modifications ◽  
Cell Cycle Progression ◽  
Nuclear Periphery ◽  
Virus Production ◽  
Nuclear Lamina ◽  
Regulatory Function ◽  
Herpesvirus Type ◽  
Lamin B1

Abstract The integrity and regulation of the nuclear lamina is essential for nuclear organization and chromatin stability, with its dysregulation being linked to laminopathy diseases and cancer. Although numerous posttranslational modifications have been identified on lamins, few have been ascribed a regulatory function. Here, we establish that lamin B1 (LMNB1) acetylation at K134 is a molecular toggle that controls nuclear periphery stability, cell cycle progression, and DNA repair. LMNB1 acetylation prevents lamina disruption during herpesvirus type 1 (HSV-1) infection, thereby inhibiting virus production. We also demonstrate the broad impact of this site on laminar processes in uninfected cells. LMNB1 acetylation negatively regulates canonical nonhomologous end joining by impairing the recruitment of 53BP1 to damaged DNA. This defect causes a delay in DNA damage resolution and a persistent activation of the G1/S checkpoint. Altogether, we reveal LMNB1 acetylation as a mechanism for controlling DNA repair pathway choice and stabilizing the nuclear periphery.

scholarly journals Checkpoint Adaptation Precedes Spontaneous and Damage-Induced Genomic Instability in Yeast

2001 ◽  
Vol 21 (5) ◽  
pp. 1710-1718 ◽  
Author(s):  
David J. Galgoczy ◽  
David P. Toczyski
Keyword(s):  
Cell Cycle ◽  
Dna Damage ◽  
Genomic Instability ◽  
Cell Cycle Progression ◽  
Repair Process ◽  
Yeast Cells ◽  
Chromosome Loss ◽  
Checkpoint Adaptation ◽  
Block Cell Cycle Progression ◽  
Break Induced Replication

ABSTRACT Despite the fact that eukaryotic cells enlist checkpoints to block cell cycle progression when their DNA is damaged, cells still undergo frequent genetic rearrangements, both spontaneously and in response to genotoxic agents. We and others have previously characterized a phenomenon (adaptation) in which yeast cells that are arrested at a DNA damage checkpoint eventually override this arrest and reenter the cell cycle, despite the fact that they have not repaired the DNA damage that elicited the arrest. Here, we use mutants that are defective in checkpoint adaptation to show that adaptation is important for achieving the highest possible viability after exposure to DNA-damaging agents, but it also acts as an entrée into some forms of genomic instability. Specifically, the spontaneous and X-ray-induced frequencies of chromosome loss, translocations, and a repair process called break-induced replication occur at significantly reduced rates in adaptation-defective mutants. This indicates that these events occur after a cell has first arrested at the checkpoint and then adapted to that arrest. Because malignant progression frequently involves loss of genes that function in DNA repair, adaptation may promote tumorigenesis by allowing genomic instability to occur in the absence of repair.

scholarly journals The Small Subunit Processome Is Required for Cell Cycle Progression at G1

2004 ◽  
Vol 15 (11) ◽  
pp. 5038-5046 ◽  
Author(s):  
Kara A. Bernstein ◽  
Susan J. Baserga
Keyword(s):  
Cell Cycle ◽  
Ribosome Biogenesis ◽  
Cell Cycle Progression ◽  
Small Subunit ◽  
Cellular Growth ◽  
Yeast Cells ◽  
G1 Phase ◽  
Relay Cell ◽  
Ssu Processome ◽  
Nucleolar Rna

Without ribosome biogenesis, translation of mRNA into protein ceases and cellular growth stops. We asked whether ribosome biogenesis is cell cycle regulated in the yeasts Saccharomyces cerevisiae and Schizosaccharomyces pombe, and we determined that it is not regulated in the same manner as in metazoan cells. We therefore turned our attention to cellular sensors that relay cell size information via ribosome biogenesis. Our results indicate that the small subunit (SSU) processome, a complex consisting of 40 proteins and the U3 small nucleolar RNA necessary for ribosome biogenesis, is not mitotically regulated. Furthermore, Nan1/Utp17, an SSU processome protein, does not provide a link between ribosome biogenesis and cell growth. However, when individual SSU processome proteins are depleted, cells arrest in the G1 phase of the cell cycle. This arrest was further supported by the lack of staining for proteins expressed in post-G1. Similarly, synchronized cells depleted of SSU processome proteins did not enter G2. This suggests that when ribosomes are no longer made, the cells stall in the G1. Therefore, yeast cells must grow to a critical size, which is dependent upon having a sufficient number of ribosomes during the G1 phase of the cell cycle, before cell division can occur.

scholarly journals CLN3 expression is sufficient to restore G1-to-S-phase progression in Saccharomyces cerevisiae mutants defective in translation initiation factor eIF4E

1999 ◽  
Vol 340 (1) ◽  
pp. 135-141 ◽  
Author(s):  
Parisa DANAIE ◽  
Michael ALTMANN ◽  
Michael N. HALL ◽  
Hans TRACHSEL ◽  
Stephen B. HELLIWELL
Keyword(s):  
Cell Cycle ◽  
S Phase ◽  
Translation Initiation Factor ◽  
Yeast Cells ◽  
Initiation Factor ◽  
G1 Phase ◽  
Mrna Levels ◽  
Wild Type ◽  
Phase Progression ◽  
Type Gene

The essential cap-binding protein (eIF4E) of Saccharomycescerevisiae is encoded by the CDC33 (wild-type) gene, originally isolated as a mutant, cdc33-1, which arrests growth in the G1 phase of the cell cycle at 37 °C. We show that other cdc33 mutants also arrest in G1. One of the first events required for G1-to-S-phase progression is the increased expression of cyclin 3. Constructs carrying the 5ʹ-untranslated region of CLN3 fused to lacZ exhibit weak reporter activity, which is significantly decreased in a cdc33-1 mutant, implying that CLN3 mRNA is an inefficiently translated mRNA that is sensitive to perturbations in the translation machinery. A cdc33-1 strain expressing either stable Cln3p (Cln3-1p) or a hybrid UBI4 5ʹ-CLN3 mRNA, whose translation displays decreased dependence on eIF4E, arrested randomly in the cell cycle. In these cells CLN2 mRNA levels remained high, indicating that Cln3p activity is maintained. Induction of a hybrid UBI4 5ʹ-CLN3 message in a cdc33-1 mutant previously arrested in G1 also caused entry into a new cell cycle. We conclude that eIF4E activity in the G1-phase is critical in allowing sufficient Cln3p activity to enable yeast cells to enter a new cell cycle.

scholarly journals Automatic synchronisation of the cell cycle in budding yeast through closed-loop feedback control

2021 ◽  
Vol 12 (1) ◽  
Author(s):  
Giansimone Perrino ◽  
Sara Napolitano ◽  
Francesca Galdi ◽  
Antonella La Regina ◽  
Davide Fiore ◽  
...  
Keyword(s):  
Cell Cycle ◽  
Autonomous Vehicles ◽  
Genetic System ◽  
Yeast Cells ◽  
Control Engineering ◽  
Loop Feedback ◽  
Experimental Approaches ◽  
Closed Loop Feedback ◽  
Theoretical Foundations

AbstractThe cell cycle is the process by which eukaryotic cells replicate. Yeast cells cycle asynchronously with each cell in the population budding at a different time. Although there are several experimental approaches to synchronise cells, these usually work only in the short-term. Here, we build a cyber-genetic system to achieve long-term synchronisation of the cell population, by interfacing genetically modified yeast cells with a computer by means of microfluidics to dynamically change medium, and a microscope to estimate cell cycle phases of individual cells. The computer implements a controller algorithm to decide when, and for how long, to change the growth medium to synchronise the cell-cycle across the population. Our work builds upon solid theoretical foundations provided by Control Engineering. In addition to providing an avenue for yeast cell cycle synchronisation, our work shows that control engineering can be used to automatically steer complex biological processes towards desired behaviours similarly to what is currently done with robots and autonomous vehicles.

Identification of an upstream activating sequence and an upstream repressible sequence of the pyruvate kinase gene of the yeast Saccharomyces cerevisiae

1989 ◽  
Vol 9 (2) ◽  
pp. 442-451
Author(s):  
M Nishizawa ◽  
R Araki ◽  
Y Teranishi
Keyword(s):  
Saccharomyces Cerevisiae ◽  
Carbon Source ◽  
Pyruvate Kinase ◽  
Transcriptional Activation ◽  
Regulatory Elements ◽  
Noncoding Region ◽  
Yeast Cells ◽  
Kinase Gene ◽  
Yeast Saccharomyces Cerevisiae ◽  
Upstream Activating Sequence

To clarify carbon source-dependent control of the glycolytic pathway in the yeast Saccharomyces cerevisiae, we have initiated a study of transcriptional regulation of the pyruvate kinase gene (PYK). By deletion analysis of the 5'-noncoding region of the PYK gene, we have identified an upstream activating sequence (UASPYK1) located between 634 and 653 nucleotides upstream of the initiating ATG codon. The promoter activity of the PYK 5'-noncoding region was abolished when the sequence containing the UASPYK1 was deleted from the region. Synthetic UASPYK1 (26mer), in either orientation, was able to restore the transcriptional activity of UAS-depleted mutants when placed upstream of the TATA sequence located at -199 (ATG as +1). While the UASPYK1 was required for basal to intermediate levels of transcriptional activation, a sequence between -714 and -811 was found to be necessary for full activation. On the other hand, a sequence between -344 and -468 was found to be responsible for transcriptional repression of the PYK gene when yeast cells were grown on nonfermentable carbon sources. This upstream repressible sequence also repressed transcription, although to a lesser extent, when glucose was present in the medium. The possible mechanism for carbon source-dependent regulation of PYK expression through these cis-acting regulatory elements is discussed.

A murine replication protein accumulates temporarily in the heterochromatic regions of nuclei prior to initiation of DNA replication

1995 ◽  
Vol 108 (3) ◽  
pp. 927-934 ◽  
Author(s):  
M. Starborg ◽  
E. Brundell ◽  
K. Gell ◽  
C. Larsson ◽  
I. White ◽  
...  
Keyword(s):  
Cell Cycle ◽  
Dna Replication ◽  
Mammalian Cells ◽  
Mitotic Cell ◽  
Yeast Cells ◽  
Metaphase Chromosomes ◽  
Licensing Factor ◽  
Mammalian Homologue ◽  
Initiation Of Dna Replication

We have analyzed the expression of the murine P1 gene, the mammalian homologue of the yeast MCM3 protein, during the mitotic cell cycle. The MCM3 protein has previously been shown to be of importance for initiation of DNA replication in Saccharomyces cerevisiae. We found that the murine P1 protein was present in the nuclei of mammalian cells throughout interphase of the cell cycle. This is in contrast to the MCM3 protein, which is located in the nuclei of yeast cells only between the M and the S phase of the cell cycle. Detailed analysis of the intranuclear localization of the P1 protein during the cell cycle revealed that it accumulates transiently in the heterochromatic regions towards the end of G1. The accumulation of the P1 protein in the heterochromatic regions prior to activation of DNA replication suggests that the mammalian P1 protein is also of importance for initiation of DNA replication. The MCM2-3.5 proteins have been suggested to represent yeast equivalents of a hypothetical replication licensing factor initially described in Xenopus. Our data support this model and indicate that the murine P1 protein could function as replication licensing factor. The chromosomal localization of the P1 gene was determined by fluorescence in situ hybridization to region 6p12 in human metaphase chromosomes.

Clonal heterogeneity in the germinal zone of the developing rat telencephalon

Development ◽  
1993 ◽  
Vol 118 (1) ◽  
pp. 175-192 ◽  
Author(s):  
S.E. Acklin ◽  
D. van der Kooy
Keyword(s):  
Cell Cycle ◽  
Cell Lines ◽  
Spatial Organization ◽  
Precursor Cell ◽  
Clonal Heterogeneity ◽  
Double Labeling ◽  
Germinal Zone ◽  
Dividing Cells ◽  
Cellular Phenotypes ◽  
Developing Rat

A double-labeling technique, combining retroviral tagging of individual cell lines (one clone per brain hemisphere) with the simultaneous [3H]thymidine-labeling of dividing cells in S phase, was used to study proliferation characteristics of individual precursor cell lines in the germinal zone of the developing rat forebrain. The cortical germinal zone was found to be segregated into three spatially distinct horizontal populations of precursor cell lineages, which differed in cell cycle kinetics, amount of cell death, and synchronous versus asynchronous mode of proliferation. The striatal germinal zone demonstrated a similar heterogeneity in the cell cycle characteristics of proliferating clones, but did not show nearly as distinct a spatial segregation of these different populations. The results demonstrate the clonal heterogeneity among precursor populations in the telencephalon and the differential spatial organization of the cortical and the striatal germinal zones. This germinal zone heterogeneity may predict some of the differences found among cellular phenotypes in the adult forebrain.

Biochemical and morphological characterization of the nuclear matrix during the synchronous cell cycle of Physarum polycephalum

1993 ◽  
Vol 105 (4) ◽  
pp. 1121-1130 ◽  
Author(s):  
S. Lang ◽  
T. Decristoforo ◽  
W. Waitz ◽  
P. Loidl
Keyword(s):  
Cell Cycle ◽  
Nuclear Matrix ◽  
Physarum Polycephalum ◽  
Nuclear Periphery ◽  
S Phase ◽  
Cycle Phase ◽  
Electron Microscopic ◽  
Nuclear Lamins ◽  
Synchronous Cell ◽  
Matrix Bound

We have investigated biochemical and ultrastructural aspects of the nuclear matrix during the naturally synchronous cell cycle of Physarum polycephalum. The morphology of the in situ nuclear matrix exhibited significant cell cycle changes as revealed by electron microscopic examination, especially during the progression of nuclei through mitosis and S-phase. In mitosis the interchromatin matrix was found to be retracted to the nuclear periphery; during S-phase this interchromatin matrix gradually resembled, concomitant with the reconstruction of a nucleolar remnant structure. During the G2-period no significant changes in matrix morphology were observed. The pattern of nuclear matrix proteins was invariant during the cell cycle; no cycle phase-specific proteins could be detected. In vivo labelling of plasmodia with [35S]methionine/cysteine showed that only a few proteins are synthesized and assembled into nuclear matrix structures in a cell cycle-dependent way; the majority of proteins were synthesized almost continuously. This was also shown for nuclear lamins homologues. In contrast to bulk nuclear histones, those histones that remain tightly bound to the nuclear matrix were synthesized and assembled into nuclear structures in the very first hour of S-phase; assembly was terminated in mid-S-phase, indicating that nuclear matrix-bound chromatin is replicated early in S-phase. Comparison of the acetylation pattern of matrix-bound histone H4 with bulk nuclear H4 revealed a largely elevated acetate content of matrix H4. The percentage of acetylated subspecies was entirely different from that in bulk nuclear H4, indicating that matrix-associated histones represent a subpopulation of nuclear histones with distinct properties, reflecting specific structural requirements of matrix-attached chromatin.

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