Your search keyword '"G2 Phase physiology"' showing total 24 results

1. The dynein adaptor Hook2 plays essential roles in mitotic progression and cytokinesis.

Author

Dwivedi D, Kumari A, Rathi S, Mylavarapu SVS, and Sharma M

Subjects

Animals, Centromere genetics, Centromere metabolism, Dyneins genetics, Dyneins metabolism, Microtubule-Associated Proteins genetics, Nuclear Envelope genetics, Spindle Apparatus genetics, Spindle Apparatus metabolism, Zebrafish genetics, Zebrafish Proteins genetics, Cytokinesis physiology, G2 Phase physiology, Microtubule-Associated Proteins metabolism, Nuclear Envelope metabolism, Zebrafish metabolism, Zebrafish Proteins metabolism

Abstract

Hook proteins are evolutionarily conserved dynein adaptors that promote assembly of highly processive dynein-dynactin motor complexes. Mammals express three Hook paralogs, namely Hook1, Hook2, and Hook3, that have distinct subcellular localizations and expectedly, distinct cellular functions. Here we demonstrate that Hook2 binds to and promotes dynein-dynactin assembly specifically during mitosis. During the late G2 phase, Hook2 mediates dynein-dynactin localization at the nuclear envelope (NE), which is required for centrosome anchoring to the NE. Independent of its binding to dynein, Hook2 regulates microtubule nucleation at the centrosome; accordingly, Hook2-depleted cells have reduced astral microtubules and spindle positioning defects. Besides the centrosome, Hook2 localizes to and recruits dynactin and dynein to the central spindle. Dynactin-dependent targeting of centralspindlin complex to the midzone is abrogated upon Hook2 depletion; accordingly, Hook2 depletion results in cytokinesis failure. We find that the zebrafish Hook2 homologue promotes dynein-dynactin association and was essential for zebrafish early development. Together, these results suggest that Hook2 mediates assembly of the dynein-dynactin complex and regulates mitotic progression and cytokinesis., (© 2019 Dwivedi et al.)

Published

2019

2. Cdk1 phosphorylation of the dynein adapter Nde1 controls cargo binding from G2 to anaphase.

Author

Wynne CL and Vallee RB

Subjects

Anaphase physiology, Carrier Proteins metabolism, Cell Line, Tumor, G2 Phase physiology, HeLa Cells, Humans, Microtubule-Associated Proteins genetics, Mitosis genetics, Phosphorylation, Protein Binding, RNA Interference, RNA, Small Interfering genetics, CDC2 Protein Kinase metabolism, Chromosomal Proteins, Non-Histone metabolism, Cytoplasmic Dyneins metabolism, Kinetochores metabolism, Microfilament Proteins metabolism, Microtubule-Associated Proteins metabolism, Nuclear Envelope metabolism

Abstract

Cytoplasmic dynein is involved in diverse cell cycle-dependent functions regulated by several accessory factors, including Nde1 and Ndel1. Little is known about the role of these proteins in dynein cargo binding, and less is known about their cell cycle--dependent dynein regulation. Using Nde1 RNAi, mutant cDNAs, and a phosphorylation site-specific antibody, we found a specific association of phospho-Nde1 with the late G2-M nuclear envelope and prophase to anaphase kinetochores, comparable to the pattern for the Nde1 interactor CENP-F. Phosphomutant-Nde1 associated only with prometaphase kinetochores and showed weaker CENP-F binding in in vitro assays. Nde1 RNAi caused severe delays in mitotic progression, which were substantially rescued by both phosphomimetic and phosphomutant Nde1. Expression of a dynein-binding-deficient Nde1 mutant reduced kinetochore dynein by half, indicating a major role for Nde1 in kinetochore dynein recruitment. These results establish CENP-F as the first well-characterized Nde1 cargo protein, and reveal phosphorylation control of Nde1 cargo binding throughout a substantial fraction of the cell cycle., (© 2018 Wynne and Vallee.)

Published

2018

3. ATAD5 regulates the lifespan of DNA replication factories by modulating PCNA level on the chromatin.

Author

Lee KY, Fu H, Aladjem MI, and Myung K

Subjects

ATPases Associated with Diverse Cellular Activities, Adenosine Triphosphatases genetics, Chromatin genetics, DNA-Binding Proteins genetics, HeLa Cells, Humans, Proliferating Cell Nuclear Antigen genetics, Protein Structure, Tertiary, Adenosine Triphosphatases metabolism, Chromatin metabolism, DNA Replication physiology, DNA-Binding Proteins metabolism, G2 Phase physiology, Proliferating Cell Nuclear Antigen metabolism, S Phase physiology

Abstract

Temporal and spatial regulation of the replication factory is important for efficient DNA replication. However, the underlying molecular mechanisms are not well understood. Here, we report that ATAD5 regulates the lifespan of replication factories. Reduced expression of ATAD5 extended the lifespan of replication factories by retaining proliferating cell nuclear antigen (PCNA) and other replisome proteins on the chromatin during and even after DNA synthesis. This led to an increase of inactive replication factories with an accumulation of replisome proteins. Consequently, the overall replication rate was decreased, which resulted in the delay of S-phase progression. Prevalent detection of PCNA foci in G2 phase cells after ATAD5 depletion suggests that defects in the disassembly of replication factories persist after S phase is complete. ATAD5-mediated regulation of the replication factory and PCNA required an intact ATAD5 ATPase domain. Taken together, our data imply that ATAD5 regulates the cycle of DNA replication factories, probably through its PCNA-unloading activity.

Published

2013

4. Different cyclin types collaborate to reverse the S-phase checkpoint and permit prompt mitosis.

Author

Yuan K, Farrell JA, and O'Farrell PH

Subjects

Animals, Cell Cycle Checkpoints genetics, Cyclins genetics, Cyclins metabolism, DNA Replication, Drosophila melanogaster, Embryo, Nonmammalian, G2 Phase genetics, G2 Phase physiology, Mitosis genetics, S Phase genetics, Cell Cycle Checkpoints physiology, Cyclins physiology, Mitosis physiology, S Phase physiology

Abstract

Precise timing coordinates cell proliferation with embryonic morphogenesis. As Drosophila melanogaster embryos approach cell cycle 14 and the midblastula transition, rapid embryonic cell cycles slow because S phase lengthens, which delays mitosis via the S-phase checkpoint. We probed the contributions of each of the three mitotic cyclins to this timing of interphase duration. Each pairwise RNA interference knockdown of two cyclins lengthened interphase 13 by introducing a G2 phase of a distinct duration. In contrast, pairwise cyclin knockdowns failed to introduce a G2 in embryos that lacked an S-phase checkpoint. Thus, the single remaining cyclin is sufficient to induce early mitotic entry, but reversal of the S-phase checkpoint is compromised by pairwise cyclin knockdown. Manipulating cyclin levels revealed that the diversity of cyclin types rather than cyclin level influenced checkpoint reversal. We conclude that different cyclin types have distinct abilities to reverse the checkpoint but that they collaborate to do so rapidly.

Published

2012

5. Erk1/2 MAP kinases are required for epidermal G2/M progression.

Author

Dumesic PA, Scholl FA, Barragan DI, and Khavari PA

Subjects

Animals, CDC2 Protein Kinase genetics, Cyclin B genetics, Cyclin B1, Enzyme Activation, Epidermal Cells, Epidermis physiology, Epithelial Cells cytology, Epithelial Cells enzymology, Fibroblasts cytology, Fibroblasts enzymology, Fibroblasts physiology, Gene Expression Regulation, Humans, Keratinocytes cytology, Keratinocytes physiology, Keratinocytes transplantation, Mice, Mice, SCID, Neoplasms enzymology, Neoplasms pathology, RNA, Small Interfering genetics, Transplantation, Heterologous, Cell Cycle physiology, Cell Division physiology, G2 Phase physiology, Mitogen-Activated Protein Kinase 1 metabolism, Mitogen-Activated Protein Kinase 3 metabolism

Abstract

Erk1/2 mitogen-activated protein kinases (MAPKs) are often hyperactivated in human cancers, where they affect multiple processes, including proliferation. However, the effects of Erk1/2 loss in normal epithelial tissue, the setting of most extracellular signal-regulated kinase (Erk)-associated neoplasms, are unknown. In epidermis, loss of Erk1 or Erk2 individually has no effect, whereas simultaneous Erk1/2 depletion inhibits cell division, demonstrating that these MAPKs are necessary for normal tissue self-renewal. Growth inhibition caused by Erk1/2 loss is rescued by reintroducing Erk2, but not by activating Erk effectors that promote G1 cell cycle progression. Unlike fibroblasts, in which Erk1/2 loss decreases cyclin D1 expression and induces G1/S arrest, Erk1/2 loss in epithelial cells reduces cyclin B1 and c-Fos expression and induces G2/M arrest while disrupting a gene regulatory network centered on cyclin B1-Cdc2. Thus, the cell cycle stages at which Erk1/2 activity is required vary by cell type, with Erk1/2 functioning in epithelial cells to enable progression through G2/M.

Published

2009

6. Rac1 accumulates in the nucleus during the G2 phase of the cell cycle and promotes cell division.

Author

Michaelson D, Abidi W, Guardavaccaro D, Zhou M, Ahearn I, Pagano M, and Philips MR

Subjects

Amino Acid Sequence, Animals, Cell Line, Humans, Molecular Sequence Data, Nuclear Localization Signals genetics, Nuclear Localization Signals metabolism, Prenylation, Proline metabolism, Protein Prenylation, Recombinant Fusion Proteins genetics, Recombinant Fusion Proteins metabolism, Sequence Alignment, rac1 GTP-Binding Protein genetics, Cell Division physiology, Cell Nucleus metabolism, G2 Phase physiology, rac1 GTP-Binding Protein metabolism

Abstract

Rac1 regulates a wide variety of cellular processes. The polybasic region of the Rac1 C terminus functions both as a plasma membrane-targeting motif and a nuclear localization sequence (NLS). We show that a triproline N-terminal to the polybasic region contributes to the NLS, which is cryptic in the sense that it is strongly inhibited by geranylgeranylation of the adjacent cysteine. Subcellular fractionation demonstrated endogenous Rac1 in the nucleus and Triton X-114 partition revealed that this pool is prenylated. Cell cycle-blocking agents, synchronization of cells stably expressing low levels of GFP-Rac1, and time-lapse microscopy of asynchronous cells revealed Rac1 accumulation in the nucleus in late G2 and exclusion in early G1. Although constitutively active Rac1 restricted to the cytoplasm inhibited cell division, activated Rac1 expressed constitutively in the nucleus increased the mitotic rate. These results show that Rac1 cycles in and out of the nucleus during the cell cycle and thereby plays a role in promoting cell division.

Published

2008

7. Chromosome breakage after G2 checkpoint release.

Author

Deckbar D, Birraux J, Krempler A, Tchouandong L, Beucher A, Walker S, Stiff T, Jeggo P, and Löbrich M

Subjects

Ataxia Telangiectasia Mutated Proteins, Cell Cycle Proteins genetics, Cell Cycle Proteins physiology, Cell Line, DNA-Binding Proteins genetics, DNA-Binding Proteins physiology, Endonucleases, Humans, Nuclear Proteins physiology, Protein Serine-Threonine Kinases genetics, Protein Serine-Threonine Kinases physiology, Tumor Suppressor Proteins genetics, Tumor Suppressor Proteins physiology, Chromosome Breakage, DNA Breaks, Double-Stranded, DNA Repair, G2 Phase physiology

Abstract

DNA double-strand break (DSB) repair and checkpoint control represent distinct mechanisms to reduce chromosomal instability. Ataxia telangiectasia (A-T) cells have checkpoint arrest and DSB repair defects. We examine the efficiency and interplay of ATM's G2 checkpoint and repair functions. Artemis cells manifest a repair defect identical and epistatic to A-T but show proficient checkpoint responses. Only a few G2 cells enter mitosis within 4 h after irradiation with 1 Gy but manifest multiple chromosome breaks. Most checkpoint-proficient cells arrest at the G2/M checkpoint, with the length of arrest being dependent on the repair capacity. Strikingly, cells released from checkpoint arrest display one to two chromosome breaks. This represents a major contribution to chromosome breakage. The presence of chromosome breaks in cells released from checkpoint arrest suggests that release occurs before the completion of DSB repair. Strikingly, we show that checkpoint release occurs at a point when approximately three to four premature chromosome condensation breaks and approximately 20 gammaH2AX foci remain.

Published

2007

8. ERK1c regulates Golgi fragmentation during mitosis.

Author

Shaul YD and Seger R

Subjects

Alternative Splicing physiology, Biomarkers metabolism, Down-Regulation physiology, G2 Phase physiology, Golgi Apparatus ultrastructure, HeLa Cells, Humans, Isoenzymes physiology, MAP Kinase Kinase Kinases metabolism, MAP Kinase Signaling System physiology, RNA Interference physiology, Cell Cycle Proteins metabolism, Golgi Apparatus metabolism, Mitogen-Activated Protein Kinase 3 metabolism, Mitosis physiology

Abstract

Extracellular signal-regulated kinase 1c (ERK1c) is an alternatively spliced form of ERK1 that is regulated differently than other ERK isoforms. We studied the Golgi functions of ERK1c and found that it plays a role in MEK-induced mitotic Golgi fragmentation. Thus, in late G2 and mitosis of synchronized cells, the expression and activity of ERK1c was increased and it colocalized mainly with Golgi markers. Small interfering RNA of ERK1c significantly attenuated, whereas ERK1c overexpression facilitated, mitotic Golgi fragmentation. These effects were also reflected in mitotic progression, indicating that ERK1c is involved in cell cycle regulation via modulation of Golgi fragmentation. Although ERK1 was activated in mitosis as well, it could not replace ERK1c in regulating Golgi fragmentation. Therefore, MEKs regulate mitosis via all three ERK isoforms, where ERK1c acts specifically in the Golgi, whereas ERK1 and 2 regulate other mitosis-related processes. Thus, ERK1c extends the specificity of the Ras-MEK cascade by activating ERK1/2-independent processes.

Published

2006

9. Temporal separation of replication and recombination requires the intra-S checkpoint.

Author

Meister P, Taddei A, Vernis L, Poidevin M, Gasser SM, and Baldacci G

Subjects

Cell Survival drug effects, Cell Survival genetics, Cell Survival physiology, DNA Damage drug effects, DNA Damage genetics, DNA Damage physiology, DNA Repair genetics, DNA Repair physiology, DNA Replication drug effects, DNA-Binding Proteins genetics, Electrophoresis, Gel, Two-Dimensional, G2 Phase drug effects, G2 Phase genetics, G2 Phase physiology, Genomic Instability drug effects, Genomic Instability genetics, Genomic Instability physiology, Hydroxyurea toxicity, Recombination, Genetic drug effects, S Phase drug effects, S Phase genetics, Schizosaccharomyces drug effects, Schizosaccharomyces genetics, Schizosaccharomyces physiology, Schizosaccharomyces pombe Proteins genetics, DNA Replication genetics, DNA-Binding Proteins metabolism, Recombination, Genetic genetics, S Phase physiology, Schizosaccharomyces pombe Proteins metabolism

Abstract

In response to DNA damage and replication pausing, eukaryotes activate checkpoint pathways that prevent genomic instability by coordinating cell cycle progression with DNA repair. The intra-S-phase checkpoint has been proposed to protect stalled replication forks from pathological rearrangements that could result from unscheduled recombination. On the other hand, recombination may be needed to cope with either stalled forks or double-strand breaks resulting from hydroxyurea treatment. We have exploited fission yeast to elucidate the relationship between replication fork stalling, loading of replication and recombination proteins onto DNA, and the intra-S checkpoint. Here, we show that a functional recombination machinery is not essential for recovery from replication fork arrest and instead can lead to nonfunctional fork structures. We find that Rad22-containing foci are rare in S-phase cells, but peak in G2 phase cells after a perturbed S phase. Importantly, we find that the intra-S checkpoint is necessary to avoid aberrant strand-exchange events during a hydroxyurea block.

Published

2005

10. Myosin-II reorganization during mitosis is controlled temporally by its dephosphorylation and spatially by Mid1 in fission yeast.

Author

Motegi F, Mishra M, Balasubramanian MK, and Mabuchi I

Subjects

Actin Cytoskeleton metabolism, Actins biosynthesis, Amino Acid Sequence physiology, G2 Phase physiology, Membrane Glycoproteins genetics, Mutation genetics, Myosin Heavy Chains genetics, Myosin Heavy Chains metabolism, Myosin Type II genetics, Phosphorylation, Protein Structure, Tertiary physiology, Schizosaccharomyces genetics, Schizosaccharomyces ultrastructure, Schizosaccharomyces pombe Proteins genetics, Membrane Glycoproteins metabolism, Mitosis physiology, Myosin Type II metabolism, Schizosaccharomyces metabolism, Schizosaccharomyces pombe Proteins metabolism

Abstract

Cytokinesis in many eukaryotes requires an actomyosin contractile ring. Here, we show that in fission yeast the myosin-II heavy chain Myo2 initially accumulates at the division site via its COOH-terminal 134 amino acids independently of F-actin. The COOH-terminal region can access to the division site at early G2, whereas intact Myo2 does so at early mitosis. Ser1444 in the Myo2 COOH-terminal region is a phosphorylation site that is dephosphorylated during early mitosis. Myo2 S1444A prematurely accumulates at the future division site and promotes formation of an F-actin ring even during interphase. The accumulation of Myo2 requires the anillin homologue Mid1 that functions in proper ring placement. Myo2 interacts with Mid1 in cell lysates, and this interaction is inhibited by an S1444D mutation in Myo2. Our results suggest that dephosphorylation of Myo2 liberates the COOH-terminal region from an intramolecular inhibition. Subsequently, dephosphorylated Myo2 is anchored by Mid1 at the medial cortex and promotes the ring assembly in cooperation with F-actin., (Copyright the Rockefeller University Press)

Published

2004

11. Distinct cell cycle-dependent roles for dynactin and dynein at centrosomes.

Author

Quintyne NJ and Schroer TA

Subjects

Animals, COS Cells, Dynactin Complex, Dyneins genetics, G1 Phase physiology, G2 Phase physiology, Gene Expression physiology, Interphase physiology, Microtubule-Associated Proteins genetics, Mitosis physiology, Protein Binding physiology, S Phase physiology, Cell Cycle physiology, Centrioles metabolism, Dyneins metabolism, Microtubule-Associated Proteins metabolism

Abstract

Centrosomal dynactin is required for normal microtubule anchoring and/or focusing independently of dynein. Dynactin is present at centrosomes throughout interphase, but dynein accumulates only during S and G2 phases. Blocking dynein-based motility prevents recruitment of dynactin and dynein to centrosomes and destabilizes both centrosomes and the microtubule array, interfering with cell cycle progression during mitosis. Destabilization of the centrosomal pool of dynactin does not inhibit dynein-based motility or dynein recruitment to centrosomes, but instead causes abnormal G1 centriole separation and delayed entry into S phase. The correct balance of centrosome-associated dynactin subunits is apparently important for satisfaction of the cell cycle mechanism that monitors centrosome integrity before centrosome duplication and ultimately governs the G1 to S transition. Our results suggest that, in addition to functioning as a microtubule anchor, dynactin contributes to the recruitment of important cell cycle regulators to centrosomes.

Published

2002

12. Reorganization of the microtubule array in prophase/prometaphase requires cytoplasmic dynein-dependent microtubule transport.

Author

Rusan NM, Tulu US, Fagerstrom C, and Wadsworth P

Subjects

Animals, Biological Transport, Cell Line, Cells, Cultured, Cytoplasm metabolism, Cytoskeleton metabolism, Dynactin Complex, Enzyme Inhibitors pharmacology, G2 Phase physiology, Green Fluorescent Proteins, Kinesins antagonists & inhibitors, Kinesins metabolism, Luminescent Proteins metabolism, Meiosis, Microtubule-Associated Proteins metabolism, Myosin Type II antagonists & inhibitors, Myosin Type II metabolism, Pyrimidines pharmacology, Spindle Apparatus metabolism, Thiones pharmacology, Tubulin metabolism, Dyneins physiology, Microtubules metabolism, Microtubules ultrastructure, Prophase, Xenopus Proteins

Abstract

When mammalian somatic cells enter mitosis, a fundamental reorganization of the Mt cytoskeleton occurs that is characterized by the loss of the extensive interphase Mt array and the formation of a bipolar mitotic spindle. Microtubules in cells stably expressing GFP-alpha-tubulin were directly observed from prophase to just after nuclear envelope breakdown (NEBD) in early prometaphase. Our results demonstrate a transient stimulation of individual Mt dynamic turnover and the formation and inward motion of microtubule bundles in these cells. Motion of microtubule bundles was inhibited after antibody-mediated inhibition of cytoplasmic dynein/dynactin, but was not inhibited after inhibition of the kinesin-related motor Eg5 or myosin II. In metaphase cells, assembly of small foci of Mts was detected at sites distant from the spindle; these Mts were also moved inward. We propose that cytoplasmic dynein-dependent inward motion of Mts functions to remove Mts from the cytoplasm at prophase and from the peripheral cytoplasm through metaphase. The data demonstrate that dynamic astral Mts search the cytoplasm for other Mts, as well as chromosomes, in mitotic cells.

Published

2002

13. Tyrosine-phosphorylated extracellular signal--regulated kinase associates with the Golgi complex during G2/M phase of the cell cycle: evidence for regulation of Golgi structure.

Author

Cha H and Shapiro P

Subjects

Animals, Antibody Specificity physiology, CHO Cells, Cell Line, Cell Membrane metabolism, Cricetinae, Cytoplasmic Vesicles metabolism, Cytoplasmic Vesicles ultrastructure, Fluorescent Antibody Technique, G2 Phase physiology, Golgi Apparatus ultrastructure, HeLa Cells, Humans, MAP Kinase Kinase 1, Macropodidae, Mannosidases metabolism, Membrane Proteins metabolism, Mitogen-Activated Protein Kinase Kinases biosynthesis, Mitogen-Activated Protein Kinase Kinases genetics, Mitosis physiology, Phosphorylation, Phosphothreonine metabolism, Phosphotyrosine metabolism, Protein Serine-Threonine Kinases biosynthesis, Protein Serine-Threonine Kinases genetics, Cell Cycle physiology, Golgi Apparatus metabolism, Mitogen-Activated Protein Kinases metabolism

Abstract

Phosphorylation of the extracellular signal-regulated kinases (ERKs) on tyrosine and threonine residues within the TEY tripeptide motif induces ERK activation and targeting of substrates. Although it is recognized that phosphorylation of both residues is required for ERK activation, it is not known if a single phosphorylation of either residue regulates physiological functions. In light of recent evidence indicating that ERK proteins regulate substrate function in the absence of ERK enzymatic activity, we have begun to examine functional roles for partially phosphorylated forms of ERK. Using phosphorylation site--specific ERK antibodies and immunofluorescence, we demonstrate that ERK phosphorylated on the tyrosine residue (pY ERK) within the TEY activation sequence is found constitutively in the nucleus, and localizes to the Golgi complex of cells that are in late G2 or early mitosis of the cell cycle. As cells progress through metaphase and anaphase, pY ERK localization to Golgi vesicles is most evident around the mitotic spindle poles. During telophase, pY ERK associates with newly formed Golgi vesicles but is not found on there after cytokinesis and entry into G1. Increased ERK phosphorylation causes punctate distribution of several Golgi proteins, indicating disruption of the Golgi structure. This observation is reversible by overexpression of a tyrosine phosphorylation--defective ERK mutant, but not by a kinase-inactive ERK2 mutant that is tyrosine phosphorylated. These data provide the first evidence that pY ERK and not ERK kinase activity regulates Golgi structure and may be involved in mitotic Golgi fragmentation and reformation.

Published

2001

14. Human ECT2 is an exchange factor for Rho GTPases, phosphorylated in G2/M phases, and involved in cytokinesis.

Author

Tatsumoto T, Xie X, Blumenthal R, Okamoto I, and Miki T

Subjects

Antibodies pharmacology, Antibody Specificity, Cell Division immunology, Epithelial Cells metabolism, Growth Inhibitors biosynthesis, Humans, Microinjections, Protein Structure, Tertiary, Proto-Oncogene Proteins biosynthesis, Proto-Oncogene Proteins immunology, Spindle Apparatus metabolism, cdc42 GTP-Binding Protein metabolism, rac1 GTP-Binding Protein metabolism, Epithelial Cells cytology, Epithelial Cells enzymology, G2 Phase physiology, Guanine Nucleotide Exchange Factors metabolism, Mitosis physiology, Proto-Oncogene Proteins metabolism, rho GTP-Binding Proteins metabolism

Abstract

Animal cells divide into two daughter cells by the formation of an actomyosin-based contractile ring through a process called cytokinesis. Although many of the structural elements of cytokinesis have been identified, little is known about the signaling pathways and molecular mechanisms underlying this process. Here we show that the human ECT2 is involved in the regulation of cytokinesis. ECT2 catalyzes guanine nucleotide exchange on the small GTPases, RhoA, Rac1, and Cdc42. ECT2 is phosphorylated during G2 and M phases, and phosphorylation is required for its exchange activity. Unlike other known guanine nucleotide exchange factors for Rho GTPases, ECT2 exhibits nuclear localization in interphase, spreads throughout the cytoplasm in prometaphase, and is condensed in the midbody during cytokinesis. Expression of an ECT2 derivative, containing the NH(2)-terminal domain required for the midbody localization but lacking the COOH-terminal catalytic domain, strongly inhibits cytokinesis. Moreover, microinjection of affinity-purified anti-ECT2 antibody into interphase cells also inhibits cytokinesis. These results suggest that ECT2 is an important link between the cell cycle machinery and Rho signaling pathways involved in the regulation of cell division.

Published

1999

15. A role for Cdk2 kinase in negatively regulating DNA replication during S phase of the cell cycle.

Author

Hua XH, Yan H, and Newport J

Subjects

Animals, Cell Cycle Proteins metabolism, Cell Nucleus physiology, Chromatin metabolism, Cyclin-Dependent Kinase 2, Cyclins metabolism, Cyclins pharmacology, Cytosol chemistry, Female, G1 Phase physiology, G2 Phase physiology, Male, Oocytes cytology, Oocytes enzymology, Protein Binding physiology, Replication Origin physiology, Spermatozoa chemistry, Xenopus, Xenopus Proteins, CDC2-CDC28 Kinases, Cyclin-Dependent Kinases metabolism, DNA Replication physiology, Protein Serine-Threonine Kinases metabolism, S Phase physiology

Abstract

Using cell-free extracts made from Xenopus eggs, we show that cdk2-cyclin E and A kinases play an important role in negatively regulating DNA replication. Specifically, we demonstrate that the cdk2 kinase concentration surrounding chromatin in extracts increases 200-fold once the chromatin is assembled into nuclei. Further, we find that if the cdk2-cyclin E or A concentration in egg cytosol is increased 16-fold before the addition of sperm chromatin, the chromatin fails to initiate DNA replication once assembled into nuclei. This demonstrates that cdk2-cyclin E or A can negatively regulate DNA replication. With respect to how this negative regulation occurs, we show that high levels of cdk2-cyclin E do not block the association of the protein complex ORC with sperm chromatin but do prevent association of MCM3, a protein essential for replication. Importantly, we find that MCM3 that is prebound to chromatin does not dissociate when cdk2-cyclin E levels are increased. Taken together our results strongly suggest that during the embryonic cell cycle, the low concentrations of cdk2-cyclin E present in the cytosol after mitosis and before nuclear formation allow proteins essential for potentiating DNA replication to bind to chromatin, and that the high concentration of cdk2-cyclin E within nuclei prevents MCM from reassociating with chromatin after replication. This situation could serve, in part, to limit DNA replication to a single round per cell cycle.

Published

1997

16. Chromosomes with two intact axial cores are induced by G2 checkpoint override: evidence that DNA decatenation is not required to template the chromosome structure.

Author

Andreassen PR, Lacroix FB, and Margolis RL

Subjects

2-Aminopurine pharmacology, Animals, Antimetabolites pharmacology, CHO Cells, Cell Cycle Proteins, Cell Line, Chromatin metabolism, Cricetinae, DNA Topoisomerases, Type II physiology, DNA-Binding Proteins metabolism, Diketopiperazines, Enzyme Inhibitors pharmacology, Kidney, Mitosis, Models, Genetic, Nuclear Proteins metabolism, Piperazines pharmacology, Teniposide pharmacology, Topoisomerase II Inhibitors, Avian Proteins, Chromosomes metabolism, DNA metabolism, G2 Phase physiology

Abstract

Here we report that DNA decatenation is not a physical requirement for the formation of mammalian chromosomes containing a two-armed chromosome scaffold. 2-aminopurine override of G2 arrest imposed by VM-26 or ICRF-193, which inhibit topoisomerase II (topo II)-dependent DNA decatenation, results in the activation of p34cdc2 kinase and entry into mitosis. After override of a VM-26-dependent checkpoint, morphologically normal compact chromosomes form with paired axial cores containing topo II and ScII. Despite its capacity to form chromosomes of normal appearance, the chromatin remains covalently complexed with topo II at continuous levels during G2 arrest with VM-26. Override of an ICRF-193 block, which inhibits topo II-dependent decatenation at an earlier step than VM-26, also generates chromosomes with two distinct, but elongated, parallel arms containing topo II and ScII. These data demonstrate that DNA decatenation is required to pass a G2 checkpoint, but not to restructure chromatin for chromosome formation. We propose that the chromosome core structure is templated during interphase, before DNA decatenation, and that condensation of the two-armed chromosome scaffold can therefore occur independently of the formation of two intact and separate DNA helices.

Published

1997

17. Antibody microinjection reveals an essential role for human polo-like kinase 1 (Plk1) in the functional maturation of mitotic centrosomes.

Author

Lane HA and Nigg EA

Subjects

Antibodies, Monoclonal pharmacology, Antibody Specificity, Cell Cycle physiology, Cell Cycle Proteins, Cell Division drug effects, Cells, Cultured cytology, Cells, Cultured enzymology, Cyclin-Dependent Kinase 2, Cyclin-Dependent Kinases metabolism, DNA biosynthesis, Epitopes physiology, Fibroblasts cytology, Fibroblasts enzymology, G2 Phase drug effects, G2 Phase physiology, HeLa Cells cytology, HeLa Cells enzymology, Humans, Male, Microinjections, Microtubules drug effects, Microtubules metabolism, Mitosis drug effects, Mitosis physiology, Protein Kinases pharmacology, Protein Serine-Threonine Kinases metabolism, Proto-Oncogene Proteins, Spindle Apparatus enzymology, Tubulin metabolism, Polo-Like Kinase 1, Antibodies pharmacology, CDC2-CDC28 Kinases, Centrosome enzymology, Protein Kinases immunology, Protein Kinases metabolism

Abstract

Mammalian polo-like kinase 1 (Plk1) is structurally related to the polo gene product of Drosophila melanogaster, Cdc5p of Saccharomyces cerevisiae, and plo1+ of Schizosaccharomyces pombe, a newly emerging family of serine-threonine kinases implicated in cell cycle regulation. Based on data obtained for its putative homologues in invertebrates and yeasts, human Plk1 is suspected to regulate some fundamental aspect(s) of mitosis, but no direct experimental evidence in support of this hypothesis has previously been reported. In this study, we have used a cell duplication, microinjection assay to investigate the in vivo function of Plk1 in both immortalized (HeLa) and nonimmortalized (Hs68) human cells. Injection of anti-Plk1 antibodies (Plk1+) at various stages of the cell cycle had no effect on the kinetics of DNA replication but severely impaired the ability of cells to divide. Analysis of Plk1(+)-injected, mitotically arrested HeLa cells by fluorescence microscopy revealed abnormal distributions of condensed chromatin and monoastral microtubule arrays that were nucleated from duplicated but unseparated centrosomes. Most strikingly, centrosomes in Plk1(+)-injected cells were drastically reduced in size, and the accumulation of both gamma-tubulin and MPM-2 immunoreactivity was impaired. These data indicate that Plk1 activity is necessary for the functional maturation of centrosomes in late G2/early prophase and, consequently, for the establishment of a bipolar spindle. Additional roles for Plk1 at later stages of mitosis are not excluded, although injection of Plk1+ after the completion of spindle formation did not interfere with cytokinesis. Injection of Plk1+ into nonimmortalized Hs68 cells produced qualitatively similar phenotypes, but the vast majority of the injected Hs68 cells arrested as single, mononucleated cells in G2. This latter observation hints at the existence, in nonimmortalized cells, of a centrosome-maturation checkpoint sensitive to the impairment of Plk1 function.

Published

1996

18. Microtubule dynamics at the G2/M transition: abrupt breakdown of cytoplasmic microtubules at nuclear envelope breakdown and implications for spindle morphogenesis.

Author

Zhai Y, Kronebusch PJ, Simon PM, and Borisy GG

Subjects

Animals, Cell Line, Cytoplasm metabolism, Epithelium, Fluorescein, Fluoresceins, Fluorescent Dyes, LLC-PK1 Cells, Lamins, Macropodidae, Microtubules drug effects, Morphogenesis, Nocodazole pharmacology, Nuclear Envelope chemistry, Nuclear Proteins analysis, Polymers, Prophase physiology, Rhodamines, Spindle Apparatus physiology, Swine, Tubulin analysis, G2 Phase physiology, Microtubules metabolism, Mitosis physiology, Nuclear Envelope metabolism, Tubulin metabolism

Abstract

We recently developed a direct fluorescence ratio assay (Zhai, Y., and G.G. Borisy. 1994. J. Cell Sci. 107:881-890) to quantify microtubule (MT) polymer in order to determine if net MT depolymerization occurred upon anaphase onset as the spindle was disassembled. Our results showed no net decrease in polymer, indicating that the disassembly of kinetochore MTs was balanced by assembly of midbody and astral MTs. Thus, the mitosis-interphase transition occurs by a redistribution of tubulin among different classes of MTs at essentially constant polymer level. We now examine the reverse process, the interphase-mitosis transition. Specifically, we quantitated both the level of MT polymer and the dynamics of MTs during the G2/M transition using the fluorescence ratio assay and a fluorescence photoactivation approach, respectively. Prophase cells before nuclear envelope breakdown (NEB) had high levels of MT polymer (62%) similar to that previously reported for random interphase populations (68%). However, prophase cells just after NEB had significantly reduced levels (23%) which recovered as MT attachments to chromosomes were made (prometaphase, 47%; metaphase, 56%). The abrupt reorganization of MTs at NEB was corroborated by anti-tubulin immunofluorescence staining using a variety of fixation protocols. Sensitivity to nocodazole also increased at NEB. Photoactivation analyses of MT dynamics showed a similar abrupt change at NEB, basal rates of MT turnover (pre-NEB) increased post-NEB and then became slower later in mitosis. Our results indicate that the interphase-mitosis (G2/M) transition of the MT array does not occur by a simple redistribution of tubulin at constant polymer level as the mitosis-interphase (M/G1) transition. Rather, an abrupt decrease in MT polymer level and increase in MT dynamics occurs tightly correlated with NEB. A subsequent increase in MT polymer level and decrease in MT dynamics occurs correlated with chromosome attachment. These results carry implications for understanding spindle morphogenesis. They indicate that changes in MT dynamics may cause the steady-state MT polymer level in mitotic cells to be lower than in interphase. We propose that tension exerted on the kMTs may lead to their lengthening and thereby lead to an increase in the MT polymer level as chromosomes attach to the spindle.

Published

1996

19. Role of inhibitory CDC2 phosphorylation in radiation-induced G2 arrest in human cells.

Author

Jin P, Gu Y, and Morgan DO

Subjects

CDC2 Protein Kinase biosynthesis, CDC2 Protein Kinase genetics, CDC2 Protein Kinase physiology, Cyclin B1, Cyclin-Dependent Kinase 2, Cyclin-Dependent Kinases biosynthesis, Cyclins metabolism, Enzyme Repression drug effects, G2 Phase radiation effects, HeLa Cells, Humans, Mitosis physiology, Mutation, Phosphorylation, Protein Serine-Threonine Kinases biosynthesis, Protein Synthesis Inhibitors pharmacology, Recombinant Fusion Proteins biosynthesis, S Phase physiology, S Phase radiation effects, Tetracycline pharmacology, CDC2 Protein Kinase metabolism, CDC2-CDC28 Kinases, Cyclin B, DNA Damage physiology, G2 Phase physiology

Abstract

The activity of the mitosis-promoting kinase CDC2-cyclin B is normally suppressed in S phase and G2 by inhibitory phosphorylation at Thr14 and Tyr15. This work explores the possibility that these phosphorylations are responsible for the G2 arrest that occurs in human cells after DNA damage. HeLa cell lines were established in which CDC2AF, a mutant that cannot be phosphorylated at Thr14 and Tyr15, was expressed from a tetracycline-repressible promoter. Expression of CDC2AF did not induce mitotic events in cells arrested at the beginning of S phase with DNA synthesis inhibitors, but induced low levels of premature chromatin condensation in cells progressing through S phase and G2. Expression of CDC2AF greatly reduced the G2 delay that resulted when cells were X-irradiated in S phase. However, a significant G2 delay was still observed and was accompanied by high CDC2-associated kinase activity. Expression of wild-type CDC2, or the related kinase CDK2AF, had no effect on the radiation-induced delay. Thus, inhibitory phosphorylation of CDC2, as well as additional undefined mechanisms, delay mitosis after DNA damage.

Published

1996

20. Initial triggering of M-phase in starfish oocytes: a possible novel component of maturation-promoting factor besides cdc2 kinase.

Author

Okumura E, Sekiai T, Hisanaga S, Tachibana K, and Kishimoto T

Subjects

Adenine analogs & derivatives, Adenine pharmacology, Animals, Cell Cycle Proteins, Enzyme Activation, G2 Phase physiology, Maturation-Promoting Factor isolation & purification, Meiosis drug effects, Mitosis drug effects, Models, Biological, Oocytes drug effects, Phosphoprotein Phosphatases, Starfish, cdc25 Phosphatases, Maturation-Promoting Factor metabolism, Meiosis physiology, Mitosis physiology, Oocytes physiology

Abstract

G2-phase-arrested immature starfish oocytes contain inactive cdc2 kinase and cdc25 phosphatase, and an inactivator for cdc2 kinase. In this system, we have studied how the regulatory balance is apped toward the initial activation of cdc2 kinase. During the hormone-dependent period (Guerrier, P., and M. Doree, 1975. Dev. Biol. 47:341-348), p34cdc2 and cdc25 protein are already converted, though not fully, to active forms, whereas the inactivators for cdc2 kinase and cdc25 phosphatase are able to exhibit their activities if the hormone were removed. We produced "triggered oocytes," in which due to a neutralizing anticdc25 antibody, the activation of cdc2 kinase is prevented out cdc25 protein is phosphorylated slightly after the maturation-inducing hormonal stimulus. In contrast to control immature oocytes, in triggered oocytes the injected cdc2 kinase is not inactivated, and accordingly the level of cdc2 kinase activity required for meiosis reinitiation is much less. These results imply the presence of a cdc2 kinase activity-independent process(es) that suppresses the inactivator for cdc2 kinase and initially phosphorylates cdc25 protein, although this process is reversible during the initial activation of cdc2 kinase. At the most initial triggering of M-phase, the cdc2 kinase activity-independent process might trip the switch leading to the initial activation of cdc2 kinase. Thereafter, in parallel, the cdc2 kinase-dependent feedback loops described by others may cause further increase in cdc2 kinase activity. We propose that a putative suppressor, which downregulates the inactivator for cdc2 kinase independently of nuclear components, might be a previously unrecognized component of maturation-promoting factor.

Published

1996

21. Yeast Num1p associates with the mother cell cortex during S/G2 phase and affects microtubular functions.

Author

Farkasovsky M and Küntzel H

Subjects

Calcium-Binding Proteins genetics, Calcium-Binding Proteins ultrastructure, Cell Membrane metabolism, Cell Nucleus physiology, Cytoskeletal Proteins, Fluorescent Antibody Technique, Indirect, Fungal Proteins genetics, Fungal Proteins ultrastructure, Microscopy, Phase-Contrast, Microtubules ultrastructure, Mutation physiology, Periodicity, RNA, Messenger metabolism, Saccharomyces cerevisiae genetics, Spindle Apparatus physiology, Tubulin genetics, Calcium-Binding Proteins metabolism, Fungal Proteins metabolism, G2 Phase physiology, Microtubules physiology, S Phase physiology, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins

Abstract

The NUM1 gene is involved in the control of nuclear migration in Saccharomyces cerevisiae. The content of NUM1 mRNA fluctuates during the cell cycle, reaching a maximum at S/G2 phase, and the translation product Num1p associates with the cortex of mother cells mainly during S, G2, and mitosis, as seen by indirect immunofluorescence. The nuclear spindle in NUM1-deficient large-budded cells often fails to align along the mother/bud axis, while abnormally elongated astral microtubules emanate from both spindle pole bodies. A num1 null mutation confers temperature sensitivity to the cold-sensitive alpha-tubulin mutant tub1-1, and shows synthetic lethality with the beta-tubulin mutant alleles tub2-402, tub2-403, tub2-404, and tub2-405. Deletion mapping has defined three functionally important Num1p regions: a potential EF hand Ca2+ binding site, a cluster of potential phosphorylation sites and a pleckstrin homology domain. The latter domain appears to be involved in targeting Num1p to the mother cell cortex. Our data suggest that the periodically expressed NUM1 gene product controls nuclear migration by affecting astral microtubule functions.

Published

1995

22. CENP-F is a protein of the nuclear matrix that assembles onto kinetochores at late G2 and is rapidly degraded after mitosis.

Author

Liao H, Winkfein RJ, Mack G, Rattner JB, and Yen TJ

Subjects

Amino Acid Sequence, Antigens, Nuclear, Autoantibodies blood, Autoantigens genetics, Base Sequence, Cell Compartmentation, Cell Nucleus ultrastructure, Chromosomal Proteins, Non-Histone genetics, Cloning, Molecular, Cross Reactions, DNA, Complementary genetics, Epitopes, Fluorescent Antibody Technique, G2 Phase physiology, HeLa Cells, Humans, Microfilament Proteins, Mitosis physiology, Molecular Sequence Data, Nuclear Matrix chemistry, Nuclear Proteins genetics, Protein Binding, Protein Structure, Secondary, Sequence Analysis, DNA, Autoantigens metabolism, Cell Division physiology, Chromosomal Proteins, Non-Histone metabolism, Kinetochores metabolism, Nuclear Matrix metabolism, Nuclear Proteins metabolism

Abstract

Centromere protein-F (CENP-F) is mammalian kinetochore protein that was recently identified by an autoimmune serum (Rattner, J. B., A. Rao, M. J. Fritzler, D. W. Valencia, and T. J. Yen. Cell Motil. Cytoskeleton. 26:214-226). We report here the human cDNA sequence of CENP-F, along with its expression and localization patterns at different stages of the HeLa cell cycle. CENP-F is protein of the nuclear matrix that gradually accumulates during the cell cycle until it reaches peak levels in G2 and M phase cells and is rapidly degraded upon completion of mitosis. CENP-F is first detected at the prekinetochore complex during late G2, and is clearly detectable as paired foci that correspond to all the centromeres by prophase. During mitosis, CENP-F is associated with kinetochores from prometaphase until early anaphase and is then detected at the spindle midzone throughout the remainder of anaphase. By telophase, CENP-F is concentrated within the intracellular bridge at either side of the mid-body. The predicted structure of the 367-kD CENP-F protein consists of two 1,600-amino acid-long coil domains that flank a central flexible core. A putative P-loop nucleotide binding site (ADIPTGKT) is located within the globular carboxy terminus. The structural features deduced from our sequence studies and the spatial and temperal distribution of CENP-F revealed in our cytological and biochemical studies suggest that it may play a role in several mitotic events.

Published

1995

23. The topoisomerase II inhibitor VM-26 induces marked changes in histone H1 kinase activity, histones H1 and H3 phosphorylation, and chromosome condensation in G2 phase and mitotic BHK cells.

Author

Roberge M, Th'ng J, Hamaguchi J, and Bradbury EM

Subjects

Animals, Aphidicolin, Cell Cycle drug effects, Cells, Cultured, Chromosomes drug effects, DNA Damage, Demecolcine pharmacology, Diterpenes pharmacology, G1 Phase, G2 Phase physiology, Metaphase physiology, Mitosis physiology, Nuclear Envelope metabolism, Phosphorylation, Protamine Kinase drug effects, Topoisomerase I Inhibitors, Topoisomerase II Inhibitors, Chromosomes metabolism, DNA Topoisomerases, Type II physiology, Histones metabolism, Protamine Kinase metabolism, Teniposide pharmacology

Abstract

We have examined the effects of topoisomerase inhibitors on the phosphorylation of histones in chromatin during the G2 and the M phases of the cell cycle. Throughout the G2 phase of BHK cells, addition of the topoisomerase II inhibitor VM-26 prevented histone H1 phosphorylation, accompanied by the inhibition of intracellular histone H1 kinase activity. However, VM-26 had no inhibitory effect on the activity of the kinase in vitro, suggesting an indirect influence on histone H1 kinase activity. Entry into mitosis was also prevented, as monitored by the absence of nuclear lamina depolymerization, chromosome condensation, and histone H3 phosphorylation. In contrast, the topoisomerase I inhibitor, camptothecin, inhibited histone H1 phosphorylation and entry into mitosis only when applied at early G2. In cells that were arrested in mitosis, VM-26 induced dephosphorylation of histones H1 and H3, DNA breaks, and partial chromosome decondensation. These changes in chromatin parameters probably reverse the process of chromosome condensation, unfolding condensed regions to permit the repair of strand breaks in the DNA that were induced by VM-26. The involvement of growth-associated histone H1 kinase in these processes raises the possibility that the cell detects breaks in the DNA through their effects on the state of DNA supercoiling in constrained domains or loops. It would appear that histone H1 kinase and topoisomerase II work coordinately in both chromosome condensation and decondensation, and that this process participates in the VM-26-induced G2 arrest of the cell.

Published

1990

24. Injection of anticentromere antibodies in interphase disrupts events required for chromosome movement at mitosis.

Author

Bernat RL, Borisy GG, Rothfield NF, and Earnshaw WC

Subjects

Anaphase physiology, Animals, Autoantibodies isolation & purification, Cell Cycle, Cell Line, G2 Phase physiology, Humans, Immunoblotting, Interphase physiology, Metaphase physiology, Microinjections, Nucleoproteins physiology, Time Factors, Centromere physiology, Chromosomes physiology, Mitosis physiology

Abstract

We have used autoantibodies to probe the function of three human centromere proteins in mitosis. These antibodies recognize three human polypeptides in immunoblots: CENP-A (17 kD), CENP-B (80 kD), and CENP-C (140 kD). Purified anticentromere antibodies (ACA-IgG) disrupt mitosis when introduced into tissue culture cells during interphase. We have identified two execution points for antibody inhibition. Antibodies injected into the nucleus greater than or equal to 3 h before mitosis prevent the chromosomes from undergoing normal prometaphase movements in the subsequent mitosis. Antibodies injected in the nucleus during late G2 cause cells to arrest in metaphase. Surprisingly, antibodies introduced subsequent to the beginning of prophase do not block mitosis. These results suggest that the CENP antigens are involved in two essential interphase events that are required for centromere action in mitosis. These may include centromere assembly coordinate with the replication of alpha-satellite DNA at the end of S phase and the structural maturation of the kinetochore that begins at prophase.

Published

1990