Intrinsic fluctuations of phosphoinositol levels are involved in the progression of the naturally synchronous cell cycle in Physarum polycephalum.

Using [3H]myo-inositol incorporation, changes in phosphoinositol (PI) metabolism at different cell cycle stages in the myxomycete Physarum polycephalum were examined by column chromatography. Two base levels for the inositol trisphosphate (IP3) fraction were determined: a low one for S-phase and a higher one for G2 phase. Two transient increases of IP3 were also observed, one in S-phase, 70 min after mitosis (no G1 phase in the Physarum cell cycle) and another in G2 phase, 90 min before mitosis. It is concluded that the fluctuations in IP3 levels reflect endogenous events in the cell cycle of Physarum, because they occurred in the absence of any exogenous signals. Pulse treatment with Li+ (10 mM) at the points of the cell cycle, characterized by the IP3 transients, had opposite effects: in early S-phase it caused an acceleration while in late G2 phase it caused a prolongation of the cell cycle duration. The pattern of Li(+)-induced changes in PI turnover is also antagonistic: in most cases the IP3 level would decrease, however, Li+ prevents the cell cycle-dependent reduction in IP3 concentration when applied at early S-phase. The possible implications of the autogenous fluctuations in the IP3 fraction on the progression of the cell cycle through several distinct checkpoints are discussed.     

Synchronization of cellular proliferation in mice with sarcoma 37 by using hydroxyurea]

The synchronizing effect of hydroxyurea on the passage of sarcoma 37 cells through the stage of the S-phase and mitosis was investigated in albino mice. The study was performed with consideration to the circadian variations in the mitotic activity and the labelled nuclei indices. The degree of synchronization was assessed by the changes in the cell count and the rate of changes in synchronicity. The tumour consisted of at least two cell populations in which the variations in the number of cells both at the S-period, and, possibly, in mitosis were shifted in respect to one another by phase. The rate of artificial cell synchronization in the mitosis proved to be much greater than the natural one in the tumour undivided into individual populations. However, the number of cells subjected to artificial synchronization showed no significant difference not only from the cell count in the tumour undivided into individual populations, but also from the number of cells synchronized naturally in one of the populations. This could be explained by the fact that hydroxyurea acted on one group of cells only since variations in the number of DNA-synthesizing cells were shifted in individual populations in respect to one another by phase.     

Felix Hoppe-Seyler Lecture 1999. Cyclin dependent kinases and regulation of the fission yeast cell cycle.

The cyclin dependent kinases (CDKs), formed by complexes between Cdc2p and the B-cyclins Cig2p and Cdc13p, have a central role in regulating the fission yeast cell cycle and maintaining genomic stability. The CDK Cig2p/Cdc2p controls the onset of S-phase and the CDK Cdc13p/Cdc2p controls the onset of mitosis and ensures that there is only one S-phase in each cell. Cdc13p/Cdc2p can replace Cig2p/Cdc2p forthe onset of S-phase, suggesting that the increasing activity of a single CDK during the cell cycle is sufficient to drive a cell in an orderly fashion into S-phase and into mitosis. If S-phase is incomplete, then inhibition of Cdc13p/ Cdc2p prevents cells with unreplicated DNA from undergoing a catastrophic entry into mitosis. Control of CDK activity is also important to allow cells to exit the cell cycle and accumulate in G1 in response to nutritional deprivation and the presence of pheromone.     

Evaluation of a short term in vitro test for granulocyte chalone activity.

A short term in vitro test for granulocyte chalone activity eas examined for its specificity and reliability. The test used the inhibition, by granulocyte extracts, of 3H-thymidine (3H-Tdr) uptake in to the acid-insoluble material by rat bone marrow cells in vitro to measure possible chalone activity. Among the many possible 3H-Tdr artifacts pool size dilution by Tdr contained in the extracts was excluded using an E. coli mutant requiring thymine. Several amino acids and biogenic amines do not affect the test. However, continuous and pulse labelling of bone marrow cells with 3H-Tdr, viability tests and micro flow fluorometric measurements of the cell cycle distribution following colcemid treatment strongly suggests that the cells do not proliferate in vitro during short term incubation, since practically no cells enter the S-phase, cells in the S-phase die and few if any cells proceed through G2 and mitosis. Moreover, the test cannot exclude cytotoxicity. Thus, the in vitro test may only sceem for an unspecific S-phase inhibitor and must hence be supplemented by another assay to prove the chalone nature of an extract or fraction. The test per se fails to meet most of the requirements of a valid granulocyte chalone assay.     

Two S-phase checkpoint systems, one involving the function of both BIME and Tyr15 phosphorylation of p34cdc2, inhibit NIMA and prevent premature mitosis.

We demonstrate that there are at least two S-phase checkpoint mechanisms controlling mitosis in Aspergillus. The first responds to the rate of DNA replication and inhibits mitosis via tyrosine phosphorylation of p34cdc2. Cells unable to tyrosine phosphorylate p34cdc2 are therefore viable but are unable to tolerate low levels of hydroxyurea and prematurely enter lethal mitosis when S-phase is slowed. However, if the NIMA mitosis-promoting kinase is inactivated then non-tyrosine-phosphorylated p34cdc2 cannot promote cells prematurely into mitosis. Lack of tyrosine-phosphorylated p34cdc2 also cannot promote mitosis, or lethality, if DNA replication is arrested, demonstrating the presence of a second S-phase checkpoint mechanism over mitotic initiation which we show involves the function of BIME. In order to overcome the S-phase arrest checkpoint over mitosis it is necessary both to prevent tyrosine phosphorylation of p34cdc2 and also to inactivate BIME. Lack of tyrosine phosphorylation of p34cdc2 allows precocious expression of NIMA during S-phase arrest, and lack of BIME then allows activation of this prematurely expressed NIMA by phosphorylation. The mitosis-promoting NIMA kinase is thus a target for S-phase checkpoint controls.     

The cell cycle during amphibian limb regeneration.

The duration of the cell cycle in the blastema of regenerating limbs of axolotls has been measured by means of [3H]thymidine pulse labelling and autoradiography. A chase was required to define the pulse period. An average cell cycle at 20 degrees C takes 53 h, S-phase takes 38 h; including parts of mitosis, G1 is 10 h and G2 is 5 h long. The protracted cycle and S-phase are consonant with the large genome in axolotis and other urodeles. The rapidly growing blastema probably contains a steady population of about 5000 proliferating cells, as there is a regular withdrawal of differentiating cells from the population. The kinds of determination which exist in this population of cells, or are exerted on it, are briefly considered.     

Evidence for a homolog of the yeast cell cycle regulatory gene product of cdc2+ in Physarum polycephalum

Evidence for the presence of a Cdc2-like protein in Physarum polycephalum has been obtained using a peptide antibody directed against a highly conserved amino acid sequence near the N-terminal end of Cdc2, Cdc28 and Cdc2HS. The antibody detected a 34 kDa cytoplasmic protein, similar in apparent size to Cdc2 in yeast and Cdc2Hs in HeLa cells. A 60 kDa nuclear band was also detected in Physarum but not in yeast or HeLa. Evidence is presented that this is not related to the 34 kDa protein nor is it found in HeLa nuclei or yeast cells. The Cdc2-like protein level did not fluctuate over more than 10 h of the naturally synchronous cell cycle of Physarum. Several heat-shock experiments using regimens that either: delayed mitosis and S-phase; prevented mitosis or uncoupled S-phase from mitosis were performed. None had any effect on the level of the Cdc2-like protein. The induction of spherulation by starvation was shown to have no effect on the levels of the 34 kDa Cdc2 analog. The invariant level of the 34 kDa protein during the cell cycle and starvation is consistent with previous results obtained with yeast. Three heat-shock regimens which either delay mitosis, eliminate S-phase or uncouple mitosis from S-phase in Physarum also had no effect on the level of the 34 kDa protein. This result emphasizes the stable nature of this protein.     

The induction of DNA synthesis in the chick red cell nucleus in heterokaryons during the first cell cycle after fusion with HeLa cells.

Induction of DNA synthesis in embryonic chick red cells has been examined during the first and second cell cycles after fusion with HeLa cells synchronized in different parts of G1 and S-phase. The data indicate that: (i) the younger the embryonic blood the more rapidly the red cells are induced into DNA synthesis; (ii) the greater the ratio of HeLa to chick nuclei in the heterokaryon, the more rapidly the induction occurs; (iii) DNA synthesis in the chick nucleus can continue after the HeLa nucleus has left S-phase and entered either G2 or mitosis; (iv) the induction potential of late S-phase HeLa is somewhat lower than that of early or mid S-phase cells; (v) less than 10% of the chick DNA is replicated during the first cycle after fusion and only a small proportion (15%) of the chick nuclei approach the 4C value of DNA during the second cycle after fusion; (vi) the newly synthesized DNA is associated either with the condensed regions of the nucleus or with the boundaries between condensed and non-condensed regions; (vii) the chick chromosomes at the first and second mitosis after fusion are in the form of PCC prematurely condensed chromosomes); they are never fully replicated and are often fragmentary; (viii) DNA synthesis in the chick nuclei is accompanied by an influx of protein (both G1 and S-phase protein) from the HeLa component of the heterokaryon.     

Regulation of DNA replication in the nuclei of the slime mold Physarum polycephalum. Transplantation of nuclei by plasmodial coalescence

Nuclei in G2 phase of the slime mold Physarum polycephalum, when transplanted, by plasmodial coalescence, into an S-phase plasmodium, failed to start another round of DNA synthesis. In the reciprocal combination, S-phase nuclei in a G2-phase host continued DNA synthesis for several hours without appreciable decrease in rate. It is suggested that the beginning of DNA replication is determined by an event, either during or shortly after mitosis, which renders the chromosomes structurally competent for DNA replication.     

S-phase and M-phase timing are under independent circadian control in the dinoflagellate Lingulodinium

In many phytoplankton species, cell division (mitosis) usually occurs at defined times of day. This timing is also observed under constant conditions, indicating that it is regulated by a circadian clock rather than by a simple response to the light-dark cycle. For those algae with cell cycles longer than a day, the clock opens a window of opportunity for mitosis at a particular time of day through which cells in an appropriate phase of the cell cycle can pass. Although the timing of mitosis is generally studied due to ease of measurement, for some phytoplankton the timing of S-phase is also circadian. This thus raises the possibility that mitosis is not directly gated by the clock but occurs instead at a defined interval (a constant G2 length) following a circadian controlled S-phase. To determine if the clock exercises independent control over the timing of both S- and M-phase, we measured the timing of both S- and M-phase in cultures of the dinoflagellate Lingulodinium grown under a variety of different photoperiods. We interpret the phase angles of both rhythms, in particular those resulting in a change in the length of G2, as an indication that the clock independently regulates the timing of S-phase and mitosis.     

Cdc25 regulates the phosphorylation and activity of the Xenopus cdk2 protein kinase complex.

The Xenopus cdk2 gene encodes a 32-kDa protein kinase with sequence similarity to the 34-kDa product of the cdc2 gene. Previous studies have shown that the kinase activity of the protein product of the cdk2 gene oscillates in the Xenopus embryonic cell cycle with a high in M-phase and a low in interphase. In the present study cdk2 was found not to be associated with any newly synthesized proteins during the cell cycle, but the enzyme did undergo periodic changes in phosphorylation. Upon exit from metaphase, cdk2 became increasingly phosphorylated on both tyrosine and serine residues, and labeling on these residues increased progressively until entry into mitosis, when tyrosine residues were markedly dephosphorylated. Phosphopeptide mapping of cdk2 demonstrated the major sites of phosphorylation were in a phosphopeptide with a pI of 3.7 that contained both phosphoserine and phosphotyrosine. This phosphopeptide accumulated in egg extracts blocked in S-phase with aphidicolin and was not evident in cdc2 immunoprecipitated under the same conditions. Under the same conditions cdc2 was phosphorylated primarily on a phosphopeptide containing both phosphothreonine and phosphotyrosine residues, most likely threonine 14 and tyrosine 15. Affinity-purified human GST-cdc25 was able to dephosphorylate and activate cdk2 isolated from interphase cells. Phosphopeptide mapping demonstrated that the phosphate was specifically removed from the same phosphopeptide identified as the major in vivo site of phosphorylation. These results demonstrate that cdk2 is regulated in the cell cycle by phosphorylation and dephosphorylation on both serine and tyrosine residues. Moreover, the increased phosphorylation of cdk2 in aphidicolin-blocked extracts and the ability of cdc25 to mediate cdk2 dephosphorylation in vitro suggest the possibility that cdk2 is part of the mechanism ensuring mitosis is not initiated until completion of DNA replication. It also implies cdc25 may have other functions in addition to the regulation of cdc2 kinase activity.     

The apoptosis of HEL cells induced by hydroxyurea

INTRODUCTIONApoptosis(programmedcelldeath)playsafundamentalroleduringinvertebrateandvertebratedevelopment.Theoriginofhumancancermaybeassociatedwiththefailureofendangeredcellstoundergoapoptosis.Apoptosishasbeenobservedinmanydifferentcellsandinresponsetomanyphysiologicalsignalsortypesofstress[1,2].Itcanbeinducedbyglucocorticoidtreatment,exposuretoCa2 ionophoresorac--irradiationofmousethymocytesandgrowthfactordeprivationofbothhematopoieticandlymphoidcellsinvitro[3,4].Hydroxyureacanstimulate…     

Detection of in situ mitotic activity of dendritic epidermal T-cells by BrdU labeling.

We analyzed mitotic dendritic epidermal T-cells (DETC) in the epidermis of C3H/He (Thy-1.2+) mice, using double immunoenzymatic labeling. Ear skin was incubated with 100 microM bromodeoxyuridine (BrdU) for 5 hr and then either directly studied or cultured for an additional 12 hr in BrdU-free medium. After BrdU labeling, with or without additional culture, epidermal sheets were obtained by ethylenediaminetetraacetic acid separation. The epidermal specimens were immunostained by the peroxidase method to visualize nuclear BrdU and then by the biotin-streptavidin-alkaline phosphatase method for surface Thy-1.2 antigen. In specimens processed immediately after BrdU labeling, a mean 3.0% of all basal cells were labeled with BrdU and a mean 1.1% of the BrdU-labeled cells were also positive for Thy-1.2. Moreover, a mean 2.1% of the DETC had incorporated BrdU. BrdU-labeled DETC had a variety of appearances; they were dendritic and round in the BrdU-treated specimens, while oval and paired cells were also found in the specimens after additional culture. These morphological changes of BrdU-labeled DETC demonstrate that resident DETC can become mother cells undergoing mitosis through the retraction of their dendrites, and it appears that DETC divide at a relatively high rate, i.e., up to 10% of the DETC may enter the S-phase of the cell cycle every 24 hr.     

Cell cycle: how cyclin E got its groove back

CDK1 has long been known to orchestrate the passage of mammalian cells into and through mitosis. Recent work revisits the idea that CDK1, in conjunction with cyclin E, participates in S-phase entry as well. The new results shed light on a recent cell-cycle mystery, and provide another dramatic example of apparent functional redundancy among cyclins and cyclin-dependent kinases.     

The deubiquitinating enzyme USP37 enhances CHK1 activity to promote the cellular response to replication stress

The deubiquitinating enzyme USP37 is known to contribute to timely onset of S phase and progression of mitosis. However, it is not clear if USP37 is required beyond S-phase entry despite expression and activity of USP37 peaking within S phase. We have utilized flow cytometry and microscopy to analyze populations of replicating cells labeled with thymidine analogs and monitored mitotic entry in synchronized cells to determine that USP37-depleted cells exhibited altered S-phase kinetics. Further analysis revealed that cells depleted of USP37 harbored increased levels of the replication stress and DNA damage markers γH2AX and 53BP1 in response to perturbed replication. Depletion of USP37 also reduced cellular proliferation and led to increased sensitivity to agents that induce replication stress. Underlying the increased sensitivity, we found that the checkpoint kinase 1 is destabilized in the absence of USP37, attenuating its function. We further demonstrated that USP37 deubiquitinates checkpoint kinase 1, promoting its stability. Together, our results establish that USP37 is required beyond S-phase entry to promote the efficiency and fidelity of replication. These data further define the role of USP37 in the regulation of cell proliferation and contribute to an evolving understanding of USP37 as a multifaceted regulator of genome stability.     

Cyclin E and its associated cdk activity do not cycle during early embryogenesis of the sea Urchin

Female sea urchins store their gametes as haploid eggs. The zygote enters S-phase 1 h after fertilization, initiating a series of cell cycles that lack gap phases. We have cloned cyclin E from the sea urchin Strongylocentrotus purpuratus. Cyclin E is synthesized during oogenesis, is present in the germinal vesicle, and is released into the egg cytoplasm at oocyte maturation. Cyclin E synthesis is activated at fertilization, although there is no increase in cyclin E protein levels due to continuous turnover of the protein. Cyclin E protein levels decline in morula embryos, while cyclin E mRNA levels remain high. After the blastula stage, cyclin E mRNA and protein levels are very low, and cyclin E expression is predominant only in cells that are actively dividing. These include cells in the left coelomic pouch, which forms the adult rudiment in the embryo. The cyclin E present in the egg is complexed with a protein kinase. Activity of the cyclin E/cdk2 changes little during the initial cell cycles. In particular, cyclin E-cdk2 levels remain high during both S-phase and mitosis. Our results suggest that progression through the early embryonic cell cycles in the sea urchin does not require fluctuations in cyclin E kinase activity.     

ATR (AT mutated Rad3 related) activity stabilizes Cdc6 and delays G2/M-phase entry during hydroxyurea-induced S-phase arrest of HeLa cells

The Cdc6 protein, a key DNA replication initiation factor, contributes to the long-term maintenance of the S-phase checkpoint by anchoring the Rad3–Rad26 complex to chromatin. Here, we demonstrate that ATR (AT mutated and Rad3 related) activity is essential for maintaining high chromatin levels of the Cdc6 protein, thereby delaying entry into mitosis during hydroxyurea (HU)-induced S-phase arrest of HeLa cells. Downregulation of ATR (AT mutated and Rad3 related) (i.e., using ATR-siRNA) reduced the protein levels of chromatin Cdc6 and significantly increased the cellular levels of phospho-histone H3 (Ser 10), an index of mitosis. Downregulation of Cdc6 was completely restored by pretreatment with MG132, a proteasome inhibitor. Moreover, mitotic entry of MG132-pretreated cells was significantly downregulated. Our results also show that ATR (AT mutated and Rad3 related) kinase phosphorylates Cdc6 at serine residue 6. Thus, this ATR (AT mutated and Rad3 related)-mediated phosphorylation of Cdc6 is likely associated with stabilization of Cdc6 protein, thereby maintaining high levels of chromatin Cdc6 and delaying premature mitotic entry. This novel mechanism likely contributes to the functional regulation of chromatin Cdc6, which delays the cell cycle of hydroxyurea-induced cells to enter mitosis at the S-phase checkpoint.     

Ellipse mutations in the Drosophila homologue of the EGF receptor affect pattern formation, cell division, and cell death in eye imaginal discs.

Ellipse alleles are mutations of the EGF-receptor homologue that reduce the number of ommatidia in the eye imaginal disc. Cobalt sulfide staining, expression of hairy and scabrous proteins, and mosaic analysis indicated that Elp mutations affect ommatidial precluster formation in the morphogenetic furrow. BrdU incorporation studies suggest that cells diverted from precluster formation instead enter S-phase after the morphogenetic furrow. Genetic studies suggest that the DER has multiple functions during eye development and that several recessive hypomorphic alleles affect another aspect of DER function that is required after precluster formation. Elp mutations show genetic interactions with the neurogenic mutations Notch and Delta. The small number of ommatidia that differentiate in Elp/Elp are separated more than in wildtype and have been studied to investigate what aspects of ommatidium development are intrinsic to the ommatidium itself. It appears that each developing ommatidium cues the determination of photoreceptors, cone cells, and primary pigment cells, but that the secondary and tertiary pigment cells, and the mechanosensory bristles, can form independently. The normal rotation of ommatidia in the dorsal-ventral axis does not require the presence of the ommatidial array. A short-range signal from a nearby ommatidium is important for mitosis. Cells not close to an ommatidium do not go through mitosis and many die.     

The Dictyostelium cell cycle and its relationship to differentiation

Abstract The Dictyostelium vegetative cell cycle is characterized by a short mitotic period followed immediately by a short S-phase (less than 30 min) and a long and variable G2 phase. The cell cycle continues during differentiation despite a decrease in cell mass: DNA replication and mitosis occur early in development and also at the tipped aggregate stage. Cells that are in mitosis, S-phase or early G2, when starved differentiate into prestalk cells and cells that are in the middle of G2 differentiate into prespore cells. We postulate that there is a restriction point late in the G2 phase, about 1–2 h before mitosis, where the cells can be arrested either by starvation and the initiation of development, by growing into stationary phase, or by prolonged incubation at low temperature. During development, this block persists to the tipped aggregate stage, where it is specifically released in prespore cells, and these cells then go through one more round of cell division. Genes encoding components of the cell cycle machinery have recently been isolated and attemps to specifically block the cell cycle by reverse genetics to study the effects on differentiation have been initiated.