435 REDUCTION OF CELL CYCLE LENGTH AND INCREASE IN S-PHASE BY GROWTH FACTORS IN PIG FETAL FIBROBLASTS

2010 ◽  
Vol 22 (1) ◽  
pp. 374
Author(s):  
S. Waghmare ◽  
B. Mir
Keyword(s):  
Cell Cycle ◽  
Cell Proliferation ◽  
Growth Factors ◽  
Growth Factor ◽  
Cycle Length ◽  
S Phase ◽  
Proliferation Rate ◽  
Fetal Fibroblasts ◽  
Cell Cycle Length ◽  
Number Of Cells

Gene targeting in primary somatic cells is inefficient compared with embryonic stem cells. This is because of a slow rate of cell proliferation, fewer cells in S-phase at a given time point under normal culture conditions, and low rate of homologous recombination. Homologous recombination occurs mainly in late S-phase and increase in gene targeting efficiency has been reported in S-phase synchronized cells in bovine and rhesus macaque fetal fibroblasts. In this study we tested several growth factors: platelet-derived growth factor (PDGF), tumor necrosis factor a (TNFα), epidermal growth factor (EGF), fibroblast growth factor (FGF), transforming growth factor β1 (TGFβ1), insulin-like growth factor 1 (ILGF-1) and insulin-like growth factor II (ILGF-II) individually and in various combinations to see the effect on cell proliferation rate. Each experimental set consisted of 3 replicates. TGFβ1-, ILGF1-, ILGFII-, and FGF-treated cells grew very slowly compared with untreated cells. However, a combination of 3 growth factors: PDGF (15 ng mL-1), EGF (50 ng mL-1) and TNFa (100 pg mL-1), herein referred to as the cocktail, accelerated cell proliferation rate and reduced cell cycle length on average from 24.5 ± 0.2 to 20.4 ± 0.5 h with no significant change in number of cells in S-phase. Further, cells grown in the presence of the cocktail showed changes in morphology. The cells became spindle-shaped and occupied less surface area per cell compared with untreated cells. Importantly, cocktail-treated cells maintained a normal karyotype without any chromosomal abnormality. Thymidine has been used successfully to block various cell types in S-phase but it failed to synchronize these cells in S-phase in the concentration range of 2 to 10 mM for 24 to 48 h. However, serum starvation (0.2% fetal bovine serum) for 48 h blocked the cell proliferation rate effectively and synchronized cells in G0 phase (80-82% cells). After releasing from the block, cells were grown in the absence or presence of cocktail and cell cycle analysis was done at different time points by flow cytometry. Each time point was repeated 3 times. We observed the maximum number of cells in S-phase at 22 to 23 h (61.33% ± 7.77 in cocktail-treated cells v. 41.7% ± 3.28 in untreated cells). In summary, the cocktail-treated cells showed changes in cell morphology, higher proliferation rate, reduction in cell cycle length by 16.7%, and maximum percentage of cells in S-phase following serum starvation but maintained normal karyotypes. This high proliferation rate, reduction in cell cycle length, and maximum number of cells in S-phase should be very helpful in increasing the efficiency of gene-targeting in pig fetal fibroblasts.

scholarly journals Replication fork rate and origin activation during the S phase of Saccharomyces cerevisiae.

1980 ◽  
Vol 85 (1) ◽  
pp. 108-115 ◽  
Author(s):  
C J Rivin ◽  
W L Fangman
Keyword(s):  
Saccharomyces Cerevisiae ◽  
Cell Cycle ◽  
Cycle Length ◽  
Replication Fork ◽  
Nitrogen Sources ◽  
S Phase ◽  
Phase Duration ◽  
Yeast Saccharomyces Cerevisiae ◽  
Origin Activation ◽  
Cell Cycle Length

When the growth rate of the yeast Saccharomyces cerevisiae is limited with various nitrogen sources, the duration of the S phase is proportional to cell cycle length over a fourfold range of growth rates (C.J. Rivin and W. L. Fangman, 1980, J. Cell Biol. 85:96-107). Molecular parameters of the S phases of these cells were examined by DNA fiber autoradiography. Changes in replication fork rate account completely for the changes in S-phase duration. No changes in origin-to-origin distances were detected. In addition, it was found that while most adjacent replication origins are activated within a few minutes of each other, new activations occur throughout the S phase.

Post-transcriptional control of the onset of DNA synthesis by an insulin-like growth factor

1984 ◽  
Vol 4 (9) ◽  
pp. 1807-1814
Author(s):  
J Campisi ◽  
A B Pardee
Keyword(s):  
Cell Cycle ◽  
Growth Factors ◽  
Growth Factor ◽  
Dna Synthesis ◽  
Transcriptional Control ◽  
S Phase ◽  
G1 Phase ◽  
Insulin Like Growth Factor ◽  
Igf I ◽  
Translational Inhibition

The control of eucaryotic cell proliferation is governed largely by a series of regulatory events which occur in the G1 phase of the cell cycle. When stimulated to proliferate, quiescent (G0) 3T3 fibroblasts require transcription, rapid translation, and three growth factors for the growth state transition. We examined exponentially growing 3T3 cells to relate the requirements for G1 transit to those necessary for the transition from the G0 to the S phase. Cycling cells in the G1 phase required transcription, rapid translation, and a single growth factor (insulin-like growth factor [IGF] I) to initiate DNA synthesis. IGF I acted post-transcriptionally at a late G1 step. All cells in the G1 phase entered the S phase on schedule if either insulin (hyperphysiological concentration) or IGF I (subnanomolar concentration) was provided as the sole growth factor. In medium lacking all growth factors, only cells within 2 to 3 h of the S phase were able to initiate DNA synthesis. Similarly, cells within 2 to 3 h of the S phase were less dependent on transcription and translation for entry into the S phase. Cells responded very differently to inhibited translation than to growth factor deprivation. Cells in the early and mid-G1 phases did not progress toward the S phase during transcriptional or translational inhibition, and during translational inhibition they actually regressed from the S phase. In the absence of growth factors, however, these cells continued progressing toward the S phase, but still required IGF at a terminal step before initiating DNA synthesis. We conclude that a suboptimal condition causes cells to either progress or regress in the cell cycle rather than freezing them at their initial position. By using synchronized cultures, we also show that in contrast to earlier events, this final, IGF-dependent step did not require new transcription. This result is in contrast to findings that other growth factors induce new transcription. We examined the requirements for G1 transit by using a chemically transformed 3T3 cell line (BPA31 cells) which has lost some but not all ability to regulate its growth. Early- and mid-G1-phase BPA31 cells required transcription and translation to initiate DNA synthesis, although they did not regress from the S phase during translational inhibition. However, these cells did not need IGF for entry into the S phase.

Moxifloxacin Enhances the Antiproliferative and Apoptotic Effects of VP-16 but Inhibits Its Proinflammatory Effects in THP-1 and Jurkat Cells.

Blood ◽  
2005 ◽  
Vol 106 (11) ◽  
pp. 4290-4290
Author(s):  
Ina Fabian ◽  
Debby Haite ◽  
Avital Levitov ◽  
Drora Halperin ◽  
Itamar Shalit
Keyword(s):  
Cell Cycle ◽  
Cell Proliferation ◽  
Cell Cycle Arrest ◽  
Mammalian Cells ◽  
Caspase 3 ◽  
S Phase ◽  
Jurkat Cells ◽  
Cycle Arrest ◽  
Topo Ii ◽  
Number Of Cells

Abstract We previously reported that the fluoroquinolone moxifloxacin (MXF) inhibits NF-kB, mitogen-activated protein kinase activation and the synthesis of proinflammatory cytokines in activated human monocytic cells (AAC48:1974,2004). Since MXF acts on topoisomerase II (Topo II) in mammalian cells, we investigated its effect in combination with another Topo II inhibitor, VP-16, on cell proliferation (by the MTT method), cell cycle, caspase-3 activity and proinflammatory cytokine release in THP-1 and Jurkat cells. THP-1 cells were incubated for 24 h with 0.5–3 μg/ml VP-16 in the presence or absence of 5–20 μg/ml MXF. VP-16 induced a dose dependent decrease in cell proliferation. An additional 2.5-and 1.6-fold decrease in cell proliferation was observed upon incubation of the cells with 0.5 or 1 μg/ml VP-16 and 20 μg/ml MXF, respectively (up to 69% inhibition). To further elucidate the mechanism of the antiproliferative activity of MXF, its effect on cell cycle progression was investigated. In control cultures 1%, 45%,18% and 36% of cells were in G0, G1, S and G2/M phases at 24 h, respectively. In contrast, in cultures treated with 1 μg/ml VP-16 and VP-16+ 20 μg/ml MXF, the number of cells in G1 decreased to 5.4 and 6.5%, respectively, while the number of cells in S phase increased to 25.5 and 42%, respectively and the number of cells in G2/M cells increased to 60 and 44%, respectively. These data provide evidence for S-G2/M cell cycle arrest induced by VP-16 and that addition of MXF shifted the S-G2/M arrest more towards the S phase. Since the antiproliferative effects of MXF could also be attributed to apoptotic cell death in addition to cell cycle arrest, we investigated the effect of the drugs on apoptosis. Using the fluorogenic assay for caspse-3 activity, we show that incubation of THP-1 cells for 6 h with 1.5 μg/ml VP-16 resulted in 630±120 unit/50μg protein of caspase-3 activity while the combination of 1.5 μg/ml VP-16 and 20 μg/ml MXF enhanced caspase-3 activity up to 1700±340 units/50μg protein (vs.233±107 in control cells), indicating that MXF synergises with VP-16 in activation of caspase-3. In Jurkat cells, the addition of 0.5 or 1 μg/ml VP-16, did not affect cell proliferation while in the presence of 20 μg/ml MXF and 1 μg/ml VP-16 there was a 62% decrease in cell proliferation (p<0.05). Exposure of Jurkat cells to 3 μg/ml VP-16 alone resulted in 504±114 units/50μg protein of caspase-3 activity and the addition of 20μg/ml MXF enhanced caspase-3 activity up to 1676± 259 units/50μg protein (vs 226±113 units/50μg protein in control cells). We further examined pro-inflammatory cytokine secretion upon stimulation of THP-1 cells with VP-16, MXF or their combination. VP-16 alone at 3 μg/ml increased IL-8 and TNF-α secretion from THP-1 cells by 2.5 and 1.8-fold respectively. Addition of MXF (5–20 μg/ml) inhibited the two cytokines secretion by 72–77% and 58–72%, respectively. The above combined data indicate that MXF, at clinically attainable concentrations, demonstrates pronounced synergistic effect with VP-16 as an anti-proliferative agent mainly by enhancing caspase-3 activity and apoptosis. At the same time MXF inhibits the pro-inflammatory effects conferred by VP-16 in the tumor cells studied. The clinical significance of the above anti-proliferative and anti-inflammatory effects of MXF in combination with VP-16 should be further investigated in animal models.

295 THE SHAPE OF PORCINE NEURAL PROGENITOR CELL CELLULAR GENEALOGIES REVEALED BY TIME-LAPSE IMAGING

2011 ◽  
Vol 23 (1) ◽  
pp. 245
Author(s):  
I. Faerge ◽  
A. Egeskov-Madsen ◽  
P. Holm
Keyword(s):  
Cell Cycle ◽  
Growth Factor ◽  
Cycle Length ◽  
Individual Cell ◽  
Time Lapse ◽  
Cell Type ◽  
Epidermal Growth ◽  
Cellular Development ◽  
Time Lapse Imaging ◽  
Cell Cycle Length

Porcine neural progenitor cells (pNPC) derived from embryonic stem cells are capable of self-renewal and differentiation into neural and glia lineages, rendering them promising candidates for cell-based therapy of neurodegenerative diseases in a large animal biomedical model. A prerequisite for the successful future therapeutic use of pNPC is a comprehensive characterisation and understanding of the neurogenic process. This is important for learning how to direct cell fates into required proportions of the cell type wanted for the specific brain disease to be treated, and it is crucial for avoiding uncontrolled cell proliferation leading to fatal tumour formations. Time-lapse analysis is a powerful tool to obtain live cell characterisation by analysing individual cell fate. Information on cellular development, division, and differentiation can be composed into a pedigree-like structure denoted as cellular genealogy giving an overview of the proliferation profile of a cell culture and the duration of each cell cycle (Al-Kofani et al. 2006). The aim of the study was to construct cellular genealogies of pNPC and differentiated neural lineages, respectively, by time-lapse imaging to evaluate the effect of external variables observed by changes in the topology of the cellular genealogy. Porcine NPC were derived from epiblast cells isolated from day-9 porcine blastocysts and cultured in DMEM/12, Pen/strep, B27 and N2 with basic fibroblast growth factor and epidermal growth factor, and differentiation was obtained by withdrawal of basic fibroblast growth factor and epidermal growth factor. The state of cellular development of undifferentiated and differentiated pNPC was verified immunohistochemically by the presence of SOX2, NESTIN, TUJI, and GFAB (Rasmussen et al. 2010). The time-lapse images were captured by a Nikon Biostation with a 10× resolution under phase contrast in a humidified chamber at 38°C with 5% CO2, 5% O2, and 90% N2. For each sequence, images were captured at intervals of 10 min in 16 frames. Sequences 1, 2, and 3 constituted passage 15 pNPC, passage 4 pNPC, and presumably differentiated cells, respectively. For each sequence, cell cycle length was calculated after manual tracking of selected cells. The cell cycle length of pNPC is shown in Table 1. Based on these data, cellular genealogies characteristic of each individual cell type have been constructed. Table 1.Cell cycle length of porcine neutral progenitor cells (pNPC) before and after differentiation

scholarly journals Cell cycle length, cell size, and proliferation rate in hydra stem cells

1990 ◽  
Vol 142 (2) ◽  
pp. 392-400 ◽  
Author(s):  
Thomas W. Holstein ◽  
Charles N. David
Keyword(s):  
Cell Cycle ◽  
Stem Cells ◽  
Cell Size ◽  
Cycle Length ◽  
Proliferation Rate ◽  
Cell Cycle Length

scholarly journals Cell cycle phase expansion in nitrogen-limited cultures of Saccharomyces cerevisiae.

1980 ◽  
Vol 85 (1) ◽  
pp. 96-107 ◽  
Author(s):  
C J Rivin ◽  
W L Fangman
Keyword(s):  
Saccharomyces Cerevisiae ◽  
Cell Cycle ◽  
Cycle Length ◽  
Time Lapse ◽  
S Phase ◽  
Cycle Phase ◽  
Yeast Saccharomyces Cerevisiae ◽  
Bud Emergence ◽  
Length Changes ◽  
Cell Cycle Length

The time and coordination of cell cycle events were examined in the budding yeast Saccharomyces cerevisiae. Whole-cell autoradiographic techniques and time-lapse photography were used to measure the duration of the S, G1, and G2 phases, and the cell cycle positions of "start" and bud emergence, in cells whose growth rates were determined by the source of nitrogen. It was observed that the G1, S, and G2 phases underwent a proportional expansion with increasing cell cycle length, with the S phase occupying the middle half of the cell cycle. In each growth condition, start appeared to correspond to the G1 phase/S phase boundary. Bud emergence did not occur until mid S phase. These results show that the rate of transit through all phases of the cell cycle can vary considerably when cell cycle length changes. When cells growing at different rates were arrested in G1, the following synchronous S phase were of the duration expected from the length of S in each asynchronous population. Cells transferred from a poor nitrogen source to a good one after arrest in G1 went through the subsequent S phase at a rate characteristic of the better medium, indicating that cells are not committed in G1 to an S phase of a particular duration.

scholarly journals Post-transcriptional control of the onset of DNA synthesis by an insulin-like growth factor.

1984 ◽  
Vol 4 (9) ◽  
pp. 1807-1814 ◽  
Author(s):  
J Campisi ◽  
A B Pardee
Keyword(s):  
Cell Cycle ◽  
Growth Factors ◽  
Growth Factor ◽  
Dna Synthesis ◽  
Transcriptional Control ◽  
S Phase ◽  
G1 Phase ◽  
Insulin Like Growth Factor ◽  
Igf I ◽  
Translational Inhibition

The control of eucaryotic cell proliferation is governed largely by a series of regulatory events which occur in the G1 phase of the cell cycle. When stimulated to proliferate, quiescent (G0) 3T3 fibroblasts require transcription, rapid translation, and three growth factors for the growth state transition. We examined exponentially growing 3T3 cells to relate the requirements for G1 transit to those necessary for the transition from the G0 to the S phase. Cycling cells in the G1 phase required transcription, rapid translation, and a single growth factor (insulin-like growth factor [IGF] I) to initiate DNA synthesis. IGF I acted post-transcriptionally at a late G1 step. All cells in the G1 phase entered the S phase on schedule if either insulin (hyperphysiological concentration) or IGF I (subnanomolar concentration) was provided as the sole growth factor. In medium lacking all growth factors, only cells within 2 to 3 h of the S phase were able to initiate DNA synthesis. Similarly, cells within 2 to 3 h of the S phase were less dependent on transcription and translation for entry into the S phase. Cells responded very differently to inhibited translation than to growth factor deprivation. Cells in the early and mid-G1 phases did not progress toward the S phase during transcriptional or translational inhibition, and during translational inhibition they actually regressed from the S phase. In the absence of growth factors, however, these cells continued progressing toward the S phase, but still required IGF at a terminal step before initiating DNA synthesis. We conclude that a suboptimal condition causes cells to either progress or regress in the cell cycle rather than freezing them at their initial position. By using synchronized cultures, we also show that in contrast to earlier events, this final, IGF-dependent step did not require new transcription. This result is in contrast to findings that other growth factors induce new transcription. We examined the requirements for G1 transit by using a chemically transformed 3T3 cell line (BPA31 cells) which has lost some but not all ability to regulate its growth. Early- and mid-G1-phase BPA31 cells required transcription and translation to initiate DNA synthesis, although they did not regress from the S phase during translational inhibition. However, these cells did not need IGF for entry into the S phase.

scholarly journals Erythropoietin-specific cell cycle progression in erythroid subclones of the interleukin-3-dependent cell line 32D [published erratum appears in Blood 1993 Jun 1;81(11):3168]

Blood ◽  
1993 ◽  
Vol 81 (4) ◽  
pp. 935-941 ◽  
Author(s):  
Y Shimada ◽  
G Migliaccio ◽  
H Ralph ◽  
AR Migliaccio ◽  
H] Shaw H$[corrected to Ralph
Keyword(s):  
Cell Cycle ◽  
Growth Factors ◽  
Growth Factor ◽  
Cell Lines ◽  
Suicide Rate ◽  
S Phase ◽  
Colony Stimulating Factor ◽  
Gm Csf ◽  
Dependent Cell ◽  
Stimulating Factor

Recently, a variety of growth factor-dependent subclones of the murine interleukin-3 (IL-3)-dependent cell line 32D have been isolated. These subclones include those dependent for growth on erythropoietin (Epo) (32D Epo), granulocyte-macrophage colony-stimulating factor (GM-CSF) (32D GM), or granulocyte colony-stimulating factor (G-CSF) (32D G). 32D Epo1.1 is a revertant of 32D Epo and is capable of growing in IL-3. These cell lines express the differentiation program appropriate to the specific growth factor and depend on the growth factors not only for proliferation but also for survival. To determine how the signal for proliferation is triggered by various growth factors, we examined the DNA histograms and the expression of cell cycle-specific genes in the different cell lines. The cell cycle-specific genes analyzed were myc (early G1), myb (late G1), and the structural genes for the calcium- binding protein 2A9 (middle G1) and histone H3 (G1-S boundary). The DNA histogram analysis of cells in the logarithmic phase of growth showed that approximately 40% of 32D, 32D GM, 32D G, and 32D Epo1.1 (growing in IL-3) were cells with a 2N DNA content (and therefore in G0/G1), and another 40% have a DNA content intermediate between 2N and 4N (in S phase). In contrast, 32D Epo and 32D Epo1.1 (growing in Epo) had fewer cells in the G0/G1 phase of the cell cycle compared with the number of cells that were in the S phase (19% to 31% v 69% to 78%, respectively). Because all the cell lines have comparable doubling times (15 to 18 hours), the cell distribution among the phases of the cell cycle is proportional to the length of the phase. Therefore, cells growing in IL- 3 (32D and 32D Epo1.1), GM-CSF (32D GM), or G-CSF (32D G) progress along the cycle in a manner typical of previously reported nontransformed cell lines. In contrast, cells growing in Epo (32D Epo or 32D Epo1.1) spend relatively less time in G0/G1 and correspondingly more time in S. These data were confirmed by the analysis of the tritiated thymidine (3H-TdR) suicide rate and of the expression of cell cycle-specific genes. The 32D and 32D Epo1.1 cells growing in IL-3 had a suicide rate of congruent to 50%, whereas the suicide rate of 32D Epo and 32D Epo1.1 growing in Epo was higher than 75%.(ABSTRACT TRUNCATED AT 400 WORDS)

Hypoxia induces major effects on cell cycle kinetics and protein expression in Drosophila melanogaster embryos

2005 ◽  
Vol 288 (2) ◽  
pp. R511-R521 ◽  
Author(s):  
R. M. Douglas ◽  
R. Farahani ◽  
P. Morcillo ◽  
A. Kanaan ◽  
T. Xu ◽  
...  
Keyword(s):  
Cell Cycle ◽  
Drosophila Melanogaster ◽  
Cycle Length ◽  
Fluorescent Protein ◽  
Fruit Fly ◽  
Cyclin A ◽  
S Phase ◽  
Green Fluorescent ◽  
Cell Cycle Length

Hypoxia induces a stereotypic response in Drosophila melanogaster embryos: depending on the time of hypoxia, embryos arrest cell cycle activity either at metaphase or just before S phase. To understand the mechanisms underlying hypoxia-induced arrest, two kinds of experiments were conducted. First, embryos carrying a kinesin-green fluorescent protein construct, which permits in vivo confocal microscopic visualization of the cell cycle, showed a dose-response relation between O2 level and cell cycle length. For example, mild hypoxia (Po2 ∼55 Torr) had no apparent effect on cell cycle length, whereas severe hypoxia (Po2 ∼25–35 Torr) or anoxia (Po2 = 0 Torr) arrested the cell cycle. Second, we utilized Drosophila embryos carrying a heat shock promoter driving the string ( cdc25) gene (HS-STG3), which permits synchronization of embryos before the start of mitosis. Under conditions of anoxia, we induced a stabilization or an increase in the expression of several G1/S (e.g., dE2F1, RBF2) and G2/M (e.g., cyclin A, cyclin B, dWee1) proteins. This study suggests that, in fruit fly embryos, 1) there is a dose-dependent relationship between cell cycle length and O2 levels in fruit fly embryos, and 2) stabilized cyclin A and E2F1 are likely to be the mediators of hypoxia-induced arrest at metaphase and pre-S phase.

Sign in / Sign up

Export Citation Format

Share Document