The average cell size as a factor reflecting the interaction of the CHO cells during process of proliferation

Changes in the cell area during cultivation of the CHO line cells were studied using time-lapse technique (start of registration in one day after cell plating). It was established that the size of the daughter cells after mitosis remains lees than the size of the mother cell for a long time (up to 6 h). Nevertheless, the average cell area of the whole population is constant throughout the observation period (up to 18 h). We assume that this phenomenon could be a result of interaction among dividing and not-dividing cells. The experimental data confirming this conclusion are presented.     

Thymidine nucleotide synthesis and catabolism by CHO cells and their changes during the cell cycle

At 0°C, CHO cells efficiently incorporated [³H]thymidine into the nucleotide fraction, but not into DNA. Upon reincubation of asynchronous cultures at 37°C, 15–25% of the radioactivity contained in the cellular nucleotide fraction was released, in the form of thymidine, into the culture medium. At 0°C, however, radioactivity of the nucleotide fraction was retained within the cells. Similarly, dTMP phosphatase (EC 3.1.3.35) in cell extracts was active at 37°C, but not at 0°C, whereas thymidine kinase (EC 2.7.1.21) was active at both temperatures. If synchronous cultures in Gl phase were prelabeled at 0°C and reincubated at 37°C, almost all radioactivity in the nucleotide fraction was released into the medium, whereas in S-phase cultures nearly all radioactivity of the nucleotide fraction was incorporated into DNA. In synchronous S-phase cultures treated with hydroxyurea, radioactivity in the nucleotide fraction was released into the medium at a rate considerably lower than that observed for Gl-phase cells. Rates of endogenous synthesis of thymidine nucleotides were calculated from changes of cellular thymidine nucleotide content, incorporation of thymidine nucleotides into DNA and release of thymidine into the medium during reincubation of prelabeled cultures in thymidine-free medium. The results obtained (see Table III) reveal marked differences between Gl and S phases with respect to the determinants of thymidine nucleotide metabolism.     

cMyc increases cell number through uncoupling of cell division from cell size in CHO cells

Background  

Over the past decades, the increase in maximal cell numbers for the production of mammalian derived biologics has been in a large part due to the development of optimal feeding strategies. Engineering of the cell line is one of probable approaches for increasing cell numbers in bioreactor.     

Steel factor controls midline cell death of primordial germ cells and is essential for their normal proliferation and migration

During germ-cell migration in the mouse, the dynamics of embryo growth cause many germ cells to be left outside the range of chemoattractive signals from the gonad. At E10.5, movie analysis has shown that germ cells remaining in the midline no longer migrate directionally towards the genital ridges, but instead rapidly fragment and disappear. Extragonadal germ cell tumors of infancy, one of the most common neonatal tumors, are thought to arise from midline germ cells that failed to die. This paper addresses the mechanism of midline germ cell death in the mouse. We show that at E10.5, the rate of apoptosis is nearly four-times higher in midline germ cells than those more laterally. Gene expression profiling of purified germ cells suggests this is caused by activation of the intrinsic apoptotic pathway. We then show that germ cell apoptosis in the midline is activated by down-regulation of Steel factor (kit ligand) expression in the midline between E9.5 and E10.5. This is confirmed by the fact that removal of the intrinsic pro-apoptotic protein Bax rescues the germ-cell apoptosis seen in Steel null embryos. Two interesting things are revealed by this: first, germ-cell proliferation does not take place in these embryos after E9.0; second, migration of germ cells is highly abnormal. These data show first that changing expression of Steel factor is required for normal midline germ cell death, and second, that Steel factor is required for normal proliferation and migration of germ cells.     

Total protein content of cells as a factor regulating their proliferation

Proliferation kinetics in stimulated stationary cultures of chick embryo fibroblasts was studied using cytophotometric and autoradiographic methods. Part of 4c cells are blocked at G2 when the culture becomes stationary. A fraction is formed among them which fails to divide in response to proliferation stimulus. Such cells differ from cycling G2 cells by a higher total protein content. Cells with an elevated total protein content are found among 2c cells too, and these also fail to synthesize DNA in response to stimulation to proliferation. It is concluded that the quantity of protein accumulated in the cytoplasm may be one of the factors controlling cell proliferation.     

Tumor necrosis factor is a survival and proliferation factor for human myeloma cells

Interleukin-6 (IL-6) is a major survival factor for malignant plasma cells. In patients with multiple myeloma (MM), cell lines whose survival and proliferation are dependent upon addition of exogenous IL-6 have been obtained. We show here that tumor necrosis factor-alpha (TNF-alpha) is also a survival factor for myeloma cell lines, although less potent than IL-6. The survival activity of TNF-alpha is not affected by anti-IL-6 or anti-gp130 monoclonal antibodies (mAbs). TNF-alpha also induces myeloma cells in the cell cycle and promotes the long-term growth of malignant plasma cell lines. As TNF-alpha is produced in patients with MM and associated with a poor prognosis, these results suggest that anti-TNF-alpha therapies could be useful in this disease.     

Transport of thymidine during the cell cycle in mitotically synchronized CHO cells

The kinetics of total uptake of thymidine into the cell were determined for cells which had been mitotically synchronized, plated into scintillation vials and pulsed with five concentrations of [³H]-thymidine at various times during the cell cycle. From Lineweaver-Burk plots of these rates, V_max and K_m values were determined for the transport of thymidine. The V_max values ranged from a low of 2.0 pmoles/ min/10⁶ cells in mid-G1 to a high of 99.7 in mid-S before a decline in late S and G2. K_m values displayed only a 5-fold range in values.     

Early and delayed changes in potassium transport during the initiation of cell proliferation in CHO culture

Stimulation by serum of cell proliferation in G1-arrested culture of Chinese hamster ovary cells CHO-K1 was accompanied by an early (during the first minutes) and delayed (2-10 h) activation of Na+,K+-ATPase and an increase in cell K+ content from 0.5-0.6 to 0.7-0.8 mmol per gram protein. Isoproterenol acted synergistically with serum in eliciting both early and delayed changes in K+ transport and in stimulating G1----S transition. Isoproterenol alone (without serum) induced a transient increase in K+ influx via Na+,K+-ATPase without changing the cell K+ content or having any mitogenic effect. Theophylline enhanced the serum-induced early activation of Na+,K+-ATPase but inhibited both the delayed increase in cell K+ and the G1----S transition. Early serum-induced increase in K+ transport was not affected by cycloheximide, whereas net accumulation of cell K+ was abolished by the drug. It is concluded that the early and the delayed activation of Na+,K+-ATPase induced by mitogens can be dissociated; the early ionic response is related to the primary transduction of membrane signal, whereas the delayed modulation of ion transport via Na+,K+-ATPase has another function and is associated with cell growth.     

Cell size distribution as a parameter for the predetermination of exponential growth during repeated batch cultivation of CHO cells

The routine measurement of the cell size distribution of a Chinese hamster ovary (CHO) cell population during a repeated batch process enables the predetermination of exponential growth even 24 h before the population enters the log phase, due to a short but significantly increased cell size during the lag phase. A prolongation of the stationary phase causes to progressive limitation in asparagine, serine, and ethanolamine. Such extended limitation influences the duration of the following lag phase and obviously induces a synchronization of the cell population that can be monitored easily by a fast cell size analyzing technique. (c) 1997 John Wiley & Sons, Inc. Biotechnol Bioeng 55: 793-797, 1997.     

Metabolic characterization of a CHO cell size increase phase in fed-batch cultures

Applied Microbiology and Biotechnology - Normally, the growth profile of a CHO cell fed-batch process can be divided into two main phases based on changes in cell concentration, being an...     

An IkappaB-beta COOH terminal region protein is essential for the proliferation of CHO cells under acidic stress

CHO-K1 cells were able to proliferate and maintain pHi homeostasis at pH 6.3. A novel acidic sensitive mutant, AS-5B, which proliferated at pH 7.4 but failed to either proliferate or maintain pHi homeostasis at pH 6.3, was derived from CHO-K1 using a replica method. The acidic-sensitivity of AS-5B was not due to deficiencies in sodium proton exchangers, HCO3- (co)transporters or H+-ATPases. A cDNA clone encoding a COOH terminal region of IkappaB-beta conferred partial acidic-resistance on AS-5B, and the encoded protein was present in CHO-K1, but was nearly absent from AS-5B. Our data demonstrated that the expression of this small protein was essential for the proliferation of CHO cells under acidic stress.     

Stem cell factor is a chemoattractant and a survival factor for CNS stem cells

Migration of neural cells to their final positions is crucial for the correct formation of the central nervous system. Several extrinsic factors are known to be involved in the regulation of neural migration. We asked if stem cell factor (SCF), well known as a chemoattractant and survival factor in the hematopoietic lineage, could elicit similar responses in neural stem cells. For that purpose, a microchemotaxis assay was used to study the effect of SCF on migration of neural stem cells from the embryonic rat cortex. Our results show that SCF-induced chemotaxis and that specific antibodies to SCF or tyrosine kinase inhibitors abolished the migratory response. The SCF-receptor, Kit, was expressed in neural stem cells and in their differentiated progeny. We also show that SCF is a survival factor, but not a mitogen or a differentiation factor for neural stem cells. These data suggest a role for SCF in cell migration and survival in the developing cortex.     

Uridine transport and phosphorylation in 3T3 and CHO cells with induced cell proliferation

In the serum-deficient medium, the cultured Swiss 3T3 and CHO-K1 cells transit to the resting state. The rates of uridine phosphorylation and RNA synthesis in these cells are lowered. After the addition of fresh medium containing 10% serum, cell proliferation is induced. At the early stage of cell entrance into the cell cycle uridine transport through the cell plasma membrane remains unchanged in both cultures. During the 1st hour after serum addition the rate of uridine phosphorylation increases in 3T3 cells to remain practically unchanged in CHO-K1 cells. At this time, RNA synthesis in cells increases almost twofold in both cultures. A correlation has been revealed between the initial level of uridine phosphorylation in 3T3 cells and the percentage of its maximal elevation after serum addition. No such a correlation was observed for CHO-K1 cells. The rate of uridine phosphorylation in arrested CHO-K1 cells is higher than that in 3T3 cells. It has been included that the initial increase of uridine phosphorylation during serum stimulation may be not obligatory for all cell types, but depends on the level of uridine kinase activity before serum addition to the cells.     

Average density and size of microclusters of epidermal growth factor receptors on A431 cells.

For some hormone receptors, the early events of signal transduction depend on their molecular arrangement and interactions at the cell surface. An understanding of the mechanism of signal transduction in general needs a careful analysis of the receptor distribution. Here, we present the first quantitative measurement of epidermal growth factor receptor distribution on A431 cells obtained by scanning fluorescence correlation spectroscopy. Prior to epidermal growth factor binding, the A431 cell membrane presents an average surface density of 7.7-8.4 microclusters/microns 2, each containing an average of 130 receptors.     

Glial cell line-derived neurotrophic factor influences proliferation of osteoblastic cells

Little is known about the role of neurotrophic growth factors in bone metabolism. This study investigated the short-term effects of glial cell line-derived neurotrophic factor (GDNF) on calvarial-derived MC3T3-E1 osteoblasts. MC3T3-E1 expressed GDNF as well as its canonical receptors, GFRα1 and RET. Addition of recombinant GDNF to cultures in serum-containing medium modestly inhibited cell growth at high concentrations; however, under serum-free culture conditions GDNF dose-dependently increased cell proliferation. GDNF effects on cell growth were inversely correlated with its effect on alkaline phosphatase (AlP) activity showing a significant dose-dependent inhibition of relative AlP activity with increasing concentrations of GDNF in serum-free culture medium. Live/dead and lactate dehydrogenase assays demonstrated that GDNF did not significantly affect cell death or survival under serum-containing and serum-free conditions. The effect of GDNF on cell growth was abolished in the presence of inhibitors to GFRα1 and RET indicating that GDNF stimulated calvarial osteoblasts via its canonical receptors. Finally, this study found that GDNF synergistically increased tumor necrosis factor-α (TNF-α)-stimulated MC3T3-E1 cell growth suggesting that GDNF interacted with TNF-α-induced signaling in osteoblastic cells. In conclusion, this study provides evidence for a direct, receptor-mediated effect of GDNF on osteoblasts highlighting a novel role for GDNF in bone physiology.