Increase of epidermal growth factor-stimulated cell-cycle progression and induction of thermotolerance by heat shock: temperature and time relationship

Culturing characteristics of Hanwoo myosatellite cells and C2C12 cells incubated at 37°C and 39°C for cultured meat

To improve culture efficiency of Hanwoo myosatellite cells, these cells were cultured at different temperatures. Hanwoo myosatellite cells were compared with C2C12 cells to observe proliferation and differentiation at culture temperatures of 37°C and 39°C and determine the possibility of using them as cultured meat. Immunofluorescence staining using Pax7 and Hoechst, both cells cultured at 37°C proliferated better than cultured at 39°C (p < 0.05). When differentiated cells were stained with myosin and Hoechst, there was no significant difference in myotube thickness and Fusion index (p > 0.05). In Western blotting analysis, Hanwoo myosatellite cells were no significant difference in the expression of myosin between cells differentiated at the two temperatures (p > 0.05). C2C12 cells were no significant difference in the expression of myosin between cells differentiated at the two temperatures (p > 0.05). In reverse transcription and quantitative polymerase chain reaction (RT-qPCR) analysis, Hanwoo myosatellite cells cultured at 39°C had significantly (p < 0.05) higher expression levels of MyHC, MYF6, and MB than those cultured at 37°C. C2C12 cells cultured at 39°C showed significantly (p < 0.05) higher expression levels of MYOG and MB than those cultured at 37°C. To increase culture efficiency of Hanwoo myosatellite cells, proliferating at 37°C and differentiating at 39°C are appropriate. Since results of temperature differences of Hanwoo myosatellite cells were similar to those of C2C12 cells, they could be used as a reference for producing cultured meat using Hanwoo satellite cells.

Serum-stimulated cell cycle progression and stress protein synthesis in C3H10T1/2 fibroblasts treated with sodium arsenite

In this work, we demonstrated that a nonlethal dose of arsenite administered to quiescent C3H10T1/2 fibroblasts can enhance the mitogenic effect of suboptimal concentrations of serum. The mitogenic effect was dependent on the serum concentration and on the time interval between the administration of arsenite and that of serum. This suggests that mitogen sensitivity changes in time after arsenite treatment. It is shown that the concentrations of arsenite that enhance the mitogenic effect of serum also increase the mRNA levels of c-fos, HSP68, and HSP84 and induce the specific synthesis of Heat Shock Proteins (HSPs). The physiological significance of this phenomenon is most likely to counteract the long-term toxic effect of arsenite by early induction of compensation for cell loss.

Responsiveness of the increase in C-fos mRNA levels depends on the inducer and the cell's past

In this paper we show that in C3H10T1/2 mouse fibroblasts, the inducibility of c-fos mRNA by heat shock or serum addition is strongly dependent on the cell's past. Four hours after a heat shock, a time point where the induced c-fos mRNA has disappeared, c-fos mRNA could not be induced again by a second heat shock. Four hours after serum addition, by which c-fos was induced, a second serum addition also failed to induce c-fos mRNA again. When, however, serum was added 4 hours after heat shock or heat shock was given 4 hours after serum addition, levels of c-fos mRNA could be enhanced again. The induction by serum of c-fos mRNA levels in thermotolerant cells might be related to their increased stimulation of DNA synthesis as compared to control cells.

Thermal sensitivity and kinetics of thermotolerance in bovine aortic endothelial cells in culture

The effect of heat on the clonogenicity of bovine aortic endothelial (BAE) cells in vitro was measured. Continuous heating of cells at 43 degrees C or 43.5 degrees C produced survival curves exhibiting thermoresistant tails. When heated at 44 degrees C the survival curve of BAE cells was exponential except for a small shoulder. The BAE cells heated at 44 degrees C and 45 degrees C had D0 values of 33 min and 19 min, respectively. The development of thermotolerance in BAE cells was studied by measuring the sensitivity of cells to a 44 degrees C heating at various times following a priming heat treatment at 43 degrees C or 44 degrees C for 30 min. The thermotolerance ratio in BAE cells preheated at 43 degrees C for 30 min reached a peak of 3.8 at 3 h and declined to 1.9 at 24 h after the prime heating. After prime heating at 44 degrees C for 30 min the thermotolerance ratio increased rapidly to 5.4 in 5 h, remained elevated at 12 h and then declined to a value of 2.1 at 24 h. Thermotolerance in endothelial cells may be partially responsible for the thermotolerance in blood vessels of normal tissues and tumours.

Increase of thermoresistance after growth stimulation of resting Reuber H35 hepatoma cells. Alteration of nuclear characteristics, non-histone chromosomal protein phosphorylation and basal heat shock protein synthesis

In this paper we demonstrate an increase in thermoresistance of resting Reuber H35 cells upon growth stimulation by serum-containing medium: late G1/early S-phase cells were thermoresistant as compared with G0 phase cells. Increase of thermoresistance during early cell cycle runs parallel with increased tolerance of structural and molecular properties of the cell nucleus. Nuclear shape and chromatin structuring became thermotolerant as determined by geometric and densitometric analysis of Feulgen-stained nuclei. Moreover, increased tolerance was demonstrated by means of the capability for endogenous phosphorylation of isolated non-histone chromosomal proteins (NHCPs). We discuss the molecular basis for this increased thermoresistance after growth stimulation and make a comparison with induction of 'acquired thermotolerance' such as has been observed in studies on fractionated hyperthermia. Both after growth stimulation and after heat shock, an increase of endogenous phosphorylation capacity of isolated NHCPs was observed, while a main enhancement of phosphorylation was found for a NHCP of Mr 95,000. Moreover, the basal synthesis of proteins inducible by heat shock (heat shock proteins) and indicated as HSP65, HSP68 and HSP84 was enhanced in thermoresistant late G1/early S phase cells as compared with thermo-sensitive G0 phase cells. A role for chromatin structuring, NHCP phosphorylation and HSPs in the regulation of thermosensitivity and cell cycling is discussed.

Heat-induced alterations in cell membrane permeability and cell inactivation of transformed mouse fibroblasts

Hyperthermia, has recently been extended in many permutations as a modality of anticancer treatment, but the mechanisms underlying heat-induced cell inactivation are poorly understood. In this study, the role of the cell permeability barrier in the process of heat cytotoxicity are examined. Changes in cell membrane permeability were determined by following the efflux of normally impermeant metabolites, e.g. nucleotides, in cultures of Swiss mouse 3T3 cells, and their transformed derivatives, 3T6 cells. The increase in cell membrane permeability as a function of temperature and exposure duration was found to be characterized by a sigmoid curve, with a threshold value, above which the permeability markedly increased. A correlation was found between cell membrane permeabilization and cell inactivation. Both heat-induced permeabilization and heat cytotoxicity were more pronounced in the transformed cells, as compared to their untransformed counterparts. The temperature-dependent permeabilization was more effective in the presence of the ionophore amphotericin B. The data suggest that heat-induced lesion in the cell membrane has a major role in hyperthermia cytotoxicity.

Effect of serum on heat response of synchronized mouse neuroblastoma cells: protection of cell cycle progression, protein synthesis and survival

The effect of serum and temperature elevation on proliferation has been studied in synchronized mouse neuroblastoma (Neuro-2A) cells. The effects of serum were studied on the induction of (a) mitotic delay due to a non-lethal heat treatment (30 min at 42.7 degrees C) and (b) the loss of colony-forming capacity after a more extensive heat treatment (45 min at 44 degrees C or a continuous 42.7 degrees C heat treatment). The following results were obtained. Under conditions of serum depletion, cell cycle extension of heated G1 phase cells was more than that of heated G2 phase cells. Serum protected against heat-induced alterations of cell cycle progression in G1- but not in G2 phase cells. This effect of serum could be mimicked by a supplement to the medium of human transferrin, bovine pancreas insulin and selenium, and was correlated with protection of protein synthesis. Serum also affected heat-induced cell killing. Under conditions of serum depletion, G1 phase cells were more resistant to heat compared to G2 cells. The presence of serum during heat treatment further increased the thermoresistance of G1 phase cells, but did not affect sensitivity of G2 phase cells. This effect of serum could not be mimicked by a supplement of transferrin, insulin and selenium. These results indicate that serum protects G1 phase cells for heat-induced changes of cell cycle progression as well as on cell survival, but the mechanisms involved in both phenomena seem to be different.