Host cell variations resulting from F plasmid-controlled replication of the Escherichia coli chromosome.

Cell size and DNA concentration were measured in Escherichia coli K-12 ET64. This strain carries a dnaA (Ts) mutation that has been suppressed by the insertion of the F plasmid into the chromosome. ET64 can grow in a balanced steady state of exponential growth at the restrictive temperature for its dnaA allele (39 degrees C), in which chromosome replication is controlled by the F plasmid, and at the permissive temperature (30 degrees C), in which chromosome replication is controlled by dnaA-oriC. When cells grown at the indicated temperatures were compared, it was observed that at 39 degrees C, the cell mass increased and the amount of cellular DNA decreased slightly; therefore, the DNA concentration was strongly reduced. These changes can neither be explained by the reduction of the generation time (which is only 10-15%) nor from observed changes in the replication time and in the time between DNA synthesis termination and cell division. Variations were mainly due to the increase in cell mass per origin of replication, at initiation, in cells grown at 39 degrees C. Control of chromosome replication by the F plasmid appears to be the reason for the increase in the initiation mass. Other possible causes, such as the modification of growth temperature, the generation time, or both, were discarded. These observations suggest that at one growth rate, the F plasmid replicates at a particular cell mass to F particle number ratio, and that this ratio is higher than the cell mass to oriC ratio at the initiation of chromosome replication. This fact might be significant to coordinate the replication of two different replicons in the same cell.     

Effect of culture pH on erythropoietin production by Chinese hamster ovary cells grown in suspension at 32.5 and 37.0 degrees C

To investigate the effect of culture pH in the range of 6.85-7.80 on cell growth and erythropoietin (EPO) production at 32.5 and 37.0 degrees C, serum-free suspension cultures of recombinant CHO cells (rCHO) were performed in a bioreactor with pH control. Lowering culture temperature from 37.0 to 32.5 degrees C suppressed cell growth, but cell viability remained high for a longer culture period. Regardless of culture temperature, the highest specific growth rate (mu) and maximum viable cell concentration were obtained at pH values of 7.00 and 7.20, respectively. Like mu, the specific consumption rates of glucose and glutamine decreased at 32.5 degrees C compared to 37.0 degrees C. In addition, they increased with increasing culture pH. Culture pH at 32.5 degrees C affected specific EPO productivity (q(EPO)) in a different fashion from that at 37 degrees C. At 37 degrees C, the q(EPO) was fairly constant in the pH range of 6.85-7.80, while at 32.5 degrees C, the q(EPO) was significantly influenced by culture pH. The highest q(EPO) was obtained at pH 7.00 and 32.5 degrees C, and its value was approximately 1.5-fold higher than that at pH 7.00 and 37.0 degrees C. The proportion of acidic EPO isoforms, which is a critical factor for high in vivo biological activity of EPO, was highest in the stationary phase of growth, regardless of culture temperature and pH. Although cell viability rapidly decreased in death phase at both 32.5 and 37.0 degrees C, the significant degradation of produced EPO, probably by the action of proteases released from lysed cells, was observed only at 37.0 degrees C. Taken together, through the optimization of culture temperature and pH, a 3-fold increase in maximum EPO concentration and a 1.4-fold increase in volumetric productivity were obtained at pH 7.00 and 32.5 degrees C when compared with those at 37.0 degrees C. These results demonstrate the importance of optimization of culture temperature and pH for enhancing EPO production in serum-free, suspension culture of rCHO cells.     

Evidence for two domains of growth temperature for the psychrotrophic bacterium Pseudomonas fluorescens MF0.

The variations in the maximal specific growth rate of the psychrotrophic bacterium Pseudomonas fluorescens MF0 with respect to temperature were studied between 0 and 30 degrees C (optimal for growth). The Arrhenius plot showed a drastic change in slope at the intermediate temperature of 17 degrees C. Over the cold domain from 0 to 17 degrees C, the temperature characteristic was twofold higher than over the suboptimal domain from 17 to 30 degrees C. The macromolecular composition of exponentially growing cells was invariant over the entire range from 0 to 30 degrees C. Variations of temperature and growth rate were independently investigated through chemostat experiments in order to characterize their respective effects on cell macromolecular composition and size. The effect of growth rate in this psychrotrophic strain is identical to that of all other bacteria assayed so far. In contrast, an original biphasic variation of total protein concentration was demonstrated in strain MF0 with respect to temperature, with a maximum at 17 to 20 degrees C. Indeed, increasing the temperature in the chemostat resulted in a biphasic decrease in the net protein production rate: a very slight decrease below 17 degrees C and a much larger decrease from 17 to 28 degrees C. These results could signify an increase in the cellular protein degradation rate with increasing temperature, especially above 17 degrees C.     

Effect of temperature dependent changes in mechanical stability of red cell aggregates on relative apparent whole blood viscosity

As the temperature dependence of relative apparent whole blood viscosity eta rel is still controversial, the relation between the temperature dependence of red cell aggregation (RCA) and that of eta rel was examined in normal donors and in patients with venous ulcers of the leg. Apparent whole blood viscosity was measured in the DEER-rheometer (0.01 Pa less than tau less than 2.9 Pa) at 10 degrees C, 20 degrees C, 30 degrees C and 37 degrees C. The instrument was calibrated for each temperature to correct for changes in viscometer geometry. Simultaneously the minimal shear stress tau Tmin to keep RCA dispersed was determined by photometric aggregometry. eta rel was found to increase with decreasing temperature. By basing the relative cold induced increase in eta rel on the state of RCA as defined by the ratio of tau/tau Tmin the relation between both features is verified: With increasing RCA the cold induced increase in eta rel is progressively enhanced.     

大肠杆菌生长温度、膜脂肪酸组成和压力抗性之间的关系

通过对大肠杆菌生长温度、膜脂肪酸组成和压力抗性之间关系研究发现,10℃培养,对数期细胞有最大的压力抗性,随着培养温度的升高直到4 5℃,压力抗性呈下降的趋势;相反,10℃培养,稳定期的细胞对压力最敏感,随着培养温度的升高,压力抗性呈增加趋势,30～37℃时达到最大,之后到4 5℃有下降。对数期和稳定期细胞膜脂中不饱和脂肪酸的组成随温度的上升而下降,这与从全细胞中抽提的磷脂的熔点密切相关。因此,对数期细胞压力抗性随着膜流动性的增大而升高;但稳定期细胞,膜流动性与压力抗性之间不存在简单的对应变化关系     

Maximizing interferon-gamma production by Chinese hamster ovary cells through temperature shift optimization: experimental and modeling

The Chinese hamster ovary (CHO) cell line producing interferon-gamma (IFN-gamma) exhibits a 2-fold increase in specific productivity when grown at 32 degrees C compared to 37 degrees C. Low temperature also causes growth arrest, meaning that the cell density is significantly lower at 32 degrees C, nutrients are consumed at a slower rate and the batch culture can be run for a longer period of time prior to the onset of cell death. At the end of the batch, product concentration is doubled at the low temperature. However, the batch time is nearly doubled as well, and this causes volumetric productivity to only marginally improve by using low temperature. One approach to alleviate the problem of slow growth at low temperature is to utilize a biphasic process, wherein cells are cultured at 37 degrees C for a period of time in order to obtain reasonably high cell density and then the temperature is shifted to 32 degrees C to achieve high specific productivity. Using this approach, it is hypothesized that IFN-gamma volumetric productivity would be maximized. We developed and validated a model for predicting the optimal point in time at which to shift the culture temperature from 37 degrees C to 32 degrees C. It was found that by shifting the temperature after 3 days of growth, the IFN-gamma volumetric productivity is increased by 40% compared to growth and production at 32 degrees C and by 90% compared to 37 degrees C, without any decrease in total production relative to culturing at 32 degrees C alone. The modeling framework presented here is applicable for optimizing controlled proliferation processes in general.     

Alterations in the nuclear matrix protein mass correlate with heat-induced inhibition of DNA single-strand-break repair

The total protein mass co-isolating with the nuclear matrix or nucleoid from Chinese hamster ovary (CHO) cells was observed to increase in heated cells as a function of increasing exposure temperature between 43 degrees C and 45 degrees C or of exposure time at any temperature. The sedimentation distance of the CHO cell nucleoid in sucrose gradients increased with increasing exposure time at 45 degrees C. Both these nuclear alterations correlated in a log-linear manner with heat-induced inhibition of DNA strand break repair. A two-fold threshold increase in nuclear matrix protein mass preceded any substantial inhibition of repair of DNA single-strand breaks. When preheated cells (45 degrees C for 15 min) were incubated at 37 degrees C the nuclear matrix protein mass and nucleoid sedimentation recovered with a half-time of about 5 h, while DNA single-strand-break repair recovered with a half-time of about 2 h. When preheated cells were placed at 41 degrees C (step-down heating; SDH) a further increase was observed in the nuclear matrix protein mass and the half-time of DNA strand break repair, while nucleoid sedimentation recovered toward control values. These results implicate alterations in the protein mass of the nuclear matrix in heat-induced inhibition of repair of DNA single-strand breaks.     

DNA, RNA, and protein biosynthesis in cells of Yersinia pseudotuberculosis at various cultivation temperatures

Y. pseudotuberculosis cells cultivated at temperatures of 37 degrees C and 8 degrees C were found to be capable of incorporating exogenic precursors into DNA, RNA and protein. The linear growth of thymidine incorporation occurred during 8 hours of cultivation at 37 degrees C, then the amount of the incorporated label decreased. At 8 degrees C the level of thymidine incorporation into DNA gradually increased for 80 hours and longer, but not reaching the level of incorporation observed at 37 degrees C. The incorporation of uridine into RNA of Y. pseudotuberculosis cells reached its maximum after 4 hours of cultivation at 37 degrees C, at a lower temperature of cultivation the incorporation of uridine into bacterial cells was almost linear, though slower, and lasted for 20 hours. The content of radioactive alanine in Y. pseudotuberculosis protein increased during 16 hours of cultivation at a high temperature, while at 8 degrees C the growth of the incorporation level lasted for at least 40 hours. For all precursors under study the incorporation rate into the cell biopolymers at the initial stages of cultivation was higher at 37 degrees C, than at a lower temperature.     

Effects of temperature on baseline and genotoxicant-induced DNA damage in haemocytes of Dreissena polymorpha

The potential application of the Comet assay for monitoring genotoxicity in the freshwater mussel Dreissena polymorpha was explored and a preliminary investigation was undertaken of the baseline levels of DNA damage in mussel haemocytes of animals kept at different temperatures. In addition, in vitro cell sensitivity against genotoxicants was assessed in relation to increasing temperatures. The mussels were kept at four different constant temperatures (4, 18, 28 and 37 degrees C) for 15 h. The haemocytes withdrawn were treated in vitro with melphalan, as a model genotoxic compound, or sodium hypochlorite, a common water disinfectant capable of producing mutagenic/carcinogenic by-products, at the established temperatures for 1h. The data obtained in vivo, in cells directly withdrawn from the mussels showed a significant (P<0.001, Student's t test) inter-individual variability, probably due to genetic and epigenetic factors and an increasing amount of DNA damage at increasing temperature. Mussel haemocytes showed a clear dose-response effect after in vitro melphalan treatment. Hypochlorite treatment also significantly increased DNA migration: the damage was temperature dependent, with a similar increase at 4 and 28 degrees C and a minimum level at 18 degrees C. This study demonstrates the potential application of the Comet assay to haemocytes of D. polymorpha. However, these findings suggest that temperature could alter both DNA damage baseline levels in untreated animals and cell sensitivity towards environmental pollutants in in vitro conditions. Therefore, more information is needed about seasonal variations and the natural background levels of DNA damage in mussels living in the wild, before they are used for the monitoring of genotoxic effects in aquatic environments.     

Early melting of supercoiled DNA.

Denaturing gradient gel electrophoresis (formamide with urea) has been used to study the melting of supercoiled DNA. A linear gradient of denaturant concentration proportional to a 25 degrees C linear increase of temperature (Teff) from the left to the right edge of the gel was created perpendicular to DNA migration. The mobility of supercoiled DNA molecules was shown to drop to the level of relaxed molecules a long way (5-30 degrees C) before linear DNA began to melt. The further increase of Teff, including the melting range for linear molecules, caused no appreciable changes in the mobility of relaxed molecules. The transition curves are S-shaped for all the topoisomers, and an increase of superhelicity shifts the transition towards lower Teff values. The analysis of the results indicates that the observed relaxation of superhelical molecules is due to denatured region forming in them, their size increasing with the topoisomer number.     

Conditions for maximum enflagellation in Naegleria fowleri

Ameba to flagellate transformation in Naegleria fowleri (Lovell strain) was affected by growth temperature, phase of growth, strain of ameba, culture agitation, enflagellation temperature, enflagellation diluent, and cell concentration. Amebae transformed best when they were grown without agitation and enflagellated with agitation. Regardless of growth temperature (23 degrees, 30 degrees, 37 degrees, and 42 degrees C were tested), amebae transformed best at 37 degrees C. Enflagellation was greatest for cells harvested between 24 h (mid-exponential) and 84 h (late stationary) of growth.     

Analysis of the tomato fruit growth response to temperature and plant fruit load in relation to cell division, cell expansion and DNA endoreduplication

BACKGROUND AND AIMS: To better understand the regulation of fruit growth in response to environmental factors, the effects of temperature and plant fruit load on cell number, cell size and DNA endoreduplication were analysed. METHODS: Plants were grown at 20/20 degrees C, 25/25 degrees C and 25/20 degrees C day/night temperatures, and inflorescences were pruned to two ('2F') or five ('5F') flowers. KEY RESULTS AND CONCLUSIONS: Despite a lower fruit growth rate at 20/20 degrees C, temperature did not affect final fruit size because of the compensation between cell number and size. The higher cell number at 20/20 degrees C (9.0 x 10(6) against 7.9 x 10(6) at 25/25 degrees C and 7.7 x 10(6) at 25/20 degrees C) resulted from an extended period of cell division, and the smaller cell size was due to a shorter period of expansion rather than a lower expansion rate. By contrast, the lower fruit growth rate and size of 5F fruits compared with 2F fruits resulted from the slow down of cell expansion, whereas the number of cells was hardly affected in the proximal fruit. However, within the inflorescence the decreasing gradient of fruit size from proximal to distal fruits was due to a decrease in cell number with similar cell size. Fruit size variations within each treatment were always positively correlated to variations in cell number, but not in cell size. Negative correlations between cell size and cell number suggested that cells of tomato pericarp can be seen as a population of competing sinks. Mean ploidy was slightly delayed and reduced in 5F fruits compared with 2F fruits. It was highest at 25/25 degrees C and lowest at 25/20 degrees C. Treatments did not affect ploidy and cell size in similar ways, but within each treatment, positive correlations existed between mean ploidy and cell size, though significant only in the 2F-25/20 treatment.     

Loss of secretory response of rat basophilic leukemia (2H3) cells at 40 degrees C is associated with reversible suppression of inositol phospholipid breakdown and calcium signals

Antigen-induced stimulatory signals as well as histamine secretion from the RBL-2H3 cells were found to be highly temperature dependent. There was no hydrolysis of inositol phospholipids, increase in cytosol calcium concentration (calcium signal), or secretion upon antigen stimulation at temperatures below 20 degrees C. At higher temperatures (i.e., 20 to 37 degrees C), all responses increased in extent with increase in temperature. Temperatures of 38 degrees C or higher, however, resulted in a marked decline in all responses, until no responses were observed at 40 to 42 degrees C. As indicated by the decay in calcium signal, the duration of response was also temperature dependent. The response was of long duration at 30 to 32 degrees C, but it became progressively more transient as the temperature was increased from 32 to 40 degrees C. The effects of low or high temperature were fully reversible. For example, in the presence of antigen, stimulatory signals immediately appeared once the temperature was decreased from 40 to 37 degrees C. Although the diminished responses could be explained, in part, by a reduction in rates of IgE receptor aggregation and phospholipase C activity, the reductions were insufficient to account for complete loss of activity at 40 degrees C. We conclude that generation of intracellular signals in 2H3 cells is blocked by quite small elevations in temperature above 37 degrees C, possibly as consequence of changes in membrane fluidity.     

Monitoring of temperature effects on animal cell metabolism in a packed bed process

Animal cell (Chinese Hamster Ovary) concentration was determined on-line in a packed bed process using dielectric spectroscopy. This enabled the evaluation of the effect of temperature on specific metabolic rates during 3 months of continuous culture. The effect of low cultivation temperature on cell growth and metabolism was monitored, and the data were used for process development. At 37 degrees C cells grew exponentially with a specific growth rate of 0.038 d-1 and specific glucose uptake and lactate production rates increased continually. Reduction of the temperature to 33.5 degrees C resulted in a lowering of these metabolic rates while having no effect on cell proliferation. Subsequent reduction of the temperature to 32 degrees C resulted in stabilization of the cell concentration at a high density (3.6 x 10(7) cell per mL of packed bed). In addition, the specific production rate of the protein of interest increased by a factor of 6 compared to the value at 37 degrees C. During the stationary phase at 32 degrees C, all other specific metabolic rates could be controlled to low and constant levels.     

Adaptation of Chinese hamster ovary cells to low culture temperature: cell growth and recombinant protein production

Recombinant Chinese hamster ovary (rCHO) cells producing erythropoietin (EPO) and rCHO cells producing follicle-stimulating hormone (FSH) showed a significant increase in specific productivity (q) when grown at 32 degrees C compared to 37 degrees C. However, low culture temperature suppressed cell growth, and therefore, did not increase volumetric productivity as much as q. In an attempt to increase the volumetric productivity through improvement of hypothermic growth, EPO producing rCHO (CHO-EPO) cells and FSH producing rCHO (CHO-FSH) cells were adapted at 32 degrees C in a repeated batch mode using spinner flasks. Cell growth of both CHO-EPO and CHO-FSH gradually improved during adaptation at 32 degrees C. Specific growth rates of CHO-EPO and CHO-FSH cells at 32 degrees C, through adaptation, were increased by 73% and 20%, respectively. During adaptation at 32 degrees C, mRNA levels of cold-inducible RNA-binding protein (CIRP) of both rCHO cell lines did not change significantly, suggesting that CIRP expression may not be the only cause for growth suppression at low culture temperature. Unlike cell growth, the recombinant protein production of both rCHO cell lines was not increased during adaptation due to decreased specific productivities. The specific EPO productivity and specific FSH productivity were decreased by 49% and 22%, respectively. Southern blot analyses showed that the decreased specific productivities were not due to the loss of foreign gene copies. Taken together, improvement of hypothermic cell growth by adaptation does not appear to be applicable for enhanced recombinant protein production, since specific productivity decreases during adaptation to the low culture temperature.     

Induction of the heat shock protein ClpB affects cold acclimation in the cyanobacterium Synechococcus sp. strain PCC 7942.

The heat shock protein ClpB is essential for acquired thermotolerance in cyanobacteria and eukaryotes and belongs to a diverse group of polypeptides which function as molecular chaperones. In this study we show that ClpB is also strongly induced during moderate cold stress in the unicellular cyanobacterium Synechococcus sp. strain PCC 7942. A fivefold increase in ClpB (92 kDa) content occurred when cells were acclimated to 25 degrees C over 24 h after being shifted from the optimal growth temperature of 37 degrees C. A corresponding increase occurred for the smaller ClpB' (78 kDa), which arises from a second translational start within the clpB gene of prokaryotes. Shifts to more extreme cold (i.e., 20 and 15 degrees C) progressively decreased the level of ClpB induction, presumably due to retardation of protein synthesis within this relatively cold-sensitive strain. Inactivation of clpB in Synechococcus sp. increased the extent of inhibition of photosynthesis upon the shift to 25 degrees C and markedly reduced the mutant's ability to acclimate to the new temperature regime, with a threefold drop in growth rate. Furthermore, around 30% fewer delta clpB cells survived the shift to 25 degrees C after 24 h compared to the wild type, and more of the mutant cells were also arrested during cell division at 25 degrees C, remaining attached after septum formation. Development of a cold thermotolerance assay based on cell survival clearly demonstrated that wild-type cells could acquire substantial resistance to the nonpermissive temperature of 15 degrees C by being pre-exposed to 25 degrees C. The same level of cold thermotolerance, however, occurred in the delta clpB strain, indicating ClpB induction is not necessary for this form of thermal resistance in Synechococcus spp. Overall, our results demonstrate that the induction of ClpB contributes significantly to the acclimation process of cyanobacteria to permissive low temperatures.     

Differences in optimal pH and temperature for cell growth and antibody production between two Chinese hamster ovary clones derived from the same parental clone

To investigate clonal variations of recombinant Chinese hamster ovary (rCHO) clones in response to culture pH and temperature, serum-free suspension cultures of two antibody-producing CHO clones (clones A and B), which were isolated from the same parental clone by the limiting dilution method, were performed in a bioreactor at pH values in the range of 6.8-7.6, and two different temperatures, 33 degrees C and 37 degrees C. In regard to cell growth, clone A and clone B displayed similar responses to temperature, although their degree of response differed. In contrast, clones A and B displayed different responses to temperature in regard to antibody production. In the case of clone A, no significant increase in maximum antibody concentration was achieved by lowering the culture temperature. The maximum antibody concentration obtained at 33 degrees C (pH 7.4) and 37 degrees C (pH 7.0) were 82.0 +/- 2.6 and 73.2 +/- 4.1 microg/ml, respectively. On the other hand, in the case of clone B, an approximately 2.5-fold increase in maximum antibody concentration was achieved by lowering the culture temperature. The enhanced maximum antibody concentration of clone B at 33 degrees C (132.6 +/- 14.9 microg/ml at pH 7.2) was due to not only enhanced specific antibody productivity but also to prolonged culture longevity. At 33 degrees C, the culture longevity of clone A also improved, but not as much as that of clone B. Taken together, CHO clones derived from the same parental clone displayed quite different responses to culture temperature and pH with regards antibody production, suggesting that environmental parameters such as temperature and pH should be optimized for each CHO clone.     

Elevated expression temperature in a mesophilic host results in increased secretion of a hyperthermophilic enzyme and decreased cell stress

Efficient protein folding and trafficking are essential for high-level production of secretory proteins. Slow folding or misfolding of proteins can lead to secretory bottlenecks that reduce productivity. We previously examined the expression of a hyperthermophilic tetramer Pyrococcus furiosus beta-glucosidase in the yeast Saccharomyces cerevisiae. A secretory bottleneck was found in the endoplasmic reticulum, presumably due to beta-glucosidase misfolding. By increasing expression temperature from 30 degrees C up to 40 degrees C, secretion yields increased by as much as 440% per cell to greater than 100 mg/L at 37 degrees C. We examined the effect of temperature on beta-glucosidase folding and secretion and determined that increased expression temperature decreased intracellularly retained, insoluble beta-glucosidase. Likewise, stress on the cell caused by beta-glucosidase expression was found to be greatly reduced at 37 degrees C compared to 30 degrees C. Levels of the abundant endoplasmic reticulum chaperone, BiP, were relatively unchanged at these temperatures during heterologous expression. Using cycloheximide to inhibit new protein synthesis, we determined that the increase in secretion is likely due to the effect of temperature on the beta-glucosidase itself rather than the cell's response to elevated temperatures. We believe that this is the first evidence of in vivo effects of temperature on the secretion of hyperthermophilic proteins.     

The cellular apoptosis of murine BW5147 thymoma during cold shock]

The mode of T-lymphoma cell death induced by cold shock was studied. The rewarming of cells at 37 degrees C following a brief period of cold (0 degrees C) resulted in internucleosomal DNA fragmentation. The cells underwent cold shock-mediated apoptosis only at a reduced (2%) serum concentration. The apoptosis was not blocked by macromolecular synthesis inhibitors such as cycloheximide and antinomycin D, or by Quin-2. EGTA per se was responsible for the initiation of cell death. Colchicine also induced internucleosomal fragmentation of DNA. Our findings suggest that cold shock induced apoptosis is associated with low temperature mediated disruption of microtubules. The role of Ca2+ and growth factors in cold shock induced cell death is discussed.