Temperature control of growth and productivity in mutant Chinese hamster ovary cells synthesizing a recombinant protein

The use of a temperature switch to control the growth and productivity of temperature-sensitive (ts) mutants was investigated to extend the productive life span of recombinant Chinese hamster ovary (CHO) cells in batch culture. Bromodeoxyuridine was used at 39 degrees C to select mutagenized CHO-K1 cells, which resulted in the isolation of 31 temperature-sensitive mutants that were growth inhibited at 39 degrees C. Two of these mutants were successfully transfected with the gene for tissue inhibitor of metalloproteinases (TIMP) using glutamine synthetase amplification, and a permanent recombinant cell line established (5G1-B1) that maintains the ts phenotype.Continuous exposure to the nonpermissive temperature (npt) of 39 degrees C led to a rapid decline in cell viability. However, a temperature regime using alternating incubations at 34 degrees C and 39 degrees C arrested the 5G1-B1 cells while retaining a high cell viability for up to 170 h in culture. The specific production rate of the growth-arrested cells was 3-4 times that of control cultures maintained at a constant 34 degrees C over the crucial 72-130-h period of culture, which resulted in a 35% increase in the maximum product yield. Glucose uptake and lactate production both decreased in arrested cells. Flow cytometric analysis indicated that 5G1-B1 cells arrested in the G(1) or G(0) phase of the cell cycle, and no major structural damage was caused to these cells by the alternating temperature regime.These results demonstrate that growth-arrested ts CHO cells have increased productivity compared to growing cultures and maintain viability for longer periods. The system offers the prospect of enhancing the productivity of recombinant mammalian cells grown in simple batch fermentors. (c) 1993 John Wiley & Sons, Inc.     

Glycopeptides prepared from mouse cerebrum inhibit protein synthesis and cell division in baby hamster kidney cells, but not in their polyoma virus-transformed analogs

Glycopeptides isolated from mouse cerebral cortex cell surfaces (BCSG) were shown to inhibit cell growth and protein synthesis in baby hamster kidney (BHK)-21 cells, whereas polyoma virus-transformed BHK-21 cells (pyBHK-21) were refractory to the inhibitory activity of the glycopeptides. Growth inhibition was shown to be reversible and non-lethal to BHK-21 cells. Despite that difference in sensitivity to the action of the glycopeptides, both cell lines could bind the inhibitor in a saturable fashion and in similar quantities. After trypsinization, BHK-21 cells appeared refractory to the inhibitor, whereas pyBHK-21 cells became sensitive. The data suggested the presence of a receptor for BCSG on the cell surface of both cell lines. Incubating BCSG with conditioned medium from pyBHK-21 cells resulted in loss of the glycopeptide's inhibitory activity. In contrast, medium conditioned by BHK-21 cells had no effect on the inhibitory activity of BCSG. We hypothesize that the refractoriness of pyBHK-21 cells to BCSG is related to their autonomous growth characteristics and failure to respond to topo-inhibitory growth control. BCSG may be a naturally occurring growth regulator whose function can be explored by use of the BHK-21/ pyBHK-21 model system.     

Inhibition of DNA synthesis and cell division by a cell surface sialoglycopeptide

We have isolated and purified a cell surface sialoglycopeptide (SGP) from bovine cerebral cortex cells that previously was shown to be a potent inhibitor of cellular protein synthesis. The following studies were carried out to characterize the potential ability of the SGP to inhibit DNA synthesis and to arrest cell division. Treatment of exponentially proliferating Swiss 3T3 cells with the SGP inhibitor resulted in a marked inhibition of thymidine incorporation within 24 h. When the SGP was removed from inhibited cultures, a sharp rise in 3H-thymidine incorporation followed within 3-4 h that peaked well above that measured in exponentially growing cultures, suggesting that the inhibitory action of the SGP was reversible and that a significant proportion of the arrested cells was synchronized in the mitotic cycle. In addition to DNA synthesis, the inhibitory action of the SGP was monitored by direct measurement of cell number. Consistent with the thymidine incorporation data, the SGP completely inhibited 3T3 cell division 20 h after its addition to exponentially growing cultures. Upon reversal there was a delay of 15 h before cell division resumed, when the arrested cells quickly doubled. Most, if not all, of the growth-arrested cells appeared to have been synchronized by the SGP. The SGP inhibited DNA synthesis in a surprisingly wide variety of target cells, and the relative degree of their sensitivity to the inhibitor was remarkably similar. Cells sensitive to the SGP ranged from vertebrate to invertebrate cells, fibroblast and epitheliallike cells, primary cells and established cell cultures, as well as a wide range of transformed cell lines.     

Colcemid effects on B16 melanoma cell progression and aberrant mitotic division

Mitotic cells selectively harvested after several h of colcemid treatment are routinely used to obtain synchronized cell cultures. DNA flow cytometry shows that when colcemid-treated B16 mitotic cells divide, they give rise to daughter cells in G1, some of which contain abnormal amounts of DNA. Two subpopulations appear to exist, one having a DNA content distribution expected of G1 cells, another having a mean DNA content about 0.8 of expected and an SD of DNA content more than 5 times expected. The effect was dependent on dose and duration of exposure to colcemid. Colcemid was more cytotoxic to cells in G2 + M than to G1 + S phase cells, and it slowed the progression of G1 cells to S. These effects of colcemid were much greater in aneuploid B16 melanoma cells than in pseudodiploid Chinese hamster ovary (CHO) cells.     

A temperature-sensitive mutation affecting S-phase progression can lead to accumulation of cells with a G2 DNA content

Cultures of ts BN75, a temperature-sensitive mutant of BHK 21 cells, show a gradual biphasic drop in [3H]thymidine incorporation together with an accumulation of cells having a G2 DNA content when incubated at 39.5 degrees. However, when higher (41 degrees - 42 degrees) nonpermissive temperatures were used, the major block was in S-phase DNA synthesis. The cultures of ts BN75 shifted to 42 degrees at the start of the S phase, cell-cycle progress was arrested in the middle of S, while under these conditions wild-type BHK cells underwent at least one cycle of DNA synthesis. When ts BN75 cells growth-arrested at high temperature with a G2 DNA content were shifted to the permissive temperature (33.5 degrees C), the restart of DNA synthesis preceded the appearance of mitotic cells. These data suggest that the ts defect of ts BN75 cells might affect primarily the S phase of the cycle rather than the G2 phase.     

SYNCHRONIZATION OF MITOCHONDRIAL DNA SYNTHESIS IN CHINESE HAMSTER CELLS (LINE CHO) DEPRIVED OF ISOLEUCINE

Mitochondrial DNA (mit-DNA) synthesis was compared in suspension cultures of Chinese hamster cells (line CHO) whose cell cycle events had been synchronized by isoleucine deprivation or mitotic selection. At hourly intervals during cell cycle progression, synchronized cells were exposed to tritiated thymidine ([³H]TdR), homogenized, and nuclei and mitochondria isolated by differential centrifugation. Mit-DNA and nuclear DNA were isolated and incorporation of radioisotope measured as counts per minute ([³H]TdR) per microgram DNA. Mit-DNA synthesis in cells synchronized by mitotic selection began after 4 h and continued for approximately 9 h. This time-course pattern resembled that of nuclear DNA synthesis. In contrast, mit-DNA synthesis in cells synchronized by isoleucine deprivation did not begin until 9–12 h after addition of isoleucine and virtually all [³H]TdR was incorporated during a 3-h interval. We have concluded from these results that mit-DNA synthesis is inhibited in CHO cells which are arrested in G₁ because of isoleucine deprivation and that addition of isoleucine stimulates synchronous synthesis of mit-DNA. We believe this method of synchronizing mit-DNA synthesis may be of value in studies of factors which regulate synthesis of mit-DNA.     

Dimethyl sulfoxide restores contact inhibition-induced growth arrest and inhibits cell density-dependent apoptosis in hamster cells.

Most nontransformed cell lines respond to confluence by arresting the cell cycle in a viable G(1) phase, whereas immortalized cell lines growing in monolayer do not stop cell cycle progression in response to high cell density and are subjected to density-dependent apoptosis. We have examined the effects, in terms of cell growth, apoptosis, and expression of adhesion molecules of culturing contact inhibition-deficient hamster cells in the presence of dimethyl sulfoxide (DMSO). Addition of 1.5% DMSO to the growth medium for 96 h arrested Chinese hamster ovary (CHO) cells in the G(1) phase as a confluent monolayer, associated with a remarkable increase in the expression of the cyclin-dependent kinase inhibitor p27. Cells cultured in DMSO-containing medium showed increased levels of cadherins and alpha5beta1 and beta1 integrin complexes. Cell exposure to DMSO also reduced both cell density-dependent apoptosis and necrosis and resulted in increased Bcl-2 expression. These results converge to indicate that DMSO restores contact inhibition-induced growth arrest and prevents high-density-dependent apoptosis and suggest that the effect of DMSO may be mediated by intracellular signaling triggered by cell-extracellular matrix and cell-cell interactions. Both p27 and bcl-2 appear to be involved in the resumption of growth control accompanying cell adhesion in DMSO-exposed CHO cells.     

Influence of G2 arrest on the cytotoxicity of DNA topoisomerase inhibitors toward human carcinoma cells with different p53 status

We here report the influence of the cell cycle abrogator UCN-01 on RKO human colon carcinoma cells differing in p53 status following exposure to two DNA damaging agents, the topoisomerase inhibitors etoposide and camptothecin. Cells were treated with the two drugs at the IC90 concentration for 24 h followed by post-incubation in drug-free medium. RKO cells expressing wild-type, functional p53 arrested the cell cycle progression in both the G1 and G2 phases of the cell cycle whereas the RKO/E6 cells, which lack functional p53, only arrested in the G2 phase. Growth-arrested cells did not resume proliferation even after prolonged incubation in drug-free medium (up to 96 h). To evaluate the importance of the cell cycle arrest on cellular survival, a non-toxic dose of UCN-01 (100 nM) was added to the growth-arrested cells. The addition of UCN-01 was accompanied by mitotic entry as revealed by the appearance of condensed chromatin and the MPM-2 phosphoepitope, which is characteristic for mitotic cells. G2 exit and mitotic transit was accompanied by a rapid activation of caspase-3 and apoptotic cell death. The influence of UCN-01 on the long-term cytotoxic effects of the two drugs was also determined. Unexpectedly, abrogation of the G2 arrest had no influence on the overall cytotoxicity of either drug. In contrast, addition of UCN-01 to cisplatin-treated RKO and RKO/E6 cells greatly increased the cytotoxic effects of the alkylating agent. These results strongly suggest that even prolonged cell cycle arrest in the G2 phase of the cell cycle is not necessarily coupled to efficient DNA repair and enhanced cellular survival as generally believed.     

Diminished G1 checkpoint after gamma-irradiation and altered cell cycle regulation by insulin-like growth factor II overexpression

High levels of insulin-like growth factor II (IGFII) mRNA expression are detected in many human tumors of different origins including rhabdomyosarcoma, a tumor of skeletal muscle origin. To investigate the role of IGFII in tumorigenesis, we have compared the mouse myoblast cell line C2C12-2.7, which was stably transfected with human IGFII cDNA and expressed high and constant amounts of IGFII, to a control cell line C2C12-1.1. A rhabdomyosarcoma cell line, RH30, which expresses high levels of IGFII and contains mutated p53, was also used in these studies. IGFII overexpression in mouse myoblast C2C12 cells causes a reduced cycling time and higher growth rate. After gamma-irradiation treatment, C2C12-1.1 cells were arrested mainly in G0/G1 phase. However, C2C12-2.7 and RH30 cells went through a very short G1 phase and then were arrested in an extended G2/M phase. To verify further the effect of IGFII on the cell cycle, we developed a Chinese hamster ovary (CHO) cell line with tetracycline-controlled IGFII expression. We found that CHO cells with high expression of IGFII have a shortened cycling time and a diminished G1 checkpoint after treatment with methylmethane sulfonate (MMS), a DNA base-damaging agent, when compared with CHO cells with very low IGFII expression. It was also found that IGFII overexpression in C2C12 cells was associated with increases in cyclin D1, p21, and p53 protein levels, as well as mitogen-activated protein kinase activity. These studies suggest that IGFII overexpression shortens cell cycling time and diminishes the G1 checkpoint after DNA damage despite an intact p53/p21 induction. In addition, IGFII overexpression is also associated with multiple changes in the levels and activities of cell cycle regulatory components following gamma-irradiation. Taken together, these changes may contribute to the high growth rate and genetic alterations that occur during tumorigenesis.     

Association of poly(ADP-rib) synthesis with cessation of DNA synthesis and DNA fragmentation

CHO cells and cs-4-D3 cells were used to investigate the association between poly(ADP-rib) synthesis and the cessation of DNA synthesis and DNA fragmentation. The cs4-D3 cells are cold-sensitive DNA synthesis arrest mutants of CHO cells. Upon incubation at 33 degrees C, DNA synthesis in the cs4-D3 cells stops and the cells enter a prolonged G1 or G0 phase. The events that occurred when cs4 cells were incubated at 33 degrees C were similar to those that occurred when wild-type CHO cells grew to high density. (1) In both cases, DNA synthesis and cell growth stopped. (2) The NAD+ concentration/cell was 20-25% lower in growth-arrested cells than in logarithmically growing cells. (3) Poly(ADP-rib) synthesis was 3-4 fold higher in growth-arrested cells than in logarithmically growing cells. (4) The growth-inhibited cells developed DNA strand breaks which resulted in large percentages of their DNA appearing in the low molecular weight range of alkaline sucrose gradients. (5) Both the increased rate of poly(ADP-rib) synthesis and the development of DNA strand breaks appears to be characteristic of the G1 phase of the cell cycle. (6) When growth-inhibited cells were restored to conditions favorable for DNA synthesis and cell growth, the DNA strand breaks were repaired. (7) Prolonged incubation under growth-restrictive conditions resulted in the accumulation of more DNA strand breaks than the cells could repair. This was followed by cell death when the cells were restored to conditions favorable for cell growth.     

The role of p21cip1 in adaptation of CHO cells to suspension and protein-free culture

The up-regulation of cyclin-dependent kinase inhibitor p21 has been shown to enhance productivity of monoclonal antibodies and has been linked to various regulatory processes. To identify the potential role of p21 in adaptation to suspension and protein-free cultures, we studied the survival and growth of anchorage- and serum-dependent CHO cell lines that differed only in the period of p21-induced arrest. p21 overexpression led to rapid adaptation of cells to suspension and protein-free cultures. The period taken to achieve adaptation was correlated with the time the cells were arrested after transfer from the monolayer and serum-fed culture. Interestingly, cell aggregation associated with protein-free suspension culture was reduced in p21 culture in response to the loss of cellular adherence. The processes of adaptation to suspension and arrest did not decrease monoclonal antibody productivity. In contrast, following adaptation to protein-free growth media, an overall increase in specific productivity was observed. The ability of cells to survive in protein-free suspension cultures was due to the requirement of G1 cells to growth factors and to their relatively high resistance to the hydrodynamic forces. This improved process has the advantage of reducing the duration of critical path activity for developing CHO commercial cell lines from 72 to 36 days.     

Regulation of protein secretion in Chinese hamster ovary cells by cell cycle position and cell density : Plasminogen activator, procollagen and fibronectin

To study the relationship between cell growth control, cell contact, and protein secretion, we examined the production of plasminogen activator, procollagen, and fibronectin by Chinese hamster ovary (CHO) fibroblasts, both as a function of position in the cell cycle and as a function of cell density. CHO fibroblasts that were synchronized at hourly intervals throughout the cell cycle by mitotic selection in an automated roller bottle apparatus secreted plasminogen activator only during the G2 and M phases of the cell cycle (10–14 h after mitotic selection). Cell-associated plasminogen activator activity was variable during G1 and S, but was greatly reduced during G2 and M. In contrast, secretion of the connective tissue matrix proteins, procollagen and fibronectin, was controlled by cell density rather than by cell cycle position. Type III procollagen and fibronectin were secreted throughout the cell cycle with no pronounced variations. Type I procollagen was not secreted by cycling cells and was observed in confluent cultures only after 24–48 h. To correlate these changes in protein secretion patterns with cell shape and contact, we used scanning electron microscopy (SEM) to study the appearance of CHO cells after mitotic selection. Actively dividing cells retained a high proportion of rounded, ruffled, and blebbed cells during all phases of the cell cycle. Only with increased cell density in contact-inhibited confluent cultures did most cells begin to flatten and spread. Thus, secretion of and attachment to extracellular matrix did not occur in rapidly dividing cells, but appeared to require the increased cell-cell contact and spreading that accompanies contact inhibition of growth. On the other hand, increased secretion of plasminogen activator was directly related to cell division and may be part of a sequence of events that allows cells growing in culture to loosen extracellular attachments in preparation for rounding and cytokinesis.     

Selection of mitotic Chinese hamster ovary cells from microcarriers. Cell cycle-dependent induction of mutation by 5-bromo-2'-deoxyuridine and ethyl methanesulfonate

Large quantities of mitotic cells may be collected by mitotic detachment from a population of Chinese hamster ovary cells growing on positively charged dextran microcarriers in suspension culture. Exponentially growing cells are treated for 2.5 h with colcemid and mitotic cells are detached from the microcarriers by increasing the stirring speed. A yield of 4-6% of the total population is obtained and, of the cells collected, 85-95% are arrested in metaphase. Using this means to synchronize cells we have determined the cell cycle dependence of the toxic and mutagenic effects of 5-bromo-2'-deoxyuridine (BUdR) and ethyl methanesulfonate (EMS). Mutation was measured at two independent loci: resistance to 6-thioguanine and resistance to ouabain. Both mutagens were more toxic during S phase as compared to G1 or G2 or mitosis. BUdR induced significant mutation only during S phase. The maximum induction of 6-thioguanine resistance was observed in cultures treated 10 h after plating of mitotic cells (2 h into S phase), while the maximum induction of ouabain resistance was observed in cultures treated 10-12 h after plating of mitotic cells (2-4 h into S phase). EMS induced significant mutation at all points in the cell cycle. Mutation induction reached a minimum during S phase but the magnitude of difference between any two points in the cell cycle was found to be less than two-fold.     

Condensed chromatin and cell inactivation by single-hit kinetics

Mammalian cells are extremely sensitive to gamma rays at mitosis, the time at which their chromatin is maximally condensed. The radiation-induced killing of mitotic cells is well described by single-hit inactivation kinetics. To investigate if radiation hypersensitivity by single-hit inactivation correlated with chromatin condensation, Chinese hamster ovary (CHO) K1 (wild-type) and xrs-5 (radiosensitive mutant) cells were synchronized by mitotic shake-off procedures and the densities of their chromatin cross sections and their radiosensitivities were measured immediately and 2 h into G1 phase. The chromatin of G1-phase CHO K1 cells was dispersed uniformly throughout their nuclei, and its average density was at least three times less than in the chromosomes of mitotic CHO K1 cells. The alpha-inactivation co-efficient of mitotic CHO K1 cells was approximately 2.0 Gy(-1) and decreased approximately 10-fold when cells entered G1 phase. The density of chromatin in CHO xrs-5 cell chromosomes at mitosis was greater than in CHO K1 cell chromosomes, and the radiosensitivity of mitotic CHO xrs-5 cells was the greatest with alpha = 5.1 Gy(-1). In G1 phase, CHO xrs-5 cells were slightly more resistant to radiation than when in mitosis, but a significant proportion of their chromatin was found to remain in condensed form adjacent to the nuclear membrane. These studies indicate that in addition to their known defects in DNA repair and V(D)J recombination, CHO xrs-5 cells may also be defective in some process associated with the condensation and/or dispersion of chromatin at mitosis. Their radiation hypersensitivity could result, in part, from their DNA remaining in compacted form during interphase. The condensation status of DNA in other mammalian cells could define their intrinsic radiosensitivity by single-hit inactivation, the mechanism of cell killing which dominates at the dose fraction size (1.8-2.0 Gy) most commonly used in radiotherapy.     

Comparative analysis of two controlled proliferation strategies regarding product quality, influence on tetracycline-regulated gene expression, and productivity.

Overexpression of the cyclin-dependent kinase inhibitor p27 and exposure to low temperature (30 degrees C) represent two strategies to establish controlled proliferation processes for production of therapeutic proteins using Chinese hamster ovary (CHO) cells. Here we analyze the effect of growth inhibition on the quality of the human model glycoprotein SEAP (secreted alkaline phosphatase) for both strategies in monoclonal CHO-derived cell lines. Separation of purified SEAP samples using two-dimensional gel electrophoresis showed that production by proliferation-controlled CHO cultures did not alter the overall integrity of the product. Further, oligosaccharide profiles were compared using HPEC-PAD analysis. No differences were detectable between SEAP profiles obtained from p27 growth-arrested and proliferating cultures. However, production at 30 degrees C led to a significant increase in the degree of sialylation, an effect that is generally considered beneficial for the in vivo efficacy of protein therapeutics. In the production context presented here, SEAP expression is controlled by the tetracycline- (tet) repressible gene regulation system. Here we show low temperature-induced upregulation of the tetracycline-dependent transactivator (tTA). This induction has been shown by Northern blot analysis to occur at the mRNA level and is independent of the promoters driving the transactivator. We also describe a novel bottleneck in productivity at low temperature found in p27 growth-arrested CHO cells cultivated at 30 degrees C.     

Onset of ribosome degradation during cessation of growth in BHK-21/C13 cells.

When BHK-21/C13 cells growing exponentially in 10% serum are transferred to a medium containing only 0.25% serum, cell growth is decreased. After initial changes in RNA synthesis and degradation, protein content of the cultures reaches a plateau and eventually DNA synthesis is arrested. rRNA is relatively stable in exponentially growing cells. Immediately after 'step-down' rRNA degradation commences, but poly(A)-containing RNA does not appear to be degraded any faster than in control cells. Reutilization of RNA precursors has been independently measured and amounts to less than 1%/h for rRNA, insufficient to influence the conclusion that rRNA degradation begins almost immediately after 'step-down'. The degree of reutilization of uridine is much greater for poly(A)-containing RNA than for poly(A)-free RNA.     

Controlled Growth of Chinese Hamster Ovary Cells and High Expression of Antibody-IL-2 Fusion Proteins by Temperature Manipulation

Growth and the expression of the anti-ErbB2 scFv-Fc-IL2 fusion protein in Chinese hamster ovary (CHO) cells were in association at 37 degrees C. The expression of the fusion protein was no more than 25 microg/ml. At 30 degrees C the cell growth was arrested but the cells continued to produce the fusion protein up to 60-80 microg/ml. About 50% of CHO cells were rapidly blocked in G2/M phase after the temperature was shifted from 37 to 30 degrees C. Lowering temperature resulted in cell growth arrest, but maintained cell viability for a longer time and enhanced the production of the antibody-IL-2 fusion protein in CHO cells.     

Continued initiation of DNA synthesis in arginine-deprived Chinese hamster ovary cells

When exponentially growing CHO cells were deprived of arginine (Arg), cell multiplication ceased after 12 h, but initiation of DNA synthesis continued: after 48 h of starvation with continuous [3H]thymidine exposure, 85% of the population had incorporated label, as detected autoradiographically. Consideration of the distribution of exponential cells in the various cell cycle phases leads to a calculation that most cells in G1 at the time that Arg was removed, as well as those in S, engaged in some DNA synthesis during starvation. In contrast, isoleucine (Ile)-starved cells did not initiate DNA synthesis, as has been reported by others. Experiments with cells synchronized by mitotic selection confirmed this difference in Arg- and Ile- deprived behavior, but also showed that cells which underwent the mitosis leads to G1 transition during Arg starvation remained arrested in G1 (G0?). The results suggest that Arg-deprived cells continue to maintain some proliferative function(s) while Ile-deprived cells do not.