Mitochondrial protein synthesis in chinese hamster cells (line CHO) synchronized by isoleucine deprivation

Mitochondrial protein synthesis was measured in line CHO cells after phases of the cell cycle were synchronized by isoleucine deprivation or mitotic selection. Maximum incorporation of [³H] leucine into mitochondrial polypeptides occurred within 2 hours after isoleucine was added to initiate G₁ traverse. In cells synchronized in G₁ by mitotic selection, the rate of mitochondrial protein synthesis was fairly constant throughout the cell cycle. SDS-polyacrylamide gel electrophoretic profiles of labeled mitochondrial polypeptides were similar in cells synchronized by either isoleucine deprivation or mitotic selection. Obvious changes in the distribution of polypeptides were not detected during various phases of the cell cycle. The increased rate of incorporation of [³H] leucine into mitochondrial polypeptides after reversal of G₁-arrest may indicate that mitochondrial protein synthesis and possibly mitochondrial biogenesis are synchronized in CHO cells deprived of isoleucine.     

Cell Cycle-Specific Expression of G0SPR1 in Chinese Hamster Ovary Cells

A family of small proline-rich proteins (SPR1s) is induced in cells undergoing squamous differentiation. Because SPR1 mRNA is detected in mesenchymal nasal cells of rats exposed to cigarette smoke, expression of this mRNA in other nonsquamous cells and tissues was investigated. Using PCR, low levels of SPR1 mRNA were identified in a number of nondifferentiating cell lines and in nonsquamous tissues. G₀SPR1 mRNA, the hamster homologue of SPR1 mRNA, was increased 10-fold in Chinese hamster ovary (CHO) cells when the culture reached 80–90% confluence and was downregulated after cells ceased growing at 100% confluence. The deduced amino acid sequence of G₀SPR1 showed a high homology to the family of SPR1 from different species. Affinity-purified antibodies to SPR1 reacted to about 50% of the CHO cell population, indicating that the protein is expressed at specific stages of the cell cycle. CHO cells that were switched to low-serum medium when they were at 60% confluence showed an increase in G₀SPR1 levels before the cells entered G₀, indicating that G₀SPR1 may be a signal to cells entering G₀. Because expression of the SPR1 family of proteins is associated with squamous differentiation, the observations in the nondifferentiating CHO cells indicate that these proteins may play a role in mediating the withdrawal from the cell cycle prior to the commitment to differentiation.     

Cell Synchrony Techniques. I. A Comparison of Methods

Abstract Selected cell synchrony techniques, as applied to asynchronous populations of Chinese hamster ovary (CHO) cells, have been compared. Aliquots from the same culture of exponentially growing cells were synchronized using mitotic selection, mitotic selection and hydroxyurea block, centrifugal elutriation, or an EPICS V cell sorter. Sorting of cells was achieved after staining cells with Hoechst 33258. After synchronization by the various methods the relative distribution of cells in G₁ S, or G₂+ M phases of the cell cycle was determined by flow cytometry. Fractions of synchronized cells obtained from each method were replated and allowed to progress through a second cell cycle. Mitotic selection gave rise to relatively pure and unperturbed early G₁ phase cells. While cell synchrony rapidly dispersed with time, cells progressed through the cell cycle in 12 hr. Sorting with the EPICS V on the modal G₁ peak yielded a relatively pure but heterogeneous G₁ population (i.e. early to late G₁). Again, synchrony dispersed with time, but cell-cycle progression required 14 hr. With centrifugal elutriation, several different cell populations synchronized throughout the cell cycle could be rapidly obtained with a purity comparable to mitotic selection and cell sorting. It was concluded that, either alone or in combination with blocking agents such as hydroxyurea, elutriation and mitotic selection were both excellent methods for synchronizing CHO cells. Cell sorting exhibited limitations in sample size and time required for synchronizing CHO cells. Its major advantage would be its ability to isolate cell populations unique with respect to selected cellular parameters.     

Sulfhydryl groups during the S phase: comparison of cells from G 1 , plateau-phase G 1 , and G 0

The non-protein sulfhydryl (NPSH) content of cells moving into S from G₁, plateau phase G₁, and G₀ was measured. Chinese hamster ovary (CHO) cells accumulated in G₁ by growth into plateau phase contain only one-fourth the NPSH concentration of cycling C₁ cells or G₁ cells accumulated by brief growth in isoleucine-deficient medium. Upon dilution of plateau cultures with fresh medium, cellular NPSH content increases rapidly, reaching the same level as that in cycling cells within four hours. This increase is prevented by cycloheximide but not by actinomycin D or hydroxyurea. Neither CHO cells cycling in vitro nor salivary gland G₀ cells stimulated with isoproterenol in vivo show significant changes in intracellular NPSH concentrations during S phase. This suggests that the concentration of intracellular NPSH (glutathione) remains constant during the cell cycle except when cells are grown to plateau phase in exhausted or deficient medium, in which case normal degradation exceeds synthesis and the gross level falls until fresh medium is provided and synthesis, apparently on preexisting RNA templates, accelerates.     

Electron spin resonance studies of changes in membrane fluidity of Chinese hamster ovary cells during the cell cycle

Electron spin resonance (ESR) spin-label methods were used with 5-doxyl-stearic acid as a probe to investigate membrane fluidity of Chinese hamster ovary (CHO) cells during the cell cycle. A 35 GHz ESR technique was developed to study membrane fluidity of intact cells. This technique requires only about $\text{1}\text{6}$ the amount of cells compared to the conventional spin-label techniques. With this technique we observed a cyclic change of membrane fluidity during the cell cycle of CHO cells: cells in mitosis had the highest membrane fluidity, whereas cells in G₁ and early S phases had the lowest membrane fluidity.     

CELL CYCLE-SPECIFIC CHANGES IN HISTONE PHOSPHORYLATION ASSOCIATED WITH CELL PROLIFERATION AND CHROMOSOME CONDENSATION

Preparative polyacrylamide gel electrophoresis was used to examine histone phosphorylation in synchronized Chinese hamster cells (line CHO). Results showed that histone f1 phosphorylation, absent in G₁-arrested and early G₁-traversing cells, commences 2 h before entry of traversing cells into the S phase. It is concluded that f1 phosphorylation is one of the earliest biochemical events associated with conversion of nonproliferating cells to proliferating cells occurring on old f1 before synthesis of new f1 during the S phase. Results also showed that f3 and a subfraction of f1 were rapidly phosphorylated only during the time when cells were crossing the G₂/M boundary and traversing prophase. Since these phosphorylation events do not occur in G₁, S, or G₂ and are reduced greatly in metaphase, it is concluded that these two specific phosphorylation events are involved with condensation of interphase chromatin into mitotic chromosomes. This conclusion is supported by loss of prelabeled ³²PO₄ from those specific histone fractions during transition of metaphase cells into interphase G₁ cells. A model of the relationship of histone phosphorylation to the cell cycle is presented which suggests involvement of f1 phosphorylation in chromatin structural changes associated with a continuous interphase "chromosome cycle" which culminates at mitosis with an f3 and f1 phosphorylation-mediated chromosome condensation.     

Cell cycle kinetics of the accumulation of heavy and light chain immunoglobulin proteins in a mouse hybridoma cell line

Rates of accumulation of immunoglobulin proteins have been determined using flow cytometry and population balance equations for exponentially growing murine hybridoma cells in the individual G₁, S and G₂+M cell cycle phases. A producer cell line that secretes monoclonal antibodies, and a nonproducer clone that synthesizes only -light chains were analyzed. The pattern for the kinetics of total intracellular antibody accumulation during the cell cycle is very similar to the previously described pattern for total protein accumulation (Kromenaker & Srienc 1991). The relative mean rate of heavy chain accumulation during the S phase was approximately half the relative mean rate of light chain accumulation during this cell cycle phase. This indicates an unbalanced synthesis of heavy and light chains that becomes most pronounced during this cell cycle phase. The nonproducer cells have on average an intracellular light chain content that is 42% lower than that of the producer cells. The nonproducer cells in the G₁ phase with low light chain content did not have a significantly higher rate of light chain accumulation relative to other G₁ phase nonproducer cells. This is in sharp contrast to what was observed for the G₁ phase producer cells. In addition, although the relative mean rate of accumulation of light chain was negative for G₂+M phase nonproducer cells, the magnitude of this relative mean rate was less than half that observed for the producer cells in this cell cycle phase. This suggests that the mechanisms that regulate the transport of fully assembled antibody molecules through the secretion pathway differ from those which regulate the secretion of free light chains. The results reported here indicate that there is a distinct pattern for the cell cycle dynamics of antibody synthesis and secretion in hybridomas. These results are consistent with a model for the dynamics of secretion which suggests that the rate of accumulation of secreted proteins will be greatest for newborn cells due to an interruption of the secretion pathway during mitosis.     

Flow cytometric BrdUrd-pulse-chase study of X-ray-induced alterations in cell cycle progression

To better understand how the flow cytometric bromodeoxyuridine (BrdUrd)-pulse-chase method detects perturbed cell kinetics we applied it to measure cell cycle progression delays following exposure to ionizing radiation. Since this method will allow both the use of asynchronous cell populations and the determination of the alterations in cell cycle progression specific to cells irradiated in given cell cycle phases, it has a significant advantage over laborious synchronization methods. Exponentially growing Chinese hamster ovary (CHO) K1 cells were irradiated with graded doses of X-rays and pulse-labelled with BrdUrd immediately thereafter. Cells were subcultured in a BrdUrd-free medium for various time intervals and prepared for flow cytometric analysis. Of five flow cytometric parameters examined, only those that involved cell transit through G₂, i.e. the fraction of BrdUrd-negative G₂ cells and the fraction of BrdUrd-positive cells that had not divided, showed radiation dose-dependent delays. The magnitude of the effects indicates that the cells irradiated in G₂ and in S are equally delayed. S phase transit of cells irradiated in S or in G₁ did not appear to be affected. There were apparent changes in flow of cells out of G₁, which could be explained by the delayed entry of G₂ cells into the compartment because of G₂ arrest. Thus, in asynchronous cells the method was able to detect G₂ delay in those cells irradiated in S and G₂ phases and demonstrate the absence of cell-cycle delays in other phases.     

Dynamics of cell cycle phase perturbations by trabectedin (ET-743) in nucleotide excision repair (NER)-deficient and NER-proficient cells, unravelled by a novel mathematical simulation approach

Abstract. Objectives: Trabectedin (ET‐743, Yondelis^®) is a natural marine product, with antitumour activity, currently in phase II/III clinical trials. Previous studies have shown that cells hypersensitive to ultraviolet (UV)‐rays because of nucleotide excision repair (NER) deficiency, were resistant to trabectedin. The purpose of this study was to investigate whether this resistance was associated with different drug‐induced cell cycle perturbations. Materials and Methods: An isogenic NER‐proficient cellular system (CHO‐AA8) and a NER‐deficient one (CHO‐UV‐96), lacking functional ERCC‐1, were studied. Flow cytometric assays showed progressive accumulation of cells in G₂ + M phase in NER‐proficient but not in NER‐deficient cells. Applying a computer simulation method, we realized that the dynamics of the cell cycle perturbations in all phases were complex. Results: Cells exposed to trabectedin during G₁ and G₂ + M first experienced a G₁ block, while those exposed in S phase were delayed in S and G₂ + M phases but eventually divided. In the presence of functional NER, exit from the G₁ block was faster; then, cells progressed slowly through S phase and were subsequently blocked in G₂ + M phase. This G₂ + M processing of trabectedin‐induced damage in NER‐proficient cells was unable to restore cell cycling, suggesting a difficulty in repairing the damage. Conclusions: This might be due either to important damage left unrepaired by previous G₁ repair, or that NER activity itself caused DNA damage, or both. We speculate that in UV‐96 cells repair mechanisms other than NER are activated both in G₁ and G₂ + M phases.     

CHANGES IN SURFACE MORPHOLOGY OF CHINESE HAMSTER OVARY CELLS DURING THE CELL CYCLE

Synchronized populations of Chinese hamster ovary (CHO) cells in confluent culture have been examined by scanning electron microscopy and their surface changes noted as the cells progress through the cycle. During G₁ it is characteristic for cells to show large numbers of microvilli, blebs, and ruffles. Except for the ruffles, these tend to diminish in prominence during S and the cells become relatively smooth as they spread thinly over the substrate. During G₂ microvilli increase in number and the cells thicken in anticipation of rounding up for mitosis. It appears that the changes observed here reflect the changing capacity of CHO cells during the cycle to respond to contact with other cells in the population, because, as noted in the succeeding paper (Rubin and Everhart), CHO cells in sparse nonconfluent cultures do not show the same wide range of changes during the cell cycle. Normal, nontransformed cells of equivalent type in confluent culture are essentially devoid of microvilli, blebs, and ruffles. The relation of these surface configurations to the internal structure of the cell is discussed.     

Interaction between acylphosphatase and SERCA in SH-SY5Y cells

Ca²⁺ transport by sarco/endoplasmic reticulum, tightly coupled with the enzymatic activity of Ca²⁺-dependent ATPase, controls the cell cycle through the regulation of genes operating in the critical G₁ to S checkpoint. Experimental studies demonstrated that acylphosphatase actively hydrolyses the phosphorylated intermediate of sarco/endoplasmic reticulum calcium ATPase (SERCA) and therefore enhances the activity of Ca²⁺ pump. In this study we found that SH-SY5Y neuroblastoma cell division was blocked by entry into a quiescent G₀-like state by thapsigargin, a high specific SERCA inhibitor, highlighting the regulatory role of SERCA in cell cycle progression. Addition of physiological amounts of acylphosphatase to SY5Y membranes resulted in a significant increase in the rate of ATP hydrolysis of SERCA. In synchronized cells a concomitant variation of the level of acylphosphatase isoenzymes opposite to that of intracellular free calcium during the G₁ and S phases occurs. Particularly, during G₁ phase progression the isoenzymes content declined steadily and hit the lowest level after 6 h from G₀ to G₁ transition with a concomitant significant increase of calcium levels. No changes in free calcium and acylphosphatase levels upon thapsigargin inhibition were observed. Moreover, a specific binding between acylphosphatase and SERCA was demonstrated. No significant change in SERCA-2 expression was found. These findings suggest that the hydrolytic activity of acylphosphatase increase the turnover of the phosphoenzyme intermediate with the consequences of an enhanced efficiency of calcium transport across endoplasmic reticulum and a subsequent decrease in cytoplasmic calcium levels. A hypothesis about the modulation of SERCA activity by acylphosphatase during cell cycle in SY5Y cells in discussed.     

Premature chromosome condensation in temperature-sensitive cells arrested in G1 phase

The structural morphology of prematurely condensed chromosomes (PCC) was used as a probe to detect accumulation of temperature-sensitive (ts) cells at different points of the G₁ phase at the non-permissive temperature (38 °C). Interphase cells of wild type Balb/c-3T3 and its ts variant clones incubated at 38 °C were fused with mitotic CHO cells. Compared to a random population of 3T3 cells, the ts variants accumulated individual grades of G₁ phase PCC. These results were in accordance with the complementation data (Naha, 1979) regarding the relative position of the variants in the G₁ phase of the cell cycle.     

The effect of cell-to-cell contact on the surface morphology of Chinese hamster ovary cells

In the previous report (Porter et al., in this issue) morphological changes in Chinese hamster ovary (CHO) cells during the cell cycle were described. In this report we describe the role of intercellular contact on these changes. We find that intercellular contact is required for cells to exhibit the morphologies Porter et al. described for S and G₂. When cells are synchronized by mitotic selection and plated onto cover slips at very low density such that no intercellular contact occurs, the cells remain in a G₁ configuration (rounded and highly blebbed through G₁, S, and G₂). This G₁ morphology is also observed in nonsynchronized log phase cells plated at low densities and allowed to grow for several generations. The addition of conditioned medium from confluent cultures does not induce low density cells to change morphology during the cell cycle. These results indicate that extensive intercellular contact is required for the complete expression of the morphological changes associated with the cell cycle (as described by Porter et al.). It is concluded that although classic contact inhibition of movement and of growth may be absent in this transformed cell line, some contact-dependent response persists.     

Molecular mechanisms involved in the production of cromosomal aberrations II. Utilization of neurospora endonuclease for the study of aberration production by X-rays in G1 and G2 stages of the cell cycle

Chinese hamster ovary cells (CHO) were X-irradiated in G₁ and G₂ stages of the cell cycle and subsequently Neurospora endonuclease (NE) (E.C.3.1.4), an enzyme which is specific in cleaving single-stranded DNA, was introduced into the cells, after making the cells permeable by treatment with inactivated Sendai virus. With this treatment all classes of X-ray-induced chromatid aberrations increased in G₂ cells, whereas in G₁ cells an increase in cromosome type of aberrations was found, associated with a profound induction of chromatid type of aberrations as well. Duration of the availability of single-strand gaps for the action of NE has been studied in G₂ cells following X-irradiation and the influence of different parts of the G₂ stage on the type and frequencies of chromatid aberrations was discerned. While the increase in chromosome type of aberrations by NE in X-irradiated G₁ cells has been interpreted as due to the conversion of DNA single-strand breaks or gaps to double-strand breaks by NE, the induction of chromatid aberrations in G₁ has been assumed to be due to conversion of some of the damaged bases strand breaks by NE. Biochemical evidence is presented for the conversion by NE of DNA single-strand breaks induced by X-rays into double-strand breaks using neutral sucrose gradient centrifugation.     

Effects of inhibition of RNA or protein synthesis on CHO cell cycle progression

Chinese hamster ovary (CHO) cells, synchronized by selective detachment at mitosis, were treated with various concentrations of actinomycin D (AMD) or cycloheximide (CHX) either immediately, or 1, 2, or 3 hr after mitosis. Since the minimum duration of G₁ phase in these cultures was 3.4 hr, the addition of RNA or protein synthesis inhibitors took place at the beginning, first third, second third, or end (G₁–S boundary) of G₁ phase. The kinetics of exit from G₁ phase, the rate and extent of traverse of S phase, and the reaccumulation of RNA were estimated under each set of growth conditions by flow cytometry of acridine orange-stained cells. A mathematical model was constructed to describe the trajectories of the cell populations with respect to their increase in RNA and DNA content in the absence or presence of the inhibitor. The chronologic synchrony imposed on the CHO cell population began to decay within 3 hr, resulting in stochastic entrance of cells into S phase in the absence of inhibitor. Addition of AMD or CHX at 0, 1, 2, or 3 hr after mitosis, regardless of the inhibitor concentration, did not provide evidence of a critical restriction point in G₁ beyond which cells were committed to enter S phase and were no longer sensitive to moderate suppression of RNA or protein synthesis. The observed kinetics of cell entrance into and traverse of S phase were consistent with an inherently heterogenous response to serum stimulation occurring at or just after cell division.     

Composition and synthesis during G1 and S phase of a high mobility group-E/G component from Chinese hamster ovary cells

A perchloric acid soluble protein from the sedimented chromatin of blended Chinese hamster ovary (line CHO) cells has been isolated by guanidine hydrochloride gradient chromatography on Bio·Rex-70^® ion exchange resin. The amino acid composition of the protein (designated as CHO HMG-E/G) is similar to that of mouse HMG-E, but it differs from that of bovine HMG-14 and HMG-17 or any possible mixture of the two. CHO HMG-E/G incorporates [³²P]phosphate like HMG-14 and HMG-17 class proteins from other species, but all resolvable molecular species incorporate phosphate, and the more highly-phosphorylated band migrates faster, rather than slower, than the other in acid-urea gel systems. Incorporation of [³H]lysine into HMG-E/G following release from isoleucine deprivation G₁ block indicates that the protein is extensively synthesized during both the G₁ and S phases of the cell cycle.     

Tumor-targeting Salmonella typhimurium A1-R decoys quiescent cancer cells to cycle as visualized by FUCCI imaging and become sensitive to chemotherapy

Quiescent cancer cells are resistant to cytotoxic agents which target only proliferating cancer cells. Time-lapse imaging demonstrated that tumor-targeting Salmonella typhimurium A1-R (A1-R) decoyed cancer cells in monolayer culture and in tumor spheres to cycle from G₀/G₁ to S/G₂/M, as demonstrated by fluorescence ubiquitination-based cell cycle indicator (FUCCI) imaging. A1-R infection of FUCCI-expressing subcutaneous tumors growing in nude mice also decoyed quiescent cancer cells, which were the majority of the cells in the tumors, to cycle from G₀/G₁ to S/G₂/M, thereby making them sensitive to cytotoxic agents. The combination of A1-R and cisplatinum or paclitaxel reduced tumor size compared with A1-R monotherapy or cisplatinum or paclitaxel alone. The results of this study demonstrate that A1-R can decoy quiescent cancer cells to cycle to S/G₂/M and sensitize them to cytotoxic chemotherapy. These results suggest a new paradigm of bacterial-decoy chemotherapy of cancer.     

Cell Cycle Kinetics of Chinese Hamster (Cho) Cells Treated With the Iron-Chelating Agent Picolinic Acid

Spontaneously transformed (tumorigenic) Chinese hamster cells (line CHO) do not exhibit picolinic acid-sensitive G₁ and G₂ cell cycle arrest points observed in normal and virus-transformed cells. Rather, picolinic acid arrests CHO cells in S phase only and produces culture growth behaviour similar to that produced by hydroxyurea. Prolonged treatment with picolinic acid permits a slow but significant traverse of cells through S phase. Thus, like hydroxyurea, picolinic acid is not a useful agent for synchronizing exponential CHO cells, but it can be used to resynchronize cultures in early S phase if a previous synchronization procedure (such as isoleucine deprivation) is used. the iron chelating properties of picolinic acid, and the similarities of its effects on cultured cells to those of hydroxyurea and the iron-chelating drug desferrioxamine, suggest that picolinic acid inhibits DNA synthesis by interfering with the iron-dependent production of a stable free organic radical which is essential for the ribonucleotide reductase formation of deoxyribonucleotides.     

UV-light-induced mutations in synchronous CHO cells

Asynchronous and synchronous CHO cells were irradiated with germicidal UV light to determine the fluence response curve for cell killing, and the induction of resistance to 6-thioguanine, ouabain, and diphtheria toxin. For asynchronous populations the data show a sigmoidal response for induced reproductive death, as has been seen by other, with a D₀ of 6 J/m² and an extrapolation number of 2.5. The induction of mutations appears to be a linear function for all three mutagenic markers up to a dose of 17 J/m².Reproductive death induced in the synchronous populations is a function of the time at which exposure occurs in the cell cycle, with late G₁ and early S being the sensitive stages. The induction of resistance to 6TG, ouabain, and diphtheria toxin (DT) all seem to depend on the time of exposure in the cell cycle. As in the case of UV-induced reproductive death, the more sensitive periods for mutation induction appear also to be the G₁ and early S period of the cell cycle, with the largest cyclic variation occurring for induced DT resistance.A comparison of the results reported here for the UV exposure with exposures of synchronous CHO cells to X-rays and ethylnitrosourea suggests that there are different age-specific responses to mutation induction for each agent, and that there are often different age responses for different mutagenic end- points with the same mutagen.