Effects of chloramphenicol on the physiology and fine structure ofTetrahymena pyriformis GL: Correlation between diminishing inner mitochondrial membrane and cell doubling

Summary A time-dependent loss of tubular infolding of the inner mitochondrial membrane was reported recently as an effect of the cytostatic drug, methotrexate (MTX), onTetrahymena (Nilsson 1983); this finding was interpreted as an inhibition of mitochondrial protein synthesis. In the present study, the cells were exposed to chloramphenicol (CAP), an inhibitor of mitochondrial translation, at the same concentrations (1–25 mM) as MTX; the question asked was whether the two drugs acted similarly. CAP affected cell proliferation by causing a dose-dependent prolongation of the generation time, but at 10–25 mM permitted only a limited number of cell doublings, whereas 1 mM MTX inhibits growth after 5 cell doublings. With CAP the inner mitochondrial membrane diminished gradually in accordance with the number of cell doublings at 10–25 mM, but in 2 mM CAP, for example, some tubular infoldings were still present after 17 cell doublings. The gradual loss of the inner mitochondrial membrane correlated with a gradual decrease in the cellular ATP content, irrespective of the concentration of the drug but dependent on the progress of the cells through their first cycle when exposed to the drug; in cells which continued to proliferate, the ATP content remained at a value corresponding to 80% of the control value. With respect to cell proliferation, the two drugs act differently. CAP is less toxic than MTX, reflected in a 10 times shorter recovery time for cell proliferation after removal of CAP. Hence, although the structural manifestation of the action of the two drugs on mitochondria is identical, their target site may differ.     

Specific G2 phase toxicity of chloramphenicol on mouse leukemic cells (L5178Y)

The effect of chloramphenicol on progression through the cell cycle of L5178Y cells was investigated. Using eosin staining as a viability index, G2 cells were shown to be specifically killed at a concentration of chloramphenicol generally used to study mitochondrial protein synthesis. Pretreating cells with chloramphenicol induced resistance to this G2 lethality.     

Concentration-dependent effects of potassium dichromate on the cell cycle

Hexavalent chromium is found to be a strong mutagen, and it also is a potential carcinogen in man. DNA flow cytometry, growth measurements, and determinations of mitotic index show that 1-2 microM K2Cr2O7 produces a prolongation of the G2 phase of the cell cycle in NHIK 3025 cells. By increasing the chromate concentrations (greater than 2 microM K2Cr2O7) the cells are also arrested in G2 phase. We have found, using synchronized cells and measuring cell cycle time, that the most chromate-sensitive part of the cell cycle is S phase. This phase is also somewhat prolonged, and the cells became arrested in early S phase at high toxic K2Cr2O7 concentrations (8 microM). Our results thus indicate that K2Cr2O7 has an effect within S phase--maybe on DNA/RNA synthesis--and also interferes with processes necessary for progression through the G2 phase.     

The role of protein accumulation in the cell cycle control of human NHIK 3025 cells

The cell cycle kinetics of NHIK 3025 cells, synchronized by mitotic selection, was studied in the presence of cycloheximide at concentrations (0.125-1.25 μM) which inhibited protein synthesis partially and slowed down the rate of cell cycle traverse. The median cell cycle duration was equal to the protein doubling time in both the control cells and in the cycloheximide-treated cultures at all drug concentrations. This conclusion was valid whether protein synthesis was continuously depressed by cycloheximide throughout the entire cell cycle, or temporarily inhibited during shorter periods at various stages of the cell cycle. These results may indicate that cell division does not take place before the cell has reached a critical size, or has completed a protein accumulation-dependent sequence of events. When present throughout the cell cycle, cycloheximide increased the median G1 duration proportionally to the total cell cycle prolongation. However, the entry of cells into S, once initiated, proceeded at an almost unaffected rate even at cycloheximide concentrations which reduced the rate of protein synthesis 50%. The onset of DNA synthesis seemed to take place in the cycloheximide-treated cells at a time when the protein content was lower than in the control cells. This might suggest that DNA synthesis in NHIK 3025 cells is not initiated at a critical cell mass.     

EXPRESSION OF THE MITOCHONDRIAL GENOME IN HELA CELLS : XV. Effect of Inhibition of Mitochondrial Protein Synthesis on Mitochondrial Formation

The effect of selective inhibition of mitochondrial protein synthesis by chloramphenicol at 40 or 200 µg/ml on the formation of mitochondria in HeLa cells was investigated. HeLa cells, under the conditions used in the present work, grow at a decreasing rate for at least four cell generations in the presence of 40 µg/ml chloramphenicol, and for two generations in the presence of 200 µg/ml chloramphenicol. The progressive cell growth inhibition which begins after 2 days of exposure of the cells to 40 µg/ml chloramphenicol is immediately or gradually reversible, upon removal of the drug, for periods up to at least 8 days of treatment, though there is a progressive loss of cloning efficiency. In cells which have been treated for 6–7 days with 40 or 200 µg/ml of chloramphenicol, mitochondrial protein synthesis occurs at a normal or near-normal rate 1 h after removal of the drug. Mitochondria increase normally in number and show a normal size and amount of cristae in the presence of either concentration of drug. However, in 4–5% of the mitochondrial profiles the cristae appear to be arranged in unusual, circular, looped or whorled configuration.     

Studies on the vegetative life cycle of Chlamydomonas reinhardi Dangeard in synchronous culture II. Effects of chloramphenicol and cycloheximide on the length of cell cycle

Cells of Chlamydomonas reinhardi Dangeard were synchronouslygrown under a 12 hr light— 12 hr dark regime. When thesecells were brought into contact with chloramphenicol for a shortperiod at early stages in the cell cycle, zoospore liberationwas delayed for a period which was nearly the same as that ofthe duration of contact with the antibiotic. When given at laterstages, the antibiotic caused no such effect. Cycloheximide,on the other hand, caused—when provided at some intermediatestage of the cell cycle— two different prolonging effectson the length of the cell cycle: one doubled the normal length(observed when the drug was administered at certain stages)and the other caused a delay similar to that caused by chloramphenicol.Interestingly, no prolonging effect was observed when cycloheximidewas given either at early stages or at later stages, such asduring the last 1/4 period of the cell cycle preceding zoosporeliberation. Based on these results, three phases were distinguishedin the algal cell cycle: "chloramphenicolsensitive", "cycloheximide-sensitive"and "insensitive" phases. Considering the known facts aboutthe modes of action of the two antibiotics inhibiting proteinsynthesis, discussions were made on the significance of proteinsynthesis in chloroplasts and in cytoplasm in determining thelength of the cell cycle. (Received October 12, 1970; )     

Cell cycle-specific glucocorticoid growth regulation of a human cell line (NHIK 3025)

It has been reported that the human cell line NHIK 3025 has a specific cytoplasmic glucocorticoid receptor. When these cells were exposed to glucocorticoids, the cell cycle time was prolonged. Cells, synchronized by mitotic selection, were subjected to the synthetic glucocorticoid dexamethasone throughout the cell cycle. Only cells exposed in the first half of G1 phase had a lengthened cell cycle time. Most of the prolongation was also located within the G1 phase. The dexamethasone growth inhibition was reversible and could be detected only in the cell cycle where the cells were exposed to the steroid. DNA-histograms of asynchronous cells were recorded by flowcytometry at various times after steroid exposure. These histograms also showed G1 phase sensitivity and G1 phase prolongation after exposure to dexamethasone. Our results thus indicate that these cells have a dexamethasone-sensitive restriction point in mid-G1 phase of the cell cycle.     

Cycloheximide and 4-OH-TEMPO suppress chloramphenicol-induced apoptosis in RL-34 cells via the suppression of the formation of megamitochondria

Toxic effects of chloramphenicol, an antibiotic inhibitor of mitochondrial protein synthesis, on rat liver derived RL-34 cell line were completely blocked by a combined treatment with substances endowed with direct or indirect antioxidant properties. A stable, nitroxide free radical scavenger, 4-hydroxy-2,2,6, 6-tetramethylpiperidine-1-oxyl, and a protein synthesis inhibitor, cycloheximide, suppressed in a similar manner the following manifestations of the chloramphenicol cytotoxicity: (1) Oxidative stress state as evidenced by FACS analysis of cells loaded with carboxy-dichlorodihydrofluorescein diacetate and Mito Tracker CMTH2MRos; (2) megamitochondria formation detected by staining of mitochondria with MitoTracker CMXRos under a laser confocal microscopy and electron microscopy; (3) apoptotic changes of the cell detected by the phase contrast microscopy, DNA laddering analysis and cell cycle analysis. Since increases of ROS generation in chloramphenicol-treated cells were the first sign of the chloramphenicol toxicity, we assume that oxidative stress state is a mediator of above described alternations of RL-34 cells including MG formation. Pretreatment of cells with cycloheximide or 4-hydroxy-2,2, 6,6-tetramethylpiperidine-1-oxyl, which is known to be localized into mitochondria, inhibited the megamitochondria formation and succeeding apoptotic changes of the cell. Protective effects of cycloheximide, which enhances the expression of Bcl-2 protein, may further confirm our hypothesis that the megamitochondria formation is a cellular response to an increased ROS generation and raise a possibility that antiapoptotic action of the drug is exerted via the protection of the mitochondria functions.     

Inhibition of cell growth by a fused protein of human ribonuclease 1 and human basic fibroblast growth factor

Pancreatic-type RNases are considered to have cytotoxic potential due to their ability to degrade RNA molecules when they enter the cytosol. However, most of these RNases show little cytotoxicity because cells have no active uptake mechanism for these RNases and because the ubiquitous cytoplasmic RNase inhibitor is considered to play a protective role against the endocytotic leak of RNases from the outside of cells. To study the cytotoxic potential of RNase toward malignant cells targeting growth factor receptors, the C-terminus of human RNase 1 was fused to the N-terminus of human basic fibroblast growth factor (bFGF). This RNase-FGF fused protein effectively inhibited the growth of mouse melanoma cell line B16/BL6 with high levels of cell surface FGF receptor. This effect appeared to result from prolongation of the overall cell cycle rather than the killing of cells or specific arrest in a particular phase of the cell cycle. Thus, human RNase 1 fused to a ligand of cell surface molecules, such as the FGF receptor, is shown to be an effective candidate for a selective cell targeting agent with low toxic effects on normal cell types.     

Regulation of gluconeogenic enzymes during the cell cycle of Saccharomyces cerevisiae growing in a chemostat

Oscillation of the activities of gluconeogenic enzymes (malate dehydrogenase, phosphoenolpyruvate carboxykinase and fructose-1,6-bisphosphatase) was observed during the cell cycle of chemostat cultures of Saccharomyces cerevisiae. Since ethanol is released by the cells at the beginning of the division cycle, its effect on enzyme expression was determined. Pulsing ethanol to a synchronously dividing yeast culture led to a prolongation of the metabolically active phase as indicated by the course of oxygen uptake and carbon dioxide production rates (concomitant ethanol and glucose assimilation). Enzyme activities also remained elevated as long as ethanol was available to the cells. After a substrate shift from glucose to ethanol during cell division, ethanol was used without a lag phase and enzyme induction increased from the level reached at the point of the substrate change. The data confirmed that the small amount of ethanol produced when the cells begin active reproduction acts as an inducer of gluconeogenic enzymes.     

Activin A-induced differentiation in K562 cells is associated with a transient hypophosphorylation of RB protein and the concomitant block of cell cycle at G1 phase.

The human erythroleukemic cell line, K562, can be induced to differentiate by the addition of activin A, a newly purified protein belonging to the TGF-beta 1 family. The present studies used flow cytometric cell cycle analysis, indirect immunofluorescence staining of the proliferating cell nuclear antigen (PCNA), and thymidine incorporation assay of cell proliferation to study the effects of activin A on the cell cycle during differentiation in K562 cells. Activin A-treated K562 cells were found to undergo a transient block in cell cycle, temporarily halting progression from G1 to S phase. The latter can be observed after approximately 24 hr of incubation with activin A and then disappears after this early stage of induction of differentiation. Cell cycle kinetics analysis using synchronized K562 cells also confirms that in the presence of activin A, K562 cells progress normally through various phases of cell cycle, except that there is prolongation of the G1 phase between 10 to 24 hr of culture. Furthermore, this transient arrest in G1 is correlated with dephosphorylation of a nucleoprotein, the RB gene product, which occurs within 9-24 hr of incubation with activin A; and phosphorylation of RB protein then develops afterward. In addition, these cell cycle-related events are observed to occur earlier than the accumulation of hemoglobins in K562 cells. It is concluded that transient dephosphorylation of RB protein and prolongation of G1 phase of cell cycle precede and accompany erythroid differentiation caused by activin A and chemical inducers, thus constituting part of the mechanism for induction of differentiation in the erythroleukemia cells.     

The effects of ouabain on the cell mitotic cycle of mouse lymphoblasts

The inhibition of cell proliferation by ouabain has been analyzed with respect to the cell cycle. Three lines of evidence indicate that growth rate is modified by altering to different degrees the rate of progress through stages of the cell cycle: (1) a three hour lag occurs between the time of ouabain addition and the inhibition of proliferation; (2) ouabain must be present at least two to four hours prior to the mitotic burst of synchronized cells for inhibition of mitosis to occur; (3) parasynchrony is observed when cells are resuspended in ouabain-free medium after 12 hours of exposure to ouabain. Analysis of the distribution of cells in each of the stages of the cell cycle at various times during ouabain treatment reveals a progressive increase in the fraction of cells in S with a concomitant decrease in the percent of cells in each of the other stages. These results indicate that the prolongation of the cell cycle time in the presence of ouabain is due primarily to an S stage block.     

The role of protein metabolism in glucocorticoid-lnduced prolongation of G1 phase in human NHIK 3025 cells

It has previously been found that human NHIK 3025 cells have a glucocortiocoid-sensitive restriction point in mid-G1 phase of the cell cycle. When these cells were synchronized by mitotic selection and exposed to dexamethasone before the restriction point, G1 phase was prolonged whereas the rest of the cell cycle was unperturbed by the hormone. These observations were confirmed by flowcytometric mesurements of synchronized cells in the present study. Cells that received dexamethasone (10^?6 M) just after mitotic selection had a 4 hour prolongation of both G1 and the total cell cycle. However, the general rates of both protein synthesis and protein degradation were found not to be altered by the hormone, i.e., the rate of protein accumulation in dexamethasone exposed cells was equal to that of control cells. Dexamethasone exposed NHIK 3025 cells were found to be larger than control cells at the time of cell division. This is a direct consequence of a prolonged cell cycle duration with no change in general protein metabolism. It thus appears that the dexamethasone-induced prolongation of G1 phase is the result of a steroid-regulated G1 specific process(es) leading toward DNA replication, a process that does not alter general protein accumulation.     

Interference of a synthetic C18 juvenile hormone with mammalian cells in vitro. II. Effects on cell cycle

Interference of a synthetic C18 juvenile (JH) with the cell cycle of mouse embryo cells (ME-cells) and mouse cells of established cell line (L-cells) was examined. After 3 hour in the medium with JH (20 mg/ml) the cells were transfered to the regular culture medium and labelled with H3-thymidine then incubated for 1 to 48 hours before processing them for autoradiography. The percentage of labelled mitosis was then calculated for all cells samples examined and the labelled mitosis curves were drown and analyzed. It was shown that in contrast to the solvent which had no effect on duration of any of the component phases of the cell cycle of ME-cells, the juvenile hormone under conditions of these experiments prolonged G1 and G2 intervals what resulted in prolongation of the total cell cycle of these cells. On the other hand it shortened G1 and prolonged G2 intervals of L-cells without changing duration of the total cell cycle. Thus, in the examined mouse cells, they were the G1 and G2 intervals which are affected by JH. This findings are considered as an argument for pleiotropic nature of the juvenile hormone interference with mouse cells, the more so as it interfered with both protein and DNA synthesis in these cells.     

The influence of 2,4-dichlorophenoxyacetic acid on cell cycle Kinetics and Sister-Chromatid Exchange Frequency in Garlic (Allium sativum L.) Meristem Cells

The effect of 2,4-dichlorophenoxyacetic acid (2,4-D) at low concentrations on cell cycle duration and sister-chromatid exchange (SCE) frequency was studied using meristem root-tip cells ofAllium sativum L. 2,4-D induced a marked prolongation of the cell cycle. At the same time, small but statistically significant increases in SCE frequencies were observed at 5 μM and 15 μM 2,4-D concentrations. The significance of these findings in the evaluation of mutagenic activity of 2,4-D is discussed.     

Evidence for a cycloheximide-sensitive component in the biological clock of Acetabularia.

An 8-h exposure to cycloheximide (0.1 μg/ml) delays the phase of the photosynthesis rhythm 6–14 h in individual Acetabularia cells monitored at 25 °C, providing the drug is present during the first half of a cell's circadian cycle. Puromycin pulses (50 μg/ml) are like cycloheximide in their effect on phase, but chloramphenicol (100 μg/ml) is ineffective. These results indicate that protein synthesis on 80S ribosomes provides a necessary component for the biochemical mechanism of circadian regulation in Acetabularia.     

Isolation and detailed characterization of human cell lines resistant to -threo-chloramphenicol

The isolation and characterization of chloramphenicol resistant derivatives of the human cell line HeLa B is described. Growth of resistant lines was unaffected in the presence of 100 μg/ml -threo-chloramphenicol, whereas growth of the parental cells was inhibited at 12.5 μg/ml. The incorporation of [³⁵S]methionine into mitochondrial protein of intact resistant cells continued normally in the presence of 100 μg/ml chloramphenicol (cytoplasmic protein synthesis was blocked by addition of 50 μg/ml emetine). Under these conditions the electrophoretic profile of labelled, presumptive mitochondrially-made proteins was similar to that of the parental cell line labelled in the absence of chloramphenicol. The cell lines selected in the presence of chloramphenicol also showed increased resistance to some other inhibitors of mitochondrial protein synthesis, e.g. carbomycin and mikamycin. [¹⁴C]Chloramphenicol was found to have normal access to the interior of resistant cells and it is therefore unlikely that resistance results from altered cell permeability. No modification of the drug by acetylation or glucuronide conjugation mechanisms was observed. The possibilities remain that resistance is mediated by altered permeability of the mitochondrial membrane, or from modification to a component of the mitochondrial protein synthetic system.