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.     

The cell cycle of epidermal cells during reprogramming in the pupa of Galleria

The epidermal cell cycle of the pupal mesonotum of Galleria was investigated by the determination of mitotic indices, [³H]thymidine incorporation and flow-cytophotometric analysis during the first 48 h after pupation.Immediately after the pupal ecdysis nearly all epidermal cells are arrested in G2. Thereafter only a few mitoses occur, leading to a slow increase in the number of G1 nuclei. With the onset of a mitotic wave at a pupal age of 21 h this increase becomes more rapid. On day 2, the cell population reaches a plateau in the number of G1 (resp. G2) cells, reflecting a steady state between mitotic activity and DNA synthesis.A comparison of these cell cycle changes with known data of the time course of reprogramming and ecdysteroid titre leads to the conclusion that there is no causal relationship between DNA synthesis and cellular determination in the sense of a quantal cell cycle, and that DNA synthesis can precede the definite rise in ecdysteroid titre.     

Autoradiographic studies on the incorporation of3H-amino acids into chromosomes during the mitotic cell cycle ofHaplopappus gracilis

The synthesis of chromosomal proteins and the incorporation of labelled proteins into chromosomes in the mitotic cell cycle ofHaplopappus gracilis, 2n=4, were traced autoradiographically with³H-arginine,³H-lysine, and³H-tryptophane. The duration of the mitotic cell cycle in the root tip cells was determined by³H-thymidine autoradiography and was measured to be 13.0 hr (G₁ 1.3 hr, S 6.5 hr, G₂ 3.8 hr and M 1.4 hr).³H-arginine labelled proteins which were synthesized at S and G₂ were found to be incorporated into chromosomes to a greater extent than proteins which were synthesized either at G₁, at the transition phase from late S to early G₂, or at the mitotic phase. Such varied incorporation was also found in³H-lysine labelled proteins, but not in³H-tryptophane labelled proteins. These findings indicate that the chromosomal proteins are synthesized mainly at S and G₂. Some of the³H-arginine labelled proteins which were synthesized during the first mitotic cell cycle, were found to be incorporated into the chromosomes of the second mitotic cell cycle. The incorporation of the proteins synthesized at one stage of the mitotic cell cycle was found to occur locally in some regions of the chromosomes, while the pattern of incorporation was observed to be similar between euchromatic and heterochromatic regions.     

EXPERIMENTAL CONTROL OF DNA SYNTHESIZING AND DIVIDING CELLS IN EXCISED ROOT TIPS OF PISUM

The number of dividing and DNA-synthesizing cells in excised pea roots can be regulated by eliminating the carbohydrate normally supplied in the culture medium. When the excised roots were allowed to remain for 24 hr in a medium lacking carbohydrate, the number of mitotic figures and tritiated thymidine (H³-T) labeled cells was reduced almost to zero. After an additional 24 hr in the incomplete culture medium, 15% of the interphase cells were H³-T labeled, the percentage of the cells that were dividing never exceeded 1.4, and 30% of these were H³-T labeled. When the roots remained in the deficient medium for 72 hr, neither cell division nor cells synthesizing DNA were observed. Upon addition of 2% sucrose, cell division and DNA synthesis were resumed in the roots that were maintained for 24 or 72 hr without an exogenous carbohydrate supply. It has been hypothesized that some proliferative systems consist of two cellular subpopulations which selectively stop or remain in either the pre-DNA synthetic (G₁) or post-DNA synthetic (G₂) periods of the mitotic cycle. The addition of sucrose, H³-T, and 5-aminouracil to the medium, after the roots had been maintained for 24 hr without a carbohydrate, indicated that most of the proliferative cells in the roots had accumulated in either G₁, a quasi-G₁ condition, i.e., DNA synthesis stopped sometime before completion, or G₂ periods of interphase; the majority, however, were in G₁ or quasi-G₁ conditions. The results suggested that DNA synthesis (S period) and mitosis or the onset of these processes have the highest metabolic requirements in the mitotic cycle and that G₁ and G₂ were the most probable states for proliferative cells in a meristem with a low metabolic level.     

Nucleic acids methylation of synchronized BHK 21 HS 5 fibroblasts during the mitotic phase

The methylation of nucleic acids has been investigated during the cell cycle of an asparagine dependent strain of transformed fibroblasts (BHK 21 HS 5). The synchrony was carried out by a partial asparagine starvation of cells for 24 hours. The amino acid supply induced all cells to enter synchronously the G₁ phase. Methylation and DNA synthesis were respectively measured by pulsed [methyl-¹⁴C] methionine and [methyl-³H] thymidine incorporation. DNA methylation followed a biphasic pattern with maximal methyl incorporations during both S phase and mitosis. A partial desynchronisation induced the S phase of the second cycle to proceed before all the cells have achieved their division. Hydroxyurea was used in order to inhibit the DNA synthesis of cells entering the second cell cycle, which might interfer with the mitosis of the first one. The inhibitor was added either at the first beginning of cell division or during all the G₁ phase. In both conditions it suppressed ³H thymidine incorporation of the second cycle. However, mitosis took place and methylations occurred as in previous experiments. The DNA methylation of the mitotic phase in the first cell cycle could thus be dissociated from the classical post-synthetic DNA maturation and did not correspond to any DNA methylation appearing in the course of the second cell cycle.     

Translational control of immunoglobulin synthesis. I. Repression of heavy chain synthesis

When myeloma cells are incubated at 25 °C the secretion of myeloma protein ceases within 20 minutes. The synthesis of heavy and light chains and the assembly into the completed 7 S immunoglobulin continue at over 40% of the synthetic rate at 37 °C, resulting in an increasing intracellular concentration of myeloma protein with time. When myeloma cells containing an increased myeloma protein pool were re-incubated at 37 °C, there was an initially decreased synthesis of H-chain² relative to L-chain or total protein. Whereas L-chain synthesis returned to the pre-25 °C synthetic rate within 15 minutes, the synthesis of H-chain required over 60 minutes to return to the pre-incubation rate.Myeloma cells maintained in exponential growth contain a larger intracellular pool of H₂L₂ than cells in late stationary phase. When both populations of cells were incubated at 25 °C and the synthesis of H and L-chain protein measured, a reduced synthesis of H-chain was again observed. Exponentially growing cells showed an 80% reduction of H-chain synthesis after 100 minutes at 25 °C. Stationary cells, with the reduced intracellular level of H₂L₂, required 210 minutes to effect an equivalent reduction of H-chain synthesis.The opposite effect on myeloma protein synthesis was observed following depletion of the H₂L₂ pool. The intracellular H₂L₂ pool was reduced by allowing secretion in the absence of protein synthesis. When protein synthesis was allowed to continue following the depletion, a stimulation of myeloma protein synthesis relative to total protein synthesis was observed.These experiments suggest a close relation between the intracellular level of H₂L₂ and the production of H-chain. From the rapidity of the repression and de-repression of H-chain synthesis, a regulation at the translational level is suggested.     

Expression of the mitochondrial genome in HeLa cells. XXI. Mitochondrial protein synthesis during the cell cycle

Chloramphenicol sensitive [³H]leucine incorporation into protein (due to mitochondrial protein synthesis) in synchronized HeLa cells has been found to continue throughout interphase, its rate per cell approximately doubling from the G₁ to the G₂ phase. This increase in the rate of [³H]leucine incorporation during the cycle does not seem to parallel closely the increase in cell mass. In fact, the observations made on cultures incubated at 34.5 °C, where the G₁ and S phases are better resolved than at 37 °C, indicate that the rate remains constant during the G₁ phase, and starts to accelerate with the onset of nuclear DNA synthesis. Correspondingly, on a per unit mass basis, there appears to be a slight decline in the rate of [³H]leucine incorporation into protein during the G₁ phase, which is compensated by an increase in the early S phase. No significant variations were observed in the mitochondrial leucine pool labeling during the cell cycle; therefore, the observed pattern of [³H]leucine incorporation into protein should reflect fairly accurately the behavior of mitochondrial protein synthesis. Evidence has been obtained indicating a depression in the rate of incorporation of [³H]leucine into protein in mitochondria of mitotic cells. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis of the products of mitochondrial protein synthesis has not revealed any differences in the size distribution of the proteins synthesized in the various portions of the cell cycle.     

CELL MITOTIC CYCLE SYNTHESIS OF NIL HAMSTER GLYCOLIPIDS INCLUDING THE FORSSMAN ANTIGEN

The synthesis of phospholipids and glycolipids during the cell mitotic cycle of an established hamster line, NIL, has been studied. Cells were synchronized with excess thymidine and mitotically harvested by shaking. Cells were radioactively labeled for 4 h with palmitate, glucosamine, or galactose. Lipids were analyzed by thin-layer chromatography. As cells progressed through the mitotic cycle, incorporation into phospholipids increased but the fraction represented by each remained constant. Similarly, ceramide monohexoside, dihexoside, and hematoside were labeled equally in all phases. Ceramide trihexoside and tetrahexoside were labeled only during G₁ and S. Ceramide pentahexoside (the Forssman antigen) shows density-dependent synthesis, accumulation, and reactivity. Ceramide pentahexoside was labeled during all phases of the mitotic cycle but the rate of incorporation decreased in S and G₂. The total amount of lipid assayed immunologically in cell extracts gradually increased. Exposure of the Forssman antigen in untreated or trypsin-treated cells was studied using binding of chemically labeled antiForssman antiserum. The amount of antigen detected in trypsinized cells increased during G₁ and early S but then remained constant. Mitotic cells exposed all detectable antigen. As cells progressed through the mitotic cycle, a large fraction of the Forssman antigen became cryptic.     

Synthesis of glycoprotein, glycolipid, protein, and lipid in synchronized L5178Y cells

Synthesis of four macromolecular classes found in membranes—glycoprotein, glycolipid, protein, and lipid—was measured as a function of time of the cell cycle in synchronized L5178Y cells. Incorporation of leucine, choline, fucose, glucosamine, or thymidine into the cells, protein, nucleic acid, or lipid was measured by pulse-labeling for ½ hr at ½ hr intervals after release from the mitotic block. The amount of protein, lipid, glycoprotein, or glycolipid released or secreted into the medium by the L5178Y cells was also measured as a function of time of the cell cycle. Cellular protein was found to be synthesized throughout the cell cycle, with the highest synthesis occurring in the S period; synthesis was depressed in the M period. Cellular glycoprotein was synthesized at approximately the same times as protein, except that the rates of glycoprotein synthesis in the S period relative to other periods were much greater than for protein. Secreted protein was synthesized throughout the cell cycle without any general pattern, except that secretion was elevated in the late S and G₂ periods. Secreted glycoprotein was similar to secreted protein. Cellular lipid and cellular glycolipid were synthesized almost exclusively in the G₂ and M periods; there was no synthesis in the G₁ and S periods. Release or secretion of glycolipid and lipid also occurred in the G₂ and M periods.     

DNA synthesis and the cell cycle in cultures of normal and mutant (mdg/mdg) embryonic mouse muscle cells.

The relationship between cell fusion, DNA synthesis and the cell cycle in cultured embryonic normal and dysgenic ($\text{mdg}\text{mdg}$) mouse muscle cells has been determined by autoradiography. The experimental evidence shows that the homozygous mutant myotubes form by a process of cell fusion and that nuclei within the myotubes do not synthesize DNA or undergo mitotic or amitotic division. The duration of the total cell cycle and its component phases was statistically the same in 2-day normal and mutant ($\text{mdg}\text{mdg}$) myogenic cultures with the approximate values: T, 21.5 hr; G₁, 10.5 hr; S, 7.5 hr; and G₂, 2.5 hr. In both kinds of cultures, labeled nuclei appeared in myotubes 15–16 hr after mononucleated cells were exposed to [³H]thymidine, and the rate of incorporation of labeled nuclei into multinucleated muscle cells was comparable in control and dysgenic cultures. Thus, homozygous $\text{mdg}\text{mdg}$ muscle cells in culture are similar to control cells with respect to their mechanism of myotube formation and the coordinate regulation of DNA synthesis and the cell cycle during myogenesis.     

Synthesis of sulfated proteoglycans throughout the cell cycle in smooth muscle cells from pig aorta

Cultured smooth muscle cells from pig aorta arrested in G0 phase by serum deprivation were stimulated to proliferate by replacing the medium with one containing 10% serum. Studies in DNA replication and proliferation of cells showed a relatively good synchrony: 90% of the cells were in G1 phase for 16 h after addition of serum; they entered S phase between 18 and 24 h, completed S phase and traversed G2 phase between 24 and 30–32 h; 75% of these cells multiplied after 30–32 h and the remainder were blocked at the end of G2 phase. The synthesis and secretion of sulfated proteoglycans were examined throughout a full cell cycle using metabolic labelling with [³⁵S]sulfate. Smooth muscle cells in G1 or G2 phase synthesized and secreted sulfated proteoglycans with a possible pause at the end of the G2 phase but at the beginning of the S phase and during mitosis the incorporation of [³⁵S]sulfate into these macromolecules stopped entirely. Structural characteristics of sulfated proteoglycans secreted into the medium during G1 phase and an entire cell cycle were investigated. The proportion of proteoglycan complexes and the relative hydrodynamic size of monomers and of constituent subunits of complexes were determined after chromatography on Sepharose CL-2B and CL-6B columns run under both associative and dissociative conditions. No significant differences were observed for the periods of the cell cycle that were studied:

1. 1. [³⁵S]Proteoglycan complexes represented at the end of G1 phase and of the cell cycle respectively 19 and 16% of the total [³⁵S]proteoglycans secreted into the medium.

2. 2. More than 90% of the subunits, obtained after dissociation of complexes, were characterized by a similar k_av after chromatography on Sepharose CL-2B columns eluted under dissociative conditions (k_av 0.68 at the end of G1 phase and 0.65 at the end of full cell cycle).

3. 3. About 95% of monomers synthesized at the two stages of the cell cycle were eluted at k_av 0.25 after chromatography on Sepharose CL-6B column run under associative conditions and were characterized by a similar glycosaminoglycan distribution. These results suggest that smooth muscle cells in culture liberate similar populations of proteoglycans into the medium during the G1 and G2 phases.

     

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.     

H3-THYMIDINE DERIVATIVE POOLS IN RELATION TO MACRONUCLEAR DNA SYNTHESIS IN TETRAHYMENA PYRIFORMIS

The formation of a soluble H³-thymidine derivative pool has been examined in Tetrahymena pyriformis as a function of macronuclear DNA synthesis during the cell life cycle. An autoradiographic technique which allows the detection of water-soluble materials within a cell has shown that these cells do not take up and retain exogenous H³-thymidine during G1 or G2. Uptake of H³-thymidine is restricted to the S period of the cell cycle. Additional autoradiographic experiments show, however, that a soluble pool of H³-thymidine derivatives persists from the end of one DNA synthesis period to the beginning of the next synthesis period in the subsequent cell cycle. Since this persisting pool cannot be labeled with H³-thymidine, the pool does not turn over during non-S periods.     

A CHARACTERIZATION OF THE BOUNDARY BETWEEN THE CYCLING AND RESTING STATES IN ASCITES TUMOR CELLS

Growth deceleration of an Ehrlich ascites tumor with increasing mass is associated with a prolongation of the cell cycle and a decline in the growth fraction. These effects are reversed upon transfer of cells from an older tumor into a new host. Studies were made to locate the stages at which a cell cycle could be suspended or resumed. Transplantation caused a prompt rise in both mitotic and flash H³TdR labeling indices. When all the cells in cycle including mitoses were prelabeled with H³TdR in older tumors, the fraction of labeled mitoses did not decline for a considerable period after transplantation into new hosts. This suggests that the early rise in mitoses is not due to a flow of resting (G_o) cells from a G² store (G²-G^o transition). It appears rather to be a reflection of a lag of the mitotic process relative to other stages during the initial readjustment of the cycle. A prompt rise in flash H₃TdR indices in the transplants suggested cell entry into S from either a suspended G_I (G₁-G_o transition) or a suspended S (S-G_o transition). These possibilities were examined by relating micro-spectrophotometric estimates of DNA to the cell cycle stage as revealed by H³TdR autoradiography. Since G_o cells had DNA values corresponding to G_I, it was concluded that decycling or recycling could occur only after mitosis and before DNA synthesis.     

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.     

The specificity of epidermal chalone action: the results of in vivo experimentation with two purified skin extracts.

To date two inhibitors of epidermal cell proliferation have been characterized: (1) a factor which depresses DNA synthesis, and (2) a factor which depresses mitotic rate. In the absence of experimental proof it has been assumed that the respective targets for these purified inhibitory factors are in G₁ and G₂ phases of the cell cycle. In the experiments reported here both these fractions were subjected to cell cycle phase specificity tests in order to verify these assumptions. In addition, an epidermally derived “cell line” (the sebaceous gland) and two nonectodermal tissues were examined for a response. The results suggest that the response induced by the inhibitor of DNA synthesis is cell cycle phase-specific, that the target cells are at the G₁-S phase boundary, and that only epidermal cells respond. Similarly the factor which depresses the flow of cells from G₂ into mitosis had no measurable effect on DNA synthesis by any of the tissues tested. The G₂ inhibitor lacks an inhibitory effect on mitosis in the sebaceous gland.The physiological roles which epidermal chalones may play are briefly discussed. It is suggested that a G₁–G₂ chalone system may have been effective in isolating kinetically cell populations with modified function during the evolutionary development in the vertebrates.     

Changes in the mitotic cycle in lateral root meristems of Vicia faba following kinetin treatment

Roots of Vicia faba were treated with H³-Thymidine (1 C/ml) for one hour, either before or after a three hour treatment with a 10^–5 M solution of kinetin. The durations of the mitotic cycle and its constituent phases were then derived from the curves recording the rhythmic entry and exit of labeled cells in prophase, both for the kinetin treated roots and the controls. The rate of DNA synthesis was also determined for the control roots and for roots exposed to H³-Thymidine immediately following treatment with kinetin. — Control values for the durations of the mitotic cycle, G1, S, G2 and mitosis were in agreement with most of the results reported in the literature. Kinetin treatment resulted in an increase in the rate of DNA synthesis, but did not affect the number of cells undergoing DNA synthesis, i.e. kinetin, or a similar compound, may be involved in the control of the rate of DNA synthesis in plant root meristems, but it does not appear to be involved in the control of the initiation of the S period of interphase. — The durations of G1 and G2 are shorter and longer respectively in the kinetin treated roots as compared with the control values. Changes in the durations of these phases of interphase, S, cycle time and the rate of cell proliferation have been discussed with respect to time after kinetin treatment and their possible relationship to carbohydrate metabolism.Research supported by an Assistant Professor Research Grant from the University of Missouri — St. Louis.     

Nuclear translocation of Cyclin B1 marks the restriction point for terminal cell cycle exit in G2 phase

Upon DNA damage, cell cycle progression is temporally blocked to avoid propagation of mutations. While transformed cells largely maintain the competence to recover from a cell cycle arrest, untransformed cells past the G1/S transition lose mitotic inducers, and thus the ability to resume cell division. This permanent cell cycle exit depends on p21, p53, and APC/C^Cdh1. However, when and how permanent cell cycle exit occurs remains unclear. Here, we have investigated the cell cycle response to DNA damage in single cells that express Cyclin B1 fused to eYFP at the endogenous locus. We find that upon DNA damage Cyclin B1-eYFP continues to accumulate up to a threshold level, which is reached only in G2 phase. Above this threshold, a p21 and p53-dependent nuclear translocation required for APC/C^Cdh1-mediated Cyclin B1-eYFP degradation is initiated. Thus, cell cycle exit is decoupled from activation of the DNA damage response in a manner that correlates to Cyclin B1 levels, suggesting that G2 activities directly feed into the decision for cell cycle exit. Once Cyclin B1-eYFP nuclear translocation occurs, checkpoint inhibition can no longer promote mitotic entry or re-expression of mitotic inducers, suggesting that nuclear translocation of Cyclin B1 marks the restriction point for permanent cell cycle exit in G2 phase.