Cell cycle-dependent protein secretion by Saccharomyces cerevisiae.

Synchronized Saccharomyces cerevisiae cell populations were used to examine secretion rates of a heterologous protein as a function of cell cycle position. The synchronization procedure had a profound effect on the type and quality of data obtained. When cell synchrony was induced by cell cycle-arresting drugs, a significant physiological perturbation of cells was observed that obscured representative secretion data. In contrast, synchronization with centrifugal elutriation resulted in synchronized first-generation daughter cells with undetectable perturbation of the physiological state. The synchronized cells did not secrete significant amounts of protein until they reached cell division, suggesting that the secretion process in these cells is strongly cell cycle dependent. However, the maximum secretion rate of the synchronized culture (7-14 molecules/cell/second) was significantly lower than that of an asynchronous culture (29-51 molecules/cell/second). This result indicates that young daughter cells isolated in the synchronization process exhibit different protein secretion behavior than older mother cells that are absent in the synchronized cell population but present in the asynchronous culture.     

Approximation of the cell cycle in synchronized populations of Streptococcus faecium.

Slowly growing populations (TD = 70 to 80 min) of Streptococcus faecium (S. faecalis ATCC 9790) were synchronized by selection after sucrose gradient fractionation. The cell cycle was approximated by correlating the patterns of DNA accumulation and cell division. More specifically, the beginning of cell cycle was equated with the beginning of a rapid linear increase in DNA accumulation. The DNA content of the culture approximately doubled during the period of accumulation, which lasted about 51 min. The period of rapid DNA accumulation, was followed by a period of reduced accumulation that lasted about 24 min. During synchronized growth, cell numbers increased rapidly in coordination with the period of rapid DNA accumulation and exhibited a plateau during the period of reduced DNA accumulation. In contrast, RNA and protein appeared to accumulate exponentially throughout the cell cycle at the same rate as culture mass.     

Cell cycle-dependent regulation of N-acetylglucosaminyltransferase-III in a human colon cancer cell line, Colo201

The mechanism for cell-cycle-dependent regulation of N-acetylglucosaminyltransferase III (GnT-III) activity was investigated using synchronized culture of Colo201, a human colon cancer cell line. In the synchronized culture, it was found that GnT-III activity rapidly increased in the M phase and the maximal activity was five times higher than the basal level found in the G1 phase. Northern blot and Western blot analyses revealed that the increase in the activity is due not to an increase in expression level of its mRNA but, rather, to the level of protein. Furthermore, it was shown by a pulse-chase experiment that the increased protein level of GnT-III is the result of its prolonged turnover rate. Lectin blotting with erythroagglutinating phytohemagglutinin showed that the content of bisecting N-acetylglucosamine structure in glycoproteins was transiently increased during the M phase in conjunction with the increased activity of GnT-III. These results suggest that GnT-III activity undergoes a cell-cycle-dependent regulation and thereby oligosaccharide structures of N-glycans vary specifically during the M phase of the cell cycle. Thus, it is possible that the cell-cycle-dependent alteration of N-glycans by GnT-III might play a role in biological events, such as the progression of cell cycle and cell division.     

Arachidonic acid release and prostaglandin biosynthesis in synchronized rat embryo fibroblasts

Arachidonic acid (AA) release and prostaglandin (PG) biosynthesis were studied in rat embryo fibroblasts (R 129) synchronized by double thymidine-excess block. Whatever the culture medium was (medium 199 supplemented with 10% fetal calf serum (FCS) or 1% FCS plus 0.1% bovine serum albumin (BSA], AA release rapidly increased until the 4th hour of the cell cycle (S phase), remained on a plateau in G2M and G1 phases and did not increase again in the S phase of the following cell cycle. Time course and amplitude of AA release in synchronized cells did not differ from what it was observed after the simple renewal of the culture medium in asynchronous cells. So AA release seemed to be independent of the cell cycle. By contrast, PGE2 and PGF2 alpha biosynthesis clearly increased in the S phase of two consecutive cell cycles, indicating that cyclooxygenase activity and not phospholipase A2 activity vary according to the cell cycle.     

Control of cell division in hepatoma cells by exogenous heparan sulfate proteoglycan

The effects of cell surface heparan sulfate proteoglycan (HSPG) prepared from log and confluent monolayers of a rat hepatoma cell line on hepatoma cell growth were studied. When HSPG isolated from confluent cells was added exogenously to log phase cells, it was internalized and free heparan sulfate (HS) chains appeared transiently in the nucleus. Concurrently, the growth of the treated cells was inhibited, but the cells resumed logarithmic growth as the level of nuclear HS fell, and the cells grew to confluence and became contact inhibited. When HSPG prepared from log-phase hepatoma cells was added exogenously to log phase cells, it was internalized but very little of the internalized HS appeared in the nucleus, and there was no change in the rate of cell growth. However, when the rate of cell growth was reduced by culture of the cells in serum- and insulin-deficient medium, HSPG prepared from log-phase cells stimulated the growth rate of these slow-growing cells. The cell cycle dependency of HSPG uptake and growth inhibition was studied in cultures synchronized by a thymidine/aphidicolin double block. When [35SO4]HSPG from confluent cells was added to synchronized cells just as they were released from the second block, a portion of the [35SO4]HSPG was internalized and [35SO4]HS appeared in the nucleus. However, at mitosis the [35SO4]HS disappeared almost completely from all of the cellular pools, and after mitosis, more of the [35SO4]HSPG was taken up and [35SO4]HS reappeared in the nucleus and remained in the nucleus until the cells divided again. When cultures were released from the aphidicolin block, both control and HSPG-treated cells progressed through the S, the G2, and the M phases of the cell cycle. However, the length of the G1 phase of the cycle was increased in the HSPG-treated cells. The treated cultures then progressed through the second S, G2, and M phases. Thus, the inhibition of cell division occurred in the G1 phase of the cell cycle, prior to the G1/S boundary. Addition of the HSPG to the synchronized cultures just after the first mitosis resulted in an immediate arrest of the cell cycle in G1.(ABSTRACT TRUNCATED AT 400 WORDS)     

Self-cycling operation increases productivity of recombinant protein in Escherichia coli

Self-cycling fermentation (SCF), a cyclical, semi-continuous process that induces cell synchrony, was incorporated into a recombinant protein production scheme. Escherichia coli CY15050, a lac(-) mutant lysogenized with temperature-sensitive phage λ modified to over-express β-galactosidase, was used as a model system. The production scheme was divided into two de-coupled stages. The host cells were cultured under SCF operation in the first stage before being brought to a second stage where protein production was induced. In the first stage, the host strain demonstrated a stable cycling pattern immediately following the first cycle. This reproducible pattern was maintained over the course of the experiments and a significant degree of cell synchrony was obtained. By growing cells using SCF, productivity increased 50% and production time decreased by 40% compared to a batch culture under similar conditions. In addition, synchronized cultures induced from the end of a SCF cycle displayed shorter lysis times and a more complete culture-wide lysis than unsynchronized cultures. Finally, protein synthesis was influenced by the time at which the lytic phase was induced in the cell life cycle. For example, induction of a synchronized culture immediately prior to cell division resulted in the maximum protein productivity, suggesting protein production can be optimized with respect to the cell life cycle using SCF.     

Changes in the carbohydrate content of the KB cell during the growth cycle

KB cells were grown in suspension culture and synchronized with a double thymidine block. Cells were removed at various times during the cell cycle and analyzed for sialic acid, fucose, mannose and galactose. The mannose, galactose, and fucose contents of the cells all showed a decrease during the mitotic phase. The content of sialic acid decreased, but later in the cycle. When the cell was not dividing the molar rations of sialic acid to fucose: mannose: galactose were approximately 2:5:3 when sialic acid was expressed as 1; the ratios dropped to approximately 1:3:1.5 throughout division. These results indicate that the glycoprotein and/or glycolipid contents of KB cells probably change throughout the cell cycle.     

Dark incubation causes reinitiation of cell cycle events in Anacystis nidulans.

Synchronized cultures of Anacystis nidulans (Synechococcus PCC 6301), an obligate phototroph, are obtained by incubating exponential cultures in the dark for 12 to 16 h. A temporal and sequential order of macromolecular synthesis is observed within the cell division cycle of a synchronously dividing culture in the light. Apparently, dark incubation causes the cells to realign their cellular activities in such a way that all cells emerge from the dark and grow synchronously in the light. A study was conducted to explore the possible mechanisms responsible for the putative dark-induction process. Samples were taken at various times from a synchronized culture and were subjected to another round of dark incubation for 16 h. When these cultures were returned to the light, the cell number increased from 3 h and doubled at about 7 h. The protein, RNA, and DNA contents started to increase in order well before 3 h. This general pattern of cellular activities, observed for nearly all samples (i.e., for cells of different physiological ages), indicated that the dark incubation period caused the ongoing cell cycle to abort and a new cell cycle to be reinitiated under light growth conditions.     

Potassium Uptake in Synchronous and Synchronized Cultures of Escherichia coli

Criteria are presented for distinguishing between synchronous and synchronized cultures (natural vs. forced synchrony) on the basis of characteristics of growth and division during a single generation. These criteria were applied in an examination of the uptake of potassium during the cell growth and division cycle in synchronous cultures and in a synchronized culture of Escherichia coli. In the synchronous cultures the uptake of ⁴²K doubled synchronously with cell number, corresponding to a constant rate of uptake per cell throughout the cell cycle. In the synchronized culture, uptake rates also remained constant during most of the cycle, but rates doubled abruptly well within the cycle. This constancy of ⁴²K uptake per cell supports an earlier interpretation for steady-state cultures that uptake is limited in each cell by a constant number of functional sites for binding, transport, or accumulation of compounds from the growth medium, and that the average number of such sites doubles late in each cell cycle. The abrupt doubling of the rate of uptake of potassium per cell in the synchronized culture appears because of partial uncoupling of cell division from activation or synthesis of these uptake sites.     

Real-time monitoring of yeast cell division by dielectric spectroscopy.

To assay cell cycle progression in synchronized culture of yeast we have applied dielectric spectroscopy to its real-time monitoring. The dielectric monitoring is based on the electromagnetic induction method, regarded as a nonelectrode method, which has resolved the problems encountered in measurements with metal electrodes, namely electrode polarization and bubble formation on electrodes. In the synchronized culture with temperature-sensitive cell division cycle mutants, the permittivity of the culture broth showed cyclic changes at frequencies below 300 kHz. The increase and decrease in the cyclic changes of the relative permittivity correspond to the increase in cell length and bud size and to the septum formation between mother and daughter cells, respectively.     

Experession and integration of genes introduced into highly synchronized plant protoplasts

Summary Chimaeric genes containing the chloramphenicol acetyltransferase (CAT) coding sequence were introduced into protoplasts of suspension-cultured tobacco cells using improved conditions of electroporation (Okada et al. 1986). CAT activity became detectable in the protoplasts within 3 h, was maximal during a period of 18–36 h after electroporation, and then declined gradually. Alpha-amanitin added to the medium abolished the transient expression of the CAT gene. The closed circular form of input DNA was as effective as the linear form for the transient expression. The suspension culture was treated with aphidicolin, and S, G₂, M and G₁ phases were identified in the highly synchronized cell cycle obtained by releasing the cells from the inhibition of DNA synthesis. When a chimacric CAT gene was introduced into M phase protoplasts prepared from the synchronized culture, the transient expression of the CAT gene was 3–4 times higher than when it was introduced into protoplasts of other cell cycle phases. The frequency of stable transformation with a chimaeric neomycin phosphotransferase II gene was studied using the same system. G-418-resistant transformants were obtained from M phase protoplasts at frequencies 2–8 times those obtained from protoplasts at other cell cycle phases. The results indicate that the absence of the nuclear membrane in mitotic cells favours delivery to the nucleus of exogenous DNA introduced into the cytoplasm.     

Flow cytometric cell cycle analysis of cultured brown bear fibroblast cells

The aim of this study was to assess by flow cytometry the cell cycle of brown bear fibroblast cells cultured under different growth conditions. Skin biopsies were taken in Cantabria (Spain) from a live, anaesthetized brown bear. DNA analysis was performed by flow cytometry following cell DNA staining with propidium iodide. Serum starvation increased (P<0.01) the percentage of G0/G1 phase cells (92.7+/-0.86) as compared to cycling cells (39.7+/-0.86) or cells cultured to confluency (87.3+/-0.86). DMSO included for 48h in the culture significantly increased (P<0.01) the percentage of G0/G1 phase of the cell cycle at all concentrations used and decreased percentages of S phase in a dose-dependent fashion. Roscovitine increased the G0/G1 phase of the cell cycle (P<0.01) at 15microM concentration. Interestingly, the G2/M stage significantly increased at 30 and 50microM compared to the control and 15microM (P<0.02). The cell cycle of brown bear adult fibroblast cells can be successfully synchronized under a variety of culture conditions.     

Commitment to differentiation induced by retinoic acid in P19 embryonal carcinoma cells is cell cycle dependent

The rate at which P19 embryonal carcinoma cells in monolayer culture become anchorage dependent during differentiation induced by retinoic acid (RA) was investigated. In both nonsynchronized cultures and cultures synchronized by mitotic selection, the ability to grow in semisolid medium, characteristic of the malignant stem cell, decreased after a lag period of about 12 hr in the continuous presence of RA, prior to an increase in cell generation time. However, striking differences between synchronized and nonsynchronized cultures were observed in their commitment to differentiation following RA removal. After only 2 hr of exposure to RA, synchronized cells continued a program of differentiation in which they became anchorage dependent, while at least 24 hr of exposure was required for exponentially growing cells to become similarly committed. Induction of anchorage dependence by RA was also strikingly cell cycle dependent; 2 or 4 hr of exposure of synchronized cells to RA in G1 phase, when the intrinsic capacity for soft agar growth is low, was sufficient to commit cells to anchorage dependence, but a similar exposure in S phase was not. Together, these results suggested that interactions between cells in different cell cycle phases in asynchronous cultures influenced commitment since exposure to RA for more than one cycle (13 hr) was required for all cells to become anchorage dependent. Increased plasminogen activator secretion and epidermal growth factor binding, markers of certain differentiated cell types, increased only 3 and 5 days after RA addition, respectively, and were not induced by pulsed exposure to RA of less than 24 hr, even in synchronized cells.     

Changes in calcium and magnesium levels during heat-shock synchronized cell division in Tetrahymena

Calcium and magnesium contents were measured in cells of Tetrahymena pyriformis induced to divide synchronously by a multi-heat-shock procedure. During free-running synchronized cell division in complex proteose peptone medium, significant peaks of both calcium and magnesium were observed at points in the cell cycle just prior to division. No such peaks were detected in cells dividing asynchronously in proteose peptone. When synchronized cell division was followed after transfer to an inorganic medium, cell calcium and magnesium levels were observed to decrease in relation to the corresponding cell number increase, indicating that in concentration terms, calcium and magnesium remain fairly constant. This latter result suggests that neither calcium nor magnesium influxes act as triggers for cell division in Tetrahymena and that the fluctuations of these metals seen during the synchronized division cycle in complex medium represent an effect rather than a cause.     

Receptors for B-melanocyte-stimulating hormone exhibit positive cooperativity in synchronized melanoma cells

Cloudman S91 mouse melanoma cells respond in culture to B-melanocyte-stimulating hormone (B-MSH) with changes in morphology, growth rates, and melanin production. The effects of MSH appear to be mediated through a stimulation of the cyclic AMP system. It was reported earlier that at least some of the responses to MSH (increased cyclic AMP production and tyrosinase activity) occur in the G2 phase of the cell cycle [Wong, G., Pawelek, J., Sansone, M., & Morowitz, J. (1974) Nature (London) 248, 351-354] and that the apparent reason for this cell cycle restriction is that receptors for MSH are most active in the G2 phase [Varga, J. M., DiPasquale, A., Pawelek, J., McGuire, J., & Lerner, A. (1974) Proc. Natl. Acad. Sci. U.S.A. 71, 1590-1593]. In this report, we found that by two separate methods of obtaining populations of cells in the G2 phase of their cycle--centrifugal elutriation or synchronization with thymidine--we observed increased binding of MSH by cells in the G2 and possibly late S phases of their cycle. However, cultures of cells passing through their cycle in synchrony were quite different from nonsynchronized (random) cultures. Both synchronized and random cultures expressed receptors for MSH in the G2 and possibly late S phases of their cycle, but synchronized cultures bound severalfold more MSH per cell than random cultures. This increased binding of MSH by synchronized cells was accompanied by an increase in tyrosinase activity and pigment production.(ABSTRACT TRUNCATED AT 250 WORDS)     

An anchorage-dependent locus in the cell cycle for the growth of 3T3 cells

Mouse fibroblasts, 3T3 cells, require a solid surface for continuous growth, but when 3T3 cells, during their exponential phase in Petri dishes, were transferred to a suspension culture, the number of cells roughly doubled by 30 h. During the suspension culture the number of pairing cells (c₂) increased, but that of the single cells decreased. When cells synchronized at mitosis or at the G1-S boundary were transferred to the suspension culture, the number of pairing cells peaked at 30 min and at 10 h, respectively. DNA synthesis began immediately after the cells, which were cultured for 16 h in the suspension, had settled onto the surface of the Petri dishes. When cells in a confluent culture were arrested at an early G1 period and were suspended, the number of pairing cells did not increase. These results indicate that the most important locus for anchorage growth seems to be at a late G1 period of the cell cycle.     

CONTROL OF COLONY AND UNICELL FORMATION IN A SYNCHRONIZED SCENEDESMUS12

Colony formation in a synchronized Scenedesmus could be controlled by the addition of 0.05% Na₃ citrate or 85 μM EDTA to modified Bristol's medium. No unicells were formed; only S. quadricauda-like or S. longispina-type colonies were observed in young cultures grown in that medium. A colony population could be made completely unicellular in 2 days if grown in soil-Bristol's medium and transferred daily. The pleomorphic Scenedesmus was examined in synchronized culture. When the organism was grown in a defined medium in a 15-hr light /9-hr dark cycle on a roller tube rotator at 2-6 rpm and transferred daily, synchrony of cell division and release of the products were achieved. In a synchronized culture 2 doublings/day were recorded, with most cytoplasmic cleavages and all releasing of daughter cells taking place in the dark period. In many observations with several synchronized strains of Scenedesmus, no fixed pattern of release of daughter products from mother cells or colonies was detected. Colonies or unicells had their full spine complement at the time of release. As a cell or colony aged the spines sometimes increased in thickness. Other Scenedesmus strains were examined to provide supporting data.     

Doubling of cell mass is not necessary in order to achieve cell division in cultured human cells

When exponentially growing NHIK 3025 cells were shifted from medium containing 30% serum to medium containing 0.03% serum the rate of net protein accumulation was reduced due to both a reduction in the rate of protein synthesis and an increase in the rate of protein degradation. This change in growth conditions increased the protein doubling time from 18 to 140 h. The cell cycle duration of cells synchronized by mitotic selection was, however, only increased from 17 to 26 h by this treatment. Therefore, when the cells divide by the end of the first cell cycle following synchronization, the cells shifted to 0.03% serum contained far less protein than those growing continuously in 30% serum. Hence, the attainment of a critical cell mass is probably not controlling cell division for cells growing in a balanced state.     

Cell cycle variations of dinucleoside polyphosphates in synchronized cultures of mammalian cells.

Zajdela hepatoma culture cells (ZHC) and mouse embryo fibroblasts (Swiss 3T3) were synchronized in G1 or S phase by serum deprivation and aphidicolin treatment, respectively, to study the variations in adenylyl nucleotide (Ap4X) pool size during the progress of the cell cycle. Only minor variations, which never exceeded a factor of 2, were observed when the Ap4X concentrations were expressed on a cellular basis. The variations were found to be strictly parallel to the ATP variations. Upon release from an aphidicolin block, the minor variations of Ap4X followed DNA synthesis and preceded cytokinesis. When the nucleotide content was compared with the amount of proteins, the faint specific cell cycle changes were almost completely damped when the cells were synchronized by serum deprivation, but remained practically unchanged in the case of aphidicolin synchronization. These results suggest that the observed variations could reflect the accumulation of some nucleotides before cell division. It is not clear yet whether the variation in Ap4X concentration is significant by itself or is simply a phenomenon resulting from changes in the ATP pool.