Measurement of c-myc protein content and cell cycle kinetics of normal and spontaneously transformed murine mastocytes by bivariate flow cytometry

Progressive in vitro culturing of interleukin-3 (IL-3) dependent normal murine mastocytes (PB-3) resulted in a variant cell line (PB-1) able to grow without exogenous IL-3 and which was tumorogenic in syngenic mice. Bivariate flow cytometry was used to evaluate the c-myc protein and DNA content of PB-3 and PB-1 cells. The c-myc protein was detected by specific monoclonal antibodies. Kinetic characteristics of PB-3 and PB-1 cell lines, namely, the duration of the G1, S and G2 + M cell cycle phases were also evaluated using the bromodeoxyuridine (BrdU) pulse-chase method and BrdU/DNA flow cytometry. Levels of c-myc protein in PB-1 cells were about two-fold higher than those of PB-3 cells in all cell cycle phases. Mean duration of the cell cycle (Tc) was 15.3 h for PB-3 cells and 12.4 h for PB-1 cells. Shortening in Tc for the transformed cells was due to a decrease of nearly 30% in mean duration of the G1 phase (from 8 h to 5.7 h). No significant differences were found in the duration of the S and G2 + M phases. These results indicate that acquired IL-3 independency in vitro and tumorogenicity of PB-1 cells were accompanied by a doubling of c-myc protein level and by a parallel shortening, or bypass, of the regulatory events within the G1 phase of the cell cycle.     

Flow cytometric correlation of the c-myc oncoprotein and cell cycle kinetics of HL60 leukaemia during induced maturation with cytosine arabinoside and dimethylsulphoxide

Abstract The c-myc oncogene codes for a DNA binding protein that functions in a cell cycle-related manner. A useful model for studying the relationship of c-myc expression with cell cycle kinetics is the HL60 cell line. HL60 cells constitutively express high levels of c-myc mRNA; however, the level can be down-regulated as the cells are induced to differentiate. We have developed a flow cytometric assay for correlating c-myc oncoprotein levels with DNA content. C-myc oncoprotein levels were additionally correlated with c-myc mRNA levels as determined by slot blot hybridization. Dimethylsulphoxide (DMSO) and cytosine arabinoside were used to induce granulocytic and monocytic maturation respectively. Treatment of HL60 cells with DMSO leads to an increase in the per cent of cells in G₁/G₀ and a decrease in mean c-myc mRNA and oncoprotein levels. The cells with G₁ DNA content show the greatest decrease in c-myc protein. ARA-c treatment of HL60 cells leads to a slowing and an accumulation of cells in S phase with a moderate decrease in mean mRNA and only a slight decrease in mean c-myc protein levels. These data support the hypothesis that c-myc is involved in the switch from G₁ to G₀.     

DNA-synthesizing cells in oral epithelium have a range of cell cycle durations: evidence from double-labelling studies using tritiated thymidine and bromodeoxyuridine

Abstract Mouse tongue epithelium is characterized by a circadian variation in the number of DNA-synthesizing cells (labelling index, LI). Cells undergoing DNA synthesis were labelled with tritiated thymidine ([³H]TdR) at 0300 (peak LI) or 1200 h (low LI). The fate of these cells was assessed by injecting animals with bromodeoxyuridine (BrdU) at intervals from 12–48 h after [³H]TdR, to follow them from one cell cycle to the next. Labelling was revealed by combining [³H]TdR autoradiography with immunoperoxidase detection of BrdU in the same sections.
A single peak in the appearance of double-labelled cells was seen at 44 h, if [³H]TdR was given at 1200 h; following [3H]TdR at 0300 h, a peak of double labelling was seen at 48 h with the possibility of smaller peaks at 24 h and 36 h.
These results show that the 24 h periodicity in LI in this tissue is associated with a predominant cell cycle duration of 44–48 h, but that a few cells cycle more quickly. Double labelling with [³H]TdR and BrdU provides a useful method for establishing cell cycle duration by labelling S-phase cells in successive cell cycles.     

Age-related changes in the cell kinetics of rat foot epidermis

Abstract. The durations of the cell cycle and its component phases have been determined for the basal layer of the epidermis of the skin from the upper surface of the hind foot of the rat using single pulse [³H]-thymidine labelling and the percent labelled mitosis (PLM) technique. Rats of three age groups were used, namely 7, 14 and 52 weeks. The duration of DNA synthesis (T_s) and the G₂ plus M phase (Tg₂± m) were comparable in 7-week and 52-week-old rats ( P > 0–1). The major difference between 7-week and 52-week-old rats was in the duration of the G₁ phase (Tg₁). In 7-week-old rats Tg₁ was 15.0 ± 0.8 h and in 52-week-old rats Tg₁ was 31.2 ± 3.5 h. A consequence of this variation was that the overall duration of the cell cycle was longer in 52-week-old rats (53.9 ± 5.3 h) than in 7-week-old rats (30.1 ± 1.3 h).
Difficulties were found in fitting a simple curve to the PLM data for 14-week-old rats. This suggests that the proliferative cell population of the epidermis of rats of this age group may be heterogeneous. A satisfactory fit to the data was obtained using a computer model which assumed that the proliferative population of the epidermis of 14-week-old rats was a mixture of cells with cell cycle parameters the same as those of the 7-week and the 52-week-old rats. These two sub-populations of relatively slowly and rapidly proliferating cells were present in the ratio of 2:1.     

Long duration of mitosis and consequences for the cell cycle concept, as seen in the isthmal cells of the mouse pyloric antrum. II. Duration of mitotic phases and cycle stages, and their relation to one another

Abstract. The kinetics of isthmal cells in mouse antrum were examined in three ways: (a) the duration of cell cycle and DNA-synthesizing (S) stage was measured by the 'fraction of labelled mitoses' method; (b) the duration of interphase and mitotic phases was determined from how frequently they occurred; and (c) mice were killed at various intervals after an intravenous injection of ³H-thymidine to time the acquisition of label by the various phases of mitosis.
The duration of the isthmal cell cycle was found to be 13.8 hr and that of the DNA-synthesizing (S) stage, 5.8 h. Estimates for the duration of the G₁ and G₂ stages were 6.8 and 1.0 hr, respectively.
From the frequency of mitotic phases, defined as indicated in the preceding article (El-Alfy & Leblond, 1987) and corrected for the probability of their occurence, it was estimated that prophase lasted 4.8 hr; metaphase, 0.2 hr; anaphase, 0.06 hr and telophase, 3.3 hr, while the interphase lasted 5.4 hr. In accordance with this, the duration of the whole mitotic process was 8.4 hr.
Ten minutes after an intravenous injection of ³H-thymidine, 38% of labelled isthmal cells were in interphase and 62% in early or mid prophase, while cells in late prophase and other mitotic phases were unlabelled. After 60 min, label was in late prophase, after 120 min, in mid telophase and after 180 min, in late telophase.
We conclude that there is overlap between some mitotic phases and cycle stages. Thus, while nuclei are at interphase during the early third of S, they are in prophase during the late two-thirds as well as during G₂. Also, nuclei are in telophase during the early half of G₁ but at interphase during the late half. Differences in nuclear diameter show that subdivision of both S and G₁ into early and late periods is practical.     

CARTILAGE CELL PROLIFERATION IN THE TAIL-VERTEBRAE of NEW-BORN RATS

Cartilage cell proliferation has been studied in the tail-vertebrae of new-born rats. At 1 day the median cycle time for cartilage cells was about 22 hr; G¹+ 1/2M, S, and G²+ 1/2M being 6.8 ± 2.5, 11.6 ± 2.2, and 4.6 ± 2.0 hr respectively. At 7-10 days, cell proliferation is confined mainly to the lower half of the epiphysis. Here cycle times are longer, about 3 1/2 days in the most active region. Differences in cycle times appear to be due to either a lengthening of G¹ or the entry of cells into a resting state. Changes in cartilage cell kinetics are discussed in relation to the structure and function of the epiphysis.     

Laser scanning cytometer (LSC) analysis of fraction of labelled mitoses (FLM)

Abstract. In this report we describe the successful application of a novel microscope-based multiparameter laser scanning cytometer (LSC) to measure duration of different phases of cell cycle in HL-60 human leukaemic cell lines by the fraction of labelled mitoses (FLM) method. Exponentially growing cells were harvested after various time intervals following pulse-labelling with 5'-bromo-2'-deoxyuridine (BrdUrd), cytocentrifuged, fixed in ethanol, and then exposed to UV light to induce DNA strand breaks at the sites of incorporated BrdUrd. The 3'OH termini of the photolytically generated DNA strand breaks were labelled with BrdUTP in the reaction catalysed by exogenous terminal deoxynucleotidyl transferase (TdT), followed by FITC-labelled BrdUrd antibodies. DNA was counterstained with propidium iodide (PI). Due to differences in chromatin structure between the interphase and mitotic cells, the LSC identified the latter by virtue of their higher red (PI) fluorescence intensity values among all pixels over the measured cell. To confirm that the cells selected were indeed cells in mitosis, predominantly in metaphase, the recorded X-Y coordinates of selected cells were used to re-position the cell for their visual examination. From the time lapse analysis of percentage BrdUrd-labelled cells progressing through mitosis it was possible to calculate the duration of individual phases of the cell cycle. The duration of S (T_s) and G₂+ M (T_G2+M) was 8 and 3 h, respectively, and the minimal duration of G₂ (T_G2) was 2 h. The cell cycle time (T_c) estimated for the cohort of the most rapidly progressing cells was 13 h. The ability to automatically and rapidly discriminate mitotic cells combined with the possibility of their subsequent identification by image analysis makes LSC the instrument of choice for the FLM analysis.     

A dual block to cell cycle progression in HL60 cells exposed to analogues of vitamin D,

Abstract. The physiologically active form of vitamin D₃, 1,25-dihydroxy-vitamin D₃, (1,25(OH)₂, D₃), induces differentiation of several types of myeloid leukaemia cells. The acquisition of monocyte-like phenotype is accompanied by slower progression through the cell cycle, and G₁, block has been reported to be the basis of this effect. It is shown here that human promyelocytic leukaemia HL60 cells treated with analogues of vitamin D₃, which are potent inducers of monocytic differentiation, have an additional cell cycle block. Exposure to 10-⁷m 1,25(OH)₂, D₃, or 1,25-(OH)₂,-16-ene-D₃ resulted in monocytic differentiation and the expected G₁, block evident at approximately 48 h in a rapidly differentiating variant of HL60 cells (HL60-G), and at 96 h in the more slowly differentiating HL60-240 cells. In addition, a G₂,+M block was noted at approximately 72 h in HL60-G and HL60-240 cells. Exposure to vitamin D₃, analogues also markedly increased the number of dikaryons, suggesting that cytokinesis was impaired more than karyokinesis. Treatment with a third analogue 25-hydroxy-16,23-diene-D₃, produced little differentiation and had minimal effects on the cell cycle parameters. These findings indicate that vitamin D₃, analogues regulate cell proliferation by control of the transition of G₁, and G₂,+M phases, reminiscent of the cdc2/CDK2 type of cell cycle control.     

CELL CYCLE PROPERTIES OF DIFFERENTIATING SPERMATOGONIA IN ADULT SPRAGUE-DAWLEY RATS

The duration of the mitotic cycle and of its components was analysed for each of the six successive generations of differentiating spermatogonia (A₁, A₂, A₃, A4, intermediate and B), using radioautographed whole mounts of seminiferous tubules from testes of adult Sprague-Dawley rats. Cell cycles were determined from two successive waves of per cent labeled metaphases obtained during the period of 81 hr after a single dose of ³H-thymidine. Except for the A₁ spermatogonia, all spermatogonial types (A₂ to B) had similar cell cycle durations of 41-42.5 hr and comparable pre-DNA synthesis phases (G₁) of 11-13 hr. Although the combined duration of DNA synthesis (S) and the post-synthesis phase (G₂) remained identical for all the cell types including A₁, there was a progressive lengthening of the S period at the expense of G₂ during the process of spermatogonial maturation. This change was most marked during the transition from A₁ to A₃ spermatogonia when the S period increased from 14 hr to 21 hr, and the G₂ phase shortened from 13 hr to 7.5 hr. This feature seems to be unique to germ cells and may be associated with an increasing amount of heterochromatin in the nucleus. Excluding the development of type A₁ cells, the entire process of spermatogonial maturation lasted for 208 hr. Combined data on cell cycle times indicated that every 313 hr or 13 days, a new sequence of spermatogonial differentiation was initiated by the A₁ cells. This was equivalent to the duration of one 'cycle' of the seminiferous epithelium as measured by other techniques.     

The effects of interleukin 4 on the cell cycle of a human B-cell lymphoma line

Abstract. Exposure of Farage, a human B-cell lymphoma line, to IL-4 for 3–11 days led to inhibition of tritiated thymidine ([³H]dT) uptake by the cells. Study of the incorporation of 5-bromodeoxyuridine by Farage cells showed that IL-4 reduced significantly the number of cells in the S phase of the cell cycle and increased the proportion of cells in the G₁ phase. Limiting dilution analysis of proliferation demonstrated that IL-4 decreased the frequency of clone-forming cells by 40%. IL-4 did not reduce the viability of Farage cells. On the contrary, IL-4 diminished the spontaneous death of Farage cells in culture, as determined by pulse chase analysis of cells which were labelled with [³H]dT. Moreover, the pre-treatment of Farage cells with IL-4 prevented their death induced by exposure to a high dose of staurosporine. IL-4 abrogated the staurosporine-induced arrest of cells in the G₂+ M phase and replaced it by accumulation of cells in the G₁ phase. IL-4 protected Farage cells from the radioactive suicide caused by the uptake of [³H]dT by dividing cells. The cytokine failed to prevent the damage to Farage cells exerted by mitomycin C, which affected cellular DNA regardless of the phase of the cell cycle. The data obtained showed that IL-4 inhibited the division of B cells by arresting their progression through the early stages of the cell cycle. This inhibition of the cell efflux from G₁ phase plays an important role in the protection against cell death during further stages of the cell cycle.     

Changes in sodium and potassium in Nitellopsis cells treated with transient salt stress

Abstract. Nitellopsis cells grown in fresh water have a relatively low cytoplasmic Na⁺ (11 mol m⁻³) and high cytoplasmic K⁺ (90 mol m⁻³) content. A 30-min treatment with 100 mol m⁻³ external NaCl resulted in a high [Na⁺]_c (90 mol m⁻³) and a low [K⁺]_c (33 mol m⁻³), Subsequent addition of external Ca²⁺ (10 mol m⁻³) prevented Na⁺ influx and then [Na⁺]_c decreased slowly. Changes in [K⁺]_c were opposite to [Na⁺]_c. During the recovery time vacuolar Na⁺ increased, while vacuolar K⁺ decreased. Since all these processes proceeded also under ice-cold conditions, the restoration of original cytoplasmic ion compositions is suggested to be a passive nature. The notion that the passive movement of ions across the tonoplast can act as an effective and economic mechanism of salt tolerance under transient or under mild salt stress conditions is discussed.     

In Human Fetal Astrocytes Exposure to Interleukin-1β Stimulates Acquisition of the GD3+ Phenotype and Inhibits Cell Division

Abstract: In human astrocyte cultures established from second-trimester fetal brain tissue, ∼5–10% of total astrocyte population in unstimulated cultures were GD3⁺/glial fibrillary acidic protein (GFAP)⁺. The GD3⁺ cells were always GFAP⁺ and grew as flat, highly spread cells but changed to process-bearing cells after interleukin-1β (IL-1β) stimulation. It is interesting that IL-1β, a known mitogen for rat astrocytes, suppressed human fetal astrocyte proliferation as determined by [³H]thymidine incorporation, bromodeoxyuridine (BrdU) labeling, and cell counting. The GD3⁺ population, however, consistently increased in absolute number after IL-1β stimulation, in a dose- and time-dependent manner. The IL-1β-mediated increase in number of GD3⁺ astrocytes was independent of initial cell density or serum concentration. By flow cytometry, IL-1β enhanced both the mean fluorescence intensity and the percentage of GD3⁺ cells. To investigate whether the increase in GD3⁺ astrocyte cell number was due to proliferation of preexisting GD3⁺ astrocytes or due to conversion of GD3⁻ to GD3⁺ cells, we performed BrdU/GD3 double immunocytochemistry. BrdU/GD3 double-positive cells were extremely rare in both control and IL-1β-stimulated cultures. Moreover, an increase in number of GD3⁺ astrocytes was still observed in control and IL-1β-stimulated cultures where GD3⁺ cells had been initially eliminated by cell sorting. These results indicate that GD3⁺ astrocytes in human fetal culture may represent a postmitotic, differentiated, distinct phenotype.     

Cell cycle progression in human cells following re-oxygenation after extreme hypoxia: consequences concerning initiation of DNA synthesis

Abstract. The initiation of DNA synthesis and further cell cycle progression in cells during and following exposure to extremely hypoxic conditions in either G₁ or G₂+M has been studied in human NHIK 3025 cells. Populations of cells, synchronized by mitotic selection, were rendered extremely hypoxic (< 4 p.p.m. O₂) for up to 24n h. Cell cycle progression was studied from flow cytometric DNA recordings. No accumulation of DNA was found to take place during extreme hypoxia. Cells initially in G₁ at the onset of treatment did not enter S during up to 24 h exposure to extreme hypoxia, but started DNA synthesis in a highly synchronous manner within 1.5 to 2.25 h after reoxygenation. The duration of S phase was only slightly affected (increased by ≅10%) by the hypoxic treatment. This suggests that the DNA synthesizing machinery either remains intact during hypoxia or is rapidly restored after reoxygenation. Cells initially in G₂ at the onset of hypoxia were able to complete mitosis, but further cell cycle progression was blocked in the subsequent G^ Following reoxygenation, these cells progressed into S phase, but the initiation of DNA synthesis was delayed for a period corresponding to at least the duration of normal G₁ and did not appear in a synchronous manner. In fact, cell cycle variability was found to be increased rather than decreased as a result of exposure to hypoxia starting in G₂. We interpret these findings as an indication that important steps in the preparation for initiation of DNA synthesis take place before mitosis. Furthermore, the change in cell cycle duration induced by hypoxia commencing in G₁ is of a nature other than that induced by hypoxia commencing in other parts of the cell cycle.     

Pharmacological evidence that stalk cell differentiation involves increases in the intracellular Ca(2+) and H(+) concentrations in Dictyostelium discoideum

Differentiation-inducing factors (DIFs) are required for stalk cell formation in Dictyostelium discoideum . In the present study, in order to support our hypothesis that DIFs may function via increases in [Ca²⁺]_c and [H⁺]_c, we investigated the combined effects of 5,5-dimethyl-2,4-oxazolidinedione (DMO, a [H⁺]_c-increasing agent), thapsigargin (Tg) and BHQ ([Ca²⁺]_c-increasing agents) on in vitro stalk cell formation in several strains. DMO, in combination with Tg or BHQ, induced stalk cell formation in a DIF-deficient mutant HM44. Although the rates of stalk cell induction by the drugs were low in the presence of cerulenin (an inhibitor of endogenous DIF production) in HM44 and V12M2 (a wild-type strain), the drugs succeeded in inducing sufficient stalk cell formation when a small amount of DIF-1 was supplied. Furthermore, co-addition of DMO, BHQ and a small amount of DIF-1 also induced sufficient stalk cell formation in AX-4 (an axenic strain) and HM1030 ( dmtA ⁻) but not in CT15 ( dimA ⁻). The drugs suppressed spore formation and promoted stalk cell formation in both HM18 (a sporogenous mutant) and 8-bromo-cAMP-stimulated V12M2. The present results suggest that DIFs function, at least in part, via increases in [Ca²⁺]_c and [H⁺]_c in D. discoideum .     

EFFECTS OF PHYTOCHROME AND BLUE-NEAR ULTRAVIOLET LIGHT-ABSORBING PIGMENT ON DURATION OF COMPONENT PHASES OF THE CELL CYCLE IN ADIANTUM GAMETOPHYTES

Single-celled protonemata of the fern Adiantum capillus-veneris, kept under continuous red light, grew with a very low rate of cell division, and the cell cycle was arrested in the early G₁ phase. Cell division was induced by transferring the protonemata to the dark after various light treatments, and the duration of component phases in the cell cycle was determined by a continuous-labelling technique with 3H-thymidine. Blue light irradiation greatly reduced the duration of the G₁ phase but did not affect that of other phases. The greater the fluence of blue light, the shorter was the duration of G₁ phase was observed. In contrast, a brief exposure of red-light-grown protonemata to far-red light given immediately before the dark incubation showed no effect on the duration of G₁ S and M phases but significantly extended that of the G₂ phase. The effect of far-red light on the G₂ phase was reversed by red light, and the effects of red and far-red light were repeatedly reversible. The progression in the M phase was shown by means of a time-lapse video system to be not at all influenced by any pre-irradiation described above.     

Regulation of nitrate uptake into Chara corallina cells via NH+4 stimulation of NO−3 efflux

Abstract. Net NO₃ uptake by NO⁻₃ deficient Chara cells was used to calculate [NO⁻₃]_c assuming that the cytoplasm occupies 10% total volume and that nitrate reduction and storage are negligible (i.e. maximum [NO⁻₃]_c was calculated). A linear relationship was found between NO⁻₃ efflux and [NO⁻₃]_c. There was an initial burst of NO⁻₃ efflux when NH⁺₄ was added, followed by a slower efflux rate which matched influx rate such that net NO⁻₃ uptake was zero. Over 50% of NO⁻₃ that had been taken up in 2 h was lost within the first 5 min of NH⁺₄ addition. The Nernst equation was used to predict the direction of the electrochemical driving force for NO⁻₃ entry. Under the experimental conditions used NO⁻₃ efflux is actively transported. The differential involvement of both NO⁻₃ influx and NO⁻₃ efflux in the regulation of NO⁻₃ uptake is discussed and a model is proposed to account for these results which envisages discrete NO⁻₃ influx and NO⁻₃ efflux carriers.     

Cell-cycle dependence of a ganglioside glycosyltransferase activity and its inhibition by enkephalin in a neurotumor cell line

Abstract: Rat glioma mouse neuroblastoma hybrid neurotumor cells (NG108-15), synchronized by amino acid deprivation, showed a cell-cycle-dependent peak of activity of a ganglioside N-acetylgalactosaminyl transferase 14-24 h following release from the cell cycle block (S/G₂ phase). Maximal expression of two typical lysosomal hydrolases, N-acetyl-β-hexosaminidase and β-galactosidase, occurred between 18 and 21 h following release (S phase), declining to G₁ phase levels during the peak of N-acetylgalactosamine (GalNAc) transferase activity. In addition, glycosyltransferase activity in G₂ phase cells showed an increase in apparent V_max (suggesting the presence of more enzyme/mg of cell protein) and apparent binding affinity for uridine diphosphate N-acetylgalactosamine (UDP-GalNAc) (32 versus 14 M) when compared to transferase activity in the G₁ phase. However, the opioid peptide enkephalin [D-Ala², o-Leu⁵], which inhibits ganglioside GalNAc transferase activity in unsynchronized NG108-15 cultures, was much more inhibitory in whole cells 8 h after release from the cell cycle block (G₁ phase) than in cells 20 h after release (G, phase), with 50% inhibition occurring at 2 ± 10^-9M and 2 ± 10^-7M, respectively. These results suggest that the GalNAc transferase activity is regulated in more than one way during the cell cycle, since both V_max and K_m changes are observed, and that the cyclic AMP-dependent mechanism by which opiates reduce transferase activity is receptor mediated and cell cycle dependent.     

Growth pattern of the human promyelocytic leukaemia cell line HL60

Abstract. In order to characterize the growth pattern of the human promyelocytic leukaemia cell line HL60, its kinetic parameters were studied. The doubling time was calculated from serial cell counts, the duration of the various cell cycle phases from the analysis of the labelled mitoses curve, and quiescent population from continuous labelling experiments. Proliferation in culture was exponential up to a saturation density of about 3.0 × 10⁶ cells/ml, with a doubling time of 34.0 hr. The cell cycle duration was 24.3 ± 4.1 hr (SD), and that of the cell cycle phases was: G₁, 3.8 ± 2.2 hr; S, 15.1 ± 3 hr; and G₂, 5.4 ± 1.2 hr. The growth fraction was 0.85, and cell loss was restricted to the quiescent cells. The HL60 cell line, with fully characterized kinetics, provides a useful tool for the in vitro study of substances which may affect human leukaemic myelopoietic proliferation.     

Monocytic differentiation of HL60 cells induced by potent analogs of vitamin D3 precedes the G1/G0 phase cell cycle block

Abstract. Differentiation of mammalian cells is accompanied by reduced rates of proliferation and an exit from the cell cycle. Human leukemic cells HL60 present a widely used model of neoplastic cell differentiation, and acquire the monocytic phenotype when exposed to analogs of vitamin D₃ (VD₃). The maturation process is accompanied by two blocks in the cell cycle: an arrest in the G₁/G₀ phase, and a recently described G₂+ M block. In this study we have analyzed the traverse of the cell cycle phases of the well-differentiating HL60-G cells exposed to one of ten analogs of VD₃, and compared the cell cycle effects of each compound with its potency as a differentiation-inducing agent. We found that in general there was a good correlation between the effects of these compounds on the cell cycle and on differentiation, but the best cell cycle predictor of differentiation potency was the extent of accumulation of the cells in the G₂ compartment. All analogs induced a marked decrease in the mitotic index, and polynucleation of HL60 cells was produced, especially by compounds which were effective as inducers of differentiation. Time course studies showed that induction of differentiation was accompanied by a transient increase of the proportion of cells in the G₂+ M compartment, but preceded the G₁ to S, and the G₂ compartment blocks. These studies indicate that complex changes in the cell cycle traverse accompany, but do not precede, the acquisition of the monocytic phenotype by HL60 cells.     

Involvement of Calcium Influx in Muscarinic Cholinergic Regulation of Phospholipase C in Cerebellar Granule Cells

Abstract: Inositol phosphate accumulation on carbachol stimulation of rat cerebellar granule cells shows a marked dependence on factors affecting cytosolic Ca²⁺ concentration ([Ca²⁺]_c). After 5 min, potassium depolarisation caused a modest accumulation of inositol phosphates but augmented the response to carbachol by a factor of 2–3. These effects of potassium were dependent on an extracellular source of calcium and could be partially blocked by specific (nifedipine) and nonspecific (verapamil) calcium channel blockers. Measurements of [Ca²⁺]_c under a range of stimulatory conditions demonstrated a close correlation between the elevation of [Ca²⁺]_c and agonist-stimulated phospholipase C (PLC) activity. The maximal potentiation of carbachol-stimulated inositol phosphate accumulation was achieved using 20 m M KCl, which increased [Ca²⁺]_c from ∼20 to ∼75 n M , indicating the involvement of relatively low threshold Ca²⁺ channels and the high sensitivity of the relevant PLC to small changes in [Ca²⁺]_c. By contrast, increases in [Ca²⁺]_c induced by the Ca²⁺ ionophore ionomycin were associated with more modest and less potent effects on agonist-stimulated PLC. These results demonstrate a cooperative interaction between a receptor/G protein-regulated PLC and voltage-stimulated elevations of [Ca²⁺]_c, which may function to integrate ionotropic and metabotropic signalling mechanisms in cerebellar granule cells.