Cyclic AMP dependent regulation of mitosis in human lymphoid cells

Intracellular levels of cyclic AMP (cAMP), cAMP-dependent phosphodiesterase activity, and adenylate cyclase activity are examined in an established line of human lymphoid cells synchronized by either excess thymidine or by colcemid treatment. cAMP levels and adenylate cyclase activities during the two G periods are high when compared with the values in M. cAMP-dependent phosphodiesterase activity, which is low during early G 2, is shown to increase during G 2 and reach a maximum activity during M. Agents such as dibutyryl cAMP, 1-methyl-3-isobutyl xanthine, noradrenaline, and isopropyl noradrenaline, which increase the levels of intracellular cAMP were examined to determine their effects on mitosis and on DNA synthesis. In thymidine-synchronized cells the onset of mitosis is prevented by increasing or maintaining high levels of cAMP during G 2. The specificity of inhibition of DNA synthesis or mitosis by dibutyryl cAMP is a function of the time, during the cell cycle, when the analogue is added. The elevation of cAMP by methyl xanthine results in a more general inhibition of nucleic acid synthesis and mitosis. Although both catecholamine hormones inhibit mitosis, isopropylnoradrenaline also inhibits DNA synthesis while noradrenaline treatment does not result in such inhibition.     

The relationship between levels and rates of synthesis of polyamines during mammalian cell cycle

The objective of this study was to examine the rate of synthesis and the intracellular levels of polyamines as a function of the HeLa cell cycle. The intracellular levels of ornithine, which were high during mitosis and early G1 phase, decreased rapidly during late G1 phase when the ornithine decarboxylase activity was at its peak. The activities of ornithine decarboxylase and S-adenosyl methionine decarboxylase reached a peak during G1 and decreased rapidly during the S phase. The levels of polyamines were maximum in mitosis and S phase. In constrast, the rate of polyamine synthesis during S phase was 5–10 fold lower than that in mitosis or G1 phase. We have also observed fluctuations in diamine-oxidase activity during the cell cycle. The enzyme activity was high during mitosis and late G1 and low during S phase. Thus, the results of this study suggest an important role for the catabolic enzymes in the regulation of polyamine levels during the mammalian cell cycle.     

Post-translational modifications of the regulatory subunits of cAMP-dependent protein kinases during G1/S progression

During the G1/S transition of the cell cycle variations in the labelling by 8-N3-[32P]cAMP of the protein kinase A regulatory subunits RI and RII, used as a probe to monitor post-translational modifications that may regulate cAMP binding, were observed in synchronized HeLa cells. A decrease in 8-N3-[32P]cAMP labelling of RI, RII and RII phosphorylated by the catalytic subunit of PKA was correlated with the increased percentage of cells in phases G1. An increase in 8-N3-[32P]cAMP incorporated into the 54-kDa RII subunit during progression from G1 to S was correlated with an increase in intracellular cAMP. A transient increase in Mn-SOD activity was detected in cells arrested at the G1/S transition using two different techniques, suggesting that oxidative modulation of regulatory subunits by free radicals may modify cAMP binding sites during the cell cycle. Decreased photoaffinity labelling by 8-N3-[32P]cAMP of RI, RII and autophosphorylated RII subunits was found to be an inherent characteristic of PKA in the G1/S transition.     

TGF-beta-induced G2/M delay in proliferating rabbit articular chondrocytes is associated with an enhancement of replication rate and a cAMP decrease: possible involvement of pertussis toxin-sensitive pathway.

This study was undertaken to gain more insight into the mechanism whereby TGF-beta influences the cell cycle progression of cultured rabbit articular chondrocytes. Using proliferating chondrocytes in fetal calf serum-containing medium, we have previously shown that TGF-beta induced a recruitment of cells at the end of the S phase (G2/M) observed 24 h after addition. The delayed cells may then be released, producing a proliferative effect at 48 h, provided a substantial amount of FCS (10%) is present in the medium. Otherwise, in low level of serum (2% FCS, for example), only inhibition of cell proliferation is observed. In chondrocytes synchronized in S phase by a thymidine block, we investigated here the time-course incorporation of [3H]-thymidine into DNA, the cell cycle traverse by flow cytofluorometric study of DNA content, the expression of PCNA (Proliferating Cell Nuclear Antigen), and cAMP levels. The data demonstrate that TGF-beta provoked a decrease of cAMP content (0.5-1 h) followed by an enhancement of the DNA synthesis rate (4 h) which was detectable through cytofluorometric analysis and [3H]-thymidine labeling and correlated with the PCNA expression. In contrast, addition of cAMP analogues to the cultures resulted in an inhibition of replication rate. We also showed that pertussis toxin produced a decrease of the DNA synthesis rate, in a transient manner and only in the presence of TGF-beta. All these results suggest that TGF-beta may accelerate the replication process of cyclized chondrocytes, making then accumulate at the G2/M boundary, via a mechanism that could involve the adenylate cyclase activity and a Gi-protein. The factor might be responsible for producing a pool of cells having already replicated their DNA and therefore capable of re-entering the cell cycle without delay. This cell population could serve as a tissue reserve able to induce a mitosis wave when necessary--for example, in the repair of tissue damage.     

Adenosine 3'':5''-monophosphate content and actions in the division cycle of synchronized HeLa cells

The involvement of adenosine 3':5'-monophosphate (cAMP) in the regulation of the cell cycle was studied by determining intracellular fluctuations in cAMP levels in synchronized HeLa cells and by testing the effects of experimentally altered levels on cell cycle traverse. Cyclic AMP levels were lowest during mitosis and were highest during late G-1 or early S phase. These findings were supported by results obtained when cells were accumulated at these points with Colcemid or high levels of thymidine. Additional fluctuations in cAMP levels were observed during S phase. Two specific effects of cAMP on cell cycle traverse were found. Elevation of cAMP levels in S phase or G-2 caused arrest of cells in G-2 for as long as 10 h and lengthened M. However, once cells reached metaphase, elevation of cAMP accelerated the completion of mitosis. Stimulation of mitosis was also observed after addition of CaCl2. The specificity of the effects of cAMP was verified by demonstrating that: (a) intracellular cAMP was increased after exposure to methylisobutylxanthine (MIX) before any observed effects on cycle traverse; (b) submaximal concentrations of MIX potentiated the effects of isoproterenol; and (c) effects of MIX and isoproterenol were mimicked by 8-Br-cAMP. MIX at high concentrations inhibited G-1 traverse, but this effect did not appear to be mediated by cAMP. Isoproterenol slightly stimulated G-1 traverse and partially prevented the MIX-induced delay. Moreover, low concentrations of 8-Br-cAMP (0.10-100 muM) stimulated G-1 traverse, whereas high concentrations (1 mM) inhibited. Both of these effects were also observed with the control, Br-5'-AMP, at 10-fold lower concentrations.     

Chromatin structure during the prereplicative phases in the life cycle of mammalian cells

The object of this study was to determine the kinetics of chromosome decondensation during the G1 period of the HeLa cell cycle. HeLa cells synchronized in the G1 period following the reversal of mitotic block were fused with Colcemid-arrested mitotic HeLa cells at 1.5, 3, 5, and 7 h after the reversal of N2O block. The resulting prematurely condensed chromosomes (PCC) were classified into six categories depending on the degree of their condensation. The frequency of occurrence of each category was plotted as a function of time after mitosis. The results of this study indicate that the process of chromosome decondensation, initiated during the telophase of mitosis continues throughout the G1 period without any interruption, thus the chromatin reaches an ultimate state of decondensation by the end of G1 period, when DNA synthesis is initiated.     

Intercellular Redistribution of cAMP Underlies Selective Suppression of Cancer Cell Growth by Connexin26

Connexins (Cx), which constitute gap junction intercellular channels in vertebrates, have been shown to suppress transformed cell growth and tumorigenesis, but the mechanism(s) still remain largely speculative. Here, we define the molecular basis by which Cx26, but less frequently Cx43 or Cx32, selectively confer growth suppression on cancer cells. Functional intercellular coupling is shown to be required, producing partial blocks of the cell cycle due to prolonged activation of several mitogenic kinases. PKA is both necessary and sufficient for the Cx26 induced growth inhibition in low serum and the absence of anchorage. Activation of PKA was not associated with elevated cAMP levels, but appeared to result from a redistribution of cAMP throughout the cell population, eliminating the cell cycle oscillations in cAMP required for efficient cell cycle progression. Cx43 and Cx32 fail to mediate this redistribution as, unlike Cx26, these channels are closed during the G2/M phase of the cell cycle when cAMP levels peak. Comparisons of tumor cell lines indicate that this is a general pattern, with growth suppression by connexins occurring whenever cAMP oscillates with the cell cycle, and the gap junction remain open throughout the cell cycle. Thus, gap junctional coupling, in the absence of any external signals, provides a general means to limit the mitotic rate of cell populations.     

Ring-deleted analogs of atrial natriuretic factor inhibit adenylate cyclase/cAMP system. Possible coupling of clearance atrial natriuretic factor receptors to adenylate cyclase/cAMP signal transduction system

We have recently shown that atrial natriuretic factor (ANF) inhibits adenylate cyclase activity in rat platelets where only one population of ANF receptors (ANF-R2) is present, indicating that ANF-R2 receptors may be coupled to the adenylate cyclase/cAMP system. In the present studies, we have used ring-deleted peptides which have been reported to interact with ANF-R2 receptors also called clearance receptors (C-ANF) without affecting the guanylate cyclase/cGMP system, to examine if these peptides can also inhibit the adenylate cyclase/cAMP system. Ring-deleted analog C-ANF4-23 like ANF99-126 inhibited the adenylate cyclase activity in a concentration-dependent manner in rat aorta, brain striatum, anterior pituitary, and adrenal cortical membranes. The maximal inhibition was about 50-60% with an apparent Ki between 0.1 and 1 nM. In addition, C-ANF4-23 also decreased the cAMP levels in vascular smooth muscle cells in a concentration-dependent manner without affecting the cGMP levels. The maximal decrease observed was about 60% with an apparent Ki of about 1 nM. Furthermore, C-ANF4-23 was also able to inhibit cAMP levels and progesterone secretion stimulated by luteinizing hormone in MA-10 cell line. Other smaller fragments of ANF with ring deletions were also able to inhibit the adenylate cyclase activity as well as cAMP levels. Furthermore, the stimulatory effects of various agonists such as 5'-(N-ethyl)carboxamidoadenosine, dopamine, and forskolin on adenylate cyclase activity and cAMP levels were also significantly inhibited by C-ANF4-23. The inhibitory effect of C-ANF4-23 on adenylate cyclase was dependent on the presence of GTP and was attenuated by pertussis toxin treatment. These results indicate that ANF-R2 receptors or so-called C-ANF receptors are coupled to the adenylate cyclase/cAMP signal transduction system through inhibitory guanine nucleotide regulatory protein.     

Changes in morphology and cell cycle traverse induced in CHO cells by methyl isobutyl xanthine

Methyl isobutyl xanthine (MIX) added to the medium of CHO cells induced a transient elevation of intracellular cAMP concentration. Values which were maximal after 30 min incubation in MIX subsequently declined until after 4–5 h incubation cAMP levels in MIX-treated cells were the same as those of controls. Following addition of MIX to the medium, several perturbations of cell cycle traverse were observed, including a block early in G1 which delayed progress of the cell through subsequent phases of the cell cycle by approx. 1 h, inhibition of transport of exogenous thymidine, arrest of cells in G2 and early M and more rapid completion of mitosis when MIX was added to metaphase cells. None of these changes persisted during prolonged incubation in MIX and cell cycle parameters of cells growing continuously in 0.2 mM MIX were identical with those of their control counterparts. In contrast, conversion from epithelial to fibroblast morphology induced by MIX persisted as long as MIX was maintained in the medium and thus appeared to be independent of elevation of cAMP levels. Morphological conversion was not related to any of the modifications of cell cycle traverse induced by short exposure to MIX.     

Premature chromosome condensation and cell cycle analysis.

The application of the phenomenon of premature chromosome condensation for cell cycle analysis in HeLa and CHO cells has been examined. Random populations of HeLa and CHO cells pulse labelled with H3-TdR were separately fused with mitotic HeLa cells using U.V. inactivated Sendai virus. The resulting prematurely condensed chromosomes (PCC) were scored and classified into G1, S and G2-PCC on the basis of both morphological and autoradiographic data, The results of this study indicated that the G1, S and G2 phase cells are equally susceptible to virus-induced fusion with mitotic cells and subsequent induction into PCC. Hence the PCC method for cell cycle analysis is both practical and accurate. This study also revealed that the process of chromosome decondensation initiated during the telophase of mitosis continues throughout the G1 period reaching an ultimate state of decondensation by the end of G1, at which point the fusion of such cells with those in mitosis yield PCC with the most diffused morphology instead of the discrete single stranded structures characteristic of early G1-PCC. Thus, the decondensation of chromatin during G1 appears to be a prerequisite for the subsequent initiation of DNA synthesis.     

Cell cycle changes in the adenylate cyclase of C6 glioma cells

The adenylate cyclase of C6 glioma cell cultures was characterized for sensitivity to the beta-adrenergic agonist isoproterenol, as well as fluoride, and GTP as a function of the cell cycle. The mitotic phase of the cell cycle was emphasized because both the basal cellular cyclic AMP level and the intact C6 cell's capacity to accumulate cyclic AMP in response to isoproterenol decreased during mitosis. Basal and stimulated adenylate cyclase activities in mitotic cells were decreased relative to the enzyme activities in the G1, S, and G2 phases of the cell cycle. Analysis of the beta-adrenergic receptor using the radioligand(-)[3H]dihydroalprenolol showed that neither ligand affinity nor receptor density changed during the cell cycle, indicating that the reduced adenylate cyclase activity of the mitotic C6 cell was not caused by alterations in this hormone receptor. The reduction in the mitotic cell's basal adenylate cyclase activity was more prominent than the decrease in isoproterenol-, fluoride, or GTP-stimulated activities suggesting that the effectiveness of these enzymes activators (i.e., the efficiency of the coupling mechanism) was not attenuated during mitosis. These studies indicate that the intrinsic catalytic capacity (not the beta-adrenergic receptor or the coupling mechanism) of the C6 adenylate cyclase complex is reduced during mitosis and contributes to the mitotic cell's inability to accumulate and maintain the cyclic AMP concentration at the interphase level.     

Regulation of cAMP on the first mitotic cell cycle of mouse embryos

Mitosis promoting factor (MPF) plays a central role during the first mitosis of mouse embryo. We demonstrated that MPF activity increased when one-cell stage mouse embryo initiated G2/M transition following the decrease of cyclic adenosine 3', 5'-monophosphate (cAMP) and cAMP-dependent protein kinase (PKA) activity. When cAMP and PKA activity increases again, MPF activity decreases and mouse embryo starts metaphase-anaphase transition. In the downstream of cAMP/PKA, there are some effectors such as polo-like kinase 1 (Plk1), Cdc25, Mos (mitogen-activated protein kinase kinase kinase), MEK (mitogen-activated protein kinase kinase), mitogen-activated protein kinase (MAPK), Wee1, anaphase-promoting complex (APC), and phosphoprotein phosphatase that are involved in the regulation of MPF activity. Here, we demonstrated that following activation of MPF, MAPK activity was steady, whereas Plk1 activity fluctuated during the first cell cycle. Plk1 activity was the highest at metaphase and decreased at metaphase-anaphase transition. Further, we established a mathematical model using Gepasi algorithm and the simulation was in agreement with the experimental data. Above all the evidences, we suggested that cAMP and PKA might be the upstream factors which were included in the regulation of the first cell cycle development of mouse embryo.     

Indomethacin-induced G1/S phase arrest of the plant cell cycle

In animal systems, indomethacin inhibits cAMP production via a prostaglandin-adenylyl cyclase pathway. To examine the possibility that a similar mechanism occurs in plants, the effect of indomethacin on the cell cycle of a tobacco bright yellow 2 (TBY-2) cell suspension was studied. Application of indomethacin during mitosis did not interfere with the M/G1 progression in synchronized BY-2 cells but it inhibited cAMP production at the beginning of the G1 phase and arrested the cell cycle progression at G1/S. These observations are discussed in relation to the putative involvement of cAMP biosynthesis in the cell cycle progression in TBY-2 cells.     

Changes in the phosphorylation of non-histone chromatin proteins during the cell cycle of HeLa S 3 cells

The phosphorylation of non-histone chromatin proteins in synchronized HeLa S₃ cells was studied in 5 phases of the cell cycle: mitosis, G₁, early and late S, and G₂. The rate of non-histone chromatin protein phosphorylation was found to be maximal during G₁ and G₂, somewhat decreased during S phase, and almost 90% depressed during mitosis. Analysis of the phosphorylated non-histone chromatin proteins by SDS-acrylamide gel electrophoresis showed a heterogeneous pattern of phosphorylation as measured by labeling with ³²P. Significant variations in the labeling pattern were seen during different stages of the cell cycle, and particular unique species appeared to be phosphorylated selectively during certain stages of the cycle.     

Depletion of BubR1 promotes premature centrosomal localization of cyclin B1 and accelerates mitotic entry

The role of BubR1 has been established mainly in mitosis as an essential mitotic checkpoint protein although it is expressed throughout the cell cycle. To explore a possible role of BubR1 in regulating the G2 phase of cell cycle, we have employed siRNA–mediated hBubR1 knockdown in HeLa cells. Here, we demonstrate that reducing BubR1 levels during the G2 phase causes accelerated mitotic entry. As expected, BubR1 depletion leads to degradation of cyclin B1 in the G2 phase. Intriguingly, cyclin B1 is prematurely targeted to centrosomes appearing at early G2 phase in BubR1-depleted cells despite its low levels. This is in contrast to control cells where cyclin B1 appears at the centrosomes in early prophase based on cell cycle-specific localization of CENP-F. Furthermore, cyclin B/Cdk1 kinase activity in early G2 is aberrantly high in BubR1-depleted cells. Together, our results indicate that hBubR1 depletion triggers premature centrosomal localization of cyclin B1 probably leading to premature mitotic entry. This study is the first to suggest a role of hBubR1 in controlling centrosome targeting of cyclin B1 and timing of mitotic entry.     

Polysome translational state during the cell cycle.

HeLa cells were synchronized with a double thymidine block. Ribosomal subunits, monomers and polyribosomes have been quantitatively analysed at hourly intervals, during interphase, and every 15 min, during mitosis. This analysis was performed on linear 7-47% sucrose gradients. From the beginning of G1 up to the end of S phase, a certain equilibrium among ribosomal subunits, monomers and polyribosomes is maintained, while from the time of entering G2 to M the translation machinery appears to be mobilized in the sense of polysome formation. Under these conditions, the amount of polysomes per cell during the mitotic cycle is expressed by a bi-phasic pattern showing pre- and post-mitotic peaks with a falling-off during S. The G1 peak, meanwhile, is much lower than the G2 peak. The incorporation of [3H]leucine into nascent polypeptide chains on polysomes, as well as into bulk cell proteins and into nuclear and cytoplasmic proteins considered separately, is also represented by a bi-phasic curve which shows, however, a higher peak in G1 and a lower peak in G2, with two fallings-off during S and M, respectively. Since between the G1 and the G2 amino acid pools there are not strong differences of leucine concentration, the discrepancy between the amount of polysomes and the rate of labelling is discussed on the basis of the differences of polysome shape found at the different stages of the cycle. In young cells, in fact, there is an abundance of small polysomes, while in the old cell large polysomes predominate. It is suggested that, in the old cell, the rate of translation on large polysomes could be relatively lower or that among these heavy aggregates a given number of "frozen" polysomes could be present. The ribosome state is considered as a probable limiting-factor of translation, particularly in mitosis.     

Calcium thresholds in the activation of DNA and RNA synthesis in cultured planarian cells: relationship with hormonal and DB cAMP effects

DNA and RNA syntheses were reduced to a basal level in dissociated planarian cells grown for 48 h in a Ca2+-free medium. These syntheses could be triggered anew by raising the Ca2+ concentration in the medium. Serotonin could be substituted for Ca2+ in stimulating DNA synthesis by Ca2+-depleted cells, while dopamine greatly enhanced RNA synthesis in these cells. When Ca2+ concentration was raised in hormone-treated cultures, DNA synthesis was again slightly increased but RNA synthesis was depressed. Both hormonal effects were completely inhibited by the anticalmodulin drug trifluoperazine. As serotonin and dopamine are both known to stimulate the adenylate cyclase system, it was further investigated whether the hormonal effects were mediated by cAMP. Indeed, a DB cAMP concentration of 1 microM increased DNA labelling when applied for 8 h to Ca2+-depleted cultures. However, when Ca2+ was present, the 8-h treatment with 1 microM DB cAMP was inhibiting. A 4-h pulse with 1 microM DB cAMP just after Ca2+ addition was a condition for a high stimulation of DNA labelling. The other DB cAMP concentrations used, 0.1 and 10 microM, reduced DNA labelling. In the absence of Ca2+, RNA labelling was only slightly increased by 0.1 microM DB cAMP, but was highly stimulated by a 4-h treatment of 1 microM DB cAMP in the presence of Ca2+. The noted effects with 1 or 0.1 microM DB cAMP on DNA or RNA labelling corresponded to true changes in synthesis rather than alterations of the specific activity of the nucleotide pool by DB cAMP. Besides, it was precluded that these effects were due to butyrate issued from DB cAMP degradation. It was further shown that DB cAMP at 1 microM increased Ca2+ uptake in planarian cells, whereas the other concentration reduced it. This observation might explain the stimulating effect on nucleic acid synthesis of 1 microM DB cAMP applied at the appropriate moment. Based on these results it seems that, for triggering RNA synthesis, the threshold value of Ca2+ was lower than for DNA synthesis. These Ca2+ thresholds might be reached, in the absence of Ca2+ in the medium, by treatments with DB cAMP or hormones at the appropriate doses and periods. This interpretation is in agreement with the succession of biochemical events described in regenerating planarians and suggests that these events might be causally related.     

Cyclic AMP-dependent and -independent protein phosphokinase activity in subcellular fractions of synchronously growing leydig I-10 cells.

The Leydig I-10 tumor cell line was synchronized by the double thymidine block method using 1.0 mM thymidine. Protein phosphokinase activity of subcellular fractions was determined at various times throughout the cell cycle. Microsomal cAMP-independent kinase activity increased in G2 and decreased during the S and G1 phases. Except for relatively small increases during the G1 and late S phases, microsomal cAMP-dependent kinase activity remained unchanged throughout most of the cycle. In the lysosomal-mitochondrial fraction, cAMP-dependent and cAMP-independent protein kinase activity increased during the S phase. Independent kinase activity peaked again during G1, while the dependent kinase became depressed. Phosphokinase activity increased in the nuclear fraction in late G2 and during mitosis, and was due to increases in both cAMP-independent and cAMP-dependent kinase activity. Cytosol cAMP-dependent kinase activity increased in G2 and during mitosis; cAMP-independent kinase activity showed some increased activity during late G2 and mitosis. These temporal variations in the subcellular kinase activities throughout the cell cycle may act to phosphorylate subcellular protein substrates in a cell cycle-specific fashion.     

Variations in the levels of cyclic adenosine 3':5'-monophosphate and in the activities of adenylate cyclase and cyclic adenosine 3':5'-monophosphate phosphodiesterase during aerobic morphogenesis of Mucor rouxii

Particulate cell fractions of mycelium of Mucor rouxii contain adenylate cyclase activity which can be partially solubilized by 2% Lubrol PX. The enzyme requires Mn²⁺ and its activity is not modified by NaF or guanosine nucleotides. Mycelial extracts also contain cyclic adenosine 3′:5′-monophosphate phosphodiesterase activity, 60% of which is soluble. This activity shows characteristic low K_m (1 μm) for cyclic AMP and does not hydrolyze cyclic guanosine 3′:5′-monophosphate. It requires Mn²⁺ ions for maximal activity and is not inhibited by methylxanthines or activated by imidazole. Both enzymatic activities vary during the aerobic life cycle of the fungus. The spores have the highest levels of adenylate cyclase and cAMP phosphodiesterase, which decrease during the aerobic development. At the round cell stage, phosphodiesterase activity reaches 40% of the activity of the spores and varies only slightly thereafter. At this stage the specific activity of adenylate cyclase is 25% of the activity of ungerminated spores, and from this stage on, the activity increases up to the end of the logarithmic phase. Intracellular levels of cyclic AMP have been measured during aerobic germination. The variations of the intracellular level are tentatively explained by unequal variations in the activities of adenylate cyclase and cyclic AMP phosphodiesterase. A continuous increase of the extracellular cyclic AMP level during aerobic development has also been found, which cannot be accounted for solely by variations in the cyclase and diesterase activities.