Permeable FGF-1 Nuclear Localization Signal Peptide Stimulates DNA Synthesis in Various Cell Types but Is Cell-Density Sensitive and Unable to Support Cell Proliferation

An earlier report indicated that a 26-amino-acid peptide (SA), comprised of the nuclear localization signal (NLS) of fibroblast growth factor-1 (FGF-1) and a membrane-permeable peptide, was able to stimulate DNA synthesis after it was taken up by NIH3T3 fibroblasts. Here, we report that SA, but not a mutant with the NLS motif destroyed, induced DNA synthesis in BALB/c3T3 murine fibroblasts, human vascular endothelial (HUVE) cells, and primary cultured hepatocytes, although the activity was weaker than that of FGF-1. The kinetics of SA-induced DNA synthesis and G₁cyclin expression were similar to those elicited by FGF-1, indicating that SA induces cell cycle progression. Kinetic analysis also suggested that SA stimulates only a fraction of the DNA replication in BALB/c3T3 cells. At high cell densities, SA-induced G₁cyclin expression and DNA synthesis were more strongly inhibited than those induced by FGF-1. SA did not induce cell division in HUVE and BALB/c3T3 cells and did not interfere with FGF-1-stimulated proliferation of HUVE cells. These results indicate that SA is able to partially induce cell cycle progression through a contact-inhibition sensitive signaling pathway, but it is insufficient to support cell mitosis. We also suggest that signaling by SA does not interfere with that of FGF-1.     

The Cellular Protein MCM3AP Is Required for Inhibition of Cellular DNA Synthesis by the IE86 Protein of Human Cytomegalovirus

Like all DNA viruses, human cytomegalovirus (HCMV) infection is known to result in profound effects on host cell cycle. Infection of fibroblasts with HCMV is known to induce an advance in cell cycle through the G₀-G₁ phase and then a subsequent arrest of cell cycle in early S-phase, presumably resulting in a cellular environment optimum for high levels of viral DNA replication whilst precluding replication of cellular DNA. Although the exact mechanisms used to arrest cell cycle by HCMV are unclear, they likely involve a number of viral gene products and evidence points to the ability of the virus to prevent licensing of cellular DNA synthesis. One viral protein known to profoundly alter cell cycle is the viral immediate early 86 (IE86) protein - an established function of which is to initially drive cells into early S phase but then inhibit cellular DNA synthesis. Here we show that, although IE86 interacts with the cellular licensing factor Cdt1, it does not inhibit licensing of cellular origins. Instead, IE86-mediated inhibition of cellular DNA synthesis requires mini-chromosome-maintenance 3 (MCM3) associated protein (MCM3AP), which can cause subsequent inhibition of initiation of cellular DNA synthesis in a licensing-independent manner.     

Coordination of growth and differentiation in the fetal lung

The male fetal lung begins to synthesize surfactant later in gestation than the female. This delay appears to be caused by androgens. We hypothesized that male fetal lung differentiation is delayed as a consequence of an extended phase of growth which is elicited by androgens. We observed that in vivo fetal lung protein synthesis relative to DNA synthesis peaked earlier in gestation in the female fetal lung and that this event was synchronous with the onset of differentiation. Pregnant rats were treated with dihydrotestosterone (DHT) during pregnancy, and fetal lung growth parameters were measured. Lung wet weight, dry weight, and DNA and protein concentrations were significantly elevated by DHT treatment. Type II cells and fibroblasts were isolated from lungs of DHT-treated fetuses. The number of total cells recovered was increased by 30%; the number of type II cells recovered was increased by 87%; and the number of fibroblasts recovered was increased by 42%. The type II cells which were recovered exhibited increased incorporation of [3H]thymidine into DNA and a reduced ratio of radiolabeled protein to radiolabeled DNA compared to that of cells from control lungs. Further studies were done in vitro with fibroblasts and type II cells isolated from untreated fetal rat lungs. Treatment of the fibroblasts with DHT during culture caused an increase in thymidine incorporation into DNA. This effect was not blocked by simultaneous treatment with cortisol, which normally causes reduced DNA synthesis and induces fibroblast differentiation. Treatment of the type II cells with DHT in culture caused a dose-dependent increase in cell number but a decrease in synthesis of disaturated phosphatidylcholine. These studies provide more direct evidence of the interrelationships between the control of growth and the control of differentiation in the fetal lung. DHT, a signal which delays the onset of expression of differentiation, also induces growth. We conclude that the controls of growth and of differentiation of the fetal lung are reciprocally linked.     

The kinetics of simian virus 40-induced progression of quiescent cells into S phase depend on four independent functions of large T antigen.

Microinjection of purified simian virus 40 large-T-antigen protein or DNA encoding T antigen into serum-starved cells stimulates them to re-enter the cell cycle and progress through G1 into the S phase. Genetic analysis of T antigen indicated that neither its Rb/p107-binding activity nor its p53-binding activity is essential to induce DNA synthesis in CV1P cells. However, T antigens bearing missense mutations that inactivate either activity induced slower progression of the cells into the S phase than did wild-type T antigen. Inactivation of both activities resulted in a T antigen essentially unable to induce DNA synthesis. Missense mutations in either the DNA-binding region of the N terminus also impaired the ability of full-length T antigen to stimulate DNA synthesis in CV1P cells. The wild-type kinetics of cell cycle progression were restored by genetic complementation after coinjection of plasmid DNAs encoding different mutant T antigens or coinjection of purified mutant T-antigen proteins, suggesting that the four mitogenic functions of T antigen are independent. The maximal rate of induction of DNA synthesis in secondary primate cells and established rodent cell lines required the same four functions of T antigen. A model to explain how four independent activities could cooperate to stimulate cell cycle progression is presented.     

Bloom's syndrome helicase and Mus81 are required to induce transient double-strand DNA breaks in response to DNA replication stress

Perturbed DNA replication either activates a cell cycle checkpoint, which halts DNA replication, or decreases the rate of DNA synthesis without activating a checkpoint. Here we report that at low doses, replication inhibitors did not activate a cell cycle checkpoint, but they did activate a process that required functional Bloom's syndrome-associated (BLM) helicase, Mus81 nuclease and ataxia telangiectasia mutated and Rad3-related (ATR) kinase to induce transient double-stranded DNA breaks. The induction of transient DNA breaks was accompanied by dissociation of proliferating cell nuclear antigen (PCNA) and DNA polymerase α from replication forks. In cells with functional BLM, Mus81 and ATR, the transient breaks were promptly repaired and DNA continued to replicate at a slow pace in the presence of replication inhibitors. In cells that lacked BLM, Mus81, or ATR, transient breaks did not form, DNA replication did not resume, and exposure to low doses of replication inhibitors was toxic. These observations suggest that BLM helicase, ATR kinase, and Mus81 nuclease are required to convert perturbed replication forks to DNA breaks when cells encounter conditions that decelerate DNA replication, thereby leading to the rapid repair of those breaks and resumption of DNA replication without incurring DNA damage and without activating a cell cycle checkpoint.     

Taxol inhibits stimulation of cell DNA synthesis by human cytomegalovirus

The microtubule (MT)-stabilizing drug, taxol, inhibited human cytomegalovirus (CMV)-initiated cell DNA synthesis by up to 100% in serum-arrested mouse embryo (ME) fibroblasts that were abortively infected by CMV. Taxol concentrations known to increase MT polymerization and to stabilize existing MTs (10 to 20 micrograms/ml) blocked CMV-stimulated cell DNA synthesis, while taxol concentrations of 2.5 micrograms/ml, or less, did not. Taxol maximally inhibited CMV initiation of cell DNA synthesis when added 3 h after virus infection and inhibited this initiation by greater than 50% when added up to 12 h after CMV infection. Control experiments suggest that taxol specifically inhibited CMV-stimulated cell DNA synthesis. Pretreatment of CMV stock with taxol did not reduce the stimulatory effect of CMV on cell DNA synthesis and taxol had no detectable effect on CMV-specific early protein synthesis. Moreover, taxol did not appear to alter thymidine pool sizes, affect cell viability, or compromise the DNA synthetic machinery in CMV-infected cells. Since taxol increases tubulin polymerization and inhibits MT disassembly, these results suggest that dynamic changes in MTs or in the pool of free tubulin subunits are necessary for CMV to stimulate cell entry into a proliferative cycle.     

Interferon-specific effects on protein synthesis in P3HR-1 cells.

The effect of interferon (IFN) on protein synthesis was studied in the Burkitt's lymphoma cell line P3HR-1 by [35S]methionine labelling of the cells, followed by two-dimensional gel electrophoresis of cell extracts. De novo synthesis of three proteins (mol. wts. 33 000, 62 000, and 98 000, respectively) and alterations in the rate of synthesis for a small number of additional proteins were observed during the first 12 h of treatment, while the rate of overall protein synthesis was unaffected. Treatment of P3HR-1 cells with 12-O-tetradecanoyl-phorbol-13-acetate (TPA) or hydrocortisone (HC), which induce similar changes in cell cycle distribution as does IFN, did not induce comparable changes in the rates of protein synthesis. Thus, the effects were specific for IFN and not induced by the change in cell cycle distribution per se, i.e., accumulation in G0. Treatment of cells with 2'-5' pA core did not mimic the effect of IFN at the translational level. A substrain of P3HR-1 cells, selected for resistance to the anti-proliferative effect of IFN, lacked six proteins found in the wild-type. The 62 000 mol. wt. protein was induced in this substrain as well as in native P3HR-1 cells on addition of IFN. The resistant substrain still developed an anti-viral effect in response to IFN. Thus, it seems as if the anti-proliferative and anti-viral effects of IFN, at least in some cells are mediated by different intracellular molecular mechanisms.     

Effect of dihydrotestosterone on hydrogen peroxide-induced apoptosis of mouse embryonic stem cells

Steroid hormones have been reported to activate various signal transducers that trigger a variety of cellular responses. Among these hormones, testosterone has been identified as an antioxidant that protects against cellular damage. Therefore, using mouse embryonic stem (ES) cells as a model system, this study evaluated the effects of dihydrotestosterone (DHT), a biologically active testosterone metabolite, on H2O2-induced apoptosis. H2O2 increased the release of lactate dehydrogenase (LDH) and DNA fragmentation but reduced the cell viability in a time-dependent manner (> or =8 h). Moreover, H2O2 decreased the level of DNA synthesis and the levels of the cell cycle regulatory proteins [cyclin D1, cyclin E, cyclin-dependent kinase (CDK) 2, and CDK 4]. These effects of H2O2 were inhibited by a pretreatment with DHT. However, a treatment with flutamide (androgen receptor inhibitor, 10(-3) M) abolished the protective effects of DHT. This result was supported by the presence of the androgen receptor in mouse ES cells. The activity of the antioxidant enzyme, catalase, was increased by the DHT treatment but not by a co-treatment with DHT and flutamide. Using CM-H(2)DCFDA (DCF-DA) for the detection of intracellular H2O2, DHT decreased the intracellular H2O2 levels but flutamide blocked this effect. H2O2 also increased the level of p38 MAPK, JNK/SAPK, and NF-kappaB phosphorylation, which were inhibited by the DHT pretreatment. Catalase inhibited the effect of H2O2 on MAPKs and NF-kappaB. However, the flutamide treatment abolished the inhibitory effects of DHT on the H2O2-induced increase in the levels of p38 MAPK, JNK/SAPK, and NF-kappaB phosphorylation. DHT inhibited the H2O2-induced increase in caspase-3 expression and decreased the level of Bcl-2 and the cellular inhibitor of apoptosis protein (cIAP)-2. These effects were abolished by the flutamide treatment. In conclusion, DHT prevents the H2O2-induced apoptotic cell death of mouse ES cells through the activation of catalase and the downregulation of p38 MAPK, JNK/SAPK, and NF-kappaB via the androgen receptor.     

THE EFFECT OF HYDROXYUREA AND FLUORODEOXYURIDINE ON CELL CYCLE EVENTS IN THE CHLOROCOCCAL ALGA SCENEDESMUS QUADRICAUDA (CHLOROPHYTA)1

The effect of hydroxyurea and 5-fluorodeoxyuridine (FdUrd) on the course of growth (RNA and protein synthesis) and reproductive (DNA replication and nuclear and cellular division) processes was studied in synchronous cultures of the chlorococcal alga Scenedesmus quadricauda (Turp.) Bréb. The presence of hydroxyurea (5 mg·L^?1)from the beginning of the cell cycle prevented growth and further development of the cells because of complete inhibition of RNA synthesis. In cells treated later in the cell cycle at the time when the cells were committed to division, hydroxyurea present in light affected the cells in the same way as a dark treatment without hydroxyurea; i. e. RNA synthesis was immediately inhibited followed after a short time period by cessation of protein synthesis. Reproductive processes including DNA replication to which the commitment was attained, however, were initiated and completed. DNA synthesis continued until the constant minimal ratio of RNA to DNA was reached. FdUrd (25 mg·L^?1) added before initiation of DNA replication in control cultures prevented DNA synthesis in treated cells. Addition of FdUrd at any time during the cell cycle prevented or immediately stopped DNA replication. However, by adding excess thymidine (100 mg·L^?1), FdUrd inhibition of DNA replication could be prevented. FdUrd did not affect synthesis of RNA, protein, or starch for at least one cell cycle. After removal of FdUrd, DNA synthesis was reinitiated with about a 2-h delay. The later in the cell cycle FdUrd was removed, the longer it took for DNA synthesis to resume. At exposures to FdUrd longer than two or three control cell cycles, cells in the population were gradually damaged and did not recover at all.     

Physiological effects of androgens on human vascular endothelial and smooth muscle cells in culture

Androgenic hormones are associated with atherosclerotic cardiovascular disease, although the underlying cellular and molecular mechanisms remain unclear. This study examines the impact of androgens on the physiology of human vascular endothelial cells (EC) and smooth muscle cells (SMC) in culture. Cells were incubated with testosterone, dihydrotestosterone (DHT) or dehydroepiandrosterone (DHEA) at various physiological concentrations (5-50 nM) in the present or absence of an androgen receptor (AR) blocker flutamide (100 nM). Cell growth and death, DNA and collagen synthesis, and gene protein expression were assessed. It was shown that: (1) DHEA protected EC from superoxide injury via AR-independent mechanisms; (2) testosterone induced DNA synthesis and growth in EC via an AR-independent manner with activation of ERK1/2 activity; (3) DHT inhibited DNA synthesis and growth in EC in an AR-dependent manner; (4) testosterone and DHT enhanced ERK1/2 activation and proliferation in SMC via AR-independent and -dependent pathways, respectively; and (5) these androgens did not significantly affect collagen synthesis in SMC. We conclude that androgens possess multiple effects on vascular cells via either AR-dependent or -independent mechanisms. Testosterone and DHEA may be “beneficial” in preventing atherosclerosis by improving EC growth and survival; in contrast, stimulation of VSMC proliferation by testosterone and DHT is potentially “harmful”. The relationship of these in vitro effects by androgens to in vivo vascular function and atherogenesis needs to be further clarified.     

Mechanism of stimulation of DNA synthesis induced by epinephrine in primary culture of adult rat hepatocytes

Addition of epinephrine to primary cultured adult rat hepatocytes stimulated their DNA synthesis dose-dependently, especially in presence of insulin and epidermal growth factor. This effect of epinephrine was strongly inhibited by an alpha 1-antagonist, prazosin, but not by a beta-antagonist, propranolol, and was also slightly inhibited by an alpha 2-antagonist, yohinbin. These results indicate that the stimulation of DNA synthesis of hepatocytes by epinephrine is mediated predominantly by an alpha 1-action. 12-o-Tetradecanoylphorbol-13-acetate (TPA) or Ca2+-ionophore A-23187 stimulated DNA synthesis of Swiss 3T3 cells, but did not induce DNA synthesis of hepatocytes either singly or in combination. The fact that pretreatment of hepatocytes with TPA caused down-regulation of the stimulatory effect of epinephrine on DNA synthesis of hepatocytes within 15 min suggested that the effect of epinephrine on hepatocytes is mediated by its alpha 1 receptor and that TPA activated protein kinase c in the hepatocytes. Addition of dibutyryl cGMP did not induce DNA synthesis of hepatocytes. Therefore, the alpha 1-action of epinephrine that induce stimulation of DNA synthesis of primary cultured adult rat hepatocytes was apparently not mediated by either activation of phospholipid-dependent protein kinase or Ca2+ mobilization. Possible alternative mechanism was discussed.     

Induction and regulation of immunoglobulin expression in a murine pre-B cell line, 70Z/3. I. Cell cycle-associated induction of sIgM expression and kappa-chain synthesis in 70Z/3 cells by LPS stimulation

Stimulation of a murine pre-B cell line, 70Z/3, with LPS induced sIgM expression and an increase of L kappa-chain mRNA within 12 hr. In synchronized 70Z/3 cells, the cell division cycle was 10 to 11 hr and LSP-stimulation did not affect the cell division cycle. LPS-signals given at G1/S boundary induced sIgM expression in the G2 to M-phase. On the other hand, LPS-signals given after M-phase did not induce sIgM expression. Inhibition of cell division with demecorcin did not affect sIgM expression in the M-phase. Induction of intracellular kappa-chain synthesis was also observed in the G2 to M-phase when the LPS-stimulation was provided at G1/S boundary, but LPS-signals given after the M-phase did not induce de novo synthesis of kappa-chain. These results showed that LPS-induced sIgM expression and synthesis of kappa-chain were cell cycle-related events and sIgM expression was associated wih de novo synthesis of kappa-chain.     

DNA damage-induced inhibition of rRNA synthesis by DNA-PK and PARP-1

RNA synthesis and DNA replication cease after DNA damage. We studied RNA synthesis using an in situ run-on assay and found ribosomal RNA (rRNA) synthesis was inhibited 24 h after UV light, gamma radiation or DNA cross-linking by cisplatin in human cells. Cisplatin led to accumulation of cells in S phase. Inhibition of the DNA repair proteins DNA-dependent protein kinase (DNA-PK) or poly(ADP-ribose) polymerase 1 (PARP-1) prevented the DNA damage-induced block of rRNA synthesis. However, DNA-PK and PARP-1 inhibition did not prevent the cisplatin-induced arrest of cell cycle in S phase, nor did it induce de novo BrdU incorporation. Loss of DNA-PK function prevented activation of PARP-1 and its recruitment to chromatin in damaged cells, suggesting regulation of PARP-1 by DNA-PK within a pathway of DNA repair. From these results, we propose a sequential activation of DNA-PK and PARP-1 in cells arrested in S phase by DNA damage causes the interruption of rRNA synthesis after DNA damage.     

Thymidine as a synchronizing agent. I. Nucleic acid and protein formation in synchronous HeLa cultures treated with excess thymidine

Synchronous cultures of HeLa cells obtained by selective detachment of mitoses were treated with high concentrations of thymidine. The inhibitor was added soon after completion of cell division and rates of cell enlargement and accumulation of DNA, RNA and protein were compared for untreated and thymidine-treated cultures at various points of the cell cycle. It was found that concentrations of thymidine which in randomly growing cultures inhibit the rate of cell division by more than 90% allowed a considerable degree of DNA synthesis and did not affect the rate of accumulation of RNA and protein, when applied to cells in the G1 phase of synchronous culture. Treated and untreated cells enlarged at the same rate throughout their life cycle. The results show that concentrations of thymidine commonly employed to produce cell synchrony do not arrest the cells at the G1-S boundary, but allow slow progress through S in respect to DNA synthesis, and near-normal progress towards G2 as regards RNA and protein accumulation and cell enlargement.     

The cell cycle and DNA mismatch repair

The DNA mismatch repair (MMR) pathway contributes to the fidelity of DNA synthesis and recombination by correcting mispaired nucleotides and insertion/deletion loops (IDLs). We have investigated whether MMR protein expression, activity, and subcellular location are altered during discrete phases of the cell cycle in mammalian cells. Two distinct methods have been used to demonstrate that although physiological MMR protein expression, mismatch binding, and nick-directed MMR activity within the nucleus are at highest levels during S phase, MMR is active throughout the cell cycle. Despite equal MMR nuclear protein concentrations in S and G(2) phases, mismatch binding and repair activities within G(2) are significantly lower, indicating a post-translational decrease in MMR activity specific to G(2). We further demonstrate that typical co-localization of MutSalpha to late S phase replication foci can be disrupted by 2 microM N-methyl-N'-nitro-N-nitrosoguanidine (MNNG). This concentration of MNNG does not decrease ongoing DNA synthesis nor induce cell cycle arrest until the second cell cycle, with long-term colony survival decreased by only 24%. These results suggest that low level alkylation damage can selectively disrupt MMR proofreading activity during DNA synthesis and potentially increase mutation frequency within surviving cells.     

Biochemical and morphological characterizations of DU-145 cell mortality in rabbit embryo-fetal fluid

Abstract. Rabbit embryo-fetal fluid (EFF) contains regulatory factors of cell proliferation which increase the duration of the cell cycle, induce a quiescent status in some cells and lead up to cell death in others. The objective of this study was to demonstrate which of the two processes, namely necrosis or apoptosis, was responsible for the cell death. Inhibitors of protein synthesis, and nuclease and phospholipase A2 activities did not restore the viability of the cells treated with EFF. Using a combination of DNA labelling and extraction, it was possible to show that a large proportion of DNA was fragmented in the cells released in the supernatant while only a very small portion of DNA was fragmented in the monolayer cells. EFF did not induce fragmentation of DNA into nucleosome-sized subunits as analysed using polyacrylamide gel electrophoresis. Nevertheless, using cytofluorometric analysis, it was possible to demonstrate that 50% of the cells released in the supernatant contained a lower quantity of DNA per cell than in the control cells. This was also observed with EFF-treated monolayer cells but not in the control monolayer cells. The reduction of the DNA content per monolayer cell became significant at 48 h of treatment with EFF. Electron microscopic analysis did not reveal blebbing of the cells. However, depletion of glycogen, condensation of mitochondria and increasing number of lysosomes and residual bodies were observed upon treatment with EFF. From these experiments we conclude that the DU-145 cells treated with EFF do not die by apoptosis, but rather seem to die by necrosis.     

Influence of cytochalasin d-induced changes in cell shape on proteoglycan synthesis by cultured articular chondrocytes

There is growing evidence that cell shape regulates both proliferation and differentiated gene expression in a variety of cell types. We have explored the relationship between the morphology of articular chondrocytes in culture and the amount and type of proteoglycan they synthesize, using cytochalasin D to induce reversible cell rounding. When chondrocytes were prevented from spreading or when spread cells were induced to round up, 35SO4 incorporation into proteoglycan was stimulated. Incorporation into the cell layer was stimulated more than into the medium. When the cells were allowed to respread by removing cytochalasin D, proteoglycan synthesis returned to control levels. Cytochalasin D-induced stimulation of 35SO4 incorporation reflected an increase in core protein synthesis rather than lengthening of glycosaminoglycan chains, because [3H]serine incorporation into core protein was also stimulated. The observed stimulation of proteoglycan synthesis was not due to an overall stimulation of protein synthesis, to inhibition of DNA synthesis, or to accumulation of cells in one phase of the cell cycle. Cytochalasin D-treatment of cells in suspension caused no further stimulation of 35SO4 incorporation, suggesting that the observed effects were due to cell rounding rather than exposure to cytochalasin D per se; nevertheless, we cannot completely rule out other, nonspecific, effects of the drug. Fibroblasts and chondrocytes that had been passaged to stimulate dedifferentiation did not incorporate more 35SO4 when treated with cytochalasin D, suggesting that increased proteoglycan synthesis in response to rounding may itself be a differentiated property of chondrocytes.     

Activation of PKR/eIF2α signaling cascade is associated with dihydrotestosterone-induced cell cycle arrest and apoptosis in human liver cells

Androgen receptor (AR) signaling plays an important role in the development and progression of several liver diseases, including hepatocellular carcinoma (HCC) and non-alcoholic fatty liver disease (NAFLD). Dihydrotestosterone (DHT) is the active metabolite of the major circulating androgen, testosterone. In this study, we investigated the effect of DHT on human liver cells. We found that DHT not only induces cell cycle arrest but also initiates apoptosis in androgen-sensitive liver cells, such as SMMC-7721 and L02. Importantly, DHT/AR induces the activation of RNA-dependent protein kinase (PKR)/eukaryotic initiation factor-2 alpha (eIF2α) cascades in androgen-sensitive liver cells. PKR/eIF2α activation-induced growth arrest and DNA damage-inducible gene 153 (GADD153) and heat shock protein 27 (Hsp27) expression contribute to cell cycle arrest in response to DHT. It is notable that DHT administration results in androgen-sensitive liver cells apoptosis, at least in part, through PKR/eIF2α/GADD153 cascades. These results suggest that the androgen/AR pathway plays a pivotal role in liver cell growth and apoptosis regulating, whose deregulation might be involved in the pathogenesis of liver diseases.