Inhibitory effect of taxol, a microtubule stabilizing agent, on induction of DNA synthesis is dependent upon cell lines and growth factors.

Growth-arrested rat fibroblasts, 3Y1, and human diploid fibroblasts, TIG-1, were induced to synthesize DNA by stimulation with various agents such as fetal bovine serum (FBS), epidermal growth factor (EGF), colcemid, or colchicine. Taxol, a microtubule-stabilizing agent, blocked the induction of DNA synthesis after stimulation with colcemid or colchicine in both cell lines. Taxol inhibited the induction of DNA synthesis after stimulation with FBS or EGF in TIG-1, but did not in 3Y1. 12-O-tetradecanoylphorbol-13-acetate (TPA) induced DNA synthesis in TIG-1, which was reduced only partly by taxol. Taxol stabilized or polymerized microtubules in both cell lines. These results indicate that the inhibitory effect of taxol on the induction of DNA synthesis varied among cell lines and among growth factors, and suggest that signal transduction processes may be differentiated by taxol sensitivity. In TIG-1 cells, when taxol was added within 6 h, about halfway into the initiation of DNA synthesis after the addition of FBS or EGF, the inhibition of DNA synthesis still occurred. Taxol did not inhibit the induction of c-fos and c-myc genes by FBS or EGF stimulation. Colchicine itself did not induce these genes in TIG-1. Thus, taxol appeared to inhibit the induction of DNA synthesis not by blockage in the early transduction process of the growth signal from the cell surface to nuclei but by blockage in processes operating in the mid- or late-prereplicative phase.     

Changes in the cell surface of human diploid fibroblasts during cellular aging.

The electrophoretic mobility of 13 human diploid cell strains, TIG-1, TIG-2, TIG-3, TIG-7, WI-38, IMR-90, MRC-5, MRC-9, TIG-1H, TIG-1L, TIG-2M, TIG-2B, and TIG-3S, which were established from different tissues of human embryos, was studied at different passages. The net negative surface charge of the cells was characteristic for each cell strain and decreased significantly during the in vitro aging of the cells. The decrease in the net negative charge of the cells correlated well with the decrease in cell density throughout the life span of the cells. A strict linear correlation between the electrophoretic mobility and the number of cells harvested at each passage was obtained for all the human diploid cell strains. Moreover, almost the same linear regression coefficient of the cells was obtained among these cell strains. Therefore, the net negative surface charge of human diploid cell strains could serve as a cell surface marker for in vitro cellular aging.     

H2O2 accelerates cellular senescence by accumulation of acetylated p53 via decrease in the function of SIRT1 by NAD+ depletion.

It has been reported that p53 acetylation, which promotes cellular senescence, can be regulated by the NAD(+)-dependent deacetylase SIRT1, the human homolog of yeast Sir2, a protein that modulates lifespan. To clarify the role of SIRT1 in cellular senescence induced by oxidative stress, we treated normal human diploid fibroblast TIG-3 cells with H(2)O(2) and examined DNA cleavage, depletion of intracellular NAD(+), expression of p21, SIRT1, and acetylated p53, cell cycle arrest, and senescence-associated beta-galactosidase (SA-beta-gal) activity. DNA cleavage was observed immediately in TIG-3 cells treated with H(2)O(2), though no cell death was observed. NAD(+) levels in TIG-3 cells treated with H(2)O(2) were also decreased significantly. Pre-incubation with the poly (ADP-ribose) polymerase (PARP) inhibitor resulted in preservation of intracellular NAD(+) levels. The amount of acetylated p53 was increased in TIG-3 cells at 4h after H(2)O(2) treatment, while there was little to no decrease in SIRT1 protein expression. The expression level of p21 was increased at 12h and continued to increase for up to 24h. Additionally, exposure of TIG-3 cells to H(2)O(2) induced cell cycle arrest at 24h and increased SA-beta-gal activity at 48h. This pathway likely plays an important role in the acceleration of cellular senescence by oxidative stress.     

A two-stage,p16(INK4A)- and p53-dependent keratinocyte senescence mechanism that limits replicative potential independent of telomere status

With increasing frequency during serial passage in culture, primary human keratinocytes express p16(INK4A) (p16) and undergo senescence arrest. Keratinocytes engineered to express hTERT maintain long telomeres but typically are not immortalized unless, by mutation or other heritable event, they avoid or greatly reduce p16 expression. We have confirmed that keratinocytes undergo p16-related senescence during growth in culture, whether in the fibroblast feeder cell system or in the specialized K-sfm medium formulation, and that this mechanism can act as a barrier to immortalization following hTERT expression. We have characterized the p16-related arrest mechanism more precisely by interfering specifically with several regulators of cell cycle control. Epidermal, oral mucosal, corneal limbal, and conjunctival keratinocytes were transduced to express a p16-insensitive mutant cdk4 (cdk4(R24C)), to abolish p16 control, and/or a dominant negative mutant p53 (p53DD), to abolish p53 function. Expression of either cdk4(R24C) or p53DD alone had little effect on life span, but expression of both permitted cells to divide 25 to 43 population doublings (PD) beyond their normal limit. Keratinocytes from a p16(+/-) individual transduced to express p53DD alone displayed a 31-PD life span extension associated with selective growth of variants that had lost the wild-type p16 allele. Cells in which both p53 and p16 were nonfunctional divided rapidly during their extended life span but experienced telomere erosion and ultimately ceased growth with very short telomeres. Expression of hTERT in these cells immortalized them. Keratinocytes engineered to express cdk4(R24C) and hTERT but not p53DD did not exhibit an extended life span. Rare immortal variants exhibiting p53 pathway defects arose from them, however, indicating that the p53-dependent component of keratinocyte senescence is telomere independent. Mutational loss of p16 and p53 has been found to be a frequent early event in the development of squamous cell carcinoma. Our results suggest that such mutations endow keratinocytes with extended replicative potential which may serve to increase the probability of neoplastic progression.     

Monochloramine inhibits ultraviolet B-induced p53 activation and DNA repair response in human fibroblasts

Monochloramine (NH2Cl) is one of the inflammation-derived oxidants, and has various effects on cell cycle, apoptosis and signal transduction. We studied the effects of NH2Cl on DNA repair response induced by ultraviolet B (UVB) irradiation in normal human diploid fibroblasts, TIG-1. TIG-1 irradiated with 20 mJ/cm2 UVB showed marked increase in thymine dimer, which decreased by about 50% after 24 h. This decrease in thymine dimer was significantly attenuated (P < 0.05) by the pretreatment of NH2Cl (200 microM), which indicated DNA repair inhibition. UVB induced p53 phosphorylation at Ser15, Ser20 and Ser37, and p53 accumulation, and NH2Cl also inhibited these changes. Consequently, UVB-induced increase in the downstream effectors of p53, namely p21Cip1 and Gadd45a, were almost completely inhibited by NH2Cl. Immunoprecipitation study indicated that the association of p53 and MDM2, an E3 ubiquitin ligase for p53, did not change substantially by NH2Cl and/or UVB. The phosphorylation of p53 (Ser15 and Ser37) by UVB is catalyzed by ATR (ataxia telangiectasia mutated and Rad3 related kinase), which works as DNA damage sensor, and ATR also phosphorylates checkpoint kinase 1(Chk1) at Ser345. NH2Cl also inhibited the phosphorylation of Chk1 (Ser345). As UVB-induced DNA damage is repaired by nucleotide excision repair (NER) in human cells, these findings indicated that NH2Cl inhibited NER through the inhibition of p53 phosphorylation and accumulation, and NH2Cl probably impaired DNA damage recognition and/or ATR activation. NH2Cl may facilitate carcinogenesis through the inhibition of NER that repairs DNA damages from various carcinogens.     

IGF-1 induces Pin1 expression in promoting cell cycle S-phase entry.

Insulin-like growth factor I (IGF-1) is a well-established mitogen to many different cell types and is implicated in progression of a number of human cancers, notably breast cancer. The prolyl isomerase Pin1 plays an important role in cell cycle regulation through its specific interaction with proteins that are phosphorylated at Ser/Thr-Pro motifs. Pin1 knockout mice appear to have relatively normal development yet the Pin1(-/-)mouse embryo fibroblast (MEF) cells are defective in re-entering cell cycle in response to serum stimulation after G0 arrest. Here, we report that Pin1(-/-) MEF cells display a delayed cell cycle S-phase entry in response to IGF stimulation and that IGF-1 induces Pin1 protein expression which correlates with the induction of cyclin D1 and RB phosphorylation in human breast cancer cells. The induction of Pin1 by IGF-1 is mediated via the phosphatidylinositol 3-kinase as well as the MAP kinase pathways. Treatment of PI3K inhibitor LY294002 and the MAP kinase inhibitor PD098059, but not p38 inhibitor SB203580, effectively blocks IGF-1-induced upregulation of Pin1, cyclin D1 and RB phosphorylation. Furthermore, we found that Cyclin D1 expression and RB phosphorylation are dramatically decreased in Pin1(-/-) MEF cells. Reintroducing a recombinant adenovirus encoding Pin1 into Pin1(-/-) MEF cells restores the expression of cyclin D1 and RB phosphorylation. Thus, these data suggest that the mitogenic function of IGF-1 is at least partially linked to the induction of Pin1, which in turn stimulates cyclin D1 expression and RB phosphorylation, therefore contributing to G0/G1-S transition.     

Human microvascular endothelial cells: Coordinate induction of morphologic differentiation and twofold extension of life span

Summary Human microvascular endothelial cells (HMVEC) from adult adipose tissue were cultured in MCDB 131 medium supplemented with 10% fetal bovine serum. Under these conditions, HMVEC from seven different donors had finite proliferative life spans ranging from 14.5 to 23.5 population doublings (PD), with a mean life span of 19 PD. Addition of 10% conditioned medium from activated human leukocyte cultures (BM Condimed^?) extended the life span of HMVEC to 31 to 41 PD, with a mean life span of 37 PD. At the end of lifespan, HMVEC cultures both with and without BM Condimed had very low labeling indices (0 to 5% [³H]thymidine labeled nuclei) and consisted of enlarged cells. However, the morphologies of the two types of HMVEC cultures were very different. Untreated HMVEC were polygonal endothelial cells that formed cobblestonelike monolayers with no cell overlapping. In contrast, BM Condimed-treated HMVEC were more elongated, less regularly shaped cells that were not strictly inhibited from overlapping. When old, these cells accumulated numerous vacuoles. The BM Condimed-treated HMVEC expressed Factor VIII antigen, which confirms their identity as endothelial cells. These cells reverted rapidly to the polygonal morphology of untreated HMVEC when they were removed from BM Condimed. Likewise, their proliferative capacity was not extended further once BM condimed was removed. These results suggest that HMVEC can exist in two distinct morphologic states in which the cells have different finite proliferative life spans. This work was supported by grants AG00947 and AG04811 from the National Institute on Aging, Bethesda, MD.     

The effects of p53 on whole organism longevity are mediated by autophagy

The tumor suppressor protein p53 has a major impact on organismal aging. Recently it has become clear that p53 not only controls DNA damage responses, senescence and apoptosis but also plays a major role in the control of autophagy. Thus, deletion, depletion, or inhibition of p53 induces autophagy in human, mouse and nematode cells. We therefore tested the hypothesis that the mutation of the p53 orthologue CEP-1 might increase the life span of Caenorhabditis elegans through an increase in baseline autophagy. For this, we evaluated the survival of nematodes lacking cep-1, alone or in combination with RNA inference with the autophagy gene bec-1 (which encodes the orthologue of Atg6/Beclin 1). cep-1 mutants exhibited a prolonged life span. While BEC-1 depletion during adult life did not cause significant modification of the life expectancy of wild type controls, it did reduce the increased life span of cep-1 mutants down to approximately normal levels. These results indicate that the life span-extending effect of the cep-1 mutation is mediated by autophagy. These results lend support to the hypothesis that autophagy has a broad positive impact on organismal aging.     

Ceramide mimics tumour necrosis factor-alpha in the induction of cell cycle arrest in endothelial cells. Induction of the tumour suppressor p53 with decrease in retinoblastoma/protein levels.

Tumour necrosis factor (TNF)-alpha induces a transient increase in N-octanoylsphingosine (C8-ceramide) which has been postulated as an intracellular mediator in TNF-alpha signalling. We tested the ability of C8-ceramide to reproduce the TNF-alpha-mediated interference with endothelial cell proliferation and DNA synthesis. TNF-alpha (10 ng.mL-1) and C8-ceramide (20 microM) inhibited the incorporation of [3H]thymidine into DNA and led to an accumulation of cells in the G1 phase of the cell cycle. When the responses of the tumour suppressors p53 and RB were analysed, it was found that TNF-alpha and C8-ceramide induced increased expression of p53. Treatment with TNF-alpha or C8-ceramide lead to a significant decrease in total retinoblastoma protein (RB) content that correlated with high levels of p53. These results suggest that p53 and RB may complement each other in their contribution to cell cycle arrest. TNF-alpha prevented RB phosphorylation whereas C8-ceramide did not interfere with this process, suggesting that it follows a ceramide-independent pathway.     

Wild-type TP53 inhibits G(2)-phase checkpoint abrogation and radiosensitization induced by PD0166285, a WEE1 kinase inhibitor

The WEE1 protein kinase carries out the inhibitory phosphorylation of CDC2 on tyrosine 15 (Tyr15), which is required for activation of the G(2)-phase checkpoint in response to DNA damage. PD0166285 is a newly identified WEE1 inhibitor and is a potential selective G(2)-phase checkpoint abrogator. To determine the role of TP53 in PD0166285-induced G(2)-phase checkpoint abrogation, human H1299 lung carcinoma cells expressing a temperature-sensitive TP53 were used. Upon exposure to gamma radiation, cells cultured under nonpermissive conditions (TP53 mutant conformation) underwent G(2)-phase arrest. However, under permissive conditions (TP53 wild-type conformation), PD0166285 greatly inhibited the accumulation of cells in G(2) phase. This abrogation was accompanied by a nearly complete blockage of Tyr15 phosphorylation of CDC2, an increased activity of CDC2 kinase, and an enhanced sensitivity to radiation. However, under permissive conditions (TP53 wild-type conformation), PD0166285 neither disrupted the G(2)-phase arrest nor increased cell death. The compound inhibited Tyr15 phosphorylation only partially and did not activate CDC2 kinase activity. To understand the potential mechanism(s) by which TP53 inhibits PD0166285-induced G(2)-phase checkpoint abrogation, two TP53 target proteins, 14-3-3rho and CDKN1A (also known as p21), that are known to be involved in G(2)-phase checkpoint control in other cell models were examined. It was found that 14-3-3rho was not expressed in H1299 cells, and that although CDKN1A did associate with CDC2 to form a complex, the level of CDKN1A associated with CDC2 was not increased in response to radiation or to PD0166285. The level of cyclin B1, required for CDC2 activity, was decreased in the presence of functional TP53. Thus inhibition of PD0166285-induced G(2)-phase checkpoint abrogation by TP53 was achieved at least in part through partial blockage of CDC2 dephosphorylation of Tyr15 and inhibition of cyclin B1 expression.     

Retinoic acid increases amount of phosphorylated raf; Ectopic expression of cFMS reveals that retinoic acid-induced differentiation is more strongly dependent on ERK2 signaling than induced go arrest is

Summary Retinoic acid is known to cause the myeloid differentiation and G1/0 cell cycle arrest of HL-60 cells in a process that requires mitogen-activated protein/extracellular signal regulated kinase (MEK)-dependent extracellular signal regulated kinase (ERK)2 activation. It has also been shown that ectopic expression of cFMS, a platelet-derived growth factor (PDGF)-family transmembrane tyrosine kinase receptor, enhances retinoic acid-induced differentiation and G1/0 arrest. The mechanism of how the retinoic acid and cFMS signaling pathways intersect is not known. The present data show that the ectopic expression of cFMS results in the differential loss of sensitivity of retinoic acid-induced differentiation or G1/0 arrest to inhibition of ERK2 activation. PD98059 was used to inhibit MEK and consequently ERK2. In wild-type HL-60 cells, PD98059 blocked retinoic acid-induced differentiation; but in cFMS stable transfectants, PD98059 only attenuated the induced differentiation, with the resulting response resembling that of retinoic acid-treated wild-type HL-60. In wild-type HL-60, PD98059 greatly attenuated the retinoic acid-induced G1/0 arrest allied with retinoblastoma (RB) hypophosphorylation; but in cFMS stable transfectants, PD98059 had no inhibitory effect on RB hypophosphorylation and G1/0 arrest. This differential sensitivity to PD98059 and uncoupling of retinoic acid-induced differentiation and G1/0 arrest in cFMS transfectants is associated with changes in mitogen-activated protein kinase signaling molecules. The cFMS transfectants had more activated ERK2 than did the wild-type cells, which surprisingly was not attributable to enhanced mitogen-activated protein-kinase-kinase-kinase (RAF) phosphorylation. Retinoic acid increased the amount of activated ERK2 and phosphorylated RAF in both cell lines. But PD98059 eliminated detectable ERK2 activation, as well as inhibited RAF phosphorylation, in untreated and retinoic acid-treated wild-type HL-60 and cFMS transfectants, consistent with MEK or ERK feedback-regulation of RAF, in all four cases. Since PD98059 blocks the cFMS-conferred enhancement of the retinoic acid-induced differentiation, but not growth arrest, the data indicate that cFMS-enhanced differentiation acts primarily through MEK and ERK2, but cFMS-enhanced G1/0 arrest allied with RB hypophosphorylation depends on another cFMS signal route, which by itself can effect G1/0 arrest without activated ERK2. Ectopic expression of cFMS and differential sensitivity to ERK2 inhibition thus reveal that retinoic acid-induced HL-60 cell differentiation and G1/0 arrest are differentially dependent on ERK2 and can be uncoupled. A significant unanticipated finding was that retinoic acid caused a MEK-dependent increase in the amount of phosphorylated RAF. This increase may help sustain prolonged ERK2 activation.     

Control of replicative life span in human cells: barriers to clonal expansion intermediate between M1 senescence and M2 crisis

The accumulation of genetic abnormalities in a developing tumor is driven, at least in part, by the need to overcome inherent restraints on the replicative life span of human cells, two of which-senescence (M1) and crisis (M2)-have been well characterized. Here we describe additional barriers to clonal expansion (Mint) intermediate between M1 and M2, revealed by abrogation of tumor-suppressor gene (TSG) pathways by individual human papillomavirus type 16 (HPV16) proteins. In human fibroblasts, abrogation of p53 function by HPVE6 allowed escape from M1, followed up to 20 population doublings (PD) later by a second viable proliferation arrest state, MintE6, closely resembling M1. This occurred despite abrogation of p21(WAF1) induction but was associated with and potentially mediated by a further approximately 3-fold increase in p16(INK4a) expression compared to its level at M1. Expression of HPVE7, which targets pRb (and p21(WAF1)), also permitted clonal expansion, but this was limited predominantly by increasing cell death, resulting in a MintE7 phenotype similar to M2 but occurring after fewer PD. This was associated with, and at least partly due to, an increase in nuclear p53 content and activity, not seen in younger cells expressing E7. In a different cell type, thyroid epithelium, E7 also allowed clonal expansion terminating in a similar state to MintE7 in fibroblasts. In contrast, however, there was no evidence for a p53-regulated pathway; E6 was without effect, and the increases in p21(WAF1) expression at M1 and MintE7 were p53 independent. These data provide a model for clonal evolution by successive TSG inactivation and suggest that cell type diversity in life span regulation may determine the pattern of gene mutation in the corresponding tumors.     

Expression of RB C pocket fragments in HSF induces delayed cell cycle progression and sensitizes to apoptosis upon cellular stresses

The retinoblastoma protein (RB) plays an important role in growth suppression through the formation of multiple protein complexes with its target proteins using A/B and C pockets. Even though the A/B and C pockets co-operate for growth suppression, the function of RB in growth arrest is inhibited by the coexpression of RB C fragments with full length RB in the absence of p53, which implies that C pocket fragments are likely to act as a dominant-negative inhibitor of RB function. In contrast, the loss of the RB functions in the presence of p53 triggers a cell cycle arrest or apoptosis by p53-dependent pathways. Thus, it still remains to be elucidated whether the expression of RB C pocket fragments in the presence of p53 induces delayed cell cycle progression and sensitizes cells to apoptosis through p53-dependent pathways. Our results show that the expression of RB C pocket fragments not only induces delayed cell cycle progression, which is mediated by the down-regulation of cyclin A, cyclin E, and E2F-1, but also sensitizes cells to apoptosis through p53-dependent pathways.