Increased cell-surface receptor expression on U-937 cells induced by 1-O-octadecyl-2-O-methyl-sn-glycero-3-phosphocholine

Association of the ether lipid, 1-O-octadecyl-2-O-methyl-sn-glycero-3-phosphocholine (ET-18-OCH₃) with liposomes (ELL-12) reduces acute toxicity while maintaining or enhancing anticancer activity in experimental tumor models. ELL-12 has been shown to induce apoptosis by a cytochrome-c-dependent caspase-mediated pathway, which results in proteolytic cleavage of poly(ADP-ribose) polymerase and lamins, but the antitumor effects of ET-18-OCH₃ or ELL-12 could result from tumor cell differentiation or activation. Here we compared the effects of ET-18-OCH₃ and ELL-12 on the expression of cell-surface proteins associated with cell differentiation and/or activation in U-937 cells. Phorbol 12-myristate 13-acetate and all-trans-retinoic acid, which induce differentiation in U-937 cells, up-regulated CD11b (MAC1 α-integrin) and CD82 and down-regulated CD71 (transferrin receptor) in a time- and dose-dependent manner. In contrast, ET-18-OCH₃ and ELL-12 up-regulated both CD71 and CD11b and did not have any effect on expression of CD82 in U-937 cells, suggesting that the ELL-12 may activate these cells rather than induce differentiation. Further evidence of activation was that ET-18-OCH₃ and ELL-12 strongly induced tumor necrosis factor α production by U-937 cells. Received: 25 February 1999 / Accepted: 4 August 1999     

Inhibition of cell division but not nuclear division by 1-O- octadecyl-2-O-methyl-Sn-glycero-3-phosphocholine

1-O-Octadecyl-2-O-methyl-glycero-3-phosphocholine (ET-18-OCH(3)) selectively inhibits the growth of cancer cells. Here we show that in some cell types ET-18-OCH(3)and liposome-associated ET-18-OCH(3)inhibit cell division without concurrent inhibition of nuclear division, leading to multinucleate cell formation, and cell death through apoptosis. Cell cycle analysis revealed that ET-18-OCH(3)-treated U-937 cells continued to move through the cell cycle, but many cells were not able to divide and instead accumulated as tetraploid cells or octaploid cells in the G0/G1 phase of the cell cycle. Inhibition of cytokinesis has been shown to be paralleled by activation of U-937 cells, including upregulation of some cell-surface markers, acquisition of phagocytic activity, and secretion of tumor necrosis factor (TNF)-alpha (Pushkareva et al., 2000). Furthermore, treatment of cells with ET-18-OCH(3)results in the accumulation of apoptotic cells in time- and dose-dependent manner. It is possible that inhibition of cytokinesis may be related to cytoskeletal effects.     

Stability of association of 1-O-octadecyl-2-O-methyl-sn-glycero-3-phosphocholine with liposomes is composition dependent

The ether lipid, 1-O-octadecyl-2-O-methyl-sn-glycero-3-phosphocholine (ET-18-OCH₃), has anticancer activity, but it has serious side-effects, including hemolysis, which prevent its optimal use. We surmised if ET-18-OCH₃ could be stably associated with liposomes, less free ET-18-OCH₃ would be available for lytic interaction with red cells. Liposome composition variables investigated included acyl chain saturation, phospholipid head group and mole ratio of Chol and ET-18-OCH₃. It was found that attenuation of hemolysis was strongly liposome composition dependent. Some ET-18-OCH₃ liposome compositions were minimally hemolytic. For example, whereas the HI₅ (drug concentration required to cause 5% human red cell lysis) was 5–6 μM for free ET-18-OCH₃, it was approximately 250 μM for DOPC (dioleoylphosphatidylcholine):Chol (cholesterol):DOPE-GA (glutaric acid derivatized DOPE):ET-18-OCH₃, (4:3:1:2) and 640 μM for DOPE (dioleyolphosphatidylethanolamine):Chol:DOPE-GA:ET-18-OCH₃ (4:3:1:2) liposomes. Efflux of carboxyfluorescein (CF) from liposomes and Langmuir trough determinations of mean molecular area of lipids in monolayers (MMAM) were used as indicators of membrane packing and stability. Incorporation of ET-18-OCH₃ in liposomes reduced the MMAM. Reduction in CF permeation was correlated with reduction in hemolysis. The most stable liposomes included components, such as cholesterol, DOPC and DOPE, which have complementary shapes to ET-18-OCH₃.     

Platelet-activating factor and its methoxy-analogue et-18-OCH3 stimulate immediate early gene expression in rat astroglial cultures

In the present paper we analyzed c-fos and zif/268 expression in rat primary astroglial cell cultures after treatment with Platelet-activating Factor (PAF) and its 2-O-methyl-analogue, 1-O-octadecyl-2-O-methoxy-glycero-3-phosphocholine (ET-18-OCH₃). Both compounds, at a dose (2 μM) that did not produce toxic effects on astroglial cells, induced a rapid and transient increase of c-fos and zif/268 mRNA level. Pretreatment of astroglial cells with the PAF antagonist BN50730 (5 μM) 10 min prior to the addition of alkyl-phospholipids almost completely prevented the activation of the immediate early genes. On the contrary triazolam, another PAF inhibitor, did not block PAF induced gene expression when added to the medium at 5 μM concentration. ET-18-OCH₃ effect on gene expression is blocked by the same antagonist (BN50730) which is effective in inhibiting PAF effect on astrocytes, suggesting that both substances act through the same binding site.Results obtained support the view that astroglial cells are a cellular target for this lipid mediator, and, like macrophages, respond to its methoxy-analogue.     

The antiproliferative effect of hexadecylphosphocholine toward HL60 cells is prevented by exogenous lysophosphatidylcholine

The mechanisms that account for the anti-proliferative properties of the biologically active lysophospholipid analog hexadecylphosphocholine (HexPC) were investigated in HL60 cells. HexPC inhibited the incorporation of choline into phosphatidylcholine and the pattern of accumulation of soluble choline-derived metabolites pinpointed CTP:phosphocholine cytidylyltransferase (CT) as the inhibited step in vivo. HexPC also inhibited recombinant CT in vitro. HexPC treatment led to accumulation of cells in G₂/M phase, triggered DNA fragmentation and caused morphological changes associated with apoptosis. The supplementation of HexPC-treated cells with exogenous lysophosphatidylcholine (LPC) completely reversed the cytotoxic effects of HexPC and restored HL60 cell proliferation in the presence of the drug. LPC provided an alternate pathway for phosphatidylcholine synthesis via the acylation of exogenous LPC. This result contrasted with the response of HL60 cells to 1-O-octadecyl-2-O-methyl-rac-glycero-3-phosphocholine (ET-18-OCH₃) where LPC overcame the cytotoxic effects but did not support continued cell proliferation. Morphological integrity, DNA stability and cell viability were maintained in cells treated with LPC plus either antineoplastic agent. Thus the inhibition of phosphatidylcholine biosynthesis at the CT step accounts for the cytotoxicity of both HexPC and ET-18-OCH₃ which is overridden by providing an alternate pathway for phosphatidylcholine synthesis via the acylation of exogenous LPC.     

Alkyllysophospholipid ET-18-OCH3 acts as an activator of protein kinase C in HL-60 cells

HL-60 cells are very sensitive to the cytotoxic action of ether lipids. Several hypotheses have been proposed to explain this cytotoxicity. We investigated the influence of the alkylphospholipid ET-18-OCH₃ on the activity of protein kinase C. HL-60 cells were incubated with ET-18-OCH₃ at a concentration of 20 μg/ml for 4 h. After the incubation the membrane fraction of the HL-60 cells was isolated and the activity of protein kinase C was determined while it was still associated with the membrane, using the synthetic peptide substrate [Ser²⁵]-protein kinase C (19–31) as a protein kinase C specific substrate. The activity of the membrane-bound protein kinase C was increased in HL-60 cells treated with ET-18-OCH₃ compared to untreated HL-60 cells. The increase in protein kinase C activity was not a consequence of translocation and appeared to be additive to the effect of the phorbol ester 12-myristate 13-acetate. In contrast, solubilized protein kinase C from HL-60 cells could be inhibited or stimulated in vitro by ET-18-OCH₃, dependent on the mode of addition of ET-18-OCH₃ and phospholipids.     

Phorbol ester-induced inhibition of proliferation of Daudi Burkitt's lymphoma cells by impairment of cytokinesis

The phorbol ester 12-O-tetradecanoylphorbol-13-acetate (TPA) exerts a dose-dependent effect on Daudi cell proliferation. A low concentration has a slight mitogenic effect but higher concentrations inhibit proliferation. The inhibitory effect is associated with increases in cell size, macromolecular content, and incorporation of precursors into RNA and protein. Cell cycle analysis indicates that TPA at 1–10 nM leads to an apparent accumulation of cells in G₂/M phase. However, within this population a significant proportion of cells undergo nuclear division but fail to carry out cytokinesis, giving rise to cells with two or more nuclei. Consistent with this, DNA synthesis continues in cells which cease to divide in the presence of TPA. The ability of the phorbol ester to inhibit proliferation can thus be attributed mainly to an inhibition of cytokinesis rather than DNA replication     

Antiproliferative activity of sulfated polysaccharide isolated from an enzymatic digest of Ecklonia cava on the U-937 cell line

A sulfated polysaccharide purified from a brown alga Ecklonia cava, having high anticoagulant activity was investigated for its antiproliferative effect on murine colon carcinoma (CT-26), human leukemic monocyte lymphoma (U-937), human promyelocytic leukemia (HL-60), and mouse melanoma (B-16) cell lines. The sulfated polysaccharide isolated and purified from an enzymatic extract of E. cava had a good selective tumor cell growth inhibition effect; its effect on HL-60 and U-937 was especially promising. The IC₅₀ value for the sulfated polysaccharide from E. cava (ECSP) on U-937 was 43.9 μg mL⁻¹. The presence of the sample in the cell culture media stimulated the induction of apoptosis, revealed by nuclear staining with Hoechst 33342. The apoptosis induction was confirmed by the cell cycle analysis, while pronounced sub-G1 phase arrests of 9.5% and 13.8% were also clearly observed when the cells were treated at 15 and 30 μg mL⁻¹ of ECSP in the U-937 cell line, respectively. After a 24-h incubation period, ECSP dose-dependently enhanced the DNA fragmentation on the U-937 cell line as observed in the agarose gel electrophoresis assay. To rule out the action mechanism of ECSP for its anticancer activity, some western blot analyses were conducted with several antibodies (caspase-7, caspase-8, Bax, Bcl-xL, and PARP) and ECSP had a clear effect on the caspase -7 and 8 which cleave protein substrates, including PARP, an inducer of apoptosis responsible for DNA cleavage. Moreover, ECSP controlled the cellular transmembrane molecules like Bax and Bcl-xL. Taken together, the above results demonstrate that the apoptosis for antiproliferative effect of ECSP was clearly induced on U-937 cells.     

Oxidative stress perturbs cell proliferation in human K562 cells by modulating protein synthesis and cell cycle

Oxidative stress leads to perturbation of a variety of cellular processes resulting in inhibition of cell proliferation. This study has determined the effect of oxidative stress on protein synthesis in human K562 cells using a hydrophilic peroxyl radical initiator, AAPH and H₂O₂. The results indicated that oxidative stress leads to a significant decrease in the rate of protein synthesis caused due to induced activation as well as expression of the erythroid cell-specific eIF-2α kinase, called the Heme Regulated Inhibitor (HRI). Elevated levels of HRI expression and activity were accompanied by increased lipid peroxidation and decreased cell proliferation. Further, oxidative stress also caused inactivation of p34^cdc2 kinase, thereby arresting cell division leading to apoptosis. Thus, the data provides the mechanism of inhibition of protein synthesis and perturbation of a cell cycle regulatory protein leading to inhibition of cell proliferation in K562 cells during oxidative stress.     

DIVISION SYNCHRONY IN PRIMARY CULTURES OF AN ENDOZOIC DINOFLAGELLATE1

Division cysts of zooxanthellae harbored by Anthopleura elegantissima were isolated from random host-associated populations by their preferential attachment to plastic surfaces. By selecting cysts at similar stages in the cell cycle, synchronous division, excystation, and daughter cell reencystment were obtained in a medium enriched with amino acids. The interval of DNA synthesis in a single growth cycle was determined by pulse-labeling with radioactive thymidine. Analysis of the sequence of morphologic changes within such cycles suggested that the initial selection procedure isolates G₂ cells. The transit time from first generation G₂ division cysts to subsequent reentry into G₂ was about 70 hr.     

CELL DIVISION IN THE DINOFLAGELLATE GAMBIERDISCUS TOXICUS IS PHASED TO THE DIURNAL CYCLE AND ACCOMPANIED BY ACTIVATION OF THE CELL CYCLE REGULATORY PROTEIN,CDC2 KINASE1

The cell division cycle in several pelagic dinoflagellate species has been shown to be phased with the diurnal cycle, suggesting that their cell cycle may be regulated by a circadian clock. In this study, we examined the cell cycle of an epibenthic dinoflagellate, Gambierdiscus toxicus Adachi and Fukuyo (Dinophyceae), and found that cell division was similarly phased to the diurnal cycle. Cell division occurred during a 3-h window beginning 6 h after the onset of the dark phase. Cell cycle progression in higher eukaryotes is regulated by a cell cycle regulatory protein complex consisting of cyclin and the cyclin-dependent kinase CDC2. In this report, we identified a CDC2-like kinase in G. toxicus that displays activity in vitro against a known substrate of CDC2 kinase, histone H1. As in higher eukaryotes, CDC2 kinase was expressed constitutively in G. toxicus throughout the cell cycle, but it was activated only late in the dark phase, concurrent with the presence of mitotic cells. These results indicate that cell division in G. toxicus is regulated by molecular controls similar to those found in higher eukaryotes.     

Phosphorylation-dephosphorylation of retinoblastoma protein not necessary for passage through the mammalian cell division cycle

Phosphorylation of the retinoblastoma protein (Rb) during the G1-phase of the mammalian cell division cycle is currently believed to be a controlling element regulating the passage of cells into S-phase. We find, however, that the suspension-grown cell lines U937, L1210, and MOLT-4 contain exclusively hyperphosphorylated Rb. Furthermore, when adherent NIH3T3 cells are grown at very low densities to avoid overgrowth and contact inhibition, they also contain only hyperphosphorylated Rb. NIH3T3 cells exhibit hypophosphorylation when the cells are grown at moderate to high cell densities. We propose that cultures of adherent cells such as NIH3T3, when grown to moderate cell densities, are made up of two populations of cells: (a) cells that are relatively isolated and therefore growing exponentially without contact inhibition, and (b) cells that are growth-inhibited by local cell density or contact inhibition. The common observation in adherent cell lines, that Rb is both hyper- and hypophosphorylated in the G1-phase and only hyperphosphorylated in the S- and G2-phases, is explained by the effects of cell density and contact inhibition. Thus, phosphorylation-dephosphorylation of Rb protein during the G1 phase is not a necessary process during the NIH3T3, L1210, MOLT-4, and U937 division cycles. We propose that phosphorylation-dephosphorylation of Rb is independent of the division cycle and is primarily determined by growth conditions throughout the division cycle.     

TGF-beta1-induced cardiac myofibroblasts are nonproliferating functional cells carrying DNA damages

TGF-β₁ induces differentiation and total inhibition of cardiac MyoFb cell division and DNA synthesis. These effects of TGF-β₁ are irreversible. Inhibition of MyoFb proliferation is accompanied with the expression of Smad1, Mad1, p15Ink4B and total inhibition of telomerase activity. Surprisingly, TGF-β₁-activated MyoFbs are growth-arrested not only at G1-phase but also at S-phase of the cell cycle. Staining with TUNEL indicates that these cells carry DNA damages. However, the absolute majority of MyoFbs are non-apoptotic cells as established with two apoptosis-specific methods, flow cytometry and caspase-dependent cleavage of cytokeratin 18. Expression in MyoFbs of proliferative cell nuclear antigen even in the absence of serum confirms that these MyoFbs perform repair of DNA damages. These results suggest that TGF-β₁-activated MyoFbs can be growth-arrested by two checkpoints, the G1/S checkpoint, which prevents cells from entering S-phase and the intra-S checkpoint, which is activated by encountering DNA damage during the S phase or by unrepaired damage that escapes the G1/S checkpoint. Despite carrying of the DNA damages TGF-β₁-activated MyoFbs are highly functional cells producing lysyl oxidase and contracting the collagen matrix.     

Sequential protein-dependent steps in the cell cycle initiation and completion of division in vitamin B12 replenishedEuglena gracilis

Summary InEuglena gracilis Z, vitamin B₁₂ deficiency arrests cell divisions in S/G 2 phase. After the addition of vitamin B₁₂ to blocked cells, nuclear and cellular divisions begin to be induced between the 3rd and the 4th and between the 4th and the 5th hour respectively; the cell population is doubled after the 11th hour.Addition of cycloheximide either with vitamin B₁₂ or 2 to 6 hours later inhibits the resumption of divisions and blocks cell development in different stages between G 2, karyokinesis and cytokinesis. These results suggest that as a prerequisite protein-dependent steps are required at precise times during the reversibility of blocked cell divisions: at least sequential syntheses of protein concern a) formation of the mitotic spindle and replication of the pellicle; b) completion of the nuclear division; c) progression of the cleavage furrow.     

Isolation and partial characterization of conditional cell division cycle mutants inChlamydomonas

Summary We have isolated a number of temperature conditional cell division cycle mutants of the unicellular plantChlamydomonas reinhardtii that are defective in single nuclear genes. Cells grow and divide normally at the permissive temperature (21 °C), but arrest in division at the restrictive temperature (33 °C). We have characterized these mutants using DNA probes and immunofluorescence techniques to localize cytoskeletal and microtubule organizing centre proteins. We describe here 3 broad classes of cell cycle mutation which result in cell cycle arrest with: unreplicated DNA (G1 arrest), duplicated DNA (G2 arrest) and multiple nuclei due to defective cytokinesis (cytokinesis arrest). The continuation of nuclear division in mutants blocked in cytokinesis provides support of an earlier hypothesis that stage specific events in theChlamydomonas cell cycle are arranged in separate dependent sequences. The mutants isolated in the present study provide insights into the role of cytoskeletal proteins in the coordination of plant cell division and the means to investigate the molecular mechanisms whereby division by multiple fission is controlled in the unicellular plantChlamydomonas.Abbreviations BB basal bodies - EMS ethylmethane sulphonate - MT microtubule - MTOC Microtubule organizing centre - NBBC nucleus-basal body connector - PAR photosynthetically active radiation     

DIEL IN SITU PICOPHYTOPLANKTON CELL DEATH CYCLES COUPLED WITH CELL DIVISION1

The diel variability in picophytoplankton cell death was analyzed by quantifying the proportion of dead cyanobacteria Prochlorococcus and Synechococcus cells along several in situ diel cycles in the open Mediterranean Sea. During the diel cycle, total cell abundance varied on average 2.8 ± 0.6 and 2.6 ± 0.4 times for Synechococcus and Prochlorococcus populations, respectively. Increasing percentages of dead cells of Prochlorococcus and Synechococcus were observed during the course of the day reaching the highest values around dusk and decreasing as the night progressed, indicating a clear pattern of diel variation in the cell mortality of both cyanobacteria. Diel cycles of cell division were also monitored. The maximum percentage of dead cells (Max % DC) and the G2 + M phase of the cell division occurred within a period of 2 h for Synechoccoccus and 4.5 h for Prochlorococcus, and the lowest fraction of dead cells occurred at early morning, when the maximum number of cells in G1 phase were also observed. The G1 maximum corresponded with the maximal increase in newly divided cells (minimum % dead cells), and the subsequent exposure of healthy daughter cells to environmental stresses during the day resulted in the progressive increase in dying cells, with the loss of these cells from the population when cell division takes place. The discovery of diel patterns in cell death observed revealed the intense dynamics of picocyanobacterial populations in nature.     

The KEULE gene is involved in cytokinesis in Arabidopsis

 We present evidence to show that the KEULE gene of Arabidopsis is involved in cytokinesis. Mutant keule embryos have large multinucleate cells with gapped or incomplete cross walls, as well as cell wall stubs that are very similar to those observed upon caffeine inhibition of cytokinesis in plants. These defects are observed in all populations of dividing cells in the mutant, including calli, but less frequently in mature cells. Cell division appears to be slowed down, and the planes of cell division are often misoriented. In late embryos and seedlings, cross-wall formation usually appears complete, suggesting that the requirement for KEULE during cytokinesis is not absolute. Nonetheless, keule mutants die as seedlings with large polyploid cells. The bloated surface layer of keule seedlings does not uniformly behave like wild-type epidermis, and patches of this layer assume characteristics of the underlying ground tissue. The cytokinesis defect of keule mutants may influence aspects of cellular differentiation. Received: 24 April 1996 / Accepted: 11 June 1996     

Mammalian cells lack checkpoints for tetraploidy,aberrant centrosome number,and cytokinesis failure

Background  

Mammalian cells have been reported to have a p53-dependent tetraploidy checkpoint that blocks cell cycle progression in G1 in response to failure of cell division. In most cases where the tetraploidy checkpoint has been observed cell division was perturbed by anti-cytoskeleton drug treatments. However, other evidence argues against the existence of a tetraploidy checkpoint. Cells that have failed to divide differ from normal cells in having two nuclei, two centrosomes, a decreased surface to volume ratio, and having undergone an abortive cytokinesis. We tested each of these to determine which, if any, cause a G1 cell cycle arrest.