Cell cycle regulation and induction of apoptosis by beta-carotene in U937 and HL-60 leukemia cells

In this communication, we report the efficacy of beta-carotene towards differentiation and apoptosis of leukemia cells. Dose (20 microM) and time dependence (12 h) tests of beta- carotene showed a higher magnitude of decrease (significance p < 0.05) in cell numbers and cell viability in HL-60 cells than U937 cells but not normal cell like Peripheral blood mononuclear cell (PBMC). Microscopical observation of beta-carotene treated cells showed a distinct pattern of morphological abnormalities with inclusion of apoptotic bodies in both leukemia cell lines. When cells were treated with 20 microM of beta-carotene, total genomic DNA showed a fragmentation pattern and this pattern was clear in HL-60 than U937 cells. Both the cell lines, on treatment with beta- carotene, showed a clear shift in G(1) phase of the cell cycle. In addition the study also revealed anti-oxidant properties of beta-carotene since there was reduction in relative fluorescent when treated than the control at lower concentration. Collectively this study shows the dual phenomenon of apoptosis and differentiation of leukemia cells on treatment with beta-carotene.     

Regulation of cell cycle transition and induction of apoptosis in HL-60 leukemia cells by lipoic acid: role in cancer prevention and therapy

 

The most common semiquantitative method of evaluation of pulmonary lesions using ¹⁸F-FDG PET is FDG standardized uptake value (SUV). An SUV cutoff of 2.5 or greater has been used to differentiate between benign and malignant nodules. The goal of our study was to investigate the correlation between the size of pulmonary nodules and the SUV for benign as well as for malignant nodules.

Methods

Retrospectively, 173 patients were selected from 420 referrals for evaluation of pulmonary lesions. All patients selected had a positive CT and PET scans and histopathology biopsy. A linear regression equation was fitted to a scatter plot of size and SUV_max for malignant and benign nodules together. A dot diagram was created to calculate the sensitivity, specificity, and accuracy using an SUV_max cutoff of 2.5.

Results

The linear regression equations and (R²)s as well as the trendlines for malignant and benign nodules demonstrated that the slope of the regression line is greater for malignant than for benign nodules. Twenty-eight nodules of group one (≤ 1.0 cm) are plotted in a dot diagram using an SUV_max cutoff of 2.5. The sensitivity, specificity, and accuracy were calculated to be 85%, 36% and 54% respectively. Similarly, sensitivity, specificity, and accuracy were calculated for an SUV_max cutoff of 2.5 and found to be 91%, 47%, and 79% respectively for group 2 (1.1–2.0 cm); 94%, 23%, and 76%, respectively for group 3 (2.1–3.0 cm); and 100%, 17%, and 82%,, respectively for group 4 (> 3.0 cm). The previous results of the dot diagram indicating that the sensitivity and the accuracy of the test using an SUV_max cutoff of 2.5 are increased with an increase in the diameter of pulmonary nodules.

Conclusion

The slope of the regression line is greater for malignant than for benign nodules. Although, the SUV_max cutoff of 2.5 is a useful tool in the evaluation of large pulmonary nodules (> 1.0 cm), it has no or minimal value in the evaluation of small pulmonary nodules (≤ 1.0 cm).     

S-Adenosylmethionine metabolism in HL-60 cells: effect of cell cycle and differentiation

The effect of the cell cycle and differentiation on S-adenosylmethionine (SAM) metabolism in HL-60 cells has been investigated. Synthesis and pool sizes of SAM and S-adenosylhomocysteine (SAH) were cell-cycle-independent (SAM, 315, μM; SAH, 4.6 μM). The SAM-synthase (ATP: l-methionine S-adenosyltransferase) of HL-60 cells has a K_m for methionine of 12.8±2.0 μM and thus appears to be of the intermediate K_m type found in other malignant tissues. The enzyme does not show cell-cycle regulation. Treatment of cells with DMSO resulted in a rapid and marked decrease of SAM and SAH levels without affecting pool turnover or the SAM/SAH ratio. A decrease in SAM concentration could also be observed in a variant cell line resistant to differentiation with DMSO. DMSO inhibited SAM-synthase in cell-free extracts. This inhibition was noncompetitive with respect to l-methionine. Inhibition of SAM-synthase by cycloleucine lowered SAM levels in intact cells, but resulted in differentiation of only a minor percentage of cells. These data indicate that changes in SAM and SAH levels in HL-60 cells seem to be a consequence rather than a cause of differentiation.     

Modulation of ionizing radiation-induced apoptosis and cell cycle arrest by all-trans retinoic acid in promyelocytic leukemia cells (HL-60)

Acute promyelocytic leukemia is characterized by a block of myeloid differentiation. The incubation of cells with 1 micromol/l all-trans retinoic acid (ATRA) for 72 h induced differentiation of HL-60 cells and increased the number of CD11b positive cells. Morphological and functional changes were accompanied by a loss of proliferative capacity. Differentiation caused by preincubation of leukemic cells HL-60 with ATRA is accompanied by loss of clonogenicity (control cells: 870 colonies/10(3) cells, cells preincubated with ATRA: 150 colonies/10(3) cells). D0 for undifferentiated cells was 2.35 Gy, for ATRA differentiated cells 2.46 Gy. Statistical comparison of clonogenity curves indicated that in the whole range 0.5-10 Gy the curves are not significantly different, however, in the range 0.5-3 Gy ATRA differentiated cells were significantly more radioresistant than non-differentiated cells. When HL-60 cells preincubated with 1 micromol/l ATRA were irradiated by a sublethal dose of 6 Gy, more marked increase of apoptotic cells number was observed 24 h after irradiation and the surviving cells were mainly in the G1 phase of the cell cycle, while only irradiated cells were accumulated in G(2) phase. Our results imply that preincubation of cells with ATRA accelerates apoptosis occurrence (24 h) after irradiation by high sublethal dose of 6 Gy. Forty-eight hours after 6 Gy irradiation, late apoptotic cells were found in the group of ATRA pretreated cells, as determined by APO2.7 positivity. This test showed an increased effect (considering cell death induction) in comparison to ATRA or irradiation itself.     

Induction of HL-60 cell differentiation by water-soluble and nitrogen-containing conjugates of retinoic acid and retinol

Retinoids induce the promyelocytic cell line, HL-60, to differentiate along the granulocytic pathway in vitro. A number of water-soluble and nitrogen-containing retinoids were synthesized in our laboratory [retinoyl-glucose (RAGL), retinyl-glucose (ROGL), retinoyl-adenosine (RADS), retinoyl-adenine (RAD), retinoyl-beta-glucuronide (beta RAG), and retinoyl-alpha-glucuronide (alpha RAG)]. These retinoids (10(-5) to 10(-8) M), as well as retinoic acid (RA) and retinol (ROL), were tested for their ability to induce the differentiation of HL-60 cells in vitro and to affect cell growth and viability during a 24- to 72-h incubation period. Differentiation was assessed by measuring the percentage of cells expressing the Mac-1 antigen on their cell surfaces. RA and the conjugates of RA were all quite active in inducing HL-60 cell differentiation, whereas ROL and ROGL had much less activity at equimolar concentrations. beta RAG, alpha RAG, RADS, and RAD were less toxic, whereas the glucose conjugates of retinol and retinoic acid (ROGL and RAGL) were both considerably more toxic than either RA or ROL at equimolar concentrations. All retinoids affected cell growth in a dose-dependent fashion. At 24 h, free RA or ROL was not detected in the cells after incubation with any of the retinoid conjugates.     

Cell cycle specific induction of apoptosis and necrosis by paclitaxel in the leukemic U937 cells

Induction of cell apoptosis and necrosis by paclitaxel was investigated in human leukemic U937 cells. To explore whether paclitaxel induces both apoptosis and necrosis in different cell cycle stages, we synchronized the cells in G1, S and G2/M stages by counterflow centrifugal elutriation (CCE). The Annexin V and PI analysis revealed that, after paclitaxel treatment, the cells in G1 and S stages died predominantly through apoptosis, whereas G2/M-stage cells died through both apoptosis and necrosis. These phenomena were verified by a trypan blue exclusion assay and by detection of the release of lactose dehydrogenase (LDH). Paclitaxel treatment significantly decreased viability in G2/M cells and led these cells to release more LDH than other cells. These treated cells also released certain substances that inhibited cell growth. These results strongly suggest that the cell membrane of the treated G2/M-cells is disrupted, leading to the leakage of LDH and cell growth inhibitory substances out of cell. Furthermore, the typical events of apoptosis, such as the release of cytochrome c and the decrease of mitochondria membrane potential, occur primarily in S stage rather than in the G2/M stages. These results suggest that paclitaxel induces typical apoptosis in the G1- and S- cells, but it induces both apoptosis and necrosis in G2/M-phase cells.     

Human myelogenous leukemia cell line HL-60 cells resistant to differentiation induction by retinoic acid. Decreased content of glycosphingolipids and granulocytic differentiation by neolacto series gangliosides

We have recently reported that neolacto series gangliosides (NeuAc-nLc) are increased during granulocytic differentiation of human myelogenous leukemia cell line HL-60 cells induced by retinoic acid and that HL-60 cells are differentiated into mature granulocytes when the cells are cultivated with NeuAc-nLc (Nojiri, H., Kitagawa, S., Nakamura, M., Kirito, K., Enomoto, Y., and Saito, M. (1988) J. Biol. Chem. 263, 7443-7446). In contrast to these wild-type-HL-60 cells, HL-60 cells resistant to differentiation induction by retinoic acid showed a markedly decreased content of gangliosides, especially NeuAc-nLc, and did not show any increase in the content of gangliosides when cultivated with retinoic acid. Neutral glycosphingolipids, the precursors of gangliosides, were not accumulated in these resistant cells. When retinoic acid-resistant HL-60 cells were cultivated in the presence of NeuAc-nLc, the cells were found to be differentiated into mature granulocytes on morphological and functional criteria. The differentiation of cells was dependent on the concentration of gangliosides and was accompanied by inhibition of cell growth. Wild-type HL-60 cells differentiated by NeuAc-nLc showed the changes in ganglioside composition, which were similar to those in wild-type HL-60 cells differentiated by retinoic acid; among the gangliosides changed, 2----3 sialylparagloboside and 2----3 sialylnorhexaosylceramide were increased. These findings suggest (a) that the synthesis of particular NeuAc-nLe molecules is an important step for retinoic acid-induced granulocytic differentiation and this step could be bypassed or replaced by exogenous NeuAc-nLc, and (b) that the defective synthesis of particular NeuAc-nLc molecules is responsible for the failure of differentiation induction in retinoic acid-resistant HL-60 cells by retinoic acid.     

Cell cycle-dependence of HL-60 cell deformability.

In this study, the role of cytoskeleton in HL-60 deformability during the cell cycle was investigated. G1, S, and G2/M cell fractions were separated by centrifugal elutriation. Cell deformability was evaluated by pipette aspiration. Tested at the same aspiration pressures, S cells were found to be less deformable than G1 cells. Moreover, HL-60 cells exhibited power-law fluid behavior: mu = mu c(gamma m/ gamma c)-b, where mu is cytoplasmic viscosity, gamma m is mean shear rate, mu c is the characteristic viscosity at the characteristic shear rate gamma c, and b is a material constant. At a given shear rate, S cells (mu c = 276 +/- 14 Pa.s, b = 0.51 +/- 0.03) were more viscous than G1 cells (mu c = 197 +/- 25, b = 0.53 +/- 0.02). To evaluate the relative importance of different cytoskeletal components in these cell cycle-dependent properties, HL-60 cells were treated with 30 microM dihydrocytochalasin B (DHB) to disrupt F-actin or 100 microM colchicine to collapse microtubules. DHB dramatically softened both G1 and S cells, which reduced the material constants mu c by approximately 65% and b by 20-30%. Colchicine had a limited effect on G1 cells but significantly reduced mu c of S cells (approximately 25%). Thus, F-actin plays the predominate role in determining cell mechanical properties, but disruption of microtubules may also influence the behavior of proliferating cells in a cell cycle-dependent fashion.     

Uptake of transcobalamin II-bound cobalamin by HL-60 cells: effects of differentiation induction

Binding and uptake of transcobalamin II-bound cobalamin by HL-60 promyelocytic leukemia cells proceed through receptor-mediated endocytosis. The affinity constant of the receptor for transcobalamin II-cobalamin was found to be 6.1 liter/nmol and the maximal rate of uptake 12 pmol/10(9) cells/h. This uptake is mediated by about 3000 receptor sites per cell. Evidence is presented that the receptor recirculates from the cell surface to the lysosomes and vice versa. Upon differentiation induction of the cells by either DMSO in granulocytic direction or by 1,25-dihydroxy-vitamin D3 in monocytic direction a rapid decline in cellular uptake and cell surface binding of the protein-bound vitamin ensues. In particular the internalization of the complex decreases faster than all other observed signs of the ongoing differentiation process, such as reduction in the OKT9-reactive transferrin receptor, increase in lineage-specific surface markers, and decrease in [3H]thymidine incorporation and actual cell proliferation. The transcobalamin II receptor on the cell surface appears to be a proliferation-associated membrane component in human leukemic cells.     

Cell cycle dependence of calmodulin levels during HL-60 proliferation and myeloid differentiation: No changes during pre-commitment

The putative role of Ca²⁺ and calmodulin in regulating cell proliferation and differentiation was tested in HL-60 human promyelocytic leukemia cells. The dependence of retinoic acid (RA)-induced terminal myeloid differentiation of HL-60 promyelocytic leukemia cells on calmodulin levels and calcium ion flux was ascertained. RA-treated and untreated control cells were stained for cellular DNA with a Hoechst dye. Populations of G1/0, S and G2+M phase cells were isolated by fluorescence activated cell sorting (FACS). Cytosolic calmodulin levels were then measured as a function of cell cycle phase for RA-treated and untreated cells using a radioimmunoassay. RA-treated cells were measured at early times, corresponding to the precommitment state, and late times, when significant cell differentiation had occurred. Cellular calmodulin levels increased with progression through the cell cycle. In contrast, no difference in calmodulin levels was observed between RA-untreated or -treated cells in the same cell cycle phases at early or late times. RA-induced HL-60 terminal myeloid differentiation was thus apparently not regulated by cellular cytosolic calmodulin levels. These conclusions were supported by the effects of calmodulin antagonists and calcium flux inhibitors. The calmodulin antagonists trifluoperazine and compound 48/80 both retarded cell growth in a concentration-dependent manner. But at concentrations where cellular effect was evidenced by slight growth inhibition, neither antagonist inhibited RA-induced cell differentiation or G1/0 growth arrest. The same was true of the gated calcium channel inhibitors, verapamil and nitrendipene, and the passive calcium flux inhibitor, CoC1₂. RA-induced HL-60 cell differentiation and arrest in G0 was thus apparently not strongly dependent on cellular calmodulin levels or calcium flux. This is in strong contrast to murine erythroleukemia cells. The results argue against a central regulatory role for calmodulin or calcium flux in control of HL-60 growth arrest or differentiation.     

Luminol and diazoluminomelanin as indicators of HL-60 cell differentiation

Summary This paper describes use of a novel substituted melanin which is useful in detection of differentiating leukemia cells and their membranes. Comparisons of luminol-(5-amino-2,3-dihydro-1,4-phthalazinedione) and diazoluminomelanin (DALM)-mediated chemiluminescence (CL) were made with various types of differentiated and undifferentiated HL-60 whole cells, cell lysates, and membrane fractions. Luminol had a greater CL response than DALM with HL-60 promyelocytic stem cells and differentiated macrophage-like or neutrophil-like whole cell and cell lysate preparations. However, DALM showed markedly greater CL than luminol for membrane fractions derived from each cell type. The greatest luminol-dependent CL was observed for cell types high in myeloperoxidase (MPO). The greatest DALM-mediated CL was seen with cell types that are high in MPO or strong producers of superoxide (O_2-) anions. In some cases, significant differences in CL could also be distinguished on the basis of inducing agent used [i.e. dimethylsulfoxide, all-trans retinoic acid or 12-o-tetradecanoylphorbol-13-acetate]. Both luminol- and DALM-dependent CL were strongly inhibited by preincubation of cellular preparations with 3-amino-l-tyrosine (a component of DALM). Taken together, these data suggest that the reaction mechanism of luminol favors interaction with cytoplasmic MPO whereas that of DALM favors membrane interactions. Thus, both reagents may be of use in assays to detect differentiating leukocytes or their cellular components.     

DMSO and retinoic acid induce HL-60 differentiation by different but converging pathways

The expression of c-myc and two calcium-binding proteins, MRP8 and MRP14, has been analyzed in wild-type and differentiation-resistant HL-60 variants. In HL-R5 cells, resistant to the induction of differentiation by retinoic acid but not DMSO, the characteristic c-myc down-regulation which is associated with HL-60 differentiation, as well as increased levels of MRP8 and MRP14, is detectable only after DMSO treatment. By contrast HL-D4 cells, which were selected for resistance to the induction of differentiation by DMSO alone, are actually resistant to both DMSO and retinoic acid. However, treatment of HL-D4 cells with DMSO results in a transient c-myc down-regulation in the absence of either growth arrest or induction of differentiation. Neither agent can induce an increase in the level of either MRP8 or MRP14 in HL-D4. The resistance of HL-D4 cells to DMSO and retinoic acid, and the different effects of these agents on c-myc RNA levels, despite their common effect on the expression of MRP8 and MRP14, suggest that the two agents act through different pathways which coverage before the onset of myeloid differentiation in HL-60 cells.     

Differentiation of HL-60 cells: cell volume and cell cycle changes

HL-60 promyelocytic leukemic cells can differentiate into more mature myeloid cells with the addition of dimethylsulfoxide, butyric acid or retinoic acid and can differentiate into macrophages with the addition of phorbol ester 12-0-tetradecanoylphorbol-13-acetate (TPA). After the addition of an inducer, the HL-60 cell volume shows a daily decrease while the cell number increases at a rate similar to the untreated control cells. Flow cytometry measurements show an increase in G1 cells and a decrease in S cells after day 1. Since the generation time is constant, the data suggest that the length of time spent in the different cell cycle stages has changed during differentiation. Within 3 hours after the addition of TPA to HL-60 cells, selective adhesion of G1 cells occurs. Smaller sized cells are recovered from the flask bottom and larger sized cells are recovered from the supernate. Flow cytometric analysis reveals a G1 and S block in cells obtained from both the supernatant and from the flask bottom. After 1 day of TPA incubation, there is preferential adhesion of G1 and G2 cells with the nonadherent cells being primarily in the S and G2 cell cycle stages and undergoing a cell cycle traverse.     

PpGalNacT2 participating in vanadium-induced HL-60 cell differentiation

The current study demonstrates vanadium plays the role of antitumor, and its antitumor effect is dosage-dependent. N-acetyl-galactosamine-transferase 2 (polypeptide: N-acetyl-α-galactosaminyl-transferases 2, ppGalNAc-T2) is a member of ppGalNAcTs (polypeptide: N-acetyl-α-galactosaminyl-transferases) family, which proves to play a vital role in the tumor emergence and development process. In this study, we focused on ppGalNAc-T2 and vanadium and aimed to determine whether ppGalNAc-T2 is correlated with vanadium’s antitumor effect. We discovered that ppGalNAc-T2 changed with the variation of HL-60 cell growth induced by vanadium at mRNA level. Peanut agglutinin (PNA) is an exogenous lectin. PpGalNacT2 can be indirectly recognized by PNA. By means of flow cytometry and immunofluorescent staining, we found the deviation of PNA binding increased significantly at high concentration vanadium. Then we docked one of the possible compound substances of vanadium onto the body, VO₃ (molecular formula O₁₃V₄, partial vanadate tetramer) and ppGalNAcT2, and simulated them via molecular dynamics, which showed that VO₃ may inhibit the activity of the enzyme by stemming conformational changes of a key loop of ppGalNAcT2. To sum up, our results suggested that ppGalNacT2 participated in vanadium induced HL-60 cell differentiation, which might be able to provide a new mechanism of vanadium’s antitumor effect.     

Induction of the differentiation of HL-60 promyelocytic leukemia cells by L-ascorbic acid

The present study was undertaken to examine the effect of L-ascorbic acid (LAA) on the growth of HL-60 promyelocytic leukemia cells, besides induction of apoptosis. LAA (> or = 10(-4) M) was found to markedly inhibit the proliferation of HL-60 in liquid culture and clonogenicity in semisolid culture. Moreover, LAA-treated HL-60 showed activity to produce chemiluminescence and expressed CD 66b cell surface antigens, indicating that LAA induces the differentiation of HL-60 mainly into granulocytes. The results are supported by morphological changes of LAA-treated HL-60 into segmented neutrophils. Therefore, the inhibitory effect of LAA on the growth of HL-60 cells seems to arise from the induction of differentiation. To assess the potential role of LAA, cells were exposed to oxygen radical scavengers in the absence or presence of LAA. Catalase abolished and superoxide dismutase promoted LAA-induced differentiation of HL-60. Thus, H2O2 produced as a result of LAA treatment seems to play a major role in induction of HL-60 differentiation.     

Retinoic acid differentiation of HL-60 cells promotes cytoskeletal polarization

Retinoic acid (RA) treatment of HL-60 cells in vitro induces granulocytic differentiation, involving reorganization of the nucleus and cytoplasm, development of chemoattractant-directed migration, and eventual apoptosis. The present studies with HL-60/S4 cells document that major elements of the cytoskeleton are changed: actin increases by 50%; vimentin decreases by more than 95%. The cellular content of alpha-tubulin does not significantly change; but the centrosomal-microtubule (MT) array moves away from the lobulating nucleus. Cytoskeletal-modifying chemicals modulate this polarized reorganization: Taxol and cytochalasin D enhance centrosome movement; nocodazole reverses it. Cytoskeletal-modifying chemicals do not appear to affect nuclear lobulation or the integrity of envelope-limited chromatin sheets (ELCS). Employing bcl-2-overexpressing HL-60 cells permitted demonstration of nuclear lobulation, ELCS formation, and centrosome-MT movement concomitantly during RA-induced differentiation, implying independence between the cellular reorganization and apoptotic programs. RA appears to promote an inherent potential in HL-60 cells for cytoskeletal polarization, likely to be important for chemoattractant-directed cell migration, an established characteristic of mature granulocytes.