Induction of apoptosis by combined treatment with differentiation-inducing agents and interferon-alpha in human lung cancer cells.

BACKGROUND: Differentiation-inducing agents for myeloid leukemic cells, such as dimethyl sulfoxide (DMSO), Na-butyrate and hexamethylene-bis-acetamide (HMBA), barely induce irreversible differentiation or growth inhibition in solid tumors when used alone. However, we previously reported that combined treatment with differentiation-inducing agents and interferon (IFN)-alpha effectively suppressed the growth of human lung cancer cell lines in vitro and in vivo. We show here that combined treatment-induced cell death is caused by apoptosis. MATERIALS AND METHODS: Induction of apoptosis was examined by expression of several apoptotic markers. RESULTS: Combined treatment-induced cell death is caused by apoptosis, which is characterized by the induction of apoptotic morphological changes and the activation of caspase-3-like protease. The expression of Apo2.7, an early apoptotic change, is also induced by this combined treatment, and is suppressed by the addition of Z-Asp-CH2-DCB, a pan caspase inhibitor. The signal transduction pathway of IFN-alpha is rapidly observed in lung cancer cells, although it does not induce significant growth inhibition when used alone. We analyzed the effect of IFN-alpha on the apoptotic pathway and found that IFN-alpha but not DMSO induces the expression of caspase-4. The combination of IFN-alpha and DMSO did not cause further increase in the expression of caspase-4. In many cases of the induction of apoptosis, cytochrome c is released from mitochondria, which induces the formation of large caspase-activating complexes. Caspase-3-like-activities induced by the combination of DMSO or Na-butyrate with IFN-alpha were analyzed by gel filtration and detected equally in fractions with molecular weights of 200-300 kDa, suggesting that caspase-3 is activated in large complexes in lung cancer cells. However, Na-butyrate and HMBA, when used alone, induced the release of cytochrome c and enhanced the loss of mitochondrial membrane potential, whereas DMSO had no effect. CONCLUSION: These results suggest that the combination of differentiation-inducing agents with IFN-alpha effectively induces apoptosis in lung cancer cells whereas the mechanism of such induction varies depending on the differentiation-inducing agent used.

Estrogen receptor (ER) beta1 and ERbetacx/beta2 inhibit ERalpha function differently in breast cancer cell line MCF7.

Estrogen receptor (ER) alpha plays an important role in the proliferation and progression of breast cancer. In order to explore the function of wild-type ERbeta (ERbeta1) and its variant form, ERbetacx/beta2, stable transformants of ERalpha-positive breast cancer MCF7 cells with ERbeta1 or ERbetacx/beta2 expression vector were established. Constitutive expression of ERbeta1 or ERbetacx/beta2 reduced the S phase population of the cell cycle in dish culture and the number of colonies in an anchorage-independent assay. DNA-protein complexes of ERE with nuclear extracts from ERbeta1 transformants were observed in the electrophoretic mobility shift assay, while no complex was observed for ERbetacx/beta2 transformants. Reporter gene assay using estrogen-responsive element (ERE)-luciferase showed less responsiveness to estrogen in these transformants compared with parental cells. Endogenous mRNA expression of two known estrogen-responsive genes, cathepsin D and IGFBP4, was weakly induced by estrogen in ERbeta1 and ERbetacx/beta2 transformants compared with parental cells. A comprehensive gene expression analysis using our custom-made cDNA microarray showed that MCF7 and ERbeta1 transformants had a similar gene expression profile, whereas ERbetacx/beta2 showed a distinct profile from others. These results indicate that ERbeta1 and ERbetacx/beta2 inhibit ERalpha function differently in MCF7 cells.

Cotylenin A, a differentiation-inducing agent, and IFN-alpha cooperatively induce apoptosis and have an antitumor effect on human non-small cell lung carcinoma cells in nude mice.

Cotylenin A, a novel inducer of the differentiation of leukemia cells, and IFN-alpha synergistically inhibited the growth of and induced apoptosis in several human non-small cell lung carcinoma cell lines. Tumor necrosis factor-related apoptosis-inducing ligand (TRAIL) and its receptor DR5 were the early genes induced by the combination of cotylenin A and IFN alpha in lung carcinoma cells. Neutralizing antibody to TRAIL inhibited apoptosis, suggesting that cotylenin A and IFN alpha cooperatively induced apoptosis through the TRAIL signaling system. This combined treatment preferentially induced apoptosis in human lung cancer cells while sparing normal lung epithelial cells and significantly inhibited the growth of human lung cancer cells as xenografts without apparent adverse effects, suggesting that this combination may have therapeutic value in treating lung cancer.

Role of MmTRA1b/phospholipid scramblase1 gene expression in the induction of differentiation of human myeloid leukemia cells into granulocytes.

OBJECTIVE: We previously cloned a human normal counterpart (MmTRA1b/phospholipid scramblase 1) of the mouse leukemogenesis-associated gene MmTRA1a. MmTRA1b gene expression was increased during differentiation of human monoblastic leukemia U937 cells using some differentiation inducers but not 1alpha,25-dihydroxyvitamin D(3) (a typical monocytic differentiation inducer). To further elucidate the role of human MmTRA1b gene expression in the differentiation of myelogenous leukemia cells, we measured MmTRA1b gene expression in several myeloid leukemia cell lines and primary leukemia cells. MATERIALS AND METHODS: The expression of MmTRA1b mRNA was determined by semiquantitative reverse transcriptase polymerase chain reaction. RESULTS: Expression of the MmTRA1b gene was markedly induced during granulocytic differentiation of promyelocytic leukemia NB4 and HT93 cells induced by all-trans retinoic acid (ATRA). The level of MmTRA1b mRNA was significantly increased during differentiation toward granulocytes, but not monocytes/macrophages, in bipotential myeloid leukemia HL-60 cells. The level of MmTRA1 mRNA was not increased during erythroid differentiation induced by hemin in erythroid leukemia K562 and HEL cells or during megakaryocytic differentiation induced by 12-O-tetradecanoylphorbol-13-acetate in K562 cells. Expression of the MmTRA1b gene also was not induced when apoptosis of NB4 cells was induced by antileukemic drugs. ATRA-induced differentiation of antisense MmTRA1b-transfected NB4 cells was significantly suppressed. On the other hand, ATRA induced the differentiation of MmTRA1b-transfected NB4 cells more efficiently than that of mock-transfected cells. MmTRA1b mRNA also was clearly induced in ATRA-treated primary acute promyelocytic leukemia cells during granulocytic differentiation. CONCLUSION: MmTRA1b mRNA was specifically induced during granulocytic differentiation of acute promyelocytic leukemia cells and was associated with induction of their differentiation.