JCS Cells Research Articles

A recombined protein (rSj16) derived from Schistosoma japonicum induces cell cycle arrest and apoptosis of murine myeloid leukemia cells

rSj16, a recombined protein from Schistosoma japonicum, has been identified as an anti-inflammatory molecule. In this study, we demonstrated that rSj16 strongly suppressed the growth of murine myeloid leukemia WEHI-3B JCS cells in a dose- and time-dependent manner. rSj16 induced apoptosis by increasing the proportion of sub-G1 apoptotic cells as well as causing cell cycle arrest at the G0/G1 phase. The expressions of cyclin D1, D2, D3, and E, and Cdk 2, 4, and 6 genes in WEHI-3B JCS cells were significantly down-regulated at 24h as measured by real-time PCR. Furthermore, apoptosis induced by rSj16 was confirmed by 4,6-diamidino-2-phenylindole nuclear staining assay and annexin V/propidium iodide double staining. A reduction of the mitochondrial membrane potential indicated an active involvement of mitochondria in the apoptosis process. rSj16 treatment induced an increase in the activity of caspase 3, 6, and 9, and expression of pro-apoptotic Bax. Meanwhile, the decreased expression of anti-apoptotic Bcl-2 was observed after rSj16 treatment. Taken together, our results implied that rSj16 can inhibit proliferation by inducing G0/G1 cell cycle arrest and apoptosis of murine myeloid leukemia cells via activation of the caspase-mediated mechanism by regulating the expression of Bcl-2 family.

Anti-Inflammatory Protein ofSchistosoma japonicumDirects the Differentiation of the WEHI-3B JCS Cells and Mouse Bone Marrow Cells to Macrophages

Sj16 is an anti-inflammatory protein identified from Schistosoma japonicum. Our previous studies showed that recombinant Sj16 (rSj16) could suppress host's inflammatory responses and inhibit macrophage maturation. In the present study, the effects of rSj16 on the differentiation of the murine myeloid leukemia WEHI-3B JCS cell line and on mouse hematopoiesis were investigated. Our data demonstrated that rSj16 expressed and purified from Escherichia coli could suppress the proliferation of the WEHI-3B JCS cells in a time- and concentration-dependent manner, while not affect the viability of the cells. Further studies indicated that rSj16 induced macrophage differentiation of the WEHI-3B JCS cells, and arrested the cell cycle in the G1/G0 and G2/M phases. The macrophage differentiation of the rSj16-treated WEHI-3B JCS cells was confirmed by their expression of macrophage specific antigen F4/80 and phagocytic activity. Furthermore, our results revealed that rSj16 biased the colony formation of mouse bone marrow cells towards macrophage linage.

Modulatory Effects and Action Mechanisms of Tryptanthrin on Murine Myeloid Leukemia Cells

Leukemia is the disorder of hematopoietic cell development and is characterized by an uncoupling of cell proliferation and differentiation. There is a pressing need for the development of novel tactics for leukemia therapy as conventional treatments often have severe adverse side effects. Tryptanthrin (6,12-dihydro-6,12-dioxoindolo-(2,1-b)-quinazoline) is a naturally-occurring, weakly basic alkaloid isolated from the dried roots of medicinal indigo plants (Ban-Lan-Gen). It has been reported to have various biological and pharmacological activities, including anti-microbial, anti-inflammatory, immunomodulatory and anti-tumor effects. However, its modulatory effects and action mechanisms on myeloid cells remain poorly understood. In this study, tryptanthrin was shown to suppress the proliferation of the murine myeloid leukemia WEHI-3B JCS cells in a dose- and time-dependent manner. It also significantly reduced the growth of WEHI-3B JCS cells in vivo in syngeneic BALB/c mice. However, it exhibited no significant direct cytotoxicity on normal murine peritoneal macrophages. Flow cytometric analysis showed an obvious cell cycle arrest of the tryptanthrin-treated WEHI-3B JCS cells at the G0/G1 phase. The expression of cyclin D2, D3, Cdk 2, 4 and 6 genes in WEHI-3B JCS cells was found to be down-regulated at 24 h as measured by RT-PCR. Morphological and functional studies revealed that tryptanthrin could induce differentiation in WEHI-3B JCS cells, as shown by the increases in vacuolation, cellular granularity and NBT-reducing activity in tryptanthrin-treated cells. Collectively, our findings suggest that tryptanthrin might exert its anti-tumor effect on the murine myelomonocytic leukemia WEHI-3B JCS cells by causing cell cycle arrest and by triggering cell differentiation.

Subcellular Localization of Merocyanine 540 (MC540) and Induction of Apoptosis in Murine Myeloid Leukemia Cells ¶

Subcellular localization of photosensitizers is thought to play a critical role in determining the mode of cell death after photodynamic treatment (PDT) of leukemia cells. Using confocal laser scanning microscopy and fluorescent organelle probes, we examined the subcellular localization of merocyanine 540 (MC540) in the murine myeloid leukemia M1 and WEHI 3B (JCS) cells. Two patterns of localization were observed: in JCS cells, MC540 was found to localize on the plasma membrane and mitochondria; and in M1 leukemia cells, MC540 was found to localize on lysosomes. The relationship between subcellular localization of MC540 and PDT-induced apoptosis was investigated. Apoptotic cell death, as judged by the formation of apoptotic nuclei, was observed 4 h after irradiation in both leukemia cell lines. Typical ladders of apoptotic DNA fragments were also detected by DNA gel electrophoresis in PDT-treated JCS and M1 cells. At the irradiation dose of 46 kJ/m2 (LD90 for JCS and LD86 for M1 cells), the percentage of apoptotic JCS and M1 cells was 78 and 38%, respectively. This study provided substantial evidence that MC540 localized differentially in the mitochondria, and the subsequent photodamage of the organelle played an important role in PDT-mediated apoptosis in myeloid leukemia cells.

Characterization of murine interferon-alpha 12 (MuIFN-α12): Biological activities and gene expression

Interferon alpha (IFN-α) belongs to the type I interferon family and consists of multiple subtypes in many species. In the mouse, there are at least 14 IFN-α genes and 3 IFN-α pseudogenes, the most recently identified of which are murine interferon-alpha 12 (MuIFN-α12), MuIFN-α13 and MuIFN-α14. To further study the biological activities of MuIFN-α12, we have produced a recombinant MuIFN-α12 (rMuIFN-α12) protein using COS-1 cells. rMuIFN-α12 was found to inhibit the growth of murine myeloid leukemia JCS cells. Flow cytofluorometric analysis with propidium iodide staining showed that the growth inhibitory activity of rMuIFN-α12 may be caused by the induction of apoptosis. Flow cytofluorometric analysis also revealed that rMuIFN-α12 was able to up-regulate the expression of MHC-I on both JCS cells and primary macrophages. Functional studies indicated that a MuIFN-α12 transgene could induce an anti-viral state in L929 cells against Influenza A virus. Moreover, expression of MuIFN-α12 was not detectable by RT-PCR in untreated, Influenza A virus infected, polyI:polyC induced L929 cells, or in a wide range of normal murine tissues. Taken together, this data shows that MuIFN-α12 is a protein with all the biological traits of a type I IFN.

Comparative study of the growth-inhibitory and apoptosis-inducing activities of black tea theaflavins and green tea catechin on murine myeloid leukemia cells

Among the black tea polyphenols, theaflavins are generally considered to be the more effective components for the inhibition of carcinogenesis. In this study, we attempted to compare the growth-inhibitory and apoptosis-inducing activities of the four black tea theaflavins (TF-1, TF-2A, TF-2B and TF-3) with the major green tea catechin epigallocatechin-3-gallate (EGCG) on the murine myeloid leukemia WEHI-3B JCS cells. All the four black tea theaflavins were shown to exert potent anti-proliferative and cytotoxic effects on the leukemia WEHI-3B JCS cells in a dose-dependent manner. The observed anti-proliferative and cytotoxic effects were in the following order of potency: EGCG > TF-2B > TF-3 > TF-2A > TF-1. In addition, all theaflavins were capable of inducing apoptosis in the leukemia WEHI-3B JCS cells. Among the four theaflavins tested, TF-2B and TF-3 were found to be slightly more potent in inducing apoptosis of the WEHI-3B JCS cells than that of TF-2A and TF-1 but were comparable to the major green tea epicatechin EGCG. More interestingly, both TF-2B and TF-3 were found to be much more effective than TF-1 and TF-2B in reducing both the in vitro clonogenicity and in vivo tumorigenicity of the WEHI-3B JCS cells, suggesting that these two black tea theaflavins might represent potential candidates for the treatment of some forms of leukemia.

Involvement of tumor necrosis factor (TNF-α) in arsenic trioxide induced apoptotic cell death of murine myeloid leukemia cells

Arsenic trioxide (As 2O 3) has recently been shown to be effective to inhibit the growth and to induce apoptosis in acute promyelocytic leukemia (APL) but not in acute myeloid leukemia (AML) cells. Recently, we have isolated an As 2O 3 sensitive subclone JCS-16 from the murine myeloid leukemia WEHI 3B (JCS). At the concentrations of 0.3–3 μM, As 2O 3 induces a dose-dependent cytotoxicity and growth inhibition on the JCS-16 cells. As 2O 3 also induces apoptotic cell death, as judged by the presence of apoptotic nuclei, at 6 h after treatment. Morphological differentiation was not observed in As 2O 3 treated JCS cells. Neutralizing anti-TNF-α antibody was found to reduce the As 2O 3-mediated apoptotic cell death of JCS-16 cells. Growth inhibitory effect of As 2O 3 was also reduced after the addition of anti-TNF-α. In addition, reverse transcription polymerase chain reaction (RT-PCR) and reverse northern blot analysis demonstrated that the expression of TNF receptor (TNF-R2), IL-4, and IL-4R was down-regulate at 1 h after As 2O 3 treatment. The expression of TNF-α and TNF-R1 was not affected. Our results suggest that the autocrine action of TNF-α might play a role in As 2O 3-induced apoptotic cell death of JCS-16 leukemia cells.

Subcellular localization of merocyanine 540 (MC540) and induction of apoptosis in murine myeloid leukemia cells.

Subcellular localization of photosensitizers is thought to play a critical role in determining the mode of cell death after photodynamic treatment (PDT) of leukemia cells. Using confocal laser scanning microscopy and fluorescent organelle probes, we examined the subcellular localization of merocyanine 540 (MC540) in the murine myeloid leukemia M1 and WEHI 3B (JCS) cells. Two patterns of localization were observed: in JCS cells, MC540 was found to localize on the plasma membrane and mitochondria; and in M1 leukemia cells, MC540 was found to localize on lysosomes. The relationship between subcellular localization of MC540 and PDT-induced apoptosis was investigated. Apoptotic cell death, as judged by the formation of apoptotic nuclei, was observed 4 h after irradiation in both leukemia cell lines. Typical ladders of apoptotic DNA fragments were also detected by DNA gel electrophoresis in PDT-treated JCS and M1 cells. At the irradiation dose of 46 kJ/m2 (LD90 for JCS and LD86 for M1 cells), the percentage of apoptotic JCS and M1 cells was 78 and 38%, respectively. This study provided substantial evidence that MC540 localized differentially in the mitochondria, and the subsequent photodamage of the organelle played an important role in PDT-mediated apoptosis in myeloid leukemia cells.

The binding characteristics and intracellular localization of temoporfin (mTHPC) in myeloid leukemia cells: phototoxicity and mitochondrial damage .

The state of aggregation of the photosensitizer meso-tetrahydroxyphenylchlorin (mTHPC) in both cell free and intracellular environment was elucidated by comparing its absorption and excitation spectra. In methanol, mTHPC existed as monomers and strongly fluoresced. In aqueous solutions such as phosphate-buffered saline (PBS), mTHPC formed nonfluorescent aggregates. Some portion of mTHPC monomerized in the presence of 10% fetal calf serum PBS. In murine myeloid leukemia M1 and WEHI-3B (JCS) cells, cytoplasmic mTHPC were monomeric. By using organelle-specific fluorescent probes, it was found that mTHPC localized preferentially at the mitochondria and the perinuclear region. Photodynamic treatment of mTHPC-sensitized leukemia cells caused rapid appearance of the apoptogenic protein cytochrome c in the cytosol. Results from flow cytometric analysis showed that the release of cytochrome c was especially pronounced in JCS cells, and well correlated with the extent of apoptotic cell death as reported earlier. Electron microscopy revealed the loss of integrity of the mitochondrial membrane and the appearance of chromatin condensation as early as 1 h after light irradiation. We conclude that rapid release of cytochrome c from photodamaged mitochondria is responsible for the mTHPC-induced apoptosis in the myeloid leukemia JCS and M1 cells.

A Comparison of the Photodynamic Effects of Temoporfin (mTHPC) and MC540 on Leukemia Cells: Efficacy and Apoptosis

The photodynamic effects of temoporfin (meso-tetrahydroxyphenylchlorin, mTHPC) and merocyanine 540 (MC540) in murine myeloid leukemia M1 and WEHI 3B (JCS) cells were compared. The mTHPC was found to be more potent and selective. At a lethal dosage of 90% killing (LD90), only 1.3 microM of mTHPC and 4.2 kJ/m2 of light irradiation was required, which was a 20-fold lower drug concentration and 11-fold smaller light dose than that required when using MC540. Meanwhile, three times less, or 15%, of the coincubated erythrocytes were destroyed by mTHPC than by MC540. Confocal micrographs showed that both drugs accumulated diffusely inside the cytoplasm in a very similar fashion, but mTHPC induced a more extensive apoptosis in photosensitized JCS cells. For example, at LD90, mTHPC practically killed all JCS cells via apoptosis and cleaved the DNA to extremely small 150 base-pair fragments. In contrast, among the JCS cells killed by MC540, about 88% died via apoptosis and large DNA fragments were abundant. Relative to MC540, the ability of mTHPC to trigger large-scale and thorough apoptosis in leukemia cells may help explain its potency and selectivity.

A Comparison of the Photodynamic Effects of Temoporfin (mTHPC) and MC540 on Leukemia Cells: Efficacy and Apoptosis

The photodynamic effects of temoporfin (meso-tetrahy-droxyphenylchlorin, mTHPC) and merocyanine 540 (MC540) in murine myeloid leukemia M1 and WEHI 3B (JCS) cells were compared. The mTHPC was found to be more potent and selective. At a lethal dosage of 90% killing (LD90), only 1.3 μM of mTHPC and 4.2 kj/m2 of light irradiation was required, which was a 20-fold lower drug concentration and 11-fold smaller light dose than that required when using MC540. Meanwhile, three times less, or 15%, of the coincubated erythrocytes were destroyed by mTHPC than by MC540. Confocal micrographs showed that both drugs accumulated diffusely inside the cytoplasm in a very similar fashion, but mTHPC induced a more extensive apoptosis in photosensitized JCS cells. For example, at LD90, mTHPC practically killed all JCS cells via apoptosis and cleaved the DNA to extremely small 150 base-pair fragments. In contrast, among the JCS cells killed by MC540, about 88% died via apoptosis and large DNA fragments were abundant. Relative to MC540, the ability of mTHPC to trigger large-scale and thorough apoptosis in leukemia cells may help explain its potency and selectivity.

Effects of biochanin A on the growth and differentiation of myeloid leukemia WEHI-3B (JCS) cells

The effects of biochanin A on the growth and differentiation of a recently characterized myeloid leukemia cell line WEHI-3B (JCS) were investigated. Biochanin A not only inhibited the growth of JCS cells in a dose-dependent manner (0 – 200 μM) but also induced the morphological differentiation of JCS cells. The phagocytic activity of biochanin A-treated JCS cells was also increased. Flow cytometric analysis showed that the expression of macrophage differentiation markers Mac-1 and F4 80 was up-regulated in biochanin A-treated JCS cells. The expression level of Mac-1 was higher than that of F4 80 . The expression of cytokine genes was studied by reverse transcription-polymerase chain reaction (RT-PCR) and cycle titration. mRNA levels of IL-1α, IL-1β and IL-4 were found to be up-regulated at 46 hours after incubation of JCS cells with biochanin A. Although the expression of LIF was also up-regulated, the LIF receptor gene was not expressed in the uninduced or induced JCS cells. Our results suggest that IL-1α, IL-1β and IL-4 may act on the later stage of biochanin A-mediated differentiation of JCS cells.

Involvement of interleukin-1 in the differentiation-inducing activity of tumor necrosis factor-alpha on a murine myeloid leukemia (WEHI-3B JCS)

We have shown previously that tumor necrosis factor-alpha (TNF-alpha) inhibits the growth and induces the differentiation of a murine myelomonocytic leukemia (WEHI-3B JCS cells) into macrophage-like cells. In this study, using reverse transcription polymerase chain reaction, we found that both endogenous interleukin-1 alpha and beta (IL-1 alpha, IL-1 beta) mRNA were up-regulated upon TNF-alpha induction. Exogenous IL-1 alpha and IL-1 beta also inhibited the growth as well as induced the differentiation of JCS cells, with IL-1 beta exerting a greater growth-inhibitory effect. Neutralizing anti-IL-1 alpha, anti-IL-1 beta and anti-TNF-alpha antibodies were further used to elucidate the role of IL-1 alpha, IL-1 beta and TNF-alpha in JCS cell differentiation. The results show that the IL-1 alpha-induced monocytic differentiation of JCS cells was effectively blocked by anti-IL-1 beta as well as anti-IL-1 beta antibodies and to a lesser extent by anti-TNF-alpha antibody. In contrast, the differentiation-inducing effect of IL-1 beta on JCS cells was only blocked by anti-IL-1 beta antibody but not by anti-IL-1 alpha or anti-TNF-alpha antibody. Finally, the TNF-alpha-induced monocytic differentiation of JCS cells was significantly blocked by anti-TNF-alpha and to a lesser extent by anti-IL-1 alpha and anti-IL-1 beta antibodies. Collectively, our results suggest that IL-1 beta alone may directly trigger JCS cell differentiation whereas the differentiation-inducing effect of IL-1 alpha may be via the endogenous production of IL-1 beta and/or TNF-alpha. In addition, IL-1 alpha and IL-1 beta may be involved, at least in part, in TNF-alpha-induced monocytic differentiation of the JCS leukemia cells.

Effects of midazolam on the differentiation of murine myeloid leukemia cells.

The effects of midazolam (MID) on the in vitro growth and differentiation of two murine myeloid leukemia WEHI 3B (JCS) and M1 cells were studied. MID inhibits the proliferation of both M1 and JCS cells in a dose-dependent manner. At the concentration of 10 micrograms/ml, MID was found to induce both monocytic and granulocytic differentiation of the JCS but not M1 cells. Induction of morphological differentiation of the JCS cells was also associated with the enhanced expression of the differentiation antigens Mac-1, F4/80, and Gr-1 for the cells. Results from mRNA phenotyping experiments also indicated that the expression of tumor necrosis factor (TNF-alpha) and neutrophil-specific J11d differentiation marker was significantly upregulated in MID-treated JCS cells. In addition, the phagocytic activity of MID-treated JCS cells was increased towards opsonized yeast cells. Results from this investigation suggested that MID may be used as an inducer for further study on the mechanisms of differentiation in these myeloid leukemia cells.

Isolation of anti-leukemia compounds from Citrus reticulata

In vitro effects of medicinal plant extracts from the pericarpium of Citrus reticulata (cv Jiao Gan) (PCRJ) on the growth and differentiation of a recently characterized murine myeloid leukemic cell clone WEHI 3B (JCS) were investigated. Extracts of PCRJ not only inhibited the proliferation of JCS cells in a dose dependent manner, but also induced differentiation of JCS cells into macrophages and granulocytes. Morphological differentiation of PCRJ treated JCS cells was associated with an increase in phagocytic activity of the cells. Furthermore, both in vitro clonogenicity and in vivo growth of PCRJ treated JCS leukemic cells in syngeneic BALB/c mice were significantly reduced. The survival rate of mice receiving PCRJ treated JCS tumour cells was also increased. Using 1H-NMR, 13C-NMR, and GC/MS, two active components isolated from PCRJ were identified as nobiletin and tangeretin.

Augmentation of Tumor Necrosis Factor-α-Induced Monocytic Differentiation of a Myelomonocytic Leukemia (WEHI-3B JCS) by Pertussis Toxin

We have shown that pertussis toxin (PTx) modulates the effect of tumor necrosis factor-alpha (TNF-α) in inducing monocytic differentiation of WEHI-3B (JCS) myeloid leukemic cells in vitro. PTx (0.1–2 ng/ml) alone was not cytotoxic and did not induce morphological changes in JCS cells. In the presence of a suboptimal concentration of TNF-α (25 U/ml), however, PTx (1 ng/ml) acted synergistically in inhibiting proliferation and in inducing monocytic differentiation of the JCS cells. Expression of the macrophage differentiation marker (Mac-1) on JCS cells was increased by the combination of PTx and TNF-α, and phagocytic activity of the cells was also enhanced. Moreover, JCS cells treated with PTx and TNF-α had reduced tumorigenic capacity in vivo. The data suggest that a PTx-sensitive G protein may be involved in regulating the TNF-α-induced monocytic differentiation of the myeloid leukemic JCS cells and that combination of PTx and TNF-α may be useful in the treatment of some forms of myelomonocytic leukemia.

Monocytic Differentiation of a Myelomonocytic Leukemic Cell (WEHI 3B JCS) Is Induced by Tumour Necrosis Factor-Alpha (TNF-α)

We have isolated a subclone (JCS) of the WEHI 3B myelomonocytic leukemia, which acquires the characteristics of mature macrophage lineage cells in the presence of PMA or noncytotoxic concentrations of TNF-α(600-1200 U/ml). JCS cells were compared with D + and D - subclones of WEHI 3B. Unlike D + cells, JCS cells did not produce differentiated granulocyte-macrophage colonies in the presence of postendotoxin serum or recombinant G-CSF. Stimulation with PMA or TNF-α reduced proliferation of JCS cells. TNF-α decreased the level of cell surface J11D antigen with concurrent increased expression of Mac-1 and FcR antigens and phagocylic activity. These TNF-α-mediated effects were enhanced by addition of IFN-γ to the cultures. Furthermore, differentiation-inducing activity of PMA could be prevented using neutralizing anti-TNF-α antibodies. The results indicate that exogenous TNF-α can act as a differentiative agent for JCS cells and that endogenous TNF-α is the active substance when PMA is used to stimulate macrophage differentiation of JCS cells.

Localization of the GTP-binding protein Gi alpha in myelomonocytic progenitor cells is regulated by proliferation (GM-CSF, IL-3) and differentiation (TNF) signals.

We have examined the role of Gi alpha in haemopoietic cells using the myelomonocytic progenitor cell lines FDC-P1 and WEHI-3B (JCS). During growth factor-dependent proliferation of FDC-P1 cells Gi alpha was found predominantly in the nucleus and associated with the plasma membrane. Following removal of growth factor, Gi alpha accumulated in the cytoplasm and at the plasma membrane. Treatment of FDC-P1 cells with pertussis toxin (PT) completely inhibited translocation of Gi alpha to the nucleus and reduced the sensitivity of FDC-P1 cells to the proliferative effects of growth factors, indicating that translocation of Gi alpha plays a regulatory role in, but may not be essential for, cell division. Gi alpha initially associated with DNA during S/G2 of the FDC-P1 cell cycle but separated from condensing chromosomes during mitosis. In contrast to FDC-P1 cells, WEHI-3B (JCS) cells proliferate in the absence of added growth factors but can be induced to differentiate by TNF-alpha. In proliferating JCS cells Gi alpha was again associated with the nucleus but when proliferation was inhibited by TNF-alpha, Gi alpha accumulated in the cytoplasm with none detected in the nucleus. Thus the cytokine regulated accumulation of Gi alpha at different intracellular sites correlated with the ability of the cell to progress through the proliferative cycle. When the tyrosine kinase inhibitor genistein was added to FDC-P1 cells prior to stimulation with IL-3 or GM-CSF, proliferation was almost completely inhibited but translocation of Gi alpha was not affected, suggesting that tyrosine phosphorylation was not involved in G protein translocation but was essential for cytokine induced cell division. Cholera toxin (CT) also inhibited proliferation of FDC-P1 cells but had no effect on translocation of Gi alpha to the nucleus. The near complete inhibition of cell division by genistein and CT without a corresponding effect on Gi alpha movement indicates that Gi alpha can be regulated independently of tyrosine kinase and adenylyl cyclase activities, respectively.