Metformin Induces Cell Cycle Arrest and Apoptosis in Drug-Resistant Leukemia Cells.

Recent epidemiological studies indicate that the antidiabetic drug metformin has chemosensitizing and chemopreventive effects against carcinogenesis. Here, we demonstrate that metformin exerts varying degrees of antitumor activity against human leukemia cells, as reflected by differences in growth inhibition, apoptosis, and alterations to metabolic enzymes. In metformin-sensitive cells, autophagy was not induced but rather it blocked proliferation by means of arresting cells in the S and G2/M phases which was associated with the downregulation of cyclin A, cyclin B1, and cdc2, but not that of cyclin E. In 10E1-CEM cells that overexpress Bcl-2 and are drug-resistant, the effect of metformin on proliferation was more pronounced, also inducing the activation of the caspases 3/7 and hence apoptosis. In all sensitive cells, metformin decreased the Δψ m and it modified the expression of enzymes involved in energy metabolism: PKCε (PKCepsilon) and PKCδ (PKCdelta). In sensitive cells, metformin altered PKCε and PKCδ expression leading to a predominance of PKCε over PKCδ which implies a more glycolytic state. The opposite occurs in the nonresponsive cells. In conclusion, we provide new insights into the activity of metformin as an antitumoral agent in leukemia cells that could be related to its capability to modulate energy metabolism.

Bexarotene activates the p53/p73 pathway in human cutaneous T-cell lymphoma.

BACKGROUND: Bexarotene is the first synthetic retinoid X receptor-selective retinoid (rexinoid) approved for the treatment of cutaneous T-cell lymphoma (CTCL). However, little is known about the signalling pathways by which it exerts its anticarcinogenic effect. OBJECTIVES: To characterize the effects of bexarotene in CTCL cell lines and elucidate the underlying molecular pathways of its antineoplastic effect. METHODS: The cell lines Hut-78, HH and MJ were used. Cell viability was assessed with the XTT assay. The self-renewal potential of cells after bexarotene treatment was studied with the methylcellulose clonogenic assay. Flow cytometry was used to analyse the effects on cell cycle, Ki-67 expression and apoptosis induction. Cell cycle and apoptosis-related protein expression were determined by Western blot and immunofluorescence. RESULTS: Bexarotene induced a loss of viability and more pronounced inhibition of clonogenic proliferation in HH and Hut-78 cells, whereas the MJ line exhibited resistance. Bexarotene upregulated and activated Bax in sensitive lines, although not enough to signal significant apoptosis. Instead, all data point to the inhibition of proliferation, rather than apoptosis, as the main mechanistic action of the rexinoid. Bexarotene signals both G(1) and G(2)/M arrest by the modulation of critical checkpoint proteins. We further found that bexarotene activates p53 by phosphorylation at Ser15, which influences the binding of p53 to promoters for cell cycle arrest, induces p73 upregulation, and, in concordance, also modulates some p53/p73 downstream target genes, such as p21, Bax, survivin and cdc2. Bexarotene-mediated ataxia telangiectasia mutated protein (ATM) activation in all studied lines suggests that ATM is likely to be the p53/p73 upstream activator. CONCLUSIONS: Our data indicate for the first time that bexarotene exerts its effect in CTCL mainly by triggering the p53/p73-dependent cell cycle inhibition pathway, probably by upstream ATM activation. Therefore, bexarotene-modulated genes represent potential biomarkers to assess the response to treatment of patients with CTCL.

Structural and functional preservation of specific sequences of DNA and mRNA in apoptotic bodies from ES cells.

Retinoic acid-induced apoptosis of embryonic stem (ES) cells is an experimental system which resembles the physiological programmed cell death that occurs during differentiation in embryonic development. Our aim was to analyze the involvement of epigenetic modifications such as DNA methylation and chromatin structure in the apoptotic process and to investigate the metabolic activity of apoptotic bodies. We found a relationship between DNA methylation and apoptosis, shown by a dose-dependent induction of apoptosis after treatment with the inhibitor of DNA methylation 5-aza-2'-deoxycytidine. Interestingly, we found a slight demethylation of specific sequences of the U2afl-rs1 imprinted gene in those RA treated cells which were specifically undergoing apoptosis. In addition, apoptotic bodies exhibited an unexpected open chromatin conformation accessible to the endonuclease DNase-I. Furthermore, we observed a structural and functional preservation of specific DNA sequences and mRNA. These results suggest that biological activities, such as transcription or protein synthesis, could be maintained even towards the end of the apoptotic process.

Effect of IL-2 and IL-6 on parameters related to metastatic activity in a murine melanoma.

Previous results have shown that the metastatic colonization with B16F10 melanoma in vivo increased after in vitro treatment of the cells with IL-2 or IL-6. To further investigate the mechanisms underlying this effect, we have studied adhesion, invasion, and proliferation properties of B16 melanoma, using two sublines with different metastatic ability. Adhesion of tumor cells to Matrigel coats increased using IL-6, which also induced upregulation of VLA-4 expression in both sublines. Unexpectedly, invasion through Matrigel filters was almost completely inhibited by IL-6 and decreased in the presence of IL-2. Cell growth was not affected by these interleukins; however, IL-6 could partially overcome the proliferation blockade induced by stress conditions. Taken together, these results suggest that upregulation of adhesion properties and/or the protective effect induced by IL-6 could account for the enhancement of metastasis exerted by this interleukin.

Interleukin-2 enhances the growth of human melanoma cells derived form primary but not from metastatic tumours.

Previously, we demonstrated that in vitro treatment of B16F10 murine melanoma cells with interleukin-2 (IL-2) enhances proliferation and metastasis. To further investigate the role played by IL-2 in human melanomas, we studied the expression of IL-2/IL-2 receptor and the effect of IL-2 on the proliferation of melanoma cell lines derived from primary (A375 and RMS cell lines) and metastatic (Hs294T cell line) tumours. We found a constitutive expression of cytoplasmic IL-2 and alpha, beta and gamma-subunits of the IL-2R on the surface of the three melanoma cell lines. The presence of IL-2 in the culture increased the proliferation rate in A375 and RMS cell lines, but no effect was observed in Hs294T metastatic cells. Biologically active IL-2 could be found in the supernatant of the three melanoma cell lines, particularly in A375 and RMS cells, in which an inhibition of the proliferation rate was observed when IL-2 was blocked. Moreover, the combination of anti-IL-2R beta and anti-IL-2R gamma blocking antibodies induced a significant down-regulation of cell proliferation in the three melanoma cell lines, and the combination of anti-IL-2R alpha, anti-IL-2R beta and anti-IL-2R gamma blocking antibodies inhibited IL-2-mediated growth stimulation in A375 and Hs294T cell lines. In RMS cells, a more significant effect was observed when only IL-2R gamma was blocked. Finally, exogenous IL-2 modulated the IL-2 endogenously produced by melanoma cells. These data show that IL-2 may modulate the growth of melanoma cells through autocrine or/and paracrine mechanisms.

Soluble interleukin-2 receptor, intercellular adhesion molecule-1 and interleukin-10 serum levels in patients with melanoma.

Serum soluble interleukin-2 receptor (sIL-2R), intercellular adhesion molecule-1 (sICAM-1) and interleukin-10 (IL-10) have each been reported as useful markers for melanoma progression. To evaluate the clinical relevance of these three markers, we simultaneously analysed their serum levels in patients with melanoma. A longitudinal study with a 3-year follow-up was performed and different stages of the disease were considered. Mean values of sIL-2R were significantly higher than in normal controls in all stages and correlated with the disease progression. The prognosis of patients with levels > 529 U/ml of sIL-2R was significantly poorer than in patients with sIL-2R levels < 529 U/ml. Levels of sICAM-1 were also elevated in melanoma patients, specially at the time of the metastatic disease. Serum IL-10 levels were more frequently detectable in the patients that developed metastasis during follow-up, and the prognosis of patients with detectable IL-10 levels was significantly poorer than in those patients with IL-10 undetected levels. Statistical analysis based on Logistic and Cox regression models showed that only sex, stage and sIL-2R value are factors significantly associated with metastatic progression. Moreover, high levels of sIL-2R could be a risk factor for malignant progression in melanoma.

The role of cleavage of cell structures during apoptosis.

In this work we have studied the behavior of some cell structures, such as actin, tubulin and chromatin during apoptosis induced in F9 cells after retinoic acid treatment. In this experimental model, all defined steps of morphological changes described for apoptosis are observed. The correlation between a partial maintenance of F-actin and microtubular structures and the spatial distribution of F-actin suggests a possible relationship between this molecule and the characteristic shape changes observed in apoptosis. Additionally, the disposition of monomeric G-actin suggests a possible relationship between the fragmentation of this molecule and the cleavage of DNA. The analysis of the U2af1-rs1 specific sequence shows that the internucleosomal fragmentation observed in this gene is randomly produced during apoptosis and is not dependent of demethylation status. The results obtained confirm that specific cleavage of these cell structures is inherent to the development of the apoptotic process and do not exclude the possibility that proteolysis of key actin and/or tubulin molecules or the cleavage of specific chromatin sequences other than the ones analyzed here, could control the different phases of the apoptotic process.

Cyclosporin A upmodulates the alpha-subunit of the interleukin-2 receptor and the metastatic ability of murine B16F10 melanoma cells.

In the present study, the effect of in vitro cyclosporin A (CsA) treatment on IL-2R expression and the metastatic behavior of B16F10 melanoma cells has been reported. CsA treatment was found to increase the percentage of B16F10 cells expressing the alpha-subunit of IL-2R on the cell surface and also at the mRNA level. Moreover, CsA treated B16F10 cells also express the beta-subunit of IL-2. In vivo experiments showed that CsA increases the affinity of B16F10 metastazing cells for the liver and decreases that for the lung. CsA modulated the expression of MHC class I and class II antigens, but no significant differences in the resistance of CsA-treated B16F10 cells to NK lysis were observed. Finally, proliferation of B16F10 cells in the presence of several doses of CsA did not vary and CsA increased the amount of IL-1beta mRNA expression. These results suggest that CsA, through the modulation of cytokines and MHC antigen expression on B16F10 cells, could have an effect upon the metastatic progression of the B16F10 melanoma.

Serum-soluble IL-2 receptor and IL-6 levels in patients with melanoma.

Elevated soluble IL-2 receptor (sIL-2R) and IL-6 serum concentrations have been reported as adverse prognostic factors in several types of cancer. In order to determine whether these factors are predictive of metastatic progression in melanoma, sIL-2R and IL-6 levels were measured in sera from 172 patients with melanoma and 60 in healthy controls. Mean sIL-2R values were significantly higher in the patients than in normal controls and the highest values were observed in those that developed metastasis during follow-up. However, no correlation was found with the stage of the disease. Serum IL-6 levels were found to be correlated with age and sex, but not correlated with sIL-2R levels. Statistical analysis was based on logistic and Cox regression models. The factors considered were age, sex, stage, disease-free interval and serum sIL-2R and IL-6 levels. The analysis showed that only the sIL-2R value is significantly linked to metastatic progression. This finding suggests that high serum levels of sIL-2R could be a predictive factor of metastatic progression in malignant melanoma.

Parental chromosome-specific chromatin conformation in the imprinted U2af1-rs1 gene in the mouse.

The imprinted U2af1-rs1 gene on mouse chromosome 11 is expressed exclusively from the paternal allele. We found that U2af1-rs1 resides in a chromosomal domain that displays marked differences in chromatin conformation and DNA methylation between the parental chromosomes. Chromatin conformation was assayed in brain and liver, in fetuses, and in embryonic stem cells by sensitivity to nucleases in nuclei. In all these tissues, the unmethylated paternal chromosome is sensitive to DNase-I and MspI and has two DNase-I hypersensitive sites in the 5'-untranslated region. In brain and in differentiated stem cells, which display high levels of U2af1-rs1 expression, a paternal DNase-I hypersensitive site is also readily apparent in the promoter region. On the maternal chromosome, in contrast, the entire U2af1-rs1 gene and its promoter are highly resistant to DNase-I and MspI in all tissues analyzed and are fully methylated. No differential MNase sensitivity was detected in this imprinted domain. The parental chromosome-specific DNA methylation and chromatin conformation were also present in parthenogenetic and androgenetic cells and in tissues from animals maternally or paternally disomic for chromosome 11. This demonstrates that these parental chromosome-specific epigenotypes are independently established and maintained and provides no evidence for interallelic trans-sensing and counting mechanisms in U2af1-rs1.

IL-2 treatment of B16F10 melanoma cells stimulates metastatic colonization in the liver.

We had previously shown that murine B16F10 melanoma cells express the receptor for IL-2, transcribe the gene for IL-2 and respond to its factor by increasing their proliferation. In the present work we have investigated the effect of in vitro IL-2 treatment on the metastatic ability of B16F10 cells. In vivo experiments showed that the metastatic colonization of the liver was notably higher after intrasplenic inoculation of IL-2-treated cells. However, no change was observed when cells were intravenously inoculated. In vitro, cells became more resistant to NK lysis although the cytometric analysis of class 1 MHC molecules revealed a decrease in H-2Kb expression. In contrast IL-2 induced a two fold increment in the expression of la antigen. On the other hand slot-blot analysis showed that IL-2 gene expression could be upregulated, however no free IL-2 was released into the culture medium of B16F10 cells. We conclude that IL-2 increases the ability of B16F10 cells to metastase to the liver. The increase in the resistance to NK activity and in la antigen expression could be involved in the mechanisms underlying this effect.

B16F10 murine melanoma cells express interleukin-2 and a functional interleukin-2 receptor.

In this study, we analyzed interleukin-2 (IL-2) and IL-2 receptor (IL-2R) expression in murine B16F10 melanoma and studied the effect of recombinant IL-2 (rIL-2) on the proliferation of these cells. Flow cytometry analysis revealed the presence of the IL-2R alpha subunit in B16F10 melanoma, with a mean positivity rate of 30%. Using confocal microscopy, the expression of this chain could be visualized on the surface of B16F10 cells and in intracellular compartments when the cells were permeabilized with ethanol. In addition to the alpha subunit, the IL-2R beta subunit was also expressed in B16F10 cells as shown by reverse transcription and polymerase chain reaction analysis. The functionality of the IL-2R on B16F10 cells was shown by the fact that cell proliferation increased dose-dependently with the addition of rIL-2 to the culture medium. We also detected expression of the IL-2 gene in B16F10 cells. In Northern blot assays, a typical band of 0.9 kb corresponding to IL-2 mRNA was observed, although supernatants from B16F10 cultures had no detectable IL-2 activity. Furthermore, the addition of neutralizing antibody (anti-IL-2) to cell cultures had no effect on cell proliferation. From these results, we concluded that an IL-2 signalling system is present in murine B16F10 melanoma cells and that IL-2 favors B16F10 cell proliferation, suggesting a role for this cytokine in the tumoral activity of these cells.

Enhancement of Ia antigen expression and nonproliferating cells correlates with metastatic capacity.

Maintaining B16F10 tumor cells in stirring culture for 48 h leads to an increase in lung and liver colonizing capacity in comparison with cells in adherent culture. Parallel to the increased metastatic capacity, we have observed a decrease in the proliferative rate of tumor cells (as the percentage of proliferating cell nuclear antigen-positive cells) and an increase in the population of tumor cells expressing Ia antigen. These results are not exclusive to B16F10 cells, since the same results were obtained when we analyzed 3LL cells maintained in identical culture conditions. In all the tumor lines tested, we found an association between the nonproliferating and the Ia-positive cell populations. We induced Ia expression by treating B16F10 cells in adherent culture with the lectin concanavalin A and again, coincident with an increase in metastatic capacity, we found the same association between the two parameters analyzed--nonproliferating state and Ia antigen expression. In addition, it was found that B16F10 cells induce lymphocytic proliferation, and a direct relationship was established between the number of Ia+ cells and lymphocytic proliferation.

Oncogene and MDR1 gene expression in rat rhabdomyosarcoma sublines of different metastatic potential.

The expression of various protooncogenes (myc, Ki-ras, Ha-ras, erbB, fms, sis, jun and fos) and a gene implicated in multidrug resistance (mdr1) was investigated in cell sublines, isolated from a rat rhabdomyosarcoma cell line, and in the corresponding tumors induced by injection of these cells into syngeneic rats. These cell lines and tumors, selected or not by treatment with chlorozotocin (Czt) or adriamycin (Adr), differed in their tumorigenicities and metastatic potentials. Our results showed that 1) an increased expression of some protooncogenes could be correlated with the metastatic potential of tumors; 2) such a correlation was not observed in the cultured cells from which these tumors were derived; 3) mdr1 expression, similarly to that of protooncogenes, was correlated with metastatic potential in all tumors except the Adr-selected tumors.

Estimating anatomical-functional position coordinates in liver tissue.

Hepatocyte enzyme activity was demonstrated by examining adult C57BL/6 mouse liver cryostat sections under a succinate dehydrogenase (SDH) histochemical reaction, and quantified by microspectrophotometry and microdensitometry. The hepatocyte SDH activity gradient along the path between the portal veins (PV) and efferent terminal hepatic venules (THV) was analyzed by measuring the concentration of the chromophore precipitated in 10 consecutive hepatic parenchymal domains located along imaginary lines drawn across the entire PV-to-THV distance. The profiles of intensity or of normalized relative optical density obtained on a high number of lines were correlated with distance values along the PV-to-THV pathway, enabling us to establish a general mathematical function relating SDH activity (chromophore concentration) to position values on a scale of 0 to 10 corresponding to the theoretical PV-to-THV distance. The equation can be used to interpolate the SDH activity surrounding any intrahepatic object located between the PV and the THV, thus making it possible to calculate the object's anatomical-functional position coordinates in the liver acinus. To demonstrate how this method is used, we have calibrated the intrahepatic position of hemopoietic foci induced in the liver tissue of adult mice treated with phenylhydrazine (PHZ), and show that these foci are located on coordinate 3.31 (maximum range 1.25-4.86) of the sinusoidal domain-that is, on the borderline between Rappaport's acinar zones 1 and 2.

Coincident implantation, growth and interaction sites within the liver of cancer and reactive hematopoietic cells.

We have examined the anatomical-functional sites within mouse liver where phenylhydrazine (PHZ)-induced hematopoietic foci, and M5076 reticulum cell sarcoma, B16F10 melanoma and Lewis lung-carcinoma cells specifically develop as colonies after intrasplenic injection. Cancer foci occurred predominantly in the 2.4 to 4.0 segment of the sinusoidal pathway, corresponding to hepatic acinar zone I. No significant differences were detected between different types of tumor, including their different tendencies to spontaneously metastasize liver, or as a result of the different procedures used for obtaining foci or metastases. In addition, PHZ-treatment of mice previously injected with tumor cells, resulted in double colonization of the liver tissue by both hematopoietic and cancer cells, predominantly in zone I. This spatial coincidence indicates that non-cancer-specific mechanisms operate in zone I, either promoting implantation and/or growth of cell colonies or, alternatively, inhibiting these processes in the region surrounding the central vein (Rappaport zone 3). Our observations failed to reveal mutual displacement of cancer or hematopoietic foci by potential competition for development sites in zone I. Enumeration and diameter measurements of cancer foci in PHZ-treated animals showed that the presence of hepatic hematopoietic foci coincided with a significant increase in the hepatic metastasis volume. However, the fact that no significant differences in pulmonary metastases occurred in both the PHZ-treated and control mice given tail-vein injection of cancer cells, and that PHZ reduces cancer cell proliferation in vitro, reveal evidence of local interactions with hematopoietic foci which promote growth of cancer foci in liver.