Synergistic induction of erythroid differentiation of mouse erythroleukemia (MEL) cells by inhibitors of topoisomerases and protein tyrosine kinases.

In vitro erythroid differentiation of mouse erythroleukemia (MEL) cells was induced by combinations of topoisomerase and protein kinase inhibitors. Neither inhibitor alone exhibited inducing activity. Although inhibitors of topoisomerases I and II were equally effective in the synergistic induction of erythroid differentiation, only inhibitors of tyrosine kinases, not of serine/threonine kinases, exhibited synergistic activity. The erythroid differentiation induced by the combination of topoisomerase and protein tyrosine kinase inhibitors was distinguished from that induced by typical erythroid inducing agents such as DMSO or HMBA by (1) earlier hemoglobin accumulation in the cells and (2) insensitivity to specific inhibitors (dexamethasone and sodium orthovanadate) of MEL cell differentiation.     

Cytoplasmic factors involved in erythroid differentiation in mouse erythroleukemia (MEL) cells

In order to identify and characterize intracellular factors involved in in vitro differentiation of mouse erythroleukemia (MEL) cells, the differentiation process was analyzed by cell and cytoplast fusion. The results suggested that the process is not a single cascade of molecular chain reactions, but a synergistic result of two different inducible intracellular reactions. One reaction is induced following damage to DNA (inhibition of DNA replication) and is not specific to MEL cells. The other reaction, which is specific to MEL cells, is fully induced by typical erythroid inducing agents such as dimethylsulfoxide or hexamethylenebisacetamide even at concentrations suboptimal for the erythroid induction. Based upon these data, we searched for the putative trans-acting differentiation-inducing factors and detected two proteinaceous factors (DIF-I and DIF-II) in the cytosol fraction which apparently correspond to these reactions. When, partially purified, either one of these factors was introduced into undifferentiated MEL cells, it triggered erythroid differentiation, provided that the recipient cells had been potentiated by the induction of the other reaction. In this article, we summarize the basic characteristics of these cytoplasmic factors involved in erythroid differentiation in MEL cells.     

Developmental program of murine erythroleukemia cells. Effect of the inhibition of protein synthesis

The relationship between protein synthesis and commitment to terminal erythroid differentiation by dimethylsulfoxide-treated murine erythroleukemia (MEL) cells has been studied. Treatment with cycloheximide blocks the commitment of MEL cells. The effects of cycloheximide are completely reversible, however. Treatment of MEL cells before commitment delays commitment for a period of time equal to the length of inhibitor treatment. Puromycin exerts a similar effect on the commitment of MEL cells. These results indicate that there is a continuous requirement for protein synthesis before the commitment event.     

Terminal differentiation of murine erythroleukemia cells: physical stabilization of end- stage cells

An important limitation in the use of the murine erythroleukenia (MEL) cell system as an in vitro system for the study of terminal erythroid differentiation has been the inability to produce significant numbers of cells which represent the end-point of the pathway in vitro. We show here that a major reason for the failure to observe end-stage cells in vitro is that such cells are physically unstable under the standard culture conditions used for MEL cell differentiation. Modification of these culture conditions by the addition of either bovine serum albumin or Ficoll leads to physical stabilization of end-stage cells. Under such culture conditions, uniform cultures of terminally differentiated MEL cells with morphological characteristics similar to those of normal mouse orthochromatophilic erythroblasts and reticulocytes are observed. Examination of physical and biochemical parameters of these cell populations give values which are similar to values characteristic of mouse reticulocytes. A physically stabilized MEL cell shows a narrow cell volume distribution with an average value of approximately 100 mum(3), similar to the cell volume distribution observed for mouse reticulocytes, while a typical MEL cell culture treated with DMSO but without a stabilizing agent exhibits a broader, more heterogeneous cell volume distribution with an average value of approximately 500 mum(3). Globin mRNA levels and levels of globin synthesis reach values almost equal to those in mouse reticulocytes in cultures of physically stabilized MEL cells while differentiating cultures not treated with a stabilizing agent reach substantially lower values for these parameters. We suggest that the ability to produce populations of MEL cells which undergo complete terminal erythroid differentiation in vitro will allow the analysis of the molecular mechanisms which control the terminal stages of the erythroid differentiation process.     

Murine erythroleukemia cells possess an active ubiquitin- and ATP-dependent proteolytic pathway

The ubiquitin (Ub)-dependent proteolytic pathway may function in selective elimination of cellular proteins during erythroid differentiation. Murine erythroleukemia (MEL) cells, which can be induced to differentiate to reticulocytes in culture, may provide a convenient system for studying the role of Ub-dependent proteolysis in erythroid differentiation. The following observations indicate that MEL cells possess an active Ub-dependent proteolytic pathway. (i) Addition of purified Ub to MEL cell fraction II (Ub-depleted lysate) stimulated ATP-dependent degradation of radioiodinated proteins. (ii) Covalent conjugation of carboxyl termini of Ub molecules to substrate protein amino groups is a necessary step in Ub-dependent degradation. Des-glygly-Ub (Ub lacking its carboxyl-terminal glygly moiety) did not stimulate protein degradation in MEL cell fraction II. (iii) The Ub-dependent component of protein degradation in MEL cell fraction II was specifically inhibited by amino acid derivatives that are inhibitors of Ub-protein ligase. (iv) MEL cell fraction II contained apparent homologs of all of the rabbit reticulocyte Ub carrier proteins (E2's) except E2(20K) and E2(230K). Ub-dependent proteolysis was seen only in MEL cell lysates prepared in the presence of leupeptin; an enzyme of the proteolytic pathway was inactivated if leupeptin was omitted.     

Activin A/erythroid differentiation factor induces thromboxane A2 synthetic activity in murine erythroleukemia cells

Activin A, a protein homologous to transforming growth factor beta, was shown to induce hemoglobin synthesis in murine erythroleukemia (MEL) cells and was also termed erythroid differentiation factor (EDF) (Eto, Y., Tsuji, T., Takezawa, M., Takano, S., Yokogawa, Y., and Shibai, H. (1987) Biochem. Biophys. Res. Commun. 142, 1095-1103). We found that activin A/EDF also induced thromboxane (TX) A2 synthetic activity in these cells. Synthesis of TXA2 from arachidonic acid is catalyzed by cyclooxygenase and TX synthase. Activin A/EDF induced the latter TX synthase activity, whereas the cyclooxygenase activity was constitutively expressed. The induction of this enzyme activity was inhibited by cycloheximide, suggesting that activin A/EDF induced de novo protein synthesis of TX synthase. Furthermore, we studied the relationship between the induction of TXA2 synthetic activity and erythroid differentiation in MEL cells, since the former is not an erythroid phenotype. We found 1) that the two responses to activin A/EDF were distinctly affected by the initial cell density; 2) that the dose-response curves for activin A/EDF were similar (ED50 = approximately 100 pM), whereas the time course of induction of TXA2 synthetic activity was much faster; and 3) that other erythroid differentiation inducers of MEL cells, namely dimethyl sulfoxide and hexamethylene bisacetamide, had little or no effect on TXA2 synthesis. These results indicate that activin A/EDF induces TXA2 synthetic activity independently of erythroid differentiation.     

Interaction of two cytoplasmic erythroid differentiation-inducing factors in mouse erythroleukemia cells.

Our previous cell fusion experiments have suggested that the in vitro erythroid differentiation of mouse erythroleukemia cells is the result of a synergistic reaction involving two intracellular differentiation-inducing factors (DIF); these were subsequently demonstrated in the cytoplasmic fraction of mouse erythroleukemia cells. Here, we present experimental evidence indicating that, under conditions in which the two factors (DIF-I and DIF-II) are coinduced, a new factor, which can trigger erythroid differentiation upon introduction into undifferentiated mouse erythroleukemia cells, is produced in the cells. A similar factor was also generated in vitro after the incubation of partially purified DIF-I and DIF-II. We found that protein phosphatases could substitute for DIF-II. These and other experiments suggest that protein dephosphorylation at a tyrosine residue(s) is involved in the generation of the new factor.     

Differential effect of hemin-controlled eIF-2 alpha kinases from mouse erythroleukemia cells on protein synthesis

Cultured mouse erythroleukemia (MEL) cells can be induced to erythroid differentiation by a variety of chemical agents. This differentiation process is marked by the onset of globin mRNA and hemoglobin synthesis. In rabbit reticulocytes, globin synthesis is regulated by a hemin-controlled translational inhibitor (HCI) which acts via phosphorylation of the alpha subunit of eukaryotic initiation factor 2 (eIF-2). From both uninduced and induced MEL cells, hemin-controlled eIF-2 alpha kinases have been partially purified. They resemble HCI with respect to their chromatographic behaviour and their sensitivity towards physiological concentrations of hemin (5-10 microM). Further purification on phosphocellulose, however, reveals that the eIF-2 alpha kinase from uninduced MEL cells is chromatographically distinct from HCI, whilst the eIF-2 alpha kinase activity from induced MEL cells represents a mixture of the former and the HCI-type eIF-2 alpha kinase. The latter inhibits protein synthesis in a fractionated system from rabbit reticulocytes which is free of, but sensitive to, HCI, whereas the eIF-2 alpha kinase from uninduced MEL cells does not show any inhibitory activity. This observation is supported by the finding that induced MEL cells respond in vivo to iron depletion with a shut-off of protein synthesis (as do rabbit reticulocytes), whilst uninduced MEL cells do not.     

Induction of murine erythroleukemia cell differentiation by proteinases is inhibited by aromatic poly-amidines

The effects of the tetra benzamidine serine-proteinase inhibitor 1,3-di-(p-amidinophenoxy) -2,2- bis- (p-amidinophenoxymethyl)propane (TAPP-H) and related compounds, including halo-derivatives, were determined on the erythroid differentiation of murine erythroleukemic cells induced by trypsin and kallikrein. These aromatic poly-amidines and their halo derivatives were found to be strong inhibitors of both trypsin and kallikrein mediated induction of commitment of MEL cells to erythroid differentiation, hemoglobin synthesis and accumulation, globin mRNA production. No inhibitory effects were detected by treating proteinase-induced MEL cells with benzamidine. Only slight inhibitory activity was found after treatment of trypsin-induced MEL cells with other antiproteinase compounds widely used in the control of proteinase-dependent functions, including leupeptin, antipain and Bowman-Birk proteinase inhibitor. MEL cells induced to erythroid differentiation by proteinases could be proposed as an experimental system to test the biological activity of proteinase inhibitors.     

Dissociation of hemoglobin accumulation and commitment during murine erythroleukemia cell differentiation by treatment with imidazole

The effect of imidazole on DMSO-induced murine erythroleukemia (MEL) cell differentiation has been examined. While imidazole does inhibit heme, globin mRNA, and hemoglobin accumulation in DMSO-induced MEL cells, it does not affect the commitment of MEL cells to the specific limitation of proliferative capacity associated with the in vitro differentiation program. Furthermore, imidazole treatment does not affect DMSO-induced changes in cell volume, in the relative proportion of nuclear protein IP25, and in the specific activity of the enzyme cytidine deaminase. A clonal analysis in the presence of imidazole indicated that the drug prevents heme accumulation even in MEL cells already committed to terminal differentiation. These observations suggest that imidazole effectively dissociates two aspects of the erythroid differentiation program of MEL cells: globin gene expression and commitment to loss of proliferative capacity.     

The fibronectin receptor on mammalian erythroid precursor cells: characterization and developmental regulation

The plasma membrane of murine erythro-leukemia (MEL) cells contains a 140-kD protein that binds specifically to fibronectin. A 125I-labeled 140-kD protein from surface-labeled uninduced MEL cells was specifically bound by an affinity matrix that contained the 115-kD cell binding fragment of fibronectin, and specifically eluted by a synthetic peptide that has cell attachment-promoting activity. The loss of this protein during erythroid differentiation was correlated with loss of cellular adhesion to fibronectin. Both MEL cells and reticulocytes attached to the same site on fibronectin as do fibroblasts since adhesion of erythroid cells to fibronectin was specifically blocked by a monoclonal antibody directed against the cell-binding fragment of fibronectin and by a synthetic peptide containing the Arg-Gly-Asp-Ser sequence found in the cell-binding fragment of fibronectin. Erythroid cells attached specifically to surfaces coated either with the 115-kD cell-binding fragment of fibronectin or with the synthetic peptide-albumin complex. Thus, the erythroid 140-kD protein exhibits several properties in common with those described for the fibronectin receptor of fibroblasts. We propose that loss or modification of this protein at the cell surface is responsible for the loss of cellular adhesion to fibronectin during erythroid differentiation.     

A hematopoietic-specific transmembrane protein, Art-1, is possibly regulated by AML1

The functions of AML1 in hematopoietic differentiation are repressed by AML1-mutants including the AML1/ETO chimeric protein, which is seen in t(8;21) acute myeloid leukemia. Erythroid progenitors of the patients with t(8;21) AML expressed AML1/ETO. To investigate the effect of AML1/ETO in erythroid cells, we made a tetracycline-regulated AML1/ETO overexpression system in mouse erythroleukemic (MEL) cells. Enforced AML1/ETO repressed the terminal erythroid differentiation. Furthermore, we performed representational difference analysis using this MEL cell system to clone the downstream targets of AML1 in erythroid cell differentiation. We cloned a novel transmembrane protein, Art-1 (AML1-regulated transmembrane protein 1), which is a member of tetramembrane spanning superfamily. Art-1 expression was restricted in hematopoietic cells. It was upregulated by AML1 and downregulated by AML1/ETO in both erythroid and myeloid cells, and increased during erythroid cell differentiation. Art-1 may play an important role in the differentiation of erythroid cells, possibly as a direct downstream target of AML1.     

Alteration of phosphotyrosine-containing proteins at the early stage of erythroid differentiation of mouse erythroleukemia (MEL) cells.

Following treatment of mouse erythroleukemia (MEL) cells with dimethyl sulfoxide and other typical erythroid inducing agents, the profile of cellular phosphotyrosine-containing proteins was drastically altered. We found that the level of almost all of the phosphotyrosine-containing proteins was either decreased or disappeared at a very early stage of differentiation. Addition of sodium orthovanadate (Na3VO4), a specific inhibitor of phosphotyrosine phosphatases, prevented the alteration as well as erythroid differentiation. Mutant MEL cells, which are resistant to differentiation by dimethyl sulfoxide, were apparently insensitive to the alteration. These results indicate that dephosphorylation of phosphotyrosine residues in cellular proteins is coupled with a reaction(s) which is responsible for triggering differentiation of MEL cells.