Amiloride in differentiation and commitment of Friend erythroleukemia cells

Dimethylsulfoxide (DMSO) converts almost all of the undifferentiated murine erythroleukemia cells (MEL or Friend cells, clone 745A) in a culture to differentiated cells that contain high levels of hemoglobin and that stop growing after a limited number of cell divisions. Contrary to other reports--that amiloride strongly inhibits DMSO-induced differentiation in MEL cells--in this laboratory, inhibition by amiloride, tested with DMSO over a range of concentrations in two kinds of media and at various cell densities, was found to be only weak or absent. Similarly, amiloride did not inhibit induction by N,N'-hexamethylene bis-acetamide (HMBA). As expected from previous findings with other cell systems, amiloride inhibited protein synthesis and cell multiplication.     

Transferrin receptors and iron utilization in DMSO-inducible and -uninducible friend erythroleukemia cells

Dimethylsulfoxide (DMSO) induces hemoglobin synthesis and erythroid differentiation of Friend erythroleukemia cells in vitro. Induction is accompanied by increased transferrin-binding activity which is necessary for the cellular acquisition of iron from transferrin for hemoglobin synthesis. There are Friend cell variants in which hemoglobin synthesis is not induced by DMSO unless exogenous hemin is also present. In this study we have compared the inducibility of transferrin receptors and iron incorporation in DMSO-inducible (745) and -uninducible (M-18 and TG-13) Friend cell lines. Cellular transferrin-binding sites were estimated by Scatchard analysis of data obtained from specific binding of [125I]transferrin by the cells. Our results show that unlike 745, DMSO treatment of the variant cell lines M-18 and TG-13 does not result in increased transferrin-binding activity. The number of transferrin-binding sites and the rate of iron uptake is similar in uninduced 745 and DMSO-treated M-18 and TG-13 cells. Although exposure of M-18 cells to DMSO and hemin induces hemoglobinization, this treatment does not cause induction of transferrin receptors. These results indicate that the primary defect in M-18 cells may be the uninducibility of transferrin receptors. We have also shown that exposure of 745 cells to hemin during DMSO treatment prevents the induction of transferrin receptors, suggesting that hemin may control the expression of transferrin receptors in erythroid cells.     

Manipulation of myogenesis in vitro: Reversible inhibition by DMSO

A system has been developed for the detailed analysis of the transition from proliferative myoblast to differentiated muscle cell. Dimethylsulfoxide (DMSO) prevents the terminal differentiation of L8 myoblasts in vitro, and its effect is reversible. DMSO (2%) inhibits the fusion of myoblasts to form multinucleate myotubes, the normal increases in activity of creatine phosphokinase (CPK) and acetylcholinesterase, and the synthesis of α-actin and acetylcholine receptor protein. Upon removal of DMSO from the medium, a lag precedes the onset of differentiation. The potential to inhibit muscle differentiation reversibly is not specific to DMSO, but is shared by a number of compounds, including dimethylformamide, hexamethylbisacetamide and butyric acid, all potent inducers of gene expression in Friend erythroleukemia cells. L8 cells routinely cease DNA synthesis and initiate fusion and muscle protein synthesis once they are confluent. In the presence of DMSO, however, nearly all cells continue DNA synthesis, even several days after reaching confluence. Protein synthetic patterns of DMSO-inhibited cells are almost indistinguishable from those of untreated myoblasts and distinct from differentiated myotubes. It appears that cells exposed to DMSO are locked indefinitely in a proliferative myoblast stage of development and are unable to enter the G₀ phase of the cell cycle necessary for initiation of differentiation. DMSO coordinately inhibits all the differentiative parameters measured. In contrast, cytochalasin B uncouples normally linked differentiative events so that fusion is inhibited while muscle-specific protein synthesis proceeds. DMSO has similar effects on both cytochalasin B-treated and fusing control cultures, suggesting that its primary effect is exerted not at the level of fusion but earlier in the differentiative timetable. Once fusion and the synthesis of muscle-specific proteins are well under way, the addition of DMSO is ineffective and differentiation continues in its presence. The potential to manipulate muscle gene expression in vitro makes this system particularly useful for the detailed analysis of the processes involved in the transition to the differentiated state and for determining the linkage of developmental events.     

Hemoglobin synthesis in cell hybrids formed between teratocarcinoma and friend erythroleukemia cells

Viable hybrid cells have been isolated following fusion of Friend erythroleukemia cells and undifferentiated teratocarcinoma cells. The hybrids formed between near-diploid parental cells resembled Friend cells in their ability to grow in suspension and to synthesize hemoglobin in the presence of the chemical inducers dimethyl sulfoxide (DMSO) and ouabain. Erythropoietin (EPO) was effective in inducing hemoglobin synthesis in some of the hybrid cell lines. The hemoglobins synthesized by the hybrids were of the adult forms, but were quantitatively different from those hemoglobins synthesized by the parental Friend cells, suggesting that the fusion event modulated the expression of the hemoglobin chain genes.     

Hydrocortisone inhibits DMSO - induced differentiation of Friend erythroleukemia cells.

Hydrocortisone (10^?6 – 10^?7M) completely inhibited the production of hemoglobin by DMSO- and DMF-treated Friend erythroleukemia cells (FLC) in vitro without affecting either cell replication or general protein synthesis. Only 11, 17-dihydroxycorticosteroids were effective in inhibiting this expression of differentiation. Addition of hydrocortisone as late as 48 hours after the addition of DMSO (at a time at which cells were committed to differentiation) still resulted in significant inhibition of hemoglobin synthesis. Although the mechanism of this action is unknown, since it was not reversed by the addition of arachidonic acid nor a number of prostaglandins, it appears to be unrelated to the ability of corticosteroids to inhibit endogenous prostaglandin synthesis.     

Alterations in electrophoretic mobility, diaphorase activity, and terminal differentiation induced in murine erythroleukemia lines by differentiating agents

The electrophoretic mobilities (EPMs) and semiquinone reductase activities of two clones of Friend murine erythroleukemia (MEL) cells were investigated as a function of treatment with the inducing agents dimethylsulfoxide (DMSO) and hexamethylene bisacetamide (HMBA). As reported previously by others, the inducible clone DS19 lost its ability to grow in soft agar and expressed hemoglobin as judged by benzidine/H2O2 staining after 96 hours of treatment with 1% DMSO or 4 mM HMBA. In addition, its EPM fell by 14%, its semiquinone reductase activity by 40%, and its mean diameter by 10%. The second clone, R1, retained its ability to grow in soft agar and lacked hemoglobin expression after treatment with HMBA and DMSO, characterizing it as noninducible. However, R1 did demonstrate alterations in EPM, semiquinone reductase activity, and cell diameter that closely paralleled those found in DS19. Such responses were not seen in three non-MEL cell lines exposed to HMBA or DMSO, suggesting that clone R1 responded to these inducing agents in a cell-line specific manner but that its ability to complete the sequences necessary for differentiation may be blocked at an unknown point distal to the block characteristic of untreated cells. The data show that while a reduction in EPM, semiquinone reductase activity, and cell diameter accompany induced differentiation in MEL cells, such changes can occur in the absence of a commitment to terminal differentiation.     

Bcl-XL induction during terminal differentiation of friend erythroleukaemia cells correlates with delay of apoptosis and loss of proliferative capacity but not with haemoglobinization

Friend murine erythroleukaemia (F-MEL) cells are a useful model for studying the processes that regulate erythroid differentiation since exposure of these cells to chemical inducers (DMSO or HMBA) results in commitment to terminal cell division and synthesis of haemoglobin. This study examined the relationship between differentiation and apoptosis in DMSO sensitive and resistant F-MEL cells. Clear apoptosis was not observed in DMSO-treated sensitive F-MEL (strain 745A) cells during the induction of differentiation. In contrast, DMSO-induced 745A cells exhibited delayed apoptosis compared to uninduced cells. Since the Bcl-2 family members play a major role in the control of apoptosis and/or differentiation, we determined their expression before and after DMSO or HMBA treatment. Neither untreated nor chemically-induced 745A cells expressed the Bcl-2 protein. The levels of Bax and Bad proteins remained relatively constant during DMSO-induced differentiation. DMSO or HMBA treatment of 745A cells induced a marked increase of Bcl-XL expression during the late phase of differentiation which persisted even when the cells began to die. This upregulation of Bcl-XL was independent of cell density but was correlated with cell arrest in G0/G1. DMSO treatment induced a similar delay of apoptosis and enhancement of Bcl-XL expression in F-MEL (strain TFP10) cells which fail to synthesize haemoglobin in the presence of DMSO. Dexamethasone, which blocks DMSO-induced differentiation of F-MEL cells, prevented the induction of Bcl-XL. Inhibitors such as imidazole or succinylacetone, which inhibit haemoglobin synthesis but not commitment to terminal cell division, did not suppress Bcl-XL induction in DMSO-induced cells. Taken together, these results indicate that DMSO treatment of F-MEL cells induces a marked increase in Bcl-XL expression suggesting a role for this anti-apoptotic protein in the process of erythroid differentiation in F-MEL cells. Moreover, induction of Bcl-XL during this process seems to be associated with loss of proliferative capacity rather than with haemoglobin synthesis.     

Isolation and properties of DMSO resistant variant clones of Friend leukemia cells.

DMSO resistant clones have been isolated from the inducible Friend leukemia cell line 5-86 both from unmutagenized cultures and following EMS mutagenesis. All the clones can grow in the presence of 1.8% DMSO and are non-inducible or poorly inducible for hemoglobin synthesis by DMSO as well as by other known inducers of Friend leukemia (FL) cells differentiation like hemin, hypoxanthine, hexamethylene bisacetamide. The clones are also defective for the expression of other properties of differentiating Friend cells like agglutinability by plant lectins and expression of the surface protein glycophorin. Some of the clones show an impaired ability to form tumors in vivo. These resistant clones might be useful for a genetic analysis of the differentiation process of Friend leukemia cells.     

Erythrocyte membrane antigen expression during friend cell differentiation: Analysis of two non-inducible variants

Erythrocyte membrane antigens have been detected on induced Friend erythroleukemic cells with a rabbit antiserum raised against mouse erythrocyte membranes. The antibody specificities of this antiserum have been quantitatively analyzed using a cellular radioimmunoassay. After absorption with thymocytes, the rabbit anti-erythrocyte membrane serum bound to dimethylsulfoxide (DMSO)-induced Friend erythroleukemic cells and to mouse erythrocytes but not to uninduced Friend cells or thymocytes. Reciprocal inhibition studies demonstrated that, following complete thymocyte absorption, the antiserum detected similar antigenic specificities, termed erythrocyte membrane antigens (EMA), on both mature erythrocytes and induced Friend cells. The expression of these erythrocyte membrane antigens was also induced on Friend cells by other agents, such as ouabain and dimethylacetamide (DMA). In contrast, exogenous hematin, which did not induce hemoglobin synthesis in the Friend cell clones used in this study, also did not induce erythrocyte membrane antigen expression. Two independently derived variant clones which do not produce hemoglobin in reponse to DMSO were analyzed for their ability to produce erythrocyte membrane antigens in response to various inducers of Friend cell differentiation. Clone TG-13 is not inducible by DMSO or hematin but is weakly induced by DMA for both hemoglobin production and erythrocyte membrane antigen expression. Another variant clone, M18, was also analyzed. This clone does not synthesize detectable hemoglobin when grown in either DMSO or hematin alone, but undergoes extensive hemoglobin synthesis when grown in medium containing both DMSO and hematin. M18 does, however, express erythrocyte membrane antigens when grown in DMSO alone: the presence of hematin and DMSO together in the growth medium does not enhance expression of these antigens. Thus M18 appears to be defective for hemoglobin inducibility, and this defect can be overcome by exogenous hematin; however, the expression of erythrocyte membrane antigens is not affected by this block in hemoglobin synthesis. The results with the variant clones are discussed in terms of a program for Friend cell differentiation in which the induction of hemoglobin synthesis and erythrocyte membrane antigen expression are under both co-ordinate and separate controls.     

Hybrid polar compounds produce a positive shift in the surface dipole potential of self-assembled phospholipid monolayers

Hybrid polar compounds (HPCs) are powerful inducers of terminal differentiation of various types of tumors, including Friend murine erythroleukemia cells (MELCs). They are known to act synergistically with an increase in the extracellular concentration of cations, which causes a positive shift in the negative value of the ionic surface potential. Two HPCs, hexamethylenebisacetamide (HMBA) and suberoylanilide hydroxamic acid (SAHA), were adsorbed on self-assembled phospholipid monolayers supported on a mercury drop and the shift in the surface dipole potential chi of the lipid film due to their adsorption was estimated from charge measurements. At their optimal concentrations for inducing MELC terminal differentiation (5 mM for HMBA and 2.6 microM for SAHA), these HPCs cause a chi shift of about 15-20 mV, positive toward the hydrocarbon tails, both on neutral phosphatidylcholine films and on negatively or positively charged phosphatidylserine films. This strongly suggests that the nonspecific effect of HPCs of different structure in inducing cancer cells to rescue their differentiation program is related to a positive chi shift on the extracellular side of the cell membrane.     

Activation of teratocarcinoma-derived hemoglobin genes in teratocarcinoma-Friend cell hybrids.

Hybrid cells formed by the fusion of murine teratocarcinoma and Friend erythroleukemia cells synthesize hemoglobin in the presence of chemical inducers such as dimethylsulfoxide (DMSO). By making use of the fact that the parental teratocarcinoma and Friend cells carried different alleles at the locus coding for the alpha chain of hemoglobin, it was possible to demonstrate that the teratocarcinoma-derived genes for the globin alpha chains are genetically active in hemoglobin-synthesizing hybrid cells. In addition, evidence is presented suggesting that the teratocarcinoma-derived genes for the beta-globin chains may also be expressed in the hybrids. Apparently the teratocarcinoma-derived genome has become reprogrammed to express erythroid functions following fusion of the teratocarcinoma cell to the Friend cell.     

Friend erythroleukemia cell differentiation: induction by retinoids

Abstract. Growth in the presence of retinoids was found to induce erythroid differentiation in Friend murine erythroleukemia (MEL) cells in culture. The program of differentiated functions expressed by retinoid-treated cells was quite similar to that promoted by other inducers of MEL cell differentiation. For example, 70% or more of induced cells synthesized hemoglobin which accumulated to a level of 8 μg–10 μg per 10⁶ cells. The level of acetylcholinesterase activity increased two to five-fold in induced cells, and induction by retinoids, like induction by dimethylsulfoxide (DMSO), promoted the appearance of cell surface lumps or 'blebs'. All-trans retinaldehyde, which promoted maximum hemoglobin and acetylcholinesterase synthesis at a concentration of 5 × 10⁻⁷ M, was found to be a more potent inducer than all-trans retinoic acid or retinol, which both showed maximum induction at 1 × 10⁻⁵ M. Like differentiation promoted by DMSO, retinoid-induced differentiation was inhibited by 10⁻⁷ M dexamethasone.     

Modification of lipophilic proteins in Friend erythroleukemia cells during their differenciation

In mouse erythroleukemia cells (MELC) a lipophilic protein of apparent M. W. 9.5 kdaltons increases during differentiation. This increase is due either to an increase of biosynthesis or to a structural alteration impairing the capacity of the protein to form polymers of apparent high M.W. or favoring its extractability. The increase is related to differentiation and precedes hemoglobin synthesis by at least 1 day. It is not related cells (TFA-11) in which dimethylsulfoxide (DMSO) causes an increase in virus production. As it occurs in cells treated with 4 different inducers, and as the increase is less marked when antagonists of the inducers are also present, it is unlikely that the increase of the 9.5 Kdalton protein is due to an effect of the inducers unrelated to differentiation.     

Inhibition of dimethyl sulfoxide-induced Friend erythroleukemia cell differentiation in vitro by lithium chloride

This report describes the ability of ultra-pure lithium chloride (LiCl) to influence the growth kinetics and differentiation of Friend erythroleukemia cells in vitro. LiCl (0.2-50 mEq/l) was effective in reducing the ability of Friend cells to grow in liquid suspension culture (p less than or equal to 0.001). In addition, the capacity of these erythroleukemic cells to respond to the inducing agent dimethyl sulfoxide (DMSO) was also significantly reduced (p less than or equal to 0.001). These results demonstrate that LiCl can influence not only the proliferation of erythroleukemia cells but also their subsequent differentiation after exposure to such chemical inducers.     

Temporal changes in phosphoamino acid phosphatase activities in murine erythroleukaemic cells

1. The activities of phosphotyrosine, phosphothreonine and phosphoserine phosphatases were measured at various time periods in Friend murine erythroleukaemic (MEL) cells. 2. Effects of DMSO (dimethyl sulphoxide) and HMBA (hexamethylene bisacetamide), inducers of differentiation, were examined. 3. The activities of all three enzymes showed cyclic variation when measured on a daily basis over a period of several days; this was also the case when phosphothreonine phosphatase was determined in cells treated with DMSO or HMBA and when phosphoserine phosphatase was assayed after stimulation of the cells with HMBA. 4. Evidence for rhythmic variation in phosphotyrosine phosphatase activities was also obtained when the activities were determined at hourly intervals both in control cells and those treated with HMBA. 5. The time-dependent changes observed could be significant in that control of dephosphorylation may possibly be achieved by altering the rhythms.     

Correlation between hypomethylation of DNA and expression of globin genes in Friend erythroleukemia cells.

This report identifies L-ethionine as an inducer of differentiation in murine erythroleukemia cells. When Friend erythroleukemia cells are grown in the presence of 4mM L-ethionine, globin mRNA accumulates and in 4-5 days, 25-30% of the cells in the culture contain hemoglobin. Incubation of the cells with bromodeoxyuridine prevents both ethionine-induced accumulation of globin mRNA and erythroide differentiation. At the concentration where L-ethionine acts as an inducer of FL cell differentiation it inhibits methylation of DNA and tRNA in vivo but does not prevent macromolecular synthesis or cell division. To establish whether a link existed between inhibition of a specific methyltransferase and activation of globin synthesis in FL cells, we examined the degree of hypomethylation of DNA and tRNA from FL cells induced to differentiate with dimethylsulfoxide and butyrate. In contrast to the tRNA from ethionine-treated cells, tRNA from cells induced by butyrate or Me2SO cannot be methylated in vitro using homologous enzymes. DNA isolated from cells exposed to any of the three inducers, however, was significantly hypomethylated when compared with DNA from uninduced cells. These data suggest that methylation of DNA may play a role in the regulation of gene expression.     

Increased carbonic anhydrase activity in Friend erythroleukemia cells during DMSO-stimulated erythroid differentiation and its inhibition by BrdU.

Carbonic anhydrase activity is increased in Friend erythroleukemia (FL) cells during the enhancement of erythroid differentiation in the presence of dimethylsulfoxide (DMSO) or butyric acid. Untreated FL cells show an increase in enzyme activity associated with logarithmic growth. The increase in the specific activity of carbonic anhydrase in the differentiating treated cells, however, appears to be due to at least two additional general mechanisms: (1) an induction of carbonic anhydrase paralleling the stimulation of hemoglobin synthesis and (2) the stability and/or retention of active carbonic anhydrase as compared to most of the other cell proteins. The stimulation of carbonic anhydrase activity in the treated cells is inhibited by 5-bromo-2'-deoxyuridine (BrdU). This is the first demonstration of BrdU inhibition of a DMSO induced product not directly related to hemoglobin.