Transient inhibition of initiation of S-phase associated with dimethyl sulfoxide induction of murine erythroleukemia cells to erythroid differentiation.

The murine erythroleukemia cell (MELC) line in suspension culture can be induced to differentiate to erythroid cells by various compounds, including dimethyl sulfoxide (Me2SO). Analysis of the cell cycle, during differentiation induced by Me2SO, using thymidine incorporation, thymidine labeling index, and relative DNA content per cell as measured by flow microfluorometry, demonstrates a transient inhibition of entry of cells into S-phase of the cell cycle which is detected as early as 5 hr and is maximal about 20 hr after beginning of nonsynchronous cultures. Furthermore, in the presence of Me2SO there is restricted binding of the intercalating dye propidium iodide to chromatin from MELC in G1 phase of the cell cycle, as early as 10 hr of culture. This restricted binding of propidium iodide to chromatin is observed in MELC cultured with other inducing agents, such as butyric acid and dimethyl-acetamide, but is not detected with an Me2SO-resistant cell line cultured with Me2SO.     

Induction of a Ca2+, Mg2+-dependent endonuclease activity during the early stages of murine erythroleukemic cell differentiation.

A Ca2+, Mg2+-dependent endonuclease activity was detected in erythroleukemic cells undergoing differentiation in vitro in response to induction by dimethyl sulfoxide (Me2SO) or hexamethylene-bis-acetamide (HMBA). The endonuclease activity was demonstrated in isolated nuclei within 6 hr after the addition of inducer, reached maximum levels between 24 and 48 hr, and returned to control levels within 72 hr. The activity caused single strand breaks in high molecular weight native DNA, which could be labeled at exposed 3'-OH termini with Escherichia coli DNA polymerase I and radiolabeled nucleotides. Alkaline elution studies revealed DNA fragmentation that appeared coincident with the presence of the endonuclease activity. The detection and levels of single strand DNA breakage correlated with induction of terminal differentiation by Me2SO or HMBA. Induction of the endonuclease activity was reversible: depletion of Me2SO from the growth medium after treatment for 6 and 18 hr led to a rapid decrease in the level of activity. Removal of the inducer prevented terminal differentiation, a finding that strongly suggests the endonuclease activity is present during the precommitment phase of differentiation. DNA fragmentation was not observed in cells incubated with hemin, which has been shown previously to increase the cytoplasmic level of globin mRNA without causing commitment to terminal maturation. Me2SO did not induce the endonuclease activity or DNA fragmentation in an uninducible Friend cell line.     

Erythroid cell differentiation: murine erythroleukemia cell variant with unique pattern of induction by polar compounds.

The murine-virus-infected erythroleukemia cell system provides an opportunity to examine regulatory mechanisms controlling cytodifferentiation. A cloned cell line (DR10c3) resistant to the erythropoiesis-inducing effect of dimethylsulfoxide (Me2SO) was isolated from the Me2SO-sensitive line DS19. DR10c3 is characterized as follows: (1) the uptake of [3H]Me2SO is similar to that in DS19; (2) cell growth with and without Me2SO is similar to that of DS19; (3) resistance is relatively stable; (4) the karyotype of DR10c3 reveals an average loss of five chromosomes per cell, but is otherwise similar to that of DS19; (5) total protein and globin synthesis by cells cultured 4 days with or without Me2SO is similar to these syntheses in DS19 cultured without Me2SO; (6) virtually no globin mRNA is detectable after 3 days in Me2SO, as assayed both by RNA-complementary DNA hybridization and by the heterologous cell-free protein-synthesizing system; (7) other polar compounds, N-methylpyrrolidinone, 1-methyl-2-piperidone, N, N-dimethylacetamide, and N-methylacetamide, induce erythroid differentiation in DR10c3, and the accumulation of alpha- and beta-globin chains is indistinguishable from that in DS19; and (8) the concentration optima for induction of differentiation by all these compounds are identical for DR10c3 and DS19.     

Lengthening of the G1 phase is not strictly correlated with differentiation in Friend erythroleukemia cells.

Friend murine erythroleukemia cells (Friend cells) undergo erythroid differentiation in vitro with an increased probability when cells are cultured in the presence of dimethyl sulfoxide (Me2SO) or other agents. Exponentially growing Friend cells, after dilution into medium containing Me2SO, underwent a transient lengthening of the G1 phase of the cell cycle before they became committed to erythroid differentiation. For nine inducing agents, a positive correlation was found between the percentage of cells that had differentiated and synthesized heme, and the percentage of progenitor cells in which a lengthened G1 phase had previously been observed. This correlation was not found, however, with two other potent inducing agents, hypoxanthine and actinomycin D. Moreover, cells that underwent a lengthened G1 phase did not always terminally differentiate. One such example was a Me2SO-resistant, variant Friend cell line (520a) grown in the presence of Me2SO. These results imply that the prolonged G1 phase, although observed with many inducers, is not a prerequisite for erythroid differentiation with all inducers.     

Replication of alpha and beta globin DNA sequences occurs during early S phase in murine erythroleukemia cells.

Murine erythroleukemia cells (MELC) can be induced to express the characteristics of erythroid differentiation by a variety of agents. Previous studies indicate that an action of inducer, occurring during early S phase, may be critical to the expression of differentiated characteristics such as initiation of accumulation of newly synthesized alpha and beta globin mRNAs. In this investigation, the time of replication of globin genes in MELC was studied. DNA was isolated from synchronous populations of cells obtained by centrifugal elutriation. Newly replicated DNA sequences were prepared from synchronized cells cultured for 1 1/2 hr with 5-bromodeoxyuridine; bromodeoxyuridine-containing DNA was isolated by CsCl gradient centrifugation. By employing cloned probes for hybridization to newly synthesized DNA, it was found that alpha and beta globin gene sequences are replicated early in S phase, while ribosomal RNA gene sequences are replicated to about the same extent in early, middle, and late S phases.     

Erythroleukemia cells: variants inducible for hemoglobin synthesis without commitment to terminal cell division.

Murine erythroleukemia cells (MELC) are virus-transformed erythroid precursors that appear to be blocked at an erythroid precursor stage comparable to the erythroid colony-forming unit (CFU-e). These cells are useful in examining factors regulating terminal differentiation. Induced MELC are characterized by a coordinated program of gene expression, including commitment to terminal cell division, accumulation of globin mRNAs and corresponding hemoglobins, and accumulation of several other proteins, including the chromatin-associated protein H1(0). Two cloned variant cell lines, DR10 and R1, have been developed from inducer-sensitive DS19 cells by selection for inducer resistance. DR10 and R1 cells fail to display commitment to terminal cell division when cultured with dimethyl sulfoxide (Me2SO), hexamethylene bisacetamide (HMBA), or butyric acid. Both cell lines are induced by all three agents to accumulate H1(0). DR10 cells are resistant to Me2SO-mediated accumulation of hemoglobin but are sensitive to HMBA- or butyric acid-mediated accumulation. R1 cells are resistant to Me2SO- and HMBA-mediated accumulation of hemoglobin but are sensitive to butyric acid-mediated accumulation. Both DR10 and R1 are commitment-negative MELC variants, displaying variable responses to inducers with respect to other features of terminal erythroid cell differentiation.     

Amiloride inhibits murine erythroleukemia cell differentiation: evidence for a Ca2+ requirement for commitment.

The effect of amiloride (an inhibitor of passive Na+ transport in many tissues) on the differentiation of murine erythroleukemia cells was investigated. Amiloride completely blocked the dimethyl sulfoxide (Me2SO)-induced erythroid differentiation of cells at a concentration (10 microgram/ml) that did not affect cell proliferation. Amiloride also prevented the decrease in cell volume normally observed afte a 20-hr exposure to Me2SO. The ratio of total cell Na+ to total cell water was essentially the same for control cells, Me2SO-treated cells, and cells treated with Me2SO plus amiloride. However, cells treated for 24 hr with Me2SO had a rate of Ca2+ uptake that was twice that of untreated cells and a similarly higher Ca2+ content. Addition of amiloride plus Me2SO prevented both the increase in Ca2+ uptake rate and the increase in Ca2+ content. Cells grown in the presence of Me2SO plus amiloride initiated differentiation immediately after removal of amiloride or addition of the Ca2+ ionophore A23187 (1 microgram/ml). Addition of sufficient ethylene glycol bis(beta-aminoethyl ether)-N,N,N'',N''-tetraacetic acid to reduce free extracellular Ca2+ to submicromolar levels prevented Me2SO-induced differentiation while only slightly affecting cell proliferation. These results suggest that an increase in in the Ca2+ level is an essential step in Me2SO induction, that amiloride either directly or indirectly inhibits this process, and that Me2SO has an early effect on cells that is necessary for differentiation and is not mimicked by A23187.     

DNA fragments in Friend erythroleukemia cells induced by dimethyl sulfoxide.

The idea of the correlation between DNA damage caused by dimethyl sulfoxide (Me2SO) and the induction of erythrodifferentiation in murine erythroleukemia (MEL) cells needs reevaluation as a result of the hydroxyapatite chromatographic analysis of DNA from Me2SO-treated and untreated cells as a function of the time in culture. Because Me2SO causes an arrest in G1 phase and consequent delay in DNA synthesis, the valid comparison would be of the DNA samples taken from control and induced cells at the same stage of growth rather than at the same time in culture. At the same stage of growth, there is no evidence of the induction of DNA damage by Me2SO. Presumably, so-called degradation reported in the past stemmed from the fragments of DNA replication.     

Iron storage in ferritin following intracellular hemoglobin denaturation in erythroleukemic cells

Murine erythroleukemia (MEL) and human K-562 cell lines were cultured in the presence of 57Fe, and the quantities of cellular iron-containing compounds were determined with the aid of Mossbauer spectroscopy. Upon induction of differentiation, both ferritin-iron and hemoglobin (Hb) iron could be detected. Treatment of the cells with 0.01%-0.02% acetylphenylhydrazine (APH) resulted in gradual denaturation of Hb and incorporation of the released Hb-iron into ferritin. Following treatment with APH, the ratio of Hb-57Fe to ferritin-57Fe decreased from 2.6 to 0.2 in MEL cells and from 0.56 to 0.12 in K-562 cells. No change was observed in the total intracellular iron. Using fluorescence ELISA, an increased level of immunologically detectable ferritin was found in hemoglobinized K-562 cells treated with APH, as compared to the amount of ferritin found in untreated cells. Ferritin may thus function not only as an intermediate during Hb synthesis, but also as storage protein for iron released during Hb denaturation.     

Inducer-mediated commitment of murine erythroleukemia cells to terminal cell division: the expression of commitment.

Murine erythroleukemia cells (MELC) are transformed cells that can be induced to differentiate by a variety of agents, such as hexamethylenebisacetamide (HMBA) and dimethyl sulfoxide. Dexamethasone suppresses HMBA-mediated MELC differentiation, but MELC retain a memory for their exposure to HMBA since, on transfer from culture with HMBA and dexamethasone to medium without additions, a portion of the cells express characteristics of terminal differentiation. This study characterizes the steroid suppressed steps in the multi-step process of inducer-mediated MELC terminal differentiation. MELC in culture with HMBA and dexamethasone show low levels of commitment to terminal cell division; upon transfer to culture with inducer alone there is a rapid increase in the proportion of committed cells. The magnitude of this rapid or "step-up" expression of commitment increased with the length of prior culture with inducer and steroid. This step-up expression is not inhibited by actinomycin D or cordycepin but is blocked by cycloheximide. HMBA is required for step-up expression of commitment. In the absence of inducer, there is a rapid decay in the capacity for step-up expression. Thus, HMBA initiates a series of changes leading to the accumulation of factors--which may be mRNAs--whose expression is blocked by dexamethasone. Hemin, which induces MELC accumulation of globin mRNA but not commitment to terminal cell division, cannot, as does HMBA or dimethyl sulfoxide, cause step-up expression of commitment.     

Maintenance of differentiated rat hepatocytes in primary culture.

Normal adult rat hepatocytes remained viable and functional for at least 43 days when plated on collagen-coated dishes and fed chemically defined medium supplemented with dimethyl sulfoxide (Me2SO). Hepatocytes isolated by collagenase perfusion and cultured in the presence or absence of Me2SO were (i) examined by light and electron microscopy for morphological changes; (ii) analyzed for the production of albumin and other plasma proteins; and (iii) tested by autoradiography for DNA synthesis. Me2SO-treated cells continued to produce specific plasma proteins during the entire culture period; albumin production was consistently high (11-19 micrograms/ml of culture medium per 24 hr) from day 2 to at least day 43 after plating. Ultrastructural analyses demonstrated that Me2SO-treated hepatocytes resembled those from intact liver in organization of cytoplasmic organelles and cellular junctions. The optimal concentration for observing the morphological and biochemical effects of Me2SO was 2% (vol/vol). We conclude that supplementation of chemically defined medium with Me2SO enables maintenance of differentiated hepatocytes in culture for extended periods of time.     

Synthesis and turnover of globin mRNA in murine erythroleukemia cells induced with hemin

When murine erythroleukemia (MEL) cells are induced with hemin, they carry out several early functions of the erythroid program. However, they do not become committed to terminal differentiation nor do they become benzidine positive. This is in contrast to MEL cells induced with dimethyl sulfoxide (Me(2)SO) which undergo a more complete program of erythroid differentiation. In order to determine the relationship between commitment and various events in the erythroid program, we compared the induction of MEL cells with hemin and with Me(2)SO. The amount of globin mRNA accumulated in inducing MEL cells and the rate of its synthesis and turnover were quantitated. Although MEL cells induced with hemin accumulated significantly less globin mRNA than did cells induced with Me(2)SO, the rate of synthesis of globin mRNA was the same in fully induced cells, irrespective of inducer. Therefore, there is no evidence that induction with hemin produces an early program that is different or altered from that which is part of Me(2)SO induction. MEL cells induced with Me(2)SO specifically destabilize their globin mRNA after 4 days of induction. This raises the question of whether this destabilization of globin mRNA is an independently programmed late event, as suggested by the time of its occurrence, or, alternatively, whether it might be the inevitable consequence of an early event(s). For instance, destabilization might be linked to the synthesis or translation of globin mRNA. Because MEL cells induced with hemin do not destabilize their globin mRNA, we have concluded that this turnover of globin mRNA is a late event, occurring only in a committed cell population.     

Dissociation of iron transport and heme biosynthesis from commitment to terminal maturation of murine erythroleukemia cells.

Treatment of murine erythroleukemia (MEL) cells with imidazole in the presence of dimethyl sulfoxide (Me2SO) has been shown to dissociate hemoglobin accumulation from commitment to terminal maturation. To explore the mechanism(s) of this effect, we studied iron transport and heme and hemoglobin synthesis in Me2SO-induced MEL cells that were then exposed to imidazole. Imidazole treatment (i) causes moderate inhibition of 125I-labeled transferrin binding to both control and Me2SO-treated MEL cells; (ii) markedly suppresses Me2SO-induced activation of iron uptake into MEL cells; (iii) markedly decreases the incorporation of iron into ferritin; and (iv) abolishes heme biosynthesis from [2-14C]glycine and hemoglobin accumulation in Me2SO-treated cells. Imidazole treatment does not inhibit other aspects of cellular maturation; cells treated with Me2SO in the presence or absence of imidazole exhibit similar changes in proliferative activity and protein synthesis and, as shown previously, in cell morphology. Inhibition of hemoglobin accumulation in MEL cells is reversible on withdrawal of imidazole but is not altered by exogenous hemin. These data indicate that commitment to terminal maturation is regulated independently from the systems for iron transport and heme biosynthesis during early phases of erythroid cell differentiation.     

Stability of alpha and beta globin messenger RNA during induced differentiation of mouse erythroleukemia cells.

Murine erythroleukemia cells (MELC) are induced to express erythroid differentiation when cultured with hexamethylene bisacetamide (HMBA). Newly synthesized alpha and beta globin mRNA are both relatively stable, half-life (t1/2) greater than 50 hr, early in the course of induced differentiation. In fully induced cells there is a decrease in stability of both newly synthesized alpha and beta globin mRNA. The decay of alpha mRNA is faster, (t 1/2, 10--12 hr) than beta globin mRNA (t1/2, 20--22 hr). Thus, differences in stability of alpha and beta globin mRNA plays a role in determining the ratio of alpha to beta mRNA content in differentiated erythroid cells.     

The proportions of hemoglobin types induced in mouse erythroleukemia cells vary with the inducer or combination of inducers, the inducer concentration and the time of induction

The relative amounts of hemoglobin (Hb) major and Hb minor accumulated during induction of erythrodifferentiation in mouse erythroleukemia (MEL) cells were studied. The ratio of major to minor was found to depend not only upon the inducer tested (as reported previously by others), but also upon the concentration of the inducer and the time of exposure to the inducer as well as the specific cell line of MEL cells studied. At concentrations required for optimal induction of differentiation, certain agents led to the accumulation of predominantly Hb major, but suboptimal concentrations of the same inducers led to predominantly Hb minor accumulation. After a relatively short induction time (2 da) utilizing a given inducer either the level of Hb minor was higher than that of Hb major or the levels of the two Hb's were approximately equal, but after longer induction periods (3-7 da) Hb major was more abundant than Hb minor. In addition, it was found that the three proteases tested induced predominantly Hb minor. The addition of suboptimal concentrations of low molecular weight inducers acted synergistically with a given protease to produce a high yield of Hb-containing cells. When these agents were added singly they induced relatively low Hb major/Hb minor ratios, but when a low molecular weight inducer was added together with a protease in a "synergistic" combination, elevated ratios were induced. The proportions of hemoglobin types induced in MEL cells may be related in part to the intensity of the induction response. In view of these data, classifications of inducers based solely on the ratios of Hb types produced must be guarded.     

Phenotypic heterogeneity among stromal cell lines from mouse bone marrow disclosed in their extracellular matrix composition and interactions with normal and leukemic cells

Study of a series of stromal cell lines from mouse bone marrow (MBA) verified and extended their classification as phenotypically distinct subtypes. Production of extracellular matrix proteins was examined using specific antibodies. Fibronectin and laminin were detected in all of the cell lines tested, yet 14F1.1 adipocytes exhibited particularly prominent extracellular deposition. This cell line and MBA-13.2 cells were positive to both collagen types I and IV, whereas MBA-1 and MBA-2.1 were stained with anticollagen type I antibodies only. Coculture experiments revealed differences among the lines in their effects on normal myeloid cells and leukemic cell lines. In promoting the in vitro accumulation of myeloid progenitors (CFU-C), 14F1.1 cells surpassed the others. The MBA-2.1 cell line was particularly inhibitory to MPC-11 plasmacytoma and Friend erythroleukemia cells. However, the latter were refractory to other stromal cell lines, whereas MPC-11 cells were inhibited to various degrees by virtually all of the cell lines. Physical separation between the interacting cells reduced the inhibition in some but not all cases, and no inhibitory activity was detected in conditioned media. The MBA-13 stromal cells synergistically promoted the differentiation of dimethylsulfoxide (Me2SO)-induced Friend erythroleukemia. The latter cells themselves, at high concentrations, as well as some of the stromal cell lines and unrelated adherent cells, antagonized the Me2SO effect, revealing possible reversible stages in the Friend cell differentiation pathway.     

Synthesis of DNA in Human Lymphocytes: Possible Control Mechanism

Partially purified, isolated nuclei from lymphocytes either stimulated or not stimulated by phytohemagglutinin can equally well synthesize DNA when [(3)H]dTTP is used as precursor. Studies of DNA polymerase activity in nuclei and cytoplasm from these cells showed that the enzyme can be detected in either stimulated or nonstimulated lymphocytes. In nonstimulated lymphocytes the uptake of thymidine is very low. The use of inhibitors such as cycloheximide, arbinosylcytosine, and actinomycin D showed that a parallel existed between thymidine uptake and DNA synthesis. All the conditions in which DNA synthesis was inhibited resulted also in an inhibition of thymidine uptake.