Differentiation of a cell line of mouse myeloid leukemia. I. Simultaneous induction of lysosomal enzyme activities and phagocytosis

Effects of type-beta 1 transforming growth factor on the proliferation and differentiation of mouse myelomonocytic leukemia cells (M1)

Murine myelomonocytic leukemia M1 cells have been used to examine the effects of type-beta 1 transforming growth factor (TGF-beta 1) on cellular proliferation and differentiation in monocyte-macrophage lineage. TGF-beta 1 inhibited immature M1 cell growth due to a general slowdown of the cell cycle, without arrest at any specific point. Ten nanograms per milliliter TGF-beta 1 completely suppressed phagocytic activity and adhesion to the dish surface and partially inhibited the expression of Fc receptors and vimentin during the differentiation of M1 cells induced by IL-6. IL-6-induced declines in the expression of c-myc mRNA and in the accumulation of G0/G1 cells were also partially blocked by TGF-beta 1. When treated concurrently with IL-6 and TGF-beta 1, approximately 50% of M1 cells were morphologically converted to promonocyte or monocyte-like cells, which did not exhibit the characteristics of mature macrophages. Although pretreatment with TGF-beta 1 also inhibited the IL-6-induced phagocytic activity, this inhibition was reversible. Once TGF-beta 1 was removed from the culture medium after 72 h of incubation with IL-6, the kinetics of differentiation induced by IL-6 were faster in pretreated cells than in nonpretreated cells. TGF-beta 1 appears to inhibit the IL-6 induced conversion of M1 cells at the intermediate stage of monocytic differentiation.

Regulation of the expression of vimentin gene during the differentiation of mouse myeloid leukemia cells

We have examined the expression of vimentin during the differentiation of mouse myeloid leukemia cells (M1), which were induced to differentiate into macrophages by exposure to conditioned medium (CM) obtained from rat embryo fibroblasts. The synthesis of vimentin, which was examined by two-dimensional gel electrophoresis, increased after 12-24 h of incubation of M1 cells in CM and the elevated level of synthesis continued up to 96 h. A macrophage cell line (Mm1) that was derived from spontaneously differentiated M1 cells constantly synthesized much higher levels of vimentin. The amount of vimentin, which was revealed by immunoblot analysis using an mAb against human vimentin, also increased after differentiation by a factor of 7 when compared on the basis of constant protein and by a factor of 17 on the basis of constant cell numbers. Mm1 cells contained greater than 12- and 45-fold more vimentin compared with undifferentiated M1 cells on the bases of constant protein and constant cell numbers, respectively. Northern blot analysis using vimentin cDNA as a probe revealed increases in vimentin mRNA in the differentiated M1 cells and Mm1 cells. Nuclear run-on assay showed that the expression of vimentin gene during the differentiation of M1 cells was transcriptionally regulated. Observations in indirect immunofluorescence microscopy and EM clearly showed that vimentin bundles were rarely observed in undifferentiated M1 cells, and increased amounts of and large-size vimentin bundles were easily observed in differentiated M1 and Mm1 cells. These results suggest the participation of increased amounts of vimentin filaments in the maldistribution of nuclei in M1 cells during differentiation.

Changes in contractile proteins during differentiation of myeloid leukemia cells. II. Purification and characterization of actin

A myeloid leukemia cell line, M1, differentiates to macrophage and gains locomotive and phagocytic activity when incubated with conditioned medium (CM) from a fibroblast culture and bacterial endotoxin. To characterize the actin molecules before and after differentiation, the actin was purified through three sequential steps: DEAE-sephadex A- 50, polymerization/depolymerization, and sephadex G-150 chromatography. There were no essential differences between the inhibitory activity of actins from control M1 cells and CM-treated M1 cells on both DNase I and heavy meromyosin (HMMM) K(+)-EDTA-ATPase; the same dose response as with skeletal muscle actin took place. After the treatment with CM, however, the specific activity for the activation of HMMM Mg(2+)- ATPase by actin became two-fold that of untreated M1 actin, which was one third of the value for skeletal muscle actin. The V(max) for the control and the CM-treated M1 cell, as well as the skeletal muscle actins, proved to be the same. By contrast, the K(app) values for the control and CM-treated M1-cell actins were 3- and 1.5-fold the value for skeletal-muscle actin. This means that CM treatment of the M1 actin produced a twofold affinity for the Mg(2+)-ATPase of skeletal-muscle myosin. The critical concentrations for polymerization were compared under different salt concentrations and temperatures. Although no marked difference was found for the presence of 2 mM MgCl(2), 0.1 M KCl in place of MgCl(2) at 5 degrees C gave the following values: 0.1 mg/ml for skeletal-muscle actin, 0.7 mg/ml for control M1 actin, 0,5 mg/ml for CM- treated M1 actin, and 1.0 mg/ml for the D(-) subline that is insensitive to CM. Although the critical concentration of D(-) actin is extraordinarily high, this actin showed normal polymerization above the critical concentration. This together with the data presented in our previous paper, that the D(-) actin in the crude extract did not polymerize, suggests that an inhibitor for actin polymerization is present in the subline. The kinetics experiment at 0.1 M KCl and 25 degrees C revealed a slower polymerization of untreated M1- and D(-)-cell actins as compared with CM-treated M1 actin. This delayed polymerization was due to a delay during the nucleation stage, not during the elongation stage. By isoelectric focusing, the ratios of beta- to gamma-actin showed a marked difference depending on the states of cells: about 4.9 for control M1, 2.8 for CM-treated M1, and 7.6 for D(-)-subline actins. Tryptic peptide maps also revealed the presence of different peptides. Thus, the functional differences of actin before and after the differentiation was accompanied by some chemical changes in actin molecules.

High intralysosomal levels of lipoprotein cholesterol influence the endocytic activity and acid hydrolase content of CH-23 fibroblasts

Lipoprotein extracts isolated from hyperlipemic rabbit serum were used to study the effects of abnormal lipid levels on the functions of the lysosomal system in Chinese hamster CH-23 fibroblasts. The ability of cells enriched with lipid to endocystose [3H]inulin was largely unimpaired and utilising density gradient fractionation procedures the fusion between incoming inulin and low density lysosomes ladened with esterified cholesterol could be demonstrated. Studies in which cells were exposed to short 'bursts' of [3H]inulin indicated, however, that the rate of fusion between inulin and secondary lysosomes was reduced. The incorporation of lipid material also produced a rapid though transient increase in several acid hydrolase activities. The stimulus for increased enzyme activity does not appear to be the deposition of ingested lipid within the lysosomes but rather at some stage prior to this, possibly the formation of endocytic vesicles. The current findings suggest that the intralysosomal incorporation of lipid material which occurs in several pathological conditions has marked effects on lysosomal function.

Differentiation and production of colony-stimulating factor induced by immunostimulants in a leukemia cell line

Immunostimulants from various microorganisms were tested on a myeloid leukemia cell line (M1) for the ability to induce production of CSF and to cause differentiation of these cells. Based on their activities, the compounds were divided into two general classes: those inducing extensive cellular differentiation and those devoid of this effect. The stimulants which were active in this regard always produced large quantities of CSF, whereas those devoid of a differentiating effect did not cause CSF production. Even the potent stimulants had no effect on the D subline, in which the differentiation was not inducible.

Changes in contractile proteins during differentiation of myeloid leukemia cells. I. Polymerization of actin

Quantitative and qualitative changes in cellular actin were followed during differentiation of a myeloid leukemia cell line, namely Ml, which was inducible with conditioned medium (CM). During 3 d of incubation with CM, when the Ml cells differentiated to macrophages and lost their mitotic activity, the actin content, F-actin ratio in total actin, and the actin synthesis showed an increase. A greater difference before and after differentiation was found in the ability of G-actin to polymerize. Actin harvested from CM-treated cells showed a greater ability to polymerize, depending on the increased concentration of MgCl2 and/or KCl and proteins, as compared with the actin from untreated Ml cells. Actin harvested from the Mml cell line, a macrophage line, had a particularly high polymerizability with or without CM treatment. In contrast, the actin from the D- subline, which is insensitive to CM, showed almost no polymerization.

Production of a colony-stimulating factor following differentiation of leukemic myleoblasts to macrophages

Leukemic cells in the myeloblastic stage from a murine myeloid leukemia cell line (M1) were induced to differentiate to macrophages by lipopolysaccharide (LPS) from Gram-negative bacteria. A granulocyte-macrophage colony-stimulating factor (CSF) was produced only during differentiation. After induction of differentiation, the continued presence of LPS was necessary to stimulate the macrophages to release CSF. In contrast, a macrophage cell line (Mm-1) derived from the M1 line produced CSF without LPS-stimulation, but CSF release was stimulated by the presence of LPS.

Characterization of lysozyme synthesized by differentiated mouse myeloid leukemia cells

Lysozyme was induced by dexamethasone during normal differentiation of cultured mouse myeloid leukemia cells (M1) to macrophages and granulocytes. A large amount of lysozyme was produced by macrophage-like line cells (Mm-1), established from spontaneously differentiated macrophage-like cells from a clonal line of M1 cells. Lysozyme purified from the culture medium of these Mm-1 cells (Mm-1 lysozyme) had a molecular weight of 15,000, as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and showed maximal activity at pH 6.6 with an optimal NaCl concentration of 0.04 M. Its mobility on polyacrylamide gel electrophoresis at pH 4.5 was distinctly lower than those of lysozymes from hen egg white and human urine. Rabbit anti-Mm-1 lysozyme serum inhibited the activities of lysozyme preparations from peritoneal macrophages of normal mice and rats and dexamethasone-induced differentiated M1 cells, but not those of preparations from hen egg white and human urine. Lysozyme was also purified from normal mouse lung, which is rich in alveolar macrophages and was found to be similar to lysozyme purified from the culture medium of Mm-1 cells in size and electrophoretic mobility and in its pH optimum, trypsin peptide map, and antigenicity. Thus the molecular structure of the lysozyme induced in differentiated mouse myeloid leukemia cells is similar to that of lysozyme produced by normal cells.

Requirements for RNA and protein synthesis in the induction of several differentiation-markers in a myeloid leukemia cell line

In a myeloid leukemia cell line, the inducibilities of the Fc receptor, phagocytosis and cell motility were compared. Thymidine analogues such as BUdR, BCdR and IUdR blocked the induction of phagocytosis and motility but not induction of the Fc receptor. This BUdR susceptibility in the induction of phagocytosis and motility was lost in a BUdR resistant line which was isolated for its growth capability in a high concentration of BUdR. Actinomycin D and puromycin brought about a marked decrease in the inducibility of phagocytosis but not in that of the Fc receptor. This led us to the following conclusion: There is a genetic control in the inducibility of phagocytosis and motility in this cell line, and the incorporation of BUdR into cellular DNA results in the DNA becoming unresponsive to a differentiation-stimulating factor. In contrast, gene activation does not seem to be necessary for induction of the Fc receptor. The order of induction of several differentiation markers was also discussed.

Induction by synthetic polyribonucleotide poly(I) of differentiation of cultured mouse myeloid leukemic cells

The effects of some synthetic polyribonucleotides on induction of differentiation of mouse myeloid leukemic M1 cells were examined. Poly(I) was found to be a potent inducer; on treatment with 100--200 microgram/ml of poly(I) for 2--4 days, M1 cells differentiated into cells resembling macrophages and granulocytes and developed phagocytosis and locomotive activities, Fc receptors and lysozyme activity. Poly(C) was less effective than poly(I) for induction of phagocytic activity, while the other single-stranded RNAs, poly(U) and poly(A), had no effect. Double-stranded RNAs, such as poly(I) . poly(C) and poly(A) . poly(U), were cytotoxic to M1 cells, and differentiation of the cells could not be detected even at the highest tolerable concentrations of these double-stranded RNAs.

Differentiation of mouse myeloid leukemia cells is inhibited by a factor from non-differentiating leukemia cells

Mouse myeloid leukemia cells (MI) were induced to differentiate by a factor(s) (D-factor) in ascitic fluid. An inhibitory activity (I-activity) for the induction of differentiation was present in conditioned medium and lysate of MI cells resistant to the D-factor. The I-activity was non-dialyzable, heat-labile and protease-sensitive. Most of the activity was recovered in the fraction precipitated with 30-50% saturated ammonium sulfate. The fraction inhibited induction of phagocytic activity, migrating activity and morphological changes in MI cells, which are typical properties of differentiated MI cells. Low levels of I-activity were detected in conditioned medium or lysate of MI cells sensitive to the D-factor. The resistant MI cells were sensitized to the D-factor by treatment with a low concentration (5-10 ng/ml) of actinomycin D. The I-activity in conditioned medium of actinomycin D-treated resistant cells decreased with development of sensitivity to the D-factor. These results suggest that production of the I-activity in the resistant cells is closely associated with resistance of the MI cells to the D-factor.