Differentiation-associated changes in membrane proteins of mouse myeloid leukemia cells

The mouse myeloid leukemia cell line (M1) is known to differentiate in vitro into macrophages and granulocytes upon treatment with various inducer including mouse ascitic fluid. Changes of cell surface proteins during differentiation of M1 cells were analyzed by the lactoperoxidase-catalyzed radioiodination method and SDS-polycrylamide slab gel electrphoresis. Treatment of the cells with ascitic fluid changed the electrophoretic pattern of the iodinated proteins, the prominent change being the appearance of a new protein with a molecular weight of 180 000 (P180). Iodinated P180 was also detected in normal macrophages in granulocytes, which are similar to differentiated M1 cells. This protein was metabolically labeled with l-[¹⁴C]fucose, increasing with the period of the treatment. P180 was not expressed on ascitic fluid-treatment of a resistant clone of M1 cells that could not be induced to differentiate. These results indicate that P180 is a glycoprotein that is exposed on the outer surface of differentiated M1 cells, and that its expression is associated with differentiation of the cells.P180 was solubilized from ¹²⁵I-labeled macrophages with detergents bound to concanavalin A-Sepharose. This suggests that P180 is one of the receptors for concanavalin A. Therefore, P180 may contribute partly to the increases in agglutinability by concanavalin A and in the number of concanavalin A binding sites on the surface of M1 cells, which are known to be associated with differentiation of M1 cells.     

Differentiation-associated changes of glycolipid composition and metabolism in mouse myeloid leukemia cells. Induction of globotriaosylceramide and a galactosyltransferase

This study was to find out whether induction of special glycolipids or glycosyltransferases for glycolipid synthesis which might be involved in the cell functions occurred during the differentiation. Mouse myeloid leukemia cell line (M1-), the differentiated cells (M1+), and a subcloned cell line (Mm1) were used for this purpose. Gangliotriaosylceramide (GA2) was the major glycolipid component in M1- cells. As a result of differentiation of M1- into M1+ cells, globotriaosylceramide (CTH) was newly induced as the main glycolipid, while GA2 decreased to a minor component. GA2 was found to be the main glycolipid in Mm1 cells but no CTH was recognized. All precursor glycolipids and glycosyltransferases required to complete the biosynthetic pathway glucosylceramide (CMH) leads to lactosylceramide (CDH) leads to GA2 leads to gangliotetraosylceramide (GA1) leads to sialosylgangliotetraosylceramide (GM1b) were found in M1- and also in Mm1 cells. A galactosyltransferase activity for CTH synthesis from CDH increased 10 fold during the differentiation. The induction of CTH in M1+ cells could be attributed to the increase of the galactosyltransferase activity. Both CTH as a surface marker and the galactosyltransferase as an enzyme marker are proposed as valuable markers of differentiation in M1- cells. Besides the galactosyltransferase, N-acetylglucosaminyltransferease involved in the formation of lactotriaosylceramide (amino-CTH) increased up to 3 fold during the differentiation. The increase of the enzyme activity seemed to be responsible for the biosynthesis of lactoneotetraosylceramide (paragloboside) which appeared in M1+ cells.     

Differentiation-associated changes of cation-transport activities in myeloid leukemic cell lines

Induction of differentiation in HL-60 and U-937 leukemic cell lines, resulted in 1.5-10-fold increase in 45Ca2+ uptake. The increased 45Ca2+ uptake in the differentiating cells was inhibited by verapamil, cromolyn and amiloride. Elevation in Ca2+ uptake in differentiating cells was also demonstrated using the fluorescent probe, fura-2 acetoxymethyl ester. The increased 45Ca2+ uptake was accompanied by a decrease in ouabain-insensitive and -sensitive 86Rb+ uptake. Furthermore, correlation between the changes in these activities was observed. Modulation of extracellular pH affected differentiation: higher pH increased the extent of differentiation.     

Changes in protease during differentiation of mouse myeloid leukemia cells.

The protease activities of mouse myeloid leukemia cells Ml were examined using fluorescein isothiocyanate-labeled albumin as substrate. Protease activity in Ml cells was greatest at alkaline pH values with a maximum at pH 11.0, and only slight activity was seen at neutral and acidic pHs. When Ml cells were induced to differentiate into mature cells by lipopolysaccharide, their alkaline protease activity decreased greatly with marked increase in acid protease activity. Moreover, in a variant cell line Mml with the properties of differentiated Ml cells, no protease activity was found at alkaline pH values.     

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.     

Modification of membrane phospholipid composition by choline analogues induces differentiation of cultured mouse myeloid leukemia cells

Mouse myeloid leukemia M1 cells could be induced by various inducers to form Fc receptors, phagocytize, produce lysozyme, and change into forms that were morphologically similar to macrophages and granulocytes. Previous experiments showed that change in phospholipid metabolism was associated with cell differentiation. In the present experiment, culture of M1 cells with choline analogs such as N-monomethylethanolamine and N,N′-dimethylethanolamine resulted in accumulation of phosphatidyl-N-monomethylethanolamine and phosphatidyl-N,N′-dimethylethanolamine in the cell membranes. This change upon treatment with choline analogs was associated with morphological and functional differentiation of the M1 cells into macrophages and granulocytes. These results suggest that phospholipid metabolism is involved in the mechanism of differentiation of M1 cells.     

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.     

Changes in phospholipid composition during differentiation of cultured mouse myeloid leukemia cells

Mouse myeloid leukemia cells(M1) could be induced by various inducers to form Fc receptors, phagocytize, migrate in agar, produce lysosomal enzyme activities, and change into forms that were morphologically similar to macrophages and granulocytes. When M1 cells were cultured with inducer, the ratio of the percentage of phosphatidylethanolamine to that of phosphatidylcholine was increased about 2-fold. This ratio of the differentiated M1 cells was similar to that of peritoneal macrophages of normal mice or Mm-1 cells, which were established from spontaneously differentiated macrophage-like cells from M1 cells. These changes in phospholipid may be involved in the mechanisms of expression of the differentiation-associated phenotypic properties.     

Expression of external-surface membrane proteins in differentiated and undifferentiated mouse neuroblastoma cells.

Murine neuroblastoma cultures were labeled externally with the cationic reagent N,N,N-[3H]-trimethylamino-beta-alanyl-N-hydroxy-succinimide ester ([3H]Me3N-beta Ala-NSuc) or with 125I/lactoperoxidase. The cells were labeled in the logarithmic and confluent growth phases as well as in a highly differentiated state following treatment with 2% dimethylsulfoxide. The labeled exterior membrane proteins were analyzed by sodium dodecyl sulfate/polyacrylamide gel electrophoresis. Major changes in the exterior membrane proteins were observed during maturation and differentiation of the cells. Most of these changes were clonal-specific, while others were common to several clones. Two proteins of Mr 55,000 and 65,000 were labeled by both 125I/lactoperoxidase and Me3N-[3H]-beta Ala-NSuc. The level of labeling was dependent on the clonal lines used and the state of the cell maturation. A group of proteins displaying a molecular weight between 150,000 and 200,000 was found to be related to the transition of a culture from logarithmic to confluent growth phases. An additional protein, with an apparent molecular weight of 95,000, was common to differentiated cells of the two inducible clones used. In general the maturation of logarithmic phase cells into confluent cells resulted in a less complex electrophoretic distribution of the pattern of labeling. After dimethyl-sulfoxide treatment, further reduction in the complexity of the externally labeled proteins was observed.     

Redistribution of membrane proteins in isolated mouse intestinal epithelial cells

Single mouse intestinal epithelial cells (IEC) may be isolated by the use of a combination of methods used for the isolation of IEC from other species. Isolated cells remain viable for several hours. The membrane integral enzymes alkaline phosphatase and leucine aminopeptidase of isolated IEC are localized to the brush borders of IEC in tissue and in most newly isolated IEC. With time, both enzymes are found distributed over the entire cell surface. Redistribution appears to occur by diffusion in the plane of the membrane. It is slowed, but not blocked, if cells are maintained at 0 degrees C instead of at 37 degrees C, and it is not blocked by fixation in 0.5-3% paraformaldehyde. Drugs that alter cell membrane potential or that affect cell levels of ATP enhance the rate of redistribution of the enzymes.     

Production of differentiation-stimulating factor in cultured mouse myeloid leukemia cells treated by glucocorticoids

Mouse myeloid leukemic cells (Ml) could be induced by glucocorticoids to produce a factor(s) stimulating their own differentiation to macrophage- and granulocyte-like cells. The differentiation-stimulating factor(s) (DSF) was not due to a contaminating steroid, although glucocorticoids were effective to induce differentiation of the cells. DSF seemed to be a glycoprotein(s) with a molecular weight of 20 000–40 000 D, since it was susceptible to a treatment of proteases of glycosidases. The inducing ability of corticoids to produce DSF was correlated with their glucocorticoid activity, which was in parallel with the inducing activity of cell differentiation. Moreover, glucocorticoids were unable to stimulate the production of DSF in a dexamethasoneresistant Ml cells which could not differentiate even in a high concentration of dexamethasone. These results suggest that production of DSF in Ml cells was closely associated with differentiation of the cells. Differentiation of Ml cells by DSF was confirmed by morphological, functional and biochemical evidences.     

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 β- to γ-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.     

Induction of differentiation of human and mouse myeloid leukemia cells by camptothecin

Low concentrations of camptothecin induced differentiation of human and mouse myeloid leukemia cells including human HL60, U937, ML1, and K562 cells and mouse M1 cells as measured by various differentiation-associated properties. When K562 cells were pretreated with 20 nM camptothecin for 2 h, 53% of the cells were induced to differentiate as measured by NBT staining. Significant single strand breaks in DNA of K562 cells were caused by this treatment. Most single strand breaks were accompanied by protein-DNA cross linking. The combination of camptothecin and rTNF synergistically induced differentiation of human ML1, U937, and M1 cells. These results suggest that topo I may be important in some differentiation of myeloid leukemia cells.     

Regulation of prostaglandin synthesis during differentiation of cultured mouse myeloid leukemia cells

Mouse myeloid leukemia cells (Ml) were induced to differentiate into mature macrophages and granulocytes by various inducers. The differentiated Ml cells synthesized and released prostaglandins, whereas untreated Ml cells did not. When the cells were prelabelled with [¹⁴C]arachidonate, the major prostaglandins released into the culture media were found to be prostaglandin E₂, D₂, and F_2α in an early stage of differentiation, but the mature cells produced predominantly prostaglandin E₂. The synthesis and release of prostaglandins were completely inhibited by indomethacin. Dexamethasone, a potent inducer of differentiation of Ml cells, did not induce production of prostaglandins in resistant Ml cells that could not differentiate even with a high concentration of dexamethasone. These results suggest that production of prostaglandins in Ml cells is closely associated with differentiation of the cells. Homogenates of dexamethasone-treated Ml cells converted arachidonate to prostaglandins, but this conversion was scarcely observed with homogenates of untreated Ml cells. Dexamethasone and the other inducers stimulated the release of arachidonate from phospholipids. Therefore, induction of prostaglandin synthesis during differentiation of Ml cells may result from induction of prostaglandin synthesis activity and stimulation of the release of arachidonate from cellular lipids. Lysozyme activity, which is a typical biochemical marker of macrophages, was induced in Ml cells by prostaglandin E₂ or D₂ alone, as well as by inducers of differentiation of the cells, but it was not induced by arachidonate or prostaglandin F_2α. These results suggest that prostaglandin synthesis is important in differentiation of myeloid leukemia cells.     

Externally disposed plasma membrane proteins. I. Enzymatic iodination of mouse L cells

The enzymatic iodination technique has been utilized in a study of the externally disposed membrane proteins of the mouse L cell. Iodination of cells in suspension results in lactoperoxidase-specific iodide incorporation with no loss of cell viability under the conditions employed, less than 3% lipid labeling, and more than 90% of the labeled species identifiable as monoiodotyrosine. 90% of the incorporated label is localized to the cell surface by electron microscope autoradiography, with 5-10% in the centrosphere region and postulated to represent pinocytic vesicles. Sodium dodecylsulfate-polyacrylamide gels of solubilized L-cell proteins reveals five to six labeled peaks ranging from 50,000 to 200,000 daltons. Increased resolution by use of gradient slab gels reveals 15-20 radioactive bands. Over 60% of the label resides in approximately nine polypeptides of 80,000 to 150,000 daltons. Various controls indicate that the labeling pattern reflects endogenous membrane proteins, not serum components. The incorporated 125-I, cholesterol, and one plasma membrane enzyme marker, alkaline phosphodiesterase I, are purified in parallel when plasma membranes are isolated from intact, iodinated L cells. The labeled components present in a plasma membrane-rich fraction from iodinated cells are identical to those of the total cell, with a 10- to 20-fold enrichment in specific activity of each radioactive peak in the membrane.     

Identification of Annexin A1 interacting proteins in chronic myeloid leukemia KCL22 cells

In the present study, we used a functional proteomic approach to identify Annexin A1 (Anxa1) interacting proteins in the Philadelphia‐positive KCL22 cell line. We focused on Anxa1 because it is one of the major proteins upregulated in imatinib‐sensitive KCL22S cells versus imatinib‐resistant KCL22R. Our proteomic strategy revealed 21 interactors. Bioinformatic analysis showed that most of these proteins are involved in cell death processes. Among the proteins identified, we studied the interaction of Anxa1 with two phosphatases, Shp1 and Shp2, which were recently identified as biomarkers of imatinib sensitivity in patients affected by chronic myeloid leukemia. Our data open new perspectives in the search for annexin‐mediated signaling pathways and may shed light on mechanisms of resistance to imatinib that are unrelated to Bcr‐Abl activity. All mass spectrometry data have been deposited in the ProteomeXchange with identifier PXD000030.     

Differences in membrane unsaturated fatty acids and electron spin resonance in different types of myeloid leukemia cells.

The fatty acid composition and some physical properties of intact cells and isolated plasma membranes of two types of mouse myeloid leukemia cell clone grown in culture have been examined. One clone type, MGI+D+, can be induced by the macrophage and granulocyte-inducing protein (MGI) to differentiate into mature macrophages and granulocytes. The other clone type, MGI+D-, could not be induced to differentiate into mature cells. A two-fold increase in the ratio of saturated fatty acid to unsaturated fatty acid was found in the MGI+D- compared to the MGI+D+ clones. The MGI+D- clones produced an unusual polyunsaturated C20:5 fatty acid at 28 degrees C, whereas the MGI+D+ clones did not grow at this temperature. The cells and their isolated plasma membranes were studied by electron spin resonance. The motion of the 5-nitroxide stearate spin label was found to be higher in the intact cells and in the membranes of MGI+D- clones than of the MGI+D+ clones. The cells of MGI+D+ clones showed a similar freedom of motion to normal myeloblasts from the bone marrow. The results indicate that myeloid leukemia cells which differ in their competence to be induced to differentiate into mature cells have different physical properties of their plasma membranes and that this is correlated with their fatty acid acyl chain composition.     

Biosynthesis of mouse erythrocyte membrane proteins by friend erythroleukemia cells

The synthesis of mouse erythrocyte membrane proteins by Friend erythroleukemia cells during dimethyl sulfoxide-induced differentiation was studied. Untreated and dimethyl sulfoxide-treated cells were incubated with l-[³H] leucine and the incorporation of radioactivity into total trichloroacetic acid-insoluble proteins and into proteins immunoprecipitated with a multivalent rabbit antibody to mouse erythrocyte membranes was determined. The immunoprecipitated membrane proteins were separated by sodium dodecyl sulfate polyacrylamide gel electrophoresis and radioactivity was detected by fluorography. The incorporation of l-[³H]leucine into total cell proteins was linear for 20 min in both untreated and treated cells. Exposure of the cells to dimethyl sulfoxide had an inhibitory effect on protein synthesis, with a significant decrease noted on the fourth day of treatment and a continued decline occurring until the seventh day when protein synthesis was 42% that of untreated cells. The synthesis of erythrocyte membrane proteins was 0.49% that of total cell proteins in untreated cells, was increased to 1.27% by the third day of treatment and remained at about 1% of total protein synthesis from the fourth to the seventh day. Untreated cells synthesized low levels of spectrin, bands 5 and 6 proteins. Treatment with dimethyl sulfoxide caused a staggered increase in synthesis of a number of erythrocyte membrane proteins. Spectrin synthesis increased 4-fold by the third day of treatment and declined thereafter. The synthesis of membrane proteins with electrophoretic mobilities similar to bands 3 and 4 was increased 2–3-fold by the fourth day, while bands 6 and 5 proteins attained maximal synthesis (4-fold) on the fifth and sixth days of treatment.