Friend Murine Erythroleukemia Cells Research Articles

Reductions in the mitochondrial ABC transporter Abcb10 affect the transcriptional profile of heme biosynthesis genes

ATP-binding cassette subfamily B member 10 (Abcb10) is a mitochondrial ATP-binding cassette (ABC) transporter that complexes with mitoferrin1 and ferrochelatase to enhance heme biosynthesis in developing red blood cells. Reductions in Abcb10 levels have been shown to reduce mitoferrin1 protein levels and iron import into mitochondria, resulting in reduced heme biosynthesis. As an ABC transporter, Abcb10 binds and hydrolyzes ATP, but its transported substrate is unknown. Here, we determined that decreases in Abcb10 did not result in protoporphyrin IX accumulation in morphant-treated zebrafish embryos or in differentiated Abcb10-specific shRNA murine Friend erythroleukemia (MEL) cells in which Abcb10 was specifically silenced with shRNA. We also found that the ATPase activity of Abcb10 is necessary for hemoglobinization in MEL cells, suggesting that the substrate transported by Abcb10 is important in mediating increased heme biosynthesis during erythroid development. Inhibition of 5-aminolevulinic acid dehydratase (EC 4.2.1.24) with succinylacetone resulted in both 5-aminolevulinic acid (ALA) accumulation in control and Abcb10-specific shRNA MEL cells, demonstrating that reductions in Abcb10 do not affect ALA export from mitochondria and indicating that Abcb10 does not transport ALA. Abcb10 silencing resulted in an alteration in the heme biosynthesis transcriptional profile due to repression by the transcriptional regulator Bach1, which could be partially rescued by overexpression of Alas2 or Gata1, providing a mechanistic explanation for why Abcb10 shRNA MEL cells exhibit reduced hemoglobinization. In conclusion, our findings rule out that Abcb10 transports ALA and indicate that Abcb10's ATP-hydrolysis activity is critical for hemoglobinization and that the substrate transported by Abcb10 provides a signal that optimizes hemoglobinization.

Fam210b Is Required for Optimal Cellular and Mitochondrial Iron Uptake during Erythroid Differentiation

Red cells synthesize large quantities of heme during terminal differentiation. Central to erythropoiesis is the transport and trafficking of iron within the cell. Despite the importance of iron transport during erythroid heme synthesis, the molecules involved in intracellular trafficking of iron are largely unknown. In a screen for genes that are up-regulated during erythroid terminal differentiation, we identified FAM210B, a predicted multi-pass transmembrane mitochondrial protein as an essential component of mitochondrial iron transport during erythroid differentiation.In zebrafish and mice, Fam210b mRNA is enriched in differentiating erythroid cells and liver (fetal and adult), which are tissues that require large amounts of iron for heme synthesis. Here, we report that FAM210B facilitates mitochondrial iron import during erythroid differentiation and is essential for hemoglobin synthesis. Zebrafish are anemic when fam210b is silenced using anti-sense morpholinos (Fig. A). CRISPR knockout of Fam210b caused a heme synthesis defect in differentiating Friend murine erythroleukemia (MEL) cells. PPIX levels in Fam210b deficient cells are normal, demonstrating that Fam210b does not participate in synthesis of the heme tetrapyrrole ring. Consistent with this result, supplementation of Fam210b deficient MEL cells with either aminolevulinic acid, the first committed substrate of the heme synthesis pathway or a chemical analog of protoporphyrin IX failed to chemically complement the heme synthesis defect. While Fam210b was not required for basal housekeeping heme synthesis, Fam210b deficientcells showed defective total cellular and mitochondrial iron uptake during erythroid differentiation (Fig. B). As a result, Fam210b deficient cells had defective hemoglobinization. Supplementation of Fam210b-/- MEL cells with non-transferrin iron chelates restored erythroid differentiation and hemoglobin synthesis; whereas, similar chemical complementation could not be achieved in the Tmem14c-/- cells, which have a primary defect in tetrapyrrole transport. (Fig. C). Our findings reveal that FAM210B is required for optimal mitochondrial iron import during erythroid differentiation for hemoglobin synthesis. It may therefore function as a genetic modifier for mitochondriopathies, anemias or porphyrias. [Display omitted] DisclosuresBauer:Biogen: Research Funding; Editas Medicine: Consultancy. Orkin:Editas Inc.: Consultancy.

Tmem14c Plays An Essential Role In Mitochondrial Heme Metabolism

Red cells synthesize large amounts of heme during terminal differentiation. Central to this process is the transport and trafficking of heme synthesis intermediates within the cell. Despite the importance of transport during heme synthesis, the molecules involved in this process are largely unknown. In a screen for genes that are upregulated during erythroid terminal differentiation, we identified Tmem14c, a predicted multi-pass transmembrane protein as an essential component of the porphyrin metabolism pathway.Here, we report that Tmem14c facilitates the synthesis of mitochondrial protoporphyrin IX from coproporphyrinogen III and is thus required for heme synthesis. Tmem14c is a mitochondrial inner-membrane protein enriched in vertebrate hematopoietic tissues and is required for terminal erythropoiesis. Tmem14c gene-trap mouse embryos are severely anemic and mostly die by E13.5 (Fig. A). Fetal liver erythroid cells derived from gene-trap embryos experience maturation arrest. shRNA silencing of Tmem14c in Friend murine erythroleukemia (MEL) cells results in a significant decrease in de-novo heme synthesis. The biochemical defect is due to a decrease in mitochondrial protoporphyrin IX synthesis, while cytoplasmic porphyrin levels remain normal (Fig. B). The heme synthesis defect in Tmem14c-silenced MEL cells is complemented with a protoporphyrin IX analog. These data show the role of Tmem14c in regulating the terminal steps in mitochondrial porphyrin trafficking. [Display omitted] Our findings collectively demonstrate that Tmem14c is required for the transport of mitochondrial porphyrins in developing erythroid cells. Due to its inner-mitochondrial localization and its relative proximity to heme synthetic enzymes coproporphyrinogen oxidase and protoporphyrinogen oxidase (Rhee et al., 2013 Science), Tmem14c can function as a molecular adaptor that facilitates the interaction of proteins involved in porphyrin transport, or as a protoporphyrinogen IX transporter (Fig. C). The identification of Tmem14c as an essential regulator of porphyrin transport and heme synthesis provides a novel genetic tool for exploring erythropoiesis and disorders of heme synthesis such as porphyria and anemia. Disclosures:No relevant conflicts of interest to declare.

K562 cell proliferation is modulated by PLCβ1 through a PKCα-mediated pathway

Phospholipase C β1 (PLCβ1) is known to play an important role in cell proliferation. Previous studies reported an involvement of PLCβ1 in G0-G1/S transition and G2/M progression in Friend murine erythroleukemia cells (FELC). However, little has been found about its role in human models. Here, we used K562 cell line as human homologous of FELC in order to investigate the possible key regulatory role of PLCβ1 during cell proliferation of this human cell line. Our studies on the effects of the overexpression of both these isoforms showed a specific and positive connection between cyclin D3 and PLCβ1 in K562 cells, which led to a prolonged S phase of the cell cycle and a delay in cell proliferation. In order to shed light on this mechanism, we decided to study the possible involvement of protein kinases C (PKC), known to be direct targets of PLC signaling and important regulators of cell proliferation. Our data showed a peculiar decrease of PKCα levels in cells overexpressing PLCβ1. Moreover, when we silenced PKCα, by RNAi technique, in order to mimic the effects of PLCβ1, we caused the same upregulation of cyclin D3 levels and the same decrease of cell proliferation found in PLCβ1-overexpressing cells. The key features emerging from our studies in K562 cells is that PLCβ1 targets cyclin D3, likely through a PKCα-mediated-pathway, and that, as a downstream effect of its activity, K562 cells undergo an accumulation in the S phase of the cell cycle.

PU.1 is dispensable to block erythroid differentiation in Friend erythroleukemia cells

Friend murine erythroleukemia cell lines derive from erythroblasts transformed with the Friend complex where the spleen-focus forming virus integrated in the vicinity of the Sfpi-1 locus. Erythroleukemia cells do not differentiate and grow indefinitely in the absence of erythropoietin. Activation of the transcription factor PU.1, encoded by the Sfpi-1 gene, is thought to be responsible for the transformed phenotype. These cells can overcome the blockage and reinitiate their differentiation program when exposed to some chemical inducers such as hexamethylene bisacetamide. In this study, we established cell cultures that were capable to proliferate unconstrained in the presence of the inducer. Resistant cell lines restart erythroid differentiation, though, if forced to exit the cell cycle or by overexpressing the transcription factor GATA-1. Unexpectedly, expression of PU.1 was suppressed in the resistant clones albeit the spleen-focus forming virus was still integrated in the proximity of the Sfpi-1 locus. Exposure to 5-Aza-2′-deoxycytidine activates PU.1 expression suggesting that the PU.1 coding gene is highly methylated in the resistant cells. Altogether these results suggest that PU.1 is dispensable to block erythroid differentiation.

A Myb dependent pathway maintains Friend murine erythroleukemia cells in an immature and proliferating state

Friend murine erythroleukemia (MEL) cells are transformed erythroid precursors that are held in an immature and proliferating state but can be induced to differentiate in vivo by treatment with a variety of chemical agents such as N, N-hexamethylene bisacetamide (HMBA). To investigate the role of Myb proteins in maintaining MEL cells in an immature and proliferating state we have produced stable transfectants in the C19 MEL cell line that contain a dominant interfering Myb allele (MEnT) under the control of an inducible mouse metallothionein I promoter. When expression of MEnT protein was induced with ZnCl2, the stable transfectants differentiated with kinetics that were similar to wild type C19 MEL cells treated with HMBA, including induction of alpha-globin mRNA expression, assembly of hemoglobin and growth arrest. Expression of endogenous c-myb and c-myc was also decreased in response to MEnT. Expression of mad-1 mRNA was rapidly increased in response to expression of MEnT resulting in a shift from predominantly c-Myc/Max complexes to predominantly Mad/Max containing complexes. These results strongly suggest that C19 MEL cells are held in an immature and proliferating state by a pathway that is dependent on Myb activity.

A Novel System to Identify Myb Target Promoters in Friend Murine Erythroleukemia Cells

ABSTRACTFriend murine erythroleukemia (MEL) cells provide an early erythroid precursor model that can be induced to terminally differentiate in cell culture and has been used to study erythroid differentiation as well as multistage tumorigenesis. During the chemically induced differentiation of MEL cells, expression of the c-myb protooncogene is downregulated in a biphasic fashion and forced expression of c-myb is able to block the differentiation process, suggesting that c-myb activity may be limiting for differentiation in MEL cells. We have recently produced stable transfectants in the C19 MEL cell line that carry a dominant interfering myb allele (MEnT) under the control of an inducible mouse metallothionein I (MTH) promoter. Upon inducing expression of MEnT, transfected cells enter a differentiation program and begin to produce α-globin mRNA, assemble hemoglobin, and stop proliferating. Differential display was used to compare mRNA expression between parental C19 MEL cells induced to differentiate with hexamethylene bisacetamide (HMBA) and stable transfectants induced to differentiate via expression of MEnT to identify potential Myb target promoters. We identified six candidate cDNAs in this fashion and present evidence that two of these represent genes that are dependent on c-Myb activity for maximal expression in MEL cells.

Phosphatidylinositol-3-kinase activation and atypical protein kinase C ζ phosphorylation characterize the DMSO signalling in erythroleukemia cells

Here we provide evidence for a role of phosphatidylinositol-3-kinase (PI-3-kinase) and for its product phosphatidylinositol-3,4,5-triphosphate (PI3,4,5P3) in the occurrence of the metabolic differentiation state induced by DMSO in murine Friend erythroleukemia cells. Of note, the activation of PI-3-kinase correlated with the modulation of the activation of another enzyme, the atypical protein kinase C ζ (aPKC ζ). In particular, the expression of PI-3-kinase was substantially unaffected by DMSO treatment while its phosphorylation and the production of PI3,4,5P3 was strongly increased within 24 h of DMSO. Such a result was paralleled by an evident phosphorylation of a PKC ζ. Treatment of the cells with the two unrelated PI-3-kinase inhibitors wortmannin and LY 294002 impaired the recovery of the number of differentiated cells, therefore indicating that PI-3-kinase might be involved in the induction of erythroid differentiation, possibly engaging a protein kinase C ζ as downstream effector.

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 χ 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 μM for SAHA), these HPCs cause a χ 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 χ shift on the extracellular side of the cell membrane.

Establishment of an apoptosis-suppressible,cell-cycle arrestable cell line and its applicationfor enhancing protein production of serum-free or-supplemented culture.

Expression of c-jun gene induces apoptosis ofcells cultured in serum-free medium. It also promotescell-cycling in serum-containing medium, leading cellsto die by overgrowth. Previously, we established anapoptosis-suppressible, cell-cycle arrestable cellline, c-jun AS, by transfecting Friend murineerythroleukemia (F-MEL) cells with adexamethasone-inducible antisense c-jun gene.Induction of the antisense c-jun transcriptionwith dexamethasone suppressed c-jun expression.As a result, c-jun AS cells survived inserum-free medium containing dexamethasone for a longtime, while F-MEL cells died quickly in the presenceor absence of dexamethasone. In serum-containingmedium, the growth of c-jun AS cells was viablyblocked by inducing antisense c-juntranscription, and the cells survived at thenon-growth state avoiding overgrowth. In the presentstudy, protein productivity of c-jun AS cellswas examined in comparison with that of wild typeF-MEL cells. C-jun AS and F-MEL cells werefurther transfected with a vector for expressingalkaline phosphatase as a protein to be produced, andnamed c-jun AS-SEAP and F-MEL-SEAP cells,respectively. In the serum-free medium withdexamethasone, c-jun AS-SEAP cells produced theprotein for up to 6 days, while F-MEL-SEAP cellsstopped production on day 3 due to cell death causedby serum deprivation. In the serum-containing mediumwith dexamethasone, c-jun AS-SEAP cells wereviably arrested in the cell cycle, and cell death dueto overgrowth was avoided. As the result, they couldproduce the protein for up to 18 days, whileF-MEL-SEAP cells stopped production within 7 days dueto cell death caused by overgrowth.

Constitutive muscarinic receptors are involved in the growth and differentiation of friend erythroleukemia cells.

Binding experiments with the specific muscarinic ligand [3H]N-methylscopolamine (3H-NMS) have shown the presence of constitutive muscarinic acetylcholine receptors (mAChR) on Friend murine erythroleukemia cells (MELC). Competition experiments with a panel of specific antagonists indicated that the mAChR were predominantly of the M3 subtype. This was confirmed by the rt-PCR analysis of mRNA levels for M1-M5 AChR. Uninduced MELC expressed approximately 2,100 and 1,200 binding sites per cell of growing and resting populations, respectively. The dissociation constant (K(D)) for 3H-NMS was in the picomolar range. The modulation of mAChR upon induction suggested that MELC growth and maturation might be under control of a cholinergic system since mAChR were markedly decreased or virtually absent in MELC induced to terminal division by dimethyl sulfoxide (DMSO) or hexamethylene bisacetamide (HMBA), respectively. In turn, the number of mAChR on MELC committed to polyploidization by colcemid was either increased over or maintained at the control levels when receptor densities were expressed per cell or surface unit (square micrometers), respectively. Moreover, the muscarinic agonist carbachol was found to inhibit MELC differentiation by decreasing by approximately 35% the amount of benzidine-positive (B+) cells in HMBA-induced cultures and, to a lesser degree, also AChE levels. The carbachol effect on erythroid differentiation was reverted by atropine that was found to restore the original amount of B+ cells, while it reduced acetylcholinesterase (AChE) to levels of approximately 66% of control. Such a selective atropine-mediated inhibition of AChE expression was observed also in HMBA-induced MELC supplemented with the antagonist. These results have suggested that mAChR on MELC are functional and might play a role in modulating the expression of either the erythroid or megakaryocytic traits of these cells.

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.

Role of peroxide in AC electrical field exposure effects on Friend murine erythroleukemia cells during dielectrophoretic manipulations

The effects of AC field exposure on the viability and proliferation of mammalian cells under conditions appropriate for their dielectrophoretic manipulation and sorting were investigated using DS19 murine erythroleukemia cells as a model system. The frequency range 100 Hz–10 MHz and medium conductivities of 10 mS/m, 30 mS/m and 56 mS/m were studied for fields generated by applying signals of up to 7V peak to peak (p-p) to a parallel electrode array having equal electrode widths and gaps of 100 μm. Between 1 kHz and 10 MHz, cell viability after up to 40 min of field exposure was found to be above 95% and cells were able to proliferate. However, cell growth lag phase was extended with decreasing field frequency and with increasing voltage, medium conductivity and exposure duration. Modified growth behavior was not passed on to the next cell passage, indicating that field exposure did not cause permanent alterations in cell proliferation characteristics. Cell membrane potentials induced by field exposure were calculated and shown to be well below values typically associated with cell damage. Furthermore, medium treated by field exposure and then added to untreated cells produced the same modifications of growth as exposing cells directly, and these modifications occurred only when the electrode polarization voltage exceeded a threshold of ∼0.4 V p-p. These findings suggested that electrochemical products generated during field exposure were responsible for the changes in cell growth. Finally, it was found that hydrogen peroxide was produced when sugar-containing media were exposed to fields and that normal cell growth could be restored by addition of catalase to the medium, whether or not field exposure occurred in the presence of cells. These results show that AC fields typically used for dielectrophoretic manipulation and sorting of cells do not damage DS19 cells and that cell alterations arising from electrochemical effects can be completely mitigated.

Constitutive and inducible expression of megakaryocyte-specific genes in Friend erythroleukaemia cells.

Friend murine erythroleukaemia cells (MELC) were analysed by semiquantitative RT-PCR for the constitutive and inducible expression of megakaryocyte-specific genes. Uninduced MELC expressed detectable levels of mRNAs for acethylcholinesterase (AChE), platelet factor-4 (PF4), glycoprotein IIb (GPIIb) and von Willebrand factor (VWF), whereas the erythroid alpha- and beta-globin genes were not transcribed appreciably. However, MELC exposed to 5 mM hexamethylene bisacetamide (HMBA) or 1.5% dimethyl sulphoxide (DMSO) seemed to be channelled towards a mixed erythroid/megakaryocytic phenotype characterized by unaltered levels of VWF mRNA, increased levels of AChE, GPIIb and PF4 mRNA. and simultaneous induction of the globin genes. Megakaryocyte-related genes were expressed. in the absence of globin gene transcription, by MELC treated with either phorbol-12-myristate acetate (PMA; 100 ng/ml) or colcemid (40 nM), an antimicrotubule agent capable of promoting polyploidization in this model. Moreover, PMA and colcemid induced also de novo expression of the thrombopoietin receptor c-mpl. PMA and colcemid did not affect high basal c-myb mRNA levels which, in turn, were down-regulated upon HMBA or DMSO induction. Additionally, both uninduced and induced MELC exhibited significant levels of Epo-R and IL-3R mRNAs, whereas no expression of granulocyte/macrophage-related genes was detected. Megakaryocyte gene expression of MELC was also compared to that of other haemopoietic cell populations from normal mice and mice infected with the anaemic strain of the Friend virus. According to our results, MELC should be seen as an unique erythro-megakaryocytic model of differentiation, potentially useful for studying molecular events governing lineage commitment as well as some steps of megakaryocytopoiesis.

NF-E2p18/mafK is required in DMSO-induced differentiation of Friend erythroleukemia cells by enhancing NF-E2 activity.

When Friend murine erythroleukemia (F-MEL) cells are induced to differentiate by dimethylsulfoxide (DMSO), erythroid-specific genes are transcriptionally activated. The erythroid transcription factor NF-E2 is essential for enhancer activity of the globin locus control regions. NF-E2 functions as a heterocomplex consisting of a 45-kDa subunit (NF-E2p45) and a 18-kDa subunit (NF-E2p18). The larger subunit NF-E2p45 is tissue-restricted and is believed to play a role in globin gene expression in F-MEL cells. The expression of the smaller subunit NF-E2p18, which is a Maf family member (MafK), is cell type- and developmental stage-specific. We have investigated the possible role of NF-E2p18 in Friend erythroid differentiation by stably transfecting either sense and antisense p18 constructs into differentiation-sensitive 745A and partially defective-differentiation TFP10 cell lines. Overexpression of NF-E2p18 induced expression of globin transcripts in both cell lines and increased their sensitivity to erythroid differentiation when exposed to DMSO. Conversely, inhibition of p18 expression by antisense transcripts resulted in the inhibition of DMSO-induced differentiation in both cell lines. These results indicate that NF-E2p18 is necessary for globin expression in F-MEL cells and that it is the predominant gene of the Maf family involved in DMSO-induced erythroid differentiation. Moreover F-MEL clones overexpressing NF-E2p18 showed an increase in specific NF-E2 DNA-binding activity whereas this activity was decreased in clones expressing antisense p18. Finally, studies using transient transfection assays showed that p18 activated NF-E2 site-dependent transcription in F-MEL cells. These data suggest that NF-E2p18 can participate in DMSO-induced erythroid differentiation of F-MEL cells by enhancing NF-E2 activity.

Establishing apoptosis resistant cell lines for improving protein productivity of cell culture.

The authors established apoptosis resistant COS-1, myeloma, hybridoma, and Friend leukemia cell lines by genetically engineering cells, aiming at more efficient protein production by cell culture. COS-1 cells, which are most widely used for eukariotic gene expression, were transfected with human bcl-2 gene. Both bcl-2 and mock transfected COS-1 cells were cultured at low (0.2%) serum concentration for 9 days. The final viable cell number of the bcl-2 transfected cells was ninefold of that of the mock transfectants. Both bcl-2 and mock transfectants were further transfected with the vector pcDNA-λ containing SV40 ori and immunoglobulin λ gene for transiently expressing λ protein. The bcl-2 expressing COS-1 cells produced more λ protein than the mock transfected COS-1 cells after 4 days posttransfection.Mouse myeloma p3-X63-Ag.8.653 cells, which are widely used as the partner for preparing hybridoma, and hybridoma 2E3 cells were transfected with human bcl-2 gene. Both bcl-2 transfected myeloma and hybridoma survived longer than the corresponding original cells in batch culture. The bcl-2 transfected 2E3 cells survived 2 to 4 four days longer in culture, producing 1.5- to 4-fold amount of antibody in comparison with the mock transfectants.Coexpression of bag-1 with bcl-2 improved survival of hybridoma 2E3 cells more than bcl-2 expression alone. The bag-1 and bcl-2 coexpressing cells produced more IgG than the the cells expressing bcl-2 alone.Apoptosis of Friend murine erythroleukemia(F-MEL) cells was suppressed with antisense c-jun expression. The antisense c-jun expressing cells survived 16 days at non-growth state.

Conditional inhibition of erythroid differentiation by c-Myb/oestrogen receptor fusion proteins

The c- myb proto-oncogene encodes a transcription factor that has been implicated in the regulation of haemopoietic cell differentiation and appears also to be required for cell proliferation in a number of different lineages. Typically, transcription of c- myb is down-regulated during haemopoietic cell differentiation, and it has been found in several erythroid and myeloid cell lines that constitutive c- myb expression, from a transfected plasmid, blocks this differentiation process. To investigate further the activity of c- myb in haemopoietic cell differentiation, we have transfected Friend murine erythroleukaemia (F-MEL) cells with plasmids encoding conditionally active c-Myb/oestrogen receptor (Myb/ER) fusion proteins. Transcriptional activity of the Myb/ER fusion proteins was found to be strictly hormone-dependent, and this property was correlated with the ability of these proteins to inhibit erythroid differentiation. From analysis of a Myb/ER protein that lacks the c-Myb transactivation domain, it was apparent that the C-terminal ER transactivation domain could substitute for that of c-Myb in inhibition of differentiation. Activation of Myb/ER in F-MEL cells had no effect upon the early and transient inhibition of entry into S phase associated with dimethyl sulfoxide (DMSO) induction. Further analyses of α-globin and PU.1 gene transcription suggested that c-Myb is unable to influence gene expression immediately following DMSO-induction and that inhibition of F-MEL cell differentiation must therefore result from the function of c-Myb in the post-commitment period. Nonetheless, c-Myb had effects on the erythroid differentiation programme that were clearly dissociated from its role in cell proliferation. The potential use of this system to identify c-Myb target genes involved in F-MEL cell differentiation is discussed.

Identification and Conditions for Selective Expression of Megakaryocytic Markers in Friend Erythroleukemia Cells

Friend murine erythroleukemia cells (MELCs) have been reevaluated in terms of their nature and potential pathways of differentiation. MELC induced with 5 mmol/L hexamethylene bisacetamide (HMBA), in addition to expression of known markers of the erythroid phenotype, were also found to exhibit traits of the megakaryocytic lineage. Erythroid differentiation was shown by the typical synthesis and accumulation of hemoglobin (Hb); megakaryoblastoid differentiation of MELCs upon induction was shown by increased specific activity of acetylcholinesterase (AChE). Incubation of MELCs with 5 mmol/L HMBA in RPMI supplemented with 1% fetal calf serum (FCS) (instead of the usual 5%), induced cells to selectively express high levels of AChE (up to approximately 170 mU/mg protein) with little activation of Hb synthesis (less than 5% B+ cells). The increase in AChE levels was a general phenomenon affecting the whole cell population and approached its maximum within 3 days of incubation with the inducer. Subsequently, MELCs become committed to terminal division, undergoing growth arrest and expression of the megakaryocytic phenotype even after the removal of HMBA. There were no appreciable changes of basal AChE levels in MELCs that were either made resistant to HMBA or treated with 0.1 mmol/L hemin that activated differentiated erythroid function without commitment. Phorbol 12-myristate 13-acetate (PMA), known to repress induced Hb synthesis in these cells, did not prevent the full increase in AChE when incubated with MELCs 2 days before HMBA addition. HMBA-induced MELCs always underwent AChE increase that was more or less pronounced depending on the low or high serum content in culture, respectively. Conversely, Hb expression was permitted only when MELCs were transferred in the late phase or at the end of commitment from low to high serum media. Variations of FCS content in culture media proved to be a simple and reliable approach to change the MELC response to inducers and to modulate expression of either megakaryocytic or mixed erythromegakaryocytic phenotype. These findings suggested that MELC might be considered, at least, as a bipotential model of differentiation to be used for studies on regulation of either megakaryocytic or erythroid markers and on competition between the two hematopoietic lineages. In this regard, it was intriguing that AChE levels attained under selective induction (low serum) were always higher than under conditions allowing coexpression of both AChE and Hb (high serum). Moreover, MELCs were also found to bind the specific rat-antimouse platelet monoclonal antibody 4A5.(ABSTRACT TRUNCATED AT 400 WORDS)

Identification and conditions for selective expression of megakaryocytic markers in Friend erythroleukemia cells

Friend murine erythroleukemia cells (MELCs) have been reevaluated in terms of their nature and potential pathways of differentiation. MELC induced with 5 mmol/L hexamethylene bisacetamide (HMBA), in addition to expression of known markers of the erythroid phenotype, were also found to exhibit traits of the megakaryocytic lineage. Erythroid differentiation was shown by the typical synthesis and accumulation of hemoglobin (Hb); megakaryoblastoid differentiation of MELCs upon induction was shown by increased specific activity of acetylcholinesterase (AChE). Incubation of MELCs with 5 mmol/L HMBA in RPMI supplemented with 1% fetal calf serum (FCS) (instead of the usual 5%), induced cells to selectively express high levels of AChE (up to approximately 170 mU/mg protein) with little activation of Hb synthesis (less than 5% B+ cells). The increase in AChE levels was a general phenomenon affecting the whole cell population and approached its maximum within 3 days of incubation with the inducer. Subsequently, MELCs become committed to terminal division, undergoing growth arrest and expression of the megakaryocytic phenotype even after the removal of HMBA. There were no appreciable changes of basal AChE levels in MELCs that were either made resistant to HMBA or treated with 0.1 mmol/L hemin that activated differentiated erythroid function without commitment. Phorbol 12-myristate 13-acetate (PMA), known to repress induced Hb synthesis in these cells, did not prevent the full increase in AChE when incubated with MELCs 2 days before HMBA addition. HMBA-induced MELCs always underwent AChE increase that was more or less pronounced depending on the low or high serum content in culture, respectively. Conversely, Hb expression was permitted only when MELCs were transferred in the late phase or at the end of commitment from low to high serum media. Variations of FCS content in culture media proved to be a simple and reliable approach to change the MELC response to inducers and to modulate expression of either megakaryocytic or mixed erythromegakaryocytic phenotype. These findings suggested that MELC might be considered, at least, as a bipotential model of differentiation to be used for studies on regulation of either megakaryocytic or erythroid markers and on competition between the two hematopoietic lineages. In this regard, it was intriguing that AChE levels attained under selective induction (low serum) were always higher than under conditions allowing coexpression of both AChE and Hb (high serum). Moreover, MELCs were also found to bind the specific rat-antimouse platelet monoclonal antibody 4A5.(ABSTRACT TRUNCATED AT 400 WORDS)

Protein kinase C beta from Friend erythroleukemia cells is associated with chromatin and DNA.

Certain protein kinase C (PKC) isotypes are localized to the nucleus during cellular proliferation in murine erythroid cells, as well as in human promyelocytic leukemia and erythroleukemia cells. Because the structure of these PKC isotypes contains a conserved cysteine-rich region that contains the zinc finger DNA binding motif, we tested the hypothesis that selected PKC isotypes found in Friend erythroleukemia cells can bind to DNA. Cell lysates from murine Friend erythroleukemia cells, which express alpha, beta I, and beta II PKC, expressed greater amounts of the beta isoforms than the alpha isoform of PKC in their nuclei, and PKC beta I was found in the chromatin of these cells. Lysates of these cells were tested for their ability to bind to a DNA-cellulose column. Bound proteins were eluted with a step gradient of increasing KCl concentrations, and eluant fractions were then subjected to immunoblot analysis using isotype-specific antibodies to the alpha and beta I isotypes of PKC. DNA binding was detected for the PKC beta I isotype, which is present in the nucleus, but not for the more abundant PKC alpha isotype, which resides primarily in the cytoplasm. These results demonstrate that PKC can associate with DNA, and that this association is isotype specific in Friend erythroleukemia cells.