Biphasic ordered induction of heme synthesis in differentiating murine erythroleukemia cells: role of erythroid 5-aminolevulinate synthase.

During dimethyl sulfoxide (DMSO)-stimulated differentiation of murine erythroleukemia (MEL) cells, one of the early events is the induction of the heme biosynthetic pathway. While recent reports have clearly demonstrated that GATA-1 is involved in the induction of erythroid cell-specific forms of 5-aminolevulinate synthase (ALAS-2) and porphobilinogen (PBG) deaminase and that cellular iron status plays a regulatory role for ALAS-2, little is known about regulation of the remainder of the pathway. In the current study, we have made use of a stable MEL cell mutant (MEAN-1) in which ALAS-2 enzyme activity is not induced by DMSO, hexamethylene bisacetamide (HMBA), or butyric acid. In this cell line, addition of 2% DMSO to growing cultures results in the normal induction of PBG deaminase and coproporphyrinogen oxidase but not in the induction of the terminal two enzymes, protoporphyrinogen oxidase and ferrochelatase. These DMSO-treated cells did not produce mRNA for beta-globin and do not terminally differentiate. In addition, the cellular level of ALAS activity declines rapidly after addition of DMSO, indicating that ALAS-1 must turn over rapidly at this time. Addition of 75 microM hemin alone to the cultures did not induce cells to terminally differentiate or induce any of the pathway enzymes. However, the simultaneous addition of 2% DMSO and 75 microM hemin caused the cells to carry out a normal program of terminal erythroid differentiation, including the induction of ferrochelatase and beta-globin. These data suggest that induction of the entire heme biosynthetic pathway is biphasic in nature and that induction of the terminal enzymes may be mediated by the end product of the pathway, heme. We have introduced mouse ALAS-2 cDNA into the ALAS-2 mutant cell line (MEAN-1) under the control of the mouse metallothionein promoter (MEAN-RA). When Cd and Zn are added to cultures of MEAN-RA in the absence of DMSO, ALAS-2 is induced but erythroid differentiation does not occur and cells continue to grow normally. In the presence of metallothionein inducers and DMSO, the MEAN-RA cells induce in a fashion similar to that found with the wild-type 270 MEL cells. Induction of the activities of ALAS, PBG deaminase, coproporphyrinogen oxidase, and ferrochelatase occurs. In cultures of MEAN-RA where ALAS-2 had been induced with Cd plus Zn 24 h prior to DMSO addition, onset of heme synthesis occurs more rapidly than when DMSO and Cd plus Zn are added simultaneously. This study reveals that induction of ALAS-2 alone is not sufficient to induce terminal differentiation of the MEAN-RA cells, and it does not appear that ALAS-2 alone is the rate-limiting enzyme of the heme biosynthetic pathway during MEL cell differentiation.     

Relationships between the cell cycle and the expression of c-myc and transferrin receptor genes during induced myeloid differentiation

We examined the relationship of cellular oncogene c-myc and transferrin receptor (TfR) gene expression to cell proliferation and cell cycle progression during myeloid differentiation in the HL-60 myeloid leukemia cell line. In order to determine levels of mRNA for these genes in HL-60 cells induced to differentiate along the myeloid pathway, RNA was isolated from HL-60 cells incubated with retinoic acid for 24 h and Northern blots were probed with labeled cDNAs for c-myc and TfR. c-myc mRNA decreased within 3 h of retinoic acid addition, and TfR mRNA decreased after 9 h; both mRNAs continued to decrease over 24 h. RNA was also isolated from HL-60 cells separated by centrifugal elutriation into cell cycle phases. TfR and c-myc cDNA probes hybridized equally to RNA from uninduced cells in all phases of the cell cycle. However, after 24 h incubation with the differentiation inducer retinoic acid, TfR mRNA was expressed substantially less in the G1 stage, whereas c-myc mRNA was still expressed equally in all cell cycle phases. These data indicate that, although TfR and c-myc expression are both associated with cell proliferation in the HL-60 line, TfR is down-regulated specifically in G1 upon induction of terminal differentiation whereas c-myc expression is disassociated from cell cycle control in these cells.     

Induction of apoptosis in fibroblasts by c-myc protein.

Although Rat-1 fibroblasts expressing c-myc constitutively are unable to arrest growth in low serum, their numbers do not increase in culture because of substantial cell death. We show this cell death to be dependent upon expression of c-myc protein and to occur by apoptosis. Regions of the c-myc protein required for induction of apoptosis overlap with regions necessary for cotransformation, autoregulation, and inhibition of differentiation, suggesting that the apoptotic function of c-myc protein is related to its other functions. Moreover, cells with higher levels of c-myc protein are more prone to cell death upon serum deprivation. Finally, we demonstrate that deregulated c-myc expression induces apoptosis in cells growth arrested by a variety of means and at various points in the cell cycle.     

Forskolin对放射性转化细胞TGF基因及部分癌基因表达的影响

3~H-TdR放射性转化细胞(TC3H/10)经1×10~(-5)mol/L Foskolin处理24 h后,TGFα、c-myc、c-K-ras基因的mRNA表达下降,TGFβ、c-fos基因表达无明显变化。非转化细胞(NC3H/10)经相同条件处理,TGFα、TGFβ、c-myc及c-K-ras基因表达无显著改变。提示:Forskolin介导的转化细胞的生长抑制作用与TGFa、cmyc、c-K-ras基因的转录表达下降有关。     

Flow cytometric correlation of the c-myc oncoprotein and cell cycle kinetics of HL60 leukaemia during induced maturation with cytosine arabinoside and dimethylsulphoxide

The c-myc oncogene codes for a DNA binding protein that functions in a cell cycle-related manner. A useful model for studying the relationship of c-myc expression with cell cycle kinetics is the HL60 cell line. HL60 cells constitutively express high levels of c-myc mRNA; however, the level can be down-regulated as the cells are induced to differentiate. We have developed a flow cytometric assay for correlating c-myc oncoprotein levels with DNA content. C-myc oncoprotein levels were additionally correlated with c-myc mRNA levels as determined by slot blot hybridization. Dimethylsulphoxide (DMSO) and cytosine arabinoside were used to induce granulocytic and monocytic maturation respectively. Treatment of HL60 cells with DMSO leads to an increase in the per cent of cells in G1/G0 and a decrease in mean c-myc mRNA and oncoprotein levels. The cells with G1 DNA content show the greatest decrease in c-myc protein. ARA-c treatment of HL60 cells leads to a slowing and an accumulation of cells in S phase with a moderate decrease in mean mRNA and only a slight decrease in mean c-myc protein levels. These data support the hypothesis that c-myc is involved in the switch from G1 to G0.     

Autocrine beta-related interferon controls c-myc suppression and growth arrest during hematopoietic cell differentiation

Different hematopoietic cells produce minute amounts of beta-related interferon (IFN) following induction of differentiation by chemical or natural inducers. The endogenous IFN binds to type I cell surface receptors and modulates gene expression in the producer cells. We show that self-induction of two members of the IFN-induced gene family differs in the dose response sensitivity and the prolonged kinetics of mRNA accumulation from the response to exogenous IFN-beta 1. Production and response to endogenous IFN are also detected when bone marrow precursor cells differentiate to macrophages after exposure to colony stimulating factor 1. In M1 myeloid cells induced to differentiate by lung-conditioned medium, addition of antibodies against IFN-beta partially abrogates the reduction of c-myc mRNA and the loss in cell proliferative activity, which both occur during differentiation. The endogenous IFN therefore functions as an autocrine growth inhibitor that participates in controlling c-myc suppression and the specific G0/G1 arrest during terminal differentiation of hematopoietic cells.     

Terminal Myeloid Differentiation is Uncoupled from Cell Cycle Arrest

It has been assumed that terminal myeloid differentiation and cell cycle arrest are coupled processes, and that prohibiting cell cycle arrest blocks differentiation. Previously we have shown that, using the murine M1 myeloid leukemic cell line, deregulated expression of the proto-oncogene c-myc results in cells that cannot be induced to undergo terminal differentiation and continued to proliferate. It has also been shown that ectopic expression of Egr-1 abrogated the c-Myc block in terminal myeloid differentiation, yet there was no accumulation of cells in the G0/G1 phase of the cell cycle. In this study we conclusively demonstrate that M1Myc/Egr-1 cells terminally differentiate while still actively cycling and synthesizing DNA, concluding that the terminal myeloid differentiation program is uncoupled from growth arrest. How deregulated expression/activation of proto-oncogenes that promote cell cycle progression interferes with differentiation and how differentiation is regulated independently of cell cycle control are discussed, as well as the implications with regard to differentiation therapy.