The molecular regulators of macrophage and granulocyte development. Role of MGI-2/IL-6

The development of a cell culture system for the in vitro cloning and clonal differentiation of normal hematopoietic cells made it possible to identify the proteins that regulate growth and differentiation of different hematopoietic cell lineages and the change in normal controls that produce leukemia. A model system with myeloid cells has identified different myeloid cell colony-inducing proteins, which we called MGI-1 (= CSF, including IL-3). There is another protein that we first described in 1976 and called MGI-2 in 1980 that induces differentiation of myeloid cells to macrophages or granulocytes without inducing the clonal growth of myeloid cells. The four CSF proteins and IL-1 induce the production of MGI-2 in myeloid cells and MGI-2 induces the production of GM-CSF. This shows the participation of MGI-2 in the network of interactions with different myeloid regulatory proteins. Using a monoclonal antibody to MGI-2, amino acid sequencing, and recombinant protein, we have shown in collaboration with the Genetics Institute that the major form of MGI-2 (MGI-2A) is IL-6. This shows that IL-6 is a myeloid cell differentiation inducing protein. The results also suggest new clinical potentials for MGI-2/IL-6.

Regulation of leukaemic cells by interleukin 6 and leukaemia inhibitory factor

Interleukin 6 (IL-6) and leukaemia inhibitory factor (LIF) can have pleiotropic effects on different cell types. M1 myeloid leukaemic cells respond to IL-6 with activation of a terminal differentiation programme which includes activation of genes for certain haemopoietic regulatory proteins (IL-6, IL-1 alpha, IL-1 beta, granulocyte-macrophage colony-stimulating factor [GM-CSF], M-CSF, tumour necrosis factor and transforming growth factor [TGF] beta 1) and for receptors for some of these proteins, thus establishing a network of positive and negative regulatory cytokines. IL-6 and some other cytokines also induce during differentiation sustained levels of transcription factors that can regulate and maintain gene expression in the differentiation programme. M1 leukaemic cells induced to differentiate with IL-6 undergo programmed cell death (apoptosis) on withdrawal of IL-6, and can be rescued from apoptosis by IL-6, IL-3, M-CSF, G-CSF or IL-1, but not by GM-CSF. These differentiating leukaemic cells can also be rescued from apoptosis by the tumour promoter TPA (12-O-tetradecanoylphorbol-13-acetate) but not by the non-tumour-promoting isomer 4-alpha-TPA, and rescue from apoptosis can be achieved by different pathways. Apoptosis can also be induced in undifferentiated M1 leukaemic cells by expression of the wild-type form of the tumour suppressor p53 protein and IL-6 can rescue the cells from this wild-type p53-mediated apoptosis. There are clones of M1 cells that differentiate with IL-6 but not with LIF and another M1 clone that differentiates with either IL-6 or LIF. Differentiation induced by IL-6 or LIF is inhibited by TGF-beta 1. The pleiotropic effects of LIF, like those of IL-6, are presumably also in a network of interacting regulatory proteins.

Epigenetics and the plasticity of differentiation in normal and cancer stem cells

Embryonic stem cells are characterized by their differentiation to all cell types during embryogenesis. In adult life, different tissues also have somatic stem cells, called adult stem cells, which in specific niches can undergo multipotent differentiation. The use of these adult stem cells has considerable therapeutic potential for the regeneration of damaged tissues. In both embryonic and adult stem cells, differentiation is controlled by epigenetic mechanisms, and the plasticity of differentiation in these cells is associated with transcription accessibility for genes expressed in different normal tissues. Abnormalities in genetic and/or epigenetic controls can lead to development of cancer, which is maintained by self-renewing cancer stem cells. Although the genetic abnormalities produce defects in growth and differentiation in cancer stem cells, these cells have not always lost the ability to undergo differentiation through epigenetic changes that by-pass the genomic abnormalities, thus creating the basis for differentiation therapy. Like normal stem cells, cancer stem cells can show plasticity for differentiation. This plasticity of cancer stem cells is also associated with transcription accessibility for genes that are normally expressed in different tissues, including tissues other than those from which the cancers originated. This broad transcription accessibility can also contribute to the behavior of cancer cells by overexpressing genes that promote cell viability, growth and metastasis.

Cytokines as suppressors of apoptosis

Many cytokines have been isolated by their ability to induce growth and have been called growth factors. But these cytokines are also essential to induce cell viability, and cell viability and growth can be separately regulated. Using as examples myeloid hematopoietic cells, lymphocytes and neuronal cells, in vitro and in vivo studies have shown the role of cytokines in inducing viability of different cell types during development to mature cells. Some cytokines can act on more than one cell type. Cytokines induce viability of normal and cancer cells by suppressing the apoptotic machinery activated by wild-type p53, or by cytotoxic agents including irradiation and compounds used in cancer chemotherapy. Cytokines can be used to decrease apoptosis in normal cells and inhibition of cytokine activity may improve cancer therapy by enhancing apoptosis in cancer cells. The apoptosis suppressing function of cytokines is mediated by changing the balance in the activity of apoptosis inducing and suppressing genes. Apoptosis suppression is upstream of caspase activation in the apoptotic process. Cytokines can suppress multiple pathways leading to apoptosis, only some of which were suppressed by other agents such as some antioxidants, Ca(2+)-mobilizing compounds and protease inhibitors.

Spatial and temporal expression pattern of Runx3 (Aml2) and Runx1 (Aml1) indicates non-redundant functions during mouse embryogenesis

The human RUNX3/AML2 gene belongs to the 'runt domain' family of transcription factors that act as gene expression regulators in major developmental pathways. Here, we describe the expression pattern of Runx3 during mouse embryogenesis compared to the expression pattern of Runx1. E10.5 and E14.5-E16.5 embryos were analyzed using both immunohistochemistry and beta-galactosidase activity of targeted Runx3 and Runx1 loci. We found that Runx3 expression overlapped with that of Runx1 in the hematopoietic system, whereas in sensory ganglia, epidermal appendages, and developing skeletal elements, their expression was confined to different compartments. These data provide new insights into the function of Runx3 and Runx1 in organogenesis and support the possibility that cross-regulation between them plays a role in embryogenesis.

The RUNX3 gene--sequence, structure and regulated expression

The RUNX3 gene belongs to the runt domain family of transcription factors that act as master regulators of gene expression in major developmental pathways. In mammals the family includes three genes, RUNX1, RUNX2 and RUNX3. Here, we describe a comparative analysis of the human chromosome 1p36.1 encoded RUNX3 and mouse chromosome 4 encoded Runx3 genomic regions. The analysis revealed high similarities between the two genes in the overall size and organization and showed that RUNX3/Runx3 is the smallest in the family, but nevertheless exhibits all the structural elements characterizing the RUNX family. It also revealed that RUNX3/Runx3 bears a high content of the ancient mammalian repeat MIR. Together, these data delineate RUNX3/Runx3 as the evolutionary founder of the mammalian RUNX family. Detailed sequence analysis placed the two genes at a GC-rich H3 isochore with a sharp transition of GC content between the gene sequence and the downstream intergenic region. Two large conserved CpG islands were found within both genes, one around exon 2 and the other at the beginning of exon 6. RUNX1, RUNX2 and RUNX3 gene products bind to the same DNA motif, hence their temporal and spatial expression during development should be tightly regulated. Structure/function analysis showed that two promoter regions, designated P1 and P2, regulate RUNX3 expression in a cell type-specific manner. Transfection experiments demonstrated that both promoters were highly active in the GM1500 B-cell line, which endogenously expresses RUNX3, but were inactive in the K562 myeloid cell line, which does not express RUNX3.

Regulation of p53 stability and p53-dependent apoptosis by NADH quinone oxidoreductase 1

The tumor suppressor gene wild-type p53 encodes a labile protein that accumulates in cells after different stress signals and can cause either growth arrest or apoptosis. One of the p53 target genes, p53-inducible gene 3 (PIG3), encodes a protein with significant homology to oxidoreductases, enzymes involved in cellular responses to oxidative stress and irradiation. This fact raised the possibility that cellular oxidation-reduction events controlled by such enzymes also may regulate the level of p53. Here we show that NADH quinone oxidoreductase 1 (NQO1) regulates p53 stability. The NQO1 inhibitor dicoumarol caused a reduction in the level of both endogenous and gamma-irradiation-induced p53 in HCT116 human colon carcinoma cells. This reduction was prevented by the proteasome inhibitors MG132 and lactacystin, suggesting enhanced p53 degradation in the presence of dicoumarol. Dicoumarol-induced degradation of p53 also was prevented in the presence of simian virus 40 large T antigen, which is known to bind and to stabilize p53. Cells overexpressing NQO1 were resistant to dicoumarol, and this finding indicates the direct involvement of NQO1 in p53 stabilization. NQO1 inhibition induced p53 degradation and blocked wild-type p53-mediated apoptosis in gamma-irradiated normal thymocytes and in M1 myeloid leukemic cells that overexpress wild-type p53. Dicoumarol also reduced the level of p53 in its mutant form in M1 cells. The results indicate that NQO1 plays an important role in regulating p53 functions by inhibiting its degradation.

Suppression or induction of apoptosis by opposing pathways downstream from calcium-activated calcineurin

Ca(2+)-mobilizing compounds such as the Ca(2+) ionophore A23187 or the endoplasmic reticulum Ca(2+) ATPase inhibitor thapsigargin can suppress or induce apoptosis in the same cells. The use of different calcineurin inhibitors has shown that both suppression and induction of apoptosis by the Ca(2+)-mobilizing compounds were mediated by calcineurin activation. Ca(2+)-mobilizing compounds activated p38 and p44/42 mitogen-activated protein kinases (MAPKs). Induction of apoptosis by the Ca(2+)-mobilizing compounds was suppressed by an inhibitor of p38 MAPK but not by an inhibitor of p44/42 MAPK. These MAPK inhibitors did not suppress apoptosis induction by wild-type p53 or by withdrawal of IL-6 from IL-6-dependent cells that are mediated by calcineurin-independent pathways. These MAPK inhibitors also did not affect the ability of Ca(2+)-mobilizing compounds to suppress apoptosis. The results indicate that (i) Ca(2+)- mobilizing compounds activate different and opposing pathways that diverge downstream from calcineurin activation that can either suppress or induce apoptosis in the same cells; (ii) p38 MAPK but not p44/42 MAPK is involved in induction of apoptosis but not in its suppression by the Ca(2+)-mobilizing compounds; and (iii) neither p38 nor p44/42 MAPKs mediate induction of apoptosis by some calcineurin-independent pathways.

Expression of AML1-d, a short human AML1 isoform, in embryonic stem cells suppresses in vivo tumor growth and differentiation

The human AML1 gene encodes a heterodimeric transcription factor which plays an important role in mammalian hematopoiesis. Several alternatively spliced AML1 mRNA species were identified, some of which encode short protein products that lack the transactivation domain. When transfected into cells these short isoforms dominantly suppress transactivation mediated by the full length AML1 protein. However, their biological function remains obscure. To investigate the role of these short species in cell proliferation and differentiation we generated embryonic stem (ES) cells overexpressing one of the short isoforms, AML1-d, as well as cells expressing the full length isoforms AML1-b and AML2. The in vitro growth rate and differentiation of the transfected ES cells were unchanged. However, overexpression of AML1-d significantly affected the ES cells' ability to form teratocarcinomas in vivo in syngeneic mice, while a similar overexpression of AML1-b and AML2 had no effect on tumor formation. Histological analysis revealed that the AML1-d derived tumors were poorly differentiated and contained numerous apoptotic cells. These data highlight the pleiotropic effects of AML1 gene products and demonstrate for the first time an in vivo growth regulation function for the short isoform AML1-d.

Different mechanisms for suppression of apoptosis by cytokines and calcium mobilizing compounds

Overexpression of wild-type p53 in M1 myeloid leukemia cells induces apoptotic cell death that was suppressed by the calcium ionophore A23187 and the calcium ATPase inhibitor thapsigargin (TG). This suppression of apoptosis by A23187 or TG was associated with suppression of caspase activation but not with suppression of wild-type-p53-induced expression of WAF-1, mdm-2, or FAS. In contrast to suppression of apoptosis by the cytokines interleukin 6 (IL-6) and interferon gamma, a protease inhibitor, or an antioxidant, suppression of apoptosis by A23187 or TG required extracellular Ca2+ and was specifically abolished by the calcineurin inhibitor cyclosporin A. IL-6 induced immediate early activation of junB and zif/268 (Egr-1) but A23187 and TG did not. A23187 and TG also suppressed induction of apoptosis by doxorubicin or vincristine in M1 cells that did not express p53 by a cyclosporin A-sensitive mechanism. Suppression of apoptosis by A23187 or TG was not associated with autocrine production of IL-6. Apoptosis induced in IL-6-primed M1 cells after IL-6 withdrawal was not suppressed by A23187 or TG but was suppressed by the cytokines IL-6, IL-3, or interferon gamma. The results indicate that these Ca2+-mobilizing compounds can suppress some pathways of apoptosis suppressed by cytokines but do so by a different mechanism.

Cytokine suppression of protease activation in wild-type p53-dependent and p53-independent apoptosis

M1 myeloid leukemic cells overexpressing wild-type p53 undergo apoptosis. This apoptosis can be suppressed by some cytokines, protease inhibitors, and antioxidants. We now show that induction of apoptosis by overexpressing wild-type p53 is associated with activation of interleukin-1beta-converting enzyme (ICE)-like proteases, resulting in cleavage of poly(ADP- ribose) polymerase and the proenzyme of the ICE-like protease Nedd-2. Activation of these proteases and apoptosis were suppressed by the cytokine interleukin 6 or by a combination of the cytokine interferon gamma and the antioxidant butylated hydroxyanisole, and activation of poly(ADP-ribose) polymerase and apoptosis were suppressed by some protease inhibitors. In a clone of M1 cells that did not express p53, vincristine or doxorubicin induced protease activation and apoptosis that were not suppressed by protease inhibitors, but were suppressed by interleukin 6. In another myeloid leukemia (7-M12) doxorubicin also induced protease activation and apoptosis that were not suppressed by protease inhibitors, but were suppressed by granulocyte-macrophage colony-stimulating factor. The results indicate that (i) overexpression of wild-type p53 by itself or treatment with cytotoxic compounds in wild-type p53-expressing or p53-nonexpressing myeloid leukemic cells is associated with activation of ICE-like proteases; (ii) cytokines exert apoptosis-suppressing functions upstream of protease activation; (iii) the cytotoxic compounds induce additional pathways in apoptosis; and (iv) cytokines can also suppress these other components of the apoptotic machinery.

Oxidative stress mediates impairment of muscle function in transgenic mice with elevated level of wild-type Cu/Zn superoxide dismutase

Cases of familial amyotrophic lateral sclerosis (fALS; a neurodegenerative disorder) have been reported in which the gene for Cu/Zn superoxide dismutase (CuZnSOD) was mutated. Several studies with the fALS mutant CuZnSOD in transgenic mice and cells showed that the fALS mutations act through an as yet undefined dominant gain-of-function mechanism. Wild-type CuZnSOD catalyzes the dismutation of superoxide (O(2)(-).) but also produces hydroxyl radicals (.OH) with H(2)O(2) as substrate. Two laboratories have recently demonstrated that the .OH production ability was preferentially enhanced by the fALS mutant CuZnSOD, suggesting that this might be the function gained in fALS. In this study, we used transgenic CuZnSOD (Tg-CuZnSOD) mice with elevated levels of CuZnSOD to determine whether overexpression of wild-type CuZnSOD was also associated with increased .OH production and impaired muscle function. Enhanced formation of .OH was detected, by spin trapping, in brain and muscle extracts of the Tg-CuZnSOD mice. Three independently derived Tg-CuZnSOD lines showed muscle abnormalities, reflected by altered electromyography (EMG) and diminished performance in the rope grip test. After treatment with paraquat (PQ), a widely used herbicide and O(2)(-).-generating compound, muscle disability significantly deteriorated in Tg-CuZnSOD mice but not in control mice. The results indicate that elevated levels of CuZnSOD cause indigenous long-term oxidative stress leading to impairment of muscle function. These findings may provide valuable clues about the concurred role of indigenous oxidative stress and exogenous agents in the etiology of sporadic ALS and several other neurodegenerative diseases in which a specific subset of neurons is affected.

Differential suppression by protease inhibitors and cytokines of apoptosis induced by wild-type p53 and cytotoxic agents

Apoptosis induced in myeloid leukemic cells by wild-type p53 was suppressed by different cleavage-site directed protease inhibitors, which inhibit interleukin-1 beta-converting enzyme-like, granzyme B and cathepsins B and L proteases. Apoptosis was also suppressed by the serine and cysteine protease inhibitor N-tosyl-L-phenylalanine chloromethylketone (TPCK) [corrected], but not by other serine or cysteine protease inhibitors including N alpha-p-tosyl-L-lysine chloromethylketone (TLCK), E64, pepstatin A, or chymostatin. Protease inhibitors suppressed induction of apoptosis by gamma-irradiation and cycloheximide but not by doxorubicin, vincristine, or withdrawal of interleukin 3 from interleukin 3-dependent 32D non-malignant myeloid cells. Induction of apoptosis in normal thymocytes by gamma-irradiation or dexamethasone was also suppressed by the cleavage-site directed protease inhibitors, but in contrast to the myeloid leukemic cells apoptosis in thymocytes was suppressed by TLCK but not by TPCK. The results indicate that (i) inhibitors of interleukin-1 beta-converting enzyme-like proteases and some other protease inhibitors suppressed induction of apoptosis by wild-type p53 and certain p53-independent pathways of apoptosis; (ii) the protease inhibitors together with the cytokines interleukin 6 and interferon-gamma or the antioxidant butylated hydroxyanisole gave a cooperative protection against apoptosis; (iii) these protease inhibitors did not suppress induction of apoptosis by some cytotoxic agents or by viability-factor withdrawal from 32D cells, whereas these pathways of apoptosis were suppressed by cytokines; (iv) there are cell type differences in the proteases involved in apoptosis; and (v) there are multiple pathways leading to apoptosis that can be selectively induced and suppressed by different agents.

Cellular oxidative stress and the control of apoptosis by wild-type p53, cytotoxic compounds, and cytokines

Apoptosis induced by wild-type p53 or cytotoxic compounds in myeloid leukemic cells can be inhibited by the cytokines interleukin 6, interleukin 3, granulocyte-macrophage colony-stimulating factor, and interferon gamma and by antioxidants. The antioxidants and cytokines showed a cooperative protective effect against induction of apoptosis. Cells with a higher intrinsic level of peroxide production showed a higher sensitivity to induction of apoptosis and required a higher cytokine concentration to inhibit apoptosis. Decreasing the intrinsic oxidative stress in cells by antioxidants thus inhibited apoptosis, whereas increasing this intrinsic stress by adding H2O2 enhanced apoptosis. Induction of apoptosis by wild-type p53 was not preceded by increased peroxide production or lipid peroxidation and the protective effect of cytokines was not associated with a decrease in these properties. The results indicate that the intrinsic degree of oxidative stress can regulate cell susceptibility to wild-type p53-dependent and p53-independent induction of apoptosis and the ability of cytokines to protect cells against apoptosis.

Control of apoptosis in hematopoiesis and leukemia by cytokines, tumor suppressor and oncogenes

Hematopoietic cells require certain cytokines including colony-stimulating factors and interleukins to maintain viability. Without these cytokines the program of apoptotic cell death is activated. Cells from many myeloid leukemias require cytokines for viability, and apoptosis is also activated in these leukemic cells after cytokine withdrawal resulting in reduced leukemogenicity. The same cytokines protect normal and leukemic cells from induction of apoptosis by irradiation and cytotoxic chemotherapeutic compounds. This suggests that decreasing the levels of viability inducing cytokines may increase the effectiveness of cytotoxic anti-cancer therapy. The susceptibility of normal and cancer cells to induction of apoptosis is also regulated by the balance between apoptosis-inducing genes such as the tumor suppressor wild-type p53, and c-myc and bax, and apoptosis-suppressing genes such as the oncogene mutant p53, and bcl-2 and bcl-XL. Cell susceptibility to induction of apoptosis in leukemic cells could be enhanced by increased expression of apoptosis-inducing genes and/or decreased expression of apoptosis-suppressing genes. Modulation of expression of apoptosis-regulating genes should thus also be useful for improvement of anti-cancer therapy.

A large variety of alternatively spliced and differentially expressed mRNAs are encoded by the human acute myeloid leukemia gene AML1

The human chromosome 21 acute myeloid leukemia gene AML1 is frequently rearranged in the leukemia-associated translocations t(8;21) and t(3;21), generating fused proteins containing the amino-terminal part of AML1. In normal blood cells, five size classes (2-8 kb) of AML1 mRNAs have been previously observed. We isolated seven cDNAs corresponding to various AML1 mRNAs. Sequencing revealed that their size differences were mainly due to alternatively spliced 5' and 3' untranslated regions, some of which were vast, exceeding 1.5 kb (5') and 4.3 kb (3'). These untranslated regions contain sequences known to control mRNA translation and stability and seem to modulate AML1 mRNA stability. Further heterogeneity was found in the coding region due to the presence of alternatively spliced stop codon-containing exons. The latter led to production of polypeptides that were smaller than the full-length AML1 protein; they lacked the trans-activation domains but maintained DNA binding and heterodimerization ability. The size of these truncated products was similar to the AML1 segment in the fused t(8;21) and t(3;21) proteins. In thymus, only one mRNA species of 6 kb was detected. Using in situ hybridization, we showed that its expression was confined to the cortical region of the organ. The 6-kb mRNA was also prominent in cultured peripheral blood T cells, and its expression was markedly reduced upon mitogenic activation by phorbol myristate acetate (TPA) plus concanavalin A (ConA). These results and the presence of multiple coding regions flanked by long complex untranslated regions, suggest that AML1 expression is regulated at different levels by several control mechanisms generating the large variety of mRNAs and protein products.

Protection of human myeloid leukemic cells against doxorubicin-induced apoptosis by granulocyte-macrophage colony-stimulating factor and interleukin 3

Hematopoietic cells require certain cytokines to maintain viability by preventing apoptotic cell death. These cytokines can also protect leukemic cell lines against induction of apoptosis by cytotoxic anticancer compounds. We now show that the cytokines granulocyte-macrophage colony-stimulating factor and interleukin 3 can protect primary human myeloid leukemic cells against doxorubicin-induced apoptosis. Protection was detected in cells from 72% of the myeloid leukemic patients tested. The results indicate that these, and perhaps other, hematopoietic cytokines can decrease the effectiveness of cytotoxic anticancer therapy in some human myeloid leukemias. Leukemic cell sensitization to cytotoxic therapy may, therefore, require decreasing the availability of certain cytokines.

Thymic abnormalities and enhanced apoptosis of thymocytes and bone marrow cells in transgenic mice overexpressing Cu/Zn-superoxide dismutase: implications for Down syndrome

The copper-zinc superoxide dismutase (CuZnSOD) gene resides on chromosome 21 and is overexpressed in Down syndrome (DS) patients. Transgenic CuZnSOD mice with elevated levels of CuZnSOD were used to determine whether, as in DS, overexpression of CuZnSOD was also associated with thymus and bone marrow abnormalities. Three independently derived transgenic CuZnSOD strains had abnormal thymi showing diminution of the cortex and loss of corticomedullary demarcation, resembling thymic defects in children with DS. Transgenic CuZnSOD mice were also more sensitive than control mice to in vivo injection of lipopolysaccharide (LPS), reflected by an earlier onset and enhanced apoptotic cell death in the thymus. This higher susceptibility to LPS-induced apoptosis was associated with an increased production of hydrogen peroxide and a higher degree of lipid peroxidation. When cultured under suboptimal concentrations of interleukin 3 or in the presence of tumour necrosis factor, bone marrow cells from transgenic CuZnSOD mice produced 2- to 3-fold less granulocyte and macrophage colonies than control. The results indicate that transgenic CuZnSOD mice have certain thymus and bone marrow abnormalities which are similar to those found in DS patients, and that the defects are presumably due to an increased oxidative damage resulting in enhanced cell death by apoptosis.

A mutant p53 antagonizes the deregulated c-myc-mediated enhancement of apoptosis and decrease in leukemogenicity

Myeloid leukemic M1 cells that do not express p53 and transfected M1 clones that constitutively express the [Val135]p53 mutant or deregulated c-myc or coexpressing both genes grew autonomously in culture with a similar growth rate and cloning efficiency. Expression of deregulated c-myc in M1 leukemic cells enhanced susceptibility to induction of apoptotic cell death and resulted in a reduced leukemogenicity when injected into isologous mice. Expression of the [Val135]p53 mutant did not change cell susceptibility to induction of apoptosis or leukemogenicity, but expression of this mutant p53 suppressed the effects of deregulated c-myc on these properties. The results indicate that the [Val135]p53 mutant can show a gain of function for susceptibility to apoptosis and leukemogenicity in leukemic cells with deregulated c-myc and, thus, enhance tumor development.

Regulation of bcl-2, bcl-XL and bax in the control of apoptosis by hematopoietic cytokines and dexamethasone

Treatment of M1 myeloid leukemic cells with interleukin 6 (IL-6) or dexamethasone (DEX), both of which induce differentiation in these cells, down-regulated expression of the apoptosis-suppressing gene bcl-2 and the apoptosis-promoting gene bax but up-regulated expression of the apoptosis-suppressing gene bcl-XL. There was a higher expression of bcl-XL in cells treated with DEX or DEX plus IL-6 compared to cells treated with IL-6 alone. The alternatively spliced bcl-X gene, bcl-Xs, which interferes with the action of bcl-2, was not expressed. Treatment with IL-6 increased the susceptibility of these cells to induction of apoptosis by Adriamycin or cycloheximide, but treatment with DEX or with IL-6 and DEX did not. Withdrawal of DEX after up-regulation of bcl-XL resulted in a decrease in bcl-XL expression and a concomitant increase in cell susceptibility to induction of apoptosis. Another myeloid leukemia that shows barely detectable expression of bcl-2 also showed up-regulated expression of bcl-XL but no change in bax after induction of differentiation with granulocyte-macrophage colony-stimulating factor, and this reduced cell susceptibility to induction of apoptosis by Adriamycin or cycloheximide. The results indicate that the related apoptosis-regulating genes bcl-2, bcl-XL, and bax are differently regulated and that up-regulation of bcl-XL expression may compensate for down-regulation of bcl-2 in the balance between genes that control apoptosis.

Interferon-gamma inhibits apoptosis induced by wild-type p53, cytotoxic anti-cancer agents and viability factor deprivation in myeloid cells

Different hematopoietic cytokines including colony-stimulating factors and interleukins can inhibit apoptotic cell death induced in myeloid cells by the tumor-suppressor gene wild-type 53 and a variety of cytotoxic anti-cancer agents. In this study we identity interferon-gamma as an anti-apoptotic cytokine for myeloid cells in which apoptosis was induced by wild-type p53, cytotoxic anti-cancer agents or viability factor deprivation. The inhibition of wild-type p53-mediated apoptosis in myeloid leukemic cells by interferon-gamma was not associated with downregulated expression of wild-type p53 or the p53-induced cyclin-dependent kinase inhibitor gene WAF-1, or with upregulated expression of the apoptosis-inhibiting gene bcl-2. Interferon-gamma also inhibited induction of apoptosis by a p53-independent pathway. Interferon-gamma inhibited apoptotic cell death caused by withdrawal of viability factors in normal myeloid precursor cells, the interleukin 3-dependent 32D cell line and differentiating myeloid leukemic cells. Interferon-alpha/beta did not inhibit apoptotic cell death in any of these systems. The results indicate that although interferon-gamma can inhibit cell multiplication and differentiation in myeloid cells, it shares with other hematopoietic cytokines the ability to protect normal and leukemic myeloid cells from induction of apoptosis.

The network of hematopoietic cytokines

Cell viability, multiplication, and differentiation to the various hematopoietic cell lineages are induced by a multigene cytokine family, and hematopoiesis is controlled by a network of interactions between these cytokines. This network includes positive regulators such as colony-stimulating factors and interleukins, and negative regulators such as transforming growth factor-beta and tumor necrosis factor. The functioning of the network requires an appropriate balance between positive and negative regulators, and the selective regulation of programmed cell death (apoptosis) by interaction of cytokines with their receptors. The cytokine network, which has arisen during evolution, allows considerable flexibility, depending on which part of the network is activated, and the ready amplification of response to a particular stimulus. This amplification occurs by autoregulation and transregulation of genes for the hematopoietic cytokines. There is also a transregulation by these cytokines of cytokine receptors. In addition to the flexibility of this network, both for response to present day infections and to infections that may develop in the future, a network may also be necessary to stabilize the whole system. The existence of a network and the cytokine-receptor regulation of apoptosis has to be taken into account in the clinical use of cytokines for therapy. Cytokines that regulate hematopoiesis induce the expression of genes for transcription factors. Cytokine signaling through transcription factors can thus ensure the autoregulation and transregulation of cytokine and receptor genes that occur in the network. Interactions between the cytokine network and transcription factors can also ensure production of specific cell types and stability of the differentiated state.

Control of sensitivity to induction of apoptosis in myeloid leukemic cells by differentiation and bcl-2 dependent and independent pathways

Induction of differentiation in M1 myeloid leukemic cells by the hematopoietic cytokines interleukin 6 and granulocyte-colony stimulating factor, or by the glucocorticoid dexamethasone, was associated with down-regulation of the apoptosis inhibiting gene bcl-2. The cytokine treated leukemic cells showed an increased sensitivity to induction of apoptotic cell death by the cancer chemotherapy compounds Adriamycin and cytosine arabinoside and by heat shock and cycloheximide. Dibutyryl cyclic AMP neither induced differentiation nor down-regulated bcl-2 expression, but it sensitized the cells to induction of apoptosis by some of these agents. Although dexamethasone induced differentiation and down-regulated bcl-2 expression, it did not sensitize the cells to induction of apoptosis and inhibited the apoptosis sensitizing effect of the cytokines and dibutyryl cyclic AMP. Dexamethasone did not inhibit induction of apoptosis by wild-type p53 or viability factor withdrawal. The apoptosis sensitizing effect of the cytokines and dibutyryl cyclic AMP was reversible upon their withdrawal.(ABSTRACT TRUNCATED AT 250 WORDS)

Hematopoietic cells from mice deficient in wild-type p53 are more resistant to induction of apoptosis by some agents

Wild-type p53 is a tumor-suppressor gene that can induce cell death by apoptosis when expressed in myeloid leukemic and some other types of tumor cells. However, the question remained as to what extent wild-type p53 is a mediator of apoptosis in normal cells. We have used mice deficient in wild-type p53 to determine whether induction of apoptosis in hematopoietic cells from these p53 deficient mice is defective. We show here that bone marrow myeloid progenitor cells from p53-deficient mice are more resistant to induction of apoptosis when there was only a low concentration of the viability factors granulocyte-macrophage colony-stimulating factor; interleukins-1 alpha, -3, and -6; or stem cell factor; or when apoptosis was induced in these cells by irradiation or heat shock. The loss of one allele of wild-type p53 was sufficient for increased resistance. The higher resistance to apoptosis in p53-deficient mice was also found in irradiated thymocytes, but not in thymocytes treated with dexamethasone or in mature peritoneal granulocytes. The degree of resistance in irradiated myeloid progenitors and thymocytes showed a dosage effect of the number of wild-type p53 genes. The results show that wild-type p53 is involved in the induction of apoptosis by some agents in normal hematopoietic cells. Loss of wild-type p53 can, therefore, contribute to tumor development by decreasing cell death at low concentrations of viability factors and after exposure to a DNA-damaging agent. The results also show that there are wild-type p53-dependent and -independent pathways of normal cell apoptosis.

Control of programmed cell death in normal and leukemic cells: new implications for therapy

Programmed cell death (apoptosis) is a normal process by which cells are eliminated during normal embryonic development and in adult life. Disruption of this normal process resulting in illegitimate cell survival can cause developmental abnormalities and facilitate cancer development. Normal cells require certain viability factors and undergo programmed cell death when these factors are withdrawn. The viability factors are required throughout the differentiation process from immature to mature cells. Although many viability factors are also growth factors, viability and growth are separately regulated. Viability factors can have clinical value in decreasing the loss of normal cells including the loss that occurs after irradiation, exposure to other cytotoxic agents or virus infection including AIDS. There is no evidence that occurs after irradiation, exposure to other cytotoxic agents or virus infection including AIDS. There is no evidence that cancer cells are immortal. Programmed cell death can be induced in leukemic cells by removal of viability factors, by cytotoxic therapeutic agents, or by the tumor-suppressor gene wild-type p53. All these forms of induction of programmed cell death in leukemic cells can be suppressed by the same viability factors that suppress programmed cell death in normal cells. A tumor-promoting phorbol ester can also suppress this death program. The induction of programmed cell death can be enhanced by deregulated expression of the gene c-myc and suppressed by the gene bcl-2. Mutant p53 and bcl-2 suppress the enhancing effect on cell death of deregulated c-myc, and thus allow induction of cell proliferation and inhibition of differentiation which are other functions of deregulated c-myc. The suppression of cell death by mutant p53 and bcl-2 increases the probability of developing cancer. The suppression of programmed cell death in cancer cells by viability factors suggests that decreasing the level of these factors may increase the effectiveness of cytotoxic cancer therapy. Treatments that downregulate the expression or activity of mutant p53 and bcl-2 in cancer cells should also be useful for therapy.

Regulation by bcl-2, c-myc, and p53 of susceptibility to induction of apoptosis by heat shock and cancer chemotherapy compounds in differentiation-competent and -defective myeloid leukemic cells

Myeloid leukemias that differ in their competence for induction of differentiation were analyzed for expression of bcl-2 and c-myc and for their sensitivity to induction of apoptosis by heat shock and cancer chemotherapy compounds. The M1 leukemia expressed a high level of bcl-2 and showed a much lower susceptibility to induction of apoptosis by heat shock, Adriamycin, 1-beta-D-arabinofuranosylcytosine, methotrexate, and cycloheximide, compared to five other leukemias which expressed a low level of bcl-2. There was no association between susceptibility to induction of apoptosis and competence for induction of differentiation. The difference in susceptibility to methotrexate, which is not regulated by the multidrug resistance (MDR) genes, and treatment with verapamil, which blocks MDR activity, have indicated that the higher resistance of the M1 leukemia to these agents was not due to MDR activity. The results indicate that the level of regulated bcl-2 expression in these myeloid leukemias was associated with cell susceptibility to induction of apoptosis by different apoptosis-inducing agents. Screening for expression of bcl-2 may thus be useful to characterize leukemias regarding susceptibility to induction of apoptosis by different agents. The level of regulated c-myc expressed in these leukemias was not associated with susceptibility to induction of apoptosis. Transfection with a deregulated mutant p53 into the M1 leukemia did not change susceptibility to apoptosis induction, but transfection with deregulated c-myc increased susceptibility to apoptosis.(ABSTRACT TRUNCATED AT 250 WORDS)

Hematopoietic cytokines inhibit apoptosis induced by transforming growth factor beta 1 and cancer chemotherapy compounds in myeloid leukemic cells

Transforming growth factor-beta 1 (TGF-beta 1) induces cell death in myeloid leukemia by apoptosis. In the M1 myeloid leukemia, this induction of apoptosis was inhibited by granulocyte colony-stimulating factor (G-CSF) or interleukin-6 (IL-6) and to a lesser extent by IL-1 alpha. IL-3 and stem cell factor/mast cell growth factor (SCF) showed only a marginal effect, and granulocyte-macrophage and macrophage CSFs (GM-CSF and M-CSF, respectively) were inactive. The induction of apoptosis by TGF-beta 1 in a different myeloid leukemia (7-M12) was inhibited by GM-CSF and IL-3 but not by the other cytokines. In the absence of TGF-beta 1, both M1 and 7-M12 leukemic cells were independent of hematopoietic cytokines for cell viability and growth. The cytotoxic compounds vincristine, vinblastine, adriamycin, cytosine arabinoside, cycloheximide, and sodium azide, some of which are used in cancer chemotherapy, induced cell death by apoptosis in both leukemias. As with TGF-beta 1, apoptosis induced by these cytotoxic compounds was inhibited by GM-CSF (7-M12 leukemia) and by G-CSF or IL-6 (M1 leukemia). Cyclosporine A decreased cell multiplication in M1 cells without inducing apoptosis, and G-CSF and IL-6 inhibited the cytostatic effect of cyclosporine A. It is suggested that the clinical use of cytokines to correct therapy-associated myelosuppression should be carefully timed to avoid protection of malignant cells from the cytotoxic action of the therapeutic compounds.

Inhibition of specific pathways of myeloid cell differentiation by an activated Hox-2.4 homeobox gene

Abnormal expression of homeobox genes is one of the abnormalities associated with the development of murine and human leukemia. Myeloid leukemic cells that can be induced to differentiate to mature cells by interleukin 6 were stably transfected with an activated Hox-2.4 homeobox gene. Expression of the Hox-2.4 gene in the transfected clones inhibited specific pathways of the myeloid differentiation program induced by interleukin 6. The expression of some genes associated with differentiation was almost completely blocked, and the expression of other genes was either partially inhibited or not affected. The results support the hypothesis that abnormal expression of Hox-2.4 may contribute to the development of leukemia by interfering with the differentiation program.

Selective regulation by hydrocortisone of induction of in vivo differentiation of myeloid leukemic cells with granulocyte-macrophage colony-stimulating factor, interleukin 6 and interleukin 1 alpha

Clones of myeloid leukemic cells can differ in their ability to be induced to differentiate in vitro by different cytokines. Using such leukemic clones, we studied the regulation by hydrocortisone of induction of in vivo differentiation by injection of recombinant interleukin 6 (IL-6), interleukin 1 alpha (IL-1 alpha), and granulocyte-macrophage colony-stimulating factor (GM-CSF). Injection of IL-6 and IL-1 alpha induced in vivo differentiation of leukemic cells that were induced to differentiate by these cytokines in vitro, but not of leukemic cells that were not susceptible to these cytokines in vitro. In contrast, injection of GM-CSF induced in vivo differentiation both in leukemic cells that were susceptible or not susceptible to GM-CSF in vitro. The effect of GM-CSF, but not of IL-6 or IL-1 alpha, on inducing differentiation in vivo was inhibited by pretreatment with hydrocortisone. In leukemic cells that were not induced to differentiate with GM-CSF in vitro, this inhibition of differentiation by pretreatment with hydrocortisone was greater than inhibition of differentiation obtained by pretreatment with cyclophosphamide or irradiation or the use of nude mice. After hydrocortisone pretreatment, the number of peritoneal cells and their ability to produce GM-CSF and IL-6 were suppressed. It is suggested that hydrocortisone can inhibit the effect of an injected cytokine such as GM-CSF on induction of in vivo differentiation of leukemic cells by inhibiting the ability of host cells to produce cytokines to which the leukemic cells are susceptible.

The network of hemopoietic regulatory proteins in myeloid cell differentiation

There are clones of myeloid leukemic cells that can be induced to undergo terminal cell differentiation to macrophages by normal hemopoietic regulatory proteins. Induction of differentiation in two different clones of myeloid leukemic cells with interleukin 6 (IL-6) or granulocyte-macrophage colony-stimulating factor (GM-CSF) resulted in induction of mRNA for the hemopoietic regulatory proteins IL-6, GM-CSF, interleukin 1 alpha and interleukin 1 beta, tumor necrosis factor, and transforming growth factor beta 1. In one of these clones, induction of differentiation with GM-CSF was also associated with induction of mRNA for macrophage colony-stimulating factor (M-CSF) but not for the receptor for M-CSF (c-fms), whereas in the other clone, induction of differentiation with IL-6 was associated with induction of mRNA for both c-fms and M-CSF. The clones also differed in their responsiveness to these regulators. There was no induction of mRNA for granulocyte colony-stimulating factor or interleukin 3 during differentiation of either clone. The results indicate that the genes for a nearly normal network of positive and negative hemopoietic regulatory proteins are induced during differentiation of these myeloid leukemic cells and that there are leukemic clones with specific defects in this network.

Rescue from programmed cell death in leukemic and normal myeloid cells

Growth factor-independent clones of myeloid leukemic cells can regain a growth factor-dependent state during differentiation. Loss of viability in these differentiating leukemic cells in the absence of growth factor was associated with DNA fragmentation and morphologic changes typical of programmed cell death (apoptosis). The differentiating leukemic cells could be rescued from apoptosis by a hematopoietic growth factor such as interleukin-3 (IL-3) and by the tumor-promoting phorbol ester 12-O-tetra-decanoyl-phorbol-13-acetate (TPA), but not by the nonpromoting phorbol ester 4-alpha-TPA. IL-3 and TPA rescued differentiating myeloid leukemic cells by different pathways and also rescued normal myeloid precursor cells from apoptosis. The rescue of differentiating leukemic and normal myeloid cells by IL-3 or TPA was blocked by amiloride inhibitors of the Na+/H+ antiporter. We suggest that TPA may act as a tumor promoter by inhibiting programmed cell death.

Wild-type p53 induces apoptosis of myeloid leukaemic cells that is inhibited by interleukin-6

Wild-type p53 protein has many properties consistent with its being the product of a tumour suppressor gene. Although the normal roles of tumour suppressor genes are still largely unknown, it seems that they could be involved in promoting cell differentiation as well as in mediating growth arrest by growth-inhibitory cytokines. Hence, the abrogation of wild-type p53 expression, which is a common feature of many tumours, could eliminate these activities. We have now tested this notion by restoring the expression of p53 in a murine myeloid leukaemic cell line that normally lacks p53. The use of a temperature-sensitive p53 mutant allowed us to analyse cells in which the introduced p53 had either wild-type or mutant properties. Although there seemed to be no effect on differentiation, the introduction of wild-type p53 resulted in rapid loss of cell viability in a way characteristic of apoptosis (programmed cell death). The effect of wild-type p53 was counteracted by interleukin-6. Thus products of tumour suppressor genes could be involved in restricting precursor cell populations by mediating apoptosis.

Induction of genes for transcription factors by normal hematopoietic regulatory proteins in the differentiation of myeloid leukemic cells

Induction of differentiation to macrophages in two different clones of myeloid leukemic cells by the hematopoietic regulatory proteins interleukin-6 (IL-6), or by granulocyte-macrophage colony-stimulating factor (GM-CSF) or interleukin-3 (IL-3), is shown to be associated with sustained accumulation of c-jun, jun-B, and c-fos mRNA that code for proteins that form complexes that are transcription factors (AP-1). In one but not in the other of these leukemic clones, differentiation is also associated with sustained accumulation of mRNA for the putative transcription factor zif/268. The results indicate that differentiation of myeloid cells by normal hematopoietic regulatory proteins is associated with induction of sustained elevated levels of mRNA for transcription factors that can regulate and maintain gene expression in the differentiation program, and that zif/268 gene expression is not essential for differentiation to macrophages.

Selective regulation of the activity of different hematopoietic regulatory proteins by transforming growth factor beta 1 in normal and leukemic myeloid cells

The viability of normal bone marrow myeloid precursor cells induced by interleukin-6 (IL-6) or IL-1 alpha and the ability of IL-6 and IL-1 alpha to induce the formation of colonies of granulocytes, macrophages, or megakaryocytes in densely seeded bone marrow cultures was suppressed by transforming growth factor-beta 1 (TGF-beta 1). Induction of normal bone marrow colony formation by IL-3 was much less sensitive to TGF-beta 1, and there was little or no effect of TGF-beta 1 on colony formation induced by macrophage colony-stimulating factor (M-CSF) or granulocyte-macrophage CSF (GM-CSF). In different clones of myeloid leukemic cells, TGF-beta 1 suppressed differentiation induced with IL-6, IL-1 alpha, or lipopolysaccharide (LPS), but did not suppress differentiation induced with IL-3 or GM-CSF. The effect of TGF-beta 1 on differentiation of the leukemic cells can be dissociated from its effect on cell growth. TGF-beta 1 suppressed the production of IL-6 in normal bone marrow cells cultured with IL-1 alpha and the production of IL-6 and GM-CSF in leukemic cells cultured with IL-1 alpha or LPS. The suppression of IL-6 production can explain the suppression by TGF-beta 1 of the effects of IL-1 alpha and LPS that are mediated by IL-6. TGF-beta 1 also suppressed differentiation in clones of myeloid leukemic cells induced with differentiation factor/leukemia inhibitory factor and tumor necrosis factor. In different leukemic clones TGF-beta 1 suppressed or enhanced induction of differentiation with dexamethasone. The results show that TGF-beta 1 can selectively control the activity of different molecular regulators of normal and leukemic hematopoiesis.

Regulation of the genes for interleukin-6 and granulocyte-macrophage colony stimulating factor by different inducers of differentiation in myeloid leukemic cells

Different clones of myeloid leukemic cells can be induced to differentiate to mature macrophages and/or granulocytes by hematopoietic regulatory proteins and by other compounds. We now show that induction of differentiation in different clones of myeloid leukemic cells with the normal hematopoietic proteins granulocyte-colony stimulating factor (G-CSF), granulocyte-macrophage colony stimulating factor (GM-CSF), or interleukin 3 and by compounds such as dexamethasone or cytosine arabinoside (ara C) induces the expression of genes for the myeloid differentiation inducing protein MGI-2 that we have shown is interleukin 6 (IL-6) and for GM-CSF. We have previously shown that induction of differentiation with interleukin-1, IL-6, or bacterial lipopolysaccharide (LPS) also induces IL-6 and GM-CSF gene expression. Treatment of these leukemic clones with hematopoietic proteins that do not induce differentiation did not induce IL-6 or GM-CSF gene expression. The results indicate that induction of IL-6 and GM-CSF gene expression is part of the normal differentiation program in myeloid cells and support our previous evidence that there is transregulation of gene expression between different hematopoietic regulatory proteins.

Clonal variation in susceptibility to differentiation by different protein inducers in the myeloid leukemia cell line M1

Differentiation-competent clones of myeloid leukemic cells, independently isolated from the M1 cell line in Rehovot, Israel, and in Saitama, Japan, can be induced to differentiate to mature cells by the protein which we called macrophage and granulocyte differentiation-inducing protein-2 (MGI-2) that we have shown is interleukin 6 (IL-6). We now show that our MGI-2/IL-6-susceptible clones of M1 cells were not induced to differentiate with the differentiation-inducing protein called D-factor/leukemia inhibitory factor (LIF) which has also been called human interleukin for DA cells (HILDA), whereas this protein induced differentiation to macrophages in the M1 clone isolated in Saitama which was also used in Melbourne, Australia, The D-factor/LIF susceptible clone also showed a 4-fold lower sensitivity to MGI-2/IL-6 than the D-factor/LIF resistant clone. Both types of clones differentiated with interleukin-1 alpha (IL-1 alpha) and dexamethasone, whereas the D-factor/LIF resistant clone, but not the D-factor/LIF susceptible clone, was induced by bacterial lipopolysaccharide (LPS) to differentiate to mature macrophages. The present results show that clonal differences in susceptibility to differentiation-inducing proteins in the M1 cell line can explain the isolation of different differentiation-inducing proteins in M1 leukemic cells in different laboratories.

Regulation of megakaryocyte development by interleukin-6

Megakaryocytes develop in densely seeded normal mouse bone marrow (BM) cells cultured in agar or in liquid medium. This formation of megakaryocytes is enhanced by the myeloid differentiation-inducing protein MGI-2, which we have shown to be interleukin-6 (IL-6). Monoclonal antibody (MoAb) that specifically neutralizes mouse IL-6 but not human IL-6 inhibited megakaryocyte development in cells cultured either with or without the addition of mouse IL-6 but did not inhibit megakaryocyte development induced by human IL-6. This MoAb to mouse IL-6 that does not neutralize mouse IL-3 also inhibited mouse IL-3-induced megakaryocyte development. Antibody to mouse GM-CSF did not inhibit the formation of megakaryocytes. The results show that the induction of megakaryocyte development by IL-3 is due to the production of IL-6 in the BM cultures. The present experiments demonstrate a new property of IL-6 and indicate that IL-6 is a regulatory protein of normal megakaryocyte development.

Autoregulation of interleukin 6 and granulocyte-macrophage colony-stimulating factor in the differentiation of myeloid leukemic cells

Induction of differentiation in one type of clone of mouse myeloid leukemic cells by mouse or human interleukin 6 (IL-6) and in another type of clone by mouse granulocyte-macrophage colony-stimulating factor (GM-CSF) was found to be associated with induction of IL-6 and GM-CSF mRNA and protein. The results indicated that IL-6 and GM-CSF could positively autoregulate their own gene expression during myeloid cell differentiation. It is suggested that this autoregulation may serve to enhance and prolong the signal induced by these proteins in cells transiently exposed to IL-6 or GM-CSF.

Induction of dependence on hematopoietic proteins for viability and receptor upregulation in differentiating myeloid leukemic cells

There are different types of myeloid leukemic cells that can be induced to differentiate to mature granulocytes or macrophages by different hematopoietic regulatory proteins. One type of leukemic clone can be induced to differentiate by recombinant macrophage and granulocyte differentiation-inducing protein-type 2 (MGI-2), which we have shown is Interleukin-6 (IL-6), and another type of leukemic clone can be differentiated by recombinant granulocyte-macrophage colony-stimulating factor (GM-CSF) or IL-3. There was no subpopulation of growth factor-responsive or differentiation-defective cells before induction of differentiation in either type of clone. In both clones, induction of differentiation-induced requirement for a hematopoietic protein for cell viability. Viability of the cells was maintained by IL-6, IL-3, or macrophage colony-stimulating factor (M-CSF) but not by GM-CSF in the cells differentiated by IL-6, and by GM-CSF or IL-3 but not by IL-6 or M-CSF in the cells differentiated by GM-CSF or IL-3. The viable cells with a differentiated phenotype continued to multiply. In undifferentiated leukemic cells with no or few surface receptors for some of these proteins, there was an upregulation of the number of receptors during differentiation for the proteins to which the cells responded. But there were also differentiating leukemic cells with an upregulation of GM-CSF receptors although GM-CSF could not maintain the viability of the differentiating cells. The results indicate that induction of hormone responsiveness and upregulation of the hormone receptors can both occur in differentiating leukemic cells, and that the regulation of these two events can be separated.

Indirect induction of differentiation of normal and leukemic myeloid cells by recombinant interleukin 1

Different clones of myeloid leukemic cells can be induced to differentiate to mature macrophages or granulocytes by different normal hematopoietic regulatory proteins. The present experiments with recombinant IL-1 alpha and recombinant IL-1 beta show that, (a) that there are clones of myeloid leukemic cells which can be induced to differentiate to mature cells by the myeloid cell differentiation-inducing protein MGI-2 and can also be induced to differentiate to mature macrophages and granulocytes by both types of IL-1; (b) this IL-1-induced differentiation is mediated by endogenous production of differentiation-inducing protein MGI-2; (c) IL-1 and MGI-2 induce production of GM-CSF in these leukemic cells; and (d) IL-1 also induces cell differentiation and production of MGI-2 and GM-CSF in normal myeloid precursor cells. The results indicate that IL-1 induces differentiation indirectly.

Control of in vivo differentiation of myeloid leukemic cells

The differentiation of leukemic cells in vivo can be a useful approach to therapy. In vivo differentiation of myeloid leukemic cells was studied in intraperitoneally implanted diffusion chambers, containing different soluble antigens. The presence of these antigens in the chambers induced differentiation of myeloid leukemic cells and this was inhibited in immune-deficient mice. Transfer of normal spleen cells enriched for T-lymphocytes or antigen-specific helper T lymphocyte cell lines to mice in which differentiation of leukemic cells was inhibited, restored in vivo differentiation of the leukemic cells. Antigen-specific helper T cells produce myeloid regulatory proteins and can accumulate at a site that contains the specific antigen. It is suggested that migration in response to antigen of helper T cells producing regulatory proteins may play an important role in inducing in vivo differentiation of leukemic cells. We have identified a class of myeloid leukemic cells that can be induced to differentiate in vitro by incubation with pure MGI-1GM (GM-CSF) or IL-3, but not with MGI-1G (G-CSF). Experiments with pure recombinant proteins have shown that MGI-1GM and IL-3, but not MGI-1G, can also induce these myeloid leukemic cells to differentiate in vivo. These results and our previous studies on the myeloid cell differentiation-inducing protein MGI-2, demonstrate the potential use of normal hematopoietic regulatory proteins not only in regulation of normal hematopoiesis, but also in the treatment of myeloid leukemia by in vivo induction of terminal cell differentiation.

The myeloid blood cell differentiation-inducing protein MGI-2A is interleukin-6

The mouse myeloid blood cell differentiation-inducing protein, macrophage and granulocyte inducer, type 2A (MGI-2A), was purified, and the amino acid sequence of a CNBr cleavage peptide (22 residues) was determined. This amino acid sequence is identical to the sequence found in positions 73 to 94 of mouse interleukin-6 (IL-6). Recombinant mouse IL-6 protein induces differentiation of mouse myeloid leukemic cells that are induced to differentiation by MGI-2, and monoclonal antimouse-MGI-2 antibody, which neutralizes MGI-2, also completely neutralizes this IL-6-induced differentiation. These results show that the major type of mouse myeloid differentiation-inducing protein (MGI-2A) and IL-6 are very similar and most likely identical proteins. Recombinant human IL-6 (also called interferon-beta 2 or B-cell differentiation factor), which shows only a 41% similarity to mouse IL-6, has 11 identical amino acid residues out of the 22 in the mouse MGI-2A peptide and also induces differentiation of the same myeloid leukemic cells.

In vivo control of differentiation of myeloid leukemic cells by cyclosporine A and recombinant interleukin-1 alpha

There are different types of hematopoietic regulatory proteins that regulate the multiplication and differentiation of normal myeloid cells. These different types include four growth-inducing proteins called colony-stimulating factors (CSF), including interleukin-3 (IL-3), or macrophage and granulocyte inducers, type 1 (MGI-1); another type (called MGI-2) that induces myeloid differentiation of normal myeloid cells without inducing myeloid cell multiplication; and interleukin-1 (IL-1), which can act on myeloid precursor cells. Different clones of myeloid leukemic cells can differ in their ability to be induced to undergo terminal cell differentiation by different hematopoietic regulatory proteins. We have now studied the ability of cyclosporine A and recombinant IL-1 alpha to regulate in vivo differentiation of different clones of myeloid leukemic cells that are either susceptible or resistant to induction of differentiation by IL-1 in vitro. The results show that (a) cyclosporine A, like other immune-suppressing compounds such as cyclophosphamide, inhibited in vivo differentiation of myeloid leukemic cells and differentiation was restored by injecting recombinant GM-CSF; (b) recombinant IL-1 alpha induced in vivo terminal differentiation of IL-1-sensitive but not IL-1-resistant clones of myeloid leukemic cells; (c) IL-1 alpha and GM-CSF synergistically induced differentiation in vivo in a GM-CSF-responsive and IL-1-nonresponsive clone of leukemic cells; and (d) IL-1 alpha induced in vivo the rapid production and release into serum of the differentiation-inducing protein MGI-2 as well as the growth-inducing proteins M-CSF and G-CSF.

Target-cell specificity of hematopoietic regulatory proteins for different clones of myeloid leukemic cells: two regulators secreted by Krebs carcinoma cells

The normal myeloid hematopoietic regulatory proteins include one class of proteins that induces viability and multiplication of normal myeloid precursor cells to form colonies (called MGI-1 = CSF or IL-3) and another class (called MGI-2 = DF) that induces differentiation of normal myeloid precursors without inducing cell multiplication. Different clones of myeloid leukemia cells can differ in their response to these regulatory proteins. The present experiments characterize proteins secreted by Krebs ascites carcinoma cells that induce differentiation of 2 different types of myeloid leukemic cell clones (clones II and 7-M12). The results indicate the following: (1) Krebs cells produce 2 distinct and separable proteins, each inducing differentiation in one of the leukemic clones. (2) One protein induced differentiation of clone-II myeloid leukemic cells and of normal myeloid precursor cells was free of any colony-inducing (MGI-1 = CSF or IL-3) activity, bound to double-stranded mammalian DNA, and was thus a differentiation-inducing protein MGI-2. This MGI-2 protein (MGI-2A) was purified to a single silver-stained band on an SDS polyacrylamide gel. (3) The other protein induced differentiation of clone 7-M12 myeloid leukemic cells, did not bind to double-stranded DNA and could not be separated from the myeloid growth-inducing protein MGI-1GM (GM-CSF) after 6 steps of purification including high-pressure liquid chromatography. The use of specific antisera confirmed that the protein which induced differentiation of clone 7-M12 leukemic cells was MGI-1 GM. The results show that Krebs ascites tumor cells produce 2 different myeloid hematopoietic regulatory proteins that differ in their target specificity for different clones of myeloid leukemic cells.

In vivo control of differentiation of myeloid leukemic cells by recombinant granulocyte-macrophage colony-stimulating factor and interleukin 3

The normal myeloid hematopoietic regulatory proteins include one class of proteins that induces viability and multiplication of normal myeloid precursor cells to form colonies (colony-stimulating factors [CSF] and interleukin 3 [IL-3], macrophage and granulocyte inducing proteins, type 7 [MGI-1]) and another class (called MGI-2) that induces differentiation of normal myeloid precursors without inducing cell multiplication. Different clones of myeloid leukemic cells can differ in their response to these regulatory proteins. One type of leukemic clone can be differentiated in vitro to mature cells by incubating with the growth-inducing proteins granulocyte-macrophage (GM) CSF or IL-3, and another type of clone can be differentiated in vitro to mature cells by the differentiation-inducing protein MGI-2. We have now studied the ability of different myeloid regulatory proteins to induce the in vivo differentiation of these different types of mouse myeloid leukemic clones in normal and cyclophosphamide-treated mice. The results show that in both types of mice (a) the in vitro GM-CSF- and IL-3-sensitive leukemic cells were induced to differentiate to mature cells in vivo in mice injected with pure recombinant GM-CSF and IL-3 but not with G-CSF, M-CSF, or MGI-2; (b) the in vitro MGI-2-sensitive leukemic cells differentiated in vivo by injection of MGI-2 and also, presumably indirectly, by GM-CSF and IL-3 but not by M-CSF or G-CSF; (c) in vivo induced differentiation of the leukemic cells was associated with a 20- to 60-fold decrease in the number of blast cells; and (d) all the injected myeloid regulatory proteins stimulated the normal myelopoietic system. Different normal myeloid regulatory proteins can thus induce in vivo terminal differentiation of leukemic cells, and it is suggested that these proteins can have a therapeutic potential for myeloid leukemia in addition to their therapeutic potential in stimulating normal hematopoiesis.

Role of different normal hematopoietic regulatory proteins in the differentiation of myeloid leukemic cells

There are 4 different normal myeloid hematopoietic cell growth-inducing proteins MGI-1 (CSF or IL-3) that induce normal precursor cells to multiply and form clones containing only macrophages (MGI-1M = M-CSF = CSF-1), only granulocytes (MGI-1G = G-CSF), both granulocytes and macrophages (MGI-1GM = GM-CSF), or granulocytes, macrophages, eosinophils, mast cells, megakaryocytes and erythroid cells (interleukin-3) (IL-3). There is another type of normal myeloid regulatory protein (MGI-2) with no MGI-1 (CSF or IL-3) activity which can induce differentiation of normal myeloid precursors and certain clones of myeloid leukemic cells. The present results with MGI-2 and pure recombinant MGI-1G, MGI-1GM and IL-3 have shown that different clones of myeloid leukemic cells can be induced to differentiate by different hematopoietic regulatory proteins. One type of leukemic clone is induced to differentiate to mature cells only by MGI-2 and is partially differentiated by MGI-1G, a second type is differentiated only by MGI-1GM or IL-3, and other workers have found a third type that is differentiated only by MGI-1G. The presence of surface receptors does not necessarily make leukemic cells differentiation-competent for these hematopoietic regulatory proteins. All 4 types of MGI-1 (CSF or IL-3) induce endogenous synthesis of MGI-2 in normal myeloid precursor cells. It is suggested that, in addition to their potential therapeutic effect on the development of normal hematopoietic cells, MGI-2, MGI-1G, MGI-1GM and IL-3 all have the potential for differentiation-directed therapy of leukemia in leukemic cells that can be differentiated by one of these normal hematopoietic regulatory proteins.

Regulation of cell-surface receptors for hematopoietic differentiation-inducing protein MGI-2 on normal and leukemic myeloid cells

The normal myeloid hematopoietic regulatory proteins include 4 different growth-inducing proteins (IL-3, MGI-1GM = GM-CSF, MGI-1G = G-CSF, and MGI-1M = M-CSF = CSF-1). There is also another type of normal myeloid regulatory protein (MGI-2) with no MGI-1 (CSF or IL-3) activity, which can induce differentiation of normal myeloid precursors and certain clones of myeloid leukemic cells. Studies on the binding of MGI-2 to differentiation-competent (D+) and differentiation-defective (D-) clones of mouse myeloid leukemic cells and to normal cells indicate that: (1) D+ clones of myeloid leukemic cells had about 2,500 high-affinity surface receptors per cell, like mature normal myeloid cells, and the bound MGI-2 was rapidly internalized with its cell-surface receptors at 37 degrees C causing down-regulation of MGI-2 receptors in both the normal and leukemic cells; (2) in some D- clones, the number and internalization of MGI-2 receptors were similar to those of D+ clones whereas other D- clones had only 0-100 MGI-2 receptors per cell; (3) normal thymus and lymph-node lymphocytes and T lymphoma cells did not show detectable MGI-2 receptors; (4) there was an independent expression of receptors for MGI-2 and for the 4 myeloid growth-inducing proteins on different clones of myeloid leukemic cells; and (5) none of the 4 myeloid growth-inducing proteins IL-3, MGI-1GM, MGI-1G, or MGI-1M, inhibited binding of MGI-2 to its receptors. The cytotoxic proteins lymphotoxin and tumor necrosis factor did not induce differentiation of the mouse myeloid leukemic cells and also did not inhibit binding of MGI-2 to its receptors. These results show that the myeloid differentiation-inducing protein MGI-2 binds to cell-surface receptors that are different from the receptors for the 4 myeloid growth-inducing proteins and these cytotoxic proteins.

Review of clinical and haematological response to low-dose cytosine arabinoside in acute myeloid leukaemia

15 patients with acute myeloid leukaemia (AML) were treated with low-dose cytosine arabinoside (LD ARA-C). 2 patients had complete remissions, which lasted for 8 and 3 months, and 5 patients had a partial remission. 46% of the patients thus responded to LD ARA-C. This included 1 responding patient who had not previously responded to therapy with 6-mercaptopurine, thioguanine, or vinblastine. The 2 patients with complete remission did not show LD ARA-C-induced hypoplasia of bone marrow, although 1 had hypoplastic AML before therapy. Leukaemic cells from 1 patient showed in vivo maturation from M1 to M3 after LD ARA-C treatment. The present results, together with the published data, indicate that: a. LD ARA-C treatment, although it may have some toxic effects, is an effective treatment for some patients with AML, especially those with hypoplastic AML; b. Response to LD ARA-C can be obtained after one or several courses of treatment; c. LD ARA-C-induced remissions are sometimes obtained even in patients who fail in more conventional treatments; d. LD ARA-C-induced remissions can be achieved without bone marrow hypoplasia, and induction of hypoplasia by itself does not always result in complete remission; e. LD ARA-C can induce in vivo maturation of leukaemic cells. It is suggested that induction of remission in AML patients by LD ARA-C may result from either differentiation of leukaemic blast cells, cytotoxicity to leukaemic blasts, or both mechanisms acting together.

Regulation of cell surface receptors for different hematopoietic growth factors on myeloid leukemic cells

There are clones of myeloid leukemic cells which are different from normal myeloid cells in that they have become independent of hematopoietic growth factor for cell viability and growth. The ability of these clones to bind three types of hematopoietic growth factors (MGI-1GM = GM-CSF, IL-3 = multi-CSF and MGI-1M = M-CSF = CSF-1) was measured using the method of quantitative absorption at 1 degree C and low pH elution of cell-bound biological activity. Results of binding to normal myeloid and lymphoid cells were similar to those obtained by radioreceptor assays. The results indicate that the number of receptors on different clones of these leukemic cells varied from 0 to 1,300 per cell. The receptors have a high binding affinity. Receptors for different growth factors can be independently expressed in different clones. There was no relationship between expression of receptors for these growth factors and the phenotype of the leukemic cells regarding their ability to be induced to differentiate. The number of receptors on the leukemic cells was lower than on normal mature macrophages. Myeloid leukemic cells induced to differentiate by normal myeloid cell differentiation factor MGI-2 (= DF), or by low doses of actinomycin D or cytosine arabinoside, showed an up-regulation of the number of MGI-1GM and IL-3 receptors. Induction of differentiation of leukemic cells by MGI-2 also induced production and secretion of the growth factor MGI-1GM, and this induced MGI-1GM saturated the up-regulated MGI-1GM receptors. It is suggested that up-regulation of these receptors during differentiation is required for the functioning of differentiated cells.