Function and signal transduction mediated by the interleukin 3 receptor system in hematopoiesis

Cloning of the murine beta5 integrin subunit promoter. Identification of a novel sequence mediating granulocyte-macrophage colony-stimulating factor-dependent repression of beta5 integrin gene transcription

We previously noted that the initial receptor by which murine osteoclast precursors bind matrix is the integrin alphav beta5 and that granulocyte-macrophage colony-stimulating factor (GM-CSF) decreases expression of this heterodimer by suppressing transcription of the beta5 gene. We herein report cloning of the beta5 integrin gene promoter and identification of a GM-CSF-responsive sequence. A 13-kilobase (kb) genomic fragment containing part of the beta5 gene was isolated by screening a mouse genomic library with a probe derived from the most 5'-end of a murine beta5 cDNA. A combination of primer extension and S1 nuclease studies identifies two transcriptional start sites, with the major one designated +1. A 1-kb subclone containing sequence -875 to + 110 is transcriptionally active in a murine myeloid cell line. This 1-kb fragment contains consensus binding sequences for basal (Sp1), lineage-specific (PU.1), and regulatable (signal transducer and activator of transcription) transcription factors. Reflecting our earlier findings, promoter activity is repressed in transfected myeloid cells treated with GM-CSF. Using deletion mutants, we localized a 109-base pair (bp) promoter region responsible for GM-CSF-inhibited beta5 transcription. We further identified a 19-bp sequence within the 109-bp region that binds GM-CSF-induced nuclear proteins by gel shift/competition assays. Mutation of the 19-bp sequence not only ablates its capacity to bind nuclear proteins from GM-CSF-treated cells, in vitro, but the same mutation, when introduced in the 1-kb promoter, abolishes its ability to respond to GM-CSF treatment. Northern analysis demonstrates that cycloheximide treatment abrogates the capacity of GM-CSF to decrease beta5 mRNA levels. In summary, we have identified a 19-bp cis-element mediating GM-CSF-induced down-regulation of beta5 by a mechanism requiring protein synthesis.

Bcr-Abl Efficiently Induces a Myeloproliferative Disease and Production of Excess Interleukin-3 and Granulocyte-Macrophage Colony-Stimulating Factor in Mice: A Novel Model for Chronic Myelogenous Leukemia

The bcr-abl oncogene plays a critical role in causing chronic myelogenous leukemia (CML). Effective laboratory animal models of CML are needed to study the molecular mechanisms by which thebcr-abl oncogene acts in the disease progression of CML. We used a murine stem cell retroviral vector (MSCV) to transduce thebcr-abl/p210 oncogene into mouse bone marrow cells and found that expression of Bcr-Abl/p210 induced a myeloproliferative disorder that resembled the chronic phase of human CML in 100% of bone marrow transplanted mice in about 3 weeks. This CML-like disease was readily transplanted to secondary recipient mice. Multiple clones of infected cells were expanded in the primary recipients, but the leukemia was primarily monoclonal in the secondary recipient mice. Mutation analysis demonstrated that the protein tyrosine kinase activity of Bcr-Abl/p210 was essential for its leukemogenic potential in vivo. Interestingly, we found that the leukemic cells expressed excess interleukin-3 (IL-3) and granulocyte-macrophage colony-stimulating factor (GM-CSF) in the diseased mice. These studies demonstrate that expression of Bcr-Abl can induce a CML-like leukemia in mice much more efficiently and reproducibly than in previously reported mouse CML models, probably due to efficient expression in the correct target cell(s). Our first use of this model for analysis of the molecular mechanisms involved in CML raises the possibility that excess expression of hematopoietic growth factors such as IL-3 and GM-CSF may contribute to the clinical phenotype of CML.

Bcr-Abl Efficiently Induces a Myeloproliferative Disease and Production of Excess Interleukin-3 and Granulocyte-Macrophage Colony-Stimulating Factor in Mice: A Novel Model for Chronic Myelogenous Leukemia

The bcr-abl oncogene plays a critical role in causing chronic myelogenous leukemia (CML). Effective laboratory animal models of CML are needed to study the molecular mechanisms by which thebcr-abl oncogene acts in the disease progression of CML. We used a murine stem cell retroviral vector (MSCV) to transduce thebcr-abl/p210 oncogene into mouse bone marrow cells and found that expression of Bcr-Abl/p210 induced a myeloproliferative disorder that resembled the chronic phase of human CML in 100% of bone marrow transplanted mice in about 3 weeks. This CML-like disease was readily transplanted to secondary recipient mice. Multiple clones of infected cells were expanded in the primary recipients, but the leukemia was primarily monoclonal in the secondary recipient mice. Mutation analysis demonstrated that the protein tyrosine kinase activity of Bcr-Abl/p210 was essential for its leukemogenic potential in vivo. Interestingly, we found that the leukemic cells expressed excess interleukin-3 (IL-3) and granulocyte-macrophage colony-stimulating factor (GM-CSF) in the diseased mice. These studies demonstrate that expression of Bcr-Abl can induce a CML-like leukemia in mice much more efficiently and reproducibly than in previously reported mouse CML models, probably due to efficient expression in the correct target cell(s). Our first use of this model for analysis of the molecular mechanisms involved in CML raises the possibility that excess expression of hematopoietic growth factors such as IL-3 and GM-CSF may contribute to the clinical phenotype of CML.

Regulation of proliferation, differentiation and survival by the IL-3/IL-5/GM-CSF receptor family

The receptors for the I1-3/IL-5/GM-CSF cytokine family are composed of a heterodimeric complex of a cytokine-specific alpha chain and a common beta chain (betac). Binding of IL-3/IL-5/GM-CSF to their respective receptors rapidly induces activation of multiple intracellular signalling pathways, including the Ras-Raf-ERK, the JAK/STAT, the phosphatidylinositol 3-kinase PKB, and the JNK/SAPK and p38 signalling pathways. This review focuses on recent advancements in understanding how these different signalling pathways are activated by IL-3/IL-5/GM-CSF receptors, and how the individual pathways contribute to the pleiotropic effects of IL-3/IL-5/GM-CSF on their target cells, including proliferation, differentiation, survival, and effector functions.

Functional granulocyte/macrophage colony stimulating factor receptor is constitutively expressed on neoplastic plasma cells and mediates tumour cell longevity

It has been shown that granulocyte/macrophage colony stimulating factor (GM-CSF) is able to support myeloma cell propagation in cooperation with interleukin (IL)-6, the major growth factor for malignant plasma cells, although the biological mechanisms involved remain unknown. Therefore we investigated (i) the expression levels of the GM-CSF receptor (GM-CSFR) constituents in three malignant plasma cell lines and in native malignant plasma cells, (ii) the ability of the receptor to mediate common signalling pathways regulating proliferation and cell survival in malignant plasma cell lines, and (iii) the effects of GM-CSF on tumour cell biology. The GM-CSFRalpha subunit was detected in the malignant plasma cell lines RPMI-8226, MC/CAR, IM-9 as well as 6/6 native myeloma cell samples derived from the bone marrow of patients with overt disease. Furthermore, GM-CSFR expression was also detected in the CD19+ fraction from 2/3 bone marrow samples and 5/8 peripheral blood samples derived from patients with malignant plasma cell disorders, but not in the CD19+ fraction of peripheral blood from healthy donors. The expressed cytokine receptor alpha-subunit was able to constitute a functional signalling complex with the ubiquitously expressed GM-CSFRbeta subunit, as demonstrated by the fact that GM-CSF induced the p21-ras/mitogen-activated protein kinase (MAPK) signalling cascade in malignant plasma cell lines. Since this signalling cascade plays an essential role in the mediation of both proliferation and cell survival, we investigated the impact of GM-CSF on these two events. Application of GM-CSF led to an increase of DNA-synthesis in MC/CAR, IM-9 and RPMI-8226 cells. Furthermore, it increased longevity of these malignant plasma cell lines by reducing the rates of spontaneous apoptosis. We conclude that (i) the functional GM-CSFR is commonly expressed on malignant plasma cells and that (ii) GM-CSF promotes the clonal expansion of myeloma cells by inhibiting spontaneous apoptosis and promoting DNA synthesis.

Cytochrome c Induces Caspase-Dependent Apoptosis in Intact Hematopoietic Cells and Overrides Apoptosis Suppression Mediated by bcl-2, Growth Factor Signaling, MAP-Kinase-Kinase, and Malignant Change

It has been shown that cytochrome c is released from mitochondria during apoptosis, activates pro-caspase CPP32 (caspase III), and induces DNA fragmentation in mixtures of cytosolic extracts and isolated nuclei. To establish whether cytochrome c can primarily induce apoptosis in intact cells, we used direct electroporation of cytochrome c into murine interleukin-3 (IL-3)–dependent cells. Electroporation of micromolar external concentrations of cytochrome c rapidly induced apoptosis (2 to 4 hours) that was concentration-dependent, did not affect mitochondrial transmembrane potential, and was independent of cell growth. Only certain isoforms of cytochrome c were apoptogenic; yeast cytochrome c and other redox proteins were inactive. Cytochrome c-induced apoptosis was dependent on heme attachment to the apo-enzyme and was completely abolished by caspase inhibitors. Nonapoptogenic isoforms of cytochrome c did not compete for apoptogenic cytochrome c. Although apoptosis induced by IL-3 withdrawal was inhibited by bcl-2 overexpression and expression of an activated MAP-kinase-kinase (MAP-KK), cytochrome c induced apoptosis in the presence of IL-3 signaling, bcl-2 over-expression, expression of activated MAP-KK, and the combined antiapoptotic action of all three. Cytochrome c also induced apoptosis in the leukemic cell line WEHI 3b. However, human HL60 and CEM cells were resistant to cytochrome c-induced apoptosis. HL60 cells did not electroporate, but CEM cells were efficiently electroporated. Our studies with IL-3–dependent cells confirm that the apoptogenic attributes of cytochrome c are identical in intact cells to those in cell extracts. We conclude that cytochrome c can be a prime initiator of apoptosis in intact growing cells and acts downstream of bcl-2 and mitochondria, but that other cells are resistant to its apoptogenic activity. The system described offers a novel, simple approach for investigating regulation of apoptosis by cytochrome c and provides a model linking growth factor signaling to metabolism, survival, and apoptosis control.

© 1998 by The American Society of Hematology.

Cytochrome c Induces Caspase-Dependent Apoptosis in Intact Hematopoietic Cells and Overrides Apoptosis Suppression Mediated by bcl-2, Growth Factor Signaling, MAP-Kinase-Kinase, and Malignant Change

It has been shown that cytochrome c is released from mitochondria during apoptosis, activates pro-caspase CPP32 (caspase III), and induces DNA fragmentation in mixtures of cytosolic extracts and isolated nuclei. To establish whether cytochrome c can primarily induce apoptosis in intact cells, we used direct electroporation of cytochrome c into murine interleukin-3 (IL-3)–dependent cells. Electroporation of micromolar external concentrations of cytochrome c rapidly induced apoptosis (2 to 4 hours) that was concentration-dependent, did not affect mitochondrial transmembrane potential, and was independent of cell growth. Only certain isoforms of cytochrome c were apoptogenic; yeast cytochrome c and other redox proteins were inactive. Cytochrome c-induced apoptosis was dependent on heme attachment to the apo-enzyme and was completely abolished by caspase inhibitors. Nonapoptogenic isoforms of cytochrome c did not compete for apoptogenic cytochrome c. Although apoptosis induced by IL-3 withdrawal was inhibited by bcl-2 overexpression and expression of an activated MAP-kinase-kinase (MAP-KK), cytochrome c induced apoptosis in the presence of IL-3 signaling, bcl-2 over-expression, expression of activated MAP-KK, and the combined antiapoptotic action of all three. Cytochrome c also induced apoptosis in the leukemic cell line WEHI 3b. However, human HL60 and CEM cells were resistant to cytochrome c-induced apoptosis. HL60 cells did not electroporate, but CEM cells were efficiently electroporated. Our studies with IL-3–dependent cells confirm that the apoptogenic attributes of cytochrome c are identical in intact cells to those in cell extracts. We conclude that cytochrome c can be a prime initiator of apoptosis in intact growing cells and acts downstream of bcl-2 and mitochondria, but that other cells are resistant to its apoptogenic activity. The system described offers a novel, simple approach for investigating regulation of apoptosis by cytochrome c and provides a model linking growth factor signaling to metabolism, survival, and apoptosis control.

© 1998 by The American Society of Hematology.

Interleukin-3: Promises and Perspectives

Interleukin-3 (IL-3) is a multipotent hematopoietic growth factor produced by activated T-cells, monocytes/macrophages and stroma cells. Human IL-3 gene is located on chromosome 5 near segment 5q31. The high affinity receptor for human IL-3 is composed of alpha and beta subunits. IL-3 shares common beta subunit with GM-CSF and IL-5 which has been mapped to chromosome 22q13.1. The biological effects of IL-3 have been studied in human and murine hematopoietic cell lines and normal human bone marrow cells. Addition of IL-3 to the culture medium induces proliferation, maturation and probably self renewal of pluripotent hematopoietic stem cells and cells of myeloid, erythroid and megakaryocytic lineages. Various clinical trials have assessed the in vivo potential of recombinant human interleukin 3 (rhIL-3). Initial results of phase I/II studies of IL-3 at a dose of 5-10 ug/kg subcutaneous (s/c) daily for 5-10 days in patients with relapsed lymphomas, small cell lung cancer, breast cancer and ovarian cancer have shown that post-chemotherapy application of IL-3 reduces chemotherapy delays and induces faster regeneration of granulocytes and platelets. However, these results were not confirmed in phase III studies. The role of IL-3 alone in the treatment of myelodysplastic syndromes (MDS), aplastic anemia (AA) and other bone marrow failure disorders have also been disappointing. However, preliminary studies of IL-3 in combination with chemotherapeutic agents and immunosuppression have demonstrated encouraging results in patients with MDS and aplastic anemia respectively. The therapeutic potential of IL-3 in peripheral blood stem cell harvesting and priming of stem cells before harvest is beginning to be identified. Initial results of IL-3 in combination with granulocyte macrophage colony stimulating factor (GM-CSF) or later acting growth factor like granulocyte colony stimulating factor (G-CSF) have yielded larger amounts of peripheral blood stem cells during PBSC harvesting. This approach and application of IL-3 with cocktail of other cytokines for ex-vivo expansion of stem cells, dendritic cell development and gene transfer requires further evaluation. The role of IL-3 in murine models of antiphospholipid syndrome (APLS) for prevention of recurrent abortion remains experimental and warrants careful assessment of adverse effects of IL-3 therapy on pregnant woman and fetus. The exact therapeutic role of IL-3 in oncology and nononcology patients is beginning to be identified. It appears that future application of IL-3 in combination with other cytokines is an attractive way forward in the prevention of treatment related mortality and morbidity in oncology patients. It also holds prospects for development of new therapeutic strategies for dose escalation and immune modulation for relapsed cancer patients.

Use of embryonal stem cells in studies of molecular haemopoiesis

Although the cell biology of haemopoietic stem cells (HSC) is relatively well understood, their molecular control is less well defined. Due to the rarity of this cell type, their incompletely defined phenotype and difficulty in generating null alleles by somatic transgenesis of HSC, alternative approaches to their study have been sought. Embryonal stem (ES) cells are toti-potential, can transmit transgenes through the germ line and have recently been shown to produce HSC in vitro. This chapter reviews the utility of gene knock-outs in ES cells in the study of molecular haemopoiesis, indicates how ES cells can be used in vitro as a strategy both for the identification of genes controlling early haemopoietic events and the analysis of their function, and outlines how emerging techniques that exploit the biology of ES cells might prove to be powerful tools in the genetic dissection of the mechanisms controlling haemopoiesis.