Leukocyte tyrosine kinase (LTK) is a receptor tyrosine kinase that belongs to the insulin receptor family. LTK is mainly expressed in pre B cells and brain. Previously we cloned the full-length cDNA of human LTK, but no ligands have so far been identified, and hence, very little is known about the physiological role of LTK. To analyze the function of the LTK kinase, we constructed chimeric receptors composed of the extracellular domain of epidermal growth factor receptor and the transmembrane and the cytoplasmic domains of LTK and established cell lines that stably express these chimeric molecules. When cultured in medium containing EGF, growth of these cell lines was stimulated, and these fusion proteins became autophosphorylated and associated with Shc in vivo in a ligand-dependent manner. By treatment with EGF, Shc was associated with the Grb2/Ash-Sos complex. Our analyses demonstrate that LTK associates with Grb2/Ash through an internal adaptor, Shc, depending on a ligand stimulation. The LTK binding site for Shc was tyrosine 862 at the carboxyl-terminal domain and to a lesser extent tyrosine 485 at the juxtamembrane domain. Both of them are located in NP/AXY motif which is consistent with binding sites for Shc. These findings demonstrate that LTK can activate the Ras pathway in a ligand-dependent manner and that at least one of the functions of this kinase is involved in the cell growth. Leukocyte tyrosine kinase (LTK) is a receptor tyrosine kinase that belongs to the insulin receptor family. LTK is mainly expressed in pre B cells and brain. Previously we cloned the full-length cDNA of human LTK, but no ligands have so far been identified, and hence, very little is known about the physiological role of LTK. To analyze the function of the LTK kinase, we constructed chimeric receptors composed of the extracellular domain of epidermal growth factor receptor and the transmembrane and the cytoplasmic domains of LTK and established cell lines that stably express these chimeric molecules. When cultured in medium containing EGF, growth of these cell lines was stimulated, and these fusion proteins became autophosphorylated and associated with Shc in vivo in a ligand-dependent manner. By treatment with EGF, Shc was associated with the Grb2/Ash-Sos complex. Our analyses demonstrate that LTK associates with Grb2/Ash through an internal adaptor, Shc, depending on a ligand stimulation. The LTK binding site for Shc was tyrosine 862 at the carboxyl-terminal domain and to a lesser extent tyrosine 485 at the juxtamembrane domain. Both of them are located in NP/AXY motif which is consistent with binding sites for Shc. These findings demonstrate that LTK can activate the Ras pathway in a ligand-dependent manner and that at least one of the functions of this kinase is involved in the cell growth.
PROLIFERATION AND DIFFERENTIATION Blood cells are generally classified into three cell lineages: erythrocytes, granulocytes and megakaryocytes.In the bone marrow, pluripotent stem cells differentiate into either the lymphoid stem cell line, where they are further induced to differentiate into B-or T-derived lymphocytes, or the myeloid stem cell (CFU-GEMM) line, where they are further induced to become erythrocytes, granulocytes (neutrophils, eosinophils or basophils), macrophages or megakaryocytes (platelets).Proliferation and differentiation of blood cells in the bone marrow are regulated by hemopoietic factors.Hemopoietic factors include those that are continuously produced, such as EPO, G-CSF and thrombopoietin (TPO), and those that are produced on demand in response to inflammation and infection, such as IL-3, IL-11 and GM-CSF.In recent years the genes for hemopoietic factors which regulate erythrocytes and granulocytes have been cloned using the techniques of genetic engineering.In 1994 the gene for TPO was cloned.TPO acts specifically on megakaryocytes.
Leukocyte tyrosine kinase (LTK) is a receptor tyrosine kinase, which belongs to the insulin receptor family and is mainly expressed in pre-B cells and brain. In this study, we show that LTK utilizes insulin receptor substrate-1 (IRS-1) and Shc as major two substrates and possesses two NPXY motifs for them separately, tyrosine 485 of one NPXY motif at the juxtamembrane domain for IRS-1 and tyrosine 862 of another NPXY motif at the carboxyl-terminal domain for Shc. By using Ba/F3 cells expressing epidermal growth factor receptor-LTK chimeric receptors containing a mutation at each NPXY site, we showed that while both NPXY motifs equally contribute to activation of the Ras pathway and generation of mitogenic signals, only tyrosine 485 of LTK transmits cell survival signals. These data suggest that IRS-1 possesses anti-apoptotic function at least in LTK signaling. Moreover, our data indicate that the survival signaling pathway of LTK is distinct from the Ras pathway and the p70S6 kinase pathway. Our results provide a useful insight in understanding the distinctive roles of Shc and IRS-1 in the signal transduction system of the insulin receptor family, and this anti-apoptotic function of IRS-1 may explain the survival effects of insulin, IGF-1, and interleukin 4. Leukocyte tyrosine kinase (LTK) is a receptor tyrosine kinase, which belongs to the insulin receptor family and is mainly expressed in pre-B cells and brain. In this study, we show that LTK utilizes insulin receptor substrate-1 (IRS-1) and Shc as major two substrates and possesses two NPXY motifs for them separately, tyrosine 485 of one NPXY motif at the juxtamembrane domain for IRS-1 and tyrosine 862 of another NPXY motif at the carboxyl-terminal domain for Shc. By using Ba/F3 cells expressing epidermal growth factor receptor-LTK chimeric receptors containing a mutation at each NPXY site, we showed that while both NPXY motifs equally contribute to activation of the Ras pathway and generation of mitogenic signals, only tyrosine 485 of LTK transmits cell survival signals. These data suggest that IRS-1 possesses anti-apoptotic function at least in LTK signaling. Moreover, our data indicate that the survival signaling pathway of LTK is distinct from the Ras pathway and the p70S6 kinase pathway. Our results provide a useful insight in understanding the distinctive roles of Shc and IRS-1 in the signal transduction system of the insulin receptor family, and this anti-apoptotic function of IRS-1 may explain the survival effects of insulin, IGF-1, and interleukin 4.
Leukocyte tyrosine kinase (LTK) is a tyrosine kinase that has been suggested to be specific for hematopoietic cells and neuronal cells and reported as an unusual membrane protein lacking an extracellular domain. Here we report the cloning of a human LTK cDNA clone containing the complete open reading frame of a putative receptor tyrosine kinase protein. The extracellular domain of the receptor protein is larger than previously predicted. Furthermore, we have cloned a set of cDNAs representing differently spliced human LTK mRNAs. These cDNAs predict a truncated receptor protein lacking the tyrosine kinase domain and a soluble receptor protein that has neither a transmembrane nor a tyrosine kinase domain. Our results suggest that the LTK gene produces not only the putative receptor tyrosine kinase for unknown ligand but also multiple protein products that may have different functions.
HEMOPOIETIC FACTORS AND BLOOD CELL PROLIFERATION AND DIFFERENTIATION: Blood cells are generally classified into three cell lineages: erythrocytes, granulocytes and megakaryocytes. In the bone marrow, pluripotent stem cells differentiate into either the lymphoid stem cell line, where they are further induced to differentiate into B- or T-derived lymphocytes, or the myeloid stem cell (CFU-GEMM) line, where they are further induced to become erythrocytes, granulocytes (neutrophils, eosinophils or basophils), macrophages or megakaryocytes (platelets). Proliferation and differentiation of blood cells in the bone marrow are regulated by hemopoietic factors. Hemopoietic factors include those that are continuously produced, such as EPO, G-CSF and thrombopoietin (TPO), and those that are produced on demand in response to inflammation and infection, such as IL-3, IL-11 and GM-CSF. In recent years the genes for hemopoietic factors which regulate erythrocytes and granulocytes have been cloned using the techniques of genetic engineering. In 1994 the gene for TPO was cloned. TPO acts specifically on megakaryocytes. PROLIFERATION AND DIFFERENTIATION OF ERYTHROCYTIC CELLS: The earliest cells destined to become erythrocytes which differentiate from the myeloid stem cells (CFU-GEMM) are early phase erythroblast progenitor cells called BFU-E cells. After the BFU-E cells have undergone several divisions, they differentiate into late phase erythroblast progenitor cells called CFU-E cells. After passing through the proerythroblast stage, the CFU-E cells become erythroblasts. Erythroblasts can be confirmed by light microscope as belonging to the erythroid cell line. Erythroblasts mature and become enucleated reticulocytes, which are then released from the bone marrow into the blood, thus becoming mature erythrocytes. Proliferation and differentiation of the erythroid progenitor cells are regulated by erythropoietin (EPO), which is primarily produced by the kidneys. In 1985 genomic DNA and cDNA for human EPO were cloned, and it was learned that the mature protein is a glycoprotein consisting of 165 amino acids and having a molecular weight of about 30,000. There is powerful evidence to suggest that EPO is produced by peritubular cells of the renal cortex. When the hematocrit drops for some reason and hypoxia occurs, the number of EPO-producing cells increases and EPO production rises in the kidneys. CFU-E cells are the main target cells for EPO. EPO receptors are expressed along the lineage from BFU-E cells to proerythroblasts, with peak expression found in CFU-E cells. The EPO receptor, which was cloned in 1989, belongs to the cytokine receptor family, transduces the EPO signal to the interior of the cell, and brings about the proliferation and differentiation of CFU-E cells. PROLIFERATION AND DIFFERENTIATION OF GRANULOCYTIC CELLS: The earliest cells destined to become neutrophils and macrophages which differentiate from the pluripotent stem cells are called granulocyte-macrophage progenitor (CFU-GM) cells. The CFU-GM cells are affected by colony-stimulating factors and become either CFU-G or CFU-M cells. Ultimately, they differentiate into mature neutrophils or macrophages. The main factor stimulating the proliferation and differentiation of neutrophils is the granulocyte colony-stimulating factor (G-CSF). CFU-GM cells are stimulated by G-CSF in the bone marrow, pass through the CFU-G stage, and become myeloblasts, which are the most primitive neutrophils that can be morphologically distinguished. Myeloblasts continue to divide and differentiate, and they mature into neutrophils, which then lose their ability to divide. Mature neutrophils are not immediately released into the blood, but rather are stored within the bone marrow. Neutrophils that have been released into the blood reside in the marginal granulocyte pool or the circulating granulocyte pool, and they later egress into tissues. G-CSF is produced by cells such as monocytes, macrophages and bone marrow stromal cells, and its action is almost entirely selective for the proliferation of neutrophils. The cDNA for G-CSF was cloned in 1986, and it was learned that the mature protein is a glycoprotein consisting of 174 amino acids and having a molecular weight of about 20,000. When G-CSF is administered to a patient it causes the release of mature neutrophils from the marrow into the peripheral blood. G-CSF also enhances neutrophil function in the presence of bacterial products, and it acts on mature neutrophils to enhance cellular motility, the production of bioactive oxygen, and microbicidal activity. The cDNA for the G-CSF receptor was cloned in 1990, and its receptor belongs to the cytokine receptor family. The human G-CSF receptor consists of 813 amino acids and has an approximate molecular weight of 100,000 to 130,000. The G-CSF receptor signal is mediated by the JAK-1 and JAK-2 tyrosine kinases.
