Murine Flt3, a gene encoding a novel tyrosine kinase receptor of the PDGFR/CSF1R family.

Receptor-type tyrosine kinases presenting an extracellular region with five immunoglobulin-like domains, and strongly related by sequence similarities in the intracellular region, constitute a family of receptors involved in development and function of various cell lineages. We have isolated and characterized the mouse Flt3 gene, encoding the sixth member of this family. The Flt3 gene possesses an open reading frame of 3000 nucleotides, and therefore appears to code for a protein of 1000 amino acids. The deduced structure of the FLT3 protein presents all the characteristics of a receptor-type kinase of this family. The gene is expressed in placenta, in various adult tissues including gonads and brain, and in hematopoietic cells. The Flt3 transcript is 3.7 kb long, except in the testis, where two shorter post-meiotic transcripts are detected. These results suggest a role for this novel receptor and its yet unidentified ligand in placenta, gonads and hematopoietic and nervous systems.

Close physical linkage of the FLT1 and FLT3 genes on chromosome 13 in man and chromosome 5 in mouse.

Receptor-type tyrosine kinases (RTK) with five or seven immunoglobulin-like domains in their extracellular region are encoded by genes grouped in clusters. In human, two such clusters have been individualized, in chromosomal regions 4q11-q12 and 5q33-qter respectively. We define here a third cluster located on chromosome 13q and containing two contiguous RTK genes, FLT1 and FLT3. The former has recently been shown to encode a RTK of a new class while the latter codes for a hematopoietic receptor closely related to the products of the FMS and KIT genes. The physical linkage is also evidenced in mouse, where the two genes appear to lie within a 350 kb Mlu I fragment, on mouse chromosome 5.

Biochemical characterization and analysis of the transforming potential of the FLT3/FLK2 receptor tyrosine kinase.

We recently cloned an additional member of the receptor type tyrosine kinase class III. This new gene, called Flt3 by our group [Rosnet, O., Matteï, M.G., Marchetto, S. & Birnbaum, D. (1991). Genomics, 9, 380-385; Rosnet, O., Marchetto, S., deLapeyriere, O. & Birnbaum, D. (1991). Oncogene, 6, 1641-1650] and Flk2 by others [Matthews, W., Jordan, C.T., Wieg, G.W., Pardoll, D. & Lemischka, I.R. (1991). Cell, 65, 1143-1152] is strongly related to the important developmental genes Kit, Fms and Pdgfr. The murine 3.2-kb full-length cDNA, when introduced into COS-1 cells, shows the expression of two polypeptides with apparent molecular weights of 155 kDa and 132 kDa. Treatment of cells with N-linked glycosylation inhibitors results in the expression of a 110-kDa protein. We have shown that FLT3 contains an intrinsic tyrosine kinase activity. A point mutation in a highly conserved residue within the phosphoryltransferase domain inactivates the catalytic function of this receptor, whereas activation by way of a chimeric molecule between the ligand-binding domain of colony-stimulating factor type 1 (CSF-1) receptor (CSF-1R) and the kinase domain of FLT3 results, in the presence of CSF-1, in the development of the transforming activity of this receptor as shown by anchorage-independent cell growth. Finally, expression analysis of the FLT3 protein shows that, in addition to the hematopoietic system, FLT3 is strongly expressed in neural, gonadal, hepatic and placental tissues in the mouse.

Tyrosine phosphorylation and complex formation of Cbl-b upon T cell receptor stimulation.

Cbl-b, a mammalian homolog of Cbl, consists of an N-terminal region (Cbl-b-N) highly homologous to oncogenic v-Cbl, a Ring finger, and a C-terminal region containing multiple proline-rich stretches and potential tyrosine phosphorylation sites. In the present study, we demonstrate that upon engagement of the T cell receptor (TCR), endogenous Cbl-b becomes rapidly tyrosine-phosphorylated. In heterogeneous COS-1 cells, Cbl-b was phosphorylated on tyrosine residues by both Syk- (Syk/Zap-70) and Src- (Fyn/Lck) family kinases, with Syk kinase inducing the most prominent effect. Syk associates and phosphorylates Cbl-b in Jurkat T cells. A Tyr-316 Cbl-binding site in Syk was required for the association with and for the maximal tyrosine phosphorylation of Cbl-b. Mutation at a loss-of-function site (Gly-298) in Cbl-b-N disrupts its interaction with Syk. Cbl-b constitutively binds Grb2 and becomes associated with Crk-L upon TCR stimulation. The Grb2- and the Crk-L-binding regions were mapped to the C-terminus of Cbl-b. The Crk-L-binding sites were further determined to be Y655DVP and Y709KIP, with the latter being the primary binding site. Taken together, these results implicate that Cbl-b is involved in TCR-mediated intracellular signaling pathways.

Role of tyrosine residues and protein interaction domains of SHC adaptor in VEGF receptor 3 signaling.

The VEGFR3/FLT4 receptor, which is involved in vasculogenesis and angiogenesis, binds and phosphorylates SHC proteins on tyrosine residues. SHC contains two phosphotyrosine interaction domains: a PTB (Phosphotyrosine Binding) and a SH2 (Src Homology 2) domain. Previous studies have shown that SHC proteins are phosphorylated on Y239/Y240 and Y313 (Y317 in humans) by tyrosine kinases such as the EGF and IL3 receptors. We have investigated which of the SHC tyrosine residues are targeted by the VEGFR3/ FLT4 kinase and the role of the SHC PTB and SH2 domains in this process. Our results show that Y239/ Y240 and Y313 are simultaneously phosphorylated by the kinase, creating GRB2 binding sites. Mutation of SHC PTB, but not SH2, domain interferes with the SHC phosphorylation by VEGFR3/FLT4. Soft agar assay experiments revealed that the VEGFR3/FLT4 transforming capacity is increased by the mutation of Y239/Y240 to phenylalanines in SHC, suggesting that these two residues mediate an inhibitory signal for cell growth. Mutation of the two phosphorylation sites increases this effect, suggesting that they have a synergistic role.

The FLT4 gene encodes a transmembrane tyrosine kinase related to the vascular endothelial growth factor receptor.

Three receptor tyrosine kinases, FLT1, FLK1 and FLT4, contain seven immunoglobin-like domains in their extracellular region and are strongly related by sequence similarities to each other and, to a lesser degree, to the class III receptors CSF1R/FMS, PDGFR, SLFR/KIT and FLT3/FLK2. They constitute a family of receptors putatively involved in the growth regulation of endothelial cells. We describe here the structure and pattern of expression of the human FLT4 gene. Two FLT4 transcripts of 5.8 and 4.5 kb are expressed in the human placenta and several hematopoietic cell lines. In mouse, a 5.8-kb transcript is expressed in a variety of tissues. A translational product 1298 amino acids in length is predicted to be encoded by the largest open reading frame. The FLT4 protein, when transiently expressed in Cos-7 cells and immunoprecipitated with a FLT4-specific rabbit immune serum, has an apparent molecular weight of 170 kDa.

Structure, chromosome mapping and expression of the murine Fgf-6 gene.

The sixth member of the fibroblast growth factor gene family was cloned and analysed in the mouse. It is composed of three coding exons and encodes a putative growth protein of 198 amino acids, possessing a potential signal peptide, and presenting 79% and 93.5% sequence similarity with the mouse Hst/K-fgf and human FGF-6 genes products, respectively. The murine Fgf-6 gene is located in a region distinct from the Int-41 locus and belongs to a linkage group conserved between chromosome 12 in man and chromosome 6 in mouse. It presents an intrinsic oncogenic capacity since it is able to transform cultured fibroblasts. Fgf-6 mRNA levels are developmentally regulated with a peak of expression in the developing fetus at day 15.5 of gestation, moderate levels during late gestation and in the neonate. In the adult, Fgf-6 mRNA can be detected in testis, heart and skeletal muscle.

FLT3 signaling in hematopoietic cells involves CBL, SHC and an unknown P115 as prominent tyrosine-phosphorylated substrates.

Proliferation and survival of hematopoietic progenitors are partially dependent on the interaction between the FLT3 receptor tyrosine kinase (RTK) and its ligand, FL. This biological function depends primarily on tyrosine phosphorylation of cellular targets that initiate several transduction cascades. These events return to their basal levels upon activation of specific phosphatases. We analyzed tyrosine phosphorylation events in response to FL, in human cell lines of different hematopoietic origins that express endogenous FLT3, namely the myelomonocytic, monocytic, pre-B and pro-B lineages. This study aimed at determining (1) the identity of FLT3 downstream substrates in physiologically relevant cells and (2) distinct substrate involvement in myeloid or early B cells. The two prominent tyrosine-phosphorylated proteins are p52SHC and p115CBL in myeloid cell lines and p52SHC and an uncharacterized p115 in early B cell lines. Following FL stimulation, a concomitant increase in both CBL phosphorylation and complex formation with p85 subunit of phosphatidylinositol 3' kinase is observed. In contrast, the GRB2/CBL association observed in unstimulated cells is not modified after stimulation, and SHC is never detected in anti-CBL immunoprecipitates. FL-inducible binding of CBL to the CRKII adaptor molecule is also demonstrated. This study presents a picture of the signaling events triggered by activation of endogenous FLT3 receptor in human hematopoietic cells, including the existence of a B cell-specific FLT3 substrate.

Expression of the FLT3 gene in human leukemia-lymphoma cell lines.

The FLT3 gene encodes a protein that appears to function as a receptor for a hematopoietic growth factor; together with the KIT and FMS receptors, FLT3 belongs to the superfamily of receptors with tyrosine kinase activity. We examined the expression of FLT3 mRNA in 36 human leukemia-lymphoma cell lines using Northern blot analysis. FLT3 transcripts were found in seven of seven pre B-ALL cell lines (derived from cases with pre B-acute lymphoblastic leukemia or chronic myeloid leukemia in lymphoid blast crisis), and in one of six B-cell lines (namely in a cell line established from a hairy cell leukemia). FLT3 message was not detected in five T-cell, five myeloid, four monocytic, four erythroid and five megakaryocytic cell lines. Two major mRNA species were expressed differentially by positive cell lines. KIT mRNA expression was also investigated in the same panel of cell lines, but was found only in cell lines with erythroid and megakaryocytic features (and not in any of the FLT3-positive cell lines). The pattern of expression of FLT3 contrasts with the transcription of FMS and KIT and suggests that the FLT3 product may play a role primary in immature lymphoid cells.

Expression of FLT3 receptor and FLT3-ligand in human leukemia-lymphoma cell lines.

The FLT3 gene encodes a receptor tyrosine kinase that is closely related to two well-known receptors, KIT and FMS, that regulate with their respective ligands, stem cell factor (SCF) and macrophage colony-stimulating factor (M-CSF), proliferation and differentiation of hematopoietic cells. The ligand for FLT3, FL, is active in both soluble and membrane-bound forms. We examined expression of FL and FLT3 mRNA in a panel of some 110 continuous human leukemia-lymphoma cell lines from all major hematopoietic cell lineages by Northern blot analysis. FLT3 mRNA is expressed primarily in pre-B cell lines, myeloid and monocytic cell lines whereas FL mRNA was detected in most cell lines from all cell lineages. Analysis of FLT3 receptor protein expression examined with a specific anti-FLT3 monoclonal antibody and flow cytometry in 17 cell lines confirmed the results obtained at the mRNA level. Forty of 110 cell lines displayed both receptor and ligand mRNA suggesting a possible autocrine or intracrine stimulation. In normal hematopoietic cells expression of FLT3 was reported to be associated with CD34 positivity, a cell surface marker of immature and precursor cells. No correlation between FLT3 and CD34 expression was found in the cell lines analyzed. These studies served to illustrate further the importance of the FL-FLT3 ligand-receptor system in the regulation of hematopoietic cells.

SHC and SHIP phosphorylation and interaction in response to activation of the FLT3 receptor.

The FLT3 receptor tyrosine kinase and its ligand, FL, regulate the development of hematopoietic stem cells and early B lymphoid progenitors. FL has a strong capacity to boost production of dendritic and natural killer cells in vivo, thereby providing a new and promising tool for anti-cancer immunotherapy. Intracellular FLT3 signaling involves tyrosine phosphorylation of several cytoplasmic proteins including SHC. We have found that upon FLT3 activation SHC phosphorylation occurs at tyrosine 239/240 and 313. SHC possesses two phosphotyrosine-binding domains: an amino-terminal phosphotyrosine binding (PTB) and a carboxy-terminal Src Homology 2 (SH2) domain. Neither is required for SHC phosphorylation, but the PTB domain is necessary and sufficient for SHC binding to the SH2 containing inositol phosphatase (SHIP). Overexpression of SHC increases the level of SHIP phosphorylation on tyrosines in response to FLT3 activation, suggesting that SHC availability is a limiting step for SHIP phosphorylation. This effect is observed only if the SHC PTB domain is functional. Interestingly, SHC overexpression in FLT3-activatable Ba/F3 cells limits FLT3-dependent cell growth and this effect requires tyrosine 313. Taken together, the present data show that SHC can antagonize cell proliferation induced by FLT3 stimulation and regulate phosphorylation of the SHIP negative regulator. In addition, our study provides the structural bases for SHC phosphorylation and formation of the SHC/SHIP complex.

Human FLT3/FLK2 receptor tyrosine kinase is expressed at the surface of normal and malignant hematopoietic cells.

FLT3/FLK2 is a receptor tyrosine kinase (RTK) which is thought to play an important role in early stages of hematopoiesis. Monoclonal antibodies (mAbs) against the extracellular domain of human FLT3 were generated to study the cell surface expression of this class III RTK on normal bone marrow cells and on leukemic blasts from patients with acute leukemias. Functional analysis of five mAbs (SF1 series) revealed that all of them can mimic to variable extents the activity of the FLT3 ligand (FL) upon receptor activation and modulation, while only one mAb weakly inhibited ligand binding. Using flow cytometry, we detected surface expression of FLT3 on cell lines of the myeloid (4/8) and B lymphoid (7/10) lineages. On normal human bone marrow cells, the expression of FLT3 is restricted, in agreement with a presumed function of this receptor at the level of the stem cells and early committed progenitors. Expression of FLT3 was found on a fraction of CD34-positive and CD34-negative cells. Three-color analysis further revealed that most of the CD34 FLT3+ cells coexpress CD117 (KIT) at a high level. Finally, FLT3 is expressed on leukemic blasts of 18/22 acute myeloid leukemias (AML) and 3/5 acute lymphoid leukemias (ALL) of the B lineage, providing a possible application in diagnosis and therapy of these diseases.

Effects of FLT3 ligand on human leukemia cells. I. Proliferative response of myeloid leukemia cells.

The growth of cells in vitro and in vivo is regulated by several environmental signals among which growth factors (cytokines) figure prominently. FLT3 is a novel cytokine receptor with intrinsic ligand-stimulated (FLT3 ligand, FL) tyrosine kinase activity. Here, using a specific anti-FLT3 monoclonal antibody (McAb) and flow cytometry we determined the expression pattern of the receptor protein in 55 human leukemia-lymphoma cell lines and in 20 primary samples from patients with acute lymphoblastic leukemia (ALL) or acute myeloid leukemia (AML). FLT3 receptor surface expression was found predominantly in pre-B cell, myeloid and monocytic cell lines and in pre-B-ALL and AML cells, FL was overexpressed in baby hamster kidney cells producing a recombinant protein that was functional in receptor binding and signaling. Incubation with FL induced 3H-thymidine uptake-measured proliferation in some myeloid cell lines and in 2/9 AML cases. The strongest proliferative response was seen in the two growth factor-dependent myeloid leukemia cell lines MUTZ-2 and OCI-AML-5. Long-term substitution of the commonly used cytokines with FL sustained the continuous proliferation of these two cell lines suggesting that also upon permanent activation FLT2 can function as a mitogenic signaling molecule. Despite the high density of FLT3 receptor expression on cultured and fresh pre-B-ALL cells, no proliferation could be stimulated in any of these specimens. Incubation with the anti-FLT3 McAb had agonistic proliferative effects in MUTZ-2 and OCI-AML-5; and anti-FL reagent blocked FL-stimulated proliferation. To summarize, we demonstrated that FL is effective in inducing proliferation of leukemic myeloid cells and that protein expression does not necessarily indicate an FL-responsive cell. While the present data clearly demonstrate that FL might play a proliferative role in leukemogenesis, further studies are needed to clarify whether the signals provided by FL:FLT3 interaction are confined to a proliferation-inducing function or whether maturational progression could also be elicited in certain cells.

Colony-forming cells expressing high levels of CD34 are the main targets for granulocyte colony-stimulating factor and macrophage colony-stimulating factor in the human fetal liver.

The effects of the granulocyte (G) and macrophage (M) colony-stimulating factors (CSFs) on the growth of purified subpopulations of human fetal liver progenitors were investigated. In contradiction to the characterization of these cytokines as CSFs acting late in the course of hematopoiesis, both G-CSF and M-CSF were most potent in promoting the growth of fetal liver colony-forming cells (CFCs) that express high levels of CD34 and CD38 (CD34++CD38+) and are depleted of cells expressing a panel of lineage markers (Lin-). Cultures of these cells in serum-deprived conditions generated a mean of 11.2 and 39.1 low-proliferative potential (LPP)-CFCs per 1.0 x 10(3) CD34++CD38+Lin- cells grown in G-CSF and M-CSF, respectively. Cultures of more mature progenitors, isolated based on a lower level of CD34 expression (CD34+ Lin-), generated few LPP-CFCs and 6.3 and 4.7 clusters per 1.0 x 10(3) CD34+Lin- cells in response to G-CSFs and M-CSF, respectively. G-CSF was also found to synergistically enhance colony growth by either kit-ligand (KL) or fit-3/flk-2 ligand (FL) in cultures of CD34++CD38+Lin- cells as well as the more primitive compartment of CD34++CD38-Lin- cells. Synergism between G-CSF and KL or FL was also observed in liquid cultures of CD34++CD38-Lin- cells. The effects of G-CSF on CD342++CD38-Lin- cells were further demonstrated by the ability of G-CSF to support the short-term survival of these cells in clonal cultures. In contrast, M-CSF did not affect the growth or survival of CD34++CD38-Lin- cells, a finding that was also supported by the observation that the receptor for M-CSF (CD115 or fms) was only expressed on CD34++CD38+Lin- cells. G-CSF receptor expression and flt-3/flk-2 expression were detected by flow cytometry on both the CD38- and CD38+ subpopulations of CD34++Lin- cells, but these receptors were not detected on CD34+ cells. Receptors for KL (CD117) and interleukin-3 (CD123), for which the ligands are active on a broad range of fetal liver progenitors, were detected on cells expressing both high and low levels of CD34. These data help to define the potential roles of cytokines in human fetal hematopoiesis.

Genomic structure of the downstream part of the human FLT3 gene: exon/intron structure conservation among genes encoding receptor tyrosine kinases (RTK) of subclass III.

The FLT3 gene encodes a subclass-III receptor tyrosine kinase (RTKIII). We have determined the structural organization of the downstream part of the human FLT3 gene (also designated dsp-FLT3) that corresponds to the intracellular region of the protein. The coding region is spread over twelve exons spanning 10 kb of genomic DNA. Exon sizes range from 83 to 154 bp, while intron sizes range from 86 bp to more than 1.9 kb. Comparison with the corresponding domain of other RTKIII genes (KIT and FMS) shows that these genes share the same number of exons, which are highly conserved in size, sequence and exon/intron boundary positions. In addition, the intron phase of equivalent introns of FLT3, KIT and FMS are all identical. Our results reinforce our hypothesis based initially only on the KIT and FMS comparison showing that RTKIII genes share a common structural organization and have evolved from a common ancestor gene by cis and trans duplication. Comparison of the genomic organization of the intracellular-encoding part of RTKIII genes with that of RTKI, II and IV genes shows that subclasses III and IV are the most closely related.

Isolation and sequence of the murine Fgf6 cDNA.

We have studied the structure of the murine Fgf6 gene encoding a fibroblast growth factor with the purpose of looking for putative regulatory sequences in the 5' and 3' non-coding regions. The Fgf6 cDNA contains a very long 3' untranslated portion of 4015 nucleotides.

A third human CBL gene is on chromosome 19.

CBL genes encode cytoplasmic proteins involved in signal transduction downstream of a number of receptors including tyrosine kinases, cytokine receptors, and T-cell or B-cell receptors. They seem to be transducers associated with negative regulation of signals, and, as such, may be potential tumor suppressors. Using a probe derived from an expressed sequence tag, we isolated a cosmid containing part of a new CBL gene, CBLc, related to the two characterized paralogous genes CBLa and CBLb. Using the cosmid in fluorescence in situ hybridization of human metaphase chromosomes, we localized the CBLc gene to band 13.2 of chromosome 19. We show that the 19q12.2-13.3 region where CBLc is located shows paralogy with two other regions of the human genome, 3q22-q27 and 11q22-q24 where CBLb and CBLa are located, respectively. Genes from several other families are located in these regions.

The expression of FMS, KIT and FLT3 in hematopoietic malignancies.

Three receptor molecules, belonging to the class III of receptor tyrosine kinases, namely the receptors for colony-stimulating factor 1, CSF1R (product of the FMS proto-oncogene) and Steel factor, SLFR (product of the KIT proto-oncogene), as well as the recently identified FLT3/FLK2 gene product, appear to play distinct roles in normal hematopoietic differentiation. Their potential role in leukemic hematopoiesis has been approached by expression studies in hematopoietic malignancies, especially in acute leukemias of the myeloid and lymphoid lineages. We present here a review of available data, and discuss the possible significance and potential applications of these results.

Tumorigenicity assay of the human mammary carcinoma cell line MCF-7.

A tumorigenicity assay was performed using DNA extracted from the human mammary carcinoma cell line MCF-7. Seven nude mouse tumors were obtained and were analyzed for the presence of human sequences and known activated oncogenes. The c-erbB.2/neu gene was identified in two tumors and two ras oncogenes in two other tumors. In order to characterize the mechanism of activation of the c-erbB.2/neu oncogene, we isolated and analyzed this gene from one of the tumors. The cloned gene did not present any rearrangement. c-erbB.2/neu transcripts from the nude mice tumors were of normal size. In one case overexpression was observed.