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Unique Effects of KIT D816V in BaF3 Cells: Induction of Cluster Formation, Histamine Synthesis, and Early Mast Cell Differentiation Antigens¹

Matthias Mayerhofer^*,, Karoline V. Gleixner^*, Andrea Hoelbl, Stefan Florian^*, Gregor Hoermann^*,, Karl J. Aichberger^*, Martin Bilban^,, Harald Esterbauer, Maria-Theresa Krauth^*, Wolfgang R. Sperr^*, Jack B. Longley^¶, Robert Kralovics^||, Richard Moriggl^#, Jacques Zappulla^**, Roland S. Liblau^**, Ilse Schwarzinger, Veronika Sexl, Christian Sillaber^* and Peter Valent^2,*

^* Department of Internal Medicine I, Division of Hematology and Hemostaseology, Clinical Institute for Medical and Chemical Laboratory Diagnostics, and Institute of Pharmacology, Medical University of Vienna, Austria; Ludwig Boltzmann Institute for Clinical and Experimental Oncology and ^¶ Skin Diseases Research Center, Department of Dermatology and Pathology, Columbia University, New York, NY 10027; ^|| Research Center for Molecular Medicine of the Austrian Academy of Sciences and ^# Ludwig Boltzmann Institute for Cancer Research, Vienna, Austria; and ^** Institut National de la Santé et de la Recherche Médicale U563, Centre de Physiopathologie Toulouse Purpan, Purpan Hospital, Toulouse, France

	Abstract

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Oncogenic tyrosine kinases (TK) usually convert growth factor-dependent cells to factor independence with autonomous proliferation. However, TK-driven neoplasms often are indolent and characterized by cell differentiation rather than proliferation. A prototype of an indolent TK-driven neoplasm is indolent systemic mastocytosis. We found that the D816V-mutated variant of KIT, a TK detectable in most patients with systemic mastocytosis, induces cluster formation and expression of several mast cell differentiation and adhesion Ags, including microphthalmia transcription factor, IL-4 receptor, histamine, CD63, and ICAM-1 in IL-3-dependent BaF3 cells. By contrast, wild-type KIT did not induce cluster formation or mast cell differentiation Ags. Additionally, KIT D816V, but not wild-type KIT, induced STAT5 activation in BaF3 cells. However, despite these intriguing effects, KIT D816V did not convert BaF3 cells to factor-independent proliferation. Correspondingly, BaF3 cells with conditional expression of KIT D816V did not form tumors in nude mice. Together, the biologic effects of KIT D816V in BaF3 cells match strikingly with the clinical course of indolent systemic mastocytosis and with our recently established transgenic mouse model, in which KIT D816V induces indolent mast cell accumulations but usually does not induce a malignant mast cell disease. Based on all these results, it is hypothesized that KIT D816V as a single hit may be sufficient to cause indolent systemic mastocytosis, whereas additional defects may be required to induce aggressive mast cell disorders.

	Introduction

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Systemic mastocytosis (SM)³ is a neoplastic disease of mast cells (MC) and their bone marrow-derived progenitors (1, 2). Indolent and aggressive variants of the disease have been described. In most adult patients, indolent systemic mastocytosis (ISM) is diagnosed. These patients usually have typical (urticaria pigmentosa-like) skin lesions and may suffer from mediator-related symptoms, but the disease does not behave as an overt malignancy (3, 4). Rather, despite accumulation of neoplastic MC, these patients have a normal or near-normal life expectancy (4, 5). Clinically, most patients with ISM would even be overlooked if they would not exhibit the striking cutaneous features of mastocytosis. This is not the case in the rare aggressive variant of mastocytosis (ASM) or (the extremely rare) MC leukemia (MCL). In these patients, malignant MC proliferation is found and the survival usually is short (3, 4, 5, 6).

The pathologic hallmark and major (World Health Organization) criterion of disease shared by all SM variants including ASM, MCL, and ISM is the focal accumulation (cluster formation) of MC in hematopoietic tissues (7, 8, 9, 10). However, whereas in ISM, MC accumulations usually remain stable and indolent over many years, the MC infiltration in ASM or MCL is aggressive and leads to organopathy within a short time (1, 2, 5, 6).

A second important feature of SM common to all disease variants is the somatic KIT point mutation D816V, a defect that is not only detectable in ASM or MCL, but also in most patients (>80%) with ISM (11, 12, 13, 14, 15). A number of previous and more recent data suggest that the KIT mutation D816V leads to autonomous tyrosine kinase (TK) activity and enhanced survival of neoplastic cells (16). So far, however, little is known about the exact role and biologic consequences of this mutation in the context of SM. Based on cell line data and studies conducted with the murine equivalent of the mutation (i.e., Kit D814V), the hypothesis was raised that the mutation is directly responsible for the abnormal tumorous proliferation of neoplastic MC (17, 18). However, as mentioned above, patients with ISM do not have malignant disease despite the expression of KIT D816V in their neoplastic MC. Furthermore, we have recently shown that KIT D816V transgenic mice usually develop indolent accumulations (clusters) of MC in internal organs, but only rarely a malignant MC disease (19).

This "paradox" prompted us to revisit the transforming effects of the human KIT mutant D816V. In a first step, we used BaF3 cells since these cells are commonly used to define the "transforming" potential of oncoproteins detectable in myeloid neoplasms. Using BaF3 cells with conditional expression of KIT D816V, we found that this oncoprotein does not provide a growth advantage, but induces differentiation. To confirm this finding, a human myeloid cell line (UT7) was engineered to inducibly express KIT D816V. The results of our study show that KIT D816V induces cluster formation and expression of MC differentiation Ags, but that it does not promote proliferation in BaF3 or UT7 cells, which is in line with the biology and indolent clinical course of ISM.

	Materials and Methods

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Reagents

Imatinib (STI571) and PKC412 were kindly provided by Dr. Elisabeth Buchdunger, Dr. Paul W. Manley, and Dr. Doriano Fabbro (Novartis Pharma). Stock solutions of PKC412 were prepared by dissolving in DMSO (Merck). Recombinant human stem cell factor (SCF) was purchased from Strathmann Biotech, recombinant murine cytokines (IL-3, IL-6, SCF) from PeproTech, RPMI 1640 medium and FCS from PAA Laboratories, puromycin from Invitrogen, hygromycin from Roche, and doxycycline from Clontech.

Generation of BaF3 cells with inducible expression of KIT D816V

BaF3 cells were grown in RPMI 1640 medium with 10% FCS and 10% WEHI-3B conditioned medium (as a source of murine IL-3) at 37°C and 5% CO₂. To generate cell lines with doxycycline-inducible expression of KIT, BaF3 cells expressing the reverse tet-transactivator (Ton.BaF.1 cells) (20) were co-transfected with pTRE2 vector (Clontech) containing KIT D816V cDNA (or wild-type (wt) KIT cDNA) and pTK-Hyg (Clontech) by electroporation. Electroporation was performed as described (21). In brief, plasmids (10 µg each) were transfected into Ton.BaF.1 cells (1 x 10⁷ cells in 800 µl) using a Gene Pulser (0.35 kV, 960 µF) (Bio-Rad). Stably transfected cells were selected by growing in hygromycin (400 µg/ml) and cloned by limiting dilution. Expression of KIT D816V was induced by addition of doxycycline (1 µg/ml). To investigate the role of STAT5 in KIT D816V-dependent signaling, Ton.Kit.D816V cells were retrovirally transduced with two different dominant negative (dn) STAT5 constructs (STAT5a749 or STAT5b754) (22) or with the empty vector. Retroviruses were produced by transient transfection of HEK-293FT cells (Invitrogen) with pMSCV-dnSTAT5-IRES-GFP, pVSV, and pGAG-Pol, using Lipofectamine2000 (Invitrogen) according to published techniques (23). Ton.Kit.D816V cells expressing dnSTAT5 (GFP⁺) were enriched by FACS sorting on a FACSAria (BD Biosciences).

Generation of UT7 cells with inducible expression of KIT D816V

UT7 (kindly provided by Dr. N. Komatsu, Jichi Medical School, Tochigi, Japan) is a human, GM-CSF-dependent myeloid (CD117⁺) cell line (24). UT7 cells were grown in RPMI 1640 medium with 10% FCS in the presence of recombinant human GM-CSF (1 ng/ml; R&D Systems) at 37°C and 5% CO₂. To generate UT7 cells with inducible expression of KIT D816V, cells were retrovirally transduced with pRevTet-On (Clontech) and selected with puromycin (1 µg/ml). To test for doxycycline-inducible gene expression in this cell line model, UT7-Tet-On cells were transduced with the pRevTRE vector (Clontech) containing a GFP cDNA. In these experiments, substantial GFP expression in the absence of doxycycline (indicating leakiness) was observed, confirming results obtained in other cell lines (25). To generate a UT7 cell line with tight doxycycline-dependent regulation of gene expression, the tetracycline repressor fused to the Kruppel-associated box repression domain (KRAB) of human Kox-1 (tTR-KRAB) fusion protein (plasmid pLV-tTR-KRAB, provided by Dr. D. Trono, École Polytechnique Fédérale de Lausanne, Switzerland) (26) was expressed in UT7-Tet-On cells. Binding of KRAB (through the tTR moiety of the fusion protein) to the tet response element of pRevTRE resulted in complete silencing of gene expression in the absence of doxycycline (26, 27). UT7-Tet-On-KRAB cells (termed UT7-tK) were then transduced with pRevTRE-KIT D816V and selected with hygromycin (400 µg/ml). Immunoprecipitation experiments using the anti-KIT Ab 1C1 (kindly provided by Dr. H.-J. Bühring, University of Tübingen, Germany) and the anti-phosphotyrosine (pTyr) Ab 4G10 (Upstate Biotechnology) revealed tight doxycycline-dependent expression of KIT D816V with virtually no leakiness in the absence of doxycycline (see Results).

Detection of the KIT D816V mutation by restriction fragment length polymorphism (RFLP)

After isolation of RNA and synthesis of cDNA (see below), a 206-bp fragment was PCR amplified using primers D816V-f (5'-TCATGGTCGGATCACAAAGA-3') and D816V-r (5'-AGGGGCTGCTTCCTAAAGAG-3'). The PCR product was digested with HinfI (New England Biolabs) and analyzed on a 15% polyacrylamide gel. The presence of the D816V mutation creates a new HinfI restriction site, resulting in cleavage of the 56-bp fragment (wt KIT) into a 42-bp and a 14-bp fragment (mutated KIT).

Western blotting

Ton.Kit.wt or Ton.Kit.D816V cells (10⁶/ml) were incubated with doxycycline (1 µg/ml) at 37°C for 24 h to induce expression of KIT. Thereafter, SCF (100 ng/ml) was added for 15 min. In inhibition experiments, cells were then incubated with PKC412, imatinib, or control medium for 4 h. Immunoprecipitation (IP) and Western blotting were performed as described (28). For IP, lysates from 10⁷ cells were incubated with anti-KIT Ab 1C1 and protein G-Sepharose beads (Amersham Biosciences) in IP buffer (50 mM Tris (pH 7.4), 150 mM NaCl, 100 mM NaF, and 1% Nonidet P-40) at 4°C overnight. Beads were then washed three times in IP buffer. Lysates as well as immunoprecipitates were separated under reducing conditions by 7.5% SDS-PAGE and transferred to a polyvinylidene difluoride membrane (Amersham Biosciences). Immunoblotting was performed using the anti-KIT Ab 1C1 and anti-pTyr Ab 4G10, as well as Abs against phosphorylated or total Akt or ERK (Cell Signaling Technology). In each case, at least three independent Western blot experiments were performed. Protein expression levels were quantified by densitometry using the EASY Win32 software (Herolab).

EMSAs

STAT DNA-binding activity was analyzed as described (22). Ton.Kit.wt and Ton.Kit.D816V cells were kept in control medium or were cultured in the presence of doxycycline (1 µg/ml) for 24 h. Then, doxycycline-treated cells were stimulated with SCF (100 ng/ml) for 15 min or were left untreated. Extracts were analyzed using blunt-ended annealed oligonucleotides. For STAT5 analysis, the proximal STAT-binding element (5'-AGATTTCTAGGAATTCAAATC-3') of the bovine β-casein promoter was employed. Binding reactions were performed by incubating 10,000 cpm of radiolabeled probe with cell lysates (20 µg) for 30 min. For supershift reactions of STAT-containing complexes, 2 µg of Abs specific for the C-terminal transactivation domains of STAT1 (M22; Santa Cruz Biotechnology) and STAT5 (C-17; Santa Cruz Biotechnology) was added before EMSA was performed. Samples were separated by electrophoresis through 6% native polyacrylamide gels and analyzed by autoradiography.

Immunostaining and RIA

Immunohistochemistry was performed on paraffin-embedded, formalin-fixed bone marrow biopsy sections using the indirect immunoperoxidase staining technique as described previously (7). Endogenous peroxidase was blocked by methanol/H₂O₂ before sections were incubated with various Abs. The following Abs were used: anti-tryptase G3 (Chemicon; working dilution 1/5000), anti-histidine decarboxylase (HDC) (PROGEN Biotechnik; working dilution 1/500), anti-KIT (Dako; working dilution 1/500), and anti-Ki67 (Dako; working dilution 1/50). The anti-tryptase Ab G3 was applied on non-pretreated bone marrow sections. For all other stainings, slides were pretreated by microwave oven. After washing, slides were incubated with biotinylated horse anti-mouse or goat anti-rabbit IgG for 30 min, washed, and exposed to avidin-biotin-peroxidase complex for 30 min. 3-Amino-9-ethylcarbazole was used as chromogen. Slides were counterstained in Mayer’s hemalaun and mounted. Immunocytochemistry was performed on cytospin preparations of BaF3 cells as described (21) using a polyclonal rabbit anti-KIT Ab (Dako). Cytospin slides were incubated with the primary Ab for 60 min at room temperature, washed, and thereafter exposed to biotinylated goat-anti-rabbit IgG (BioCarta) for 30 min. As chromogen, streptavidin-alkaline-phosphatase complex (BioCarta) was used. Antibody reactivity was made visible using Neofuchsin (Nichirei). Slides were counterstained in Mayer’s hemalaun and mounted.

In selected experiments, flow cytometry was performed on a FACScan (BD Biosciences) using an Ab against murine ICAM-1 (CD54, BD Biosciences). Histamine was measured by a commercial RIA (Immunotech).

Gene expression profiling

Preparation of cRNA, hybridization to the murine U74Av2 GeneChip set (Affymetrix), and scanning of arrays were conducted according to the manufacturer’s protocols (http://www.affymetrix.com). Images were analyzed with GeneChip software (Affymetrix, MAS 5.0). Changes in gene expression were calculated as ratio of doxycycline-treated vs medium-treated cells.

Real-time PCR

RNA was isolated using the RNeasy Kit (Qiagen), and cDNA was synthesized using Moloney murine leukemia virus reverse transcriptase (Invitrogen) and random primers (Invitrogen) according to the manufacturer’s instructions. mRNA levels were quantified on a 7900HT Fast Real-Time PCR System (Applied Biosystems) using iTaq SYBR Green Supermix with ROX (Bio-Rad) and were normalized to β-actin. Results were expressed as CT values (CT = (CT_{mRNA Control} – CT_{mRNA Sample}) – (CT_{β-actin Control} – CT_{β-actin Sample}) or as "fold of control". Primer sequences are available on request.

Mice

To determine the transforming capacity of KIT D816V in vivo, a tumor model using nude mice as well as a bone marrow transplantation model using C57BL/6 mice deficient for Rag2 and the common -chain, were applied. Mice were housed at the Biomedical Research Institute, Medical University of Vienna. Additionally, we used KIT D816V transgenic mice described recently (19). All animal studies were approved by the local institutional review committee for animal research. Doxycycline (400 µg/ml) and sucrose (1%) were added to the drinking water of the nude mice (BALB/c) 1 wk before injection of BaF3 cells (water bottles were light-protected). Ton.Kit.D816V cells or control cells, that is, Ton.B210 expressing BCR/ABL (29) (10⁷ in 0.25 ml PBS plus 2 µg/ml doxycycline), were injected subcutaneously into each flank of the nude mice. Water containing doxycycline was changed every 3 days.

To generate an ecotropic retroviral producer cell line, GP+E86 cells were transfected with pMSCV-KIT.D816V-IRES-GFP. KIT D816V expressing GP+E86 cells (GFP⁺) were then enriched by FACS-sorting on a FACSAria (Becton Dickinson). For transplantation, bone marrow cells from C57/Bl6 mice were cocultured with GP+E86-KIT.D816V cells in the presence of cytokines (IL-3: 25 ng/ml, IL-6: 50 ng/ml, SCF: 50 ng/ml) and polybrene (7 µg/ml) for 48 h as described (30). The percentage of transduced progenitor cells was determined by FACS analysis 48 h after the transduction procedure using the Biotin-Conjugated Mouse Lineage Panel (BD Biosciences) and Abs against kit (PE-Cy5-conjugated; eBioscience) and sca-1 (PE-Cy7 conjugated, clone D7; BD Biosciences). Progenitor cells were defined as lin^–, GFP⁺, sca-1⁺, and c-kit⁺. Each mouse received 10³ progenitor cells transduced with KIT D816V (five animals) or (as a control) with BCR/ABL (three animals). Two days after transplantation, one animal of each group was sacrificed and engraftment of GFP-positive cells in the bone marrow was verified by FACS analysis.

	Results

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Generation and characterization of BaF3 cells with doxycycline-inducible expression of KIT D816V (Ton.Kit.D816V)

Three BaF3 cell clones with conditional expression of KIT D816V were established. In most experiments, clone Ton.Kit.D816V.27 was used. As control, BaF3 cells with inducible expression of wt KIT were employed. As shown in Fig. 1A, expression of KIT can be induced by addition of doxycycline (1 µg/ml) in Ton.Kit.D816V cells as well as in Ton.Kit.wt cells. The presence of the KIT D816V mutation in Ton.Kit.D816V cells was confirmed by RFLP (Fig. 1B). As expected, KIT D816V was found to be constitutively tyrosine phosphorylated, whereas wt KIT was phosphorylated only in the presence of SCF (100 ng/ml) (Fig. 1C). In line with the known pharmacologic response profile of the mutant, the KIT-targeting TK inhibitor PKC412 (31) was found to counteract phosphorylation of KIT D816V in Ton.Kit.D816V cells, whereas imatinib showed no effects (Fig. 1D).

View larger version (43K): [in this window] [in a new window]   FIGURE 1. Establishment of BaF3 cell lines with conditional expression of wt KIT and KIT D816V. A, Ton.Kit.D816V.27 cells and Ton.Kit.wt cells were kept in control medium (–Doxy) or doxycycline (1 µg/ml (+ Doxy)) for 24 h. After incubation, cells were spun on cytospin slides and analyzed by indirect immunoalkaline phosphatase staining technique using an anti-KIT Ab. B, Ton.Kit.D816V cells (clones 3, 6, and 27) and Ton.Kit.wt cells (wt) were cultured in the presence of doxycycline (1 µg/ml) for 24 h. Thereafter, the presence or absence of the D816V mutation was determined by RFLP as described in Materials and Methods. C, Ton.Kit.wt cells and Ton.Kit.D816V.27 cells were incubated in control medium or doxycycline (Doxy) for 24 h, and then were kept with or without SCF (100 ng/ml) for 15 min at 37°C. After immunoprecipitation (IP) for KIT, lysates were split and subjected to immunoblotting (IB) using anti-pTyr (p-tyr) or anti-KIT Abs. The blot shows one representative experiment; identical results were obtained in two other independent experiments. D, Ton.Kit.D816V.27 cells were grown in the absence or presence of doxycycline for 24 h and were then treated with PKC412 (200 nM to 1 µM), imatinib (1 µM), or were kept in control medium for 4 h. Phosphorylation of KIT was determined as described above. One typical experiment (out of three independent experiments with identical results) is shown.

BaF3 cells are factor-dependent cells that undergo apoptosis on withdrawal of IL-3. Growth-promoting oncogenes such as BCR/ABL can substitute for IL-3 as growth-enhancing factor in these cells. In the present study, BaF3 cells with doxycycline-inducible expression of KIT D816V (Ton.kit.D816V) were used to characterize the effects of this mutant on growth (Ton.B210 cells with inducible expression of BCR/ABL served as control cells). However, expression of KIT D816V did not substitute for IL-3 as a growth-promoting stimulus in BaF3 cells, contrasting with the effect of BCR/ABL (Fig. 2A). Additionally, KIT D816V did not increase, but it even decreased the proliferation of Ton.Kit.D816V cells in the presence of IL-3, SCF, or a combination of both cytokines (Fig. 2B). The same results were obtained when lower cytokine concentrations (10 ng/ml, 1 ng/ml) were applied. Combined annexin V/propidium iodide staining showed that most cells exposed to doxycycline remained viable, and that only a smaller percentage of these cells (10–30%) entered apoptosis (not shown). Contrasting the failure of KIT D816V to induce proliferation, we found that SCF promotes the growth of Ton.Kit.wt cells expressing wt KIT after exposure to doxycycline (Fig. 2C). In control cells (native BaF3 cells), doxycycline did not show growth-modulating effects. To exclude the possibility that differences in promoter strength were the cause for varying biological effects between human KIT D816V in our cell line model and murine KIT mutants in other studies (17, 18), BaF3 cells were retrovirally transduced with pMSCV-KIT.D816V-IRES-GFP (expression of KIT D816V driven by a strong LTR promoter). However, although high expression levels of constitutively phosphorylated KIT could be detected in the transduced cells, these cells were not transformed to growth factor independence and rapidly underwent apoptosis in the absence of IL-3 (not shown).

View larger version (39K): [in this window] [in a new window]   FIGURE 2. Effects of KIT D816V on growth and survival. A, Comparative effects of KIT D816V and BCR/ABL on growth of BaF3 cells. Ton.Kit.D816V.27 cells (left) and Ton.B210 cells (right) were cultured in control medium (Co) or medium supplemented with doxycycline (Dox) (1 µg/ml) for 3 days. Then, the number of viable cells was determined. B, Ton.Kit.D816V cells were cultured in IL-3 (), IL-3 plus doxycycline (), IL-3 plus doxycycline plus SCF (100 ng/ml) (•), doxycycline (), doxycycline plus SCF (100 ng/ml) (), or in the absence of growth factors (=starved, ) for various time periods. Results show cell counts and represent the means ± SD of three independent experiments. C, Ton.Kit.wt cells were cultured in the presence of doxycycline plus SCF (100 ng/ml) (), doxycycline plus SCF (100 ng/ml) plus IL-3 (), IL-3 (•), doxycycline (), or in the absence of growth factors (=starved, ) for various time periods. Results show cell counts and represent the means ± SD of three independent experiments. D, Ton.Kit.D816V cells (107) (left) or Ton.B210 cells (107) (right) were injected subcutaneously into the flanks of nude mice given water with doxycycline (400 µg/ml). Sites of Ton.B210 injections resulting in tumors are indicated by arrows. Control mice receiving water without doxycycline did not develop any tumors (not shown). E, Rag2–/–c–/– mice were transplanted with KIT D816V-transduced bone marrow cells or BCR/ABL-transduced bone marrow cells. After 6 wk, mice transplanted with BCR/ABL-transduced bone marrow cells developed a lethal leukemia, whereas mice transplanted with KIT D816V-transduced bone marrow cells remained healthy. On day 46, mice were sacrificed and the percentage of GFP-positive cells in the spleen of mice was determined by FACS analysis. The figure shows typical examples of mice transplanted with KIT D816V-transduced bone marrow cells (left panel) and mice transplanted with BCR/ABL-transduced bone marrow cells (right panel). SSC, Side scatter.

Inducible expression of KIT D816V cannot substitute for the growth-promoting effects of GM-CSF in human UT7 cells

To investigate the biologic effects of KIT D816V in human myeloid cells, we established a UT7 cell line with doxycycline-inducible expression of KIT D816V (Fig. 3A). As for BaF3 cells, UT7 cells are strictly cytokine-dependent and undergo apoptosis in the absence of GM-CSF within 2 days (24). Confirming our data obtained with BaF3 cells, conditional expression of KIT D816V in UT7 cells did not promote growth or viability in the absence of GM-CSF (Fig. 3B). Interestingly, expression of KIT D816V was found to slightly decrease the proliferation rate of UT7 cells—a result that was also obtained with Ton.Kit.D816V cells (Fig. 2B). In contrast to KIT D816V, expression of BCR/ABL in UT7 cells was found to confer factor-independent growth. These data provide further evidence that KIT D816V does not promote growth of neoplastic hematopoietic/myeloid cells.

View larger version (24K): [in this window] [in a new window]   FIGURE 3. Effects of KIT D816V on growth of UT7 cells. A, UT7 cells with inducible expression of KIT D816V (UT7-tK.D816V) were cultured in the absence or presence of doxycycline (1 µg/ml) for 24 h. Thereafter, expression and phosphorylation of KIT was analyzed by immunoprecipitation/immunoblotting using the 1C1 and 4G10 Abs. One typical experiment (out of three independent experiments with identical results) is shown. B, UT7-tK.D816V cells were cultured in GM-CSF (), GM-CSF plus doxycycline (), doxycycline (), or in the absence of GM-CSF (= starved, ) for various time periods. Results show the number of viable cells and represent the means ± SD of three independent experiments.

Despite the observation that KIT D816V is not a growth-promoting oncoprotein, we asked whether the mutant induces activation of signal transduction molecules and whether KIT D816V-dependent signaling differs from signaling cascades activated by the wt KIT receptor. As shown in Fig. 4, A and B, KIT D816V (in the absence or presence of SCF) as well as wt KIT (in the presence of SCF) were found to lead to phosphorylation of ERK and Akt. Interestingly, KIT D816V induced a more pronounced phosphorylation of Akt (127 ± 51-fold in the absence of SCF and 129 ± 36-fold in the presence of SCF as assessed by densitometry) compared with wt KIT in the presence of SCF (68 ± 14-fold). These data suggest that wt KIT and KIT D816V utilize in part identical signaling pathways, although the effect of the mutant exceeded the effects of wt KIT. An even greater (clear-cut) difference was found when analyzing STAT1 and STAT5. In fact, whereas wt KIT did not activate these STAT molecules in our BaF3 cell model, KIT D816V was found to lead to a strong activation (phosphorylation) of STAT1 and STAT5 (Fig. 4C). These data suggest that the KIT D816V point mutation leads to activation of distinct signaling cascades in BaF3 cells including STAT1 and STAT5 activation.

View larger version (64K): [in this window] [in a new window]   FIGURE 4. Effects of the D816V mutation on signaling of the KIT receptor. A and B, Ton.Kit.D816V.27 and Ton.Kit.wt cells were kept in the absence or presence of doxycycline (Doxy) for 24 h at 37°C. Then, cells were incubated with or without SCF (100 ng/ml) for 15 min at 37°C. Phosphorylation of Akt and ERK (p42/44) was determined by immunoblotting using Abs against phosphorylated forms (p-) or total Akt and total ERK, respectively. Densitometric quantification showed 68 ± 14-fold induction of pAkt in Ton.Kit.wt cells in the presence of doxycycline and SCF, whereas pAkt was induced 127 ± 51-fold (in the presence of doxycycline) and 129 ± 36-fold (in the presence of doxycycline and SCF) in Ton.Kit.D816V cells (three independent experiments, means ± SD). C, Ton.Kit.wt and Ton.Kit.D816V.27 cells were kept in control medium (0) or were cultured in the presence of doxycycline (1 µg/ml) for 24 h. Then, doxycycline-treated cells were stimulated with SCF (100 ng/ml (Doxy + SCF)) for 15 min or were left untreated (Doxy). Extracts were analyzed using blunt-ended annealed oligonucleotides. For supershift reactions of STAT-containing complexes, Abs specific for the C-terminal transactivation domains of STAT1 and STAT5 were added before EMSA was performed. One out of three independent experiments is shown.

The observation that KIT D816V, albeit showing no growth-promoting effects, can induce specific signaling prompted us to screen for biologic effects that the mutant exerts in BaF3 cells. Since SM is associated with focal accumulation of MC in hematopoietic tissues, we first examined whether KIT D816V induces cluster formation. Indeed, KIT D816V was found to induce the formation of large clusters of Ton.Kit.D816V cells (Fig. 5A). Cluster formation was observed within 12 h after the addition of doxycycline. As expected, the KIT D816V-induced cluster formation in Ton.Kit.D816V cells was inhibited dose-dependently by PKC412, but it was not inhibited by imatinib (Fig. 5B). No cluster formation was observed in doxycycline-exposed Ton.Kit.wt cells in the presence of SCF (Fig. 5A). To characterize the signal transduction pathways involved in KIT D816V-dependent cluster formation, we applied pharmacologic inhibitors of MEK (PD98059) and PI3K (LY294002). In these experiments, we found that inhibition of MEK abolishes clustering of Ton.Kit.D816V cells in the presence of doxycyline, whereas the PI3K-targeting drug LY294002 did not show an inhibitory effect on cluster formation (Fig. 5C). In control experiments, LY294002 inhibited the phosphorylation of Akt, and PD98059 inhibited the phosphorylation of ERK in KIT D816V-expressing BaF3 cells (not shown). To investigate a potential role of STAT5 in KIT D816V-induced cell–cell adhesion, two different dn STAT5 constructs (STAT5a749 or STAT5b754) were expressed in Ton.Kit.D816V cells. However, although expression of these dn STAT5 constructs inhibited KIT D816V-induced phosphorylation of STAT5, no effect on cluster formation in the presence of doxycycline was observed (not shown). These data suggest that KIT D816V induces cluster formation of BaF3 cells through a MEK-dependent pathway.

View larger version (36K): [in this window] [in a new window]   FIGURE 5. Effects of KIT D816V on cluster formation. A, Examples of cluster formation of Ton.Kit wt cells and Ton.Kit.D816V cells exposed to control medium or doxycycline (Doxy) with or without SCF (100 ng/ml) under inverted microscope (magnification x20). B, Ton.Kit.D816V cells were cultured without (Co) or with (Doxy) doxycycline (1 µg/ml) for 24 h. Doxycycline-exposed cells were kept in the presence of various concentrations of PKC412 as indicated. Cluster formation is expressed as cluster per field. Results represent the means ± SD of three independent experiments. C, Ton.Kit.D816V cells were cultured in the absence or presence of doxycycline as indicated. KIT D816V-expressing cells were treated with the MEK inhibitor PD98059 (50 µM) or with the PI3K inhibitor LY294002 (20 µM) for 24 h. Cluster formation is expressed as cluster per field. Results represent the means ± SD of three independent experiments.

Since expression of KIT D816V was consistently associated with decreased cell growth, we asked whether this oncoprotein would induce differentiation rather than proliferation in hematopoietic progenitors. To test this hypothesis, we first examined the morphology of Ton.Kit.D816V cells after exposure to doxycycline (with or without SCF or additional cytokines: IL-3, IL-4, IL-6). As assessed by light microscopy, a few doxycycline-exposed Ton.Kit.D816V cells were found to display metachromatic granules when stained with Wright-Giemsa, although the numbers of granules was low and the cells remained in a blast stage of differentiation (Fig. 6A) irrespective of the cytokine(s) applied or the time of culture (up to 4 wk).

View larger version (16K): [in this window] [in a new window]   FIGURE 6. Effects of KIT D816V on differentiation. A, Ton.Kit.D816V.3 cells were exposed to control medium (left panel), doxycycline (middle panel), or doxycycline and murine mast cell growth factors (IL-3, IL-4, and IL-9, each 100 ng/ml) (right panel) for 2 days. Cells were spun on cytospin slides and stained by Wright-Giemsa. B, Histamine levels determined by RIA in Ton.Kit.D816V.27 (left panel) cells and Ton.B210 cells (right panel) after exposure to control medium (Co) or doxycycline (left panel, KIT D816V; right panel, BCR/ABL) for 24 h. C, Induction of HDC mRNA in BaF3 cells by KIT D816V. Ton.Kit.D816V.27 cells (left panel) or Ton.Kit.wt cells (right panel) were cultured in the absence (Co) or presence of doxycycline (Doxy) with or without SCF (100 ng/ml) for 24 h as indicated. Expression levels of HDC were quantified by real-time PCR and were normalized to β-actin mRNA. Results represent triplicates ± SD from one representative experiment. D, Ton.Kit.D816V cells induced to express KIT D816V were treated with various drugs (PD98059, 50 µM; LY294002, 20 µM; PKC412, 1 µM; imatinib, 1 µM) as indicated for 24 h. Thereafter, histamine levels were determined by RIA. Results represent the means ± SD of three independent experiments. E, Ton.Kit.D816V cells transduced with the empty MSCV vector were cultured in the absence or presence of doxycycline (1 µg/ml), PD98059 (50 µM), or LY294002 (20 µM) as indicated. Additionally, Ton.Kit.D816V cells transduced with MSCV-STAT5a749 or with MSCV-STAT5b754 were induced to express KIT D816V. After 24 h, cells were harvested and the expression of HDC mRNA levels was quantified by real-time PCR. Results represent triplicates ± SD from one representative experiment.

KIT D816V induces expression of a number of mast cell differentiation and adhesion-related Ags in BaF3 cells

We next performed gene chip analysis to define the profile of MC Ags expressed in Ton.Kit.D816V cells in response to KIT D816V. In these experiments, KIT D816V was found to promote expression of a number of important MC adhesion- and MC differentiation-associated Ags including IL4R, mouse mast cell protease 5 (MMCP5), microphthalmia transcription factor (MITF), ICAM-1, and lysosome-associated protein 3 (LAMP-3) (Fig. 7A and Table I). In contrast, however, KIT D816V did not induce expression of late-stage MC differentiation Ags such as FcRI. Other MMCPs (MMCP1/9, 2, 4, 6, 7, 8) were not expressed in BaF3 cells. Another interesting observation was that proliferation-associated Ags such as Ki-67 and the transferrin receptor CD71 were found to be down-regulated by KIT D816V (Table I). Up-regulation of these Ags by KIT D816V was confirmed by quantitative PCR (qPCR) (Fig. 7B). KIT D816V-induced up-regulation of ICAM-1 on BaF3 cells was also demonstrable by flow cytometry (Fig. 7C). Together, our results suggest that KIT D816V regulates a number of genes involved in cell–cell adhesion and MC differentiation, but it down-regulates proliferation-associated Ags.

View larger version (35K): [in this window] [in a new window]   FIGURE 7. Effects of KIT D816V on expression of differentiation-associated Ags. A, Gene expression profiles determined by Affymetrix technology in two independent experiments (Expt. 1 and Expt. 2) employing Ton.Kit.D816V.3 cells. Cells were exposed to IL-3 alone (Control) or IL-3 and doxycycline (1 µg/ml (Doxy)) for 24 h and then subjected to gene array analysis. The scatter blots show the following patterns: nonexpressed (yellow dots), constantly expressed (red dots), and switched on or switched off (blue dots) as determined by default settings by the MAS 5.0 algorithm for detection calls. Lines indicate 3-, 10-, and 30-fold changes (up- or down-regulation) in mRNA expression levels. The black arrow shows up-regulation of the reference mRNA (= HDC) (21-fold and 11-fold in experiments 1 and 2, respectively). B, Ton.Kit.D816V.27 cells were exposed to control medium or doxycycline (1 µg/ml) for 24 h (37°C). Expressions of mast cell-related differentiation and activation Ags were quantified by real-time PCR. Expression levels were normalized to β-actin mRNA and are given as "fold of control". Results represent the mean ± SD of three independent experiments. C, Flow cytometric evaluation of expression of ICAM-1/CD54 on Ton.Kit.D816V.27 cells after induction of KIT D816V. Ton.Kit.D816V.27 cells were cultured in control medium (gray graph) or doxycycline (1 µg/ml; black graph) for 24 h. The Ab omission control is also shown (dotted lines).

To define the specific consequences and features associated with the transforming effects of KIT D816V in neoplastic cells in a human model, we compared histological, phenotypic and biochemical markers in patients with KIT D816V⁺ ISM with that in patients suffering from KIT D816V^– but tryptase⁺ neoplasm, that is, myelomastocytic leukemia (MML) and tryptase⁺ AML. In patients suffering from KIT D816V⁺ ISM, MC were found to form clusters and aggregates in tryptase-stained bone marrow sections, whereas no MC clusters were found in patients with D816V^– MML (Fig. 8A). In MC clusters, the tryptase⁺ neoplastic cells were found to coexpress several MC-differentiation Ags including HDC and CD63, whereas the proliferation-associated Ag Ki67 was not detectable (Fig. 8A and Table III). We also were unable to detect morphologic signs of MC proliferation (mitosis) in any of the patients with SM examined.

View larger version (79K): [in this window] [in a new window]   FIGURE 8. Cluster formation and growth of mast cells in ISM. A, Cluster formation of MC in the bone marrow of patients with ISM (KIT D816V+) as opposed to patients with MML (D816V– MC disease) or the normal bone marrow. Neoplastic MC (in focal aggregates) in ISM express tryptase, KIT, HDC, and CD63, but do not express Ki67. B, Serum tryptase levels in ISM patients (n = 10) exhibiting KIT D816V (typical ISM, n = 8; smoldering SM (SSM), n = 2) (left panel), and in 7 patients with tryptase+ (Ki67+) leukemias (KIT D816V+ MC leukemia (MCL), n = 2; tryptase+ acute myeloid leukemia (AML), n = 5) (right panel). In healthy individuals, serum tryptase levels average 5 ng/ml (range 0–15 ng/ml).

	Discussion

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The tyrosine kinase receptor KIT and its ligand SCF are critically involved in the regulation of differentiation and maturation of MC (35, 36, 37). The KIT mutation D816V is detectable in most patients with SM (11, 12, 13) and is associated with ligand-independent autonomous kinase activity (16). Therefore, this mutation has been implicated in malignant growth of MC and in the pathogenesis of SM (16, 17, 18). However, the mutation occurs not only in aggressive SM but also in most patients (>80%) with ISM, a disease variant without progression and with normal life expectancy (13, 14). This prompted us to revisit the oncogenic potential of this KIT mutation by using BaF3 cells with inducible expression of KIT D816V as well as KIT D816V-transgenic mice. The results of our study show that KIT D816V promotes cluster formation and MC differentiation in BaF3 cells as well as in transgenic mice without inducing a substantial proliferation in MC. Based on these data we think that the effects of this KIT mutation can explain the clinical picture and course of ISM, but cannot explain the clinical course of aggressive SM or MCL.

So far, most studies analyzing mutated KIT in the context of mastocytosis in cell line systems (mostly BaF3) have employed murine KIT D814V (17, 18) or have used human KIT D816V in combination with other oncogenes (38, 39). In several studies, BaF3 cells that had been preselected for growth advantage were used (40, 41). In this study we thought that such cell line models would not be an optimal tool for the evaluation of growth-promoting effects of the KIT mutant. Therefore, we generated BaF3 cell lines with doxycycline-inducible expression of KIT D816V. The precommitted cell line BaF3 was used because 1) SM is known to arise from uncommitted hematopoietic progenitors, 2) BaF3 cells lack oncogenic hits and undergo apoptosis in the absence of IL-3, 3) BaF3 is a suitable and established model to investigate effects of oncogenes expressed by myeloid neoplasms (20, 21, 29, 42, 43), and 4) despite the fact that IL-3 is a major MC differentiation factor in the mouse system, BaF3 cells (with or without IL-3) do not exhibit MC-related Ags by gene chip profiling (precommitted progenitor).

The first results obtained with these newly generated Ton.Kit cell lines were somehow disappointing in that doxycycline-induced expression of KIT D816V was not associated with enhanced growth regardless of the condition tested. In fact, KIT D816V neither promoted cell growth in the presence of IL-3 or SCF nor did the mutant substitute for IL-3 as a growth-promoting factor. In contrast, wt KIT induced the proliferation of Ton.Kit.wt cells in the presence of SCF. The principal message of our paper, that KIT D816V induces differentiation rather than proliferation, is in line with the data of Ferrao et al. (44), but are in contrast to other previous observations made with cell lines stably expressing KIT D816V or expressing the murine equivalent KIT D814V (17, 18, 40, 41). With regard to cell lines stably expressing KIT mutants, the discrepancy may best be explained by additional growth-promoting factors or cooperating oncogenes (most of these cells were selected for growth advantage). In case of KIT D814V, the difference may also be explained by (species-specific) differences in the aggressiveness or transforming potential of these two mutants. The failure of BaF3 cells to grow better in the presence of KIT D816V in inducible cell line models might also explain why such cell line models had not been established and presented so far.

In a next step, we were interested to learn why KIT D816V is unable to promote growth of BaF3 cells and as to whether the mutant would induce other critical functions or features specific for MC development (and relevant for the pathogenesis of SM). As a first step, we were able to demonstrate that KIT D816V induces massive cluster formation in BaF3 cells in suspension as well as synthesis of histamine. Additionally, we were able to demonstrate by gene expression profiling and qPCR that the KIT D816V-induced histamine synthesis and cluster formation are accompanied by expression of several MC differentiation Ags including MITF, HDC, MMCP5, CD63, and IL-4R, as well as expression of several adhesion molecules including CD54/ICAM-1, CD53, and CD63. These observations are of particular interest, as in SM the major diagnostic feature (and World Health Organization criterion) common to all disease variants is cluster formation of MC (7, 8, 9, 10). So far, it remains unknown, however, which of these adhesion molecules are most critical determinants for the abnormal adhesion and MC cluster formation in SM. In fact, all these molecules including CD63 and CD54/ICAM-1 are well known to be expressed on the surface of neoplastic MC in SM (45, 46) and, in most cases, neoplastic MC also display respective counterreceptors.

Another interesting observation was that KIT D816V down-regulates expression of several proliferation-linked Ags such as Ki67 or the transferrin receptor (CD71). This observation is in line with our immunohistochemical data obtained in patients with ISM in whom neoplastic MC did not express Ki67 and did not show signs of proliferation (mitosis). The down-regulation of proliferation-associated Ags may also explain the failure of the mutant to induce growth. Alternatively, the failure of KIT D816V to induce growth in BaF3 cells could be associated with induction of STAT1. The most likely scenario is that several of these factors act together to prevent a proliferative response. Lastly, enhanced differentiation/maturation is in general associated with a decrease in proliferation in normal and neoplastic cells, so that one could speculate that the KIT D816V-induced differentiation is closely linked with the decrease in proliferation. Whatever the explanation is, it appears that KIT D816V induces MC differentiation and cluster formation without inducing proliferation. To test this hypothesis in vivo, we injected BaF3 cells exhibiting KIT D816V into nude mice. However, no tumor formation was observed, whereas the BCR/ABL oncoprotein was found to induce BaF3 tumor formation in mice. The finding that KIT D816V is not a growth-promoting oncoprotein is also supported by a recently described mouse model (19). In this study, Zappula et al. found that transgenic mice that express KIT D816V under the control of the chymase promoter do not develop aggressive mast cell neoplasms, but they develop indolent mast cell disorders after prolonged periods (19).

So far, little is known about signaling molecules and signal transduction pathways specifically involved in KIT D816V-induced differentiation or clustering (39). In the present study, we found that both KIT D816V as well as wt KIT (in the presence of SCF) induce activation of several signaling molecules including PI3K, Akt, and ERK. A remarkable observation was that KIT D816V but not wt KIT induces phosphorylation of STAT5 as well as STAT1 in BaF3 cells. This is of particular interest since STAT5 has recently been described as a major regulator of MC growth and development (47, 48). In fact, STAT5-deficient mice exhibit MC deficiency similar to KIT-deficient mice (36). Additionally, neoplastic MC in SM show expression of constitutively phosphorylated STAT5 (49, 50). Based on these observations, it is tempting to speculate that STAT5 is a critical downstream molecule and regulator of KIT D816V-dependent functions of neoplastic MC in SM, and thus a potential new interesting target in this disease. An interesting aspect was that STAT5 was activated by KIT D816V but was not induced by wt KIT in BaF3 cells. This difference may have several explanations. First, KIT D816V may activate STAT5 preferentially in human cells but not (or less potently) in murine cells. Another possibility could be that wt STAT5 induces STAT5 activation in very immature stem cells but not in a precommitted progenitor such as BaF3. Lastly, the difference between wt KIT and KIT D816V in their capacity to activate STAT5 may be a BaF3-specific phenomenon. Whatever the reason is for the differential effects of the KIT variants in BaF3 cells, it recently has been described that primary neoplastic MC in patients with SM display activated STAT5 (49, 50), which was recently also confirmed in our studies (data not shown).

To study the potential role of signaling molecules in KIT D816V-induced histamine formation (differentiation) and clustering in BaF3 cells, pharmacologic inhibitors of MEK (PD98059) and of PI3K (LY294002) were applied. In these experiments, KIT D816V-dependent synthesis of histamine was suppressed by both inhibitors, whereas cluster formation was selectively inhibited by PD98059. The latter observation was quite unexpected as both wt KIT and KIT D816V induced the phosphorylation of ERK in our BaF3 cell line model, whereas only KIT D816V (but not wt KIT) induced cluster formation. One possible explanation may be that not only MEK activation, but also other signaling molecules (triggered by KIT D816V but not wt KIT) are required for the induction of cluster formation. An alternative hypothesis would be that MEK downstream signaling pathways differ when comparing KIT D816V-expressing and wt KIT-expressing cells. A role for STAT5 in KIT D816V-induced cluster formation of BaF3 cells could be excluded using a dominant STAT5 construct.

The observation that KIT D816V as a single "hit" is not sufficient to convert a premalignant cell into a malignant cell with major proliferative capacity, but is sufficient to induce MC differentiation and MC cluster formation in hematopoietic progenitors far enough to reach the biological and clinical picture of indolent mastocytosis, is a remarkable finding. To a degree this observation seems to contradict the established "multihit" theory of cancer development (51). On the other hand, ISM behaves as a "pre-neoplasm" rather than a malignant disease, and would simply be overlooked in most cases if patients would not exhibit the striking cutaneous features of mastocytosis (9). An important unresolved question in this regard is how the massive burden of MC in the tissues in patients with ISM can be explained in the absence of MC proliferation. Based on our data, this "paradox" is best explained by a constant differentiation of MC from a pool of uncommitted KIT D816V-bearing progenitors, which, in contrast to their progeny, may undergo (constant) proliferation. An alternative explanation would be an extremely long half-life of neoplastic MC, leading to their accumulation over time (52).

In summary, our data show that the SM-specific mutant KIT D816V induces MC differentiation and MC cluster formation without promoting MC proliferation in BaF3 cells as well as in mice. Based on these data, the effects of this mutant can explain the pathology and biologic behavior of the neoplastic clone in ISM, whereas additional (proliferation-enhancing) defects/hits may be responsible for the clinical picture and adverse course in patients with ASM or MCL.

	Acknowledgments

 
We thank Dr. N. Komatsu (Jichi Medical School, Tochigi, Japan) for sharing the UT7 cell line and Dr. D. Trono (École Polytechnique Fédérale de Lausanne, Switzerland) for providing the pLV-tTR-KRAB plasmid.

	Disclosures

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The authors have no financial conflicts of interest.

	Footnotes

 
The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked advertisement in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

¹ This work was supported by the Fonds zur Förderung der Wissenschaftlichen Forschung in Österreich (FWF) Grants P17205-B14, SFB no. F28, and SFB no. F18–20.

² Address correspondence and reprint requests to Dr. Peter Valent, Department of Internal Medicine I, Division of Hematology and Hemostaseology, Medical University of Vienna, Währinger Gürtel 18-20, A-1090 Vienna, Austria. E-mail address: peter.valent{at}meduniwien.ac.at

³ Abbreviations used in this paper: SM, systemic mastocytosis; MC, mast cell; ISM, indolent systemic mastocytosis; ASM, aggressive mastocytosis; MCL, mast cell leukemia; TK, tyrosine kinase; SCF, stem cell factor; wt, wild type; dn, dominant negative; tTR-KRAB, tetracycline repressor fused to the Kruppel-associated box repression domain of human Kox-1; pTyr, phosphotyrosine; IP, immunoprecipitation; HDC, histidine decarboxylase; MMCP5, mouse mast cell protease 5; MITF, microphthalmia transcription factor; LAMP-3, lysosome-associated protein 3; MML, myelomastocytic leukemia; IB, immunoblot; RFLP, restriction fragment length polymorphism; qPCR, quantitative PCR.

Received for publication January 30, 2007. Accepted for publication February 11, 2008.

	References

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1. Lennert, K., M. R. Parwaresch. 1979. Mast cells and mast cell neoplasia: a review. Histopathology 3: 349-365. [Medline]
2. Metcalfe, D. D.. 1991. Classification and diagnosis of mastocytosis: current status. J. Invest. Dermatol. 96: 2S-4S. [Medline]
3. Akin, C., D. D. Metcalfe. 2004. Systemic mastocytosis. Annu. Rev. Med. 55: 419-432. [Medline]
4. Valent, P., C. Akin, W. R. Sperr, H. P. Horny, M. Arock, K. Lechner, J. M. Bennett, D. D. Metcalfe. 2003. Diagnosis and treatment of systemic mastocytosis: state of the art. Br. J. Haematol. 122: 695-717. [Medline]
5. Escribano, L., C. Akin, M. Castells, A. Orfao, D. D. Metcalfe. 2002. Mastocytosis: current concepts in diagnosis and treatment. Ann. Hematol. 81: 677-690. [Medline]
6. Tefferi, A., A. Pardanani. 2004. Clinical, genetic, and therapeutic insights into systemic mast cell disease. Curr. Opin. Hematol. 11: 58-64. [Medline]
7. Horny, H. P., C. Sillaber, D. Menke, E. Kaiserling, M. Wehrmann, B. Stehberger, A. Chott, K. Lechner, K. Lennert, P. Valent. 1998. Diagnostic value of immunostaining for tryptase in patients with mastocytosis. Am. J. Surg. Pathol. 22: 1132-1140. [Medline]
8. Horny, H. P., P. Valent. 2001. Diagnosis of mastocytosis: general histopathological aspects, morphological criteria, and immunohistochemical findings. Leuk. Res. 25: 543-551. [Medline]
9. Valent, P., H. P. Horny, L. Escribano, B. J. Longley, C. Y. Li, L. B. Schwartz, G. Marone, R. Nunez, C. Akin, K. Sotlar, et al 2001. Diagnostic criteria and classification of mastocytosis: a consensus proposal. Leuk. Res. 25: 603-625. [Medline]
10. Valent, P., H. P. Horny, C. Y. Li, B. J. Longley, D. D. Metcalfe, M. R. Parwaresch, J. M. Bennett. 2001. Mastocytosis (mast cell disease). E. Jaffe, and N. Harris, and H. Stein, and J. W. Vardiman, eds. World Health Organization (WHO) Classification of Tumours, Pathology & Genetics. Tumours of Haematopoietic and Lymphoid Tissues 291 IARC Press, Lyon, France.
11. Nagata, H., A. S. Worobec, C. K. Oh, B. A. Chowdhury, S. Tannenbaum, Y. Suzuki, D. D. Metcalfe. 1995. Identification of a point mutation in the catalytic domain of the protooncogene c-kit in peripheral blood mononuclear cells of patients who have mastocytosis with an associated hematologic disorder. Proc. Natl. Acad. Sci. USA 92: 10560-10564. [Abstract/Free Full Text]
12. Longley, B. J., L. Tyrrell, S. Z. Lu, Y. S. Ma, K. Langley, T. G. Ding, T. Duffy, P. Jacobs, L. H. Tang, I. Modlin. 1996. Somatic c-KIT activating mutation in urticaria pigmentosa and aggressive mastocytosis: establishment of clonality in a human mast cell neoplasm. Nat. Genet. 12: 312-314. [Medline]
13. Longley, B. J., Jr, D. D. Metcalfe, M. Tharp, X. Wang, L. Tyrrell, S. Z. Lu, D. Heitjan, Y. Ma. 1999. Activating and dominant inactivating c-KIT catalytic domain mutations in distinct clinical forms of human mastocytosis. Proc. Natl. Acad. Sci. USA 96: 1609-1614. [Abstract/Free Full Text]
14. Fritsche-Polanz, R., J. H. Jordan, A. Feix, W. R. Sperr, G. Sunder-Plassmann, P. Valent, M. Fodinger. 2001. Mutation analysis of C-KIT in patients with myelodysplastic syndromes without mastocytosis and cases of systemic mastocytosis. Br. J. Haematol. 113: 357-364. [Medline]
15. Feger, F., D. A. Ribadeau, L. Leriche, P. Valent, M. Arock. 2002. Kit and c-kit mutations in mastocytosis: a short overview with special reference to novel molecular and diagnostic concepts. Int. Arch. Allergy Immunol. 127: 110-114. [Medline]
16. Furitsu, T., T. Tsujimura, T. Tono, H. Ikeda, H. Kitayama, U. Koshimizu, H. Sugahara, J. H. Butterfield, L. K. Ashman, Y. Kanayama, et al 1993. Identification of mutations in the coding sequence of the proto-oncogene c-kit in a human mast cell leukemia cell line causing ligand-independent activation of c-kit product. J. Clin. Invest. 92: 1736-1744. [Medline]
17. Kitayama, H., Y. Kanakura, T. Furitsu, T. Tsujimura, K. Oritani, H. Ikeda, H. Sugahara, H. Mitsui, Y. Kanayama, Y. Kitamura, et al 1995. Constitutively activating mutations of c-kit receptor tyrosine kinase confer factor-independent growth and tumorigenicity of factor-dependent hematopoietic cell lines. Blood 85: 790-798. [Abstract/Free Full Text]
18. Tsujimura, T., K. Hashimoto, H. Kitayama, H. Ikeda, H. Sugahara, I. Matsumura, T. Kaisho, N. Terada, Y. Kitamura, Y. Kanakura. 1999. Activating mutation in the catalytic domain of c-kit elicits hematopoietic transformation by receptor self-association not at the ligand-induced dimerization site. Blood 93: 1319-1329. [Abstract/Free Full Text]
19. Zappulla, J. P., P. Dubreuil, S. Desbois, S. Letard, N. B. Hamouda, M. Daeron, G. Delsol, M. Arock, R. S. Liblau. 2005. Mastocytosis in mice expressing human Kit receptor with the activating Asp816Val mutation. J. Exp. Med. 202: 1635-1641. [Abstract/Free Full Text]
20. Daley, G. Q., D. Baltimore. 1988. Transformation of an interleukin 3-dependent hematopoietic cell line by the chronic myelogenous leukemia-specific P210bcr/abl protein. Proc. Natl. Acad. Sci. USA 85: 9312-9316. [Abstract/Free Full Text]
21. Mayerhofer, M., S. Florian, M. T. Krauth, K. J. Aichberger, M. Bilban, R. Marculescu, D. Printz, G. Fritsch, O. Wagner, E. Selzer, et al 2004. Identification of heme oxygenase-1 as a novel BCR/ABL-dependent survival factor in chronic myeloid leukemia. Cancer Res. 64: 3148-3154. [Abstract/Free Full Text]
22. Moriggl, R., V. Gouilleux-Gruart, R. Jahne, S. Berchtold, C. Gartmann, X. Liu, L. Hennighausen, A. Sotiropoulos, B. Groner, F. Gouilleux. 1996. Deletion of the carboxyl-terminal transactivation domain of MGF-Stat5 results in sustained DNA binding and a dominant negative phenotype. Mol. Cell Biol. 16: 5691-5700. [Abstract]
23. Mayerhofer, M., K. V. Gleixner, J. Mayerhofer, G. Hoermann, E. Jaeger, K. J. Aichberger, R. G. Ott, K. Greish, H. Nakamura, S. Derdak, et al 2007. Targeting of heat shock protein 32 (Hsp32)/heme oxygenase-1 (HO-1) in leukemic cells in chronic myeloid leukemia: a novel approach to overcome resistance against imatinib. Blood 111: 2200-2210. [Medline]
24. Komatsu, N., H. Nakauchi, A. Miwa, T. Ishihara, M. Eguchi, M. Moroi, M. Okada, Y. Sato, H. Wada, Y. Yawata, et al 1991. Establishment and characterization of a human leukemic cell line with megakaryocytic features: dependency on granulocyte-macrophage colony-stimulating factor, interleukin 3, or erythropoietin for growth and survival. Cancer Res. 51: 341-348. [Abstract/Free Full Text]
25. Van Craenenbroeck, K., P. Vanhoenacker, J. E. Leysen, G. Haegeman. 2001. Evaluation of the tetracycline- and ecdysone-inducible systems for expression of neurotransmitter receptors in mammalian cells. Eur. J. Neurosci. 14: 968-976. [Medline]
26. Wiznerowicz, M., D. Trono. 2003. Conditional suppression of cellular genes: lentivirus vector-mediated drug-inducible RNA interference. J. Virol. 77: 8957-8961. [Abstract/Free Full Text]
27. Deuschle, U., W. K. Meyer, H. J. Thiesen. 1995. Tetracycline-reversible silencing of eukaryotic promoters. Mol. Cell Biol. 15: 1907-1914. [Abstract]
28. Gleixner, K. V., M. Mayerhofer, K. J. Aichberger, S. Derdak, K. Sonneck, A. Bohm, A. Gruze, P. Samorapoompichit, P. W. Manley, D. Fabbro, et al 2006. PKC412 inhibits in vitro growth of neoplastic human mast cells expressing the D816V-mutated variant of KIT: comparison with AMN107, imatinib, and cladribine (2CdA) and evaluation of cooperative drug effects. Blood 107: 752-759. [Abstract/Free Full Text]
29. Klucher, K. M., D. V. Lopez, G. Q. Daley. 1998. Secondary mutation maintains the transformed state in BaF3 cells with inducible BCR/ABL expression. Blood 91: 3927-3934. [Abstract/Free Full Text]
30. Sexl, V., R. Piekorz, R. Moriggl, J. Rohrer, M. P. Brown, K. D. Bunting, K. Rothammer, M. F. Roussel, J. N. Ihle. 2000. Stat5a/b contribute to interleukin 7-induced B-cell precursor expansion, but abl- and bcr/abl-induced transformation are independent of stat5. Blood 96: 2277-2283. [Abstract/Free Full Text]
31. Fabbro, D., S. Ruetz, S. Bodis, M. Pruschy, K. Csermak, A. Man, P. Campochiaro, J. Wood, T. O’Reilly, T. Meyer. 2000. PKC412—a protein kinase inhibitor with a broad therapeutic potential. Anticancer Drug Des. 15: 17-28. [Medline]
32. Schwartz, L. B., D. D. Metcalfe, J. S. Miller, H. Earl, T. Sullivan. 1987. Tryptase levels as an indicator of mast-cell activation in systemic anaphylaxis and mastocytosis. N. Engl. J. Med. 316: 1622-1626. [Abstract]
33. Schwartz, L. B., K. Sakai, T. R. Bradford, S. Ren, B. Zweiman, A. S. Worobec, D. D. Metcalfe. 1995. The alpha form of human tryptase is the predominant type present in blood at baseline in normal subjects and is elevated in those with systemic mastocytosis. J. Clin. Invest. 96: 2702-2710. [Medline]
34. Sperr, W. R., J. H. Jordan, M. Fiegl, L. Escribano, C. Bellas, S. Dirnhofer, H. Semper, I. Simonitsch-Klupp, H. P. Horny, P. Valent. 2002. Serum tryptase levels in patients with mastocytosis: correlation with mast cell burden and implication for defining the category of disease. Int. Arch. Allergy Immunol. 128: 136-141. [Medline]
35. Kitamura, Y., S. Go, K. Hatanaka. 1978. Decrease of mast cells in W/Wv mice and their increase by bone marrow transplantation. Blood 52: 447-452. [Abstract/Free Full Text]
36. Kitamura, Y., S. Go. 1979. Decreased production of mast cells in S1/S1d anemic mice. Blood 53: 492-497. [Free Full Text]
37. Valent, P., E. Spanblochl, W. R. Sperr, C. Sillaber, K. M. Zsebo, H. Agis, H. Strobl, K. Geissler, P. Bettelheim, K. Lechner. 1992. Induction of differentiation of human mast cells from bone marrow and peripheral blood mononuclear cells by recombinant human stem cell factor/kit-ligand in long-term culture. Blood 80: 2237-2245. [Abstract/Free Full Text]
38. Ferrao, P., T. J. Gonda, L. K. Ashman. 1997. Expression of constitutively activated human c-Kit in Myb transformed early myeloid cells leads to factor independence, histiocytic differentiation, and tumorigenicity. Blood 90: 4539-4552. [Abstract/Free Full Text]
39. Chian, R., S. Young, A. Nilkovitch-Miagkova, L. Ronnstrand, E. Leonard, P. Ferrao, L. Ashman, D. Linnekin. 2001. Phosphatidylinositol 3 kinase contributes to the transformation of hematopoietic cells by the D816V c-Kit mutant. Blood 98: 1365-1373. [Abstract/Free Full Text]
40. Zermati, Y., S. P. De, F. Feger, S. Letard, J. Kersual, N. Casteran, G. Gorochov, M. Dy, D. A. Ribadeau, K. Dorgham, et al 2003. Effect of tyrosine kinase inhibitor STI571 on the kinase activity of wild-type and various mutated c-kit receptors found in mast cell neoplasms. Oncogene 22: 660-664. [Medline]
41. Schittenhelm, M. M., S. Shiraga, A. Schroeder, A. S. Corbin, D. Griffith, F. Y. Lee, C. Bokemeyer, M. W. Deininger, B. J. Druker, M. C. Heinrich. 2006. Dasatinib (BMS-354825), a dual SRC/ABL kinase inhibitor, inhibits the kinase activity of wild-type, juxtamembrane, and activation loop mutant KIT isoforms associated with human malignancies. Cancer Res. 66: 473-481. [Abstract/Free Full Text]
42. Gesbert, F., J. D. Griffin. 2000. Bcr/Abl activates transcription of the Bcl-X gene through STAT5. Blood 96: 2269-2276. [Abstract/Free Full Text]
43. Weisberg, E., C. Boulton, L. M. Kelly, P. Manley, D. Fabbro, T. Meyer, D. G. Gilliland, J. D. Griffin. 2002. Inhibition of mutant FLT3 receptors in leukemia cells by the small molecule tyrosine kinase inhibitor PKC412. Cancer Cell 1: 433-443. [Medline]
44. Ferrao, P. T., T. J. Gonda, L. K. Ashman. 2003. Constitutively active mutant D816VKit induces megakayocyte and mast cell differentiation of early haemopoietic cells from murine foetal liver. Leuk. Res. 27: 547-555. [Medline]
45. Escribano, L., B. Díaz-Agustín, C. Bellas, R. Navalon, R. Nuñez, W. R. Sperr, G. H. Schernthaner, P. Valent, A. Orfao. 2001. Utility of flow cytometric analysis of mast cells in the diagnosis and classification of adult mastocytosis. Leuk. Res. 25: 563-570. [Medline]
46. Escribano, L., A. Orfao, B. Díaz-Agustín, J. Villarrubia, C. Cervero, A. Lopez, M. A. Marcos, C. Bellas, S. Fernandez-Canadas, M. Cuevas, et al 1998. Indolent systemic mast cell disease in adults: immunophenotypic characterization of bone marrow mast cells and its diagnostic implications. Blood 91: 2731-2736. [Abstract/Free Full Text]
47. Shelburne, C. P., M. E. McCoy, R. Piekorz, V. V. Sexl, S. R. Gillespie, D. P. Bailey, A. Gharse, P. Mirmonsef, M. N. Mann, M. Kashyap, et al 2002. Stat5: an essential regulator of mast cell biology. Mol. Immunol. 38: 1187-1191. [Medline]
48. Shelburne, C. P., M. E. McCoy, R. Piekorz, V. Sexl, K. H. Roh, S. M. Jacobs-Helber, S. R. Gillespie, D. P. Bailey, P. Mirmonsef, M. N. Mann, et al 2003. Stat5 expression is critical for mast cell development and survival. Blood 102: 1290-1297. [Abstract/Free Full Text]
49. Zuluaga Toro, T., F. H. Hsieh, J. Bodo, H. Y. Dong, E. D. Hsi. 2007. Detection of phospho-STAT5 in mast cells: a reliable phenotypic marker of systemic mast cell disease that reflects constitutive tyrosine kinase activation. Br. J. Haematol. 139: 31-40. [Medline]
50. Pan, J., A. Quintas-Cardama, H. M. Kantarjian, C. Akin, T. Manshouri, P. Lamb, J. E. Cortes, A. Tefferi, F. J. Giles, S. Verstovsek. 2007. EXEL-0862, a novel tyrosine kinase inhibitor, induces apoptosis in vitro and ex vivo in human mast cells expressing the KIT D816V mutation. Blood 109: 315-322. [Abstract/Free Full Text]
51. Hahn, W. C., C. M. Counter, A. S. Lundberg, R. L. Beijersbergen, M. W. Brooks, R. A. Weinberg. 1999. Creation of human tumour cells with defined genetic elements. Nature 400: 464-468. [Medline]
52. Födinger, M., G. Fritsch, K. Winkler, W. Emminger, G. Mitterbauer, H. Gadner, P. Valent, C. Mannhalter. 1994. Origin of human mast cells: development from transplanted hematopoietic stem cells after allogeneic bone marrow transplantation. Blood 84: 2954-2959. [Abstract/Free Full Text]

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