The G-CSF-R^T617N mutation is located in the transmembrane (TM) domain of the receptor, analogously to the MPL^S505N mutation associated with hereditary or acquired thrombocythemia (Ding et al., 2004; Chaligne et al., 2008). To evaluate the influence of the T617N mutation on TM helix interactions in the G-CSF-R, conformational searches were performed to identify low energy dimer conformations (Adams et al., 1996). For the wild-type G-CSF-R sequence, the lowest energy dimer structure that emerged from the searches had a symmetric orientation of the TM helices with Thr617 in the interface. The lowest energy structures of T617N G-CSF-R dimers had the same helix orientation, but with substantially lower interaction energies (wild-type, approximately –69 kcal/mol; T617N mutant, approximately –81 kcal/mol; Fig. 2). These computational data strongly support the notion that Asn617 stabilizes an active dimeric orientation for G-CSF-R by forming interhelical hydrogen bonds.

View larger version (39K): [in this window] [in a new window] [Download PPT slide]   Figure 2. Computational searches of wild-type and T617N G-CSF-R dimers. (A) Molecular structure of the helix dimer of the T617N mutant having the overall lowest energy in the computational searches. The helices have a left-handed crossing angle and an axial separation of 10.5 Å. The interfacial amino acids are highlighted. (B) Plot of the helix interaction energies in the wild-type (black) and T617N (red) TM helix dimers with axial separations of 10.5 Å. In the wild-type G-CSF-R, the dominant interaction is a direct Thr617–Thr617 hydrogen bond between side chain hydroxyl groups. In contrast, there are several strong stabilizing interactions in the mutant. The Asn amide side chain forms hydrogen bonds to the thiol side chain of Cys620. Trp624 forms stabilizing van der Waals contacts with the opposing helix; the indole NH is also able to form an interhelical H bond with Cys620. The total interaction energies were very similar for the lowest energy T617N dimers in computational searches at 10 Å (–80.6 kcal/mol) and 10.5 Å (–81.0 kcal/mol). (C) Cross section of the T617N helix dimer showing hydrogen-bonding interactions involving Thr617 and Cys620. The axial separation is 10.5 Å. (D) Cross section of the T617N helix dimer with an axial separation of 11 Å stabilized by interhelical interactions between Asn617 side chains and between Asn617 and Cys618. The overall interaction energies were generally higher at longer interhelical separations for both the wild-type and mutant dimers, although the T617N dimers were consistently lower in energy than those of the wild-type dimers because of the ability of Asn617 to form interhelical hydrogen bonds.

To investigate the effects of the T617N mutation on G-CSF-R signaling, CD34⁺ cells isolated from normal donors or patients were first deprived of cytokines, and then stimulated with G-CSF for various periods of time and subjected to Western blot analysis using specific antibodies. Interestingly, patient cells exhibited constitutive phosphorylation of JAK2, STAT3, AKT, and ERK. After G-CSF stimulation, JAK2, STAT3, STAT5, ERK, and AKT were rapidly and transiently activated in cells from normal donors, whereas phosphorylation was much more potent and sustained in cells from patients (Fig. 1 F). In addition, a specific JAK2 inhibitor abrogated constitutive and G-CSF–induced activation, suggesting that the mechanism of neutrophilia was JAK2 dependent, reminiscent of JAK2^V617F MPD.

We next infected mouse lineage (Lin^–) BM cells with a retrovirus containing CSF3R^wt or CSF3R^T617N mutation or the empty vector (Migr), and engrafted the infected cells into irradiated hosts. Mice transplanted with cells expressing the mutant G-CSF-R^T617N developed neutrophilia and displayed a high percentage of Gr-1⁺ granulocytes both in blood (33% in T617N vs. 15% in WT) and spleen (31% in T617N vs. 6% in WT; Fig. 3, A, B, E, and F), whereas the percentage of granulocytes in BM was only slightly affected (Fig. 3, C and D). An increase in B220⁺ B cells was also observed in the spleen, which may be caused by an increase in lymphopoiesis mediated by the ectopic expression of the G-CSF-R^T617N after retroviral transduction in hematopoietic stem cells (HSCs). Alternatively, this might be related to cytokine release in the spleen by the granulocytic precursors. All CSF3R^T617N mice developed splenomegaly (Fig. 3 G). These data demonstrate that the T617N mutation in the G-CSF-R is at the origin of the neutrophilia observed in patients. To directly assess the consequences of this mutation on human HSCs, we performed xenotransplantation in irradiated NOG mice of CD34⁺ cells isolated either from the blood of patient 15 or from a G-CSF–mobilized normal donor. At week 15 after transplant, the level of engraftment was measured by the percentage of human CD45⁺ cells in mouse blood, BM, spleen, and thymus. Levels of chimerism were lower in the four organs studied when patient CD34⁺ cells were injected compared with control cells (Fig. 4 A). Conversely, myeloid cells represented the predominant population in the blood, BM, and spleen of mice transplanted with patient CD34⁺ cells (Fig. 4 B), whereas B cells were prevalent with control cells (Fig. 4 C), as previously described (Bhatia et al., 1997; Ito et al., 2002; Matsumura et al., 2003). This skewed differentiation of HSCs to myeloid differentiation in immunodeficient mice has previously been described in MPDs (James et al., 2008). The frequency of human myeloid progenitors found among the CD45⁺ in the BM of mice engrafted with patient cells was increased in comparison to control cells. Moreover, a marked increase in the content of hematopoietic progenitors was observed in the blood of patient cell–engrafted mice (Fig. 4 D). Collectively, these results show that G-CSF-R^T617N mutant not only skews cells to myeloid differentiation in NOG mice but also induces a mobilization of hematopoietic progenitors. Thus, in contrast to the truncating mutations found in severe congenital neutropenia, the CSF3R^T617N mutation does not confer a major HSC-proliferative advantage but rather increases myeloid differentiation (McLemore et al., 1998; Liu et al., 2008).

View larger version (29K): [in this window] [in a new window] [Download PPT slide]   Figure 3. CSF3RT617N mutation yields to MPD in the mouse BM transplant model. BM cells were collected from C57/B6 SJL (CD45.2) mice 2 d after 5-fluorouracil treatment. Lin– cells were purified; cultured for 2 d with IL-3, SCF, IL-6, and TPO; infected twice with the viral particles containing empty vector (Migr), CSF3Rwt, or CSF3RT617N; and finally injected intravenously into lethally irradiated (825 rad) C57BL6 (CD45.1) mice. After 5 wk, mice were sacrificed and the total number of cells (A, C, and E) or the percentage of cells (B, D, and F) including granulocytes (Gr-1+), B lymphocytes (B220+), or T lymphocytes (CD3+) was measured in CD45.2+ donor mouse cells in the blood (A and B), BM (C and D), and spleen (E and F). (G) Spleen from Migr-engrafted (I), CSF3Rwt-engrafted (II), and CSF3RT617N-engrafted (III) mice. The results are the means ± SD of four mice of each group from two independent experiments. *, P < 0.05 compared with Migr-engrafted mice.

View larger version (24K): [in this window] [in a new window] [Download PPT slide]   Figure 4. CSF3RT617N mutation yields to MPD in the xenotransplantation model. CD34+ cells from normal subjects or from patients were intravenously injected into NOG mice and sacrificed at 15 wk. Flow cytometry analysis of human cell engraftment shows the percentage of human CD45+ cells (A) and percentage of B (CD19+) and myeloid (CD33+) cells (B and C) among CD45+ cells in the peripheral blood, BM, spleen, and thymus. The results are the means ± SD of four mice for donors and patient from two independent experiments. (D) Peripheral blood progenitors among CD45+ cells from donor- or patient-engrafted mice.

	MATERIALS AND METHODS

Top ABSTRACT RESULTS AND DISCUSSION MATERIALS AND METHODS REFERENCES

 
Patient cells.
Blood samples from patients, normal subjects, and G-CSF–mobilized patients were collected after informed consent was obtained. The study was approved by the Local Research Ethics Committee from the Hôtel-Dieu and the Henri Mondor hospitals, and informed consent was obtained from each patient in accordance with the Declaration of Helsinki.

Purification and in vitro differentiation of CD34⁺ cells.
Mononuclear cells were separated over a Ficoll density gradient, and CD34⁺ cells were purified by a double-positive magnetic cell sorting system (AutoMACS; Miltenyi Biotec) according to manufacturer's recommendations. CD34⁺ cells were either plated for 15 d in methylcellulose (StemCell Technologies Inc.) in the presence of 25 ng/ml SCF and G-CSF, or amplified for 21 d in granulocytic conditions in serum-free liquid medium containing IMDM with penicillin/streptomycin/glutamine, -thioglycerol, BSA, a mixture of sonicated lipids, and insulin-transferrin in the presence of recombinant human cytokines (25 ng/ml SCF and 20 ng/ml G-CSF).

Western blot analysis.
After purification, CD34⁺ cells were deprived in IMDM alone for 4 h in the presence or not of JAK2 inhibitor (AZD1480) at 1 µM. AZD1480 was a gift from AstraZeneca (Waltham, MA). Cells were stimulated by 20 ng/ml G-CSF for different intervals, washed in PBS, and lysed in denaturing loading dye buffer. Western blot analysis was performed using conventional techniques using anti-Jak2 (pY1007/1008), anti-STAT3 (pY705), anti-STAT5 (pY705), anti-ERK p42-p44 (T202/Y204), and anti-AKT (S473) antibodies (Cell Signaling Technology), and anti–β-actin antibodies. Antibodies were visualized using the enhanced chemoluminescence detection kit (GE Healthcare).

DNA sequencing.
Genomic DNAs were isolated from mononuclear cells or granulocytes according to standard procedures. Each of the 17 exons of the CSF3R gene (available from GenBank/EMBL/DDBJ under accession no. M59820) was amplified using standard PCR conditions from 300 ng of genomic DNA and primer sequences derived from flanking intronic sequences. PCR products were filtration purified (Multiscreen PCR; Millipore), sequenced using the BigDye Terminator cycle sequencing ready reaction kit (Applied Biosystems) according to the manufacturer's protocol, and analyzed on an ABI PRISM 3100 Genetic Analyzer (Applied Biosystems).

Generation of CSF3R mutant retroviruses and in vivo reconstitution of mouse hematopoietic system.
A human hemagglutinin-tagged full-length CSF3R open reading frame was cloned the in pMIGR-IRES-GFP retroviral vector. Mutagenesis reactions for human CSF3R were performed using the QuickChange site-directed mutagenesis kit (Agilent Technologies). All constructs were verified by sequencing.

Vesicular stomatitis virus glycoprotein–pseudotyped viral particles of pMIGR-IRES-GFP (empty vector), pMIGR-CSF3R-IRES-GFP, and pMIGR-T617N-CSF3R-IRES-GFP were produced into the 293 EBNA cells. Ecotropic virus-producing cell lines were generated from infection of the GP+E-86 packaging cell line (supplied by A. Bank, Columbia University, New York, NY) with concentrated virus supernatants.

BM (Lin^–) cells were collected from C57BL/6 SJL (CD45.2) mice (Charles River Laboratories) 2 d after 5-fluorouracil treatment. Lin^– cells were purified; cultured for 2 d with IL-3, SCF, IL-6, and TPO; and infected twice with the viral particles and finally injected intravenously into lethally irradiated (8.25 Gy) C57BL/6 (CD45.1) mice.

Hemoglobin, mean corpuscular volume, hematocrit, RBC, platelet, and WBC counts, and the lymphocyte/granulocyte ratio were determined using an automated counter (MS9; Schloessing Melet) on blood collected from the retro-orbital plexus in citrated tubes. BM cells were removed by flushing two femurs and two tibias. Spleens were weighed and single-cell suspensions were prepared. Differential cell counts were performed after May-Grünwald-Giemsa staining of blood smears or spleen and BM cell cytospins.

NOG mice repopulation assays.
24 h before transplantation, 6–8-wk-old NOD/SCID/c^–/– (NOG) mice, provided by M. Ito (Central Institute for Experimental Animals, Kawasaki, Japan), were sublethally irradiated (3 Gy) as previously described (Ito et al., 2002). CD34⁺ cells from G-CSF–mobilized donors or from patients were intravenously injected into NOG mice without any administration of cytokines. Human cell engraftment was assessed by flow cytometry by measuring human leukocytes (CD45⁺). Blood was lysed. BM cells were removed by flushing both femurs. Spleens were weighed and single-cell suspensions were prepared. NOG mice were bred in our pathogen-free breeding facility (Service Centrale d'Expérimentation Animale).

For progenitor assay, 50 µl of peripheral blood and BM from mice engrafted with donors or patient cells were seeded in methylcellulose, and progenitors were counted after 14 d in the presence of a cocktail of cytokines (100 IU/ml IL-3, 25 ng/ml SCF, 3 IU/ml erythropoietin, and 5 ng/ml GM-CSF). The number of human colonies was normalized to 100,000 human cells.

FACS analysis.
Flow cytometry was used to determine GFP expression and cell content of blood, BM, and spleen cells with appropriate PE- or allophycocyanin-conjugated antibodies (anti–human CD45, anti-CD45.1, anti-CD45.2, anti-CD19, anti-CD3, anti-CD33, anti-CD11b, anti-CD15, anti-CD14, anti-CD34, anti-CDB220, and anti–Gr-1 antibodies; BD) using a cytometer (FACSsort) with the Cell Quest software package (BD).

Modeling the effect of the T617N mutation on G-CSFR structure and dimerization.
Computational searches for low energy dimer conformations were performed using the program CHI (Adams et al., 1996). Canonical helices were constructed from the TM sequence of the G-CSF-R (IILGLFGLLLLLTCLCGTAWLCC). Low energy conformations of helix dimers were searched by rotating each helix through rotation angles 1 and 2 from 0–360°, with a sampling size of 45° for axial separations between TM helices of 9.5, 10, 10.5, 11, and 11.5 Å, as described previously (Seubert et al., 2003).

Online supplemental material.
Fig. S1 shows qRT-PCR of EVI1 using the Taqman gene expression master mix (Applied Biosystems) and specific primers, as previously described (Vinatzer et al., 2003). In Fig. S2, CD34⁺ progenitors cells either from controls or from patients were cultured in methylcellulose in the presence of SCF and various doses of G-CSF, or in the presence of SCF alone. Granulocytic colonies were counted 15 d later. Alternatively, cells from patients were cultured with or without 1 µM AZD1480. Fig. S3 indicates granulocytic differentiation using FACS analysis using anti-CD34, anti-CD15, anti-CD14, and anti-CD11b antibodies. Online supplemental material is available at http://www.jem.org/cgi/content/full/jem.20090693/DC1.

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