Methods and Compositions for Modulating TH-GM Cell Function

Abstract
Disclosed herein is a T-helper cell (“TH-GM” cell) that is regulated by IL-7/STAT5 and which secrete GM-CSF/IL-3. Also disclosed are methods and compositions for modulating TH-GM function for the treatment of, e.g., inflammatory disorders. Diagnostic and prognostic methods for specifically identifying TH-GM-mediated inflammatory disorders (e.g., rheumatoid arthritis), as distinct from and/or in addition to non-TH-GM-mediated (e.g., TNF-α-mediated) inflammatory disorders, are also provided.
Description
RELATED APPLICATION

This application claims the benefit of Singapore Patent Application No. 10201406130P, filed Sep. 26, 2014. The entire teachings of the above application are incorporated herein by reference.


BACKGROUND OF THE INVENTION

A significant body of research has led to the current model of immunity and inflammation, as well as the dysregulation in immune and inflammatory disorders. It is currently understood that CD4+ helper T (TH) cells play a crucial role in host defense against various pathogens by orchestrating adaptive and innate immune responses. Upon T-cell receptor (TCR) activation by cognate antigen, naïve CD4+ T cells are committed to differentiate into at least live major subsets: TH1, TH2, TH17, iTreg and TFH, which are modulated by cytokine milieus. TH1 and TH17 cells are known to be the primary effectors of inflammation. However, the pathogenic roles of either TH1 or TH17 in various inflammatory disorders remain unclear. For example, recent studies conflict with previously understood paradigm of TH17 in multiple sclerosis (MS) pathogenicity (Haak et al., 2009), making it more challenging to identify potential drug targets for MS therapy. Similarly, while rheumatoid arthritis (RA) is traditionally understood to be a disorder mediated by tumor necrosis factor α (TNF-α), up to 40% of RA patients fail to respond to anti-TNF-α treatment.


Accordingly, there remains a significant unmet need for effective treatment methods for autoimmune and inflammatory disorders such as, e.g., MS and RA.


SUMMARY OF THE INVENTION

The present disclosure relates, in part, to the identification of an interleukin-7 (IL-7)/signal transducer and activator of transcription 5 (STAT5)-regulated granulocyte macrophage colony-stimulating factor (GM-CSF)/IL-3-producing TH cells, termed TH-GM, which represent a distinct helper T cell subset with unique developmental and functional characteristics. Identified herein is an inflammatory pathway mediated by TH-GM cells (TH-GM-mediated inflammatory pathway), which represents an independent inflammatory pathway apart from known non-TH-GM-mediated inflammatory pathways (e.g., TNF-a, IL-6, and IL-1b pathways of inflammation). The present disclosure provides methods and compositions for diagnosing inflammatory disorders that are TH-GM-mediated, and modulating TH-GM cell function for the treatment of inflammatory disorders mediated by the TH-GM pathway.


Accordingly, in one aspect, the present disclosure provides a method of diagnosing a TH-GM-mediated inflammatory disorder in a patient suffering from an inflammatory disorder, comprising: a) contacting a sample collected from a patient suffering from an inflammatory disorder with a detecting agent that detects a polypeptide or nucleic acid level of STAT5 (e.g., phospho-STAT5 (Tyr694)). IL-7, GM-CSF or IL-3, or a combination thereof; and h) quantifying the polypeptide or nucleic acid level of STAT5 (e.g., phospho-STAT5 (Tyr694)), IL-7, GM-CSF or IL-3, or a combination thereof, wherein an increased level of STAT5 (e.g., phospho-STAT5 (Tyr694)), interleukin-7 (IL-7), GM-CSF or interleukin-3 (IL-3), or a combination thereof relative to a reference level indicates that the patient suffers from a TH-GM-mediated inflammatory disorder.


In another aspect, the present disclosure provides an isolated population of GM-CSF-secreting T-helper cells (TH-GM), wherein the TH-GM cells are differentiated from cluster of differentiation 4 (CD4+) precursor cells in the presence of IL-7 and activated STAT5, and wherein the TH-GM cells express GM-CSF and IL-3.


In another aspect, the present disclosure provides a method of modulating TH-GM function, comprising contacting the TH-GM, or CD4+ precursor cells, or both, with a modulating agent that modulates TH-GM function.


In some aspects, the present disclosure provides a method of treating a TH-GM-mediated inflammatory disorder in a patient in need thereof, comprising administering to said patient an effective amount of a modulating agent that modulates TH-GM cell function.


In other aspects, the present disclosure provides a method of treating rheumatoid arthritis in a patient who exhibits limited response to anti-tumor necrosis factor alpha (TNF-α) therapy, comprising administering to said patient an effective amount of a modulating agent that modulates TH-GM function.


In another aspect, the present disclosure provides a method of treating a STAT5-mediated inflammatory disorder in a patient in need thereof, comprising administering to the patient an effective amount of an agent that modulates STAT5 function.


In further aspects, the present disclosure provides a method of screening to identify a modulator of TH-GM cell function, comprising contacting an isolated population of TH-GM cells, or an isolated population of CD4+ precursor cells, with a candidate agent, and determining a readout of TH-GM function in the presence or absence of the candidate agent, wherein a change in the readout of TH-GM function indicates that the candidate agent is a modulator of TH-GM function.


The present disclosure enables the identification or classification between inflammatory disorders that are either primarily TH-GM-mediated, or primarily non-TH-GM-mediated (e.g., mediated by TNF-α, IL-6, and/or IL-1β), or both. Thus, using the methods described herein, it is possible to determine whether a patient suffering from, e.g., RA, suffers from an RA that is primarily TH-GM-mediated, or primarily non-TH-GM-mediated, or both. This differentiation allows for a more targeted and tailored method of treating inflammatory disorders such as RA, for which current treatments are only 40% effective. Further, the present disclosure provides methods and compositions for prognosing the progression of an inflammatory disorder so as to tailor the treatment according to the stage of the disease. Also provided herein are compositions and methods for and the treatment of inflammatory disorders, particularly those that are TH-GM-mediated.





BRIEF DESCRIPTION OF THE DRAWINGS

The foregoing will be apparent from the following more particular description of example embodiments of the invention.



FIGS. 1A-1D depict Stat5-conditional mutant mice are resistant to EAE. Clinical EAE scores (FIG. 1A) and incidence (FIG. 1B) of Stat5+/+ and Stat5−/− mice immunized twice with MOG35-55/CFA. Data are representative of three independent experiments (FIG. 1A) or pooled from three experiments (FIG. 1B, n=18 per group). Clinical scores of EAE mice immunized once with MOG35-55/CFA (FIG. 1C, n=5 per group) or immunized twice with MOG35-55/LPS (FIG. 1D). Data are representative of two independent experiments.



FIGS. 2A-2D depict reduced neuroinflammation in Stat5 conditional mutant mice. Histology of spinal cord sections obtained from EAE mice at day 9 after 2nd immunization (FIG. 1A). Images shown are representative of two independent experiments with three mice per group. Scale bars, 200 μm (top), 50 μm (bottom). CD4+ and CD11b+ cells in spinal cord sections were stained by immunofluorescence (FIG. 1B). Images shown are representative of two independent experiments with three mice per group. Scale bars, 200 μm. CNS mononuclear cells were analyzed by flow cytometry at peak of disease (FIGS. 2C and 2D). Right panels are cell proportions (FIG. 2C, right) or cell numbers (FIG. 2D, right) pooled from two experiments (n=9).



FIGS. 3A and 3B depict the resistance to EAE in Stat5-deficient mice is independent of TH1, TH17 or Treg cells. Flow cytometric analysis of IL-17 and IFN-γ expression by CNS-infiltrating CD4+ T cells at peak of disease (FIG. 3A). Data are representative of three independent experiments. Percentage of CD25+ among CD4+ T cells in the CNS of Stat5+/+ and Stat5−/− EAE mice at peak of disease were analyzed by flow cytometry (FIG. 3B).



FIGS. 4A-4C depict conditional Stat5 mutant mice have no defect in CD4+ T cell generation in periphery. Spleens were obtained from MOG35-55/CFA-immunized Stat5+/+ and Stat5−/− mice at day 7 (FIG. 4A) and day 21 (FIG. 4B). The proportions of CD4+ and CD8+ T cells were analyzed by flow cytometry. The absolute number of CD4+ T cells was calculated (right panels). Data are representative of two independent experiments (FIG. 4A) or pooled from two independent experiments (FIG. 4B). IL-17 and IFN-γ expression by splenic CD4+ T cells of Stat5+/+ and Stat5−/− EAE mice was determined by intracellular cytokine staining (FIG. 4C). Data are representative of three independent experiments. *p<0.5, **p<0.005, ***p<0.0005.



FIGS. 5A-5D depict Stat5-deficient CD4+ T cells can infiltrate CNS but fail to induce effective neuroinflammation. CCR6, CXCR3 and CD69 expression by splenic CD4+ T cells of Stat5+/+ and Stat5−/− EAE mice was measured. Data are representative of two independent experiments with three to five mice per group (FIG. 5A). CNS-infiltrating CD4+ T cells were analyzed at day 7, 9 and 21 after first MOG35-55/CFA immunization (FIGS. 5B-5D). Cell numbers were calculated (FIG. 5D). Data are representative of two independent experiments with three mice per group. *p<0.5.



FIGS. 6A-6C show resistance to EAE in Stat5−/− mice is not caused by any defect in the survival of CD4+ T cells in the absence of STAT5. CD4+ T cell infiltration (FIG. 6A) and clinical scores (FIG. 6B) of Rag2−/− recipient mice transferred with different numbers of Stat5+/+ and Stat5−/− CD4+ T cells. Clinical scores and frequencies of CD4+ T cells in the CNS at day 21 (disease peak) of EAE induction (FIG. 6C). *p<0.05. ***p<0.0005.



FIGS. 7A-7C depict the intrinsic defect of Stat5-deficient CD4+ T cells in encephalitogenicity. Clinical EAE scores (FIG. 7A) and incidence (FIG. 7B) of Rag2−/− mice (n=5 per group) after adoptive transfer of 2 million MOG35-55-specific Stat5+/+ or Stat5−/− CD4+ T cells respectively. IL-17 and IFN-γ expression by CNS-infiltrating CD4+ T cells was measured at peak of disease (FIG. 7C). Data represent two independent experiments, *p<0.05.



FIGS. 8A-8D depict the diminished induction of GM-CSF in splenic Stat5−/− CD4+ T cells. In FIGS. 8A-8D, splenocytes were obtained from MOG35-55/CFA-immunized Stat5+/+ and Stat5−/− mice (n=3 per group) before disease onset and challenged with MOG35-55 at various concentrations for 24 h. GM-CSF secretion was measured by ELISA (FIG. 8A). Golgiplug was added in the last 4 h of MOG35-55 (20 μg/ml) challenge and the frequencies of IL-17+ and GM-CSF+ cells among CD4+CD44hi T cells were measured (FIG. 8B). In FIGS. 8C and 8C, splenocytes were obtained from MOG35-55/CFA-immunized Stat5−/−, Stat3−/− or wild-type control mice and stimulated with PMA/Ionomycin in the presence of Golgiplug for 4 h. The frequencies of IL-17+ and GM-CSF+ cells among splenic CD4+CD44hi T cells were measured by intracellular cytokine staining. *p<0.05, ***p<0.001.



FIGS. 9A-9C depict the diminished induction of GM-CSF in CNS-infiltrating Stat5−/− CD4+ T cells. In FIG. 9A, IL-17, IFN-γ and GM-CSF expression by CNS-infiltrating CD4+ T cells of Stat5+/+ and Stat5−/− mice was measured at peak of disease. The percentage of GM-CSF+ cells among IL-17+ or IFN-γ+ cells was calculated (bottom right. FIG. 9A). IL-17. IFN-γ and GM-CSF expression by CNS-infiltrating CD4+ T cells of Rag2−/− recipient mice at peak of disease in adoptive transfer EAE (FIG. 9B). Time-course analysis of cytokine mRNA expression in the CNS of naïve and MOG35-55/CFA-immunized Stat5+/+ and Stat5−/− mice (n=3 per group at each time point). The RT-PCR data were normalized to Rn18S, and expression in naïve mice was set to 1 (FIG. 9C). Data represent two independent experiments. *p<0.05.



FIGS. 10A-10C show STAT5-mediated GM-CSF induction is independent of IL-23 or IL-1β signaling. In FIG. 10A, purified CD4+ T cells were cultured with TGF-β and IL-6 for 3 days, followed by starvation for 6 h. Then cells were treated with various cytokines for 30 min. and pSTAT3 and pSTAT5 was determined by immunoblotting. STAT3 and STAT5 were further detected after stripping. FIG. 10B shows the mRNA expression of IL-23R and IL-1R1 in splenic CD4+ T cells of Stat5+/+ and Stat5−/− EAE mice (n=3 per group). The RT-PCR data were normalized to β-Actin. In FIG. 10C, splenocytes were obtained from MOG35-55/CFA-immunized WT mice before disease onset and challenged with MOG35-55 (20 μg/ml) in the absence or presence of IL-2 for 48 h. The frequencies of GM-CSF+ and IL-17+ cells among CD4+CD44hi T cells were measured by flow cytometry. *p<0.05.



FIGS. 11A-11C depict IL-7-induced STAT5 activation promotes GM-CSF expression in autoreactive CD4+ T cells. Splenocytes were obtained from MOG35-55/CFA-immunized Stat5+/+ and Stat5−/− mice before disease onset and challenged with MOG35-55 (20 μg/ml) in the absence or presence of IL-7 for 48 h. Frequencies of GM-CSF+ and IL-17+ cells among CD4+CD44hi T cells were measured by flow cytometry (FIG. 11A). GM-CSF secretion was measured by ELISA (FIG. 11B). Data represent two independent experiments with two to three mice per group. Splenic CD62LhiCD44lo and CD62LloCD44hi T cells from MOG35-55/CFA-immunized mice were sorted out. Cells were stimulated with anti-CD3 and anti-CD28 in the absence or presence of IL-7 for 4 h and then harvested for the analysis of GM-CSF expression by RT-PCR (FIG. 11C). *p<0.05



FIGS. 12A-12F depict IL-7Rα neutralization attenuates GM-CSF expression and ameliorates EAE. Clinical scores of EAE mice (n=5) treated with anti-IL-7Rα or normal IgG given every other day from day 5 after 2nd immunization, as indicated by arrows. Data represent two independent experiments (FIG. 12A). Spinal cord sections were obtained from EAE mice at day 11 after 2nd immunization. Immune cell infiltration was assessed histologically. Images shown are representative of three individuals per group. Scale bars, 200 μm (top), 50 μm (FIG. 12B, bottom). The percentages of CD4+ and CD8+ T cells in spleens of EAE mice. Data represent two independent experiments (FIG. 12C). FIGS. 12D and 12E illustrate the frequencies of GM-CSF+, IL-17+ and IFN-γ+ cells among CD4+ T cells in the CNS of EAE mice receiving different treatment. The mRNA expression of IFN-γ, IL-17 and GM-CSF in the CNS of EAE mice (FIG. 12F). *p<0.05



FIGS. 13A and 13B depict the differentiation of GM-CSF-expressing TH cells is distinct from TH17 and TH1. Naïve CD4+ T cells were primed with plate-bound anti-CD3 and soluble anti-CD28 in the presence of a combination of various cytokines and neutralizing antibodies as indicated. GM-CSF, IL-17 and IFN-γ expression was analyzed by intracellular staining (FIG. 13A) or RT-PCR (FIG. 13B)



FIGS. 14A-14D show the effect of IL-2 and IL-6 on TH-GM differentiation from naïve T cells. GM-CSF and IFN-γ expression in naive CD4+ T cells activated for 72 h with anti-CD3 alone or plus anti-CD28 (FIG. 14A). In FIG. 14B, sorted naïve CD4+ T cells were stimulated with anti-CD3 and anti-CD28 in the presence of neutralizing antibodies against IL-12 and IFN-γ without or with the addition of IL-6. The frequencies of GM-CSF+ and IL-17+ cells were measured by intracellular staining (FIG. 14B). In FIG. 14C, naïve CD4+ T cells from Stat3+/+ and Stat3−/− mice were polarized under conditions as indicated for 72 h. The frequencies of GM-CSF+ and IL-17+ cells were analyzed. In FIG. 14D, naïve CD4+ T cells were activated with anti-CD3 and anti-CD28 in the presence of IL-2 or anti-IL-2. The frequencies of GM-CSF+, IL-17+ and IFN-γ+ cells were analyzed.



FIGS. 15A-15F depict IL-7-STAT5 signaling programs TH-GM differentiation from naïve precursor cells. Naïve CD4+ T cells were primed with plate-hound anti-CD3 and soluble anti-CD28 in the presence of various concentration of IL-7 as indicated. GM-CSF and IFN-γ expression was analyzed by intracellular staining (FIG. 15A) or ELISA (FIG. 15B). In FIGS. 15C and 15D, Stat5+/+ and Stat5−/− naïve CD4+ T cells were activated with anti-CD3 and anti-CD28 in the presence IL-7 for 3 days. GM-CSF, IL-17 and IFN-γ expression was analyzed by intracellular cytokine staining (FIG. 15C). GM-CSF secretion was measured by ELISA (FIG. 15D). Immunoblotting of pSTAT5 and STAT5 in IL-7-stimulated CD4+ T cells isolated from Stat5−/− or control mice (FIG. 15E). The ChIP assay was performed with Stat5+/+ and Stat5−/− CD4+ T cells using normal IgG or STAT5-specific antibody. The binding of antibodies to Csf2 promoter region was detected by RT-PCR (FIG. 15F).



FIGS. 16A and 16B depict the differentiation conditions for TH-GM subset. Naïve CD4+ T cells were activated with anti-CD3 and anti-CD28 in the presence of IL-7 or/and anti-IFN-γ as indicated. GM-CSF. IL-17 and IFN-γ expression was analyzed (FIG. 16A). The mRNA expression of T-bet and RORγt in naïve. TH1 (IL-12+anti-IL-γ), TH17 (TGF-β+IL-6+anti-IFN-γ+anti-IL-4) and TH-GM cells (IL-7 anti-IFN-γ) (FIG. 16B). The RT-PCR data were normalized to Gapdh, and expression in naïve T cells was set to 1.



FIGS. 17A-17E illustrate that IL-7 but not IL-2 induces STAT5 activation and GM-CSF expression in naïve CD4+ T cells. FIGS. 17A-17C show flow cytometry of CD25 and CD127 on the surface of naïve CD4+ T cells or cells activated with anti-CD3 and anti-CD28 at various time points as indicated. Activation of STAT5 in naïve CD4+ T cells stimulated with IL-2 or IL-7 for 30 min (FIG. 17D). FIG. 17E shows the mRNA expression of GM-CSF in naïve CD4+ T cells stimulated with anti-CD3 and anti-CD28 in the presence of IL-2 or IL-7. The RT-PCR data were normalized to β-Actin, and expression in naïve T cells activated for 2 h without cytokine was set to 1.



FIGS. 18A-18C show that both IL-2 and IL-7 can induce STAT5 activation and GM-CSF expression in activated CD4+ T cells. As shown in FIGS. 1.8A and 18B, CD4+ T cells were activated with anti-CD3 and anti-CD28 for 3 days. After resting in fresh medium, cells were stimulated with IL-2 or IL-7 at various time points. The pTyr-STAT5 and β-Actin were detected by immunoblotting (FIG. 18A). GM-CSF mRNA expression was measured by RT-PCR (FIG. 18B). The RT-PCR data were normalized to 13-Actin, and expression in cells without cytokine stimulation was set to 1. The ChIP assay shown in FIG. 18C was performed with normal IgG or STAT5-specific antibody. The binding of antibodies to Csf2 promoter region was detected by RT-PCR.



FIG. 19 depicts surface molecules selectively expressed at high level or low level in TH-GM subset as characterized by microarray analysis. These surface molecules specific for each lineage serves as markers, signatures and potential targets for novel diagnosis, treatment and prevention of autoimmune inflammation including, but not limited to multiple sclerosis and rheumatoid arthritis. These cell surface molecules are listed in detail in Table 1. The order of naïve, Th1, Th17, and Th-GM as indicated in the figure insert is the same as that appears for the bars in each graph.



FIGS. 20A-20D show that IL-3 is preferentially expressed in TH-GM cells. In FIGS. 20A and 20B, naïve CD4+ T cells were activated with anti-CD3 and anti-CD28 under TH1—(IL-12+anti-IL-4), TH17−(TGF-β+IL-6+anti-IFN-γ+anti-IL-4) and TH-GM—(GM-CSF+ TH, IL-7+anti-IFN-γ+anti-IL-4) polarizing conditions. GM-CSF and IL-3 expression was analyzed by intracellular staining (FIG. 20A). The mRNA expression of IL-3, EBI-3, PENK or RANKL cytokines was measured by RT-PCR (FIG. 20B). Frequency of IL-3+ cells differentiated without or with IL-7 (FIG. 20C). GM-CSF and IL-3 expression by WT or STAT5-deficient GM-CSF-producing TH cells (FIG. 20D).



FIG. 21 depicts clinical EAE scores of Rag2−/− mice (n=3˜6 mice per group) after adoptive transfer of 6×105 various MOG35-55-specific TH subsets.



FIGS. 22A-27E depict inhibition of STAT5 activation suppresses TH-GM cell differentiation in vitro. CD4+ T cells were pre-incubated with STAT5 inhibitor (Calbiochem) (FIG. 22A) or JAK3 inhibitor (FIG. 22B) at indicated concentrations or vehicle (−) for 1 h before stimulation with IL-7 for 30 min. Activation (Tyr694 phosphorylation) of STAT5 was determined by immunoblotting. CD4+ T cells were pre-incubated with STAT5 inhibitor at indicated concentrations or vehicle (−) for 1 h before stimulation with IL-6 for 30 min. Activation (Tyr705 phosphorylation) of STAT3 was determined by immunoblotting (FIG. 22C). In FIG. 221), CD4+ T cells were pre-incubated with STAT5 inhibitor at indicated concentrations or vehicle (−) for 1 h before stimulation with IFN-γ for 30 min. Activation (Tyr701 phosphorylation) of STAT1 was determined by immunoblotting. In FIG. 22E, naïve CD4+ T cells were isolated and activated under neutral condition or TH-GM cell-favoring condition with the addition of different concentrations of STAT5 inhibitor for 3 days. GM-CSF and IFN-γ expression was analyzed by intracellular cytokine staining and flow cytometry.



FIGS. 23A-23D depict targeting STAT5 activation by chemical inhibitor ameliorates EAE. (FIG. 23A) Clinical EAE scores of wild-type control mice (n=5) or administrated with STAT5 inhibitor (Calbiochem). Arrow indicates the treatment points. (FIG. 23B) Histology of spinal cords at clay 18 of EAE mice receiving different treatments. (FIG. 23C) Intracellular staining and flow cytometry of CNS-infiltrating CD4+ T cells at peak of disease. (FIG. 23D) Whole CNS was harvest for RNA extraction. GM-CSF mRNA expression was analyzed by RT-PCR. Data represent two independent experiments. *p<0.05.



FIGS. 24A-24E depict GM-CSF-producing TH cells are in association with human RA. Plasma concentrations of GM-CSF and TNF-α in healthy control HC (n=32) and RA (n=47) were quantified by ELISA (FIG. 24A). In FIGS. 24B and 24C, peripheral blood mononuclear cells (PBMCs) were collected from healthy control (HC) and rheumatoid arthritis (RA) patients, and were stimulated for 4 h with PMA/lonomycin in the presence of Golgiplug, followed by intracellular cytokine staining. Representative flow cytometry of GM-CSF, IFN-γ and IL-17 in CD4+ T cells (FIG. 24B) and statistics of n>=9 per group (FIG. 24C) are shown. FIG. 241D shows the correlation between the frequency of GM-CSF+IFN-γ TH cells and the level of plasma GM-CSF in peripheral blood of RA patients (n=18). Cytokine expression by CD4+ T cells derived from synovial fluid of RA patients was analyzed by intracellular cytokine staining and flow cytometry (FIG. 24E). A representative image of three cases was shown. *p<0.05, **p<0.01, ***p<0.001; ns, not significant.



FIGS. 25A-25E depict distinguishable effects of GM-CSF and TNF-α in mouse AIA. FIG. 25A shows knee joint swelling of wild-type mice over 7 days after intraarticular injection of 100 μg mBSA in AIA model, receiving treatment with control IgG, GM-CSF-specific and TNF-α-specific neutralizing antibodies separately or in combination (n=5 per group) at indicated times (arrows). FIG. 25B shows knee joint swelling of Stat5+/+ and Stat5−/− mice (n=6 per group) over 7 days after arthritis induction. Data are representative of more than three independent experiments. Representative images of joint sections stained with H&E (FIG. 25C) or Safranin-O/Fast Green (FIG. 25D) at day 7 after arthritis induction as in FIG. 25C. Bars, 500 μm (FIG. 25C upper panels and FIG. 25D) or 100 μm (FIG. 25C lower panels). Arrow in upper panels (FIG. 25C) indicated hone destruction. In FIG. 25E, serum concentrations of GM-CSF, IFN-γ and TNF-α in Stat5+/+ and Stat5−/− AIA mice were quantified by ELISA. Statistics of n>=8 per group were shown. *p<0.05, **p<0.01, ***p<0.001.



FIGS. 26A-26D depicts mice with Stat5 deletion in T cells are resistant to CIA. (FIG. 26A) Representative images of paw swelling of Stat5+/+ and Stat5−/− mice at day 40 after collagen II/CFA immunization in CIA model. (FIG. 26B) Clinical score of Stat5+/+ and Stat5−/− mice (n=5 per group) over 40 days after collagen II/CFA immunization. Data are representative of two independent experiments. (FIG. 26C) Representative images of paw sections stained with H&E at clay 40. (FIG. 26D) Serum concentrations of TNF-α (n=8 per group) were quantified by ELISA. *p<0.05, **p<0.01, ***p<0.001.



FIGS. 27A-27E depicts STAT5-deficient CD4+ T cells are defective in arthritogenic potential. (FIGS. 27A and 27B) Representative flow cytometry of CD4+ T cells in spleens (FIG. 27A) and inguinal lymph nodes (FIG. 27B) of Stat5+/+ and Stat5−/− mice at day 7 after AIA induction. (FIGS. 27C and 27D) Synovial tissues were harvested from Stat5+/+ and Stat5−/− mice at day 7 after AIA induction, and dissociated into single cells. Cell numbers of CD45+ leukocytes were calculated (FIG. 27C). The percentages of CD4+ T cells among CD45+ fraction were analyzed by flow cytometry, and cell numbers were calculated (FIG. 27D). (FIG. 27E) Histological analysis of joint sections from wild-type naïve mice at day 7 after being transferred with in vitro-expanded antigen-reactive CD4+ T cells and followed with intraarticular injection of mBSA. Bars, 100 μm. Data represent two independent experiments. *p<0.05; ns, not significant.



FIGS. 28A-28G depicts STAT5-regulated GM-CSF-producing TH cells are crucial for AIA. Spleens and synovial tissues were collected from Stat5+/+ and Stat5−/− mice at day 7 after arthritis induction. (FIG. 28A) Splenic fractions of wild-type AIA mice (n=3) were stimulated under indicated conditions for 18 h. GM-CSF levels in supernatant were quantified by ELISA. (FIGS. 28B-28D) Intracellular staining and flow cytometry of GM-CSF, IL-17 and IFN-γ in splenic CD4+CD44hi effector T cells (FIG. 28B) or in synovial infiltrating CD4+ T cells (FIGS. 28C and 28D) after restimulation for 4 h with PMA/Ionomycin in the presence of Golgiplug. Representative images and statistics of n=5 (FIG. 28B, right panels) or n=3 (FIG. 28D, right panels) per group were shown. Data represent two independent experiments. (FIG. 28E) Protein expression of several proinflammatory cytokines in synovial tissues was measured by ELISA. (FIGS. 28F and 28G) Representative images of joint sections stained with H&E (FIG. 28F) or Safranin-O/Fast Green (FIG. 28G) at day 7 after intraarticular injection of mBSA alone to the right knee joints and mBSA supplemented with GM-CSF to the left knee joints. Bars, 500, 50 or 200 μm as indicated. Data represent two independent experiments.*p<0.05, **p<0.01. ***p<0.001; ns, not significant. “Splenocytes” represent the left-most bars in each group, “splenocytes depleted of CD4+ T cells” represent the middle bars in each group, and “CD4+ T cells” represent the right-most bars in each group.



FIGS. 29A-29C depicts loss of STAT5 results in impaired GM-CSF production by antigen-specific CD4+ T cells. Spleens and inguinal LNs were collected from Stat5+/+ and Stat5−/− mice at day 7 after arthritis induction, and dissociated into single cell suspensions. Then, cells were stimulated with mBSA (20 μg/ml) for 24 h. (FIG. 29A) Golgiplug was added in the last 4 h of culture, followed by intracellular staining and flow cytometry. Representative plots of GM-CSF, IL-17 and IFN-γ expression in CD4+CD44hi effector T cells was shown, representing two independent experiments. (FIGS. 29B and 29C) Secreted cytokines in the supernatant (n=3 per group) were quantified by ELISA. Data represent two independent experiments. *p<0.05; ns, not significant.



FIGS. 30A-30C depicts loss of STAT5 impairs IL-6 and IL-1β expression in synovial tissues of arthritic mice. (FIGS. 30A-30C) The mRNA (FIGS. 30A and 30 C) and protein (FIG. 30B) expression of several proinflammatory cytokines in synovial tissues of Stat5+/+ and Stat5−/− mice (n>=3 per group) at day 5 or 7 after arthritis induction was measured by qPCR and ELISA. The qPCR data were normalized to Rn18S.



FIGS. 31A-31D depicts SAT5-induced GM-CSF expression mediates CD11b+ cell accumulation in inflamed synovial tissues. (FIG. 31A) The frequencies of CD11b+ cells in spleens of Stat5+/+ and Stat5−/− AIA mice were analyzed by flow cytometry. Statistics of n=3 per group (right panel) were shown. (FIG. 31B) Synovial tissues were harvested from Stat5+/+ and Stat5−/− mice at day 7 after arthritis induction, and dissociated into single cell suspensions. The percentage of CD11b+ myeloid cells among CD45+ fraction was analyzed by flow cytometry. Statistics of n=5 per group were shown in right panel. (FIG. 31C) Representative flow cytometry of CD11b+ and CD4+ cells gated on synovial CD45+ fraction over 7 days after arthritis induction. (FIG. 31D) Flow cytometric analysis of CD4+, CD11b+ and B220+ cell infiltration in synovial tissues of Stat5+/+ and Stat5−/− mice at day 7 after intraarticular injection of mBSA alone to the right knee joints and mBSA supplemented with GM-CSF to the left knee joints. Representative images were shown. All data shown are representative of two independent experiments. **p<0.01; ns, not significant.



FIGS. 32A-32D depicts GM-CSF mediates neutrophil accumulation in arthritic mice. (FIG. 32A) Flow cytometric analysis of Ly6C and Ly6G expression gated on synovial CD45+CD11b+ fraction over 7 days after arthritis induction. (FIG. 32B) Giemsa stain of sorted Ly6ChiLy6G and Ly6CloLy6Ghi cells from synovial tissues of AIA mice. Scale bar, 100 μm (left) or 20 μm (right). (FIG. 32C) Flow cytometric analysis of Ly6ChiLy6G and Ly6CloLy6Ghi populations in synovial tissues of Stat5+/+ and Stat5−/− mice at day 7 after intraarticular injection of mBSA alone to the right knee joints and mBSA supplemented with GM-CSF to the left knee joints. (FIG. 32D) Knee joint swelling of wild-type mice treated with Ly6G-specific neutralizing antibody (1A8) or IgG control (n=5 per group) over 3 days after intraarticular injection of mBSA in AIA model. Arrows indicate time points of antibody administration. *p<0.05.



FIGS. 33A-33C depicts GM-CSF enhances neutrophil transmigration and delay apoptosis in vitro. (FIG. 33A) Percentages of migrated neutrophils with or without GM-CSF as chemoattractant in transmigration assay at 3 h post start. (FIG. 33B) Microscopic images of CFSE-labeled neutrophils in the bottom of the lower chamber in transmigration assay. (FIG. 33C) Sorted neutrophils were cultured in vitro with or without GM-CSF (20 ng/ml) for 24 h. Neutrophils undergoing apoptosis were examined by Annexin V and propidium iodide (PI) co-staining. A representative flow cytometry of three repeats was shown. *p<0.05.



FIGS. 34A-34I depicts GM-CSF mediates proinflammatory cytokine expression by myeloid cells and synovial fibroblasts in arthritic mice. Synovial tissues were dissected from wild-type AIA mice and dissociated into single cell suspensions. (FIG. 34A) Flow cytometry plots depicting the fractionation into different populations based on differential expression of surface markers. (FIG. 34B) The mRNA expression of several proinflammatory cytokines in sorted CD45+TCRβ+ (TCRβ+ in short). CD45+TCRβCD11cCD11b+ (CD11b+) and CD45+TCRβCD11c+ (CD11c+) populations was measured by qPCR. The qPCR data were normalized to GAPDH. (FIG. 34C) The mRNA expression of IL-6, IL-1β and TNF-α in sorted Ly6ChiLy6G and Ly6CloLy6Ghi populations (gated on CD11b+ cells). The qPCR data were normalized to GAPDH. (FIGS. 34D and 34E) The mRNA expression of IL-6 and IL-1β by BMDMs (FIG. 34D) and BMDCs (FIG. 34E) upon stimulation with 20 ng/ml GM-CSF for 1 h. The qPCR data were normalized to GAPDH. (FIGS. 34F and 34G) BMDMs (FIG. 34F) and BMDCs (FIG. 34G) were stimulated with GM-CSF at indicated concentrations (n=3 per group) for 18 h. The secretion of IL-6 in the culture supernatant was quantified by ELISA. (FIG. 34H) BMDMs were primed with LPS (100 μg/ml) in the presence of GM-CSF at indicated concentrations (n=3 per group) for 6 h, followed by stimulation with ATP (5 mM) for 30 min. The secretion of IL-1β in the culture supernatant was quantified by ELISA. (FIG. 34I) Cells were cultured in DMEM medium supplemented with 10% PBS for over 20 days with more than 5 passages to obtain synovial fibroblasts. Synovial fibroblasts were stimulated with GM-CSF (20 ng/ml) for 1 h and harvested for RNA extraction. The mRNA expression of IL-1β was measured by qPCR. The qPCR data were normalized to GAPDH. All data shown represent two independent experiments.*p<0.05, **p<0.01.





DETAILED DESCRIPTION OF THE INVENTION

A description of example embodiments of the invention follows.


The present disclosure relates, in part, to the identification of a granulocyte macrophage colony stimulating factor (GM-CSF)-secreting T helper cell, termed “TH-GM”. As detailed herein. IL-7/STAT5 signaling programs the differentiation of precursor CD4+ cells to TH-GM, a process which is further modulated by IL-2 and IL-23 signaling. TH-GM cells are characterized by, e.g., GM-CSF and IL-3 production. TH-GM cells are distinct from the known helper T cells TH1 and TH17, with respect to, e.g., differentiation conditions, transcriptional regulation and effector cytokine expression. For example, IL-12/IFN-γ and TGF-0/IL-6, which mediate (e.g., promote the development of) TH1 and TH17, respectively, potently suppress the development of TH-GM from naïve CD4+ precursor cells, establishing that TH-GM cells develop via a lineage distinct from TH1 and TH17. Thus, the present disclosure provides a distinct network of factors, unique from factors known to mediate TH1 or TH17, that mediate TH-GM function (e.g., its differentiation and pathogenicity).


As shown herein, TH-GM cells preferentially induce EAE as compared with TH1 and TH17 cells, indicating that TH-GM cells represent the primary effectors in the pathogenesis of autoimmune neuroinflammation in humans. Moreover, blockade of IL-7 signaling and/or inhibition of STAT5 function (e.g., abrogation of expression or inhibition of STAT5 activity) attenuates autoimmune neuroinflammation associated with diminished GM-CSF production by TH-GM cells. Further, blockade of TH-GM cell-secreted GM-CSF ameliorates experimental arthritis in a TNT-α-independent manner, indicating an approach for the treatment of, e.g., rheumatoid arthritis patients who are unresponsive to TNF-α antagonistic drugs. Thus, the present disclosure enables one to distinguish between an inflammatory disorder (e.g., RA) that is mediated by the TH-GM pathway (e.g., a disorder that results from TH-GM pathogenicity through the action of, e.g., GM-CSF and/or IL-3, or any factor associated with the TH-GM pathway), or an inflammatory disorder that is mediated by, e.g., TNF-α, IL-6, and/or IL-1β pathways (i.e., non-TH-GM-mediated pathway). For example, a patient who has, e.g., RA may be afflicted with a type of RA that is primarily TH-GM-mediated, or primarily non-TH-GM-mediated (e.g., TNF-α-mediated or IL-6 mediated). The present disclosure enables the classification between TH-GM-mediated and non-TH-GM-mediated inflammation, allowing for a more precise diagnosis, prognosis, and treatment in an individual who is afflicted with an inflammatory disorder such as RA or MS.


As demonstrated herein, the present disclosure identifies a helper T cell subset (TH-GM), provides the molecular basis for the commitment and development of this subset from naïve precursor cells in vitro and in vivo, and demonstrates TH-GM cells as the primary pathogenic cells in autoimmune diseases and inflammatory disorders, for example, MS and RA. Thus, provided herein are compositions and methods for diagnosing inflammatory conditions primarily mediated by TH-GM cells, thereby enabling the identification of, e.g., RA patients who are non-responsive to TNF-α therapy (e.g., TNF-α inhibitor based therapy), as well as compositions and methods for modulating TH-GM function to treat autoimmune and inflammatory disorders. The methods of modulating TH-GM function include, e.g., administering agents to modulate the function (e.g., signaling, expression or activity) of the network of factors (e.g., IL-2/IL-7/STAT5/GM-CSF/IL-3) that mediate TH-GM function in an effective amount to modulate the function (e.g., development and pathogenicity) of TH-GM cells. In particular, the disclosure provides methods and composition for differentiating and diagnosing an inflammatory disorder, e.g., multiple sclerosis (MS), rheumatoid arthritis (RA) as primarily mediated by either TH-GM cells (i.e. TH-GM pathway mediated) or by non-TH-GM mechanism (e.g., TNF-α, IL-6, and/or IL-1β pathways), or both. Also provided herein are compositions and methods for and the treatment of inflammatory disorders, particularly those that are TH-GM-mediated.


Accordingly, in one aspect, the present disclosure provides a method of diagnosing a TH-GM-mediated inflammatory disorder in a patient suffering from an inflammatory disorder. In some embodiments, the method comprises contacting a sample collected from a patient suffering from an inflammatory disorder with a detecting agent that detects a polypeptide or nucleic acid level of a TH-GM-mediating factor, such as, e.g., STAT5, IL-7, GM-CSF or IL-3, or a combination thereof; and quantifying the polypeptide or nucleic acid level of the TH-GM-mediating factor (e.g., STAT5, IL-7, GM-CSF or IL-3, or a combination thereof), wherein an increased level of a TH-GM-mediating factor (e.g., STAT5, IL-7, GM-CSF or IL-3, or a combination thereof) relative to a reference level indicates that the patient suffers from a TH-GM-mediated inflammatory disorder, thereby diagnosing a TH-GM-mediated inflammatory disorder in a patient suffering from an inflammatory disorder.


As used herein, a “TH-GM-mediated” inflammatory disorder refers to a subtype of an inflammatory disorder (e.g., a subtype of RA or MS) that results from the physiological action of any one or more of the network of factors in the pathway that modulate TH-GM function (a “TH-GM-mediating factor”), as described herein. Such factors include, e.g., GM-CSF, activated STAT5, IL-7, IL-2, and IL-3. In a particular embodiment, STAT5 is activated STAT5, wherein tyrosine at position 694 is phosphorylated.


In some embodiments, the level of a TH-GM-mediating factor (e.g., STAT5, IL-7, GM-CSF or IL-3, or a combination thereof) that is not increased relative to a reference level indicates that the patient suffers from a non-TH-GM-mediated inflammatory disorder.


In certain embodiments, the method further comprises administering to the patient a TNF-α therapy, as described herein, if the level of a TH-GM-mediating factor (e.g. STAT5, IL-7, GM-CSF or IL-3, or a combination thereof) is not increased relative to a reference level.


As used herein, a “non-TH-GM-mediated” inflammatory disorder refers to an inflammatory disorder (e.g., RA or MS) that is primarily caused by, e.g., TNF-α, IL-6, or IL-1β (and/or factors in the TNF-α, IL-6, or IL-1β pathway). As such, a “TH-GM-mediated” inflammatory disorder results primarily (or exclusively) from a pathway that is distinct from one or more of the pathways that leads to a “non-TH-GM-mediated” inflammatory disorder (e.g., the pathways associated with TNF-α, IL-6, or IL-1β).


However, as those of skill in the art would appreciate, a TH-GM-mediated inflammatory disorder does not necessarily exclude the possibility that the inflammatory disorder could also be partially non-TH-GM-mediated (e.g., mediated by TNF-α, IL-6, or IL- and/or factors in the TNF-α, IL-6, or IL-1β pathway). Thus, a classification or diagnosis as “TH-GM-mediated” is synonymous with “primarily/predominantly TH-GM-mediated”, and a classification as “non-TH-GM-mediated” is synonymous with “primarily/predominantly non-TH-GM-mediated.” For example, without wishing to be bound by any particular theory, an inflammatory disorder in its early stage may be TH-GM-mediated. As the inflammatory condition advances to a late stage characterized by, e.g., tissue damage, the inflammatory disorder becomes progressively non-TH-GM-mediated. In some embodiments, a TH-GM-mediated inflammatory disorder is a condition that is responsive to modulation of TH-GM function, as determined by clinical standards; a non-TH-GM-mediated inflammatory disorder is a condition that is responsive to, e.g., TNF-α, IL-6, or IL-1β therapy, as determined by clinical standards. In certain embodiments, an inflammatory disorder can be responsive to modulation of TH-GM function as well as TNF-α, IL-6, and/or IL-1β therapy.


In some embodiments, the sample can be e.g., peripheral blood, cerebrospinal fluid, synovial fluid, or synovial membrane, or a combination thereof.


In some embodiments, the inflammatory disorder is an autoimmune disorder. In certain embodiments, the inflammatory disorder can be any inflammatory disorder mediated by TH-GM cells, and includes, but is not limited to rheumatoid arthritis, multiple sclerosis, ankylosing spondylitis, Crohn's disease, diabetes. Hashimoto's thyroiditis, hyperthyroidism, hypothyroidism, Irritable Bowel Syndrome (IBS), lupus erythematosus, polymyalgia rheumatic, psoriasis, psoriatic arthritis, Raynaud's syndrome/phenomenon, reactive arthritis (Reiter syndrome), sarcoidosis, scleroderma, Sjögren's syndrome, ulcerative colitis, uveitis, or vasculitis.


As used herein, a “detecting agent” refers to, e.g., an antibody, a peptide, a small molecule, or a nucleic acid that binds to a polypeptide or nucleic acid to be detected (e.g., STAT5 (e.g., phospho-STAT5 (Tyr694)), IL-7, GM-CSF or IL-3), and enables the quantification of the polypeptide or nucleic acid to be detected. The detecting agent can be detectably labeled, or quantifiable by other means known in the art.


In some embodiments, the detecting agent is an antibody that binds to the polypeptide of STAT5, IL-7, GM-CSF or IL-3. In one embodiment, the antibody is one that binds to an activated STAT5 (e.g., phosphorylated STAT5), as described herein. Antibodies to STAT5 (e.g., phospho-STAT5 (Tyr694)), IL-7, GM-CSF or IL-3 suitable for use in the present method are known and commercially available in the art (e.g., STAT5 Ab: C-17 from Santa Cruz Biotech; Phospho-STAT5 (Tyr694) Ab: #9351 or #9359 from Cell Signaling; IL-7 Ab: clone BVD10-40F6 from BD Pharmingen; IL-7R Ab: clone SB/14 from BD Pharmingen; GM-CSF Ab: clone MP1-22E9 from BD Pharmingen; IL-3 Ab: clone MP2-8F8 from BD Pharmingen.


In other embodiments, the detecting agent is a nucleic acid that hinds to the nucleic acid of STAT5. IL-7, GM-CSF and/or IL-3. Nucleic acid molecules encoding a, e.g., STAT5. IL-7, GM-CSF and/or IL-3 sequence, or fragments or oligonucleotides thereof, that hybridize to a nucleic acid molecule encoding a e.g., STAT5, IL-7, GM-CSF and/or IL-3 polypeptide sequence at high stringency may be used as a probe to monitor expression of nucleic acid levels of STAT5, IL-7, GM-CSF and/or IL-3 in a sample for use in the diagnostic methods of the disclosure. Methods of quantifying nucleic acid levels are routine and available in the art.


In some embodiments, the method further comprises contacting the sample with a detecting agent that detects a polypeptide or nucleic acid level of one or more genes (as well as the gene product) listed in Table 1. As described herein, Table 1 lists genes that are differentially expressed in TH-GM cells as well as genes that are differentially expressed on the surface of TH-GM cells, as compared to TH1 or TH17 cells.


In a particular embodiment, the method further comprises contacting the sample with a detecting agent that detects the polypeptide or nucleic acid level of basic helix-loop-helix family member e40 (BHLHe40), chemokine (C-C Motif) Receptor 4 (CCR4), and/or CCR6.


Standard methods may be used to quantify polypeptide levels in any sample. Such methods include, e.g., ELISA, Western blotting, immunohistochemistry, fluorescence activated cells sorting (FACS) using antibodies directed to a polypeptide, and quantitative enzyme immunoassay techniques known in the art. Such methods are routine and available in the art. Similarly, methods for quantifying nucleic acid levels (e.g., mRNA) are known in the art.


In the diagnostic method of the present disclosure, an increased level of STAT5 (e.g., activated phospho-STAT5 (Tyr694)), IL-7, GM-CSF and/or IL-3 relative to a reference level indicates that the patient suffers from a TH-GM-mediated inflammatory disorder.


In some embodiments, a STAT5 (e.g., activated phospho-STAT5 (Tyr694)), IL-7, GM-CSF and/or IL-3 level that is increased by at least 10%, at least 20%, at least 30%, at least 40%, at least 50%, at least 60%, at least 70%, at least 80%, at least 90%, at least 100%, at least 110%, at least 120%, at least 130%, at least 140%, at least 150%, at least 160%, at least 170%, at least 180%, at least 190%, at least 200%, at least 220%, at least 240%, at least 260%, at least 280%, at least 300%, at least 350%, at least 400%, at least 450%, at least 500%, at least 550%, or at least 600% relative to a reference level indicates that the patient suffers from a TH-GM-mediated inflammatory disorder. In a particular embodiment, an increase of at least 40%, at least 50%, at least 60%, at least 70%, at least 80%, at least 90%, at least 100%, or at least 150% relative to a reference level indicates that the patient suffers from a TH-GM-mediated inflammatory disorder.


In some embodiments, a STAT5 (e.g., activated phospho-STAT5 (Tyr694)), IL-7, GM-CSF and/or IL-3 level that is not increased by at least 40%, at least 50%, at least 60%, at least 70%, at least 80%, at least 90%, at least 100%, or at least 150% relative to a reference level indicates that the patient suffers from a non-TH-GM-mediated inflammatory disorder.


In certain embodiments, a STAT5 (e.g., activated phospho-STAT5 (Tyr694)), IL-7, GM-CSF and/or IL-3 level that is comparable (or unchanged) relative to a reference level indicates that the patient suffers from a non-TH-GM-mediated disorder. As used herein, a level that is “comparable” to that of a reference level refers to a level that is unchanged, or a change relative to the reference level that is statistically insignificant according to clinical standards. In certain embodiments, a comparable level (or unchanged level) can include a level that is not increased by at least 40%, at least 50%, at least 60%, or at least 70% relative to a reference level as, for example, it may not indicate a clinically significant change. In some embodiments, a level of a TH-GM-mediating factor (e.g., STAT5 (e.g., activated phospho-STAT5 (Tyr694)). IL-7, GM-CSF, and/or IL-3) that is decreased relative to a reference level can also indicate that the patient suffers from a non-TH-GM-mediated disorder.


In some embodiments, the reference level is a level that is used for comparison purposes, and may be obtained from, for example, a prior sample taken from the same patient; a normal healthy subject; a sample from a subject not having an autoimmune disease or an inflammatory disorder; a subject that is diagnosed with a propensity to develop an autoimmune disease but does not yet show symptoms of the disease; a patient that has been treated for an autoimmune disease; or a sample of a purified reference polypeptide or nucleic acid molecule of the disclosure (e.g., STAT5) at a known normal concentration. By “reference standard or level” is meant a value or number derived from a reference sample, or a value or range accepted in the art as indicative of being healthy (e.g., an individual that does not have an inflammatory disorder). A normal reference standard or level can also be a value or number derived from a normal subject who does not have an autoimmune disease. In one embodiment, the reference sample, standard, or level is matched to the sample subject by at least one of the following criteria; age, weight, body mass index (BMI), disease stage, and overall health. A standard curve of levels of purified DNA. RNA or mRNA within the normal reference range can also be used as a reference. A standard curve of levels of purified protein within the normal reference range can also be used as a reference.


In some embodiments, the patient afflicted with an inflammatory disorder who has been diagnosed or classified as having a TH-GM-mediated inflammatory disorder does not have a non-TH-GM-mediated inflammatory disorder (i.e., does not have a TNF-α, IL-6, or IL-1β-mediated inflammatory disorder). That is, the patient diagnosed as suffering from a TH-GM-mediated inflammatory disorder responds to modulation of TH-GM function (e.g., inhibition of STAT5, IL-7, GM-CSF and/or IL-3), but does not respond (or exhibits a limited response) to TNF-α therapy, as determined by clinical standards. However, as described herein, a TH-GM-mediated inflammatory disorder does not exclude the possibility that the inflammatory disorder is also partially (though not primarily) contributed by a non-TH-GM-mediated pathway (e.g., TNF-α, IL-6, IL-1β).


In some embodiments, the methods of the present disclosure further comprise administering an effective amount of a modulating agent that modulates TH-GM cell function to the patient diagnosed or classified as having a TH-GM-mediated inflammatory disorder. As described herein, in some embodiments, the modulating agent inhibits TH-GM function.


In some embodiments, the methods of the present disclosure further comprise administering an effective amount of, e.g., a TNF-α therapy, an IL-6 therapy, or an IL-1β therapy to a patient diagnosed or classified as having a non-TH-GM-mediated inflammatory disorder, as described herein.


In some aspects, the present disclosure also provides a method of classifying a patient suffering from an inflammatory disorder as having a TH-GM-mediated inflammatory disorder or a non-TH-GM-mediated inflammatory disorder. In some embodiments, the method comprises contacting a sample collected from a patient suffering from an inflammatory disorder with a detecting agent that detects a polypeptide or nucleic acid level of a TH-GM-mediating factor, such as, e.g., STAT5 (e.g., phosphorylated STAT5, Tyr694), IL-7, GM-CSF or IL-3, or a combination thereof. In certain aspects, the method further comprises quantifying the polypeptide or nucleic acid level of the TH-GM-mediating factor, such as, e.g., STAT5. IL-7, GM-CSF or IL-3, or a combination thereof, wherein an increased level of the TH-GM-mediating factor, such as, e.g., STAT5, IL-7, GM-CSF or IL-3, or a combination thereof relative to a reference level indicates that the patient suffers from a TH-GM-mediated inflammatory disorder; or a comparable level of the TH-GM-mediating factor, such as, e.g., STAT5, IL-7, GM-CSF or IL-3, or a combination thereof relative to a reference level indicates that the patient suffers from a non-TH-GM-mediated inflammatory disorder, thereby classifying the patient suffering from an inflammatory disorder as a TH-GM-mediated inflammatory disorder or a non-TH-GM-mediated inflammatory disorder.


In other aspects of the present disclosure, the methods disclosed herein can further comprise measuring the polypeptide or nucleic acid level of a factor that mediates a non-TH-GM-mediated inflammatory disorder. Such factors include, e.g., TNF-α, IL-6, and IL-1β.


For example, in some aspects, the present disclosure provides a method of determining a treatment regimen in a patient suffering from an inflammatory disorder. To illustrate, the method comprises quantifying a polypeptide or nucleic acid level of, e.g., activated STAT5 or GM-CSF in a sample collected from a patient suffering from an inflammatory disorder, and quantifying the polypeptide or nucleic acid level of, e.g., TNF-α in a sample collected from the patient. At least four scenarios can be considered.


In the first scenario, if the activated STAT5 or GM-CSF level is increased (e.g., by at least 40%, at least 50%, at least 60%, at least 70%, at least 80%, at least 90%, at least 100%, or at least 150%) relative to a first reference level and the TNF-α level is comparable to a second reference level, then the patient is classified as having a TH-GM-mediated inflammatory disorder and the patient can be treated with an agent that modulates TH-GM function, as described herein.


In a second scenario, if the activated STAT5 or GM-CSF level is comparable to the first reference level and the TNF-α level is increased (e.g., by at least 40%, at least 50%, at least 60%, at least 70%, at least 80%, at least 90%, at least 100%, or at least 150%) relative to the second reference level, then the patient is classified as having a non-TH-GM-mediated inflammatory disorder and the patient can be treated with, e.g., a TNF-α therapy.


In a third scenario, if the activated STAT5 or GM-CSF level is increased relative to the first reference level and the TNF-α level is also increased relative to the second reference level, and the increase is equivalent within clinical and/or statistical standards (e.g., both GM-CSF and TNF-α are at least 50% increased relative to the respective reference levels), then the patient is classified as having an inflammatory disorder that is equally TH-GM-mediated and non-TH-GM mediated (e.g., TNF-α-mediated). In such a case, the patient can be treated with an effective amount of an agent that modulates TH-GM function and an effective amount of, e.g., a TNF-α therapy. As demonstrated herein, the combination of both agents can have a synergistic effect.


In a fourth scenario, if the activated STAT5 or GM-CSF level is increased relative to the first reference level and the TNF-α level is also increased relative to the second reference level, but one is increased more than the other, then the inflammatory disorder is primarily mediated by the pathway that shows a greater increase. For example, if GM-CSF is increased by 40% relative to a reference level, and TNF-α is increased by 90% relative to a reference level, then the inflammatory disorder is primarily non-TH-GM-mediated. However, in this scenario, the patient may receive a combined treatment with an agent that modulates TH-GM function as well a TNF-α therapy (e.g., anti-TNF-α therapy), since GM-CSF is increased by, e.g., at least 40% relative to a reference level.


In some embodiments, the first and second reference levels are obtained from the same reference sample.


In a related aspect, the disclosure also provides a method of tailoring the treatment of a patient suffering from an inflammatory disorder according to the progression of a patient's inflammatory disorder. In the above illustrative example, the first scenario (increased TH-GM-mediating factor, e.g. STAT5 or GM-CSF but TNF-α level is comparable to a reference level) may indicate that the patient is in an early stage of an inflammatory disorder. Without wishing to be bound by any particular theory, during, for example, the early stages of an inflammatory disorder, naïve T cells are stimulated by antigen and programmed by IL-7/STAT5 to differentiate into GM-CSF/IL-3 producing TH-GM cells. During, for example, the late stages of an inflammatory disorder, TH-GM cytokines (e.g., IL-3 and GM-CSF) progressively stimulate more inflammatory cells such as macrophages and neutrophils resulting in the production of, e.g., TNF-α, IL-6, IL-1β, resulting in full-scale inflammation. Thus, in the above illustrative example, the second scenario (activated STAT5 Or GM-CSF level is comparable to the first reference level and the TNF-α level is increased) may indicate that the patient is in a late stage of an inflammatory disorder characterized by, e.g., tissue damage. Accordingly, the present disclosure enables the prognosis of a patient depending on the quantifiable level of one or more TH-GM-mediating factor (e.g., STAT5 (e.g., activated phospho-STAT5 (Tyr694)), IL-7, GM-CSF, and/or IL-3) and one or more non-TH-GM-mediating factor (e.g., TNF-α, IL-6, IL-1β), thereby tailoring the treatment according to the progression of the disease. Accordingly, as would be appreciated by those of skill in the art, a patient suffering from an inflammatory disorder can be monitored for disease progression to ensure effective and tailored treatment according to the level of one or more TH-GM-mediating factor, as described herein, and one or more non-TH-GM-mediating factor (e.g., TNF-α, IL-6, IL-1β).


In related aspects, the present disclosure also provides a method of prognosing progression of an inflammatory disorder in a patient in need thereof. In some embodiments, the method comprises a) quantifying a polypeptide or nucleic acid level of a TH-GM-mediating factor, such as, e.g., STAT5, IL-7, GM-CSF or IL-3, or a combination thereof, in a first sample collected from a patient suffering from an inflammatory disorder, and b) quantifying a polypeptide or nucleic acid level of, e.g., TNF-α, IL-6, or IL-1β, or a combination thereof, in a second sample collected from the patient, wherein i) an increased level of the TH-GM-mediating factor, such as, e.g., STAT5, IL-7, GM-CSF or IL-3, or a combination thereof relative to a first reference level and an unchanged level of TNF-α, IL-6, or IL-1β, or a combination thereof relative to a second reference level indicates that the patient is in an early stage of the inflammatory disorder, as described herein; or ii) an unchanged level of the TH-GM-mediating factor, such as, e.g., STAT5, IL-7, GM-CSF or IL-3, or a combination thereof relative to the first reference level and an increased level of TNF-α, IL-6, or IL-43, or a combination thereof relative to the second reference level indicates that the patient is in a late stage of the inflammatory disorder, as described herein. In some embodiments, the method further comprises administering an effective amount of an agent that modulates TH-GM function and/or, e.g., a TNF-α therapy, as described herein.


In some embodiments, the first sample and the second sample are the same.


In various aspects, the present disclosure also provides an isolated population of GM-CSF-secreting T-helper cells (TH-GM). In one embodiment, the TH-GM cells are differentiated from a precursor cell (e.g., CD4+ cells) in the presence of signal transducer and activator of transcription 5 (STAT5) and/or IL-7, and wherein the TH-GM cells express GM-CSF and IL-3.


In some embodiments, the TH-GM cells are differentiated from a precursor cell (e.g., CD4+ cells) in the presence of an agent that inhibits IL-12, IFN-γ. TGF-β, and/or IL-6. Similarly, the differentiation of a precursor cell (e.g., CD4+ precursor cell) into a TH-GM cell is inhibited by IL-12, IFN-γ, TFG-β, and/or IL-6.


In some embodiments, the TH-GM cells are differentiated from a precursor cell in vitro, under artificial conditions, but wherein the TH-GM cells retain physiological properties as described herein.


In some embodiments, the TH-GM cells are further characterized by an overexpression of one or more genes listed in Table 1. For example, the TH-GM cells are further characterized by an overexpression of, for example, basic helix-loop-helix family, member e40 (BHLHe40), preproenkephalin (PENK), IL-2, serine (or cysteine) peptidase inhibitor, Glade B member 6 h (Serpinb6b), neuritin 1 (Nrn1), stearoyl-Coenzyme A desaturase 1 (Scd1), or phosphotriesterase related C1q-like 3 (Pter), or a combination thereof.


In some embodiments, the TH-GM cells are further characterized by an underexpression of one or more genes listed in Table 1. For example, the TH-GM cells are further characterized an underexpression of lymphocyte antigen 6 complex, locus A (Ly6a); CD27; or selectin, lymphocyte (Sell).


As described herein, the identification of a distinct network of factors (unique from factors known to mediate TH1 or TH17) that mediate TH-GM function (e.g., its differentiation and pathogenicity) enables targeted modulation of TH-GM function to treat TH-GM-mediated disorders, e.g., disorders that result from aberrant TH-GM function. Thus, in some aspects, the present disclosure provides a method of modulating TH-GM function, comprising contacting the TH-GM, or cluster of differentiation 4 (CD4+) precursor cells, or both, with a modulating agent that modulates TH-GM function. In one embodiment, the modulating agent is contacted with the TH-GM cells or CD4+ precursor cells in vitro or in VIVO.


As used herein, “TH-GM function” refers to the commitment, development, maintenance, survival, proliferation, or activity, or a combination thereof, of TH-GM cells. Thus, an agent that modulates (e.g., enhances or inhibits) TH-GM function is one that modulates TH-GM commitment, development, survival, proliferation, or activity, or combination thereof, of TH-GM cells. For example, TH-GM function can be modulated by modulating its: commitment from a CD4+ precursor T cell; development of a CD4+ precursor cell that has been committed to the TH-GM developmental pathway; maintenance of a TH-GM phenotype; survival or proliferation under development or effector TH-GM cells; and/or activity of effector TH-GM cells (e.g., modulating function of a secreted factor such as GM-CSF or IL-3). For example, a modulation in TH-GM function includes, but is not limited to, a modulation in: the number of TH-GM cells; the survival of TH-GM cells; the proliferation of TH-GM cells; and/or the activity of TH-GM cells. The activity of TH-GM cells herein includes the activity induced by the cytokines, chemokines, growth factors, enzymes and other factors secreted by TH-GM cells, as described herein, and the activity induced by direct contact with TH-GM cells.


As used herein, a T helper subset cell “TH-GM” refers to a cell that, similar to TH1 and TH17 cells, differentiates from precursor CD4+ precursor cells, but which commits and develops through a pathway that is mediated by a subset of factors (the TH-GM-mediating factors) that is distinct and unique from the known subset of factors that commit and develop TH1 or TH17 cell subtypes, as described herein. In some embodiments, a TH-GM cell produces a distinct and unique set of genes (see, e.g., Table 1) and effects pathogenicity through a different mechanism and pathway than the known factors that mediate pathogenicity of TH1 or TH17 cell subtypes. For example, a TH-GM cell commits and develops by IL-7/STAT5 function (its regulators), and effects pathogenicity by GM-CSF/IL-3 (its effectors).


In some aspects, the present disclosure provides a method of treating a TH-GM-mediated inflammatory disorder in a patient in need thereof, comprising administering to said patient an effective amount of a modulating agent that modulates TH-GM cell function. In certain embodiments, the patient is previously diagnosed as having a TH-GM-mediated inflammatory disorder, as described herein.


In some aspects, the present disclosure also provides a method of treating rheumatoid arthritis in a patient who exhibits limited response to TNF-α therapy, comprising administering to said patient an effective amount of a modulating agent that modulates TH-GM function.


As used herein, “limited response” refers to no response or insignificant response such that a patient is not treated by the therapy, as determined by clinical standards.


“Treatment” or “treating” refers to therapy, prevention and prophylaxis and particularly refers to the administration of medicine or the performance of medical procedures with respect to a patient, for either prophylaxis (prevention) or to reduce the extent of or likelihood of occurrence of the condition or event in the instance where the patient is afflicted. It also refers to reduction in the severity of one or more symptoms associated with the disease or condition. In the present application, it may refer to amelioration of one or more of the following: pain, swelling, redness or inflammation associated with an inflammatory condition or an autoimmune disease. As used herein, and as well-understood in the art, “treatment” is an approach for obtaining beneficial or desired results, including clinical results. For purposes of this disclosure, beneficial or desired clinical results include, but are not limited to, alleviation or amelioration of one or more symptoms, diminishment of extent of disease, stabilized (e.g., not worsening) state of disease, delay or slowing of disease progression, and/or amelioration or palliation of the disease state. “Treatment” can also mean prolonging survival as compared to expected survival if not receiving treatment.


An “effective amount” of an agent is that amount sufficient to effect beneficial or desired results, including clinical results. An “effective amount” depends upon the context in which it is being applied. In the context of administering a composition that modulates an autoimmune response, an effective amount of an agent which is a modulator of TH-GM function is an amount sufficient to achieve such a modulation as compared to the response obtained when there is no agent administered. An effective amount can confer immediate, short term or long term benefits of disease modification, such as suppression and/or inhibition of TH-GM function, as defined herein. An effective amount can be administered in one or more administrations. An “effective amount” as used herein, is intended to mean an amount sufficient to reduce by at least 10%, at least 25%, at least 50%, at least 75%, or an amount that is sufficient to cause an improvement in one or more clinically significant symptoms in the patient.


In some embodiments, the modulating agent inhibits TH-GM function to, e.g., reduce inflammation. The inhibition conferred by the modulating agent (the inhibitor) does not imply a specific mechanism of biological action. Indeed, the term “antagonist” or “inhibitor” as used herein includes all possible pharmacological, physiological, and biochemical interactions with factors that mediate TH-GM function (e.g., IL-7, IL-7 receptor, STAT5, GM-CSF, IL-3, IL-2, IL-2 receptor, PENK, RANKL, JAK1/3, or any of the genes that are differentially expressed in TH-GM cells, e.g., genes in Tables 1 and 2), whether direct or indirect, and includes interaction with a factor (or its active fragment) that mediates TH-GM function at the protein and/or nucleic acid level, or through another mechanism.


In certain embodiments, a modulating agent that inhibits TH-GM function includes an antibody, a polypeptide (e.g., a soluble receptor that hinds and inhibits, for example, IL-7), a small molecule, a nucleic acid (e.g., antisense, small interfering RNA molecule, short hairpin RNA, microRNA), or a protein (e.g., cytokine), or a combination thereof that prevents the function (e.g., expression and/or activity) of a factor that mediates TH-GM function. Methods of designing, producing, and using such inhibitors are known and available in the art.


As used herein, “binds” is used interchangeably with “specifically binds,” which means a polypeptide (e.g., a soluble receptor) or antibody which recognizes and hinds a polypeptide of the present disclosure, but that does not substantially recognize and bind other molecules in a sample, for example, a biological sample, which naturally includes a polypeptide of the present disclosure. In one example, an antibody specifically binds an activated STAT5 polypeptide does not hind a non-STAT5 polypeptide.


As used herein, “antibody” refers to an intact antibody or antigen-binding fragment of an antibody, including an intact antibody or antigen-binding fragment that has been modified or engineered, or that is a human antibody.


In a particular embodiment, the antibody binds to and inhibits the function of any one or more of the factors that mediate TH-GM function. For example, the antibody hinds to and inhibits the function of IL-7, IL-7 receptor (IL-7R), IL-2, IL-2 receptor (IL-2R), STAT5 or janus kinase 1/3 (JAK1/3), or a combination thereof. In other examples, the antibody hinds to and inhibits the function of GM-CSF (or its receptor), IL-3, PENK, or RANKL, or a combination thereof. In some embodiments, the antibody binds to and inhibits the function of a gene listed in Table 1. In some embodiments, the antibody hinds to and inhibits the protein or any functional fragment thereof. Methods of designing, producing and using suitable antibodies are known and available to those of skill in the art. Examples of antibodies suitable for use in the present disclosure include. e.g., daclizumab, basiliximab, mavrilimumab, MOR103, KB003, namilumab, and MOR Ab-022.


The terms “protein” and “polypeptide” are used interchangeably, and can include full-length polypeptide or functional fragments thereof (e.g., degradation products, alternatively spliced isoforms of the polypeptide, enzymatic cleavage products of the polypeptide), the polypeptide hound to a substrate or ligand, or free (unbound) forms of the polypeptide. The term “functional fragment”, refers to a portion of a full-length protein that retains some or all of the activity (e.g., biological activity, such as the ability to bind a cognate ligand or receptor) of the full-length polypeptide.


In some embodiments, the modulating agent that inhibits TH-GM function can be a particular biological protein (e.g., cytokines) that inhibits, directly or indirectly, one or more of the factors that mediate TH-GM function. Such cytokines include, e.g., IL-12, IFN-γ, TGF-β, and IL-6.


In some embodiments, the modulating agent that inhibits TH-GM function can be a small molecule that inhibits, directly or indirectly, one or more of the factors that mediate TH-GM function. As used herein a “small molecule” is an organic compound or such a compound complexed with an inorganic compound (e.g., metal) that has biological activity and is not a polymer. A small molecule generally has a molecular weight of less than about 3 kilodaltons. Examples of known small molecules include CAS 285986-31-4 (Calbiochem), pimozide, and tofacitinib.


In other embodiments, the modulating agent enhances TH-GM function in disorders such as, e.g., viral, fungal and bacterial infections, cancers and/or conditions associated with therewith. In one embodiment, modulating agents that enhance TH-GM function include. e.g., CD28 activator; IL-7 and/or IL-2 on naïve (precursor) CD4+ T cells; activator of STAT5; or effectors of TH-GM cells (e.g., GM-CSF. IL-3).


In another aspect, the present disclosure provides a method of treating a STAT5-mediated inflammatory disorder in a patient in need thereof, comprising administering to the patient an effective amount of an agent that modulates STAT5 function.


As used herein, “STAT5-mediated” inflammatory disorder refers to an inflammatory disorder that is caused by aberrant STAT5 function (aberrantly enhanced or inhibited), and which is responsive to modulation of STAT5 function, as determined by clinical standards. In some embodiments, the STAT5 is activated STAT5 (e.g., phospho-STAT5, Tyr694).


In some embodiments, the inflammatory disorder is an autoimmune disorder. In certain embodiments, the inflammatory disorder can be any inflammatory disorder mediated by STAT5 (e.g., activated STAT5), and includes, but is not limited to rheumatoid arthritis, multiple sclerosis, ankylosing spondylitis. Crohn's disease, diabetes. Hashimoto's thyroiditis, hyperthyroidism, hypothyroidism, Irritable Bowel Syndrome (IBS), lupus erythematosus, polymyalgia rheumatic, psoriasis, psoriatic arthritis. Raynaud's syndrome/phenomenon, reactive arthritis (Reiter syndrome), sarcoidosis, scleroderma. Sjögren's syndrome, ulcerative colitis, uveitis, or vasculitis.


In some embodiments, the term “patient” refers to a mammal, preferably human, but can also include an animal in need of veterinary treatment, e.g., companion animals (e.g., dogs, cats, and the like), farm animals (e.g., cows, sheep, pigs, horses, and the like), and laboratory animals (e.g., rats, mice, guinea pigs, and the like).


In some embodiments, the agent inhibits STAT5 function (e.g., expression and/or activity). Examples of agents that inhibit STAT5 (e.g., activated STAT5, Tyr694) are described herein.


In certain embodiments, the methods of the present disclosure further comprise administering to the patient a TNF-αc therapy. In certain embodiments, TNF-α therapy is administered in a patient determined to have an inflammatory condition that is non-TH-GM-mediated. As described herein, in certain embodiments, a TNF-α therapy is administered if a quantified TNF-α level is increased by, e.g., at least 40% relative to a reference level.


Examples of TNF-α therapy include those that are TNF-α-inhibitor based, and those that are non-TNF-α-inhibitor based. In particular, TNF-α-inhibitor based therapy includes etanercept, adalimuinab, infliximab, golimumab, and certolizumab pegol. Examples of non-TNF-α-inhibitor based therapy includes corticosteroid medications (e.g., prednisone), nonsteroidal anti-inflammatory drugs (e.g., methotrexate), and JAK inhibitors (e.g., tofacitinib). Other examples of non-TNF-α-inhibitor based therapy include anakinra, abatacept, rituximab and tocilizumab.


The TNF-α therapy can be administered before, simultaneously with, or alter the administration of an effective amount of an agent that modulates TH-GM function. Accordingly, an agent that modulates TH-GM function and the TNF-α therapy can be administered together in a single dose, or can be administered in separate doses, e.g., either simultaneously or sequentially, or both. The duration of time between the administration of an agent that modulates TH-GM function and a TNF-α therapy will depend on the nature of the therapeutic agent(s). In addition, an agent that modulates TH-GM function and a TNF-α therapy may or may not be administered on similar dosing schedules. For example, the agent that modulates TH-GM function and the TNF-α therapy may have different half-lives and/or act on different time-scales such that the agent that modulates TH-GM function is administered with greater frequency than the TNF-α therapy, or vice-versa. The number of days in between administration of therapeutic agents can be appropriately determined by persons of ordinary skill in the art according to the safety and pharmacodynamics of each drug.


The identification of the TH-GM cells as well as the identification of genes differentially produced by TH-GM cells relative to TH1 or TH17 enables the use of TH-GM cells to identify novel therapeutics for modulating TH-GM function, thereby enabling new therapeutics for treating TH-GM-mediated disorders (e.g., inflammatory disorders). Thus, in further aspects, the present disclosure provides a method of screening to identify a modulator of TH-GM cell function, comprising contacting an isolated population of TH-GM cells, or an isolated population of CD4+ precursor cells, with a candidate agent, and measuring a readout of TH-GM function in the presence or absence of the candidate agent, wherein a change in the readout of TH-GM function indicates that the candidate agent is a modulator of TH-GM function.


As used herein, a candidate agent refers to an agent that may modulate TH-GM function by modulating the function (e.g., expression and/or activity) of a factor that mediates TH-GM function. Such candidate agents include, e.g., an antibody, a peptide, a small molecule, a nucleic acid (e.g., antisense, small interfering RNA molecule), or a protein (e.g., cytokine), or a combination thereof. A candidate agent can be designed to target any of the factors (at the protein and/or nucleic acid level) that mediate TH-GM function, as described herein, including the genes listed in Table 1 (e.g., genes preferentially upregulated in TH-GM cells, genes preferentially overexpressed/underexpressed on the surface of TH-GM cells).


As used herein, “readout” refers to any change (or lack of change) in TH-GM function that can be measured or quantified. For example, a candidate agent can be assessed for its effect on, e.g., GM-CSF secretion by TH-GM cells, or its effect on the abundance of TH-GM cells (through an effect on the commitment/development/proliferation of TH-GM cells), as described herein. Assays for determining such readouts are known and available in the art, and are exemplified herein.


In some embodiments, the change in the presence of the candidate agent is a reduction in the measurement of the readout, indicating an inhibition of TH-GM function (e.g., decrease in GM-CSF or IL-3 production, or decrease in the abundance of TH-GM cells), thereby identifying the candidate agent as an inhibitor of TH-GM function.


In certain embodiments, the change in the presence of the candidate agent is an increase in the measurement of the readout, indicating an enhancement of TH-GM function (e.g., increase in GM-CSF or IL-3 production, or increase in the abundance of TH-GM cells), thereby identifying the candidate agent as an enhancer of TH-GM function.


In some embodiments, the readout can be any one or more of the genes listed in Tables 1 and 2 which are preferentially upregulated or downregulated in TH-GM cells. Thus, a candidate agent that downregulates a gene that is preferentially upregulated in a TH-GM cell is a inhibitor of TH-GM function. Similarly, a candidate agent that upregulates a gene that is preferentially downregulated in a TH-GM cell is an enhancer of TH-GM function.


In certain aspects, the method of screening, if performed with precursor CD4+ cells, is performed under TH-GM polarizing conditions, as described herein. For example, the method can be performed in the presence of IL-7/STAT5, TCR activation, CD28 co-stimulation, in combination with the blockade of IFN-gamma and IL-4.


Unless indicated otherwise, the definitions of terms described herein apply to all aspects and embodiments of the present disclosure


The practice of the present disclosure includes use of conventional techniques of molecular biology such as recombinant DNA, microbiology, cell biology, biochemistry, nucleic acid chemistry, and immunology as described for example in: Molecular Cloning: A Laboratory Manual, second edition (Sambrook et al., 1989) and Molecular Cloning: A Laboratory Manual, third edition (Sambrook and Russel, 2001), jointly and individually referred to herein as “Sambrook”); Oligonucleotide Synthesis (M. J. Gait, ed., 1984); Animal Cell Culture (R. I. Freshney, ed., 1987); Handbook of Experimental Immunology (D. M. Weir & C. C. Blackwell, eds.); Gene Transfer Vectors for Mammalian Cells (J. M. Miller & M. P. Calos, eds., 1987); Current Protocols in Molecular Biology (F. M. Ausubel et al., eds., 1987, including supplements through 2001); PCR: The Polymerase Chain Reaction, (Mullis et al., eds., 1994); Current Protocols in Immunology (J. E. Coligan et al., eds., 1991); The Immunoassay Handbook (D. Wild. ed., Stockton Press NY, 1994); Bioconjugate Techniques (Greg T. Hermanson, ed., Academic Press, 1996); Methods of Immunological Analysis (R. Masseyeff, W. H. Albert, and N. A. Staines, eds., Weinheim: VCH Verlags gesellschaft mbH, 1993), Harlow and Lane (1988) Antibodies, A Laboratory Manual, Cold Spring Harbor Publications, New York. and Harlow and Lane (1999) Using Antibodies: A Laboratory Manual Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y. jointly and individually referred to herein as “Harlow and Lane”), Beaucage et al. eds., Current Protocols in Nucleic Acid Chemistry (John Wiley & Sons, Inc., New York, 2000); and Aerawal, ed., Protocols for Oligonucleotides and Analogs, Synthesis and Properties (Humana Press Inc., New Jersey, 1993).


EXEMPLIFICATION

Methods


Mice


Stat5f/f mice were provided by L. Hennighausen (National Institute of Diabetes and Digestive and Kidney Diseases). Stat3f/f mice were generated as described2. Cd4-Cre transgenic mice were purchased from Taconic Farms. Rag2−/− mice were obtained from Jean-Pierre Abastado (Singapore Immunology Network). All mice are on a C57BL/6 genetic background and housed under specific-pathogen-free conditions at National University of Singapore. All experiments were performed with mice 6˜8 weeks old and approved by the Institutional Animal Care and Use Committee of NUS.


Patients and Controls


Blood samples (n=47) and synovial fluid samples (n=3) were collected from RA patients admitted to the Department of Rheumatology and Immunology, the Affiliated Drum Tower Hospital of Nanjing University Medical School. All patients fulfilled the American College of Rheumatology criteria for the classification of RA. Age and gender matched healthy controls (n=32) were obtained from Medical Examination Center of the Affiliated Drum Tower Hospital. The study protocol was approved by the Ethics Committee of the Affiliate Drum Tower Hospital of Nanjing University Medical School.


In Vitro T Cell Differentiation


CD4+ T cells were obtained from spleens and lymph nodes by positive selection and magnetic separation (Miltenyi Biotech), followed by purification of naïve CD4+ T cell population (CD4+CD25CD62LhiCD44lo) sorted with FACS Aria. Naïve CD4+ T cells were stimulated with plate-hound anti-CD3 (3 μg/ml; BD Pharmingen) and anti-CD28 (1 μg/ml; BD Pharmingen) in presence of different combinations of neutralizing antibodies and cytokines for 3˜4 days: for neutral conditions, no addition of any cytokine or neutralizing antibody; for TH 1 conditions, IL-12 (10 ng/ml), and anti-IL-4 (10 μg/ml, BD Pharmingen); for TH17 conditions, hTGF-β (3 ng/ml), IL-6 (20 ng/ml), anti-IFN-γ (10 μg/ml, eBioscience), and anti-IL-4 (10 μg/ml); for an alternative TH17 conditions, IL-6 (20 ng/ml), IL-23 (10 ng/ml), IL-1 (10 ng/ml), anti-IFN-γ (10 μg/ml), and anti-IL-4 (10 μg/ml). For GM-CSF-expressing cell differentiation, naïve CD4+ T cells were stimulated with plate-bound anti-CD3 (2 μg/ml) and soluble anti-D28 (1 μg/ml) with the addition of IL-7 and/or anti-IFN-γ (10 μg/ml) as indicated. All cytokines were obtained from R&D Systems. All cells were cultured in RPMI 1640 supplemented with 10% FBS, 100 units/ml penicillin, 0.1 mg/ml streptomycin, 1 mM sodium pyruvate, 0.1 mM nonessential amino acid and 5 μM beta-mercaptoethanol. After 3˜4 days polarization, cells were washed and restimulated with phorbol 12-myristate 13-acetate (PMA) and ionomycin in presence of Golgiplug for 4-5 h, followed by fixation and intracellular staining with a Cytofix/Cytoperm kit from BD Pharmingen. Foxp3 staining was done with a kit from eBioscience. Cells were acquired on the LSR II (BD Biosciences) and analyzed with FlowJo software (Tree Star).


EAE Induction


EAE induction procedures were modified from previous report3. For active EAE induction, mice were immunized in two sites on the hind flanks with 300 μg MOG35-55 in 100 μl CFA containing 5 mg/ml heat-killed M. tuberculosis strain H37Ra (Difco) at day 0 and day 7. Pertussis toxin (List Bio Lab) was administrated intraperitoneally at the dosage of 500 ng per mouse at day 1 and day 8. For single MOG35-55/CFA immunization, the similar procedure was performed at day 0 and day 1 only. In an alternative active EAE induction, LPS (600 μg/ml in IFA, O111:B4 from Sigma) was used as adjuvant. For active EAE induction in Rag2−/− mice, CD4+ T cells derived from Stat5f/f or Cd4-Cre; Stat5f/f mice were transferred, followed by MOG35-55/CFA immunization as described above. Clinical symptoms were scored as follows: 0, no clinical sign; 1, loss of tail tone; 2, wobbly gait; 3, hind limb paralysis; 4, hind and fore limb paralysis; 5, death. IL-7Rα neutralizing antibody (SB/14, BD Pharmingen) and isotype control was administrated intraperitoneally at 200 μg per mouse every other day. For analysis of CNS-infiltrating cells, both spinal cord and brain were collected and minced from perfused mice, and mononuclear cells were isolated by gradient centrifuge with Percoll (GE Healthcare).


For passive EAE induction with Stat5+/+ or Stat5−/− T cells, splenocytes and LNs were harvested 10-14 days post-immunization and passed through a 70 μm cell strainer (BD Falcon). Cells were cultured in vitro for 3 days with MOG35-55 (20 μg/ml) in the presence of IL-23 (5 ng/ml) and IL-1β (2 ng/ml). After harvesting, CD4+ T cells were purified by positive selection to a purity >90%. CD4+ T cells (2 million in sterile PBS) were injected intraperitoneally into Rag2−/− mice, followed by Pertussis toxin administration on the following day. Mice were observed daily for the signs of EAE as described above. For EAE induction by transferring various TH subsets, similar procedures was performed as described above. Different subsets skewing conditions were as follows: Non-skewed, MOG35-55 only; TH1: MOG35-55 plus IL-12 (10 ng/ml) and anti-IL-4 (5 μg/ml); TH17: MOG35-55 plus TGF-β (3 ng/ml), IL-6 (10 ng/ml), anti-IFN-γ (5 μg/ml) and anti-IL-4 (5 μg/ml); GM-CSF-expressing TH: MOG35-55 plus IL-7 (2 ng/ml) and anti-IFN-γ (5 μg/ml). 6×105 CD4+ T cells were transferred per recipient mouse.


Antigen-Induced Arthritis (AIA)


Briefly, mice were immunized subcutaneously in two sites on the hind flanks with 100 μg methylated bovine serum albumin (mBSA, Sigma) in 100 μl complete Freund's adjuvant (CFA) containing 5 mg/ml heat-killed M. tuberculosis strain H37Ra (Difco) at day 0. Pertussis toxin (List Bio Lab) was administrated intraperitoneally at the dosage of 250 ng per mouse at day 1. Arthritis was induced by intraarticular injection of 100 μg mBSA (in 10 saline) into the hind right knee joint at day 7 after immunization. The hind left knee joint was injected with same volume of saline as control. Joint swelling was recorded by measuring the difference between right and left knee joint diameters with a caliper over 7 days after arthritis induction. To assess the effect of GM-CSF administration, MA was induced by intraarticular injection of mBSA alone to the right knee joint or mBSA supplemented with 100 ng GM-CSF (ImmunoTools) to the left knee joint. To assess the effect of GM-CSF and/or TNF-α blockade, mice were administrated intraperitoneally with neutralizing antibodies (100 μg for each antibody per mouse) specific for GM-CSF (MP1-22E9, BD Pharmingen) and/or TNF-α (MP6-XT3. BD Pharmingen) at indicated times.


For AIA induction by adoptive transfer, splenocytes and inguinal LN cells were isolated from mBSA/CFA-immunized mice at day 7, and cultured in vitro with mBSA (10 μg/ml) in the presence of IL-7 (2 ng/ml) for 3 days. After harvesting, CD4+ T cells were purified by positive selection (Miltenyi Biotec) to a purity >90%. Then CD4+ T cells (1 million in sterile PBS) were transferred into WT naïve mice, followed by intraarticular injection of mBSA on the next day.


Collagen-Induced Arthritis (CIA)


CIA was induced in a similar procedure as AIA as described above, by immunizing mice with chicken collagen II/CFA emulsion (purchased from Chondrex, Inc), followed with pertussis toxin injection. Mice were monitored and scored for arthritis; 0, normal; 1, mild swelling of ankle or wrist, or apparent swelling limited to individual digits; 2, moderate swelling of entire paw; 3, severe swelling of entire paw with ankylosis. Scores for four limbs were summed for each mouse.


Histological Analysis


For paraffin-embedded tissues, spinal cords were fixed in 4% PFA. Knee joints or paws were removed, fixed in 10% formalin and decalcified in 5% formic acid before dehydration and embedding. Sections (5 μm) were stained with hematoxylin and eosin (H&E) to assess immune cell infiltration and inflammation, or with Safranin-O/Fast Green to assess cartilage depletion. For frozen tissues, spinal cords were embedded in OCT (Tissue-Tek) and snap frozen on dry ice. Sections (10 μm) were fixed in ice-cold acetone and stained with primary anti-CD4 (Biolegend) and anti-CD11b (eBioscience), followed by incubation with fluorescence-conjugated secondary antibodies (Invitrogen). For ALA experiments, knee joint were fixed in 10% formalin for 5 days, followed by decalcification in 5% formic acid for 5 clays. Sections (10 μm) were stained with hematoxylin and eosin (H&E) to assess immune cell infiltration and inflammation, or stained with Safranin-O/fast green to access cartilage destruction.


Cell Sorting and May Grünwald-Giemsa Staining


Monocytes/macrophages (Ly6ChiLy6G) and neutrophils (Ly6CloLy6Ghi) gated on CD45+CD11b+ were sorted with FACS Aria from spleens or synovial single cell suspensions. Sorted cells were cytospun onto glass slides and subsequently stained with May Grünwald and Giemsa dye following a standard procedure.


Real-Time PCR


Total RNA was extracted from cells with RNeasy kit (Qiagen) according to the manufacturer's instruction. Complementary DNA (cDNA) was synthesized with Superscript reverse transcriptase (Invitrogen). Gene expressions were measured by 7500 real-time PCR system (Applied Biosystems) with SYBR qPCR kit (KAPA). Actinb, Gapdh or Rn18S was used as internal control. The primer sequences are available upon request.


ELISA


TNF-α, IL-6, IL-1β, IFN-γ, GM-CSF and IL-2 levels were assayed by Ready-SET-Go ELISA kit (eBioscience), and IL-17 level was measured by DuoSet ELISA kit (R&D Systems) according to the manufactures' instructions.


Chromatin Immunoprecipitation Assays


CD4+ T cells isolated from Stat5f/f or Cd4-Cre; Stat5f/f mice were activated with plate-bound anti-CD3 and anti-CD28 for 3 days. Cells were stimulated with IL-7 (20 ng/ml) or IL-2 (25 ng/ml) for 45 min. Crosslink was performed by addition of formaldehyde at final concentration of 1% for 10 min followed by quenching with Glycine. Cell lysates were fragmented by sonication and precleared with protein G Dynabeals, and subsequently precipitated with anti-STAT5 antibody (Santa Cruz) or normal rabbit IgG (Santa Cruz) overnight at 4° C. After washing and elution, crosslink reversal was clone by incubating at 65° C. for 8 hr. The eluted DNA was purified and analyzed by RT-PCR with primers specific to C42 promoter as described previously5.


Statistics


Statistical significance was determined by Student's t test using GraphPad Prism 6.01. The p value <0.05 was considered significant. The p values of clinical scores were determined by two-way multiple-range analysis of variance (ANOVA) for multiple comparisons. Unless otherwise specified, data were presented as mean and the standard error of the mean (mean±SEM).


Example 1. Stat5 Conditional Knockout Mice are Resistant to EAE

STAT5 negatively regulates TH17 differentiation by restraining IL-17 production (Laurence et al., 2007; Yang et al., 2011). However, the function of STAT5 in TH17-mediated pathogenesis is not well understood. To explore this question, EAE was induced in Cd4-Cre; Stat5f/f (Stat5−/−) mice, where Stat5 was specifically deleted in T cell compartment, and in littermate controls by immunizing the mice with MOG35-55/CFA at day 0 and day 7. Development of paralysis was assessed by daily assignment of clinical scores. Surprisingly, diminished occurrence and severity of clinical disease in Stat5−/− mice was observed (FIGS. 1A and 1B), a result that was opposite to expectations based on an antagonistic role for STAT5 in TH17 generation. Similar results were observed when a single MOG35-55/CFA immunization was performed or replaced CFA with LPS as the adjuvant to induce EAE (FIGS. 1C and 1D). Consistent with reduced EAE disease in Stat5−/− mice, a remarkable reduction of immune cell infiltration in the spinal cord of Stat5−/− mice was observed (FIG. 2A). Furthermore, the infiltration of various immune cell populations, including CD4+, CD8+. B220+ and CD11b+ cells was reduced in Stat5−/− mice (FIGS. 2B-D and data not shown). However, the frequencies of IL-17+ and IFN-γ+ cells among CD4+ T cells in the CNS were comparable between Stat5+/+ and Stat5−/− mice (FIG. 3A), suggesting the resistance to EAE in Stat5−/− mice is independent of TH1 and TH17 cell development. Nevertheless, decreased CD4+CD25+ Treg population in the CNS of Stat5−/− mice was detected (FIG. 3B), indicating the resistance to EAE in Stat5−/− mice was unlikely due to altered Treg, cells.


Example 2. Resistance to EAE in Stat5-Mutant Mice is Due to an Intrinsic Defect of Antigen Specific CD4+ T Cells Independent of TH1 and TH17 Generation

Stat5 deletion (Cd4-cre; Stat5f/−) mice was reported to develop peripheral lymphopenia, with a reduction of both CD4+ and CD8+ T cells (Yao et al., 2006). However, another study showed that Stat5 deletion (Cd4-cre; Stat5f/f) did not affect the proportion of peripheral CD4+ T cells (Burchill et al., 2007). In the experimental setting, a change in the absolute number of peripheral CD4+ T cells was not detected by Stat5 deletion during EAE development (FIGS. 4A and 4B), suggesting the resistance to EAE in Stat5−/− mice was not caused by peripheral lymphopenia. Furthermore, increased frequencies of IL-17+ and IFN-γ+ cells were detected among CD4+ T cells in spleens of Stat5−/− mice (FIG. 4C), which further support the idea that the resistance to EAE in Stat5−/− mice is likely independent of TH1 and TH17 generation. To validate the function of STAT5 in TH1 and TH17 generation, the in vitro differentiation was performed by activating naïve CD4+ T cells under TH1- and TH17-polarizing conditions. In agreement with previous reports, that STAT5 mediated the suppressive effect of IL-2 on TH17 differentiation (data not shown). Interestingly, IL-7, which also signals through STAT5, was not observed to have a demonstrable effect on TH17 differentiation (data not shown). Nevertheless, a slight decrease of IFN-γ+ cells under TH1-polarizing condition was observed when STAT5 was deleted (data not shown).


To confirm if the resistance of EAE in Stat5+/+ mice is mediated by CD4+ T cells, Rag2−/− mice were reconstituted with Stat5+/+ or Stat5−/− CD4+ T cells followed by EAE induction. We found that Rag1−/− mice that received Stat5−/− CD4+ T cells were resistant to the disease compared with mice receiving wild-type cells (data not shown), demonstrating that Stat5−/− CD4+ T cells were impaired in their ability to promote EAE development.


Next, whether the lack of encephalitogenicity was caused by defects in migration of Stat5−/− CD4+ T cells to the CNS was examined. It has been shown that the chemokine receptor CCR6 is essential for TH17 cell entry into the CNS through the choroid plexus (Reboldi et al., 2009). Thus. CCR6 expression in both Stat5−/− and Stat5+/+ CD4+ T cells was examined. Increased CD4+CCR6+ cells in spleens of Stat5−/− mice compared with Stat5+/+ controls (FIG. 5A) was observed. CXCR3 and CD69 expression was also examined, which showed increased expression of both molecules in CD4+ T cells in the absence of STAT5 (FIG. 5A). These results indicate that Stat5−/− CD4+ T cells can infiltrate CNS. Furthermore, comparable number of CD4+ T cells present in the CNS of Stat5+/+ and Stat5−/− mice during EAE induction was observed (at day 7 and day 9) (FIG. 5B). However, CD4+ T cells in CNS of Stat5−/− mice dropped dramatically during disease onset (Day 21) (FIGS. 5C and 5D). Together, these results demonstrate that Stat5−/− CD4+ T cells can infiltrate CNS, but fail to induce effective inflammation in the CNS in EAE.


To further exclude the possibility that the resistance of Stat5-deficient mice to EAE was caused by any potential defect in the survival of autoreactive CD4+ T in the CNS, increased numbers of Stat5−/− CD4+ T cells than wild-type cells were transferred into Rag1−/− mice respectively to make sure comparable numbers of autoreactive CD4+ T cells were present in the CNS during EAE development. As shown in FIGS. 6A and 6B, despite similar numbers of CD4+ T cells in the CNS between two groups of mice, reduced disease severity was nevertheless observed in mice receiving Stat5-deficient CD4+ T cells. Additionally, certain numbers of Stat5-deficient mice containing similar numbers of CD4+ T cells in the CNS as wild-type mice at peak of EAE disease were observed, yet, they were relatively resistant to EAE compared with those wild-type mice (FIG. 6C), further suggesting that the resistance to EAE disease in Stat5-deficient mice was unlikely due to impaired CD4+ T cell survival in the CNS.


To further develop a causal link between these observations and the intrinsic impairment of Stat5−/− CD4+ T cells, MOG35-55-specific Stat5+/+ and Stat5−/− CD4+ T cells were transferred into Rag2−/− mice separately without further immunization to test if these cells were able to mediate EAE development. As shown in FIGS. 7A and 7B, mice receiving Stat5+/+ CD4+ T cells spontaneously developed EAE disease 1 week after transfer. In contrast, mice receiving Stat5−/− CD4+ T cells had significantly reduced disease severity and incidence. The frequencies of IL-17+ and IFN-γ+ cells among CD4+ T cells in the CNS of Rag2−/− mice were comparable between two groups (FIG. 7C), further suggesting that the intrinsic defect in encephalitogenicity of Stat5−/− CD4+ T cells is independent of TH1 and TH17. To exclude the possible role of CD8+ T cells in the resistance to EAE observed in Stat5 mice, Rag2−/− mice were reconstituted with MOG35-55-specific Stat5+4 or Stat5−/− CD4+ T cells together with equal numbers of Stat5+/+ CD8+ T cells. The transfer of Stat5−/− CD4+ together with Stat5+/+ CD8+ T cells still failed to induce EAE (data not shown). Together, these data demonstrate that Stat5+/+ CD4+ T cells have intrinsic defect in encephalitogenicity. The relevant teachings of all patents, published applications and references cited herein are incorporated by reference in their entirety.


Example 3. Diminished Expression of GM-CSF in Stat5−/− CD4+ T Cells

To test whether GM-CSF production was impaired by Stat5 deletion, its expression was examined in MOG35-53-specific Stat5+/+ and Stat5+/+ CD4+ T cells. Splenocytes derived from MOG35-55/CFA-immunized Stat5+/+ and Stat5−/− mice were challenged with various concentrations of MOG35-55 for 24 h, to examine the secretion of GM-CSF. GM-CSF production was observed to increase in a MOG35-55 dose-dependent manner in Stat5+/+ cells (FIG. 8A). In contrast, GM-CSF production was severely diminished in Stat5+/− cells in all conditions. To further validate this, splenocytes derived from mice were stimulated during the development of EAE with PMA/Ionomycin in the presence of GolgiPlug for GM-CSF and IL-17 intracellular staining. Although IL-17 expression was enhanced in Stat5−/− cells, a significantly reduced proportion of GM-CSF+IL-17″ and GM-CSF+IL-17+ cells was observed among CD4+CD44hi cells in the absence of STAT5 (FIG. 8B). Moreover, the frequency of MOG35,55-specific GM-CSF+ T cells was also significantly reduced in spleens of Stat5−/− mice (FIG. 8C). Together, these results indicate that STAT5 is required for GM-CSF expression in autoreactive CD4+ T cells. However, STAT5, an important transcription factor in TH17 differentiation, was required for GM-CSF expression (FIG. 8D).


Next. GM-CSF induction in the CNS during EAE development was examined. Although IL-17 and IFN-γ production by CNS-infiltrating CD4+ T cells was not impaired by Stat5 deficiency, a diminished frequency of CD4+GM-CSF+ cells in the CNS of Stat5−/− mice was detected compared with control mice (FIG. 9A). Further analysis showed a reduced GM-CSF+ percentage among CD4+IL-17; cells and among CD4+IFN-γ+ cells (FIG. 9A). Similarly, Rag2−/− mice transferred with MOG35-55-specific Stat5−/− CD4+ T cells also showed a reduced frequency of CD4+GM-CSF+ T cells in the CNS compared with control mice (FIG. 9B). GM-CSF mRNA expression in the CNS of Stat5−/− mice was markedly lower than that of Stat5+/+ mice at day 8 after EAE induction (FIG. 9C), when comparable CD4+ T cell infiltration was detected in Stat5−/− and Stat5+/+ mice (FIGS. 5C and 5D). Meanwhile, no significant difference of IL-17 and IFN-γ expression was detected between Stat5−/− and Stat5+/+ mice (FIG. 9C). The impaired cytokine induction (IL-17 and IFN-γ) in the CNS of Stat5−/− mice at later stage (day 14, FIG. 9C) could be explained by the inability of Stat5−/− CD4+ T to sustain neuroinflammation (FIGS. 5C and 5D). Interestingly, GM-CSF induction in the CNS preceded IL-23 induction (FIG. 9C), suggesting IL-23 might not be required for GM-CSF expression in the induction phase of EAE. In summary, the results suggest that GM-CSF expression in autoreactive CD4+ T cells is regulated by STAT5 and the impaired GM-CSF production in the absence of STAT5 caused the resistance of the mice to EAE.


Example 4. IL-7-STAT5 Signaling Induces GM-CSF Expression in Autoreactive CD4+ T Cells and Contributes to Neuroinflammation

Next, the mechanism by which STAT5 regulates GM-CSF expression was investigated. As the present disclosure indicates, neither IL-23 nor IL-1β seemed to be potent STAT5 stimulators (FIG. 10A). Furthermore, IL-1R1 expression was not changed, whereas IL-23Rα expression was increased in Stat5−/− CD4+ T cells (FIG. 10B). These data suggest that the ability of STAT5 to induce GM-CSF expression is likely independent of IL-23 and IL-1β signaling. In contrast, both IL-2 and IL-7 potently activated STAT5 by inducing tyrosine phosphorylation (FIG. 10A). Therefore, the effect of these two cytokines on GM-CSF induction in autoreactive T cells was further examined. Splenocytes derived from MOG35-55-immunized wild-type mice were challenged with MOG35-55 alone or plus IL-2. GM-CSF and IL-17 production by CD4+ T cells were analyzed by intracellular cytokine staining. As shown in FIG. 10C, IL-2 showed modest effects on the frequency of GM-CSF+ T cells. In contrast, IL-7 significantly promoted GM-CSF expression in both IL-1T and IL-17+ CD4+CD44hi T cells (FIG. 11A). Furthermore, IL-7 carried out this function in a STAT5-dependent manner, as Stat5 deletion abrogated its effect on GM-CSF expression as assessed by intracellular cytokine staining and ELISA (FIG. 11A, lower panels, and FIG. 11B).


IL-7Rα is expressed in both CD62LhiCD44loT cells and CD62loCD44hi T cells, suggesting IL-7 may directly act on CD4+ T cells to regulate GM-CSF expression. Thus, CD62LhiCD44lo and CD62LloCD44hi T cells were sorted from Stat5−/− mice and littermate controls during EAE development, and then activated cells in the presence or absence of IL-7. As shown in FIG. 11C, CD62LloCD44hi T cells potently expressed GM-CSF, while CD62LhiCD44lo) T cells expressed 30-fold lower GM-CSF amounts. STAT5 deletion resulted in reduced basal GM-CSF production in CD62LloCD44hi T cells. As expected, IL-7 promoted GM-CSF expression in both subsets of CD4+ T cells in a STAT5-dependent manner (FIG. 11C).


To examine the contribution of IL-7-induced GM-CSF expression in autoreactive CD4+ T cells to EAE development, mice were treated with IL-7Rα-specific antibody (clone SB/14) during EAE development. The treatment resulted in a significant reduction of disease severity, which was accompanied with reduced CNS inflammation (FIGS. 12A and 12B). In agreement with previous report (Lee et al., 2012), this neutralizing antibody did not have T cell depleting activity (FIG. 12C). Notably, the blocking of IL-7 signaling resulted in decreased GM-CSF expression in CNS-infiltrating CD4+ T cells (FIGS. 120-12F). In summary, the present findings indicate that IL-7 induces STAT5-dependent GM-CSF expression in autoreactive CD4+ T cells, which contributes to the development of neuroinflammation.


Example 5. GM-CSF-Expressing TH Cells are Distinct from TH17 and TH1

Since both TH17 and TH1 can produce GM-CSF, it was determined if the IL-7-stimulated phenotype was related to either of these subsets. To further understand the characteristics of GM-CSF-expressing CD4+ cells, naïve CD4+ T cells were stimulated with plate-bound anti-CD3 and soluble anti-CD28 under TH1- or TH17-polarizing conditions. It was observed that anti-CD3 together with anti-CD28 induced the expression of GM-CSF (FIG. 14A). However, while TH1 differentiation conditions promoted IFN-γ expression and TH17 conditions promoted IL-17 expression as expected, both TH1 and TH17 differentiation conditions greatly suppressed the production of GM-CSF (FIGS. 13A and 13B). Conversely, IL-12 and IFN-γ neutralization promoted GM-CSF-expressing cell generation (FIG. 13A), consistent with a previous report (Codarri et al., 2011). IL-23 and IL-1β did not increase GM-CSF-expressing cell differentiation from naïve CD4+ T cells (FIG. 13A), which was consistent with the finding that naïve CD4+ T cells did not express their receptors. TGF-β inhibits GM-CSF expression (El-Behi et al., 2011). IL-6, an essential cytokine for TH17 differentiation, had a profound inhibitory effect on GM-CSF expression (FIG. 14B), indicating STAT3 could be a negative regulator. To address this, naïve CD4+ T cells were purified from Stat3−/− mice for cell differentiation. Strikingly, in the absence of STAT3, cells polarized under TH17 condition expressed GM-CSF (FIG. 14C). Interestingly, even without exogenous IL-6, STAT3 still had a moderate suppressive effect on GM-CSF-expressing cell differentiation (FIG. 14C). In addition, RORγt and T-bet have been reported unnecessary for GM-CSF expression in CD4+ T cells (El-Behi et al., 2011). Thus, the present datasupport a model wherein GM-CSF-expressing CD4+ T cells develop via a lineage distinct from TH17 and TH1.


Example 6. IL-7-STAT5 Programs GM-CSF-Expressing TH Cell Differentiation

The present findings disclosed herein (including .g., diminished GM-CSF expression in Stat5−/− CD4+ T cells in vivo, IL-7/STAT5-mediated induction of GM-CSF expression in naïve CD4+ T cells, and the distinct features of GM-CSF-expressing TH cells versus TH1 and TH17 cells) indicates a distinct TH cell subset that is regulated by IL-7-STAT5 signaling. This finding was further explored by examining GM-CSF-expressing TH cell differentiation in vitro by activating naïve CD4+ T cells with anti-CD3 and anti-CD28 in the presence of different concentrations of IL-7. As shown in FIGS. 15A and 15B, IL-7 strongly promoted the generation of GM-CSF-expressing cells and GM-CSF secretion. Moreover, the generation of GM-CSF-expressing TH by IL-7 was mediated by STAT5. Without STAT5, IL-7 was unable to promote the generation of GM-CSF-expressing cells (FIGS. 15C and 15D). Further investigation showed that IL-7-induced STAT5 activation directly hound promoter regions of the Csf2 gene (FIGS. 15E and 15F).


Small proportions of IFN-γ-expressing cells were generated during GM-CSF-expressing TH differentiation (FIG. 1.5A). Thus, the effect of blocking IFN-γ on GM-CSF-expressing cell generation was tested, which showed that the combination of IL-7 and IFN-γ neutralization induced the highest frequency of GM-CSF+ cells, where few IL-17+ or IFN-γ+ cells were detected (FIG. 16A). Moreover, the expression of subset defining transcriptional factors in GM-CSF-expressing TH was examined and observed that the expression of RORγt or T-bet in GM-CSF-expressing TH was significantly lower than those in TH17 or TH1 cells, respectively (FIG. 16B), confirming that the GM-CSF-expressing TH cells are distinct from TH1 and TH17 cells. Together, these data suggest that IL-7-STAT5 signaling direct the differentiation of a novel GM-CSF-expressing helper T cell subset, termed TH-GM.


Next, it was determined whether IL-2 signaling could influence TH-GM differentiation from naïve CD4+ T cells. The addition of IL-2 or antibody against IL-2 only had modest effect on the frequency of GM-CSF+ cells (FIG. 14D), indicating a minimal effect of IL-2 on TH-GM differentiation. Unlike IL-7Rα, IL-2 high-affinity receptor IL-2Ra was not expressed in naïve CD4+ T cells, but its expression was gradually induced by TCR activation (FIGS. 17A-17C). Thus, the minimal effect of IL-2 at least in part is due to the unresponsiveness of naïve CD4+ T cells to IL-2 stimulation. In support of this view, IL-7, but not IL-2, induced STAT5 activation and upregulated GM-CSF mRNA expression in naïve CD4+ T cells (FIGS. 17D and 17E). To further confirm this idea, activated CD4+ T cells were stimulated with IL-2 or IL-7, which showed that both cytokines induced STAT5 activation, Csf2 promoter binding and GM-CSF mRNA upregulation (FIGS. 18A-18C). Notably, IL-2 induced a prolonged STAT5 activation compared with IL-7 (FIG. 18A).


Example 7. Distinct Gene Expression Profile of TH-GM

To demonstrate TH-GM as distinct from known T cell subsets (e.g., TH1 and TH17), a whole transcriptome analysis was performed by microarray to validate its specificity compared with known T cell subsets, in particular TH17 cells. Naïve CD4+ T cells were differentiated into TH1, TH17 and TH-GM. Microarray analysis was performed to examine their gene expression profiles. Whole transcriptome clustering indicates TH-GM cells as representing a novel subset distinct from TH1 or TH17 cells. T cell lineage-specific gene expression is shown in Table 1. A list of 202 genes preferentially expressed in TH1 cells were identified, compared with naïve, TH17 or TH-GM cells (fold change >1.7), among which IFN-γ and T-bet are on the top of the list (Table 1). Similarly, TH17-feature genes, such as IL-17, IL-17F, RORγt and RORα, were identified in the list including 411 genes specific to TH17 cells (Table 1). The TH-GM cell-specific gene list (“Genes preferentially upregulated in TH-GM” the TH-GM signature genes) contains 210 genes including the gene encoding GM-CSF as the top gene in the list (Table 1). A set of surface molecules which were selectively expressed at high level in TH-GM subset, and another set of surface molecules which were selectively expressed at low level in TH-GM subset compared with other subsets were identified (FIG. 19 and Table 1). These molecules (also TH-GM signature genes) can be used for further characterization by surface markers to identify the TH-GM subset of T cells. Several other genes of interest were also identified, including genes encoding cytokines and transcriptional factors, in particular IL-3. Various helper T cells were differentiated in vitro and confirmed that TH-GM cells are potent IL-3 producers as compared with TH1 and TH17 cells (FIGS. 20A, 20C and 20D). In addition, several other cytokines, including EBI-3, PENL and RANKL were found preferentially expressed in TH-GM cells (FIG. 20B), indicating diverse biological functions of TH-GM cells.


Example 8. TH-GM Cells are the Primary Pathogenic Population

To test the hypothesis that GM-CSF-expressing TH subset (TH-GM) was the primary encephalitogenic effector cells, adoptive transfer of different subsets of MOG35-55-specific CD4+ T cells was performed into Rag2−/− mice for EAE induction. As shown in FIG. 21, GM-CSF-expressing TH cells were preferentially able to induce EAE compared with TH17 and TH1 subsets.


Example 9. The Suppression of STAT5 Activity by Chemical Inhibitor Attenuates GM-CSF Expression by TH-GM and Ameliorates EAE

The effect of disrupting STAT5 activation by chemical inhibitor was examined to explore possible methods of treating autoimmune neuroinflammation. The phosphorylation on the key tyrosine residue in SH2 domain is crucial for STAT5 activation and function. A commercial STAT5 inhibitor (CAS 285986-31-4, Calbiochem) has been reported to selectively disrupt tyrosine phosphorylation and DNA binding of STAT5 (Muller et al., 2008). First, the inhibitory effect of this inhibitor on STAT5 activation upon IL-7 stimulation in CD4+ T cells was tested. At a concentration of 50 μM, the inhibitor had about 50% inhibitory effect, which was further enhanced with the increase of concentration (FIG. 22A). STAT5 inhibitor had low affinity and thus required a high concentration to fully block STAT5 activation, whereas JAK3 inhibitor showed potent inhibitory effect even at low concentration (FIG. 22B). The specificity of STAT5 inhibitor was next tested by examining its effect on the activation of STAT3 and STAT1. As shown in FIGS. 22C and 22D, this STAT5 inhibitor at relatively lower concentration (50 or 100 μM) showed minimal inhibitory effect on both STAT3 and STAT1 activation.


The effect of STAT5 inhibition on TH-GM differentiation was examined. As shown, STAT5 inhibitor suppressed TH-GM differentiation in a dosage-dependent manner (FIG. 22E). Reduced TH1 differentiation upon STAT5 inhibitor treatment was observed (data not shown), but TH17 differentiation was not suppressed by STAT5 inhibitor (data not shown).


To explore the therapeutic effect of targeting STAT5 activation in EAE disease, the commercial STAT5 inhibitor was administered to wild-type mice intraperitoneally every other clay after disease onset. Development of paralysis was assessed by daily assignment of clinical scores. STAT5 inhibition ameliorated EAE severity, associated with reduced immune cell infiltration in the CNS (FIGS. 23A and 23B). In contrast, although JAK3 inhibitor can potently block STAT5 activation (FIG. 22B), it showed detrimental effect on EAE (FIG. 23B). Of note, STAT5 inhibitor resulted in reduced GM-CSF production in CNS-infiltrating CD4+ T cells (FIGS. 23C and 23D). This study indicates that targeting STAT5 by chemical inhibitor is useful in therapeutic intervention in MS.


Example 10. GM-CSF-Producing TH Cells are Associated with Human RA

Plasma concentrations of GM-CSF and TNF-α in peripheral blood of RA patients were examined in comparison with gender/age-matched healthy control (HC), and found that both cytokines were elevated in RA (FIG. 24A). Ex vivo frequencies of IFN-γ-, IL-17- or GM-CSF-producing TH cells were quantified in RA and HC. High frequencies of IFN-γ- and/or GM-CSF-producing TH cells were detected in all samples, but observed low frequency (<1%) of IL-17-producing TH cells (FIG. 24B). GM-CSF-single-producing (GM-CSF+IFN-γ) TH cells represented a substantial population in both RA and HC (FIG. 24B). More importantly, the frequency of this population in peripheral blood of RA was significantly higher than that of HC (FIG. 24C). In contrast, neither GM-CSF/IFN-γ-double-producing nor IFN-γ-single-producing TH cells showed any significant difference in their frequencies between RA and HC (FIG. 24C). Therefore, the frequency of GM-CSF-single-producing TH cells in peripheral blood is selectively elevated in RA, suggesting a functional association of TH-cell-secreted GM-CSF with RA. Moreover, a significant correlation between plasma GM-CSF concentration and GM-CSF-single-producing TH cell frequency was observed in RA (FIG. 24D).


To further evaluate the association of GM-CSF-producing TH cells with RA, mononuclear cells were isolated from synovial fluid of RA patients and analyzed the abundance of these cells. A marked elevation of GM-CSF-producing TH cell frequency was observed in synovial fluid compared with peripheral blood, but most of these cells co-expressed IFN-γ (FIG. 24E). Similarly, both TH1 and TH17 frequencies were also increased in synovial fluid, with TH17 remaining to be a minor population compared with TH1 (FIG. 24E).


Example 11. GM-CSF Mediates Experimental Arthritis in a TNF-α-Independent Manner

The elevation of GM-CSF and TNF-α level in plasma of RA in comparison to HC may suggest a therapeutic approach by targeting these two cytokines. The efficacy of blocking both GM-CSF and TNF-α was tested in treating arthritic mice in antigen-induced arthritis (AIA) model, which is a T-cell driven RA model and is easily inducible in C57BL/6 strain with a rapid and synchronized disease onset, facilitating the exploration of RA pathogenesis. Either GM-CSF or TNF-α individual blockade attenuated MA development (FIG. 25A). Interestingly, the combination of GM-CSF- and TNF-α-specific neutralizing antibodies showed better efficacy in controlling arthritis development than individual treatments (FIG. 25A). That is, targeting GM-CSF may have beneficial efficacy in treating arthritis in a way independent of TNF-α activity. To further study the distinguishable effects of GM-CSF and TNF-α in mediating arthritis development, a mouse strain (Cd4-Cre; Stat5f/f, or Stat5−/− in short) with conditional Stat5 deletion was used in T cells for AIA induction. These conditional Stat5-knockout mice resisted arthritis development, as exemplified by milder joint selling, fewer immune cell infiltration in synovia, and reduced joint destruction (FIGS. 25B-25D), even though they had markedly increased level of serum TNF-α as well as IFN-γ (FIG. 25E). In contrast, serum level of GM-CSF was significantly reduced in knockout mice (FIG. 25E), which was likely the causal factor of the resistance to arthritis development as further supported by results described below. Consistent results were also observed in collagen-induced arthritis (CIA) model (FIGS. 26A-26D). Together, these findings suggest that GM-CSF is an important pathogenic mediator in RA and also indicate the promise of developing anti-GM-CSF drugs to treat RA patients who are anti-TNFα drugs unresponsive, marking GM-CSF-producing TH cells as a new biomarker for RA diagnosis.


Example 12. STAT5-Regulated GM-CSF Secretion by Autoreactive TH Cells Mediates Synovial Inflammation

On the basis of association of GM-CSF with RA, the cellular producers of GM-CSF and the regulatory mechanism underlying GM-CSF expression in arthritic mice were examined. Splenocytes were collected from wild-type AIA mice and separated cells into three fractions: splenocytes, splenocytes depleted of CD4+ T cells and CD4+ T cells; and stimulated each fraction at same cell numbers under various conditions. Splenocytes produced low but detectable level of GM-CSF without stimulation, which was markedly increased by PMA/Ionomycin or mBSA antigen stimulation (FIG. 28A). Under all conditions, splenocytes depleted of CD4+ T cells almost completely abrogated GM-CSF production (FIG. 28A). In contrast, CD4+ T cells produced dramatically elevated GM-CSF in comparison to splenocytes under all conditions (FIG. 28A). These results strongly support that CD4+ T cells are predominant producers of GM-CSF at least in spleens of arthritic mice, which is somehow consistent the observed correlation of plasma GM-CSF concentration with GM-CSF-single-producing TH cell frequency in RA (FIG. 24D). Thus, the functional significance of TH-cell-secreted GM-CSF was examined in arthritis development. Given T-cell-specific Csf2-knockout mice is not available and STAT5 is a key regulator of GM-CSF expression in TH cells, conditional Stat5-knockout mice was used, which showed decreased GM-CSF level and resistance to arthritis development as described above.


Consistent with a previous study (Burchill et al., 2007), similar frequencies of CD4+ T cells were observed in peripheral lymphoid tissues as well as in inflamed synovial tissues of STAT5-deficient mice compared with wild-type mice at day 7 after AIA induction (FIGS. 27A-27D), suggesting loss of STAT5 seems to not impair CD4+ T-cell generation in periphery and infiltration in synovial tissues. To determine the requirement of STAT5 for arthritogenic potential of CD4+ T cells, ex vivo-expanded antigen-reactive CD4+ T cells, derived from Stat5+/+ and Stat5−/− ALA mice, were transferred into wild-type naïve mice separately, followed by intra-articular injection of mBSA. Mice receiving Stat5+/+ CD4+ T cells displayed an abundant immune cell infiltration in synovial tissues at day 7 after AIA induction (FIG. 27E). In contrast, mice receiving Stat5−/− CD4+ T cells had marked reduction of synovial infiltrates (FIG. 27E). Therefore, STAT5-deficient CD4+ T cells are defective in arthritogenic potential.


Multiple lines of evidence support a central role of T cells in RA. However, the pathogenic mechanism of T cells remains insufficiently understood. Although TH1 is a predominant population among synovial infiltrating CD4+ T cells in human RA (Berner et al., 2000; Yamada et al., 2008), defective IFN-γ signaling results in increased disease susceptibility in animal models of arthritis (Guedez et al., 2001; Irmler et al., 2007; Manoury-Schwartz et al., 1997; Vermeire et al., 1997). In contrast, TH17 cells are proven crucial in animal models of arthritis (Pernis, 2009), but predominance of TH17 cells is limited in both peripheral blood and synovial compartment of human RA (Yamada et al., 2008) and (FIGS. 1B and 1E). As demonstrated herein, STAT5-regulated GM-CSF-producing TH cells potentiate arthritis pathogenesis.


To validate the regulatory role of STAT5 in GM-CSF production, splenocytes derived from AIA mice were stimulated with PMA/Ionomycin plus Golgiplug ex viva, followed by intracellular cytokine staining and flow cytometry. As expected, the frequency of GM-CSF-single-producing cells among CD4+CD44hi population was significantly decreased in Stat5−/− mice (FIG. 2834B). Notably, no significant differences were observed in frequencies of IL-17-single-producing (TH17) or IFN-γ-single-producing (TH1) cells between two groups (FIG. 28B). Further study by combining mBSA restimulation and intracellular cytokine staining showed that the frequency of mBSA-specific GM-CSF-producing effector T cells was much lower in spleens of Stat5−/− mice than those in controls (FIG. 29A). In addition, AIA mice-derived splenocytes and inguinal lymph nodes (LNs) were restimulated with mBSA ex viva to measure cytokine concentrations in culture supernatants and found a significant reduction of GM-CSF with deletion of STAT5, but comparable levels of both IL-17 and IFN-γ between two groups (FIGS. 29B and 29C). Together, the results indicate that loss of STAT5 may specifically suppress GM-CSF-producing effector Th cells but not TH17 or TH1 cells in experimental arthritis.


To investigate the involvement of GM-CSF-producing TH cells and their regulation by STAT5 in synovial inflammation, synovial tissues were dissected from AIA mice and examined cytokine production by TH cells. In spite of multiple cellular sources of GM-CSF (Cornish et al., 2009). CD4+ TH cells were prominent producers of GM-CSF in synovial tissues of AIA mice (FIG. 28C), consistent with the observation in spleens (FIG. 28A). Moreover, a significantly lower percentage of synovial GM-CSF-producing TH cells was detected in Stat5−/− mice than Stat5+/+ mice (FIG. 28D). On the other hand, both TH1 and TH17 cells exhibited similar percentages between two groups (FIG. 28C). A decrease in GM-CSF level in synovial compartments of Stat5−/− mice in comparison to controls was expected. To address this, inflamed synovial tissues were harvested from AIA mice for RNA and protein extraction to examine cytokine level by qPCR and ELISA. Indeed, lower synovial GM-CSF but not IFN-γ or IL-17 was detected in Stat5−/− mice than Stat5+/+ mice at day 5 or 7 after arthritis induction (FIGS. 28E and 30A-30C). In addition, two important proinflammatory cytokines IL-6 and IL-1β were also found persistently and significantly reduced in STAT5-deficient mice (FIGS. 28E and 30A-30C), indicating the attenuated synovial inflammation. Notably. TNF-α production was reduced at day 7 but not at day 5 in STAT5-deficient mice (FIGS. 28E and 30A-C). Together, these results indicate that STAT5-regulated GM-CSF expression by arthritogenic TH cells is crucial for evoking synovial inflammation.


To determine the critical role of STAT5-regulated GM-CSF production by TH cells in mediating synovitis and arthritis development, GM-CSF was administered via intra-articular injection in mixture with mBSA to the left knee joints of mBSA/CFA-immunized mice, whereas mBSA was injected alone to the right knee joints. Injection with mBSA alone was sufficient to induce abundant immune cell infiltration in the synovial compartments of Stat5+/+ mice but failed to do so in Stat5−/− mice (FIG. 28F). Administration of GM-CSF together with mBSA efficiently restored synovial inflammation in Stat5−/− mice (FIG. 34F). Consistently, the Safranin-O/Fast Green staining revealed severe cartilage depletion upon GM-CSF/mBSA injection, but not mBSA alone, in Stat5−/− mice (FIG. 28G). These results therefore provide support for the notion that STAT5-regulated GM-CSF production by arthritogenic TH cells is essential for mediating arthritis pathogenesis.


Example 13. Th-Cell-Derived GM-CSF Mediates Neutrophil Accumulation in Synovial Tissues

The mechanism by which GM-CSF-producing Th cells evoke synovial inflammation and drive arthritis development was examined. Myeloid lineage-derived cells, including neutrophils, DCs and macrophages, express GM-CSF receptor and are common targets of GM-CSF (Hamilton, 2008). Importantly, those cells invade synovial compartments in RA patients and mouse arthritis models, and contribute to synovitis (McInnes and Schett, 2011). The infiltration of myeloid lineage-derived cells in synovial compartments of ALA mice was examined. CD11b+ myeloid cells represented a predominant population (˜70%) among synovial infiltrating leukocytes (FIG. 31B). Although CD4+ TH cell infiltration was not altered by STAT5 deletion, synovial CD11b+ cell infiltration was significantly reduced in Stat5−/− mice compared with Stat5+/+ mice when examined at day 7 after arthritis induction (FIG. 31B). This reduction is unlikely due to defective hematopoiesis, as similar frequencies of CD11b+ cells were detected in spleens of two group (FIG. 31A). Further, CD11b+ cells continuously increased in synovial tissues of wild-type mice, but not STAT5-deficient mice, over a 7-day time course (FIG. 31C). Notably, the selective ablation of synovial CD11b+ cell accumulation in STAT5-deficient mice can be partially restored by local administration of GM-CSF during arthritis induction (FIG. 31D). Together, these results indicate that myeloid cell accumulation in synovial compartments may be specifically dampened by T-cell-specific STAT5 deletion and resultant GM-CSF insufficiency.


Next, different populations of CD11b+ cells, including DCs, macrophages and neutrophils were analyzed. Monocyte-derived dendritic cells (MoDCs), characterized as CD11cintCD11bhiLy6C+/hiMHCIIhi, were recently reported to be involved in the mBSA/IL-1β arthritis model (Campbell et al., 2011). In the AIA model of the present study, MoDCs were identified at low abundance in spleens and synovial tissues (data not shown). Furthermore, comparable frequencies of MoDCs were detected in both peripheral lymphoid tissues and synovial tissues between Stat5+/+ and Stat5−/− mice (data not shown). These results are in agreement with a previous study showing a dispensable role of GM-CSF in MoDC differentiation (Greter et al., 2012).


Neutrophils have great cytotoxic potential and contribute to the RA initiation and progression in multiple ways (Wright et al., 2014). It has been suggested that RA disease activity and joint destruction directly correlates with neutrophil influx to joints (Wright et al., 2014). Based on the differential expression of Ly6C and Ly6G, CD11b+ myeloid cells can be classified into Ly6CloLy6Ghi population (neutrophils) and Ly6ChiLy6G population (monocytes/macrophages). The present study shows that Ly6CloLy6Ghi population continued to accumulate in synovial tissues over a 7-clay time course, and represented a predominant population among synovial CD11b+ cells in wild-type mice at day 7 after AIA induction, whereas this population was persistently and dramatically diminished in STAT5-deficient mice (FIG. 32A). Using Giemsa stain, it was validated that synovial-infiltrating Ly6CloLy6Ghi population were neutrophils, which displayed typical polymorphonuclear characteristics with ring-shaped nuclei (FIG. 32B). In contrast, synovial-infiltrating Ly6ChiLy6G population had mononuclear morphology and were likely monocytes/macrophages (FIG. 32B). Importantly, intraarticular administration of GM-CSF during arthritis induction efficiently restored neutrophil accumulation in synovial compartments of STAT5-deficient mice (FIG. 32C), suggesting a critical role of TH-cell-derived GM-CSF in mediating neutrophil accumulation to inflamed joints.


Neutrophils are recruited during inflammation, in which complex interactions between neutrophils and vascular endothelial cells direct neutrophil adhesion and transmigration from circulation to inflamed tissues (Kolaczkowska and Kubes, 2013). In an in vitro transmigration assay, neutrophil adhesion and migration across monolayers of endothelial cells was significantly enhanced by GM-CSF as chemoattractant (FIGS. 33A and 33B), suggesting GM-CSF may mediate neutrophil recruitment to inflamed joints in AIA. Effective neutrophil apoptosis is crucial for the resolution of inflammation. However, in synovitis, neutrophil apoptosis is delayed with a result of extended survival and persistent inflammation (Wright et al., 2014). Thus, the effect of GM-CSF on neutrophil survival was tested and found that GM-CSF had profound efficacy in delaying neutrophil apoptosis (FIG. 33C). Together, these results indicate that GM-CSF may mediate neutrophil recruitment and sustain neutrophil survival in synovial compartments and contribute to persistent synovitis. To determine the critical role of neutrophils in AIA, \ a neutralizing antibody (1A8) specific for Ly6G was used to deplete neutrophils in vivo. The administration of neutralizing antibody resulted in significant improvement of joint swelling in AIA (FIG. 32D). Thus, neutrophils accumulation mediated by TH-cell-derived GM-CSF are important for AIA development.


Example 14. GM-CSF Enhances Proinflammatory Cytokine Production by Myeloid Cells and Synovial Fibroblasts

Cytokines are important mediators in the cross-talk between innate and adaptive immunity. As shown herein, several proinflammatory cytokines (IL-6, IL-1β and TNF-α), which are in association with RA pathogenesis (Choy and Panayi, 2001), were significantly reduced in synovial tissues of STAT5-deficient AIA mice (FIGS. 28E and 30A-30C). To gain insights into the mechanism underlying the observed cytokine reduction, the cellular sources of these proinflammatory cytokines were examined by fractionating synovial cells into different populations based the differential expression of surface markers (FIG. 34A). Cytokine mRNA expression level in CD45+TCRβ+ population (T cells), CD45+TCRβCD11c CD11b+ population (mostly monocytes/macrophages and neutrophils) and CD45+TCRβ CD11c+ population (dendritic cells) was assessed by RT-PCR. GM-CSF, as similar to IL-17 (as a control), was predominantly produced by synovial T cells (FIG. 34B), further reinforcing the importance of GM-CSF-producing TH cells. In contrast, IL-6 and IL-1β were mainly produced by myeloid cells, e.g. CD11b+ population and CD11c+ population (FIG. 34B). TNF-α was expressed by all three populations, with relatively lower abundance in T cells (FIG. 34B). Based on the differential expression of Ly6C and Ly6G in CD11b+ population as discussed above, Ly6CloLy6Ghi population (neutrophils) and Ly6ChiLy6G population (monocytes/macrophages) were further analyzed, which showed that monocytes/macrophages were likely the major IL-6 producers whereas neutrophils seemed to be better producers of IL-1β and TNF-α (FIG. 34C). These results, together with the findings above (FIGS. 28E and 30A-30C), indicate a link that TH-cell-secreted GM-CSF elicits proinflammatory cytokine expression from myeloid cells in synovitis.


To test the regulatory role of GM-CSF in the expression of IL-6 and IL-1β, bone marrow-derived macrophages (BMDMs) and bone marrow-derived dendritic cells (BMDCs) were cultured, and stimulated with GM-CSF. Indeed, GM-CSF stimulation quickly upregulated mRNA expression of both IL-6 and IL-1β within 1 hour (FIGS. 34D and 34E). In addition, GM-CSF markedly increased the secretion of IL-6 from BMDMs in a dosage-dependent manner (FIG. 34F), and from BMDCs even at low dosage (FIG. 34G). To induce mature IL-1β secretion, BMDMs were primed with LPS for 6 h during which different concentrations of GM-CSF was added, followed by ATP stimulation. The addition of GM-CSF significantly enhanced the secretion of IL-1β into culture supernatant as measured by ELISA (FIG. 34H). Synovial fibroblasts, the active players in synovial inflammation (Muller-Ladner et al., 2007), also showed increased IL-1β mRNA expression upon GM-CSF stimulation (FIG. 34I). An inducible effect of GM-CSF on TNF-α expression was not observed in BMDMs, BMDCs or synovial fibroblasts (data not shown). Given the functional importance of IL-6 and IL-1β in arthritis development (Choy and Panayi, 2001), TH-cell-secreted GM-CSF may mediate synovial inflammation also via eliciting the expression of IL- and IL-1β from myeloid cells and synovial fibroblasts.









TABLE 1





Summary of genes differentially expressed in TH1, TH17, and TH-GM cells
















Genes differentially
Genes differentially


expressed in TH1
expressed in TH17










Gene

Gene



ID
Gene Title
ID
Gene Title





10366586
interferon gamma
10353415
interleukin 17F


10598013
chemokine (C-C
10511779
ATPase, H+



motif) receptor 5 ///

transporting,



chemokine (C-C

lysosomal V0



motif) receptor 2

subunit D2


10523717
secreted
10345762
interleukin 1



phosphoprotein 1

receptor, type 1


10420308
granzyme B
10359697
chemokine (C





motif) ligand 1


10545135
interleukin 12
10587639
5′ nucleotidase,



receptor, beta 2

ecto


10531724
placenta-specific 8
10501860
formin binding





protein 1-like


10363070
glycoprotein 49 A ///
10345032
interleukin 17A



leukocyte



immunoglobulin-



like receptor,



subfamily B,



member 4


10363082
leukocyte
10446965
RAS, guanyl



immunoglobulin-

releasing protein 3



like receptor,



subfamily B,



member 4


10424683
lymphocyte antigen
10565990
ADP-



6 complex, locus G

ribosyltransferase





2a


10552406
natural killer cell
10465059
cathepsin W



group 7 sequence


10603151
glycoprotein m6b
10358476
proteoglycan 4





(megakaryocyte





stimulating factor,





articular





superficial zone





protein)


10360173
SLAM family
10471953
activin receptor



member 7

IIA


10455961
interferon inducible
10400006
aryl-hydrocarbon



GTPase 1

receptor


10400304
EGL nine homolog
10409876
cytotoxic T



3 (C. elegans)

lymphocyte-





associated protein





2 alpha


10574023
metallothionein 2
10388591
carboxypeptidase





D


10493108
cellular retinoic
10390640
IKAROS family



acid binding protein

zinc finger 3



II


10375436
family with
10590623
chemokine (C-X-



sequence similarity

C motif) receptor



71, member B

6


10398039
serine (or cysteine)
10367734
uronyl-2-



peptidase inhibitor,

sulfotransferase



clade A, member 3F ///



serine (or



cysteine) peptidase



inhibitor, clade A,



member 3G


10349108
serine (or cysteine)
10500656
CD101 antigen



peptidase inhibitor,



clade B, member 5


10607738
carbonic anhydrase
10347895
WD repeat



5b, mitochondrial

domain 69


10496539
guanylate binding
10495854
protease, serine,



protein 5

12 neurotrypsin





(motopsin)


10373918
leukemia inhibitory
10425049
apolipoprotein



factor

L9b ///





apolipoprotein





L9a


10455954
predicted gene 4951
10378286
integrin alpha E,





epithelial-





associated


10598976
tissue inhibitor of
10362896
CD24a antigen



metalloproteinase 1


10492136
doublecortin-like
10409866
cytotoxic T



kinase 1

lymphocyte-





associated protein





2 beta


10405211
growth arrest and
10400989
potassium



DNA-damage-

voltage-gated



inducible 45 gamma

channel,





subfamily H (eag-





related), member





5


10503202
chromodomain
10590242
chemokine (C-C



helicase DNA

motif) receptor 8



binding protein 7


10542275
ets variant gene 6
10407435
aldo-keto



(TEL oncogene)

reductase family





1, member Cl8


10556820
transmembrane
10592023
amyloid beta



protein 159

(A4) precursor-





like protein 2


10444291
histocompatibility
10359480
dynamin 3



2, class II antigen A,



beta 1


10439299
stefin A3
10475544
sema domain,





transmembrane





domain (TM), and





cytoplasmic





domain,





(semaphorin) 6D


10547641
solute carrier family
10409767
golgi membrane



2 (facilitated glucose

protein 1



transporter),



member 3


10503200
chromodomain
10392464
family with



helicase DNA

sequence



binding protein 7

similarity 20,





member A


10544320
RIKEN cDNA
10504891
transmembrane



1810009J06 gene ///

protein with EGF-



predicted gene 2663

like and two





follistatin-like





domains 1


10503218
chromodomain
10504817
transforming



helicase DNA

growth factor,



binding protein 7

beta receptor 1


10503198
chromodomain
10393559
tissue inhibitor of



helicase DNA

metalloproteinase



binding protein 7

2


10507594
solute earner family
10474419
leucine-rich



2 (facilitated glucose

repeat-containing



transporter),

G protein-coupled



member 1

receptor 4


10438626
ets variant gene 5
10456492
DNA segment,





Chr 18, ERATO





Doi 653,





expressed


10390328
T-box 21
10345241
dystonin


10574027
metallothionein 1
10471555
angiopoietin-like





2


10493820
S100 calcium
10494821
tetraspanin 2



binding protein A6



(calcyclin)


10376324
predicted gene
10542355
epithelial



12250

membrane protein





1


10406852
calponin 3, acidic
10500295
pleckstrin





homology domain





containing, family





O member 1


10412076
gem (nuclear
10375402
a disintegrin and



organelle)

metallopeptidase



associated protein 8

domain 19





(meltrin beta)


10496555
guanylate binding
10484227
SEC 14 and



protein 1 ///

spectrin domains



guanylate binding

1



protein 5


10345074
centrin 4
10472097
formin-like 2


10503194
chromodomain
10587829
procollagen



helicase DNA

lysine, 2-



binding protein 7

oxoglutarate 5-





dioxygenase 2


10537561
RIKEN cDNA
10530536
tec protein



1810009J06 gene ///

tyrosine kinase



predicted gene 2663


10439895
activated leukocyte
10586700
RAR-related



cell adhesion

orphan receptor



molecule

alpha


10459772
lipase, endothelial
10354191
ring finger





protein 149


10439762
S-
10438738
B-cell



adenosylhomocysteine

leukemia/lymphoma



hydrolase

6


10482030
stomatin
10347888
chemokine (C-C





motif) ligand 20


10459905
SET binding
10440131
G protein-



protein 1

coupled receptor





15


10357833
ATPase, Ca++
10453057
cytochrome P450,



transporting, plasma

family 1,



membrane 4

subfamily b,





polypeptide 1 ///





RIKEN cDNA





1700038P13 gene


10475517
expressed sequence
10542140
killer cell lectin-



AA467197 ///

like receptor



microRNA 147

subfamily B





member 1F


10585778
sema domain,
10471880
microRNA 181b-2



immunoglobulin



domain (Ig), and



GPI membrane



anchor,



(semaphorin) 7A


10354529
RIKEN cDNA
10542791
PTPRF



1700019D03 gene

interacting





protein, binding





protein 1 (liprin





beta 1)


10582275
solute carrier family
10583242
sestrin 3



7 (cationic amino



acid transporter, y+



system), member 5


10576034
interferon
10489569
phospholipid



regulatory factor 8

transfer protein ///





cathepsin A


10503222
chromodomain
10523297
cyclin G2



helicase DNA



binding protein 7


10503220
chromodomain
10381187
ATPase, H+



helicase DNA

transporting,



binding protein 7

lysosomal V0





subunit A1


10503210
chromodomain
10346651
bone



helicase DNA

morphogenic



binding protein 7

protein receptor,





type II





(serine/threonine





kinase)


10476945
cystatin F
10490159
prostate



(leukocystatin)

transmembrane





protein, androgen





induced 1


10503216
chromodomain
10389581
yippee-like 2



helicase DNA

(Drosophila)



binding protein 7


10366983
transmembrane
10581992
avian



protein 194

musculoaponeurotic





fibrosarcoma





(v-maf) AS42





oncogene





homolog


10495675
coagulation factor
10413250
cytoplasmic



III

polyadenylated





homeobox


10421697
RIKEN cDNA
10555063
integrator



9030625A04 gene

complex subunit 4


10445112
ubiquitin D
10406982
a disintegrin-like





and





metallopeptidase





(reprolysin type)





with





thrombospondin





type 1 motif, 6


10530627
leucine rich repeat
10596303
acid phosphatase,



containing 66

prostate


10440019
transmembrane
10357472
chemokine (C-X-



protein 45a

C motif) receptor





4


10378783
ribosomal protein
10545130
growth arrest and



L36

DNA-damage-





inducible 45 alpha


10447341
ras homolog gene
10436402
claudin domain



family, member Q ///

containing 1



phosphatidylinositol



glycan anchor



biosynthesis, class F


10373452
predicted gene 129
10539135
capping protein





(actin filament),





gelsolin-like


10454286
microtubule-
10428534
trichorhinophalangeal



associated protein,

syndrome 1



RP/EB family,

(human)



member 2


10572497
interleukin 12
10368675
myristoylated



receptor, beta 1

alanine rich





protein kinase C





substrate


10368060
epithelial cell
10531910
hydroxysteroid



transforming

(17-beta)



sequence 2

dehydrogenase 13



oncogene-like


10471457
ST6 (alpha-N-
10370303
adenosine



acetyl-neuraminyl-

deaminase, RNA-



2,3-beta-galactosyl-

specific, B1



1,3)-N-



acetylgalactosaminide



alpha-2,6-



sialyltransferase 4


10374366
epidermal growth
10592888
chemochine (C-



factor receptor

X-C motif)





receptor 5


10450501
tumor necrosis
10503259
transformation



factor

related protein 53





inducible nuclear





protein 1


10347291
chemokine (C-X-C
10446771
lysocardiolipin



motif) receptor 2

acyltransferase 1


10553501
solute carrier family
10428579
exostoses



17 (sodium-

(multiple) 1



dependent inorganic



phosphate



cotransporter),



member 6


10345824
interleukin 18
10476314
prion protein



receptor accessory



protein


10458314
transmembrane
10406598
serine



protein 173

incorporator 5


10388430
serine (or cysteine)
10461765
leupaxin



peptidase inhibitor,



clade F, member 1


10496015
phospholipase A2,
10428536
trichorhinophalangeal



group XIIA

syndrome 1





(human)


10510391
spermidine synthase
10362245
erythrocyte





protein band 4.1-





like 2


10486396
EH-domain
10604008
predicted gene



containing 4

10058 ///





predicted gene





10230 ///





predicted gene





10486 ///





predicted gene





14632 ///





predicted gene





14819 ///





predicted gene





4836 ///





predicted gene





2012 ///





predicted gene





5169 ///





predicted gene





6121 /// Sycp3





like X-linked ///





predicted gene





5168 ///





predicted gene





10488 ///





predicted gene





14525 ///





predicted gene





5935


10368054
epithelial cell
10409857
RIKEN cDNA



transforming

4930486L24 gene



sequence 2



oncogene-like


10608637
na
10522368
NIPA-like





domain containing





1


10595718
carbohydrate
10368720
solute carrier



sulfotransferase 2

family 16





(monocarboxylic





acid transporters),





member 10


10496580
guanylate binding
10438639
diacylglycerol



protein 3

kinase, gamma


10594053
promyelocytic
10499431
synaptotagmin XI



leukemia


10544829
JAZF zinc finger 1
10565840
neuraminidase 3


10601778
armadillo repeat
10494023
RAR-related



containing, X-linked

orphan receptor



3

gamma


10355967
adaptor-related
10391103
junction



protein complex AP-

plakoglobin



1, sigma 3


10592503
cytotoxic and
10417053
muscleblind-like



regulatory T cell

2



molecule


10496023
caspase 6
10350341
microRNA 181b-1


10599192
LON peptidase N-
10459071
RIKEN cDNA



terminal domain and

2010002N04 gene



ring finger 3


10467578
phosphoinositide-3-
10463476
Kazal-type serine



kinase adaptor

peptidase inhibitor



protein 1

domain 1


10585703
ribonuclease P 25
10348537
receptor



subunit (human)

(calcitonin)





activity modifying





protein 1


10365482
tissue inhibitor of
10348432
ArfGAP with



metalloproteinase 3

GTPase domain,





ankyrin repeat and





PH domain 1


10469151
inter-alpha
10576332
tubulin, beta 3 ///



(globulin) inhibitor

melanocortin 1



H5

receptor


10503192
chromodomain
10554094
insulin-like



helicase DNA

growth factor 1



binding protein 7

receptor


10593050
interleukin 10
10495794
phosphodiesterase



receptor, alpha

5A, cGMP-





specific


10597648
myeloid
10569504
tumor necrosis



differentiation

factor receptor



primary response

superfamily,



gene 88

member 23


10538290
sorting nexin 10
10452516
ankyrin repeat





domain 12


10503204
chromodomain
10534596
cut-like



helicase DNA

homeobox 1



binding protein 7


10353707
protein tyrosine
10362073
serum/glucocorticoid



phosphatase 4a1 ///

regulated



protein tyrosine

kinase 1



phosphatase 4a1-



like


10377010
SCO cytochrome
10408331
acyl-CoA



oxidase deficient

thioesterase 13



homolog 1 (yeast)


10440903
RIKEN cDNA
10415413
NYN domain and



4932438H23 gene

retroviral





integrase





containing


10521205
SH3-domain
10598359
synaptophysin



binding protein 2


10604587
microRNA 363
10544114
homeodomain





interacting protein





kinase 2


10571958
SH3 domain
10436128
myosin, heavy-



containing ring

chain 15



finger 1


10357553
interleukin 24
10408450
SRY-box





containing gene 4


10606730
armadillo repeat
10487011
glycine



containing, X-linked

amidinotransferase



6

(L- arginine: glycine





amidinotransferase)


10564960
furin (paired basic
10378833
slingshot



amino acid cleaving

homolog 2



enzyme)

(Drosophila)


10402585
tryptophanyl-tRNA
10521498
collapsin



synthetase

response mediator





protein 1


10417095
FERM, RhoGEF
10538939
eukaryotic



(Arhgef) and

translation



pleckstrin domain

initiation factor 2



protein 1

alpha kinase 3



(chondrocyte-



derived)


10442435
ribonucleic acid
10585276
POU domain,



binding protein S1

class 2,





associating factor





1


10394990
membrane bound
10512156
aquaporin 3



O-acyltransferase



domain containing 2


10538753
atonal homolog 1
10469110
USP6 N-terminal



(Drosophila)

like


10351667
signaling
10568392
regulator of G-



lymphocytic

protein signalling



activation molecule

10



family member 1


10461844
guanine nucleotide
10603346
proteolipid



binding protein,

protein 2



alpha q polypeptide


10422057
ribosomal protein
10353947
transmembrane



L7A

protein 131


10572897
heme oxygenase
10452633
TGFB-induced



(decycling) 1

factor homeobox





1


10507784
palmitoyl-protein
10380289
monocyte to



thioesterase 1

macrophage





differentiation-





associated


10445702
ubiquitin specific
10521969
IMP1 inner



peptidase 49

mitochondrial





membrane





peptidase-like





(S. cerevisiae)


10569057
ribonuclease/
10521678
CD38 antigen



angiogenin inhibitor 1


10370471
1-acylglycerol-3-
10592515
ubiquitin



phosphate O-

associated and



acyltransferase 3

SH3 domain





containing, B


10586591
carbonic
10512470
CD72 antigen



anyhydrase 12


10512701
translocase of outer
10587085
cDNA sequence



mitochondrial

BC031353



membrane 5



homolog (yeast)


10462702
HECT domain
10492689
platelet-derived



containing 2

growth factor, C





polypeptide


10552740
nucleoporin 62 ///
10514221
perilipin 2



Nup62-Il4i1 protein


10581996
chromodomain
10458247
leucine rich



protein, Y

repeat



chromosome-like 2

transmembrane





neuronal 2


10363901
ets variant gene 5
10468898
lymphocyte





transmembrane





adaptor 1


10520862
fos-like antigen 2
10555059
potassium





channel





tetramerisation





domain containing





14


10526520
procollagen-lysine,
10408629
RIKEN cDNA



2-oxoglutarate 5-

1300014106 gene



dioxygenase 3


10571274
glutathione
10546510
leucine-rich



reductase

repeats and





immunoglobulin-





like domains 1


10351206
selectin, platelet
10544596
transmembrane





protein 176B


10493474
mucin 1,
10361748
F-box protein 30



transmembrane


10370000
glutathione S-
10356291
RIKEN cDNA



transferase, theta 1

A530040E14 gene


10500272
predicted gene 129
10581450
DEAD (Asp-Glu-





Ala-Asp) box





polypeptide 28


10452815
xanthine
10414417
pellino 2



dehydrogenase


10393823
prolyl 4-
10372528
potassium large



hydroxylase, beta

conductance



polypeptide

calcium-activated





channel,





subfamily M, beta





member 4 ///





RIKEN cDNA





1700058G18 gene


10408280
leucine rich repeat
10408613
tubulin, beta 2B



containing 16A


10575685
nudix (nucleoside
10411274
synaptic vesicle



diphosphate linked

glycoprotein 2c



moiety X)-type



motif 7


10599174
interleukin 13
10456357
phorbol-12-



receptor, alpha 1

myristate-13-





acetate-induced





protein 1


10458940
zinc finger protein
10511498
pleckstrin



608

homology domain





containing, family





F (with FYVE





domain) member





2


10476197
inosine
10402136
G protein-



triphosphatase

coupled receptor



(nucleoside

68



triphosphate



pyrophosphatase)


10419790
ajuba
10549990
vomeronasal 1





receptor, G10 ///





vomernasal 1





receptor Vmn1r-





ps4 ///





vomeronasal 1





receptor 3 ///





vomeronasal 1





receptor





Vmn1r238 ///





vomeronasal 1





receptor 2


10364909
ornithine
10554789
cathepsin C



decarboxylase



antizyme 1 ///



ornithine



decarboxylase



antizyme 1



pseudogene


10503190
chromodomain
10427928
triple functional



helicase DNA

domain (PTPRF



binding protein 7

interacting)


10516932
sestrin 2
10549162
ST8 alpha N





acetyl-





neuraminide





alpha-2,8-





sialyltransferase 1


10585338
KDEL (Lys-Asp-
10482109
mitochondrial



Glu-Leu) containing

ribosome



2

recycling factor ///





RNA binding





motif protein 18


10464425
G protein-coupled
10425092
cytohesin 4



receptor kinase 5


10441601
T-cell activation
10356866
programmed cell



Rho GTPase-

death 1



activating protein


10482059
glycoprotein
10554204
ATP/GTP



galactosyltransferase

binding protein-



alpha 1,3

like 1


10522411
cell wall biogenesis
10403229
integrin beta 8



43 C-terminal



homolog



(S. cerevisiae)


10369276
coiled-coil domain
10374529
expressed



containing 109A

sequence





AV249152


10368970
PR domain
10565434
ribosomal protein



containing 1, with

S13



ZNF domain


10369541
hexokinase 1
10431266
ceramide kinase


10374236
uridine
10410124
cathepsin L



phosphorylase 1


10489660
engulfment and cell
10441003
runt related



motility 2, ced-12

transcription



homolog

factor 1



(C. elegans)


10488797
peroxisomal
10555303
phosphoglucomutase



membrane protein 4

2-like 1


10558090
transforming, acidic
10530215
RIKEN cDNA



coiled-coil

1110003E01 gene



containing protein 2


10409265
AU RNA binding
10480275
nebulette



protein/enoyl-



coenzyme A



hydratase


10374364
thymoma viral
10434302
kelch-like 24



proto-oncogene 2

(Drosophila)


10598575
LanC (antibiotic
10565002
CREB regulated



synthetase

transcription



component C-like 3

coactivator 3



(bacterial)


10439514
growth associated
10413338
na



protein 43


10497842
Bardet-Biedl
10523670
AF4/FMR2



syndrome 7 (human)

family, member 1


10462091
Kruppel-like factor
10478594
cathepsin A



9 /// predicted gene



9971


10498024
solute carrier family
10514128
tetratricopeptide



7 (cationic amino

repeat domain



acid transporter, y+

39B



system), member 11


10483719
chimerin
10535956
StAR-related



(chimaerin) 1

lipid transfer





(START) domain





containing 13


10606694
Bruton
10503695
BTB and CNC



agammaglobulinemia

homology 2



tyrosine kinase


10443110
synaptic Ras
10584334
sialic acid



GTPase activating

acetylesterase



protein 1 homolog



(rat)


10368062
epithelial cell
10502890
ST6 (alpha-N-



transforming

acetyl-



sequence 2

neuraminyl-2,3-



oncogene-like

beta-galactosyl-





1,3)-N-





acetylgalactosaminide





alpha-2,6-





sialyltransferase 3


10575693
vesicle amine
10564467
leucine rich



transport protein 1

repeat containing



homolog-like

28



(T. californica)


10562897
zinc finger protein
10345715
mitogen-activated



473 /// vaccinia

protein kinase



related kinase 3

kinase kinase





kinase 4


10373709
eukaryotic
10568668
a disintegrin and



translation initiation

metallopeptidase



factor 4E nuclear

domain 12



import factor 1

(meltrin alpha)


10487238
histidine
10462406
RIKEN cDNA



decarboxylase

C030046E11 gene


10594988
mitogen-activated
10472649
myosin IIIB



protein kinase 6


10422436
dedicator of
10363894
inositol



cytokinesis 9

polyphosphate





multikinase


10459084
synaptopodin
10606058
chemokine (C-X-





C motif) receptor





3


10567450
dynein, axonemal,
10439955
family with



heavy chain 3

sequence





similarity 55,





member C


10604751
fibroblast growth
10530615
OC1A domain



factor 13

containing 2


10584827
myelin protein
10528183
spermatogenesis



zero-like 2

associated





glutamate (E)-rich





protein 4d ///





spermatogenesis





associated





glutamate (E)-rich





protein 4c ///





spermatogenesis





associated





glutamate (E)-rich





protein 4e ///





predicted gene





9758 /// RIKEN





cDNA





4930572O03 gene ///





spermatogenesis





associated





glutamate (E)-rich





protein 7,





pseudogene 1 ///





predicted gene





7361


10473356
ubiquitin-
10488507
abhydrolase



conjugating enzyme

domain containing



E2L6

12


10498350
purinergic receptor
10420668
microRNA 15a



P2Y, G-protein



coupled, 14


10497862
transient receptor
10469951
ring finger



potential cation

protein 208



channel, subfamily



C, member 3


10368056
epithelial cell
10501629
CDC14 cell



transforming

division cycle 14



sequence 2

homolog A



oncogene-like

(S. cerevisiae)


10425357
Smith-Magenis
10386789
Unc-51 like



syndrome

kinase 2



chromosome region,

(C. elegans)



candidate 7-like



(human)


10498952
guanylate cyclase 1,
10401138
ATPase, H+



soluble, alpha 3

transporting,





lysosomal V1





subunit D


10548905
epidermal growth
10554118
family with



factor receptor

sequence



pathway substrate 8

similarity 169,





member B


10579703
calcium
10603843
synapsin I



homeostasis



endoplasmic



reticulum protein ///



RIKEN cDNA



1700030K09 gene


10404630
RIO kinase 1
10575184
WW domain



(yeast)

containing E3





ubiquitin protein





ligase 2


10518069
EF hand domain
10537712
glutathione S-



containing 2

transferase kappa





1


10469672
glutamic acid
10511541
dpy-19-like 4



decarboxylase 2

(C. elegans)


10526941
RIKEN cDNA
10394816
predicted gene



D830046C22 gene

9282


10567448
dynein, axonemal,
10587503
SH3 domain



heavy chain 3

binding glutamic





acid-rich protein





like 2


10437885
myosin, heavy
10411359
proteolipid



polypeptide 11,

protein 2



smooth muscle


10600122
X-linked
10579939
ubiquitin specific



lymphocyte-

peptidase 38 ///



regulated 3B /// X-

predicted gene



linked lymphocyte-

9725



regulated 3C /// X-



linked lymphocyte-



regulated 3A


10587665
RIKEN cDNA
10370242
poly(rC) binding



4930579C12 gene

protein 3




10350753
glutamate-





ammonia ligase





(glutamine





synthetase)




10456296
mucosa





associated





lymphoid tissue





lymphoma





translocation gene





1




10380571
guanine





nucleotide binding





protein (G





protein), gamma





transducing





activity





polypeptide 2 ///





ABI gene family,





member 3




10369413
sphingosine





phosphate lyase 1




10552276
ubiquitin-





conjugating





enzyme E2H ///





predicted gene





2058




10394532
ubiquitin-





conjugating





enzyme E2F





(putative) ///





ubiquitin-





conjugating





enzyme E2F





(putative)





pseudogene




10556463
aryl hydrocarbon





receptor nuclear





translocator-like




10471994
kinesin family





member 5C




10395328
sorting nexin 13




10599348
glutamate





receptor,





ionotropic,





AMPA3 (alpha 3)




10601595
RIKEN cDNA





3110007F17 gene ///





predicted gene





6604 ///





predicted gene





5167 ///





predicted gene





2411 ///





predicted gene





14957




10372891
SLIT-ROBO Rho





GTPase activating





protein 1




10355024
islet cell





autoantigen 1-like




10518147
podoplanin




10473537
olfactory receptor





1123




10424411
tumor





susceptibility gene





101




10439960
centrosomal





protein 97




10551852
CAP-GLY





domain containing





linker protein 3




10599291
reproductive





homeobox 4E ///





reproductive





homeobox 4G ///





reproductive





homeobox 4F ///





reproductive





homeobox 4A ///





reproductive





homeobox 4C ///





reproductive





homeobox 4B ///





reproductive





homeobox 4D




10587315
glutathione S-





transferase, alpha





4




10447167
metastasis





associated 3




10480288
nebulette




10491300
SKl-like




10596637
mitogen-activated





protein kinase-





activated protein





kinase 3




10518019
DNA-damage





inducible protein





2 /// regulatory





solute carrier





protein, family 1,





member 1




10384685
RIKEN cDNA





1700093K21 gene




(0439483
Rho GTPase





activating protein





31




10353844
neuralized





homolog 3





homolog





(Drosophila)




10459604
RIKEN cDNA





4933403F05 gene




10488892
transient receptor





potential cation





channel,





subfamily C,





member 4





associated protein




10542822
RAB15 effector





protein




10553354
neuron navigator





2




10425966
ataxin 10




10360506
thymoma viral





proto-oncogene 3




10531610
RasGEF domain





family, member





1B




10417787
guanine





nucleotide binding





protein (G





protein), gamma 2




10381588
granulin




10437080
tetratricopeptide





repeat domain 3




10509560
ribosomal protein





L38




10466886
na




10580457
NEDD4 binding





protein 1




10451061
runt related





transcription





factor 2




10433953
yippee-like 1





(Drosophila)




10447461
stonin 1




10501909
methyltransferase





like 14 /// Sec24





related gene





family, member D





(S. cerevisiae)




10519693
sema domain,





immunoglobulin





domain (Ig), short





basic domain,





secreted,





(semaphorin) 3D




10385557
CCR4-NOT





transcription





complex, subunit





6




10413047
plasminogen





activator,





urokinase




10406663
arylsulfatase B




10430113
Rho GTPase





activating protein





39




10475830
mitochondrial





ribosomal protein





S5




10410892
RAS p21 protein





activator 1




10515994
stromal





membrane-





associated





GTPase-activating





protein 2




10410099
CDC14 cell





division cycle 14





homolog B





(S. cerevisiae)




10428157
ring finger





protein 19A




10563643
tumor





susceptibility gene





101




10412260
follistatin ///





thyroid hormone





receptor





associated protein





3




10386539
similar to





ubiquitin A-52





residue ribosomal





protein fusion





product 1




10415574
cyclin 1




10494978
protein tyrosine





phosphatase, non-





receptor type 22





(lymphoid)




10511416
thymocyte





selection-





associated high





mobility group





box




10562500
dpy-19-like 3





(C. elegans)




10568135
proline-rich





transmembrane





protein 2 ///





RIKEN cDNA





2900092E17 gene




10514466
Jun oncogene




10500847
membrane





associated





guanylate kinase,





WW and PDZ





domain containing





3




10549760
zinc finger





protein 580




10549377
RIKEN cDNA





1700034J05 gene




10430174
apolipoprotein L9a ///





apolipoprotein L9b




10474333
elongation





protein 4 homolog





(S. cerevisiae)




10560791
predicted gene,





EG381936 ///





predicted gene





6176




10407159
ankyrin repeat





domain 55




10603659
mediator complex





subunit 14




10576854
cortexin 1




10353775
BEN domain





containing 6




10573865
predicted gene





3579




10356886
solute carrier





organic anion





transporter family,





member 4C1




10507273
phosphatidylinositol





3 kinase,





regulatory





subunit,





polypeptide 3





(p55)




10424252
WDYHV motif





containing 1




10518735
splA/ryanodine





receptor domain





and SOCS box





containing 1




10562576
pleckstrin





homology domain





containing, family





F (with FYVE





domain) member





1




10375667
ring finger





protein 130




10528268
protein tyrosine





phosphatase, non-





receptor type 12




10593205
REX2, RNA





exonuclease 2





homolog





(S. cerevisiae)




10576056
microtubule-





associated protein





1 light chain 3





beta




10547916
parathymosin




10377689
gamma-





aminobutyric acid





receptor





associated protein




10602307
ovary testis





transcribed ///





predicted gene





15085 ///





predicted gene





15127 ///





predicted gene,





OTTMUSG00000019001 ///





leucine zipper





protein 4 ///





predicted gene





15097 ///





predicted gene





15091 ///





predicted gene





10439 ///





predicted gene





15128




10426835
DIP2 disco-





interacting protein





2 homolog B





(Drosophila)




10439798
DAZ interacting





protein 3, zinc





finger




10375614
glutamine





fructose-6-





phosphate





transaminase 2




10361882
NHS-like 1




10419274
glia maturation





factor, beta




10424781
glutamate





receptor,





ionotropic, N-





methyl D-





aspartate-





associated protein





1 (glutamate





binding)




10546960
na




10514713
WD repeat





domain 78




10394954
grainyhead-like 1





(Drosophila)




10437205
Purkinje cell





protein 4




10464251
attractin like 1




10496251
3-





hydroxybutyrate





dehydrogenase,





type 2




10396383
solute carrier





family 38,





member 6




10585794
cytochrome P450,





family 11,





subfamily a,





polypeptide 1




10385719
Sec24 related





gene family,





member A





(S. cerevisiae)




10407358
polyadenylate





binding protein-





interacting protein





1




10498775
golgi integral





membrane protein





4




10584435
von Willebrand





factor A domain





containing 5A




10466304
deltex 4 homolog





(Drosophila)




10598292
forkhead box P3 ///





RIKEN cDNA





4930524L23 gene ///





coiled-coil





domain containing





22




10472440
Taxi (human T-





cell leukemia





virus type I)





binding protein 3




10398455
protein





phosphatase 2,





regulatory subunit





B (B56), gamma





isoform




10493076
SH2 domain





protein 2A




10409152
RIKEN cDNA





1110007C09 gene




10542880
RIKEN cDNA





4833442J19 gene




10378523
Smg-6 homolog,





nonsense





mediated mRNA





decay factor





(C. elegans)




10531560
anthrax toxin





receptor 2




10467319
retinol binding





protein 4, plasma




10395978
predicted gene





527




10471715
mitochondrial





ribosome





recycling factor




10511755
WW domain





containing E3





ubiquitin protein





ligase 1




10353754
zinc finger





protein 451




10477572
chromatin





modifying protein





4B




10359161
sterol O-





acyltransferase 1




10462035
lactate





dehydrogenase B




10543319
family with





sequence





similarity 3,





member C




10579052
predicted gene





10033




10475532
sulfide quinone





reductase-like





(yeast)




10428857
metastasis





suppressor 1




10475144
calpain 3 ///





glucosidase,





alpha; neutral C




10396645
zinc finger and





BTB domain





containing 1




10428302
Kruppel-like





factor 10




10577882
heparan-alpha-





glucosaminide N-





acetyltransferase




10548069
dual-specificity





tyrosine-(Y)-





phosphorylation





regulated kinase 4




10436053
developmental





pluripotency





associated 2




10401564
RIKEN cDNA





1110018G07 gene




10471535
family with





sequence





similarity 129,





member B




10349404
mannoside





acetylglucosaminyltransferase 5




10520173
amiloride-





sensitive cation





channel 3




10508860
solute carrier





family 9





(sodium/hydrogen





exchanger),





member 1




10374500
vacuolar protein





sorting 54 (yeast)




10387723
RIKEN cDNA





2810408A11 gene




10488020
thioredoxin-





related





transmembrane





protein 4




10411126
junction-





mediating and





regulatory protein




10345706
DNA segment,





Chr 1, Brigham &





Womens Genetics





0212 expressed




10364375
cystatin B




10480379
mitochondrial





ribosomal protein





S5




10521243
G protein-





coupled receptor





kinase 4




10497920
ankyrin repeat





domain 50




10593723
acyl-CoA





synthetase





bubblegum family





member 1




10375634
mitogen-activated





protein kinase 9




10384555
aftiphilin




10468113
Kv channel-





interacting protein





2




10423363
progressive





ankylosis




10538150
transmembrane





protein 176A




10396485
synaptic nuclear





envelope 2




10401007
protein





phosphatase 2,





regulatory subunit





B (B56), epsilon





isoform




10419151
eosinophil-





associated,





ribonuclease A





family, member 1




10390768
SWI/SNF related,





matrix associated,





actin dependent





regulator of





chromatin,





subfamily e,





member 1




10478145
protein





phosphatase 1,





regulatory





(inhibitor) subunit





16B




10433057
calcium binding





and coiled coil





domain 1




10545921
MAX





dimerization





protein 1




10392449
WD repeat





domain,





phosphoinositide





interacting 1




10545608
sema domain,





immunoglobulin





domain (Ig), TM





domain, and short





cytoplasmic





domain




10567219
ADP-ribosylation





factor-like 6





interacting protein





1




10471201
c-abl oncogene 1,





receptor tyrosine





kinase




10505841
predicted gene





13271 ///





predicted gene





13290 ///





predicted gene





13277 ///





predicted gene





13276




10414360
lectin, galactose





binding, soluble 3




10403258
guanosine





diphosphate





(GDP)





dissociation





inhibitor 2




10476759
Ras and Rab





interactor 2




10430866
cytochrome P450,





family 2,





subfamily d,





polypeptide 10




10432619
POU domain,





class 6,





transcription





factor 1




10521972
protocadherin 7




10350646
ER degradation





enhancer,





mannosidase





alpha-like 3




10440993
regulator of





calcineurin 1




10505008
solute carrier





family 44,





member 1




10566670
olfactory receptor





478




10356172
phosphotyrosine





interaction domain





containing 1




10418506
stabilin 1




10419429
olfactory receptor





723 /// olfactory





receptor 724




10581434
dipeptidase 2




10401365
zinc finger,





FYVE domain





containing 1




10591188
olfactory receptor





843




10565846
signal peptidase





complex subunit 2





homolog





(S. cerevisiae)




10467258
myoferlin




10548547
predicted gene





6600




10523012
deoxycytidine





kinase




10348547
ubiquitin-





conjugating





enzyme E2F





(putative)




10483667
corepressor





interacting with





RBPJ, 1




10584071
PR domain





containing 10




10585249
protein





phosphatase 2





(formerly 2A),





regulatory subunit





A (PR 65), beta





isoform




10546137
ankyrin repeat





and BTB (POZ)





domain containing





1




10484720
olfactory receptor





1166




10571415
vacuolar protein





sorting 37 A





(yeast)




10595189
solute carrier





family 17





(anion/sugar





transporter),





member 5




10584426
olfactory receptor





910




10585986
myosin IXa




10401753
VPS33B





interacting





protein, apical-





basolateral





polarity regulator




10349793
dual





serine/threonine





and tyrosine





protein kinase




10527528
SWI/SNF related,





matrix associated,





actin dependent





regulator of





chromatin,





subfamily e,





member 1




10485767
olfactory receptor





1277




10557459
mitogen-activated





protein kinase 3




10471486
endoglin




10420846
frizzled homolog





3 (Drosophila)




10405849
olfactory receptor





466




10568691
RIKEN cDNA





A130023I24 gene




10351111
dynamin 3,





opposite strand ///





microRNA 214 ///





microRNA 199a-2




10540785
RIKEN cDNA





6720456B07 gene




10540923
makorin, ring





finger protein, 2




10413416
interleukin 17





receptor D




10386636
ubiquitin specific





peptidase 22




10383799
transcobalamin 2












Genes differentially
Genes upregulated
Genes downregulated on


upregulated in TH-GM cells
on TH-GM surface
TH-GM cells surface












Gene

Gene

Gene



ID
Gene Title
ID
Gene Title
Symbol
Gene Title





10385918
interleukin 3
10435704
CD80 antigen
Ly6a
lymphocyte







antigen 6 complex,







locus A


10511363
preproenkephalin
10548409
killer cell lectin-
Cd27
CD27 antigen





like receptor





subfamily C,





member 1


10497878
interleukin 2
10421737
tumor necrosis
Sell
selectin,





factor (ligand)

lymphocyte





superfamily,





member 11


10385912
colony
10597420
chemokine (C-C
Ctsw
cathepsin W



stimulating factor

motif) receptor 4



2 (granulocyte-



macrophage)


10404422
serine (or
10441633
chemokine (C-C
Ltb
lymphotoxin B



cysteine)

motif) receptor 6



peptidase



inhibitor, clade



B, member 6b


10408689
neuritin 1
10365933
early endosome
Gngt2
guanine nucleotide





antigen 1

binding protein (G







protein), gamma







transducing activity







polypeptide 2 ///







ABI gene family,







member 3


10467979
stearoyl-
10404840
CD83 antigen
Gpr18
G protein-coupled



Coenzyme A



receptor 18



desaturase 1


10469312
phosphotriesterase
10359434
Fas ligand (TNF
Igfbp4
insulin-like growth



related ///

superfamily,

factor binding



Clq-like 3

member 6)

protein 4


10435704
CD80 antigen
10344966
lymphocyte
Il17ra
interleukin 17





antigen 96

receptor A


10502655
cysteine rich
10345752
interleukin 1
Il18r1
interleukin 18



protein 61

receptor, type II

receptor 1


10350159
ladinin
10439527
T cell
Klrd1
killer cell lectin-





immunoreceptor

like receptor,





with Ig and ITIM

subfamily D,





domains

member 1


10548409
killer ceil lectin-
10494595
Notch gene
Mctp2
multiple C2



like receptor

homolog 2

domains,



subfamily C,

(Drosophila)

transmembrane 2



member 1


10571399
zinc finger,
10597279
chemokine (C-C
Ms4a6b
membrane-



DHHC domain

motif) receptor-

spanning 4-



containing 2

like 2

domains, subfamily







A, member 6B


10538791
TNFAIP3
10485405
CD44 antigen
Pld3
phospholipase D



interacting



family, member 3



protein 3


10407126
polo-like kinase
10561104
AXL receptor
Pyhin1
pyrin and HIN



2 (Drosophila)

tyrosine kinase

domain family,







member 1


10355984
serine (or
10585048
cell adhesion
S1pr1
sphingosine-1-



cysteine)

molecule 1

phosphate receptor



peptidase



1



inhibitor, clade



E, member 2


10421737
tumor necrosis


Slc44a2
solute carrier



factor (ligand)



family 44, member



superfamily,



2



member 11


10503023
cystathionase



(cystathionine



gamma-lyase)


10389207
chemokine (C-C



motif) ligand 5


10361887
PERP, TP53



apoptosis



effector


10530841
insulin-like



growth factor



binding protein 7


10504838
nuclear receptor



subfamily 4,



group A, member



3


10482762
isopentenyl-



diphosphate delta



isomerase


10597420
chemokine (C-C



motif) receptor 4


10441633
chemokine (C-C



motif) receptor 6


10595402
family with



sequence



similarity 46,



member A


10480139
Clq-like 3 ///



phosphotriesterase



related


10540472
basic helix-loop-



helix family,



member e40


10404429
serine (or



cysteine)



peptidase



inhibitor, clade



B, member 9


10595404
family with



sequence



similarity 46,



member A


10365933
early endosome



antigen 1


10384373
fidgetin-like 1


10400072
scinderin


10377938
enolase 3, beta



muscle


10589994
eomesodermin



homolog



(Xenopus laevis)


10404840
CD83 antigen


10485624
proline rich Gla



(G-



carboxyglutamic



acid) 4



(transmembrane)


10369102
predicted gene



9766


10505030
fibronectin type



III and SPRY



domain



containing 1-like


10606868
brain expressed



gene 1


10501832
ATP-binding



cassette, sub-



family D (ALD),



member 3


10457225
mitogen-



activated protein



kinase kinase



kinase 8


10554521
phosphodiesterase



8A


10446229
tumor necrosis



factor (ligand)



superfamily,



member 9


10593842
tetraspanin 3


10407211
phosphatidic



acid phosphatase



type 2A


10488655
BCL2-like 1


10470182
brain expressed



myelocytomatosis



oncogene


10445977
Epstein-Barr



virus induced



gene 3


10587495
interleukin-1



receptor-



associated kinase



1 binding protein



1


10419082
RIKEN cDNA



5730469M10



gene


10472212
plakophilin 4


10487588
interleukin 1



alpha


10359434
Fas ligand (TNF



superfamily,



member 6)


10351015
serine (or



cysteine)



peptidase



inhibitor, clade C



(antithrombin),



member 1


10344966
lymphocyte



antigen 96


10488415
cystatin C


10598771
monoamine



oxidase A


10345752
interleukin 1



receptor, type II


10588577
cytokine



inducible SH2-



containing



protein


10439527
T cell



immunoreceptor



with Ig and ITIM



domains


10511258
family with



sequence



similarity 132,



member A


10403584
nidogen 1


10399973
histone



deacetylase 9


10494595
Notch gene



homolog 2



(Drosophila)


10346168
signal transducer



and activator of



transcription 4


10350630
family with



sequence



similarity 129,



member A


10564667
neurotrophic



tyrosine kinase,



receptor, type 3


10419288
GTP



cyclohydrolase 1


10407535
ribosomal



protein L10A ///



ribosomal protein



L10A,



pseudogene 2


10468945
acyl-Coenzyme



A binding



domain



containing 7


10435271
HEG homolog 1



(zebrafish)


10576639
neuropilin 1


10505059
T-cell acute



lymphocytic



leukemia 2


10457091
neuropilin



(NRP) and



tolloid (TLL)-



like 1


10428081
heat-responsive



protein 12


10435712
CD80 antigen


10597279
chemokine (C-C



motif) receptor-



like 2


10485405
CD44 antigen


10436662
microRNA 155


10562044
zinc finger and



BTB domain



containing 32


10463599
nuclear factor of



kappa light



polypeptide gene



enhancer in B-



cells 2, p49/p100


10456005
CD74 antigen



(invariant



polypeptide of



major



histocompatibility



complex, class



II antigen-



associated)


10490903
carbonic



anhydrase 13


10468762
RIKEN cDNA



4930506M07



gene


10470316
na


10363195
heat shock factor



2


10596652
HemK



methyltransferase



family member 1


10435693
cytochrome c



oxidase, subunit



XVII assembly



protein homolog



(yeast)


10544660
oxysterol



binding protein-



like 3


10384725
reticuloendotheliosis



oncogene


10408600
serine (or



cysteine)



peptidase



inhibitor, clade



B, member 6a


10391444
RUN domain



containing 1 ///



RIKEN cDNA



1700113I22 gene


10561516
nuclear factor of



kappa light



polypeptide gene



enhancer in B-



cells inhibitor,



beta


10566846
DENN/MADD



domain



containing 5A


10435048
Tctex1 domain



containing 2


10470175
lipocalin 13


10586250
DENN/MADD



domain



containing 4A


10512774
coronin, actin



binding protein



2A


10366546
carboxypeptidase



M


10354286
KDEL (Lys-



Asp-Glu-Leu)



containing 1


10547621
apolipoprotein B



mRNA editing



enzyme, catalytic



polypeptide 1


10440419
B-cell



translocation



gene 3 /// B-cell



translocation



gene 3



pseudogene


10407467
aldo-keto



reductase family



1, member E1


10558580
undifferentiated



embryonic cell



transcription



factor 1


10544644
na


10424543
WNT1 inducible



signaling



pathway protein



1


10507137
PDZK1



interacting



protein 1


10384691
RIKEN cDNA



0610010F05



gene


10565315
fumarylacetoacetate



hydrolase


10586248
DENN/MADD



domain



containing 4A


10561104
AXL receptor



tyrosine kinase


10385837
interleukin 13


10440393
SAM domain,



SH3 domain and



nuclear



localization



signals, 1


10401987
potassium



channel,



subfamily K,



member 10


10453715
RAB18, member



RAS oncogene



family


10496466
alcohol



dehydrogenase 4



(class II),



pipolypeptide


10396712
fucosyltransferase 8


10603708
calcium/calmodulin-



dependent



serine protein



kinase (MAGUK



family)


10352178
saccharopine



dehydrogenase



(putative) ///



similar to



Saccharopine



dehydrogenase



(putative)


10349081
PH domain and



leucine rich



repeat protein



phosphatase 1


10364950
growth arrest



and DNA-



damage-



inducible 45 beta


10566877
SET binding



factor 2


10575160
nuclear factor of



activated T-cells



5


10458090
receptor



accessory protein



5


10439845
predicted gene



5486


10461558
solute carrier



family 15,



member 3


10586254
DENN/MADD



domain



containing 4A


10574166
copine II


10598467
proviral



integration site 2


10447084
galactose



mutarotase


10366346
pleckstrin



homology-like



domain, family



A, member 1


10355567
transmembrane



BAX inhibitor



motif containing



1


10407420
neuroepithelial



cell transforming



gene 1


10411882
neurolysin



(metallopeptidase



M3 family)


10585048
cell adhesion



molecule 1


10538890
hypothetical



protein



LOC641050


10406681
adaptor-related



protein complex



3, beta 1 subunit


10455647
tumor necrosis



factor, alpha-



induced protein 8


10447521
transcription



factor B1,



mitochondrial ///



T-cell lymphoma



invasion and



metastasis 2


10523772
leucine rich



repeat containing



8D


10417759
ubiquitin-



conjugating



enzyme E2E 2



(UBC4/5



homolog, yeast)


10586244
DENN/MADD



domain



containing 4A


10436500
glucan (1,4-



alpha),



branching



enzyme 1


10556297
adrenomedullin


10593492
zinc finger



CCCH type



containing 12C


10373358
interleukin 23,



alpha subunit p19


10358583
hemicentin 1


10567995
nuclear protein 1


10512030
RIKEN cDNA



3110043021



gene


10594652
lactamase, beta


10344960
transmembrane



protein 70


10399908
protein kinase,



cAMP dependent



regulatory, type



II beta


10605766
melanoma



antigen, family



D, 1


10474141
solute carrier



family 1 (glial



high affinity



glutamate



transporter),



member 2


10461909
cDNA sequence



BC016495


10548030
CD9 antigen


10525473
transmembrane



protein 120B


10435266
HEG homolog 1



(zebrafish)


10593483
ferredoxin 1


10476569
RIKEN cDNA



2310003L22



gene


10526718
sperm motility



kinase 3A ///



sperm motility



kinase 3B ///



sperm motility



kinase 3C


10547613
ribosomal



modification



protein rimK-like



family member B


10511446
aspartate-beta-



hydroxylase


10375137
potassium large



conductance



calcium-activated



channel,



subfamily M,



beta member 1


10528154
predicted gene



6455 /// RIKEN



cDNA



4933402N22



gene


10514173
ribosomal



protein L34 ///



predicted gene



10154 ///



predicted



pseudogene



10086 ///



predicted gene



6404


10586227
DENN/MADD



domain



containing 4A


10402648
brain protein 44-



like


10575745
ATM interactor


10346255
ORM1-like 1



(S. cerevisiae)


10400405
nuclear factor of



kappa light



polypeptide gene



enhancer in B-



cells inhibitor,



alpha


10528527
family with



sequence



similarity 126,



member A


10472738
DDB 1 and



CUL4 associated



factor 17


10368534
nuclear receptor



coactivator 7


10407543
GTP binding



protein 4


10376555
COP9



(constitutive



photomorphogenic)



homolog,



subunit 3



(Arabidopsis




thaliana)



10567297
inositol 1,4,5-



triphosphate



receptor



interacting



protein-like 2


10589886
RIKEN cDNA



4930520004



gene


10423593
lysosomal-



associated



protein



transmembrane



4B


10577954
RAB11 family



interacting



protein 1 (class I)


10604528
muscleblind-like



3 (Drosophila)


10432675
RIKEN cDNA



I730030J21 gene


10385747
PHD finger



protein 15


10398240
echinoderm



microtubule



associated



protein like 1


10511803
RIKEN cDNA



2610029I01 gene


10466606
annexin A1


10520304
ARP3 actin-



related protein 3



homolog B



(yeast)


10425903
na


10488709
RIKEN cDNA



8430427H17



gene


10376096
acyl-CoA



synthetase long-



chain family



member 6


10429491
activity



regulated



cytoskeletal-



associated



protein


10439710
pleckstrin



homology-like



domain, family



B, member 2


10467110
expressed



sequence



AI747699


10536898
interferon



regulatory factor



5


10505044
fukutin


10605370
membrane



protein,



palmitoylated


10363669
DnaJ (Hsp40)



homolog,



subfamily C,



member 12


10496727
dimethylarginine



dimethylaminohydrolase



1


10587683
B-cell



leukemia/lymphoma



2 related



protein A1a ///



B-cell



leukemia/lymphoma



2 related



protein A1d ///



B-cell



leukemia/lymphoma



2 related



protein A1b ///



B-cell



leukemia/lymphoma



2 related



protein A1e


10458816
toll like receptor



adaptor molecule



2


10513008
Kruppel-like



factor 4 (gut)


10550906
plasminogen



activator,



urokinase



receptor


10362674
U3A small



nuclear RNA


10473190
DnaJ (Hsp40)



homolog,



subfamily C,



member 10


10477581
ribosomal



protein L5


10571774
aspartylglucosaminidase


10395356
anterior gradient



homolog 3



(Xenopus laevis)


10392440
solute carrier



family 16



(monocarboxylic



acid



transporters),



member 6


10352815
interferon



regulatory factor



6









REFERENCES



  • Afkarian, M., Sedy, J. R., Yang, J., Jacobson, N. G., Cereb, N., Yang, S. Y., Murphy. T. L., and Murphy, K. M. (2002). T-bet is a STAT1-induced regulator of IL-12R expression in naive CD4+ T cells. Nature immunology 3, 549-557.

  • Ansel, K. M., Djuretic, I., Tanasa, B., and Rao. A, (2006). Regulation of Th2 differentiation and 114 locus accessibility. Annual review of immunology 24, 607-656.

  • Baron. J. L., Madri, J. A., Ruddle, N. H., Hashim, G., and Janeway, C. A., Jr. (1993). Surface expression of alpha 4 integrin by CD4 T cells is required for their entry into brain parenchyma. J Exp Med 177, 57-68.

  • Bell, A. L., Magill. M. K., McKane, W. R., Kirk, F., and Irvine, A. E. (1995). Measurement of colony-stimulating factors in synovial fluid: potential clinical value. Rheumatol Int 14, 177-182.

  • Berner, B., Akca, D., Jung, T., Muller, G. A., and Reuss-Borst, M. A. (2000). Analysis of Th1 and Th2 cytokines expressing CD4+ and CD8+ T cells in rheumatoid arthritis by flow cytometry. J Rheumatol 27, 1128-1135.

  • Bettelli, E., Carrier, Y., Gao, W., Korn, T., Strom, T. B., Oukka, M., Weiner, H. L., and Kuchroo, V. K. (2006). Reciprocal developmental pathways for the generation of pathogenic effector TH17 and regulatory T cells. Nature 441, 235-238.

  • Brustic, A., Heink, S., Huber, M., Rosenplanter, C., Stadelmann, C., Yu. P., Arpaia, E., Mak, T. W., Kamradt, T., and Lohoff, M. (2007). The development of inflammatory T(H)-17 cells requires interferon-regulatory factor 4. Nature immunology 8, 958-966.

  • Burchill, M. A., Yang, J., Vogtenhuber, C., Blazar, B. R., and Farmr, M. A. (2007). IL-2 receptor beta-dependent STAT5 activation is required for the development of Foxp3+ regulatory T cells. J Immunol 178, 280-290.

  • Campbell. I. K., Rich, M. J., Bischof, R. J., Dunn. A. R., Grail. D., and Hamilton, J. A. (1998). Protection from collagen-induced arthritis in granulocyte-macrophage colony-stimulating factor-deficient mice. J Immunol 161, 3639-3644.

  • Campbell, I. K., van Nieuwenhuijze, A., Segura, E., O'Donnell, K., Coghill, E., Hommel, M., Gerondakis, S., Villadangos. J. A., and Wicks, I. P. (2011). Differentiation of inflammatory dendritic cells is mediated by NF-kappaB1-dependent GM-CSF production in CD4 T cells. J Immunol 186, 5468-5477.

  • Choy, E H., and Panayi, G. S. (2001). Cytokine pathways and joint inflammation in rheumatoid arthritis. N Engl J Med 344, 907-916.

  • Codarri, L., Gyulveszi, G., Tosevski, V., Hesske, L., Fontana. A., Magnenat, L., Suter, T., and Becher. B. (2011). RORgammat drives production of the cytokine GM-CSF in helper T cells, which is essential for the effector phase of autoimmune neuroinflammation. Nat Immunol 12, 560-567.

  • Cook, A. D., Braine, E. L., Campbell, I. K., Rich, M. J., and Hamilton, J. A. (2001). Blockade of collagen-induced arthritis post-onset by antibody to granulocyte-macrophage colony-stimulating factor (GM-CSF): requirement for GM-CSF in the effector phase of disease. Arthritis Res 3, 293-298.

  • Cope, A. P., Schulze-Koops, H., and Aringer, M. (2007). The central role of T cells in rheumatoid arthritis. Clin Exp Rheumatol 25, S4-11.

  • Cornish, A. L., Campbell, I. K., McKenzie, B. S., Chatfield, S., and Wicks, I. P. (2009). G-CSF and GM-CSF as therapeutic targets in rheumatoid arthritis. Nat Rev Rheumatol 5, 554-559.

  • Croxford, A. L., Mair, F., and Becher, B. (2012). IL-23: one cytokine in control of autoimmunity. European journal of immunology 42, 2263-2273.

  • Cua, D. J., Sherlock, J., Chen, Y., Murphy, C. A., Joyce, B., Seymour, B., Lucian, L., To, W., Kwan. S., Churakova, T., et al. (2003). Interleukin-23 rather than interleukin-12 is the critical cytokine for autoimmune inflammation of the brain. Nature 421, 744-748.

  • El-Behi, M., Ciric, B., Dai, H., Yan, Y., Cullimore, M., Safavi, F., Zhang, G. X., Dittel, B. N., and Rostami, A. (2011). The encephalitogenicity of T(H)17 cells is dependent on IL-1- and IL-23-induced production of the cytokine GM-CSF. Nat Immunol 12, 568-575.

  • Gran. B., Zhang, G. X., Yu, S., Li. J., Chen, X. H., Ventura, E. S., Kamoun, M., and Rostami, A. (2002). IL-12p35-deficient mice are susceptible to experimental autoimmune encephalomyelitis: evidence for redundancy in the IL-12 system in the induction of central nervous system autoimmune demyelination. J Immunol 69, 7104-7110.

  • Gregory, S. G., Schmidt, S., Seth. P., Oksenberg, J. R., Hart, J., Prokop, A., Caillier, S. J., Ban, M., Goris, A., Barcellos, L. F., et al. (2007). Interleukin 7 receptor alpha chain (IL7R) shows allelic and functional association with multiple sclerosis. Nature genetics 39, 1083-1091.

  • Greter, M., Helft, J., Chow, A., Hashimoto, D., Mortha, A., Agudo-Cantcro, J., Bogunovic, M., Gautier, E. L., Miller, J., Leboeuf, M., et al., (2012). GM-CSF controls nonlymphoid tissue dendritic cell homeostasis but is dispensable for the differentiation of inflammatory dendritic cells. Immunity 36, 1031-1046.

  • Guedez, Y. B., Whittington, K. B., Clayton, J. L., Joosten, L. A., van de Loo, F. A., van den Berg, W. B., and Rosloniec, E. F. (2001). Genetic ablation of interferon-gamma upregulates interleukin-1 beta expression and enables the elicitation of collagen-induced arthritis in a nonsusceptible mouse strain. Arthritis Rheum 44, 2413-2424.

  • Gutcher, I., and Becher, B. (2007). APC-derived cytokines and T cell polarization in autoimmune inflammation. J Clin Invest 117, 1119-1127.

  • Haak, S., Croxford, A. L., Kreymborg, K., Heppner, F. L., Pouly, S., Becher, B., and Waisman, A. (2009). IL-17A and IL-17F do not contribute vitally to autoimmune neuroinflammation in mice. J Clin Invest 119, 61-69.

  • Hamilton, J. A. (2008). Colony-stimulating factors in inflammation and autoimmunity. Nat Rev Immunol 8, 533-544.

  • Harrington, L. E., Hatton, R. D., Mangan, P. R., Turner, H., Murphy, T. L., Murphy,

  • K. M., and Weaver, C. T. (2005). Interleukin 17-producing CD4+ effector T cells develop via a lineage distinct from the T helper type 1 and 2 lineages. Nat Immunol 6, 1123-1132.

  • Hofstetter, 1-1.1-1., Ibrahim, S. M., Koczan, D., Kruse, N., Weishaupt, A., Toyka, K. V., and Gold, R. (2005). Therapeutic efficacy of IL-17 neutralization in murine experimental autoimmune encephalomyelitis. Cell Immunol 237, 123-130.

  • Irmler, I. M., Gajda, M., and Brauer. R. (2007). Exacerbation of antigen-induced arthritis in IFN-gamma-deficient mice as a result of unrestricted IL-17 response. J Immunol 179, 6228-6236.

  • Ivanov, I I. McKenzie, B. S., Zhou. L., Tadokoro, C. E., Lepelley, A., Lafaille, J. J., Cua, D. J., and Littman, D. R. (2006). The orphan nuclear receptor RORgammat directs the differentiation program of proinflammatory IL-17+T helper cells. Cell 126, 1121-1133.

  • Kaplan, M. N., Schindler, U., Smiley, S. T., and Grusby, M. J. (1996a). Stat6 is required for mediating responses to IL-4 and for development of Th2 cells. Immunity 4, 313-319.

  • Kaplan, M. H., Sun, Y. L., Hoey, T., and Grusby, M. J. (1996b). Impaired IL-12 responses and enhanced development of Th2 cells in Stat4-deficient mice. Nature 382, 174-177.

  • Kolaczkowska, E., and Kubes, P. (2013). Neutrophil recruitment and function in health and inflammation. Nat Rev Immunol 13, 159-175.

  • Komatsu, N., and Takayanagi, H. (2012). Autoimmune arthritis: the interface between the immune system and joints. Adv Immunol 115, 45-71.

  • Korn. T., Bettelli, E., Gao, W., Awasihi, A., Jager. A., Strom, T. B., Oukka, M., and Kuchroo, V. K. (2007). IL-21 initiates an alternative pathway to induce proinflammatory T(H)17 cells. Nature 448, 484-487.

  • Langrish, C. L., Chen, Y., Blumenschein, W. M., Mattson, J., Basham, B., Sedgwick, J. D., McClanahan, T., Kastelein, R. A., and Cua, D. J. (2005). IL-23 drives a pathogenic T cell population that induces autoimmune inflammation. J Exp Med 201, 233-240.

  • Laurence, A., Tato. C. M., Davidson, T. S., Kanno, Y., Chen. Z., Yao, Z., Blank, R. B., Meylan, F., Siegel. R., Hennighausen, L., et al. (2007). Interleukin-2 signaling via STAT5 constrains T helper 17 cell generation. Immunity 26, 371-381.

  • Lawlor, K. E., Wong, P. K., Campbell, P. K., van Rooijen, N., and Wicks, I. P. (2005). Acute CD4+T lymphocyte-dependent interleukin-1-driven arthritis selectively requires interleukin-2 and interleukin-4, joint macrophages, granulocyte-macrophage colony-stimulating factor, interleukin-6, and leukemia inhibitory factor. Arthritis Rheum 52, 3749-3754.

  • Lee, L. F., Logronio, K., Tu, G. H., Zhai, W., Ni, I., Mei, L., Dilley, J., Yu, J., Rajpal, A., Brown, C., et al. (2012). Anti-IL-7 receptor-alpha reverses established type 1 diabetes in nonobese diabetic mice by modulating effector T-cell function. Proc Natl Acad Sci USA 109, 12674-12679.

  • Leonard, J. P., Waldburger, K. E., and Goldman, S. J. (1995). Prevention of experimental autoimmune encephalomyelitis by antibodies against interleukin 12. J Exp Med 181.381-386.

  • Lighvani, A. A., Frucht, D. M., Jankovic, D., Yamanc, H., Aliberti, J., Hissong, B. D., Nguyen, B. V., Gadina, M., Sher. A., Paul, W. E., and O'Shea. J. J. (2001). T-bet is rapidly induced by interferon-gamma in lymphoid and myeloid cells. Proc Natl Acad Sci USA 98, 15137-15142.

  • Liu, X., Lee, Y. S., Yu, C. R., and Egwuagu, C. E. (2008). Loss of STAT5 in CD4+ T cells prevents development of experimental autoimmune diseases. J Immunol 180, 6070-6076.

  • Lock, C., Hermans, G., Pedotti, R., Brendolan, A., Schadt, E., Garren, H., Langer-Gould, A., Stroher, S., Cannella, B., Allard, J., et al. (2002). Gene-microarray analysis of multiple sclerosis lesions yields new targets validated in autoimmune encephalomyelitis. Nat Med 8, 500-508.

  • Lundmark, F., Duvefelt. K., Iacobaeus, E., Kockum, I., Wallstrom, E., Khademi, M., Oturai, A., Ryder, L. P., Saatchi, J., Harbo, H. F., et al. (2007). Variation in interleukin 7 receptor alpha chain (IL7R) influences risk of multiple sclerosis: Nature genetics 39, 1108-1113.

  • Manoury-Schwartz, B., Chiocchia, G., Bcssis, N., Ahchsira-Amar, O., Batteux, F., Muller, S., Huang, S., Boissier, M. C., and Fournier, C. (1997). High susceptibility to collagen-induced arthritis in mice lacking IFN-gamma receptors. J Immunol 158, 5501-5506.

  • MeGeachy, M. J., Chen, Y., Tato, C. M., Laurence, A., Joyce-Shaikh, B., Blumenschein, W. M., McClanahan, T. K., O'Shea, J. J., and Cua, D. J. (2009). The interleukin 23 receptor is essential for the terminal differentiation of interleukin 17-producing effector T helper cells in vivo. Nat Immunol 10, 314-324.

  • McInnes, I. B., and Schen, G. (2007). Cytokines in the pathogenesis of rheumatoid arthritis. Nat Rev Immunol 7, 429-442.

  • McInnes, I. B., and Schen, G. (2011). The pathogenesis of rheumatoid arthritis. N Engl J Med 365, 2205-2219.

  • Muller-Ladner, U., Ospelt, C., Gay, S., Distler, O., and Pap, T. (2007). Cells of the synovium in rheumatoid arthritis. Synovial fibroblasts. Arthritis Res Ther 9, 223.

  • Muller, J., Sperl, B., Reindl, W., Kiessling, A., and Berg, T. (2008). Discovery of chromone-based inhibitors of the transcription factor STAT5. Chembiochem: a European journal of chemical biology 9, 723-727.

  • Nurieva, R., Yang, X. O., Martinez, G., Zhang, Y., Panopoulos, A. D., Ma, L., Schluns, K., Tian, Q., Watowich, Jetten. A. M., and Dong, C. (2007). Essential autocrine regulation by IL-21 in the generation of inflammatory T cells. Nature 448, 480-483.

  • Okada. Y., Wu, D., Trynka, G., Raj, T., Terao, C., Ikari, K., Kochi, Y., Ohmura, K., Suzuki, A., Yoshida, S., et al. (2014). Genetics of rheumatoid arthritis contributes to biology and drug discovery. Nature 506, 376-381.

  • Pernis, A. B. (2009). Th17 cells in rheumatoid arthritis and systemic lupus erythematosus. J Intern Med 265, 644-652.

  • Plater-Zyberk. C., Joosten, L. A., Helsen, M. M., Hepp, J., Baeuerle, P. A., and van den Berg, W. B. (2007). GM-CSF neutralisation suppresses inflammation and protects cartilage in acute streptococcal cell wall arthritis of mice. Ann Rheum Dis 66, 452-457.

  • Ponomarev, E. D., Shriver, L. P., Maresz, K., Pedras-Vasconcelos, J., Verthelyi, D., and Dittel, B. N. (2007). GM-CSF production by autoreactive T cells is required for the activation of microglial cells and the onset of experimental autoimmune encephalomyelitis. J Immunol 178, 39-48.

  • Reboldi, A., Coisne, C., Baumjohann, D., Benvenuto, F., Bottinelli, D., Lira, S., Uccclli, A., Lanzavecchia, A., Engelhardt. B., and Sallusto, F. (2009). C-C chemokine receptor 6-regulated entry of TH-17 cells into the CNS through the choroid plexus is required for the initiation of EAE. Nat Immunol 10, 514-523.

  • Segal, B. M., and Shevach, E. M. (1996). IL-12 unmasks latent autoimmune disease in resistant mice. J Exp Med 184, 771-775.

  • Shimoda, K., van Deursen, J., Sangster, M. Y., Sarawar, S. R., Carson, R. T., Tripp, R. A., Chu, C., Quelle, F. W., Nosaka, T., Vignali, D. A., et al. (1996). Lack of IL-4-induced Th2 response and IgE class switching in mice with disrupted Stat6 gene. Nature 380, 630-633.

  • Sonderegger, I., Iezzi, G., Maier, R., Schmitz, N., Kurrer, M., and Kopf, M. (2008). GM-CSF mediates autoimmunity by enhancing IL-6-dependent Th17 cell development and survival. J Exp Med 205, 2281-2294.

  • Steinman, L. (2007). A brief history of T(H)17, the first major revision in the T(H)1/T(H)2 hypothesis of T cell-mediated tissue damage. Nat Med 13, 139-145.

  • Stritesky, G. L., Ych, N., and Kaplan. M. H. (2008). IL-23 promotes maintenance but not commitment to the Th17 lineage. J Immunol 181, 5948-5955.

  • Szabo, S. J., Sullivan, B. M., Stemmann, C., Satoskar, A. R., Sleckman, B. P., and Glimcher, L. H. (2002). Distinct effects of T-bet in TH1 lineage commitment and IFN-gamma production in CD4 and CD8 T cells. Science 295, 338-342.

  • Takeda, K., Tanaka, T., Shi, W., Matsumoto, M., Minami, M., Kashiwamura, S., Nakanishi, K., Yoshida. N., Kishimoto, T., and Akira. S. (1996). Essential role of Stat6 in IL-4 signalling. Nature 380, 627-630.

  • Thierfelder. W. E., van Deursen. J. M., Yamamoto, K., Tripp, R. A., Sarawar, S. R., Carson, R. T., Sangster, M. Y., Vignali, D. A., Doherty, P. C., Grosveld, G. C., and Elle, J. N. (1996). Requirement for Stat4 in interleukin-12-mediated responses of natural killer and T cells. Nature 382, 171-174.

  • Veldhoen, M., Hirota, K., Westendorf, A. M., Buer, J., Dumoutier, L., Renauld, J. C., and Stockinger. B. (2008). The aryl hydrocarbon receptor links TH17-cell-mediated autoimmunity to environmental toxins. Nature 453, 106-109.

  • Veldhoen, M., Hocking, R. J., Atkins, C. J., Locksley, R. M., and Stockinger, B. (2006). TGFbeta in the context of an inflammatory cytokine milieu supports de novo differentiation of IL-17-producing T cells. Immunity 24, 179-189.

  • Vermeire, K., Heremans, H., Vandeputte, M., Huang, S., Billiau, A., and Matthys, P. (1997). Accelerated collagen-induced arthritis in IFN-gamma receptor-deficient mice. J Immunol 158, 5507-5513.

  • Willenborg, D. O., Fordham, S., Bernard, C. C., Cowden, W. B., and Ramshaw, I. A. (1996). IFN-gamma plays a critical down-regulatory role in the induction and effector phase of myelin oligodendrocyte glycoprotein-induced autoimmune encephalomyelitis. J Immunol 157, 3223-3227.

  • Wright, H. L., Moots, R. J., and Edwards, S. W. (2014). The multifactoral role of neutrophils in rheumatoid arthritis. Nat Rev Rheumatol 10, 593-601.

  • Yamada, H., Nakashima, Y., Okazaki, K., Mawatari, T., Fukushi, J. I., Kaibara, N., Hori, A., Iwamoto, Y., and Yoshikai, Y. (2008). Th1 but not Th17 cells predominate in the joints of patients with rheumatoid arthritis. Ann Rheum Dis 67, 1299-1304.

  • Yang, X. O., Panopoulos, A. D., Nurieva, R., Chang, S. H., Wang, D., Watowich, S. S., and Dong, C. (2007a). STAT3 regulates cytokine-mediated generation of inflammatory helper T cells. The Journal of biological chemistry 282, 9358-9363.

  • Yang, X. O., Pappu, B. P., Nurieva, R., Akimzhanov, A., Kang. H. S., Chung, Y., Ma, L., Shah, B., Panopoulos, A. D., Schluns, K. S., et al. (2008). T helper 17 lineage differentiation is programmed by orphan nuclear receptors ROR alpha and ROR gamma. Immunity 28, 29-39.

  • Yang, X. P., Ghoreschi, K., Steward-Tharp, S. M., Rodriguez-Canales, J., Zhu, J., Grainger, J. R., Hirahara, K., Sun, H. W., Wei, L., Vahedi. G., et al. (2011). Opposing regulation of the locus encoding IL-17 through direct, reciprocal actions of STAT3 and STAT5. Nat Immunol 12, 247-254.

  • Yang, Y., Ochando, J. C., Bromberg, J. S., and Ding, Y. (2007b). Identification of a distant T-bet enhancer responsive to IL-12/Stat4 and IFNgamma/Stat1 signals. Blood 110, 2494-2500.

  • Yang, Y. H., and Hamilton. J. A. (2001). Dependence of interleukin-1-induced arthritis on granulocyte-macrophage colony-stimulating factor. Arthritis Rheum 44, 111-119.

  • Yao, Z., Cui, Y., Watford, W. T., Bream, J. H., Yamaoka, K., Hissong, B. D., Li, D., Durum, S. K., Jiang, Q., Bhandoola, A., et al. (2006). Stat5a/h are essential for normal lymphoid development and differentiation. Proc Natl Acad Sci USA 103, 1000-1005.

  • Zhang, G. X., Gran, B., Yu, S., Li. J., Siglienti, L., Chen, X., Kamoun, M., and Rostami, A. (2003). Induction of experimental autoimmune encephalomyelitis in IL-12 receptor-beta 2-deficient mice: IL-12 responsiveness is not required in the pathogenesis of inflammatory demyelination in the central nervous system. J Immunol 170, 2153-2160.

  • Zhou, L., Ivanov, I I, Spolski, R., Min, R., Shenderov, K., Egawa, T., Levy, D. E., Leonard. W. J., and Littman. D. R. (2007). IL-6 programs T(H)-17 cell differentiation by promoting sequential engagement of the IL-21 and IL-23 pathways. Nature immunology 8, 967-974.

  • Zhu, J., and Paul, W. E. (2010). Peripheral CD4+ T-cell differentiation regulated by networks of cytokines and transcription factors. Immunological reviews 238, 247-262.



While this invention has been particularly shown and described with references to example embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the scope of the invention encompassed by the appended claims.

Claims
  • 1.-33. (canceled)
  • 34. A method of treating an inflammatory disease associated with a TNF-α-independent inflammatory pathway, comprising administering to a subject in need thereof an effective amount of a signal transducer and activator of transcription 5 (STAT5) inhibitor, wherein the inflammatory disease is mediated by granulocyte macrophage colony-stimulating factor (GM-CSF)-secreting T-helper (Th-GM) cells, wherein the STAT5 inhibitor reduces serum level of GM-CSF in the subject and thereby providing a therapeutic benefit to the subject in a TNF-α-independent manner.
  • 35. The method of claim 34, wherein the inflammatory disease is rheumatoid arthritis.
  • 36. The method of claim 34, wherein the inflammatory disease is multiple sclerosis.
  • 37. The method of claim 34, wherein the TH-GM cells are differentiated from precursor CD4+ cells in the presence of activated STAT5 and IL-7.
  • 38. The method of claim 34, wherein the STAT5 inhibitor is pimozide.
  • 39. The method of claim 34, wherein the STAT5 inhibitor is CAS 285986-31-4.
  • 40. The method of claim 34, wherein the STAT5 inhibitor is an antibody that specifically binds to STAT5.
  • 41. The method of claim 34, wherein the STAT5 inhibitor is an antisense nucleic acid, small interfering RNA, short hairpin RNA, or microRNA.
  • 42. A method of treating rheumatoid arthritis, comprising administering to a subject in need thereof an effective amount of (A) a STAT5 inhibitor and (B) a therapeutic agent that inhibits the TNF-α inflammatory pathway.
  • 43. The method of claim 42, wherein the STAT5 inhibitor is pimozide.
  • 44. The method of claim 42, wherein the STAT5 inhibitor is CAS 285986-31-4.
  • 45. The method of claim 42, wherein the STAT5 inhibitor is an antibody that specifically binds to STAT5.
  • 46. The method of claim 42, wherein the STAT5 inhibitor is an antisense nucleic acid, small interfering RNA, short hairpin RNA, or microRNA.
  • 47. The method of claim 42, wherein the therapeutic agent that inhibits the TNF-α inflammatory pathway is an etanercept, adalimumab, infliximab, golimumab, or certolizumab pegol.
  • 48. The method of claim 42, wherein the therapeutic agent that inhibits the TNF-α inflammatory pathway is prednisone, methotrexate, or tofacitinib.
  • 49. The method of claim 42, Wherein the therapeutic agent that inhibits the TNF-α inflammatory pathway is anakinra, abatacept, rituximab, or tocilizumab.
  • 50. The method of claim 42, wherein (A) and (B) are administered sequentially.
  • 51. The method of claim 42, wherein (A) and (B) are administered simultaneously.
  • 52. The method of claim 42, wherein (A) and (B) are administered in a single dose.
Priority Claims (1)
Number Date Country Kind
10201406130P Sep 2014 SG national
Continuations (1)
Number Date Country
Parent 15514644 Mar 2017 US
Child 16902189 US