CD200fc enhances anti-tumoral immune response and inhibits visceral metastasis of breast carcinoma.

CD200 is a widely expressed cell surface glycoprotein that inhibits excessive inflammation in autoimmunity, transplantation, and viral infections. We previously observed that visceral metastasis of highly aggressive and inflammatory 4THM breast carcinoma cells was markedly decreased in CD200 transgenic mice. The goal of this study was to determine whether exogenous exposure to CD200fc mimics the effects of endogenously over expressed CD200. Female BALB/c mice were injected with CD200fc two times a week for five times. Injection was started two days after orthotopic injection of 4THM cells. Tumor infiltrating Gr1+Cd11b+ cells were decreased while CD8+ cells were increased in CD200fc-treated animals. CD200fc injection significantly decreased lung and liver metastasis and the growth of primary tumors. CD200fc injection enhanced the tumor-induced IFN-g response while suppressing the IL-10 response. We observed excessive basal IL-6 secretion in MLC which was significantly decreased in CD200fc treated mice 12 days after injection of 4TM cells. These results are in accord with previous data from CD200 transgenic mice, and demonstrate for the first time that CD200 analogues might have therapeutic potential in the treatment of aggressive breast carcinoma which induces excessive systemic inflammation.

Microenvironmental interleukin-6 suppresses toll-like receptor signaling in human leukemia cells through miR-17/19A.

The regulation of toll-like receptor (TLR) signaling in a tumor microenvironment is poorly understood despite its importance in cancer biology. To address this problem, TLR7-responses of chronic lymphocytic leukemia (CLL) cells were studied in the presence and absence of a human stromal cell-line derived from a leukemic spleen. CLL cells alone produced high levels of tumor necrosis factor (TNF)-α and proliferated in response to TLR7-agonists. A signal transducer and activator of transcription 3 -activating stromal factor, identified as interleukin (IL)-6, was found to upregulate microRNA (miR)-17 and miR-19a, target TLR7 and TNFA messenger RNA, and induce a state of tolerance to TLR7-agonists in CLL cells. Overexpression of the miR-17-92 cluster tolerized CLL cells directly and miR-17 and miR-19a antagomiRs restored TLR7-signaling. Inhibition of IL-6 signaling with antibodies or small-molecule Janus kinase inhibitors reversed tolerization and increased TLR7-stimulated CLL cell numbers in vitro and in NOD-SCIDγc (null) mice. These results suggest IL-6 can act as tumor suppressor in CLL by inhibiting TLR-signaling.

PPARα and fatty acid oxidation mediate glucocorticoid resistance in chronic lymphocytic leukemia.

High-dose glucocorticoids (GCs) can be a useful treatment for aggressive forms of chronic lymphocytic leukemia (CLL). However, their mechanism of action is not well understood, and resistance to GCs is inevitable. In a minimal, serum-free culture system, the synthetic GC dexamethasone (DEX) was found to decrease the metabolic activity of CLL cells, indicated by down-regulation of pyruvate kinase M2 (PKM2) expression and activity, decreased levels of pyruvate and its metabolites, and loss of mitochondrial membrane potential. This metabolic restriction was associated with decreased size and death of some of the tumor cells in the population. Concomitant plasma membrane damage increased killing of CLL cells by DEX. However, the nuclear receptor peroxisome proliferator activated receptor α (PPARα), which regulates fatty acid oxidation, was also increased by DEX, and adipocyte-derived lipids, lipoproteins, and propionic acid protected CLL cells from DEX. PPARα and fatty acid oxidation enzyme inhibitors increased DEX-mediated killing of CLL cells in vitro and clearance of CLL xenografts in vivo. These findings suggest that GCs prevent tumor cells from generating the energy needed to repair membrane damage, fatty acid oxidation is a mechanism of resistance to GC-mediated cytotoxicity, and PPARα inhibition is a strategy to improve the therapeutic efficacy of GCs.

Ectodomain shedding of CD200 from the B-CLL cell surface is regulated by ADAM28 expression.

CD200, a membrane glycoprotein of the immunoglobulin superfamily, is overexpressed in CLL. Soluble in serum CD200 (sCD200) is correlated with poor prognosis in CLL. ADAM (a disintegrin and metalloproteinase) enzymes are implicated in membrane protein shedding. ADAM28 mRNA expression in CLL was correlated with plasma sCD200 levels, and release into culture from CLL cells. siRNA for ADAM28 decreased release of sCD200 from cultures and transfection of a cloned ADAM28 gene into CD200(+) cells enhanced release of sCD200. Our data support the hypothesis that ADAM28 plays a role in the shedding of CD200 from B-cell CLL cells.

A comparison of the biological properties of small molecular weight agonists and antagonists of CD200:CD200R interactions.

Our laboratory and others have documented in some detail the immunological consequences which follow from interaction of the ubiquitously expressed molecule CD200 with its receptor(s) CD200R (expressed predominantly on cells of myeloid and lymphoid origin). In particular, there is evidence that these interactions lead to immunosuppressive signals which modulate graft rejection responses; decrease the manifestations of arthritis in rodent models; diminish mast cell mediator release in models of allergic disease; and favour the growth of tumors in both mice and humans. The development of small molecular weight agonists (and/or antagonists) of these interactions would thus likely have significant clinical importance. The data reported herein characterizes several such molecules in a number of rodent models.

An interaction between CD200 and monoclonal antibody agonists to CD200R2 in development of dendritic cells that preferentially induce populations of CD4+CD25+ T regulatory cells.

In previous studies we reported that while interaction between the relatively ubiquitously expressed molecule CD200 and one of its receptors, CD200R1, resulted in direct suppression of alloreactivity, engagement of alternate receptors led instead to altered differentiation of dendritic cells (DCs) from marrow precursors, which could in turn foster development of Foxp3(+) regulatory T cells. We have explored this effect of engagement of alternate receptors by using a monoclonal agonist Ab to CD200R2 and investigating expression of TLRs on DCs induced in vivo and in vitro after CD200 stimulation in mice in which the gene encoding CD200R1 was deleted. CD200 stimulation was achieved by using either a soluble form of CD200 (CD200Fc) or overexpression of CD200 as a doxycycline-inducible transgene. Although broadly similar effects were seen, consistent with the hypothesis that triggering of CD200R2 does produce DCs with a characteristic TLR repertoire, there are subtle differences in suppression of alloreactivity achieved by CD200 delivered in these two manners, which is consistent with a complexity of CD200:CD200R engagement not previously appreciated.

Peptides of CD200 modulate LPS-induced TNF-alpha induction and mortality in vivo.

Interaction of the ubiquitously expressed molecule CD200 with its receptor(s) CD200R, expressed on cells of myeloid and lymphoid origin, delivers immunoregulatory signals that modulate inflammation in a number of diseases, including transplant rejection and arthritis. A number of isoforms of CD200R have been described in mice with distinct function. We have synthesized small (9-13 mer) peptides defining distinct regions of CD200, and asked whether different peptides would function as agonists and/or antagonists of different CD200R isoforms. The assays used to characterize these functions include a model of inflammation and tumor necrosis factor-alpha production induced following lipopolysaccharide administration in vivo, and mixed leukocyte cultures in vitro. Discrete agonist and antagonist peptides were defined for different CD200Rs, which suggests this approach may have some clinical utility.

Mice lacking CD200R1 show absence of suppression of lipopolysaccharide-induced tumor necrosis factor-alpha and mixed leukocyte culture responses by CD200.

BACKGROUND: CD200:CD200R interactions deliver immunoregulatory signals. A family of CD200Rs (CD200R1-5) has been described, and engagement of CD200R1 by its ligand CD200 suppresses LPS-induced macrophage cytokine production, decreases alloimmune responses in vivo and in vitro, and suppresses collagen-induced arthritis. METHODS: We generated C57BL/6 mice lacking the genomic exons encoding the extracellular domains of the CD200R1 molecule using transformation of ES cells and explored cell subtypes and immune responses in these mice. RESULTS: Myeloid cells/splenocytes from CD200R1(-/-) mice were not stained in FACS by anti-CD200R1 mAb. Stimulation of splenic tumor necrosis factor-alpha production by lipopolysaccharide was enhanced relative to control (+/+) mice and was not suppressed by addition of exogenous CD200Fc. Modulation of alloreactivity in mixed leukocyte cultures by CD200Fc depended upon CD200R1+ stimulatory cells, although maximal immunoregulation by CD200Fc occurred only when CD200R1+ T responder cells also were used. CD200Fc failed to suppress graft rejection in CD200R1(-/-) mice. CONCLUSION: CD200:CD200R1 plays an immunoregulatory role in vivo.