Stat 6-dependent induction of myeloid derived suppressor cells after physical injury regulates nitric oxide response to endotoxin.

OBJECTIVE: To delineate the role of T-helper 2 (Th2) cytokines in the induction of trauma induced myeloid suppressor cells (TIMSC) and the regulation of nitric oxide production. BACKGROUND: Trauma induces myeloid cells that express CD11b+/Gr1+ and arginase 1 and exhibit an immune suppressing activity. This article explores the mechanisms that induce TIMSC and the effects on nitric oxide production in response to endotoxin. METHODS: TIMSC were studied in response to Th2 cytokines and a subsequent challenge to endotoxin. The role of Th2 cytokines was studied in STAT6-/- mice. Accumulation of TIMSC in spleens was studied using flow cytometry and immunhistochemistry. Plasma was recovered to measure accumulation of nitric oxide metabolites. RESULTS: TIMSC accumulated in the spleen of injured mice and were particularly sensitive to IL-4 and IL-13 with large inductions of arginase activity. Significant blunting in both the accumulation of TIMSC in the spleen and induction of arginase 1 was observed in STAT6-/- mice after physical injury. Accumulation of nitric oxide metabolites to endotoxin was observed in STAT6-/- mice. CONCLUSION: This study shows that induction of CD11b+/Gr1+ cells after physical injury play an essential role in the regulation of nitric oxide production after a septic challenge. The accumulation and induction of arginase 1 in TIMSC is Th2 cytokine dependent. To our knowledge, the role of TIMSC in the regulation of nitric oxide is a novel finding. This observation adds to the possibility that TIMSC could play an important role in immunosuppression observed after physical injury.

Nature of myeloid cells expressing arginase 1 in peripheral blood after trauma.

BACKGROUND: Myeloid cells that express arginase 1 are upregulated by different stimuli, including trauma, and are capable of depleting arginine from the surrounding environment. Through arginine depletion, myeloid cells are capable of regulating T-cell function. We have previously reported increased arginase 1 expression in the peripheral blood mononuclear cells (PBMCs) after injury. The nature of the cells expressing arginase in humans after trauma is unknown and is the focus of this article. METHODS: PBMCs were isolated using a Ficoll-Hypaque gradient. Arginase activity was measured by conversion of arginine to ornithine, and arginase 1 protein expression was measured by Western blot. The percent CD16 granulocytes and phenotypical analysis of the cells present in PBMCs were determined by flow cytometry. Magnetic microbeads were used for isolation and exclusion of specific cell subpopulations. RESULTS: Trauma patients exhibited a dramatic increase in arginase activity (p < 0.05) and an increased percentage of CD16 granulocytes in the PBMC layer (p < 0.05) compared with control volunteers. Increased arginase activity in the PBMC layer was due to the contamination of this layer by granulocytes, as their exclusion decreased arginase activity back to baseline (p < 0.05). Granulocytes isolated from the PBMC layer expressed increased CD11b (p < 0.05) and CD66b (p < 0.05), markers of granulocyte activation. Furthermore, these granulocytes were significantly more swollen and degranulated compared with noncontaminating granulocytes. CONCLUSION: In humans, increased arginase 1 expression after trauma observed in the PBMC layer seems to be exclusively the result of an increased number of activated granulocytes.

Effect of citrulline and glutamine on nitric oxide production in RAW 264.7 cells in an arginine-depleted environment.

BACKGROUND: Nitric oxide (NO) is a highly reactive free radical essential for antimicrobial and tumor immunity as well as endothelial function. Arginine is a limiting factor in NO synthesis. Citrulline can be converted to arginine and might restore NO production when arginine availability is limited, while glutamine may competitively inhibit citrulline availability. We aimed to assess how these amino acids interact to generate NO using an in vitro model. METHODS: RAW 264.7 cells were exposed to various amino acid concentrations before and after lipopolysaccharide (LPS) stimulation, and NO production was assessed. RESULTS: NO production directly correlated up to 200 microM with arginine available after LPS stimulation (R(2) = 0.99). Provided the same arginine concentrations following LPS stimulation, low arginine precultured cells produced significantly less NO than high arginine precultured cells (P < .01). Citrulline added to low arginine preculture significantly increased NO production compared to cells in low arginine alone (P < .01). When glutamine was withdrawn before and after LPS stimulation, cells precultured in low arginine and citrulline produced NO equivalent to that of high arginine precultured cells. Additional citrulline provided after LPS stimulation additionally improved NO production beyond that observed in cells precultured in high arginine (P < .01), and NO production became less dependent on arginine availability (R(2) = 0.78). CONCLUSION: Arginine availability is a limiting factor for NO production. Citrulline is a potential substitute to restore NO production when arginine availability is limited. Glutamine appears to be an important modulator that interferes with citrulline-mediated NO production.

Arginine and immunity.

For many years, dietary arginine supplementation, often combined with other substances, has been used as a mechanism to boost the immune system. Considerable controversy, however, exists as to the benefits and indications of dietary arginine due in part to a poor understanding of the role played by this amino acid in maintaining immune function. Emerging knowledge promises to clear this controversy and allow for arginine's safe use. In myeloid cells, arginine is mainly metabolized either by inducible nitric oxide (NO) synthases (iNOS) or by arginase 1, enzymes that are stimulated by T helper 1 or 2 cytokines, respectively. Thus, activation of iNOS or arginase (or both) reflects the type of inflammatory response in a specific disease process. Myeloid suppressor cells (MSC) expressing arginase have been described in trauma (in both mice and humans), intra-abdominal sepsis, certain infections, and prominently, cancer. Myeloid cells expressing arginase have been shown to accumulate in patients with cancer. Arginase 1 expression is also detected in mononuclear cells after trauma or surgery. MSC efficiently deplete arginine and generate ornithine. Through arginine depletion, MSC may control NO production and regulate other arginine-dependent biological processes. Low circulating arginine has been documented in trauma and cancer, suggesting that MSC may exert a systemic effect and cause a state of arginine deficiency. Simultaneously, T lymphocytes depend on arginine for proliferation, zeta-chain peptide and T-cell receptor complex expression, and the development of memory. T-cells cocultured with MSC exhibit the molecular and functional effects associated with arginine deficiency. Not surprisingly, T-cell abnormalities, including decreased proliferation and loss of the zeta-chain, are observed in cancer and after trauma.

High mobility group B1 protein suppresses the human plasmacytoid dendritic cell response to TLR9 agonists.

Plasmacytoid dendritic cells (PDC) are innate immune effector cells that are recruited to sites of chronic inflammation, where they modify the quality and nature of the adaptive immune response. PDCs modulate adaptive immunity in response to signals delivered within the local inflammatory milieu by pathogen- or damage-associated molecular pattern, molecules, and activated immune cells (including NK, T, and myeloid dendritic cells). High mobility group B1 (HMGB1) is a recently identified damage-associated molecular pattern that is released during necrotic cell death and also secreted from activated macrophages, NK cells, and mature myeloid dendritic cells. We have investigated the effect of HMGB1 on the function of PDCs. In this study, we demonstrate that HMGB1 suppresses PDC cytokine secretion and maturation in response to TLR9 agonists including the hypomethylated oligodeoxynucleotide CpG- and DNA-containing viruses. HMGB1-inhibited secretion of several proinflammatory cytokines including IFN-alpha, IL-6, TNF-alpha, inducible protein-10, and IL-12. In addition, HMGB1 prevented the CpG induced up-regulation of costimulatory molecules on the surface of PDC and potently suppressed their ability to drive generation of IFN-gamma-secreting T cells. Our observations suggest that HMGB1 may play a critical role in regulating the immune response during chronic inflammation and tissue damage through modulation of PDC function.