Editor's Highlight: Role of Spleen-Derived Macrophages in Ozone-Induced Lung Inflammation and Injury.

Macrophages and inflammatory mediators have been implicated in ozone toxicity. In these studies, we used splenectomized (SPX) mice to assess the contribution of splenic monocytes to pulmonary inflammation and injury induced by ozone. Cells and tissue were collected 24-72 h after exposure of mice to air or ozone (0.8 ppm, 3 h). Following ozone exposure, increased numbers of pro-inflammatory CD11b + Ly6CHi and anti-inflammatory CD11b + Ly6CLo monocytes were observed in spleens of control (CTL) mice. CD11b + Ly6CHi and MMP-9+ pro-inflammatory macrophages were also observed in lungs of CTL mice after ozone, along with CD11b + Ly6CLo and mannose receptor (MR)+ anti-inflammatory macrophages. This was accompanied by increased lung expression of proteins involved in monocyte/macrophage trafficking including CCL3, CCL4, CCR1, and AT1R. Splenectomy resulted in decreases in pro-inflammatory macrophages in the lung and down regulation of CCR2, CCL2, and CCL4, but increases in CD11b + Ly6CLo anti-inflammatory macrophages. CD11b+Ly6G+Ly6C+ granulocytic (G)- and monocytic (M)-myeloid derived suppressor cells (MDSC)s were also detected in the lungs and spleens of CTL mice; these increased after ozone exposure. Splenectomy was associated with a decrease in G-MDSCs in the lung, with no effect on M-MDSCs. Changes in lung macrophage subpopulations and MDSCs in SPX mice were correlated with reduced ozone toxicity, as measured by decreases in bronchoalveolar lavage protein content and reduced 4-hydroxynonenal expression in the lung. These data suggest that the spleen is a source of pro-inflammatory/cytotoxic macrophages that contribute to ozone-induced lung injury, inflammation, and oxidative stress.

The spleen as an extramedullary source of inflammatory cells responding to acetaminophen-induced liver injury.

Macrophages have been shown to play a role in acetaminophen (APAP)-induced hepatotoxicity, contributing to both pro- and anti-inflammatory processes. In these studies, we analyzed the role of the spleen as an extramedullary source of hepatic macrophages. APAP administration (300mg/kg, i.p.) to control mice resulted in an increase in CD11b(+) infiltrating Ly6G(+) granulocytic and Ly6G(-) monocytic cells in the spleen and the liver. The majority of the Ly6G(+) cells were also positive for the monocyte/macrophage activation marker, Ly6C, suggesting a myeloid derived suppressor cell (MDSC) phenotype. By comparison, Ly6G(-) cells consisted of 3 subpopulations expressing high, intermediate, and low levels of Ly6C. Splenectomy was associated with increases in mature (F4/80(+)) and immature (F4/80(-)) pro-inflammatory Ly6C(hi) macrophages and mature anti-inflammatory (Ly6C(lo)) macrophages in the liver after APAP; increases in MDSCs were also noted in the livers of splenectomized (SPX) mice after APAP. This was associated with increases in APAP-induced expression of chemokine receptors regulating pro-inflammatory (CCR2) and anti-inflammatory (CX3CR1) macrophage trafficking. In contrast, APAP-induced increases in pro-inflammatory galectin-3(+) macrophages were blunted in livers of SPX mice relative to control mice, along with hepatic expression of TNF-α, as well as the anti-inflammatory macrophage markers, FIZZ-1 and YM-1. These data demonstrate that multiple subpopulations of pro- and anti-inflammatory cells respond to APAP-induced injury, and that these cells originate from distinct hematopoietic reservoirs.

Maternal immune stimulation during pregnancy shapes the immunological phenotype of offspring.

Epidemiological studies have associated infection during pregnancy with increased risk of neurodevelopmental disorders in children, which is modeled in rodents by stimulating the immune system of pregnant dams with microorganisms or their mimics, such as poly(I:C) or LPS. In two prenatal mouse models, we show that in utero exposure of the fetus to cytokines/inflammatory mediators elicited by maternal immune stimulation with poly(I:C) yields offspring that exhibit a proinflammatory phenotype due to alterations in developmental programming of their immune system. Changes in the innate and adaptive immune elements of these pro-inflammatory offspring result in more robust responses following exposure to immune stimuli than those observed in control offspring from PBS-injected pregnant dams. In the first model, offspring from poly(I:C)-injected immunologically naïve dams showed heightened cellular and cytokine responses 4 h after injection of zymosan, a TLR2 agonist. In the second model, using dams with immunological memory, poly(I:C) injection during pregnancy produced offspring that showed preferential differentiation toward Th17 cell development, earlier onset of clinical symptoms of EAE, and more severe neurological deficits following immunization with MOG35-55. Such "fetal programming" in offspring from poly(I:C)-injected dams not only persists into neonatal and adult life, but also can have profound consequences on health and disease.

Maternal immune stimulation during pregnancy affects adaptive immunity in offspring to promote development of TH17 cells.

Behavioral abnormalities in offspring of murine dams that receive immune stimulation with (poly)I:C during pregnancy are well-documented. In this prenatal model, (poly)I:C-induced maternal cytokines, particularly IL-6, appear involved in the etiology of the behavioral abnormalities. While much has been published on the abnormal behaviors of offspring in this model, much less is known about how maternal immune stimulation affects the adaptive immune system of the offspring, and its possible role in the observed pathophysiology. In the present study, pregnant dams were stimulated with (poly)I:C at E12, and 24h later cytokine levels were measured in maternal sera and amniotic fluids. Lymphocytes from offspring were also analyzed for T Helper (TH) cell subsets. The results demonstrate that lymphocytes from offspring of pregnant dams stimulated with (poly)I:C develop into TH17 cells upon in vitro activation. This preferential TH17 cell differentiation occurs in offspring of pregnant dams with an immunological "memory" phenotype, but not in offspring of immunologically "naive" dams. Comparable levels of IL-6 were found in the sera of immune and naïve pregnant dams, however, there was a disparity between levels of IL-6 in maternal sera and amniotic fluids of (poly)I:C-injected dams. In matings between IL-6 KO dams (IL-6-/-) and wild-type males (IL-6+/+) there was no IL-6 in sera from (poly)I:C-injected dams, but there were high levels of IL-6 in their amniotic fluids. Analysis of supernatants of cultured placental cell preparations from these IL-6 KO dams confirmed that the IL-6 was produced from the fetal (IL-6+/-) component, and heterozygous IL-6+/- offspring could also produce IL-6.

Preferential development of Th17 cells in offspring of immunostimulated pregnant mice.

Pregnant mice were stimulated at day 12 of gestation with the nucleotide poly(I:C). At 24h after stimulation, serum levels of maternal cytokines were measured, and at postnatal ages 2 and 3 weeks, offspring were analyzed for T helper (Th) cell subsets. Lymphocytes from offspring of poly(I:C)-injected (vs. control PBS-injected) pregnant dams preferentially developed into T helper 17 (Th17) cells upon in vitro activation. This occurred in offspring of pregnant dams who exhibited an immunological "memory" phenotype, but not in offspring of immunologically "naïve" dams. Preferential development of Th17 cells in these offspring may be facilitated by the higher levels of pro-inflammatory cytokines such as IL-6, found in immune vs. naïve pregnant dams. Murine immune stimulation during pregnancy is frequently used to model human neurological disorders, such as autism and schizophrenia. However, immune stimulation of women during pregnancy occurs in the context of an immunological "memory" phenotype, resulting from previous immunizations and/or natural exposure to micro-organisms and other antigens. Therefore, use of previously immunized female mice with a similar immunological memory phenotype to study maternal immune stimulation during pregnancy presents a more biologically relevant experimental strategy to investigate developmental, behavioral, and immunological sequelae of offspring in such rodent models.