The Effect of Prenatal Stress on a Mouse Model of Allergic Airway Disease

Chau, Jessie T.

04 1900

<p>Prenatal life events have been long observed to be able to influence disease into adulthood in both epidemiological and animal studies. Prenatal stress (maternal stress during gestation) is one of such factors that has been shown to impact cognition and behaviour of the offspring. However, the effects of prenatal stress on the immune system are not understood. This study has evaluated the effects of prenatal stress on a murine model. Prenatal stress increased allergic airway inflammation in male, but not female offspring following sensitization and challenge with cockroach extract. This corresponded with stress-induced changes in the immune environment of non-sensitized animals. These changes included a decrease in regulatory T cells at baseline in males compared to non-stressed controls and increased splenic dendritic cell percentage and cytokine, particularly IFN-γ, secretion compared to prenatally stressed females. In females, prenatal stress decreased allergic inflammation, which corresponded to a decreased percentage of dendritic cells in the lung and mesenteric lymph node. Prenatal stress did not affect dendritic cell antigen presentation in ether male or female offspring. There was no evidence to suggest a prenatal stress induced change in glucocorticoid sensitivity of dendritic cells. In order to explore the possibility of prenatal stress induced decrease of parasympathetic output, a vagotomy model was used as a proof of concept in naïve animals not exposed to prenatal stress. Vagal modulation of dendritic cell phenotype and function was assessed. While there was some evidence that vagotomy may indirectly modulate dendritic cell function, its effects on the immune system were different then the changes caused by prenatal stress and thus it is a role of reduced parasympathetic output was not supported. Overall this data indicates a role of prenatal stress on the immune system with clear sex differences, but the mechanism for how this occurs is currently unknown. Further research is needed to investigate the role of TLRs and IFN-γ in this model, as well as other possible mediators of prenatal stress such as the changes to the parasympathetic nervous system that may in turn mediate alterations to the immune system. Differences in when the effects of prenatal stress are expressed during postnatal life are discussed.</p> / Master of Science (MSc)

Prenatal Stress

Allergic Airway Disease

Mouse Model

Immunopathology

Medical Immunology

Immunopathology

Development and stability of IL-17-secreting T cells

Glosson, Nicole L.

January 2014

Indiana University-Purdue University Indianapolis (IUPUI) / IL-17-producing T cells are critical to the development of pathogen and tumor immunity, but also contribute to the pathology of autoimmune diseases and allergic inflammation. CD8+ (Tc17) and CD4+ (Th17) IL-17-secreting T cells develop in response to a cytokine environment that activates Signal Transducer and Activator of Transcription (STAT) proteins, though the mechanisms underlying Tc17/Th17 development and stability are still unclear. In vivo, Tc17 cells clear vaccinia virus infection and acquire cytotoxic potential, that is independent of IL-17 production and the acquisition of IFN-γ-secreting potential, but partially dependent on Fas ligand, suggesting that Tc17-mediated vaccinia virus clearance is through cell killing independent of an acquired Tc1 phenotype. In contrast, memory Th cells and NKT cells display STAT4-dependent IL-23-induced IL-17 production that correlates with Il23r expression. IL-23 does not activate STAT4 nor do other STAT4-activating cytokines induce Il23r expression in these populations, suggesting a T cell-extrinsic role for STAT4 in mediating IL-23 responsiveness. Although IL-23 is important for the maintenance of IL-17-secreting T cells, it also promotes their instability, often resulting in a pathogenic Th1-like phenotype in vitro and in vivo. In vitro-derived Th17 cells are also flexible when cultured under polarizing conditions that promote Th2 or Th9 differentiation, adopting the respective effector programs, and decreasing IL-17 production. However, in models of allergic airway disease, Th17 cells do not secrete alternative cytokines nor adopt other effector programs, and remain stable IL-17-secretors. In contrast to Th1-biased pro-inflammatory environments that induce Th17 instability in vivo, during allergic inflammatory disease, Th17 cells are comparatively stable, and retain the potential to produce IL-17. Together these data document that the inflammatory environment has distinct effects on the stability of IL-17-secreting T cells in vivo.

Anti-inflammatory agents

Inflammation -- Immunological aspects

Respiratory allergy

T cells -- Immunology

Interleukins -- Immunology

Asthma -- Pathophysiology

Th1 cells -- Research

Th2 cells -- Research

Cellular immunity

Immune response -- Regulation

Cellular control mechanisms