TSLP conditions the lung immune environment for the generation of pathogenic innate and antigen-specific adaptive immune responses.

Thymic stromal lymphopoietin (TSLP) is crucial for the development of atopic diseases in humans and mice. Mice that express a lung-specific TSLP transgene (surfactant protein C promoter (SPC)-TSLP) develop a spontaneous and progressive asthma-like disease, suggesting that TSLP expression alone was sufficient for disease development. In this study, we show that, in fact, TSLP alone only causes a weak innate response that is insufficient for development of full airway inflammatory disease. Complete disease development requires both TSLP and antigenic stimulation. These data suggest that the spontaneous lung inflammation observed in SPC-TSLP mice reflects a TSLP-driven predisposition toward the development of aberrant responses against innocuous environmental Ags. This provides evidence that TSLP may act directly to induce susceptibility to the inappropriate allergic responses that characterize atopy and asthma. We additionally show that disease development requires CD4 T cells but not B cells. Further, we reveal a TSLP-driven innate response involving mucus overproduction and goblet cell metaplasia. Taken together, these data suggest a multifaceted model of TSLP-mediated airway inflammation, with an initial activation of resident innate immune cells, followed by activation of the adaptive immune system and full disease development. This study provides new insight into the unique features of the asthma pathology contributed by the innate and adaptive immune responses in response to TSLP stimulation.

Reversal of thymic stromal lymphopoietin-induced airway inflammation through inhibition of Th2 responses.

Lung-specific thymic stromal lymphopoietin (TSLP) expression is sufficient for the development of an asthma-like chronic airway inflammatory disease. However, the nature of the downstream pathways that regulate disease development are not known. In this study, we used IL-4- and Stat6-deficient mice to establish the role of Th2-type responses downstream of TSLP. IL-4 deficiency greatly reduced, but did not eliminate, TSLP-induced airway hyperresponsiveness, airway inflammation, eosinophilia, and goblet cell metaplasia, while Stat6 deficiency eliminated these asthma-like symptoms. We further demonstrate, using the chronic model of TSLP-mediated airway inflammation, that blockade of both IL-4 and IL-13 responses, through administration of an anti-IL-4R alpha mAb, reversed asthma-like symptoms, when given to mice with established disease. Collectively these data provide insight into the pathways engaged in TSLP-driven airway inflammation and demonstrate that simultaneous blockade of IL-4 and IL-13 can reverse established airway disease, suggesting that this may be an effective approach for the therapy of Th2-mediated inflammatory respiratory disease.

Local increase in thymic stromal lymphopoietin induces systemic alterations in B cell development.

The cytokine thymic stromal lymphopoietin (TSLP) drives immature B cell development in vitro and may regulate T helper type 2 responses. Here we analyzed the involvement of TSLP in B cell development in vivo with a doxycycline-inducible, keratin 5-driven transgene encoding TSLP (K5-TSLP). K5-TSLP-transgenic mice given doxycycline showed an influx of immature B cells into the periphery, with population expansion of follicular mature B cells, near-complete loss of marginal zone and marginal zone precursor B cells, and 'preferential' population expansion of peritoneal B-1b B cells. These changes promoted cryoglobulin production and immune complex-mediated renal disease. Identical events occurred in mice without T cells, in alternative TSLP-transgenic models and in K5-TSLP-transgenic mice with undetectable systemic TSLP. These observations suggest that signals mediating localized TSLP expression may modulate systemic B cell development and promote humoral autoimmunity.