CCL5/RANTES is a key proinflammatory chemokine produced by virus-infected epithelial cells and present in respiratory secretions of asthmatics. To examine the role of CCL5 in viral lung disease, we measured its production during primary respiratory syncytial virus (RSV) infection and during secondary infection after sensitizing vaccination that induces Th2-mediated eosinophilia. A first peak of CCL5 mRNA and protein production was seen at 18 to 24 h of RSV infection, before significant lymphocyte recruitment occurred. Treatment in vivo with Met-RANTES (a competitive chemokine receptor blocker) throughout primary infection decreased CD4؉ and CD8 ؉ cell recruitment and increased viral replication. In RSV-infected, sensitized mice with eosinophilic disease, CCL5 production was further augmented; Met-RANTES treatment again reduced inflammatory cell recruitment and local cytokine production. A second wave of CCL5 production occurred on day 7, attributable to newly recruited T cells. Paradoxically, mice treated with Met-RANTES during primary infection demonstrated increased cellular infiltration during reinfection. We therefore show that RSV induces CCL5 production in the lung and this causes the recruitment of RSV-specific cells, including those making additional CCL5. If this action is blocked with Met-RANTES, inflammation decreases and viral clearance is delayed. However, the exact effects of chemokine modulation depend critically on time of administration, a factor that may potentially complicate the use of chemokine blockers in inflammatory diseases.Bronchiolitis resulting from respiratory syncytial virus (RSV) infection is the single major cause of infant hospitalization in the developed world (25). It is characterized by excessive cell recruitment to the lung, leading to bronchiolar obstruction and sometimes ventilatory failure (24). RSV bronchiolitis is associated with the recurrent wheezing and asthma diagnosis in later childhood (33).CCL5 (RANTES) is a potent chemoattractant cytokine that recruits monocytes, T cells, and eosinophils, acting via the receptors CCR1, CCR3, and CCR5 (30). Infection of respiratory epithelial cells with RSV causes upregulation of CCL5 secretion (21) by NF-B translocation (39) and by increasing the stability of CCL5 mRNA (16), as does stimulation of epithelial cells with the Th1 cytokine gamma interferon (IFN-␥) (37). Children with RSV infections have increased CCL5 protein levels in both the upper and lower airway secretions, and levels of CCL5 in upper airway secretions correlate positively with disease severity (2, 9, 11, 36). In mice, CCL5 induction by RSV infection contributes to subsequent allergic pulmonary inflammation (14). CCL5 is a key chemokine in recruitment of CD8 T cells to the lung (6) and has been implicated in classical IFN-␥ dominant Th1 responses, and yet it is also involved in eosinophilic disease driven by Th2 cells (7,8,17,27).In mice, RSV infection can prime for Th1-or Th2-biased T-cell populations that control infection but also enhance inflammation upon su...
Understanding how immune challenges elicit different responses is critical for diagnosing and deciphering immune regulation. Using a modular strategy to interpret the complex transcriptional host response in mouse models of infection and inflammation, we show a breadth of immune responses in the lung. Lung immune signatures are dominated by either IFN-γ and IFN-inducible, IL-17-induced neutrophil- or allergy-associated gene expression. Type I IFN and IFN-γ-inducible, but not IL-17- or allergy-associated signatures, are preserved in the blood. While IL-17-associated genes identified in lung are detected in blood, the allergy signature is only detectable in blood CD4 + effector cells. Type I IFN-inducible genes are abrogated in the absence of IFN-γ signaling and decrease in the absence of IFNAR signaling, both independently contributing to the regulation of granulocyte responses and pathology during Toxoplasma gondii infection. Our framework provides an ideal tool for comparative analyses of transcriptional signatures contributing to protection or pathogenesis in disease.
Host defenses, while effecting viral clearance, contribute substantially to inflammation and disease. This double action is a substantial obstacle to the development of safe and effective vaccines against many agents, particularly respiratory syncytial virus (RSV). RSV is a common cold virus and the major cause of infantile bronchiolitis worldwide. The role of αβ T cells in RSV-driven immunopathology is well studied, but little is known about the role of “unconventional” T cells. During primary RSV challenge of BALB/c mice, some Vγ7+ γδ T cells were present; however, immunization with a live vaccinia vector expressing RSV F protein substantially enhanced Vγ4+ γδ T cell influx after RSV infection. Harvested early, these cells produced IFN-γ, TNF, and RANTES after ex vivo stimulation. By contrast, those recruited 5 days after challenge made IL-4, IL-5, and IL-10. Depletion of γδ T cells in vivo reduced lung inflammation and disease severity and slightly increased peak viral replication but did not prevent viral clearance. These studies demonstrate a novel role for γδ T cells in the development of immunopathology and cellular influx into the lungs after immunization and RSV challenge. Though a minor population, γδ T cells have a critical influence on disease and are an attractive interventional target in the alleviation of viral lung disease.
IL-9 is a cytokine of great current interest associated with allergic/Th2 responses. High levels of IL-9 are present in bronchial secretions from infants with respiratory syncytial virus (RSV) bronchiolitis. To test its effects in RSV disease with a Th2 profile, BALB/c mice were vaccinated with recombinant vaccinia virus expressing the RSV G protein. On RSV challenge, immunized mice developed augmented disease characterized by enhanced pulmonary Th2 and local IL-9 production peaking on days 7–10 of RSV infection. Depletion with anti-IL-9 Ab at vaccination or RSV challenge enhanced viral clearance. Depletion only at challenge had no effect on disease severity, whereas depletion at immunization and challenge enhanced Th1 responses, inhibited virus-specific IgG1 production, and enhanced disease severity. By contrast, depletion of IL-9 at immunization boosted IgG2a and inhibited the Th2 response and disease during subsequent infection without a concomitant increase in type 1 cytokines. Adoptive transfer of secondary memory CD4 T cells from the spleens of IL-9-depleted mice into naive recipients replicated many of the effects of depletion, indicating that IL-9 acts via CD4 T cells. Therefore, IL-9 is a previously unknown but key modulator of antiviral immunity, regulating T and B cell responses and having potent and specific effects on viral lung disease.
CD4-T-helper-cell (Th) differentiation is influenced by costimulatory molecules expressed on conventional dendritic cells (DCs) in regional lymph nodes and results in specific patterns of cytokine production. However, the function of costimulatory molecules on ‘inflammatory’ (CD11b+) DCs in the lung during recall responses is not fully understood, but important for development of novel interventions to limit immunopathological responses to infection. Using a mouse model in which vaccination with vaccinia virus vectors expressing the respiratory syncytial virus (RSV) fusion protein (rVVF) or attachment protein (rVVG) leads to type 1- or type 2-biased cytokine responses respectively upon RSV-challenge, we found expression of CD40 and OX40L on lung inflammatory DCs was higher in rVVF- than in rVVG-primed mice early after RSV-challenge, while the reverse was observed later in the response. Conversely, PD-L2 was higher in rVVG-primed mice throughout. Inflammatory DCs isolated at the resolution of inflammation revealed OX40L on type 1-biased DCs promoted IL-5, while on type 2-biased DCs enhanced IFNγ production by antigen-reactive Th cells. In contrast, PD-L2 promoted IFNγ production irrespective of conditions, suppressing IL-5 only if expressed on type 1-biased DCs. Thus, OX40L and PD-L2 expressed on DCs differentially regulate cytokine production during recall responses in the lung. Manipulation of these costimulatory pathways may provide a novel approach to controlling pulmonary inflammatory responses.
A role for interleukin-21 (IL-21) has recently been found in several diseases, but contribution to mucosal defences has not been described. In BALB/c mice infected with respiratory syncytial virus (RSV), IL-21 depletion had little effect in primary infection. However, depletion of mice during priming with recombinant vaccinia expressing RSV G protein (which primes RSV-specific T helper type 2 cells and causes lung eosinophilia during RSV infection) further exacerbated pathology during RSV challenge, with reduced viral clearance and impaired virus-specific serum antibody responses. This enhancement was accompanied by lymphocyte, neutrophil, and antigen-presenting cell recruitment to the lungs, with increased bronchoalveolar lavage interferon-γ and IL-17 levels. Adoptive transfer of splenic CD4 T cells from depleted mice into naive recipients replicated these effects, indicating that IL-21 mediates its effects via CD4 T cells. Endogenous IL-21, therefore, has potent and specific effects on mucosal antiviral responses, assisting viral clearance, regulating pulmonary T- and B-cell responses, and inhibiting IL-17 production.
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