Low-Dose Lipopolysaccharide Protects from Lethal Paramyxovirus Infection in a Macrophage- and TLR4-Dependent Process.

Respiratory diseases are a major public health burden and a leading cause of death and disability in the world. Understanding antiviral immune responses is crucial to alleviate morbidity and mortality associated with these respiratory viral infections. Previous data from human and animal studies suggested that pre-existing atopy may provide some protection against severe disease from a respiratory viral infection. However, the mechanism(s) of protection is not understood. Low-dose LPS has been shown to drive an atopic phenotype in mice. In addition, LPS has been shown in vitro to have an antiviral effect. We examined the effect of LPS treatment on mortality to the murine parainfluenza virus Sendai virus. Low-dose LPS treatment 24 h before inoculation with a normally lethal dose of Sendai virus greatly reduced death. This protection was associated with a reduced viral titer and reduced inflammatory cytokine production in the airways. The administration of LPS was associated with a marked increase in lung neutrophils and macrophages. Depletion of neutrophils failed to reverse the protective effect of LPS; however, depletion of macrophages reversed the protective effect of LPS. Further, we demonstrate that the protective effect of LPS depends on type I IFN and TLR4-MyD88 signaling. Together, these studies demonstrate pretreatment with low-dose LPS provides a survival advantage against a severe respiratory viral infection through a macrophage-, TLR4-, and MyD88-dependent pathway.

Immunopathology of Differing Viral Infection in Allergic Asthma Disease.

The pathophysiology of asthma development is heterogenous. Although complex interactions between factors are present in any one individual, early life viral infections have been shown to play a major role through induction of epithelial damage as well as various innate and adaptive immune responses. The cytokine profile that results from epithelial damage leads to Th2 skewing of the adaptive immune response. Most asthma exacerbations in children and up to half of adults are related to viral infections that also induce epithelial damage and an acute predominately Th2 inflammatory response, leading to acute symptoms and chronic airway remodeling.

Mouse Model of Sendai Virus-Induced Lung Disease.

Sendai virus (SeV), also known as the murine parainfluenza virus 1, is an enveloped negative-sense RNA paramyxovirus from the family Paramyxoviridae and genus Respirovirus. The virus was named after Sendai, city in Japan, where it was first isolated (Kuroya, Ishida, Yokohama Med Bull 4:217-233, 1953). Antigenically, SeV is closely related to human parainfluenza viruses 1 and 3. SeV is pneumotropic and naturally infects the respiratory tract of rodents. At the proper inoculum (2 × 105 pfu), SeV causes infection that is limited to the airway mucosa and inflammation mainly restricted to bronchiolar tissues as seen in asthma pathogenesis models using C57BL/6 wild-type mice (Walter et al, J Clin Invest 110:165-175, 2002). We utilize SeV to explore the mechanism(s) by which a respiratory viral infection translates into postviral airway disease in mice. This chapter primarily describes the protocols we use to infect mice in vivo, assay viral replication, and assess outcomes in the lungs of the host.

Atopic Neutrophils Prevent Postviral Airway Disease.

Respiratory syncytial virus (RSV) infection in infancy is associated with increased risk of asthma, except in those with allergic disease at the time of infection. Using house dust mite allergen, we examined the effect of pre-existing atopy on postviral airway disease using Sendai virus in mice, which models RSV infection in humans. Sendai virus drives postviral airway disease in nonatopic mice; however, pre-existing atopy protected against the development of airway disease. This protection depended upon neutrophils, as depletion of neutrophils at the time of infection restored the susceptibility of atopic mice to postviral airway disease. Associated with development of atopy was an increase in polymorphonuclear neutrophil-dendritic cell hybrid cells that develop in Th2 conditions and demonstrated increased viral uptake. Systemic inhibition of IL-4 reversed atopic protection against postviral airway disease, suggesting that increased virus uptake by neutrophils was IL-4 dependent. Finally, human neutrophils from atopic donors were able to reduce RSV infection of human airway epithelial cells in vitro, suggesting these findings could apply to the human. Collectively our data support the idea that pre-existing atopy derives a protective neutrophil response via potential interaction with IL-4, preventing development of postviral airway disease.

Epidemiology of Infections and Development of Asthma.

Asthma and allergic diseases have become more prevalent, although the reasons for this increase in disease burden are not known. Understanding why these diseases have become more common requires knowledge of the disease pathogenesis. Multiple studies have identified respiratory viral infections and atypical bacteria as potential etiologic agents underlying the development of asthma (and possibly allergies). This review discusses the epidemiology and potential mechanistic studies that provide links between these infectious agents and the development (and exacerbation) of asthma. These studies provide insight into the increase in disease prevalence and have identified potential targets for future therapeutic intervention.