Chlamydia muridarum Lung Infection in Infants Alters Hematopoietic Cells to Promote Allergic Airway Disease in Mice

Background

Viral and bacterial respiratory tract infections in early-life are linked to the development of allergic airway inflammation and asthma. However, the mechanisms involved are not well understood. We have previously shown that neonatal and infant, but not adult, chlamydial lung infections in mice permanently alter inflammatory phenotype and physiology to increase the severity of allergic airway disease by increasing lung interleukin (IL)-13 expression, mucus hyper-secretion and airway hyper-responsiveness. This occurred through different mechanisms with infection at different ages. Neonatal infection suppressed inflammatory responses but enhanced systemic dendritic cell:T-cell IL-13 release and induced permanent alterations in lung structure (i.e., increased the size of alveoli). Infant infection enhanced inflammatory responses but had no effect on lung structure. Here we investigated the role of hematopoietic cells in these processes using bone marrow chimera studies.

Methodology/Principal Findings

Neonatal (<24-hours-old), infant (3-weeks-old) and adult (6-weeks-old) mice were infected with C. muridarum. Nine weeks after infection bone marrow was collected and transferred into recipient age-matched irradiated naïve mice. Allergic airway disease was induced (8 weeks after adoptive transfer) by sensitization and challenge with ovalbumin. Reconstitution of irradiated naïve mice with bone marrow from mice infected as neonates resulted in the suppression of the hallmark features of allergic airway disease including mucus hyper-secretion and airway hyper-responsiveness, which was associated with decreased IL-13 levels in the lung. In stark contrast, reconstitution with bone marrow from mice infected as infants increased the severity of allergic airway disease by increasing T helper type-2 cell cytokine release (IL-5 and IL-13), mucus hyper-secretion, airway hyper-responsiveness and IL-13 levels in the lung. Reconstitution with bone marrow from infected adult mice had no effects.

Conclusions

These results suggest that an infant chlamydial lung infection results in long lasting alterations in hematopoietic cells that increases the severity of allergic airway disease in later-life.     

T Cell Responses Are Required for Protection from Clinical Disease and for Virus Clearance in Severe Acute Respiratory Syndrome Coronavirus-Infected Mice

A dysregulated innate immune response and exuberant cytokine/chemokine expression are believed to be critical factors in the pathogenesis of severe acute respiratory syndrome (SARS), caused by a coronavirus (SARS-CoV). However, we recently showed that inefficient immune activation and a poor virus-specific T cell response underlie severe disease in SARS-CoV-infected mice. Here, we extend these results to show that virus-specific T cells, in the absence of activation of the innate immune response, were sufficient to significantly enhance survival and diminish clinical disease. We demonstrated that T cells are responsible for virus clearance, as intravenous adoptive transfer of SARS-CoV-immune splenocytes or in vitro-generated T cells to SCID or BALB/c mice enhanced survival and reduced virus titers in the lung. Enhancement of the number of virus-specific CD8 T cells by immunization with SARS-CoV peptide-pulsed dendritic cells also resulted in a robust T cell response, earlier virus clearance, and increased survival. These studies are the first to show that T cells play a crucial role in SARS-CoV clearance and that a suboptimal T cell response contributes to the pathological changes observed in SARS. They also provide a new approach to SARS vaccine design.Severe acute respiratory syndrome (SARS), caused by a novel coronavirus (SARS-CoV), resulted in over 8,000 cases of respiratory disease, with 10% mortality, in 2002 and 2003 (18). Patients with severe disease developed acute lung injury (ALI), concomitant with neutrophilia, lymphopenia, and prolonged expression of several proinflammatory cytokines (4, 17, 18, 32). Virus was cleared slowly from these patients and could be detected in respiratory secretions for as long as 21 days postinfection (p.i.) (14, 17).SARS has not recurred to a significant extent since 2003, so most studies have used animal infections to investigate the mechanism of severe disease. These studies have been facilitated by the isolation and characterization of SARS-CoV variants that cause severe respiratory disease in mice or rats after adaptation to these hosts by serial passage (15, 16, 22). One strain, isolated after 15 passages through the lungs of BALB/c mice, caused respiratory disease in young BALB/c mice (MA15 virus) (22). As in humans with severe disease, cytokine expression is elevated and prolonged in animals with severe disease, whether caused by the human Urbani or rodent-adapted strains of SARS-CoV, and is accompanied by delayed kinetics of virus clearance (1, 5, 15, 23, 26, 35). This elevated expression of proinflammatory mediators is believed to be a major contributory factor in the development of pneumonia and, subsequently, ALI.These studies did not address the role of the antivirus T cell response in disease. T cell responses are critical for virus clearance and protection from clinical disease in mice infected with other coronaviruses, such as mouse hepatitis virus (MHV) (31), or other pulmonary pathogens, such as influenza A virus or Sendai virus (7, 29). Although some studies using the Urbani strain showed that virus clearance was T cell independent (5, 34), mice infected with this strain develop only mild pneumonitis, so that the requirement for a virus-specific T cell response for protection in SARS-CoV-infected animals remains unclear.Young BALB/c mice infected with MA15 virus develop severe respiratory disease, with substantial mortality, dependent upon virus dosage (22). We recently showed that the pulmonary immune response is inefficiently activated in these mice at early times after infection, resulting in a barely detectable antivirus T cell response in mice with a lethal infection (35). Survival correlated with the development of a SARS-CoV-specific CD4 and CD8 T cell response. Poor activation of the immune response could be reversed by depletion of inhibitory alveolar macrophages with clodronate, a drug that depletes phagocytic cells (28, 30), or by treatment with poly(I-C) or CpG, both of which activate macrophages and dendritic cells (DCs). Disease could also be ameliorated by adoptive transfer of activated DCs, which are able to traffic to the lung draining lymph nodes (DLN) and prime the antivirus T cell response. These interventions effect two changes in the host immune response: they result in activation of the innate immune system and facilitate the development of a robust virus-specific T cell response. From these results, we could not determine the relative importance of these two limbs of the immune response in protection. Here, we examined whether a robust antivirus T cell response was sufficient to protect mice in the absence of interventions that activated the innate immune response. Our results indicate that virus-specific T cells are necessary and sufficient for virus clearance and for protection from clinical disease in MA15 virus-infected mice.     

Regulatory T Cells Prevent Th2 Immune Responses and Pulmonary Eosinophilia during Respiratory Syncytial Virus Infection in Mice

During viral infection, inflammation and recovery are tightly controlled by competing proinflammatory and regulatory immune pathways. Respiratory syncytial virus (RSV) is the leading global cause of infantile bronchiolitis, which is associated with recurrent wheeze and asthma diagnosis in later life. Th2-driven disease has been well described under some conditions for RSV-infected mice. In the present studies, we used the Foxp3^DTR mice (which allow specific conditional depletion of Foxp3⁺ T cells) to investigate the functional effects of regulatory T cells (Tregs) during A2-strain RSV infection. Infected Treg-depleted mice lost significantly more weight than wild-type mice, indicating enhanced disease. This enhancement was characterized by increased cellularity in the bronchoalveolar lavage (BAL) fluid and notable lung eosinophilia not seen in control mice. This was accompanied by abundant CD4⁺ and CD8⁺ T cells exhibiting an activated phenotype and induction of interleukin 13 (IL-13)- and GATA3-expressing Th2-type CD4⁺ T cells that remained present in the airways even 14 days after infection. Therefore, Treg cells perform vital anti-inflammatory functions during RSV infection, suppressing pathogenic T cell responses and inhibiting lung eosinophilia. These findings provide additional evidence that dysregulation of normal immune responses to viral infection may contribute to severe RSV disease.     

Role of Interferon Regulatory Factor 7 in T Cell Responses during Acute Lymphocytic Choriomeningitis Virus Infection

Type I interferons (IFNs), predominantly IFN-α and -β, play critical roles in both innate and adaptive immune responses against viral infections. Interferon regulatory factor 7 (IRF7), a key innate immune molecule in the type I IFN signaling pathway, is essential for the type I IFN response to many viruses, including lymphocytic choriomeningitis virus (LCMV). Here, we show that although IRF7 knockout (KO) mice failed to control the replication of LCMV in the early stages of infection, they were capable of clearing LCMV infection. Despite the lack of type I IFN production, IRF7 KO mice generated normal CD4⁺ T cell responses, and the expansion of naïve CD8⁺ T cells into primary CD8⁺ T cells specific for LCMV GP_33–41 was relatively normal. In contrast, the expansion of the LCMV NP₃₉₆-specific CD8⁺ T cells was severely impaired in IRF7 KO mice. We demonstrated that this defective CD8⁺ T cell response is due neither to an impaired antigen-presenting system nor to any intrinsic role of IRF7 in CD8⁺ T cells. The lack of a type I IFN response in IRF7 KO mice did not affect the formation of memory CD8⁺ T cells. Thus, the present study provides new insight into the impact of the innate immune system on viral pathogenesis and demonstrates the critical contribution of innate immunity in controlling virus replication in the early stages of infection, which may shape the quality of CD8⁺ T cell responses.     

Lupus-Prone Mice Fail to Raise Antigen-Specific T Cell Responses to Intracellular Infection

Systemic lupus erythematosus (SLE) is characterized by multiple cellular abnormalities culminating in the production of autoantibodies and immune complexes, resulting in tissue inflammation and organ damage. Besides active disease, the main cause of morbidity and mortality in SLE patients is infections, including those from opportunistic pathogens. To understand the failure of the immune system to fend off infections in systemic autoimmunity, we infected the lupus-prone murine strains B6.lpr and BXSB with the intracellular parasite Toxoplasma gondii and survival was monitored. Furthermore, mice were sacrificed days post infection and parasite burden and cellular immune responses such as cytokine production and cell activation were assessed. Mice from both strains succumbed to infection acutely and we observed greater susceptibility to infection in older mice. Increased parasite burden and a defective antigen-specific IFN-gamma response were observed in the lupus-prone mice. Furthermore, T cell:dendritic cell co-cultures established the presence of an intrinsic T cell defect responsible for the decreased antigen-specific response. An antigen-specific defect in IFN- gamma production prevents lupus-prone mice from clearing infection effectively. This study reveals the first cellular insight into the origin of increased susceptibility to infections in SLE disease and may guide therapeutic approaches.     

Acute and Chronic Airway Disease After Human Respiratory Syncytial Virus Infection in Cotton Rats (Sigmodon hispidus)

Infection with respiratory syncytial virus (RSV) generally presents as a mild, upper airway disease in human patients but may cause severe lower airway disease in the very young and very old. Progress toward understanding the mechanisms of RSV pathogenesis has been hampered by a lack of relevant rodent models. Mice, the species most commonly used in RSV research, are resistant to upper respiratory infection and do not recapitulate the pattern of virus spread in the human host. To address the need for better rodent models of RSV infection, we have characterized the acute and chronic pathology of RSV infection of a relatively permissive host, cotton rats (Sigmodon hispidus). We demonstrate that virus delivered to the upper airway results in widespread RSV replication in the ciliated respiratory epithelial cells of the nasal cavity and, to a lesser extent, of the lung. Although acute inflammation is relatively mild and rapidly eliminated after viral clearance, chronic, eosinophilic lung pathology persists. These data support the use of cotton rats as a robust rodent model of human RSV disease, including the association between RSV pneumonia and subsequent development of allergic asthma.Abbreviations: BAL, bronchoalveolar lavage; RSV, human respiratory syncytial virusHuman respiratory syncytial virus (RSV) is the primary cause of lower airway disease in infants and children worldwide.³⁹ Although generally limited to the upper airway, RSV infection can also manifest as bronchiolitis and pneumonia in young children and the elderly and has been implicated as a major cause of middle ear infections (otitis media).^3,55 In addition to the problems associated with acute illness, children who experience severe RSV disease in infancy are at increased risk for development of asthma and recurrent wheezing later in childhood.^35,53,56RSV is ubiquitous worldwide, with most children infected in infancy, and essentially all children are infected by 3 y of age.²⁰ Although reinfection throughout life has been documented, the true incidence of upper airway infection is difficult to quantify, given that treatment for such infections typically is not sought. In comparison, lower airway infection is more likely to come to medical attention, and it is currently estimated that at least 33.8 million episodes of RSV-induced acute pulmonary infection in children younger than 5 y occur yearly and that as many as 200,000 of those episodes are fatal.⁴⁰ Although supportive treatment for severe RSV disease is highly effective in infants, access to such treatment is generally only available in industrialized countries. More than 90% of fatal RSV cases occur in the developing world.⁴⁰Mice have been used extensively to study RSV infection, yet there are key limitations of the mouse model for the study of human RSV disease and immunity. The most important of these is the poor permissiveness of the mouse for human RSV. RSV replicates to a limited extent in the mouse lung, and large viral loads delivered in a relatively large volume are generally used with this model. Even with intranasal inoculation, primarily lower, and not upper, airway infection is achieved in WT mice. This scenario is unlike the human disease, in which the upper airway is the primary target of RSV replication.^24,25 Mice are essentially resistant to upper airway infection, with little to no virus detected in nasal washes evaluated by plaque assay, and only rare RSV-antigen–positive cells are detected by immunohistochemistry.^13,18,21 In addition to this altered route of entry, the pattern of lung infection is markedly divergent between humans and mice. In humans, RSV primarily infects ciliated bronchiolar epithelial cells and, to a much lesser extent, alveolar cells.³² In contrast, bronchiolar epithelial cells are infected only rarely in the mouse lung; instead RSV targets the pneumocytes.³⁷Unlike mice, cotton rats are susceptible to RSV infection of the upper airway, and the pattern of lower airway infection mirrors that seen in human patients. The cotton rat was established as a model of RSV infection more than 3 decades ago and has since emerged as the preferred rodent model in which to evaluate RSV therapeutics and vaccine candidates.^{19,23,33,41,49,57,60} In addition, as the availability of species-specific reagents has improved, cotton rats have become an increasingly useful model in which to study RSV pathogenesis.⁶ However, whereas the susceptibility of cotton rats to RSV infection has been established firmly, the pathology of RSV infection in this species has not yet been extensively characterized.Asthma clearly is a multifactorial disease, dependent on both genetic and environmental factors (see references 28 and 30 for recent reviews), and many studies have pointed to a role for respiratory virus infection in the induction of asthma. In one study,¹⁷ the combination of atopy and the presence of virus in nasal secretions synergistically increased the odds ratio for wheezing in children 25-fold, and another study²⁹ showed that repeated rhinovirus infections in the first 3 y of life increased by 26-fold the risk of developing asthma by the age of 6 y. This relationship is obviously a complex one, influenced both by the nature and the timing of the viral infection. Nonetheless, as many as 80% of acute asthma exacerbations in children and approximately 50% in adults are associated with viral infection.^33,42 The majority of these infections are attributed to rhinoviruses, but other respiratory viruses, including influenza virus, RSV, and coronaviruses, can provoke these attacks.^33,42 Beyond the exacerbation of established asthma, evidence that severe RSV disease in infancy is correlated with development of asthma and recurrent wheezing in later childhood is mounting. An association between lower airway RSV infection and subsequent development of recurrent wheezing and asthma was demonstrated more than 30 y ago,¹⁶ and several recent prospective studies have strengthened this correlation.^27,53In the current study, we expand upon existing knowledge of the cotton rat model of RSV infection by characterizing the spread of virus after droplet inhalation and the early and late inflammatory response to viral challenge. We confirm the observation that cotton rats are relatively permissive in regard to RSV infection as compared with mice, and we demonstrate that the infection of cotton rats, like that in the human host, is primarily an upper airway phenomenon. In addition, we show that primary RSV infection of the cotton rat lung, even at the low levels in this study, induces chronic changes consistent with those in cases of human allergic asthma. This finding is of interest because of the substantial literature associating early, severe respiratory infection with the development of asthma later in life. The studies of RSV infection in cotton rats that we describe here suggest that this species may be predisposed to atopy and that, long after virus clearance, changes associated with allergic inflammation persist in human hosts. Therefore, in addition to the usefulness of cotton rats for testing RSV treatments and vaccine candidates, we suggest that this species may serve as a model system for determining the involvement of virus infection in the development of allergic asthma.     

Critical Role of Airway Macrophages in Modulating Disease Severity during Influenza Virus Infection of Mice

Airway macrophages provide a first line of host defense against a range of airborne pathogens, including influenza virus. In this study, we show that influenza viruses differ markedly in their abilities to infect murine macrophages in vitro and that infection of macrophages is nonproductive and no infectious virus is released. Virus strain BJx109 (H3N2) infected macrophages with high efficiency and was associated with mild disease following intranasal infection of mice. In contrast, virus strain PR8 (H1N1) was poor in its ability to infect macrophages and highly virulent for mice. Depletion of airway macrophages by clodronate-loaded liposomes led to the development of severe viral pneumonia in BJx109-infected mice but did not modulate disease severity in PR8-infected mice. The severe disease observed in macrophage-depleted mice infected with BJx109 was associated with exacerbated virus replication in the airways, leading to severe airway inflammation, pulmonary edema, and vascular leakage, indicative of lung injury. Thymic atrophy, lymphopenia, and dysregulated cytokine and chemokine production were additional systemic manifestations associated with severe disease. Thus, airway macrophages play a critical role in limiting lung injury and associated disease caused by BJx109. Furthermore, the inability of PR8 to infect airway macrophages may be a critical factor contributing to its virulence for mice.Airway macrophages (Mφ) (AM), located at the interphase between air and lung tissue, provide the first line of defense following inhalation of airborne pathogens, including influenza viruses. In addition to phagocytosis of virions and virus-infected cells (16, 24), infection of AM represents an early event in recognition of the virus by the innate immune system. Following intranasal (i.n.) infection of mice, influenza virus replicates productively in type II epithelial cells lining the respiratory tract. Murine Mφ are also susceptible to influenza virus infection and viral proteins are produced, but replication is abortive and infectious progeny are not released (52, 69), although recent studies suggest limited release from mouse Mφ exposed to highly pathogenic H1N1 and H5N1 viruses (44). Following exposure to influenza virus, Mφ synthesize and release proinflammatory cytokines and alpha/beta interferon (26, 27, 45, 55), which further limit viral replication and spread within the respiratory tract. Inflammatory responses in the airways must be tightly regulated to ensure rapid virus clearance while avoiding excessive or chronic inflammation that may damage the delicate tissue-air interface.Liposome-encapsulated dichloromethylene diphosphonate (clodronate or CL2-MDP) is taken up by phagocytic Mφ and accumulates in the cytosol, resulting in Mφ death and depletion (66). Administration of clodronate liposomes (CL-LIP) has been widely used to selectively deplete airway Mφ in mouse models without affecting circulating monocytes (for examples, see references 4, 6, 8, 36, 47, 64, and 71). While CL-LIP has been used predominantly in rodent models of infection, it is noteworthy that CL-LIP treatment of pigs, a natural host of influenza virus, resulted in enhanced morbidity and mortality following infection with a human H1N1 subtype virus (30). In murine studies, depletion of airway Mφ prior to influenza virus infection led to increased cytotoxic CD8⁺ T-cell responses in the lungs of virus-infected mice (71); however, treatment with CL-LIP 48 h after infection was associated with impaired CD8⁺ T-cell responses (41). Furthermore, CL-LIP treatment prior to intranasal infection of mice with a recombinant virus bearing the surface glycoproteins of the 1918 pandemic strain led to exacerbated disease and mortality (64). Treatment of mice with CL-LIP has been associated with enhanced virus replication (41, 64, 71); however, the mechanisms by which airway Mφ initiate and modulate inflammatory responses and disease after influenza virus infection have not been fully elucidated.We observed in a previous study that influenza A virus strains show marked differences in their abilities to infect murine Mφ in vitro and implicated the Mφ mannose receptor (MMR) (CD206), a C-type lectin (46), in infectious virus entry (48). Virus strain BJx109, a reassortant virus bearing the surface glycoproteins of A/Beijing/353/89 (H3N2) and internal components derived from A/PR/8/34 (H1N1) (PR8) bears a highly glycosylated hemagglutinin (HA) molecule and was shown to infect Mφ to high levels, while the HA of PR8 is poorly glycosylated and the virus infected Mφ very poorly. In the current study, we demonstrate that intranasal infection of mice with BJx109 leads to mild clinical disease, while infection with an equivalent dose of PR8 leads to severe disease and rapid death. Depletion of airway Mφ by intranasal administration of CL-LIP prior to and during infection with influenza viruses had little effect on the course of PR8 infection; however, BJx109 infection of Mφ-depleted animals led to severe disease and death. Severe disease was associated with enhanced virus replication, severe airway inflammation, and pulmonary edema and vascular leakage, indicative of lung injury. Together, these data demonstrate that airway Mφ play a critical role in moderating disease severity during BJx109 infection. Furthermore, they suggest that the ability of PR8 to evade infectious uptake by airway Mφ is likely to be an important factor contributing to its virulence for mice.     

Evolution of CD8+ T Cell Responses after Acute PARV4 Infection

PARV4 is a small DNA human virus that is strongly associated with hepatitis C virus (HCV) and HIV infections. The immunologic control of acute PARV4 infection has not been previously described. We define the acute onset of PARV4 infection and the characteristics of the acute-phase and memory immune responses to PARV4 in a group of HCV- and HIV-negative, active intravenous drug users. Ninety-eight individuals at risk of blood-borne infections were tested for PARV4 IgG. Gamma interferon enzyme-linked immunosorbent spot assays, intracellular cytokine staining, and a tetrameric HLA-A2–peptide complex were used to define the T cell populations responding to PARV4 peptides in those individuals who acquired infection during the study. Thirty-five individuals were found to be PARV4 seropositive at the end of the study, eight of whose baseline samples were found to be seronegative. Persistent and functional T cell responses were detected in the acute infection phase. These responses had an active, mature, and cytotoxic phenotype and were maintained several years after infection. Thus, PARV4 infection is common in individuals exposed to blood-borne infections, independent of their HCV or HIV status. Since PARV4 elicits strong, broad, and persistent T cell responses, understanding of the processes responsible may prove useful for future vaccine design.     

Increased Hematopoietic Extracellular RNAs and Vesicles in the Lung during Allergic Airway Responses

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Protective Vaccine-Induced CD4+ T Cell-Independent B Cell Responses against Rabies Infection

A major goal in rabies virus (RV) research is to develop a single-dose postexposure prophylaxis (PEP) that would simplify vaccination protocols, reduce costs associated with rabies prevention in humans, and save lives. Live replication-deficient RV-based vaccines are emerging as promising single-dose vaccines to replace currently licensed inactivated RV-based vaccines. Nonetheless, little is known about how effective B cells develop in response to live RV-based vaccination. Understanding this fundamental property of rabies immunology may help in developing a single-dose RV vaccine. Typically, vaccines induce B cells secreting high-affinity, class-switched antibodies during germinal center (GC) reactions; however, there is a lag time between vaccination and the generation of GC B cells. In this report, we show that RV-specific antibodies are detected in mice immunized with live but not inactivated RV-based vaccines before B cells displaying a GC B cell phenotype (B220⁺GL7^hiCD95^hi) are formed, indicating a potential role for T cell-independent and early extrafollicular T cell-dependent antibody responses in the protection against RV infection. Using two mouse models of CD4⁺ T cell deficiency, we show that B cells secreting virus-neutralizing antibodies (VNAs) are induced via T cell-independent mechanisms within 4 days postimmunization with a replication-deficient RV-based vaccine. Importantly, mice that are completely devoid of T cells (B6.129P2-Tcrβ^tm1Mom Tcrδ^tm1Mom/J) show protection against pathogenic challenge shortly after immunization with a live replication-deficient RV-based vaccine. We show that vaccines that can exploit early pathways of B cell activation and development may hold the key for the development of a single-dose RV vaccine wherein the rapid induction of VNA is critical.     

Environmental Enrichment Alters Splenic Immune Cell Composition and Enhances Secondary Influenza Vaccine Responses in Mice

Chronic stress has deleterious effects on immune function, which can lead to adverse health outcomes. However, studies investigating the impact of stress reduction interventions on immunity in clinical research have yielded divergent results, potentially stemming from differences in study design and genetic heterogeneity, among other clinical research challenges. To test the hypothesis that reducing glucocorticoid levels enhances certain immune functions, we administered influenza vaccine once (prime) or twice (boost) to mice housed in either standard control caging or environmental enrichment (EE) caging. We have shown that this approach reduces mouse corticosterone production. Compared with controls, EE mice had significantly lower levels of fecal corticosterone metabolites (FCMs) and increased splenic B and T lymphocyte numbers. Corticosterone levels were negatively associated with the numbers of CD19⁺ (r² = 0.43, p = 0.0017), CD4⁺ (r² = 0.28, p = 0.0154) and CD8⁺ cells (r² = 0.20, p = 0.0503). Vaccinated mice showed nonsignificant differences in immunoglobulin G (IgG) titer between caging groups, although EE mice tended to exhibit larger increases in titer from prime to boost than controls; the interaction between the caging group (control versus EE) and vaccine group (prime versus boost) showed a strong statistical trend (cage-group*vaccine-group, F = 4.27, p = 0.0555), suggesting that there may be distinct effects of EE caging on primary versus secondary IgG vaccine responses. Vaccine-stimulated splenocytes from boosted EE mice had a significantly greater frequency of interleukin 5 (IL-5)-secreting cells than boosted controls (mean difference 7.7, IL-5 spot-forming units/10⁶ splenocytes, 95% confidence interval 0.24–135.1, p = 0.0493) and showed a greater increase in the frequency of IL-5–secreting cells from prime to boost. Our results suggest that corticosterone reduction via EE caging was associated with enhanced secondary vaccine responses, but had little effect on primary responses in mice. These findings help identify differences in primary and secondary vaccine responses in relationship to stress mediators that may be relevant in clinical studies.     

Aged Mice Exhibit a Severely Diminished CD8 T Cell Response following Respiratory Syncytial Virus Infection

Respiratory virus infections in the elderly result in increased rates of hospitalization and death. Respiratory syncytial virus (RSV) is a leading cause of severe virus-induced respiratory disease in individuals over the age of 65. CD8 T cells play a critical role in mediating RSV clearance. While it is clear that T cell immunity declines with age, it is not clear to what extent the CD8 T cell response to RSV is altered. Using aged BALB/c mice, we demonstrated that RSV-specific CD8 T cell responses were significantly reduced in the lungs of aged mice at the peak of the T cell response and that this decrease correlated with delayed viral clearance. Despite a decrease in the overall numbers of RSV-specific CD8 T cells during acute infection, their capacity to produce effector cytokines was not impaired. Following viral clearance, the RSV-specific memory CD8 T cells were similar in total number and phenotype in young and aged mice. Furthermore, following infection with a heterologous pathogen expressing an RSV epitope, RSV-specific memory CD8 T cells exhibited similar activation and ability to provide early control of the infection in young and aged mice. These data demonstrate a decrease in the capacity of aged mice to induce a high-magnitude acute CD8 T cell response, leading to prolonged viral replication, which may contribute to the increased disease severity of RSV infection observed for aged individuals.     

Analysis of Pulmonary Dendritic Cell Maturation and Migration during Allergic Airway Inflammation

Dendritic cells (DCs) are the key players involved in initiation of adaptive immune response by activating antigen-specific T cells. DCs are present in peripheral tissues in steady state; however in response to antigen stimulation, DCs take up the antigen and rapidly migrate to the draining lymph nodes where they initiate T cell response against the antigen^1,2. Additionally, DCs also play a key role in initiating autoimmune as well as allergic immune response³.DCs play an essential role in both initiation of immune response and induction of tolerance in the setting of lung environment⁴. Lung environment is largely tolerogenic, owing to the exposure to vast array of environmental antigens⁵. However, in some individuals there is a break in tolerance, which leads to induction of allergy and asthma. In this study, we describe a strategy, which can be used to monitor airway DC maturation and migration in response to the antigen used for sensitization. The measurement of airway DC maturation and migration allows for assessment of the kinetics of immune response during airway allergic inflammation and also assists in understanding the magnitude of the subsequent immune response along with the underlying mechanisms.Our strategy is based on the use of ovalbumin as a sensitizing agent. Ovalbumin-induced allergic asthma is a widely used model to reproduce the airway eosinophilia, pulmonary inflammation and elevated IgE levels found during asthma^6,7. After sensitization, mice are challenged by intranasal delivery of FITC labeled ovalbumin, which allows for specific labeling of airway DCs which uptake ovalbumin. Next, using several DC specific markers, we can assess the maturation of these DCs and can also assess their migration to the draining lymph nodes by employing flow cytometry.