The host immune response in respiratory virus infection: balancing virus clearance and immunopathology

The respiratory tract is constantly exposed to the external environment, and therefore, must be equipped to respond to and eliminate pathogens. Viral clearance and resolution of infection requires a complex, multi-faceted response initiated by resident respiratory tract cells and innate immune cells and ultimately resolved by adaptive immune cells. Although an effective immune response to eliminate viral pathogens is essential, a prolonged or exaggerated response can damage the respiratory tract. Immune-mediated pulmonary damage is manifested clinically in a variety of ways depending on location and extent of injury. Thus, the antiviral immune response represents a balancing act between the elimination of virus and immune-mediated pulmonary injury. In this review, we highlight major components of the host response to acute viral infection and their role in contributing to mitigating respiratory damage. We also briefly describe common clinical manifestations of respiratory viral infection and morphological correlates. The continuing threat posed by pandemic influenza as well as the emergence of novel respiratory viruses also capable of producing severe acute lung injury such as SARS-CoV, MERS-CoV, and enterovirus D68, highlights the need for an understanding of the immune mechanisms that contribute to virus elimination and immune-mediated injury.     

The airway epithelium: soldier in the fight against respiratory viruses

The airway epithelium acts as a frontline defense against respiratory viruses, not only as a physical barrier and through the mucociliary apparatus but also through its immunological functions. It initiates multiple innate and adaptive immune mechanisms which are crucial for efficient antiviral responses. The interaction between respiratory viruses and airway epithelial cells results in production of antiviral substances, including type I and III interferons, lactoferrin, β-defensins, and nitric oxide, and also in production of cytokines and chemokines, which recruit inflammatory cells and influence adaptive immunity. These defense mechanisms usually result in rapid virus clearance. However, respiratory viruses elaborate strategies to evade antiviral mechanisms and immune responses. They may disrupt epithelial integrity through cytotoxic effects, increasing paracellular permeability and damaging epithelial repair mechanisms. In addition, they can interfere with immune responses by blocking interferon pathways and by subverting protective inflammatory responses toward detrimental ones. Finally, by inducing overt mucus secretion and mucostasis and by paving the way for bacterial infections, they favor lung damage and further impair host antiviral mechanisms.     

Non-cytotoxic antiviral activities of granzymes in the context of the immune antiviral state

Summary: Viruses are obligatory intracellular parasites, whose replication depends on components encoded by the virus and pathways and functions of the host cell. In addition to the pathways required for viral synthesis, viruses activate multiple mechanisms to evade immune attack, promoting viral propagation while avoiding or slowing the host immune response. To achieve efficient control of viral infections, the immune system in vertebrates relies on diverse and synergistic antiviral pathways (both at the innate and adaptive immune response), which target and inactivate viral and host components involved both in viral replication and in viral defenses that block host antiviral activities. During this process, the immune system uses mechanisms to slow down viral propagation, while apoptotic pathways are triggered to kill (when possible) the infected cell. Granzymes (granule enzymes) are key components of the immune response that play important roles in eliminating host cells infected by intracellular pathogens. Although the induction of target cell death has been considered the central function for these proteases, recent evidence supports that granzymes can achieve direct antiviral activities through the cleavage of viral and host factors required for viral replication and viral defense. In addition, granzyme A can stimulate the production of pro-inflammatory cytokines. The focus of this review is to discuss recent views on antiviral mechanisms involved in controlling viral infections, with special interest in novel and potential non-death-related antiviral functions of the granzymes, and how these unique functions complement and synergize with the ‘antiviral state’ created by interferons and cytotoxic lymphocytes in response to virus.     

The role of plasmacytoid dendritic cell-derived IFN alpha in antiviral immunity

Viral infections represent a major source of acute and chronic human disease. The immune system plays a central role in the elimination of viruses through its ability to recognize pathogens and to induce virus-specific cellular activation, accompanied by a robust production of soluble molecules with antiviral effects. Interferons are among the most powerful natural soluble antiviral molecules. Upon viral infection, interferons are produced by a variety of cell types, with immune cells being the main contributors. The immune system works as a well-orchestrated team composed of multiple cell types. The mechanisms of intercellular cooperation that includes dendritic cells (DCs), their soluble factors, and different types of immune cells are yet to be fully understood. Further, the effects of viral infections on interimmune cooperation need to be investigated. In this review, we define the role of plasmacytoid dendritic cells (PDC) and PDC-derived interferon alpha (IFNalpha) during viral infections. Specifically, we address the mechanisms of IFNalpha induction and the cooperation between PDC, PDC-derived IFNalpha and T cells, B cells, NK, iNKT, and myeloid dendric cells in antiviral immune responses.     

Role of viral infections in asthma and chronic obstructive pulmonary disease

Substantial evidence implicates common respiratory viral infections in the pathogenesis of asthma and chronic obstructive pulmonary disease (COPD). Children who experience recurrent virally induced wheezing episodes during infancy are at greater risk for developing asthma. In addition, respiratory viral infections are a major trigger for acute exacerbations of both asthma and COPD. Despite the importance of viral infections in asthma and COPD, the mechanisms by which viruses predispose to, or cause exacerbations of, these diseases remain poorly understood. It is clear that viral infections lead to enhanced airway inflammation and can cause airways hyperresponsiveness. The epithelial cell is the principal site of viral infection in the airways and plays a central role in viral modulation of airway inflammation via release of a variety of cytokines, chemokines, and growth factors. The mechanisms by which viral infections modulate epithelial function, therefore, is a topic of intense investigation. The epithelium also contributes to the host innate defense response to viral infection by releasing products that are antiviral and/or can lead to increased recruitment of dendritic cells and lymphocytes. Some evidence supports a role for the epithelial cell in specific immunity, although the response of more conventional cells of the immune system to viral infections is likely the dominant factor in this regard. Although current therapies may help combat virally induced disease exacerbations, they are less than ideal. A better understanding of the mechanisms underlying viral modulation of these diseases, therefore, may lead to new therapeutic approaches.     

Genetic influences on viral-induced cytokine responses in the lung

Infection with respiratory viruses such as influenza, respiratory syncytial virus and coronavirus provides a difficult immunological challenge for the host, where a balance must be established between controlling viral replication and limiting damage to the delicate lung structure. Although the genetic architecture of host responses to respiratory viral infections is not yet understood, it is clear there is underlying heritability that influences pathogenesis. Immune control of virus replication is essential in respiratory infections, but overt activation can enhance inflammation and disease severity. Cytokines initiate antiviral immune responses but are implicated in viral pathogenesis. Here, we discuss how host genetic variation may influence cytokine responses to respiratory viral infections and, based on our current understanding of the role that cytokines play in viral pathogenesis, how this may influence disease severity. We also discuss how induced pluripotent stem cells may be utilised to probe the mechanistic implications of allelic variation in genes in virus-induced inflammatory responses. Ultimately, this could help to design better immune modulators, stratify high risk patients and tailor anti-inflammatory treatments, potentially expanding the ability to treat respiratory virus outbreaks in the future.     

Current Aspects of Innate and Adaptive Immunity in Atopic Dermatitis

Atopic dermatitis (AD) is a highly pruritic, chronic, multifactorial skin disease predisposing to bacterial and viral infections based on abnormalities of the innate and acquired immune system. The innate system quickly mobilizes an inflexible, standardized first-line response against different pathogens. Epidermal barrier dysfunction results in increased protein allergen penetration through the epidermis and predisposes to secondary skin infections. Two loss-of-function mutations in the epidermal filaggrin gene are associated with AD. Langerhans cells and inflammatory dendritic epidermal cells (IDEC) express high affinity IgE receptors, which are functional in IgE-mediated antigen presentation. Inducible antimicrobial peptides including the antiviral cathelicidin and the antibacterial beta-defensins show defective upregulation in lesional AD skin. The desmosomal protein nectin-1 is unmasked in AD lesions, thus becoming a relevant herpes simplex virus (HSV) entry receptor. Type I IFN-producing plasmacytoid dendritic cells are decreased and dysfunctional in AD skin, predisposing the patients to viral skin infections. Molluscum contagiosum virus produces a unique IL-18 binding protein to evade antiviral defense mechanisms. Innate and adaptive immunity do not simply coexist but are linked to one another in a complex network of skin immunobiology.     

Modulation of dendritic cell function by persistent viruses

Worldwide, chronic viral infections cause major health problems with severe morbidity and mortality. HIV and hepatitis C virus (HCV) manifest themselves as persistent infections, but they are entirely distinct viruses with distinct replication mechanisms, tropism, and kinetics. Coinfections with HCV among people with HIV are emerging as a growing problem. Cellular immune responses play an important role in viral clearance and disease pathogenesis. However, cellular immunity to HIV and HCV is affected severely in chronic patients. Various hypotheses have been proposed to explain the dysfunctional T cell response, including viral escape mutations, exhaustion of the T cell compartment, and the activity of regulatory T cells. Also, modulation of the function of dendritic cells (DC) has been suggested as one of the mechanisms used by persistent viruses to evade the immune system. In this review, we will focus on DC interactions with one murine persistent virus (lymphocytic choriomeningitis virus clone 13) and two human persistent viruses (HIV-1 and HCV), intending to examine if general strategies are used by persistent viruses to modulate the function of DC to improve our understanding of the mechanisms underlying the development and maintenance of viral persistence.     

Replication-defective viruses as vaccines and vaccine vectors

The classical viral vaccine approaches using inactivated virus or live-attenuated virus have not been successful for some viruses, such as human immunodeficiency virus or herpes simplex virus. Therefore, new types of vaccines are needed to combat these infections. Replication-defective mutant viruses are defective for one or more functions that are essential for viral genome replication or synthesis and assembly of viral particles. These viruses are propagated in complementing cell lines expressing the missing gene product; however, in normal cells, they express viral gene products but do not replicate to form progeny virions. As vaccines, these mutant viruses have advantages of both classical types of viral vaccines in being as safe as inactivated virus but expressing viral antigens inside infected cells so that MHC class I and class II presentation can occur efficiently. Replication-defective viruses have served both as vaccines for the virus itself and as a vector for the expression of heterologous antigens. The potential advantages and disadvantages of these vaccines are discussed as well as contrasting them with single-cycle mutant virus vaccines and replicon/amplicon versions of vaccines. Replication-defective viruses have also served as important probes of the host immune response in helping to define the importance of the first round of infected cells in the host immune response, the mechanisms of activation of innate immune response, and the role of the complement pathway in humoral immune responses to viruses.     

Generation and maintenance of human memory cells during viral infection

Long-term maintenance of memory T cell response is the hallmark of immune protection and hence the holy grail of most vaccine development studies. Persistent memory cells, developed after either viral infection or vaccination, ensure the generation of an antiviral response upon reexposure to the pathogen. During acute viral infections, as in the case of measles and influenza viruses, strong T cell effector functions, which eradicate the virus and protect patients against reexposure, are achieved by the generation of persistent protective memory cells. However, in chronic infections, T cells drastically lose effector functions before acquiring a memory phenotype. Chronic infections can be categorized into infections where viremia is controlled and protective memory cells are maintained as in the case of EBV and CMV infections, or where the virus persists and memory cells are exhausted and disrupted as in the case of human immunodeficiency virus infection. In this review, we will discuss the different phenotypical and functional characteristics of memory cells subsets, the importance of the role they play during acute and chronic infections, and the mechanisms behind their effectiveness and persistence.     

Probiotics in respiratory virus infections

Viral respiratory infections are the most common diseases in humans. A large range of etiologic agents challenge the development of efficient therapies. Research suggests that probiotics are able to decrease the risk or duration of respiratory infection symptoms. However, the antiviral mechanisms of probiotics are unclear. The purpose of this paper is to review the current knowledge on the effects of probiotics on respiratory virus infections and to provide insights on the possible antiviral mechanisms of probiotics. A PubMed and Scopus database search was performed up to January 2014 using appropriate search terms on probiotic and respiratory virus infections in cell models, in animal models, and in humans, and reviewed for their relevance. Altogether, thirty-three clinical trials were reviewed. The studies varied highly in study design, outcome measures, probiotics, dose, and matrices used. Twenty-eight trials reported that probiotics had beneficial effects in the outcome of respiratory tract infections (RTIs) and five showed no clear benefit. Only eight studies reported investigating viral etiology from the respiratory tract, and one of these reported a significant decrease in viral load. Based on experimental studies, probiotics may exert antiviral effects directly in probiotic–virus interaction or via stimulation of the immune system. Although probiotics seem to be beneficial in respiratory illnesses, the role of probiotics on specific viruses has not been investigated sufficiently. Due to the lack of confirmatory studies and varied data available, more randomized, double-blind, and placebo-controlled trials in different age populations investigating probiotic dose response, comparing probiotic strains/genera, and elucidating the antiviral effect mechanisms are necessary.     

Respiratory viral infections and asthma pathogenesis: a critical role for dendritic cells?

BACKGROUND: Respiratory viral infections can influence the course of asthma at different time points. Severe respiratory viral infections during early age are associated with a higher prevalence of asthma in later childhood. In established asthma, viral infections are a frequent cause of asthma exacerbation. OBJECTIVES: The present review focuses on epidemiological and experimental animal data that can illuminate the mechanisms by which viral infections can lead to sensitization to antigen, and exacerbate ongoing allergic airway inflammation and focuses on the role played by dendritic cells (DCs). RESULTS: In experimental rodent models of asthma, respiratory viral infection at the time of a first inhaled antigen exposure is described to induce Th2 sensitization and to enhance the allergic response to a second encounter with the same antigen. Virus infections can modulate airway dendritic cell function by upregulation of costimulatory molecule expression, enhanced recruitment, and by inducing an inflammatory environment, all leading to an enhanced antigen presentation and possibly changing the normal tolerogenic response to inhaled antigen into an immunogenic response. In established asthma, respiratory viral infections attract several inflammatory cells, alter receptor expression on airway smooth muscle and modulate neuroimmune mechanisms, possibly leading to exacerbation of disease. CONCLUSIONS: Animal data suggest that the link between respiratory viral infections and increased asthma is causally related, the viral infection acting on the immune and structural cells to enhance antigen presentation and inflammatory cell recruitment.     

Travels along the viral–immunobiology highway

Summary: Michael Oldstone began his biomedical research career over three decades ago, showing contrary to established scientific dogma, the host was not tolerant but made a specific antiviral immune response during persistent virus infections. Further, the immune response to the virus actually caused tissue damage and disease, the first observation that several manifestations ordinarily accompanying infections were due to the host's antiviral immune response. These observations made originally with lymphocytic choriomeningitis virus (LCMV) and murine retroviruses were extended to other microbial infections including those in humans. Buildings on this work, he showed that antibodies to virus could recognize similar amino acid sequences or motifs found in host/cell proteins and cause disease. This cross-reactivity, referred to as molecular mimicry, has and is now been extensively studied by many laboratories. Another mechanism by which persistent virus infection produced disease was uncovered by cocumenting that viruses could alter the differentiation or "luxury" function of cells with causing cell destruction, thereby altering homeostasis. Finally, Oldstone was one of the first to show that viruses caused immunosuppression, abrogated immunologic surveillance resulting in viral persistence, work carried out long before HIV was discovered. He has also defined host-cell receptors for several viruses. In recent studies, host-cell receptor used by LCMV strains or variants that cause persistence have been identified. This led to observations that a single amino acid on the viral glycoprotein provides the infectious agent a selective ability ot displace extra-cellular matrix molecule, bind to and infect dendritic cells leading to their inability to act as antigen presenting cells thereby aborting the host's ability to generate the antiviral immune response required to clean the infection.     

Regulation of immunity to respiratory syncytial virus by dendritic cells, toll-like receptors, and notch

The activation and maintenance of pulmonary viral disease is regulated at multiple levels and determined by the early innate response to the pathogenic stimuli. Subsequent activation events that rely directly and indirectly on the virus itself can alter the development and severity of the ensuing immunopathologic responses. In the present review we outline several interconnected mechanisms that rely on the early recognition of viral nucleic acid for the most appropriate anti-viral immune responses, including TLRs and Notch activation in DCs and T cells. Deviation or persistence of the immune response to respiratory viruses may impact significantly on the severity of the responses. While these mechanisms are likely similar in most respiratory viral infections, this review will focus on findings with respiratory syncytial virus (RSV) infections.     

Role of NK and NKT cells in the immunopathogenesis of HCV-induced hepatitis

Natural killer (NK) cells constitute the first line of host defense against invading pathogens. They usually become activated in an early phase of a viral infection. Liver is particularly enriched in NK cells, which are activated by hepatotropic viruses such as hepatitis C virus (HCV). The activated NK cells play an essential role in recruiting virus-specific T cells and in inducing antiviral immunity in liver. They also eliminate virus-infected hepatocytes directly by cytolytic mechanisms and indirectly by secreting cytokines, which induce an antiviral state in host cells. Therefore, optimally activated NK cells are important in limiting viral replication in this organ. This notion is supported by the observations that interferon treatment is effective in HCV-infected persons in whom it increases NK cell activity. Not surprisingly, HCV has evolved multiple strategies to counter host's NK cell response. Compromised NK cell functions have been reported in chronic HCV-infected individuals. It is ironic that activated NK cells may also contribute toward liver injury. Further studies are needed to understand the role of these cells in host defense and in liver pathology in HCV infections. Recent advances in understanding NK cell biology have opened new avenues for boosting innate and adaptive antiviral immune responses in HCV-infected individuals.     

CD8+ T cells and immunoregulatory networks in asthma

It is well established that infection with respiratory viruses can cause acute local inflammation in humans and is a leading cause in the hospitalization of asthmatics. Less well recognized is the potential for viral infections to actually protect against the development of asthma, as are the cellular mechanisms which might underlie such protection. This review outlines the basic immunological pathways involved in atopic asthma and details the currently recognized cellular mechanisms induced by respiratory viral infections which can protect against the development of asthma. Specifically, it appears that virus infection induced memory T cells that remain in tissues, e.g. the lung and airways, can under certain circumstances create a local cytokine milieu which inhibits the development of ensuing allergic immune responses at that site. One key aspect of this immune modulation is the cytokine-dependent communication which occurs between the innate and the adaptive immune systems. The mechanistic principles underlying this form of immunomodulation should be taken into consideration when developing future forms of therapy and rational vaccine design.     

The yin and yang of viruses and interferons

Interferons (IFNs)-α/β are critical effectors of the innate immune response to virus infections. Through activation of the IFN-α/β receptor (IFNAR), they induce expression of IFN-stimulated genes (ISGs) that encode antiviral proteins capable of suppressing viral replication and promoting viral clearance. Many highly pathogenic viruses have evolved mechanisms to evade an IFN response and the balance between the robustness of the host immune response and viral antagonistic mechanisms determines whether or not the virus is cleared. Here, we discuss IFNs as broad-spectrum antivirals for treatment of acute virus infections. In particular, they are useful for treatment of re-emerging virus infections, where direct-acting antivirals (DAAs) have limited utility due to DAA-resistant mutations, and for newly emerging virus strains in which the time to vaccine availability precludes vaccination at the onset of an outbreak.     

Lung dendritic cells and the inflammatory response.

OBJECTIVE: To discuss the role of conventional and plasmacytoid dendritic cells in inducing and modulating immune responses in the lung. DATA SOURCES: The primary literature and selected review articles studying the role of dendritic cells in both rodent and human lungs as identified via a PubMed/MEDLINE search using the keywords dendritic cell, antigen-presenting cell, viral airway disease, asthma, allergy, and atopy. STUDY SELECTION: The author's knowledge of the field was used to identify studies that were relevant to the stated objective. RESULTS: Dendritic cells are well positioned in the respiratory tract and other mucosal surfaces to respond to any foreign protein. These cells are crucial to the initiation of the adaptive immune response through induction of antigen specific T-cell responses. These cells also play an important role in the regulation of developing and ongoing immune responses, an area that is currently under intense investigation. This review discusses the various subsets of human and rodent dendritic cells and the pathways involved in antigen processing and subsequent immune regulation by dendritic cells in the lung using both viral and nonviral allergenic protein exposure as examples. CONCLUSIONS: Conventional and plasmacytoid dendritic cells are uniquely situated in the immune cascade to not only initiate but also modulate immune responses. Therapeutic interventions in allergic and asthmatic diseases will likely be developed to take advantage of this exclusive position of the dendritic cell.