A viral-vectored RSV vaccine induces long-lived humoral immunity in cotton rats

Human respiratory syncytial virus (RSV) is the leading cause of lower airway disease in infants worldwide and repeatedly infects immunocompetent individuals throughout life. Severe lower airway RSV infection during infancy can be life-threatening, but is also associated with important sequelae including development of asthma and recurrent wheezing in later childhood. The basis for the inadequate, short-lived adaptive immune response to RSV infection is poorly understood, but it is widely recognized that RSV actively antagonizes Type I interferon (IFN) production. In addition to the induction of the anti-viral state, IFN production during viral infection is critical for downstream development of robust, long-lived immunity. Based on the hypothesis that a vaccine that induced robust IFN production would be protective, we previously constructed a Newcastle disease virus-vectored vaccine that expresses the F glycoprotein of RSV (NDV-F) and demonstrated that vaccinated mice had reduced lung viral loads and an enhanced IFN-γ response after RSV challenge. Here we show that vaccination also protected cotton rats from RSV challenge and induced long-lived neutralizing antibody production, even in RSV immune animals. Finally, pulmonary eosinophilia induced by RSV infection of unvaccinated cotton rats was prevented by vaccination. Overall, these data demonstrate enhanced protective immunity to RSV F when this protein is presented in the context of an abortive NDV infection.     

Formulation of the respiratory syncytial virus fusion protein with a polymer-based combination adjuvant promotes transient and local innate immune responses and leads to improved adaptive immunity

Respiratory syncytial virus (RSV) causes serious upper and lower respiratory tract infections in newborns and infants. Presently, there is no licensed vaccine against RSV. We previously reported the safety and efficacy of a novel vaccine candidate (ΔF/TriAdj) in rodent and lamb models following intranasal immunization. However, the effects of the vaccine on the innate immune system in the upper and lower respiratory tracts, when delivered intranasally, have not been characterized. In the present study, we found that ΔF/TriAdj triggered transient production of chemokines, cytokines and interferons in the nasal tissues and lungs of BALB/c mice. The types of chemokines produced were consistent with the populations of immune cells recruited, i.e. dendritic cells, macrophages and neutrophils, in the nose-associated lymphoid tissue (NALT), lung and their draining lymph nodes of the ΔF/TriAdj-immunized group. In addition, ΔF/TriAdj stimulated cellular activation with generation of mucosal and systemic antibody responses, and conferred complete protection from viral infection in the lungs upon RSV challenge. The effect of ΔF/TriAdj was short-lived in the nasal tissues and more prolonged in the lungs. In addition, both innate and adaptive immune responses were lower when mice were immunized with ΔF alone. These results suggest that ΔF/TriAdj modulates the innate mucosal environment in both upper and lower respiratory tracts, which contributes to robust adaptive immune responses and long-term protective efficacy of this novel vaccine formulation.     

The emerging role of innate immunity in protection against HIV-1 infection

Preventive immunization against HIV-1 infection requires a rapid immune response that does not rely exclusively on B or T cell memory. Innate immunity may fulfill this function as it may be activated directly at the time of HIV-1 transmission, inhibit early HIV-1 replication, stimulate adaptive immunity and enable specific antibodies followed by CD8(+) T cells to deal with the virus effectively. The three components of innate immunity - cellular, extracellular and intracellular - are presented, with an example given for each of these components; gammadelta T cells, CC chemokines and APOBEC3G. This brief account is presented to highlight the immuno-virological concept of coordinating activated innate immunity with adaptive antibody and T cell responses in preventive vaccination against HIV-1 infection.     

Evaluation of the immune response and protective effects of rhesus macaques vaccinated with biodegradable nanoparticles carrying gp120 of human immunodeficiency virus

We previously reported that biodegradable amphiphilic poly(γ-glutamic acid) nanoparticles (NPs) carrying the recombinant gp120 env protein of the human immunodeficiency virus type 1 (HIV-1) were efficiently taken up by dendritic cells, and induced strong CD8⁺ T cell responses against the gp120 in mice. To evaluate gp120-carrying NPs (gp120-NPs) as a vaccine candidate for HIV-1 infection, we vaccinated rhesus macaques with these gp120-NPs and examined the immune response and protective efficacy against a challenge inoculation of simian and human immunodeficiency chimeric virus (SHIV). We found that gp120-NP vaccination induced stronger responses for both gp120-specific cellular and humoral immunity than gp120-alone vaccination. After the challenge inoculation with SHIV, however, the peak value of viral RNA in the peripheral blood was higher in the vaccinated groups, especially the gp120-NP vaccinated group, than naive control group. Higher value of viral load was also maintained in gp120-NP vaccinated group. Furthermore, CD4⁺ T cells from the peripheral blood decreased more in the vaccinated groups than the control group. Thus, induced immune responses against gp120 enclosed in NPs were not effective for protection but, conversely enhanced the infection, although the gp120-NPs showed a stronger induction of immune responses against the vaccinated antigen in rhesus macaques. These results support the importance of determining immune correlate of protective immunity for vaccine development against HIV-1 infection.     

Recombinant adenoviral vector expressing HCV NS4 induces protective immune responses in a mouse model of Vaccinia-HCV virus infection: A dose and route conundrum

Hepatitis C virus (HCV) leads to chronic infection in the majority of infected patients presumably due to failure or inefficiency of the immune responses generated. Both antibody and cellular immune responses have been suggested to be important in viral clearance. Non-replicative adenoviral vectors expressing antigens of interest are considered as attractive vaccine vectors for a number of pathogens. In this study, we sought to evaluate cellular and humoral immune responses against HCV NS4 protein using recombinant adenovirus as a vaccine vector expressing NS4 antigen. We have also measured the effect of antigen doses and routes of immunization on the quality and extent of the immune responses, especially their role in viral load reduction, in a recombinant Vaccinia-HCV (Vac-HCV) infection mouse model. Our results show that an optimum dose of adenovirus vector (2 × 10⁷ pfu/mouse) administered intramuscularly (i.m.) induces high T cell proliferation, granzyme B-expressing CD8⁺ T cells, pro-inflammatory cytokines such as IFN-γ, TNF-α, IL-2 and IL-6, and antibody responses that can significantly reduce the Vac-HCV viral load in the ovaries of female C57BL/6 mice. Our results demonstrate that recombinant adenovirus vector can induce both humoral and cellular protective immunity against HCV-NS4 antigen, and that immunity is intricately controlled by route and dose of immunizing vector.     

Analysis of the immune response and viral evolution during the acute phase of SIV infection

Development of an effective vaccine against human immunodeficiency virus (HIV) will require knowledge of the immune responses that correlate with protection. During the acute phase of HIV infection the host immune responses appear to control viral replication. It is thought that virus-specific cellular immunity is intimately involved in this viral control. We have developed a model system to measure the entire T cell response and viral evolution in the face of this onslaught in rhesus macaques during the acute phase of infection with molecularly cloned simian immunodeficiency virus (SIV). We used intracellular cytokine staining (ICS) of peripheral blood mononuclear cells (PBMCs) from animals during the acute phase of viral infection stimulated with peptides spanning the entire protein sequence of SIV to determine which peptides were recognized by CD8 and CD4 positive T cells. Furthermore, we sequenced the entire virus during the acute phase of infection. This approach has proved highly effective for measuring acute phase T cell responses and viral evolution in SIV-infected rhesus macaques and might facilitate the definition of cellular immune responses in HIV-infected humans during the acute phase.     

Identification of protective and non-protective T cell epitopes in influenza

Understanding the immune response to different CD8 T cell epitopes is important for the development of vaccines designed to promote protective cellular immunity. Recently, we have shown that vaccination with the PA(224-233)/D(b) epitope of influenza virus was poorly protective in terms of viral clearance. To determine if other influenza virus epitopes behave in this manner, we analyzed the ability of three newly identified CD8 T cell epitopes and three previously defined epitopes to provide protection following vaccination and viral challenge. All six of the peptide-based vaccinations resulted in significantly increased numbers of epitope-specific CD8 T cells in the spleen. Interestingly, we found that vaccination with three peptides (HA(332-340), M1(128-135), or PA(224-233)) resulted in delayed viral clearance following infection. These findings indicate that some epitopes have a detrimental impact on viral clearance and have important implications for the development of vaccination strategies designed to provide protection against subsequent influenza virus challenge.     

Live attenuated influenza vaccine strains elicit a greater innate immune response than antigenically-matched seasonal influenza viruses during infection of human nasal epithelial cell cultures

Influenza viruses are global pathogens that infect approximately 10–20% of the world's population each year. Vaccines, including the live attenuated influenza vaccine (LAIV), are the best defense against influenza infections. The LAIV is a novel vaccine that actively replicates in the human nasal epithelium and elicits both mucosal and systemic protective immune responses. The differences in replication and innate immune responses following infection of human nasal epithelium with influenza seasonal wild type (WT) and LAIV viruses remain unknown. Using a model of primary differentiated human nasal epithelial cell (hNECs) cultures, we compared influenza WT and antigenically-matched cold adapted (CA) LAIV virus replication and the subsequent innate immune response including host cellular pattern recognition protein expression, host innate immune gene expression, secreted pro-inflammatory cytokine production, and intracellular viral RNA levels. Growth curves comparing virus replication between WT and LAIV strains revealed significantly less infectious virus production during LAIV compared with WT infection. Despite this disparity in infectious virus production the LAIV strains elicited a more robust innate immune response with increased expression of RIG-I, TLR-3, IFNβ, STAT-1, IRF-7, MxA, and IP-10. There were no differences in cytotoxicity between hNEC cultures infected with WT and LAIV strains as measured by basolateral levels of LDH. Elevated levels of intracellular viral RNA during LAIV as compared with WT virus infection of hNEC cultures at 33 °C may explain the augmented innate immune response via the up-regulation of pattern recognition receptors and down-stream type I IFN expression. Taken together our results suggest that the decreased replication of LAIV strains in human nasal epithelial cells is associated with a robust innate immune response that differs from infection with seasonal influenza viruses, limits LAIV shedding and plays a role in the silent clinical phenotype seen in human LAIV inoculation.     

Inhibition of porcine reproductive and respiratory syndrome virus by Cecropin D in vitro

Porcine reproductive and respiratory syndrome virus (PRRSV) continues to cause substantial economic losses to the pig industry worldwide. Although vaccines are commercially available for the control of PRRSV infection, no vaccination regimen has been proved sustained success in terms of generating a protective immune response. Therefore, the development of novel antivirals is urgently needed. Antimicrobial peptides display broad-spectrum antimicrobial activities against bacteria, fungi, and viruses and play an important role in host innate immune response. Here, we tested whether Cecropin D (CD) could inhibit PRRSV infection and replication in vitro. The inhibitory effect of CD occurred during viral attachment and the early period of viral entry into Marc-145 cells. CD also attenuated virus-induced apoptosis during the late phase of PRRSV infection and suppressed virus release in Marc-145 cells, which might contribute to the inhibition of PRRSV infection. Similar inhibitory effects on PRRSV infection were also found with CD treatment in porcine alveolar macrophages, the major target cell type of PRRSV infection in pigs in vivo. These findings suggest that CD has the potential to develop a new therapeutic agent against PRRSV infection.     

Antiviral response in pandemic influenza viruses

The outcome of viral infections depends on a complex set of interactions between the viruses and their hosts. Particularly, viral infection triggers specific signaling programs within the infected cells that results in substantial changes in host gene expression. While some of these changes might be beneficial for viral replication, others represent the induction of a host antiviral response. In this respect, viruses have evolved genes that counteract this initial innate antiviral response. These viral-host interactions shape the subsequent phases of the disease and influence the adaptive immune response. In influenza viruses, the nonstructural protein 1 inhibits the interferon-mediated antiviral response. The regulatory activities of this viral protein play a major role in the pathogenicity of influenza virus and appear partially responsible for the ability of influenza viruses to infect multiple animal species, which likely contributes to the generation of new pandemic viruses in humans.     

冠状病毒感染的免疫应答及其致病机制研究进展

近年来冠状病毒感染在全球多次暴发流行,对全球公共卫生安全构成严重威胁。机体的免疫应答在病毒感染性疾病的发生、发展和转归中发挥重要作用,与病毒的致病性密切相关,对于控制和清除冠状病毒感染至关重要。本文在简述冠状病毒及其感染的相关疾病基础上,综述机体固有免疫应答和适应性免疫应答在冠状病毒发生、发展和致病中的作用和机制,为疾病的治疗和预防提供理论和实验依据。     

Development of bioluminescence imaging of respiratory syncytial virus (RSV) in virus-infected live mice and its use for evaluation of therapeutics and vaccines

Respiratory Syncytial virus (RSV) is one of the leading causes of pneumonia among infants with no human vaccine or efficient curative treatments. Efforts are underway to develop new RSV vaccines and therapeutics. There is a dire need for animal models for preclinical evaluation and selection of products against RSV. Herein, we developed a whole body bioluminescence imaging to follow replication of RSV A2 virus strain expressing firefly luciferase (RSVA2-line19-FFL) in live BALB/c mice that can be used as an extremely sensitive readout for studying effects of antiviral and vaccines in living mice. Strong bioluminescence signal was detected in the nasal cavity and in the lungs following intranasal infection of mice with RSVA2-line19-FFL. The kinetics of viral replication in lungs quantified by daily live imaging strongly correlated with viral titers measured by ex-vivo plaque assay and by assessing viral RNA by qRT-PCR. Vaccination of mice with a pre-fusion F protein elicited high neutralizing antibody titers conferring strong protective immunity against virus replication in the nasal cavity and lungs. In contrast, post-challenge treatment of mice with the monoclonal antibody Palivizumab two days after infection reduced viral replication in the nasal cavity at day 4, but only modestly reduced virus loads in the lungs by day 5. In contrast to RSV bioluminescence, plaque assay did not detect viral titers in lungs on day 5 in Palivizumab-treated animals. This difference between viral loads measured by the two assays was found to be due to coating of virions with the Palivizumab that blocked infection of target cells in vitro and shows importance of live imaging in evaluation of RSV therapeutics. This recombinant RSV based live imaging animal model is convenient and valuable tool that can be used to study host dissemination of RSV and evaluation of antiviral compounds and vaccines against RSV.     

Role of MHC class Ib molecule,H2-M3 in host immunity against tuberculosis

The MHC class I family comprises both classical (class Ia) and non-classical (class Ib) members. While the prime function of classical MHC class I molecules (MHC class Ia) is to present peptide antigens to pathogen-specific cytotoxic T cells, non-classical MHC-I (MHC class Ib) antigens perform diverse array of functions in both innate and adaptive immunity. Vaccines against intracellular pathogens such as Mycobacterium tuberculosis need to induce strong cellular immune responses. Recent studies have shown that MHC class I molecules play an important role in the protective immune response to M. tuberculosis infection. Both MHC Ia-restricted and MHC class Ib-restricted M. tuberculosis -reactive CD8⁺ T cells have been identified in humans and mice, but their relative contributions to immunity is still uncertain. Unlike MHC class Ia-restricted CD8⁺ T cells, MHC class Ib-restricted CD8⁺ T cells are constitutively activated in naive animals and respond rapidly to infection challenge, hence filling the temporal gap between innate and adaptive immunity. The present review article summarizes the general host immunity against M. tuberculosis infection highlighting the possible role of MHC class Ib molecule, H2-M3 and their ligands (N-formylated peptides) in protection against tuberculosis.     

Intranasal immunization with formalin-inactivated virus vaccine induces a broad spectrum of heterosubtypic immunity against influenza A virus infection in mice

It has been known that influenza A virus infection induces a cross-protective immunity against infection by viruses with different subtypes of viral envelope proteins, hemagglutinin (HA) and neuraminidase (NA). This heterosubtypic immunity is generally mediated by cytotoxic T lymphocytes (CTL) reactive to specific epitopes in the viral internal proteins, such as nucleoprotein and matrix protein. By contrast, immunization with inactivated virus antigens has been thought to be unable to generate heterosubtypic immunity, since inactivated antigens do not usually induce CTL responses. However, we show that intranasal immunization with formalin-inactivated intact virus, but not ether-split vaccines, induced a broad spectrum of heterosubtypic protective immunity in mice. The protection may be mediated by the mucosal immune response, most likely secretory IgA antibodies to the viral proteins. This approach may overcome limitations in the efficacy of inactivated influenza vaccines and confer potent immunity to humans against viruses with new pandemic potential.     

Single mucosal immunization of recombinant adenovirus-based vaccine expressing F1 protein fragment induces protective mucosal immunity against respiratory syncytial virus infection

Respiratory syncytial virus (RSV) is a major cause of severe lower respiratory tract disease in infancy and early childhood. Despite its importance as a pathogen, there is no licensed vaccine against RSV. The fusion (F) protein of RSV is a potentially important target for protective antiviral immune responses. Here, we studied the immune responses elicited by recombinant replication-deficient adenovirus (rAd)-based vaccines expressing the soluble F1 fragment of F protein (amino acids 155–524) in murine model. The expression of secreted F1 fragment by rAd was significantly increased by codon optimization. Strong mucosal IgA response was induced by single intranasal immunization of codon-optimized vaccine, rAd/F1co, but not by rAd/F1wt. A single intranasal immunization with rAd/F1co provided potent protection against subsequent RSV challenge. Interestingly, neither serum Ig nor T-cell response directed to F protein was detected in the rAd/F1co-immune mice, suggesting that protective immunity by rAd/F1co is mainly mediated through mucosal IgA induction. Indeed, co-delivery of cholera toxin B subunit significantly enhanced mucosal IgA responses by the optimized vaccine, which correlates with protective efficacy. Taken together, our data demonstrate that a single intranasal administration of rAd/F1co is sufficient for the protection and represents a promising prophylactic vaccination regimen against RSV infection.     

Induction of mucosal and systemic immunity against respiratory syncytial virus by inactivated virus supplemented with TLR9 and NOD2 ligands

Respiratory syncytial virus (RSV) infection is the most important viral cause of severe respiratory disease in infants and children worldwide and also forms a serious threat in the elderly. The development of RSV vaccine, however, has been hampered by the disastrous outcome of an earlier trial using an inactivated and parenterally administered RSV vaccine which did not confer protection but rather primed for enhanced disease upon natural infection. Mucosal administration does not seem to prime for enhanced disease, but non-replicating RSV antigen does not induce a strong mucosal immune response. We therefore investigated if mucosal immunization with inactivated RSV supplemented with innate receptor ligands, TLR9 (CpG ODN) and NOD2 (L18-MDP) through the upper or total respiratory tract is an effective and safe approach to induce RSV-specific immunity. Our data show that beta-propiolactone (BPL) inactivated RSV (BPL-RSV) supplemented with CpG ODN and L18-MDP potentiates activation of antigen-presenting cells (APC) in vitro, as demonstrated by NF-κB induction in a model APC cell line. In vivo, BPL-RSV supplemented with CpG ODN/L18-MDP ligands induces local IgA responses and augments Th1-signature IgG2a subtype responses after total respiratory tract (TRT), but less efficient after upper respiratory tract (intranasal, IN) immunization. Addition of TLR9/NOD2 ligands to the inactivated RSV also promoted affinity maturation of RSV-specific IgG antibodies and shifted T cell responses from mainly IL-5-secreting cells to predominantly IFN-γ-producing cells, indicating a Th1-skewed response. This effect was seen for both IN and TRT immunization. Finally, BPL-RSV supplemented with TLR9/NOD2 ligands significantly improved the protection efficacy against a challenge with infectious virus, without stimulating enhanced disease as evidenced by lack of eotaxin mRNA expression and eosinophil infiltration in the lung.We conclude that mucosal immunization with inactivated RSV antigen supplemented with TLR9/NOD2 ligands is a promising approach to induce effective RSV-specific immunity without priming for enhanced disease.     

Protection of mice against Friend retrovirus infection by vaccination with antigen-loaded, spleen-derived dendritic cells

Antigen-loaded dendritic cells (DC) have been shown to induce specific immune responses in vivo. In the current study we used Friend virus (FV) as a model to analyze whether a DC vaccine is capable of inducing protective immunity against retroviral infections. Mice were vaccinated twice with spleen-derived DC loaded with FV antigen. All control mice that received DC without antigen developed progressive leukemia after FV challenge. In contrast, five of the 14 vaccines were protected against infection, three recovered from FV-induced disease, and only six progressed to lethal leukemia. Animals that progressed to disease had high viral loads in blood and spleen similar to the control mice. Virus-specific antibody responses were not induced by DC vaccination. In contrast, protection correlated with a vaccine-induced CD8+ T-cell response directed against an immunodominant epitope of FV. CD8+ T-cells were critical for the protective effect of the DC vaccine, since in vivo depletion of these cells from immunized mice prevented their protection. Our results demonstrate that antigen-loaded DC can induce specific cellular immune responses and prevent retrovirus-induced disease.     

Live attenuated influenza vaccine (LAIV) impacts innate and adaptive immune responses

Influenza A infection induces a massive inflammatory response in the lungs that leads to significant illness and increases the susceptibility to secondary bacterial pneumonia. The most efficient way to prevent influenza infection is through vaccination. While inactivated vaccines induce protective levels of serum antibodies to influenza hemaglutinin (HA) and neuraminidase (NA) surface proteins, these are strain specific and offer little protection against heterosubtypic influenza viruses. In contrast, live attenuated influenza vaccines (LAIVs) induce a T cell response in addition to antibody responses against HA and NA surface proteins. Importantly, LAIV vaccination induces a response in a mouse model that protects against illness due to heterosubtypic influenza strains. While it is not completely clear what is the mechanism of action of LAIV heterosubtypic protection in humans, it has been shown that LAIV induces heterosubtypic protection in mice that is dependent upon a Type 1 immune response and requires CD8 T cells. In this study, we show that LAIV-induced immunity leads to significantly reduced viral titers and inflammatory responses in the lungs of mice following heterosubtypic infection. Not only are viral titers reduced in LAIV vaccinated mice, the amounts of inflammatory cytokines and chemokines in lung tissue are significantly lower. Additionally, we show that LAIV vaccination of healthy adults also induces a robust Type 1 memory response including the production of chemokines and cytokines involved in T cell activation and recruitment. Thus, our results indicate that LAIV vaccination functions by inducing immune memory which can act to modulate the immune response to subsequent heterosubtypic challenge by influencing both innate and adaptive responses.     

蚊虫对病原体的免疫机制研究

蚊虫是重要的虫媒疾病传播媒介,可传播多种疾病,如疟疾、登革热等,严重危害人类健康。媒介蚊虫的防治是控制此类传染病的重要措施。蚊虫依赖天然免疫系统抵御疟原虫、真菌、病毒等外源病原体的侵染。蚊虫免疫主要分为体液免疫和细胞免疫。补体识别激活系统、免疫信号通路、黑化反应和活性氧等途径均参与了对病原体的免疫反应。现就媒介蚊虫抵御疟原虫和真菌等病原体免疫应答机制的最新进展进行综述。这将为发展新的蚊虫控制策略提供理论支持。