The cotton rat model of respiratory viral infections

Development of successful vaccines against human infectious diseases depends on using appropriate animal models for testing vaccine efficacy and safety. For some viral infections the task is further complicated by the frequently changing genetic make-up of the virus, as in the case of influenza, or by the existence of the little-understood phenomenon of vaccine-enhanced disease, as in the case of respiratory syncytial virus (RSV). The cotton rat Sigmodon hispidus has been used for years as an excellent small animal model of the RSV vaccine-enhanced disease. Recently, using cotton rats, we have demonstrated that vaccination against another paramyxovirus, human metapneumovirus (hMPV), can also lead to vaccine-enhanced disease. In addition to the study of paramyxoviruses, S. hispidus presents important advantages for the study of orthomyxoviruses such as influenza. The cotton rat is susceptible to infection with unadapted human influenza strains, and heterosubtypic immunity to influenza can be evoked in S. hispidus. The mechanisms of influenza, RSV, and hMPV pathogenesis and immunity can now be investigated in the cotton rat with the development of species-specific reagents for this animal model.     

The contribution of animal models to the understanding of the host range and virulence of influenza A viruses

Since ferrets were first used in 1933 during the initial isolation of influenza A viruses, animal models have been critical for influenza research. The following review discusses the contribution of mice, ferrets, and non-human primates to the study of influenza virus host range and pathogenicity.     

Annual vaccination against influenza virus hampers development of virus-specific CD8⁺ T cell immunity in children

Infection with seasonal influenza A viruses induces immunity to potentially pandemic influenza A viruses of other subtypes (heterosubtypic immunity). We recently demonstrated that vaccination against seasonal influenza prevented the induction of heterosubtypic immunity against influenza A/H5N1 virus induced by infection with seasonal influenza in animal models, which correlated with the absence of virus-specific CD8(+) T cell responses. Annual vaccination of all healthy children against influenza has been recommended, but the impact of vaccination on the development of the virus-specific CD8(+) T cell immunity in children is currently unknown. Here we compared the virus-specific CD8(+) T cell immunity in children vaccinated annually with that in unvaccinated children. In the present study, we compared influenza A virus-specific cellular and humoral responses of unvaccinated healthy control children with those of children with cystic fibrosis (CF) who were vaccinated annually. Similar virus-specific CD4(+) T cell and antibody responses were observed, while an age-dependent increase of the virus-specific CD8(+) T cell response that was absent in vaccinated CF children was observed in unvaccinated healthy control children. Our results indicate that annual influenza vaccination is effective against seasonal influenza but hampers the development of virus-specific CD8(+) T cell responses. The consequences of these findings are discussed in the light of the development of protective immunity to seasonal and future pandemic influenza viruses.     

Avian influenza h6 viruses productively infect and cause illness in mice and ferrets

Influenza pandemic preparedness has focused on influenza virus H5 and H7 subtypes. However, it is not possible to predict with certainty which subtype of avian influenza virus will cause the next pandemic, and it is prudent to include other avian influenza virus subtypes in pandemic preparedness efforts. An H6 influenza virus was identified as a potential progenitor of the H5N1 viruses that emerged in Hong Kong in 1997. This virus continues to circulate in the bird population in Asia, and other H6 viruses are prevalent in birds in North America and Asia. The high rate of reassortment observed in influenza viruses and the prevalence of H6 viruses in birds suggest that this subtype may pose a pandemic risk. Very little is known about the replicative capacity, immunogenicity, and correlates of protective immunity for low-pathogenicity H6 influenza viruses in mammals. We evaluated the antigenic and genetic relatedness of 14 H6 influenza viruses and their abilities to replicate and induce a cross-reactive immune response in two animal models: mice and ferrets. The different H6 viruses replicated to different levels in the respiratory tracts of mice and ferrets, causing varied degrees of morbidity and mortality in these two models. H6 virus infection induced similar patterns of neutralizing antibody responses in mice and ferrets; however, species-specific differences in the cross-reactivity of the antibody responses were observed. Overall, cross-reactivity of neutralizing antibodies in H6 virus-infected mice did not correlate well with protection against heterologous wild-type H6 viruses. However, we have identified an H6 virus that induces protective immunity against viruses in the North American and Eurasian lineages.     

The human model: a genetic dissection of immunity to infection in natural conditions

Tremendous progress has been achieved in developmental, cellular and molecular immunology in the past 20 years, largely due to studies using the mouse as a model system and the arrival of molecular genetics. Immunology is now faced with a difficult challenge. What are the functions of the individual cells and molecules in achieving immunity to infection? Renewed interest in animal models of disease has provided considerable insight in this area, but such models of infection suffer from the inherent limitation of being experimental. In humans, the complex host-environment interaction occurs in natural, as opposed to experimental, conditions. The human model is therefore an indispensable complement to animal models, as it allows an observational genetic dissection of immunity to infection.     

Assessing Mathematical Models of Influenza Infections Using Features of the Immune Response

The role of the host immune response in determining the severity and duration of an influenza infection is still unclear. In order to identify severity factors and more accurately predict the course of an influenza infection within a human host, an understanding of the impact of host factors on the infection process is required. Despite the lack of sufficiently diverse experimental data describing the time course of the various immune response components, published mathematical models were constructed from limited human or animal data using various strategies and simplifying assumptions. To assess the validity of these models, we assemble previously published experimental data of the dynamics and role of cytotoxic T lymphocytes, antibodies, and interferon and determined qualitative key features of their effect that should be captured by mathematical models. We test these existing models by confronting them with experimental data and find that no single model agrees completely with the variety of influenza viral kinetics responses observed experimentally when various immune response components are suppressed. Our analysis highlights the strong and weak points of each mathematical model and highlights areas where additional experimental data could elucidate specific mechanisms, constrain model design, and complete our understanding of the immune response to influenza.     

Vaccine-Induced Boosting of Influenza Virus-Specific CD4 T Cells in Younger and Aged Humans

Current yearly influenza virus vaccines induce strain-specific neutralizing antibody (NAb) responses providing protective immunity to closely matched viruses. However, these vaccines are often poorly effective in high-risk groups such as the elderly and challenges exist in predicting yearly or emerging pandemic influenza virus strains to include in the vaccines. Thus, there has been considerable emphasis on understanding broadly protective immunological mechanisms for influenza virus. Recent studies have implicated memory CD4 T cells in heterotypic immunity in animal models and in human challenge studies. Here we examined how influenza virus vaccination boosted CD4 T cell responses in younger versus aged humans. Our results demonstrate that while the magnitude of the vaccine-induced CD4 T cell response and number of subjects responding on day 7 did not differ between younger and aged subjects, fewer aged subjects had peak responses on day 14. While CD4 T cell responses were inefficiently boosted against NA, both HA and especially nucleocaspid protein- and matrix-(NP+M) specific responses were robustly boosted. Pre-existing CD4 T cell responses were associated with more robust responses to influenza virus NP+M, but not H1 or H3. Finally pre-existing strain-specific NAb decreased the boosting of CD4 T cell responses. Thus, accumulation of pre-existing influenza virus-specific immunity in the form of NAb and cross-reactive T cells to conserved virus proteins (e.g. NP and M) over a lifetime of exposure to infection and vaccination may influence vaccine-induced CD4 T cell responses in the aged.     

Influenza pandemic waves under various mitigation strategies with 2009 H1N1 as a case study

A significant feature of influenza pandemics is multiple waves of morbidity and mortality over a few months or years. The size of these successive waves depends on intervention strategies including antivirals and vaccination, as well as the effects of immunity gained from previous infection. However, the global vaccine manufacturing capacity is limited. Also, antiviral stockpiles are costly and thus, are limited to very few countries. The combined effect of antivirals and vaccination in successive waves of a pandemic has not been quantified. The effect of acquired immunity from vaccination and previous infection has also not been characterized. In times of a pandemic threat countries must consider the effects of a limited vaccine, limited antiviral use and the effects of prior immunity so as to adopt a pandemic strategy that will best aid the population. We developed a mathematical model describing the first and second waves of an influenza pandemic including drug therapy, vaccination and acquired immunity. The first wave model includes the use of antiviral drugs under different treatment profiles. In the second wave model the effects of antivirals, vaccination and immunity gained from the first wave are considered. The models are used to characterize the severity of infection in a population under different drug therapy and vaccination strategies, as well as school closure, so that public health policies regarding future influenza pandemics are better informed.     

小鼠、大鼠、豚鼠和沙鼠对禽流感病毒致病敏感性的比较初报

目的比较不同物种和品系的哺乳类实验动物对H5N1禽流感病毒(AIV)致病的敏感性。方法对不同动物经鼻腔接毒,然后通过体温、体重、临床症状、病理变化、病毒分离和抗体测定进行比较分析。结果在实验的4个不同物种共7个品系的哺乳动物中,小鼠对AIV较豚鼠、沙鼠和大鼠敏感。结论ICR和NIH小鼠适宜用来制作AIV感染的动物模型。     

H9N2亚型猪流感病毒感染BALB/c小鼠动物模型的建立

目的建立H9N2亚型猪流感病毒感染BALB/c小鼠动物模型,为研究病毒致病机制提供模型动物。方法通过滴鼻的方法将H9N2亚型猪流感病毒感染BALB/c小鼠,观察小鼠的症状和组织病理变化。结果 BALB/c小鼠的临床症状明显,病理变化典型。结论 H9N2亚型猪流感病毒感染BALB/c小鼠的疾病模型成功建立。     

Experimental influenzal and tuberculous infections under conditions of specific and nonspecific immunosuppression]

The course of influenza and tuberculosis infections under the conditions of disturbances in the immune response of experimental animals has been studied. As revealed in the survival test, the induction of secondary T- and B-cell-mediated immunodeficiency in mice leads to an increase in the sensitivity of the body to influenza virus, especially in cases of T-cell-mediated immunodeficiency. The injection of BCG in combination with cyclophosphamide into mice induces tolerance to this antigen in the animals; this tolerance has a "split" character, i.e. it affects only T-cell-mediated, but not humoral immunity. The induction of T-cell-mediated immunodeficiency or tolerance to BCG in mice has been shown (in the survival test) to lead to the development of the sensitivity of the animals to experimental tuberculosis infection. B-cell-mediated immunodeficiency did not influence the animal survival rate.     

Influenza virus evades innate and adaptive immunity via the NS1 protein

Both antibodies and T cells contribute to immunity against influenza virus infection. However, the generation of strong Th1 immunity is crucial for viral clearance. Interestingly, we found that human dendritic cells (DCs) infected with influenza A virus have lower allospecific Th1-cell stimulatory abilities than DCs activated by other stimuli, such as lipopolysaccharide and Newcastle disease virus infection. This weak stimulatory activity correlates with a suboptimal maturation of the DCs following infection with influenza A virus. We next investigated whether the influenza A virus NS1 protein could be responsible for the low levels of DC maturation after influenza virus infection. The NS1 protein is an important virulence factor associated with the suppression of innate immunity via the inhibition of type I interferon (IFN) production in infected cells. Using recombinant influenza and Newcastle disease viruses, with or without the NS1 gene from influenza virus, we found that the induction of a genetic program underlying DC maturation, migration, and T-cell stimulatory activity is specifically suppressed by the expression of the NS1 protein. Among the genes affected by NS1 are those coding for macrophage inflammatory protein 1beta, interleukin-12 p35 (IL-12 p35), IL-23 p19, RANTES, IL-8, IFN-alpha/beta, and CCR7. These results indicate that the influenza A virus NS1 protein is a bifunctional viral immunosuppressor which inhibits innate immunity by preventing type I IFN release and inhibits adaptive immunity by attenuating human DC maturation and the capacity of DCs to induce T-cell responses. Our observations also support the potential use of NS1 mutant influenza viruses as live attenuated influenza virus vaccines.     

Role of immune cytolysis and its thymosin stimulation in experimental influenza

In experiments on C57BL and CC57W mice the acute or chronic course of experimental influenza infection has been shown to correlate with the activity of immune cytolysis. At a low level of the cytolytic activity of T-lymphocytes the prolonged persistence of influenza virus develops. The stimulation of cell-mediated immunity with thymosin prevents the development of chronic influenza infection.     

Rats, mice and men - models for immune effector mechanisms against schistosomiasis

Experimental studies have demonstrated the diversity of immune effector mechanisms against schistosomes. Among the various animal models, the rat appears as an excellent experimental system for investigation of antibody-mediated immunity to Schistosoma mansoni. Rat monoclonal antibodies have allowed the identification of effector and regulatory mechanisms operating in human infection, together with the characterization of protective antigens, leading to promising approaches to vaccine development.     

Peculiarities of influenza infection caused by highly and poorly immunogenic strains of influenza virus

The authors studied the peculiarities of the course of experimental influenza infection induced by the administration of highly and poorly immunogenic strains of influenza virus to mice. Influenza viruses with varying immunogenic activity were obtained from the vaccine strain A/Victoria/35/72/50 (H3N2) by immunoselection modelling the process of natural selection. The administration of strains with high and poor immunogenicity to mice of the F1 (CBA X C57B1) line led to the development of acute influenza infection accompanied by reproduction of viruses in the tissue of the lungs and other internal organs. The poorly immunogenic strain 5/II-Victoria, unlike the initial virus A/Victoria/35 and its highly immunogenic variant 2/I-Victoria, is able to circulate for a long time in the organism of the infected animal causing development of chronic inflammatory processes and stimulating the formation of neoplasms. Immunogenicity is thus one of the factors determining the character of the course of experimental influenza infection. A conclusion was drawn concerning the epidemiological and aetiological importance of viruses with reduced immunogenicity and their role in the evolution of influenza virus. It is presumed that reduced immunogenicity is one of the adaptation mechanisms of aggression permitting the population of influenza virus to escape control by specific humoral immunity.     

Influenza type A virus escape mutants emerge in vivo in the presence of antibodies to the ectodomain of matrix protein 2

The ectodomain of matrix protein 2 (M2e) of human influenza type A virus strains has remained remarkably conserved since 1918. Because M2e-specific immunity has been shown to decrease morbidity and mortality associated with influenza virus infection in several animal models and because natural infection and current vaccines do not appear to induce a good M2e-specific antibody (Ab) response, M2e has been considered as potential vaccine for inducing cross-reactive protection against influenza type A viruses. The high degree of structural conservation of M2e could in part be the consequence of a poor M2e-specific Ab response and thus the absence of pressure for change. To assess this possibility, we studied the course of infection in SCID mice in the presence or absence of passive M2e-specific monoclonal Abs (MAbs). We found that virus mutants with antigenic changes in M2e emerged in 65% of virus-infected mice treated with M2e-specific but not control MAbs. However, the diversity of escape mutants was highly restricted since only two types were isolated from 22 mice, one with a proline-to-leucine and the other with a proline-to-histidine interchange at amino acid position 10 of M2e. The implications of these findings for the use of M2e as a broadly protective vaccine are discussed.     

体液免疫抗白念珠菌感染的研究

探讨抗白念珠菌IgY及其免疫血清对多种动物模型感染白念珠菌的保护作用。制备烧伤继发感染白念珠菌大鼠、白念珠菌性阴道炎小鼠及免疫功能低下小鼠多种动物感染模型 ,分别应用抗白念珠菌IgY、鼠免疫血清和生理盐水对照 ,观察比较各自的作用。抗白念珠菌IgY对烧伤继发感染白念珠菌大鼠及白念珠菌性阴道炎小鼠均有明显的保护作用 ;鼠免疫血清则对阻止远程靶器官的白念珠菌扩散有较好的作用。体液免疫成份抗白念珠菌IgY及其免疫血清对烧伤继发感染白念珠菌大鼠、白念珠菌性阴道炎小鼠及免疫功能低下小鼠均有良好的保护作用。     

The benefits of using diverse animal models for studying pertussis

Pertussis, a respiratory disease caused by infection with Bordetella pertussis, represents one of the most devastating diseases in infants and young children worldwide. Significant research efforts over the last five decades have led to the introduction of two types of vaccines, which are now available worldwide and which have significantly reduced the global incidence of pertussis. The use of animal models and, in particular, the mouse model has benefited in the development of these vaccines tremendously. However, open questions regarding the duration of immunity, the type of immune response needed for protection and the role of mucosal and innate immunity in disease protection still remain. Here, we review the various animal models available currently and their benefits for studying this important disease.     

Structural basis of Blastomyces Endoglucanase-2 adjuvancy in anti-fungal and -viral immunity

The development of safe subunit vaccines requires adjuvants that augment immunogenicity of non-replicating protein-based antigens. Current vaccines against infectious diseases preferentially induce protective antibodies driven by adjuvants such as alum. However, the contribution of antibody to host defense is limited for certain classes of infectious diseases such as fungi, whereas animal studies and clinical observations implicate cellular immunity as an essential component of the resolution of fungal pathogens. Here, we decipher the structural bases of a newly identified glycoprotein ligand of Dectin-2 with potent adjuvancy, Blastomyces endoglucanase-2 (Bl-Eng2). We also pinpoint the developmental steps of antigen-specific CD4⁺ and CD8⁺ T responses augmented by Bl-Eng2 including expansion, differentiation and tissue residency. Dectin-2 ligation led to successful systemic and mucosal vaccination against invasive fungal infection and Influenza A infection, respectively. O-linked glycans on Bl-Eng2 applied at the skin and respiratory mucosa greatly augment vaccine subunit- induced protective immunity against lethal influenza and fungal pulmonary challenge.     

Experimental Infection of Macaques with a Wild Water Bird-Derived Highly Pathogenic Avian Influenza Virus (H5N1)

Highly pathogenic avian influenza virus (HPAIV) continues to threaten human health. Non-human primate infection models of human influenza are desired. To establish an animal infection model with more natural transmission and to determine the pathogenicity of HPAIV isolated from a wild water bird in primates, we administered a Japanese isolate of HPAIV (A/whooper swan/Hokkaido/1/2008, H5N1 clade 2.3.2.1) to rhesus and cynomolgus monkeys, in droplet form, via the intratracheal route. Infection of the lower and upper respiratory tracts and viral shedding were observed in both macaques. Inoculation of rhesus monkeys with higher doses of the isolate resulted in stronger clinical symptoms of influenza. Our results demonstrate that HPAIV isolated from a water bird in Japan is pathogenic in monkeys by experimental inoculation, and provide a new method for HPAIV infection of non-human primate hosts, a good animal model for investigation of HPAIV pathogenicity.