Neonates have an immature immune system, which cannot adequately protect against infectious diseases. Early in life, immune protection is accomplished by maternal antibodies transferred from mother to offspring. However, decaying maternal antibodies inhibit vaccination as is exemplified by the inhibition of seroconversion after measles vaccination. This phenomenon has been described in both human and veterinary medicine and is independent of the type of vaccine being used. This review will discuss the use of animal models for vaccine research. I will review clinical solutions for inhibition of vaccination by maternal antibodies, and the testing and development of potentially effective vaccines. These are based on new mechanistic insight about the inhibitory mechanism of maternal antibodies. Maternal antibodies inhibit the generation of antibodies whereas the T cell response is usually unaffected. B cell inhibition is mediated through a cross-link between B cell receptor (BCR) with the Fcγ-receptor IIB by a vaccine–antibody complex. In animal experiments, this inhibition can be partially overcome by injection of a vaccine-specific monoclonal IgM antibody. IgM stimulates the B cell directly through cross-linking the BCR via complement protein C3d and antigen to the complement receptor 2 (CR2) signaling complex. In addition, it was shown that interferon alpha binds to the CD21 chain of CR2 as well as the interferon receptor and that this dual receptor usage drives B cell responses in the presence of maternal antibodies. In lieu of immunizing the infant, the concept of maternal immunization as a strategy to protect neonates has been proposed. This approach would still not solve the question of how to immunize in the presence of maternal antibodies but would defer the time of infection to an age where infection might not have such a detrimental outcome as in neonates. I will review successful examples and potential challenges of implementing this concept.
Internal N 6 -methyladenosine (m 6 A) modification is one of the most common and abundant modifications of RNA. However, the biological role(s) of viral RNA m 6 A remains elusive. Using human metapneumovirus (hMPV) as a model, we demonstrate that m 6 A serves as a molecular marker for innate immune discrimination of self from nonself RNAs. We show that hMPV RNAs are m 6 A methylated and that viral m 6 A methylation promotes hMPV replication and gene expression. Inactivating m 6 A addition sites with synonymous mutations or demethylase resulted in m 6 A deficient recombinant hMPVs and virion RNAs that induced significantly higher expression of type I interferon (IFN) which was dependent on the cytoplasmic RNA sensor RIG-I, not MDA5. Mechanistically, m 6 A-deficient virion RNA induces higher expression of RIG-I, binds more efficiently to RIG-I, and facilitates the conformational change of RIG-I, leading to enhanced IFN expression. Furthermore, m 6 A-deficient rhMPVs triggered higher IFN in vivo and were significantly attenuated in cotton rats yet retained high immunogenicity. Collectively, our results highlight that (i) virus acquires m 6 A in their RNAs as a means of mimicking cellular RNA to avoid detection by innate immunity; and (ii) viral RNA m 6 A can serve as a target to attenuate hMPV for vaccine purposes.
Three discrete activities of the paramyxovirus hemagglutinin-neuraminidase (HN) protein, receptor binding, receptor cleaving (neuraminidase), and triggering of the fusion protein, each affect the promotion of viral fusion and entry. For human parainfluenza virus type 3 (HPIV3), the effects of specific mutations that alter these functions of the receptor-binding protein have been well characterized using cultured monolayer cells, which have identified steps that are potentially relevant to pathogenesis. In the present study, proposed mechanisms that are relevant to pathogenesis were tested in natural host cell cultures, a model of the human airway epithelium (HAE) in which primary HAE cells are cultured at an air-liquid interface and retain functional properties. Infection of HAE cells with wild-type HPIV3 and variant viruses closely reflects that seen in an animal model, the cotton rat, suggesting that HAE cells provide an ideal system for assessing the interplay of host cell and viral factors in pathogenesis and for screening for inhibitory molecules that would be effective in vivo. Both HNs receptor avidity and the function and timing of F activation by HN require a critical balance for the establishment of ongoing infection in the HAE, and these HN functions independently modulate the production of active virions. Alterations in HNs F-triggering function lead to the release of noninfectious viral particles and a failure of the virus to spread. The finding that the dysregulation of F triggering prohibits successful infection in HAE cells suggests that antiviral strategies targeted to HNs F-triggering activity may have promise in vivo.Paramyxoviruses are enveloped viruses that enter cells by fusing directly with the cell membrane. During entry, the viral surface glycoproteins hemagglutinin-neuraminidase (HN) (the receptor-binding molecule) and F (the fusion protein) cooperate in a highly specific way to mediate fusion upon receptor binding. To understand these mechanisms, elucidate how paramyxoviruses enter cells, and develop strategies to prevent or treat infection, we study human parainfluenza virus (HPIV), an important cause of croup and bronchiolitis in children. Our results have uncovered fundamental roles of the receptor-binding protein in paramyxovirus fusion and principles of coordinated interaction between the glycoproteins during the viral life cycle.To understand how the diverse functions of the viral glycoproteins are regulated during the viral life cycle, we have used viruses bearing variant HN molecules with mutations at the binding/F-triggering site (and/or the primary receptor-binding site) to study how this molecule works to trigger F (2,3,7,10,15,18,20). The correct timing of F activation (triggering) by HN is essential for entry. For infection to occur, triggering must occur only when F is in proximity to the target cell membrane, and we propose that the regulation of F triggering is essential for the survival of the virus. The outcome of infection is determined by the target cell's propertie...
Surface-contact-mediated signaling induced by the measles virus (MV) fusion and hemagglutinin glycoproteins is necessary and sufficient to induce T-cell unresponsiveness in vitro and in vivo. To define the intracellular pathways involved, we analyzed interleukin (IL)-2R signaling in primary human T cells and in Kit-225 cells. Unlike IL-2-dependent activation of JAK/STAT pathways, activation of Akt kinase was impaired after MV contact both in vitro and in vivo. MV interference with Akt activation was important for immunosuppression, as expression of a catalytically active Akt prevented negative signaling by the MV glycoproteins. Thus, we show here that MV exploits a novel strategy to interfere with T-cell activation during immunosuppression.
Summary T he hispid cotton rat (Sigm o d o n h ispid us)has been a longstanding laboratory anim al model of infectious diseases. In this review, the most common usage of hispid cotton rats as models of infectious diseases is discussed in detail and all organisms, which have been shown to infect cotton rats, are listed. A state of the art overview is given on handling and maintenance of hispid cotton rats as well as experimental techniques such as narcosis and blood withdrawal. Most im portantly, through the development of new reagents, the hispid cotton rat can be used to study im mune responses against the respective pathogen. Hispid cotton rat cytokine and chemokine genes have been sequenced and cotton rat speci®c antibodies and cell lines have been produced which in connection with the establishment of immunological methods should facilitate the use of hispid cotton rats as anim al models in the pathogenesis of infectious diseases.
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