Global ETD Search

1	The role of IL-17A in modulating B cell response during influenza virus infection Wang, Xiaohui, 王晓辉 January 2014 (has links) Interleukin-17A (IL-17A)is an important pro-inflammatory cytokine that plays a critical role in host defenses against diverse pathogens. Studies have shown that IL-17Aplays protective role against sub-lethal H1 and H3 subtypes influenza infections, but it is unclear about the role of IL-17A in the highly pathogenic H5N1 and lethal H1N1 influenza virus infection. B cell is an important effector cell type in anti-influenza immunity. Although roles of B cell in influenza infection have been extensively investigated, it is unclear whether and how IL-17AregulatesB cell response during influenza infection. I examined the role of IL-17A against influenza infection by challengingIL-17A knockout (KO) and wild-type (WT) mice with highly pathogenic H5N1 and lethal H1N1 influenza viruses. Following challenge, IL-17AKO mice exhibited significantly lower survival rate, profoundly reduced body weight, more severe tissue damage and higher viral burden in the lung tissues. These evidences suggest that IL-17Aplays a protective role in lethal influenza infection. To study whether IL-17Amodulates B cell response against influenza, I found that both B-1a and B-2 cells were detected in the lung tissue and pulmonary draining lymph node, Mediastinal lymph node (MedLN),as early as 2days post-infection. Meanwhile, B-1a cells predominantly contributed to the early virus-specific IgM in the respiratory tract. However, virus-specific IgM markedly reduced in IL-17A KO mice when compared with WT controls. Adoptive transfer of B-1a cells or B-1a cell-derived antibodies conferred protection in IL-17A KO mice. These results demonstrate that IL-17A plays a critical role in modulating early antibody production of B-1a cells against lethal influenza infection. To further elucidate how IL-17A regulates B-1a cell response, I observed that B-1a cells migrated into MedLN and lung tissues during infection and underwent plasmacytic differentiation with increased antibody production in airways. IL-17A deficiency impaired these processes of B-1a cells, while intra-nasally instillation of IL-17A restored B-1a cell response by promoting both B-1a cell migration and plasmacytic differentiation. By inducing blimp-1 expression in B-1a cells in an NF-κB dependent pathway, IL-17A directly promoted plasmacytic differentiation of B-1a cells both in vivo and in vitro. Furthermore, chromatin immuno-precipitation analysis confirmed that NF-κB directly bound to the promoter of blimp-1 gene and promoted blimp-1 expression in B-1a cells following IL-17A stimulation. To determine the functional significance of IL-17A signaling in modulating B cell response against influenza infection, I first uncovered markedly reduced B cell response, predominantly B-1a cell response in IL-17A KO mice, showing reduced local migration and impaired plasmacytic differentiation in the early stage of infection. Next, intra-nasal administration of IL-17A into IL-17A KO mice significantly restored this B-1a cell response. Moreover, I detected expression of IL-17A receptor in B-1a cells. IL-17A treatment could promote antibody production from B-1a cells by inducing blimp-1 expression in an NF-κB dependent pathway. Taken together, these findings identify a novel role of IL-17A in actingas an immune modulator of B cell response against influenza infection, which will contribute to a fuller understanding of B cell biology and anti-viral response in host defense. / published_or_final_version / Pathology / Doctoral / Doctor of Philosophy Influenza - Immunological aspects Interleukins
2	Identification of CLEC5A in modulating host immune response after influenza A virus infection Teng, Ooiean, 丁瑋嫣 January 2014 (has links) Human infections with influenza A virus (IAV) exhibit mild to severe clinical outcomes as a result of differential virus-host interactions. C-type lectin receptors (CLRs) are pattern recognition receptors that may sense carbohydrates, proteins, or lipids derived from infected hosts or the invading microbes including bacteria, viruses, fungi, or parasites. CLR-viral interaction may lead to increased viral entry and spread; furthermore, their interactions have been reported to trigger downstream signaling that further modulates host’s innate immune responses through the induction of pro-inflammatory cytokines. To date, DC-SIGN and DC-SIGNR have been shown to mediate IAV entry; however, the potential interactions between other human transmembrane CLRs with IAV have not yet been systematically investigated. We utilized lentiviral-based pseudoparticles expressing influenza hemagglutinin (HA) to examine the binding potential between HA and a panel of human CLRs expressed in soluble form. CLEC5A was identified as a potential interacting target with the HA proteins derived from a highly pathogenic avian H5N1 virus A/VN/1203/04 (VN1203) or a human seasonal H1N1 virus A/HK/54/98 (HK5498), albeit at different binding intensity. Applying siRNA gene silencing, we confirmed that CLEC5A did not enhance influenza entry in human monocytic U937 cells that constitutively express CLEC5A or in the lentiviral-transduced stable CHO and CHO-Lec2 cells that overly expressed CLEC5A. To investigate downstream signaling upon engagement of CLEC5A to influenza virus, M-CSF or GM-CSF differentiated human macrophages with high expression levels of CLEC5A and DAP12, a known adaptor protein for CLEC5A upon phosphorylation to initiate signal transduction, was subjected to CLEC5A siRNA gene silencing followed by infection with recombinant A/PR/8/34 virus expressing HA and NA derived from either VN1203 (H5N1) or HK5498 (H1N1) viruses. RG-PR8xVN1203HA,NA (H5N1) exhibited a higher infectivity and induced higher levels of pro-inflammatory cytokines (TNF-( and IFN-α) and chemokines (IP-10, MCP-1, MIG and MIP-1α) secretion in M-CSF or GM-CSF differentiated macrophages while compared to that of the RG-PR8xHK5498HA,NA (H1N1) virus. Knocking-down CLEC5A in macrophages led to a universal reduction of cytokines and chemokines secretion after infection with either the RG-PR8xVN1203HA,NA, RG-PR8xHK5498HA,NA, RG-A/VN/1203/04 (H5N1) or A/Shanghai/2/2014 (H7N9) viruses, suggesting that CLEC5A plays a role as cytokine and chemokine amplifier after influenza infection. Since DAP12 phosphorylation is known to activate downstream signaling via Spleen tyrosine kinase (Syk), pre-incubation of M-CSF macrophages with a Syk inhibitor (Bay 61-3606) also lead to a significant reduction of TNF-α and IP-10 in infected macrophages. A higher mortality was observed in CLEC5A-/- mice while compared to the wild-type C57BL/6 mice after challenged with a lethal dose of RG-A/VN/1203/04 (H5N1) influenza virus suggesting that CLEC5A as a host innate response amplifier play a protective role upon influenza infection. In conclusion, we have identified CLEC5A as a novel host factor for influenza pathogenesis by modulating host innate inflammatory response. / published_or_final_version / Public Health / Doctoral / Doctor of Philosophy Influenza - Immunological aspects Lectins - Immunology
3	The role of mannose binding lectin in influenza virus infection Ling, Man-to., 凌文韜. January 2009 (has links) published_or_final_version / Paediatrics and Adolescent Medicine / Master / Master of Philosophy Mannose. Lectins. Influenza A virus. Influenza - Immunological aspects.
4	The immunological roles of human gammadelta T lymphocytes in influenzavirus infection Qin, Gang, 秦刚 January 2011 (has links) published_or_final_version / Paediatrics and Adolescent Medicine / Doctoral / Doctor of Philosophy T cells. Lymphocytes. Influenza - Immunological aspects.
5	The study of immune response to co-infection of influenza virus and Streptococcus pneumoniae 吳越, Wu, Yuet January 2013 (has links) Influenza is a leading cause of respiratory disease worldwide. During pandemic and seasonal influenza, secondary Streptococcus pneumoniae infection is a severe complication that contributes to morbidity and mortality. With the clinical significance of this co-infection, it is imperative to understand the disease mechanisms and how our immune system would be modulated in dealing with the dual infection. First, in vivo co-infection model was established. Mice were sequentially infected with influenza virus and then Streptococcus pneumoniae. Co-infected mice lost their body weight significantly and had 100% mortality, whereas mice infected with either influenza virus or pneumococcus alone lost their body weight transiently and all recovered from the infection. Then, lung inflammatory response during the co-infection was examined. Although it is a common phenomenon that co-infection enhances inflammation, the kinetic of, and the relative contribution of influenza virus or pneumococcus to the lung inflammation is not well defined. Therefore, this study characterized the general lung inflammatory environment after co-infection. It was found that influenza virus and pneumococcus differentially modulated inflammatory response in terms of kinetics, leukocyte infiltration and cytokine production. At the early time point after co-infection, pneumococcal infection contributed more than the influenza virus infection to enhance inflammatory cytokine and neutrophil infiltrating the lung. At the later time point after co-infection, both influenza virus and pneumococcus contributed to synergistically increase inflammatory cytokine and macrophage infiltrating the lung. Influenza virus infection induced IFN-γ that contributed to the elevated IFN-γ level in co-infected mice. Influenza virus and pneumococcus synergistically increased Th2 associated cytokine including IL-4, IL-5, and IL-10. These up-regulated immune responses might contribute to the severe lung pathology. Next, adaptive immunity to co-infection was examined. Literature studying co-infection often reports how prior influenza virus infection impairs the immune response against subsequent bacterial infection. However, whether and how secondary pneumococcal infection would affect the immunity to the initial influenza virus is unknown. Therefore this study investigated the modulation of immunity to influenza virus by secondary pneumococcal infection. It was found that co-infection significantly enhanced virus titer in lung and depleted the number of cell in spleen. Secondary pneumococcal infection after influenza decreased influenza virus specific IgG in the lung and peripheral blood. The reduced level of virus specific IgG was associated with the decrease in the number and the percentage of follicular B cell and CD4 T follicular helper cell through both pneumococcal capsular polysaccharide dependent and independent manner. Treating co-infected mice with immune serum containing influenza virus specific IgG successfully improved survival, which suggested the important protective function of virus specific IgG to the co-infection. Taken together, these data suggested that secondary pneumococcal infection impairs the antibody response to influenza virus, which might enhance mortality after co-infection. In conclusion, this study provides new insight to understand the pathogenesis of co-infection, reveals the general lung inflammatory environment, highlights the negative role of pneumococcus to impair virus control and explores novel treatment for the co-infection. / published_or_final_version / Paediatrics and Adolescent Medicine / Doctoral / Doctor of Philosophy Influenza - Immunological aspects
6	Immune response of human monocyte-derived dendritic cells to co-infection of influenza virus and Streptococcus pneumoniae Wu, Yuet., 吳越. January 2010 (has links) published_or_final_version / Paediatrics and Adolescent Medicine / Master / Master of Philosophy Dendritic cells. Influenza - Immunological aspects.
7	The role of mannose binding lectin in pandemic H1N1 influenza virus infection Ling, Man-to., 凌文韜. January 2012 (has links) abstract / Paediatrics and Adolescent Medicine / Doctoral / Doctor of Philosophy Mannose. Lectins. Influenza A virus. H1N1 influenza - Immunological aspects.
8	The role of mannose binding lectin in pandemic H1N1 influenza virus infection Ling, Man-to, 凌文韜 January 2012 (has links) Mannose-binding lectin (MBL) functions as pattern recognition molecule to mediate first-line host defense against invading pathogens. Although MBL is well-known for its anti-bacterial action, its role towards virus infection is less comprehensively understood. In 2009, the pandemic H1N1 2009 (pdmH1N1) influenza A virus caused more than 18,000 deaths worldwide and is still circulating in human community as a seasonal strain. In this study, the role of MBL in pdmH1N1 infection was investigated. Using in vitro microtiter capture assay, MBL was found to bind to pdmH1N1 virus via its carbohydrate recognition domain. Under transmission electron microscope (TEM), MBL was clearly visible on the surface of pdmH1N1 virus. By infecting C57B6/J wild-type (WT) and MBL knockout (KO) mice with a sub-lethal dose of pdmH1N1 virus, WT mice displayed greater weight loss and more severe lung damage than MBL KO mice. Using flow cytometry-based profiling analysis of the lung homogenates isolated from infected mice, a variety of proinflammatory cytokines and chemokines were found to be significantly up-regulated. These results indicate that the presence of MBL can cause excess proinflammatory cytokine production and result in a more severe pdmH1N1 infection. To provide physiologically relevant insight into the immunomodulating role of MBL, the investigation was further extended to the use of human cell line model. Infection of A549 cells, which is a human lung epithelial cell line, with MBL-bound pdmH1N1 virus elevated the production of MCP1, RANTES and IL-8 significantly more than unbound pdmH1N1 infection. The increased production of chemokines also enhanced recruitment of monocytes as demonstrated by transwell migration assay. Interestingly, MBL did not affect viral entry or replication kinetics. TEM and confocal imaging revealed the presence of MBL-bound pdmH1N1 inside infected A549 cells, suggesting that the endocytosed MBL may interact with intracellular components to promote the release of cytokines and chemokines. To this end, expressions of Toll-like receptors were examined (TLR3, TLR7, TLR8 and TLR9) and found that TLR3 expression was dramatically enhanced upon pdmH1N1 infection. Interestingly, in MBL-bound pdmH1N1 infection, TLR3 mRNA and protein expression was significantly higher than unbound pdmH1N1 infection in A549 cells. In addition, the NF-κB signaling was further activated in the presence of MBL-bound pdmH1N1. A novel physical interaction between MBL and TLR3 was also delineated as evidenced by MBL’s capability to bind to TLR3 in vitro; and their colocalization in the endosomes of the infected A549 cells. In summary, MBL can bind to pdmH1N1 virus but fails to inhibit its infection in human lung epithelial cell line. Upon pdmH1N1 infection, MBL is internalized with the virus into the cell, where it may associate with TLR3 to further amplify the NF-κB signaling and augment the cytokine production in the human lung epithelial cells. The present findings advocate the adverse immunomodulating role of MBL during pdmH1N1 infection. / published_or_final_version / Paediatrics and Adolescent Medicine / Doctoral / Doctor of Philosophy Influenza A virus Mannose H1N1 influenza - Immunological aspects Lectins
9	Tissue-wide dynamics of human anti-viral immunity Poon, Maya January 2022 (has links) The human body is exposed to a multitude of prevalent viruses, requiring ongoing surveillance and protection by the immune system. Maintenance of human anti-viral adaptive immunity in diverse tissue sites is determined by a multitude of factors and critical for long-term protection against repeat exposure to viral infection. Yet, studies of anti-viral immunity have primarily been limited to animal studies and studies of peripheral blood in humans. Studies in mice have demonstrated that memory T cells in tissues provide superior protection against viral infection compared to circulating T cells, particularly tissue-resident memory T cells (TRM), which remain in tissues long-term without re-entering circulation. However, much remains to be understood about how anti-viral immune responses are maintained in human tissues and how adaptive immune cells in various tissues sites function upon re-exposure to viral antigens. We have established a human tissue resource through a collaboration with LiveOnNY, a local organ procurement organization, to obtain blood and multiple lymphoid and mucosal sites from donors of all ages. Using this tissue resource, we employed comprehensive cellular and molecular analysis to investigate tissue immunity to three prevalent but distinct viruses—influenza A, CMV, and SARS-CoV-2. We compared CD8+ T cells recognizing ubiquitous and longstanding viruses influenza A and CMV across multiple tissue sites of 58 organ donors ages 1-78 years in order to elucidate how covariates of virus, tissue, age, and sex impact the anti-viral immune response. Using flow cytometry, T cell receptor repertoire sequencing, functional assays, and single-cell transcriptional profiling, we showed that virus specificity and tissue localization are the primary drivers of anti-viral T cell immune responses in the human body, with age and sex further influencing T cell subset differentiation. Specifically, virus specificity correlated with virus-specific T cell distribution, memory subset differentiation, and clonal repertoire, while tissue localization determined overall subset distribution and functional responses. We further investigated the tissue-localized immune response to emergent SARS-CoV-2. By examining multiple tissues of organ donors who had recovered from natural infection by SARS-CoV-2, we showed that adaptive memory immune responses persisted months after infection, with memory T and B cells preferentially localized in the lung and lung-associated lymph node. Persisting memory cell populations included tissue-resident T and B cells, particularly in the lung, as well as germinal center B cells in the lung-associated lymph node along with follicular helper T cells, indicating ongoing generation of humoral immunity. Together, these findings highlight the importance of tissue-localized anti-viral immunity and help to define characteristics of site-specific protective immunity that may be leveraged for the development of more effective treatment and prevention strategies. Immunology T cells--Therapeutic use Influenza--Immunological aspects Cytomegalovirus infections COVID-19 (Disease)--Treatment

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