BackgroundIndividuals suffering from spinal cord injury (SCI) are at higher risk for respiratory-related viral infections such as influenza. In a previous study (Zha et al., J Neuroinflammation 11:65, 2014), we demonstrated that chronic spinal cord injury caused impairment in CD8+T cell function with increased expression of the immunosuppressive protein, programmed cell death 1 (PD-1). The present study was undertaken to establish whether chronic SCI-induced immune deficits would affect antiviral immunity directed against primary and secondary infections.MethodsSix to seven weeks following a SCI contusion at thoracic level T9, mice were infected intranasally with influenza virus. Virus-specific immunity was analyzed at various time points post-infection and compared to uninjured controls.ResultsWe report that chronic thoracic SCI impairs the ability of the animals to mount an adequate antiviral immune response. While all uninjured control mice cleared the virus from their lungs by day 10 post-infection, a significant number (approximately 70 %) of chronic SCI mice did not clear the virus and succumbed to infection-induced mortality. This was attributed to severe deficits in both virus-specific antibody production and CD8+ T cell response in injured mice after primary infection. We also determined that previously acquired humoral immunity was maintained after spinal cord injury as vaccination against influenza A prior to injury-protected mice from a homologous viral challenge. In contrast, prior immunization did not protect mice from a heterotypic challenge with a different strain of influenza virus.ConclusionsTaken together, our data demonstrate that chronic SCI attenuates virus-specific humoral and cellular immunity during the establishment of primary response and impairs the development of memory CD8+ T cells. In contrast, B cell memory acquired through vaccination prior to SCI is preserved after injury which demonstrates that antigen-specific memory cells are refractory following injury. Our study defines important parameters of the deficits of chronic SCI-induced immune depression during a viral respiratory infection. Our objective is to better understand the mechanisms of spinal cord injury-induced immune depression with the goal of developing more effective therapies and reduce mortality due to complications from influenza and other infections.Electronic supplementary materialThe online version of this article (doi:10.1186/s12974-016-0574-y) contains supplementary material, which is available to authorized users.
Lytic replication of Kaposi's Sarcoma Associated Herpes Virus (KSHV) exacerbates Kaposi's sarcoma (KS) progression, an angiogenic spindle‐cell sarcoma associated with AIDS. Current antiviral therapy targeting lytic replication can prevent KS in seropositive patients. KSHV lytic infection is not manifested in vitro, and currently there are no animal models that display pathogenic phenotypes. In this study, we employed a biological and genetically mouse pathogen similar to KSHV, the murine gammaherpes virus (gHV) 68 (MHV68), that readily infects laboratory mice providing a valuable small animal model. Moreover, MHV68 in vitro infection exhibits a default lytic infection. Several studies have shown that during infection KSHV employs several viral proteins to de‐regulate the host transcription factor hypoxia inducible factor 1 alpha (HIF1α) and KSHV‐induced activation of HIF1α is necessary for viral persistence and KS progression. However, little is known about the role of HIF1 α in gHV replication and pathogenesis. To further investigate the role of this host factor, we induced transcriptional inactivation of HIF1α in MHV68 virus‐specific cells in vivo. Conditional knock out of HIF1α was achieved by infecting transgenic mice with Cre‐recombinase (Cre) LoxP specific site within the functional domain of HIF1α gene using a recombinant MHV68 that expressing a CMV driven Cre expression. Our data demonstrated for the first time that HIF1α inactivation during gammaherpes virus infection in vivo affects viral gene transcription resulting in impaired virus expansion and early clearance of acute infection in a mouse model. In addition, our results from in vitro MHV68 lytic infection of mouse fibroblasts lacking HIF1α showed that lytic virus production and transcription is decreased. During latency establishment in vivo, the frequency of MHV68 latent splenocytes undergoing latent to lytic replication was largely decreased as well. Our data suggest that HIF1α is required for sustained acute infection since it's deletion in virus‐infected cells resulted in early clearance of productive infection and impairment in reactivation. Moreover, HIF1α is required for mRNA upregulation of glycolytic enzymes during MHV68 lytic infection suggesting a role for HIF1a as a modulator of cell energetics and viral gene expression. We conclude that gammaherpes viruses required the function of the cellular host factor HIF1α in order to effectively replicate and establish latency within its host. Support or Funding Information National Cancer Institute 3R01CA136387‐08S1 This abstract is from the Experimental Biology 2018 Meeting. There is no full text article associated with this abstract published in The FASEB Journal.
While apoptosis plays a role in B-cell self-tolerance, its significance in preventing autoimmunity remains unclear. Here, we report that dysregulated B cell apoptosis leads to delayed onset autoimmune phenotype in mice. Our longitudinal studies revealed that mice with B cell-specific deletion of pro-apoptotic Bim (BBimfl/fl) have an expanded B cell compartment with a notable increase in transitional, antibody secreting and recently described double negative (DN) B cells. They develop greater hypergammaglobulinemia than mice lacking Bim in all cells and accumulate several autoantibodies characteristic of Systemic Lupus Erythematosus (SLE) and related Sjögren’s Syndrome (SS) including anti-nuclear, anti-Ro/SSA and anti-La/SSB at a level comparable to NODH2h4 autoimmune mouse model. Furthermore, lymphocytes infiltrated the tissues including submandibular glands and formed follicle-like structures populated with B cells, plasma cells and T follicular helper cells indicative of ongoing immune reaction. This autoimmunity was ameliorated upon deletion of Bruton’s tyrosine kinase (Btk) gene, which encodes a key B cell signaling protein. These studies suggest that Bim-mediated apoptosis suppresses and B cell tyrosine kinase signaling promotes B cell-mediated autoimmunity.
We frequently use diagrams or animations to reveal to others biological phenomena that are both invisible to the naked eye and difficult to conceptualize. But these didactic tools fall short in that they generally do not provide feedback or interaction with the user, nor adapt easily to the user’s needs and abilities. Adaptability to the user’s educational level and needs is critical to catalyze effective learning, especially when the new content is highly complex in nature. The need for adaptability is key in museum learning environments, where the student audience is very diverse in age and academic training. We are rethinking the way we go about representing biological processes to general audiences, particularly highly complex topics such as those found in neuroscience. We have experimented with the concept of using (what we are calling) “experiential posters” in the context of museum educational experiences to represent processes in neuroscience in a way that is more accessible to the general public. An experiential poster is an installation that uses props and staging to provide the user or learner an opportunity to “act out” the sequence of events and the flow of materials in a biological process of interest. We describe the use of an “experiential poster” to meet specific learning objectives. We also discuss the potential for its use in service learning and science outreach education.
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