Project description:PRV infection in swine can cause devastating disease and pose a potential threat to humans. Advancing the interplay between PRV and host is essential to elucidate the pathogenic mechanism of PRV and identify novel anti-PRV targets. In this study, we identified PARP11 as a host factor that can significantly affect PRV infection. Inhibition of PARP11 and knockout of PARP11 can significantly promoted PRV infection. Subsequently, we further found that PARP11 knockout upregulated the transcription of NXF1 and CRM1, resulting in enhanced transcription of viral genes. Furthermore, we also found that PARP11 knockout could activate the autophagy pathway and suppress the mTOR pathway during PRV infection. These findings could provide insight into the mechanism in which PARP11 participated during PRV infection and offer a potential target to develop anti-PRV therapies.

Project description:Flaviviruses pose a significant threat to public health due to their ability to infect the central nervous system (CNS) and cause severe neurologic disease. Astrocytes play a crucial role in the pathogenesis of flavivirus encephalitis through their maintenance of blood-brain barrier (BBB) integrity and their modulation of immune cell recruitment and activation within the CNS. We have previously shown that receptor interacting protein kinase-3 (RIPK3) is a central coordinator of neuroinflammation during CNS viral infection, a function that occurs independently of its canonical function in inducing necroptotic cell death. To date, however, roles for necroptosis-independent RIPK3 signaling in astrocytes are poorly understood. Here, we use mouse genetic tools to induce astrocyte-specific deletion, overexpression, and chemogenetic activation of RIPK3 to demonstrate an unexpected anti-inflammatory function for astrocytic RIPK3. RIPK3 activation in astrocytes was required for host survival in multiple models of flavivirus encephalitis, where it restricted neuropathogenesis by limiting immune cell recruitment to the CNS. Transcriptomic analysis revealed that, despite inducing a traditional pro-inflammatory transcriptional program, astrocytic RIPK3 paradoxically promoted neuroprotection through the upregulation of serpins, endogenous protease inhibitors with broad immunomodulatory activity. Notably, intracerebroventricular administration of SerpinA3N in infected mice preserved BBB integrity, reduced leukocyte infiltration, and improved survival outcomes in mice lacking astrocytic RIPK3. These findings highlight a previously unappreciated role for astrocytic RIPK3 in suppressing pathologic neuroinflammation and suggests new therapeutic targets for the treatment of flavivirus encephalitis.

Project description:Brain glia cells exhibit highly heterogeneity which can modify their genetic landscape and responding sensitivity, thus achieving appropriate responses to environmental changes for maintenance of CNS homeostasis. However, technical restriction has prevented the study on the self-orchestrating activity of CNS resident immune cells. Microglia and astrocytes are predominant responding cells at early stages during CNS viral infection. Their activation not only contributes to the recruitment of peripheral immune cells that aid in viral clearance, but also increases the risk of long-term detrimental inflammatory injury associated with many neurodegenerative diseases. Optimal autophagic activity is vital to maintain brain integrity, yet the autophagy regulation of immune activity in brain glia cells remains poorly understood. Here, we identify the membrane protein SHISA9 as an autophagy cargo receptor that modulates the heterogenic immune responses during CNS infection. By 10x single-cell RNA sequencing, we identify the astrocytes with increased Shisa9 expression followed by decreased expression of inflammatory transcriptional programs. Shisa9 has temporal characteristics in modulating both antiviral and inflammatory responses in microglia and astrocytes at different stages during infection. Shisa9-/- mice are highly susceptible to herpes simplex virus encephalitis, accompanied by higher rates of pathogenic astrocytes which might contribute to neurodegeneration progression and display a more severe neuroinflammation symptoms compared to wild-type mice. Taken together, our study unravels a critical role of selective autophagy in orchestrating immune heterogeneity of different CNS resident cells through SHISA9-IKKi axis.

Project description:Microglia, the resident macrophages of the central nervous system, exhibit altered gene expression in response to various neurological conditions. This study investigates the relationship between West Nile Virus infection, and microglial senescence, focusing on the role of LGALS3BP, a protein implicated in both antiviral responses and aging. Using spatial transcriptomics, RNA sequencing and flow cytometry, we characterized changes in microglial gene signatures in adult and aged mice following recovery from WNV encephalitis. Additionally, we analyzed Lgals3bp expression and generated Lgals3bp-deficient mice to assess the impact on neuroinflammation and microglial phenotypes. Our results show that WNV-activated microglia share transcriptional signatures with aged microglia, including upregulation of genes involved in interferon response and inflammation. Lgals3bp was broadly expressed in the CNS and robustly upregulated during WNV infection and aging. Lgals3bp-deficient mice exhibited reduced neuroinflammation, increased homeostatic microglial numbers, and altered T cell populations without differences in virologic control or survival. This data indicates that LGALS3BP has a role in regulating neuroinflammation and microglial activation and suggest that targeting LGALS3BP might provide a potential route for mitigating neuroinflammation-related cognitive decline in aging and post-viral infections.

Project description:To further explain why GSDMD deletion can significantly weaken the pathogenic ability of PRV and explore what role do GSDMD play and how do GSDMD act in the process of PRV infection and induction of tissue injury, we firstly sequenced the transcriptome of over 13,275 unselected cells of inflammatory cells isolated from the lung of PRV-infected WT mice and PRV-infected Gsdmd-/- mice using scRNA-seq .

Project description:We examined the global succinylation during PRV infection through a 4D label free quantitative proteomics method, which is the conventional separation of the three dimensions of mass-to-charge ratio, retention time, and ion intensity with the inclusion of the ion separation as a fourth dimension. We analyzed the function of some key enzymes that underwent succinylation and determine whether viral proteins undergo succinylation.

Project description:Japanese encephalitis virus (JEV) is a causative agent of encephalitis, mostly prevalent in Asia and South-Asian countries. Neuroinflammation is the hallmark of encephalitis, mediated in parts through the activation of brain-resident microglial cell, thus playing a critical role in determining pathogenesis. Deregulated activity of microglia can be lethal for the brain tissue. Interferon Regulatory Factor 8 (Irf8) mediates differentiation and transformation of microglia to reactive phenotypes and also regulates antiviral response through cross-talk with interferon pathway. In this study, we have conducted a comparative study between JEV infected C57BL/6 wild type and Irf8 Knockout (IRF8-/-) to identify the genes directly or indirectly regulated by IRF8.

Project description:Sustained smouldering, or low grade, activation of myeloid cells is a common hallmark of several chronic neurological diseases, including multiple sclerosis (MS). Distinct metabolic and mitochondrial features guide the activation and the diverse functional states of myeloid cells. However, how these metabolic features act to perpetuate neuroinflammation is currently unknown. Using a multiomics approach, we identified a new molecular signature that perpetuates the activation of myeloid cells through mitochondrial complex I (CI) activity driving reverse electron transport (RET) and the production of reactive oxygen species (ROS). Blocking CI activity in pro-inflammatory microglia protected the central nervous system (CNS) against neurotoxic damage and improved functional outcomes in animal disease models in vivo. Our data show that mitochondrial CI in microglia is a potential new therapeutic target to foster neuroprotection in smouldering inflammatory CNS disorders.

Project description:Sustained smouldering, or low grade, activation of myeloid cells is a common hallmark of several chronic neurological diseases, including multiple sclerosis (MS). Distinct metabolic and mitochondrial features guide the activation and the diverse functional states of myeloid cells. However, how these metabolic features act to perpetuate neuroinflammation is currently unknown. Using a multiomics approach, we identified a new molecular signature that perpetuates the activation of myeloid cells through mitochondrial complex I (CI) activity driving reverse electron transport (RET) and the production of reactive oxygen species (ROS). Blocking CI activity in pro-inflammatory microglia protected the central nervous system (CNS) against neurotoxic damage and improved functional outcomes in animal disease models in vivo. Our data show that mitochondrial CI in microglia is a potential new therapeutic target to foster neuroprotection in smouldering inflammatory CNS disorders.

Project description:Sustained smouldering, or low grade, activation of myeloid cells is a common hallmark of several chronic neurological diseases, including multiple sclerosis (MS). Distinct metabolic and mitochondrial features guide the activation and the diverse functional states of myeloid cells. However, how these metabolic features act to perpetuate neuroinflammation is currently unknown. Using a multiomics approach, we identified a new molecular signature that perpetuates the activation of myeloid cells through mitochondrial complex I (CI) activity driving reverse electron transport (RET) and the production of reactive oxygen species (ROS). Blocking CI activity in pro-inflammatory microglia protected the central nervous system (CNS) against neurotoxic damage and improved functional outcomes in animal disease models in vivo. Our data show that mitochondrial CI in microglia is a potential new therapeutic target to foster neuroprotection in smouldering inflammatory CNS disorders.